Merge pull request #187 from cyberman54/development

v1.6.5
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Verkehrsrot 2018-10-21 22:34:54 +02:00 committed by GitHub
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39
LICENSE
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@ -20,9 +20,9 @@ Parts of the source files in this repository are made available under different
listed below. Refer to each individual source file for more details. listed below. Refer to each individual source file for more details.
------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------
wifiscan.cpp wifiscan.cpp and macsniff.cpp:
Prior art was used for wifiscan.cpp and taken from Parts were derived or taken from
* Copyright (c) 2017, Łukasz Marcin Podkalicki <lpodkalicki@gmail.com> * Copyright (c) 2017, Łukasz Marcin Podkalicki <lpodkalicki@gmail.com>
* ESP32/016 WiFi Sniffer * ESP32/016 WiFi Sniffer
@ -208,10 +208,9 @@ under this License:
END OF TERMS AND CONDITIONS" END OF TERMS AND CONDITIONS"
------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------
src/lorawan.cpp and /lib/arduino-lmic-1.5.0-<...> lorawan.cpp
Parts of lorawan.cpp, and the arduino lmic library, which is included in the /lib directory of this Parts of lorawan.cpp, and the arduino lmic library were derived or taken from
repository, were derived or taken from
Arduino-LMIC Library Arduino-LMIC Library
TTN OTAA Example TTN OTAA Example
@ -222,10 +221,32 @@ and it's fork
LoraWAN-in-C library, adapted to run under the Arduino environment LoraWAN-in-C library, adapted to run under the Arduino environment
https://github.com/jpmeijers/arduino-lmic https://github.com/jpmeijers/arduino-lmic
under this Licence: under this MIT Licence:
"MIT License
Copyright (C) 2014-2016 IBM Corporation
Copyright (c) 2016-2018 MCCI Corporation
Copyright (c) 2015 Thomas Telkamp and Matthijs Kooijman
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE."
"License
Most source files in this repository are made available under the Eclipse Public License v1.0. The examples which use a more liberal license. Some of the AES code is available under the LGPL. Refer to each individual source file for more details."
------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------
blescan.cpp blescan.cpp
@ -415,4 +436,4 @@ under this Licence:
END OF TERMS AND CONDITIONS" END OF TERMS AND CONDITIONS"
------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------

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@ -59,7 +59,9 @@ Hardware dependent settings (pinout etc.) are stored in board files in /hal dire
Before compiling the code, Before compiling the code,
- **edit paxcounter.conf** and tailor settings in this file according to your needs and use case. Please take care of the duty cycle regulations of the LoRaWAN network you're going to use. - **edit src/paxcounter.conf** and tailor settings in this file according to your needs and use case. Please take care of the duty cycle regulations of the LoRaWAN network you're going to use.
- **edit src/lmic_config.h** and tailor settings in this file according to your country and device hardware. Please take care of national regulations when selecting the frequency band for LoRaWAN.
- **create file loraconf.h in your local /src directory** using the template [loraconf.sample.h](https://github.com/cyberman54/ESP32-Paxcounter/blob/master/src/loraconf.sample.h) and populate it with your personal APPEUI und APPKEY for the LoRaWAN network. If you're using popular <A HREF="https://thethingsnetwork.org">TheThingsNetwork</A> you can copy&paste the keys from TTN console or output of ttnctl. - **create file loraconf.h in your local /src directory** using the template [loraconf.sample.h](https://github.com/cyberman54/ESP32-Paxcounter/blob/master/src/loraconf.sample.h) and populate it with your personal APPEUI und APPKEY for the LoRaWAN network. If you're using popular <A HREF="https://thethingsnetwork.org">TheThingsNetwork</A> you can copy&paste the keys from TTN console or output of ttnctl.
@ -336,3 +338,4 @@ Thanks to
- [Oliver Brandmüller](https://github.com/spmrider) for idea and initial setup of this project - [Oliver Brandmüller](https://github.com/spmrider) for idea and initial setup of this project
- [Charles Hallard](https://github.com/hallard) for major code contributions to this project - [Charles Hallard](https://github.com/hallard) for major code contributions to this project
- [robbi5](https://github.com/robbi5) for the payload converter - [robbi5](https://github.com/robbi5) for the payload converter
- [terrillmoore](https://github.com/mcci-catena) for maintaining the LMIC for arduino LoRaWAN stack

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@ -53,7 +53,7 @@ extern std::array<uint64_t, 0xff> beacons;
extern TaskHandle_t irqHandlerTask, wifiSwitchTask; extern TaskHandle_t irqHandlerTask, wifiSwitchTask;
#ifdef HAS_GPS #ifdef HAS_GPS
#include "gps.h" #include "gpsread.h"
#endif #endif
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED) #if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
@ -67,7 +67,7 @@ extern TaskHandle_t irqHandlerTask, wifiSwitchTask;
#endif #endif
#ifdef HAS_SPI #ifdef HAS_SPI
#include "spi.h" #include "spisend.h"
#endif #endif
#ifdef HAS_DISPLAY #ifdef HAS_DISPLAY

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@ -1,5 +1,5 @@
#ifndef _GPS_H #ifndef _GPSREAD_H
#define _GPS_H #define _GPSREAD_H
#include <TinyGPS++.h> // library for parsing NMEA data #include <TinyGPS++.h> // library for parsing NMEA data
#include <TimeLib.h> #include <TimeLib.h>

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@ -17,7 +17,7 @@ int version_compare(const String v1, const String v2);
void display(const uint8_t row, const std::string status, void display(const uint8_t row, const std::string status,
const std::string msg); const std::string msg);
#ifdef HAS_DISPLAY #ifdef HAS_DISPLAY
void show_progress(size_t current, size_t size); void show_progress(unsigned long current, unsigned long size);
#endif #endif
#endif // USE_OTA #endif // USE_OTA

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@ -1,5 +1,5 @@
#ifndef _SPI_H #ifndef _SPISEND_H
#define _SPI_H #define _SPISEND_H
extern TaskHandle_t SpiTask; extern TaskHandle_t SpiTask;
extern QueueHandle_t SPISendQueue; extern QueueHandle_t SPISendQueue;

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@ -1,365 +0,0 @@
Arduino-LMIC library
====================
This repository contains the IBM LMIC (LoraMAC-in-C) library, slightly
modified to run in the Arduino environment, allowing using the SX1272,
SX1276 tranceivers and compatible modules (such as some HopeRF RFM9x
modules).
This library mostly exposes the functions defined by LMIC, it makes no
attempt to wrap them in a higher level API that is more in the Arduino
style. To find out how to use the library itself, see the examples, or
see the PDF file in the doc subdirectory.
This library requires Arduino IDE version 1.6.6 or above, since it
requires C99 mode to be enabled by default.
Installing
----------
To install this library:
- install it using the Arduino Library manager ("Sketch" -> "Include
Library" -> "Manage Libraries..."), or
- download a zipfile from github using the "Download ZIP" button and
install it using the IDE ("Sketch" -> "Include Library" -> "Add .ZIP
Library..."
- clone this git repository into your sketchbook/libraries folder.
For more info, see https://www.arduino.cc/en/Guide/Libraries
Features
--------
The LMIC library provides a fairly complete LoRaWAN Class A and Class B
implementation, supporting the EU-868 and US-915 bands. Only a limited
number of features was tested using this port on Arduino hardware, so be
careful when using any of the untested features.
What certainly works:
- Sending packets uplink, taking into account duty cycling.
- Encryption and message integrity checking.
- Receiving downlink packets in the RX2 window.
- Custom frequencies and datarate settings.
- Over-the-air activation (OTAA / joining).
What has not been tested:
- Receiving downlink packets in the RX1 window.
- Receiving and processing MAC commands.
- Class B operation.
If you try one of these untested features and it works, be sure to let
us know (creating a github issue is probably the best way for that).
Configuration
-------------
A number of features can be configured or disabled by editing the
`config.h` file in the library folder. Unfortunately the Arduino
environment does not offer any way to do this (compile-time)
configuration from the sketch, so be careful to recheck your
configuration when you switch between sketches or update the library.
At the very least, you should set the right type of transceiver (SX1272
vs SX1276) in config.h, most other values should be fine at their
defaults.
Supported hardware
------------------
This library is intended to be used with plain LoRa transceivers,
connecting to them using SPI. In particular, the SX1272 and SX1276
families are supported (which should include SX1273, SX1277, SX1278 and
SX1279 which only differ in the available frequencies, bandwidths and
spreading factors). It has been tested with both SX1272 and SX1276
chips, using the Semtech SX1272 evaluation board and the HopeRF RFM92
and RFM95 boards (which supposedly contain an SX1272 and SX1276 chip
respectively).
This library contains a full LoRaWAN stack and is intended to drive
these Transceivers directly. It is *not* intended to be used with
full-stack devices like the Microchip RN2483 and the Embit LR1272E.
These contain a transceiver and microcontroller that implements the
LoRaWAN stack and exposes a high-level serial interface instead of the
low-level SPI transceiver interface.
This library is intended to be used inside the Arduino environment. It
should be architecture-independent, so it should run on "normal" AVR
arduinos, but also on the ARM-based ones, and some success has been seen
running on the ESP8266 board as well. It was tested on the Arduino Uno,
Pinoccio Scout, Teensy LC and 3.x, ESP8266, Arduino 101.
This library an be quite heavy, especially if the fairly small ATmega
328p (such as in the Arduino Uno) is used. In the default configuration,
the available 32K flash space is nearly filled up (this includes some
debug output overhead, though). By disabling some features in `config.h`
(like beacon tracking and ping slots, which are not typically needed),
some space can be freed up. Some work is underway to replace the AES
encryption implementation, which should free up another 8K or so of
flash in the future, making this library feasible to run on a 328p
microcontroller.
Connections
-----------
To make this library work, your Arduino (or whatever Arduino-compatible
board you are using) should be connected to the transceiver. The exact
connections are a bit dependent on the transceiver board and Arduino
used, so this section tries to explain what each connection is for and
in what cases it is (not) required.
Note that the SX1272 module runs at 3.3V and likely does not like 5V on
its pins (though the datasheet is not say anything about this, and my
transceiver did not obviously break after accidentally using 5V I/O for
a few hours). To be safe, make sure to use a level shifter, or an
Arduino running at 3.3V. The Semtech evaluation board has 100 ohm resistors in
series with all data lines that might prevent damage, but I would not
count on that.
### Power
The SX127x transceivers need a supply voltage between 1.8V and 3.9V.
Using a 3.3V supply is typical. Some modules have a single power pin
(like the HopeRF modules, labeled 3.3V) but others expose multiple power
pins for different parts (like the Semtech evaluation board that has
`VDD_RF`, `VDD_ANA` and `VDD_FEM`), which can all be connected together.
Any *GND* pins need to be connected to the Arduino *GND* pin(s).
### SPI
The primary way of communicating with the transceiver is through SPI
(Serial Peripheral Interface). This uses four pins: MOSI, MISO, SCK and
SS. The former three need to be directly connected: so MOSI to MOSI,
MISO to MISO, SCK to SCK. Where these pins are located on your Arduino
varies, see for example the "Connections" section of the [Arduino SPI
documentation](SPI).
The SS (slave select) connection is a bit more flexible. On the SPI
slave side (the transceiver), this must be connect to the pin
(typically) labeled *NSS*. On the SPI master (Arduino) side, this pin
can connect to any I/O pin. Most Arduinos also have a pin labeled "SS",
but this is only relevant when the Arduino works as an SPI slave, which
is not the case here. Whatever pin you pick, you need to tell the
library what pin you used through the pin mapping (see below).
[SPI]: https://www.arduino.cc/en/Reference/SPI
### DIO pins
The DIO (digitial I/O) pins on the transceiver board can be configured
for various functions. The LMIC library uses them to get instant status
information from the transceiver. For example, when a LoRa transmission
starts, the DIO0 pin is configured as a TxDone output. When the
transmission is complete, the DIO0 pin is made high by the transceiver,
which can be detected by the LMIC library.
The LMIC library needs only access to DIO0, DIO1 and DIO2, the other
DIOx pins can be left disconnected. On the Arduino side, they can
connect to any I/O pin, since the current implementation does not use
interrupts or other special hardware features (though this might be
added in the feature, see also the "Timing" section).
In LoRa mode the DIO pins are used as follows:
* DIO0: TxDone and RxDone
* DIO1: RxTimeout
In FSK mode they are used as follows::
* DIO0: PayloadReady and PacketSent
* DIO2: TimeOut
Both modes need only 2 pins, but the tranceiver does not allow mapping
them in such a way that all needed interrupts map to the same 2 pins.
So, if both LoRa and FSK modes are used, all three pins must be
connected.
The pins used on the Arduino side should be configured in the pin
mapping in your sketch (see below).
### Reset
The transceiver has a reset pin that can be used to explicitely reset
it. The LMIC library uses this to ensure the chip is in a consistent
state at startup. In practice, this pin can be left disconnected, since
the transceiver will already be in a sane state on power-on, but
connecting it might prevent problems in some cases.
On the Arduino side, any I/O pin can be used. The pin number used must
be configured in the pin mapping (see below).
### RXTX
The transceiver contains two separate antenna connections: One for RX
and one for TX. A typical transceiver board contains an antenna switch
chip, that allows switching a single antenna between these RX and TX
connections. Such a antenna switcher can typically be told what
position it should be through an input pin, often labeled *RXTX*.
The easiest way to control the antenna switch is to use the *RXTX* pin
on the SX127x transceiver. This pin is automatically set high during TX
and low during RX. For example, the HopeRF boards seem to have this
connection in place, so they do not expose any *RXTX* pins and the pin
can be marked as unused in the pin mapping.
Some boards do expose the antenna switcher pin, and sometimes also the
SX127x *RXTX* pin. For example, the SX1272 evaluation board calls the
former *FEM_CTX* and the latter *RXTX*. Again, simply connecting these
together with a jumper wire is the easiest solution.
Alternatively, or if the SX127x *RXTX* pin is not available, LMIC can be
configured to control the antenna switch. Connect the antenna switch
control pin (e.g. *FEM_CTX* on the Semtech evaluation board) to any I/O
pin on the Arduino side, and configure the pin used in the pin map (see
below). It is not entirely clear why would *not* want the transceiver to
control the antenna directly, though.
### Pin mapping
As described above, most connections can use arbitrary I/O pins on the
Arduino side. To tell the LMIC library about these, a pin mapping struct
is used in the sketch file.
For example, this could look like this:
lmic_pinmap lmic_pins = {
.nss = 6,
.rxtx = LMIC_UNUSED_PIN,
.rst = 5,
.dio = {2, 3, 4},
};
The names refer to the pins on the transceiver side, the numbers refer
to the Arduino pin numbers (to use the analog pins, use constants like
`A0`). For the DIO pins, the three numbers refer to DIO0, DIO1 and DIO2
respectively. Any pins that are not needed should be specified as
`LMIC_UNUSED_PIN`. The nss and dio0 pin is required, the others can
potentially left out (depending on the environments and requirements,
see the notes above for when a pin can or cannot be left out).
The name of this struct must always be `lmic_pins`, which is a special name
recognized by the library.
#### LoRa Nexus by Ideetron
This board uses the following pin mapping:
const lmic_pinmap lmic_pins = {
.nss = 10,
.rxtx = LMIC_UNUSED_PIN,
.rst = LMIC_UNUSED_PIN, // hardwired to AtMega RESET
.dio = {4, 5, 7},
};
Examples
--------
This library currently provides three examples:
- `ttn-abp.ino` shows a basic transmission of a "Hello, world!" message
using the LoRaWAN protocol. It contains some frequency settings and
encryption keys intended for use with The Things Network, but these
also correspond to the default settings of most gateways, so it
should work with other networks and gateways as well. This example
uses activation-by-personalization (ABP, preconfiguring a device
address and encryption keys), and does not employ over-the-air
activation.
Reception of packets (in response to transmission, using the RX1 and
RX2 receive windows is also supported).
- `ttn-otaa.ino` also sends a "Hello, world!" message, but uses over
the air activation (OTAA) to first join a network to establish a
session and security keys. This was tested with The Things Network,
but should also work (perhaps with some changes) for other networks.
- `raw.ino` shows how to access the radio on a somewhat low level,
and allows to send raw (non-LoRaWAN) packets between nodes directly.
This is useful to verify basic connectivity, and when no gateway is
available, but this example also bypasses duty cycle checks, so be
careful when changing the settings.
Timing
------
Unfortunately, the SX127x tranceivers do not support accurate
timekeeping themselves (there is a sequencer that is *almost* sufficient
for timing the RX1 and RX2 downlink windows, but that is only available
in FSK mode, not in LoRa mode). This means that the microcontroller is
responsible for keeping track of time. In particular, it should note
when a packet finished transmitting, so it can open up the RX1 and RX2
receive windows at a fixed time after the end of transmission.
This timing uses the Arduino `micros()` timer, which has a granularity
of 4μs and is based on the primary microcontroller clock. For timing
events, the tranceiver uses its DIOx pins as interrupt outputs. In the
current implementation, these pins are not handled by an actual
interrupt handler, but they are just polled once every LMIC loop,
resulting in a bit inaccuracy in the timestamping. Also, running
scheduled jobs (such as opening up the receive windows) is done using a
polling approach, which might also result in further delays.
Fortunately, LoRa is a fairly slow protocol and the timing of the
receive windows is not super critical. To synchronize transmitter and
receiver, a preamble is first transmitted. Using LoRaWAN, this preamble
consists of 8 symbols, of which the receiver needs to see 4 symbols to
lock on. The current implementation tries to enable the receiver for 5
symbol times at 1.5 symbol after the start of the receive window,
meaning that a inacurracy of plus or minus 2.5 symbol times should be
acceptable.
At the fastest LoRa setting supported by the tranceiver (SF5BW500) a
single preamble symbol takes 64μs, so the receive window timing should
be accurate within 160μs (for LoRaWAN this is SF7BW250, needing accuracy
within 1280μs). This is certainly within a crystal's accuracy, but using
the internal oscillator is probably not feasible (which is 1% - 10%
accurate, depending on calibration). This accuracy should also be
feasible with the polling approach used, provided that the LMIC loop is
run often enough.
It would be good to properly review this code at some point, since it
seems that in some places some offsets and corrections are applied that
might not be appropriate for the Arduino environment. So if reception is
not working, the timing is something to have a closer look at.
The LMIC library was intended to connect the DIO pins to interrupt
lines and run code inside the interrupt handler. However, doing this
opens up an entire can of worms with regard to doing SPI transfers
inside interrupt routines (some of which is solved by the Arduino
`beginTransaction()` API, but possibly not everything). One simpler
alternative could be to use an interrupt handler to just store a
timestamp, and then do the actual handling in the main loop (this
requires modifications of the library to pass a timestamp to the LMIC
`radio_irq_handler()` function).
An even more accurate solution could be to use a dedicated timer with an
input capture unit, that can store the timestamp of a change on the DIO0
pin (the only one that is timing-critical) entirely in hardware.
Unfortunately, timer0, as used by Arduino's `millis()` and `micros()`
functions does not seem to have an input capture unit, meaning a
separate timer is needed for this.
If the main microcontroller does not have a crystal, but uses the
internal oscillator, the clock output of the transceiver (on DIO5) could
be usable to drive this timer instead of the main microcontroller clock,
to ensure the receive window timing is sufficiently accurate. Ideally,
this would use timer2, which supports asynchronous mode (e.g. running
while the microcontroller is sleeping), but that timer does not have an
input capture unit. Timer1 has one, but it seems it will stop running
once the microcontroller sleeps. Running the microcontroller in idle
mode with a slower clock might be feasible, though. Instead of using the
main crystal oscillator of the transceiver, it could be possible to use
the transceiver's internal RC oscillator (which is calibrated against
the transceiver crystal), or to calibrate the microcontroller internal
RC oscillator using the transceiver's clkout. However, that datasheet is
a bit vague on the RC oscillator's accuracy and how to use it exactly
(some registers seem to be FSK-mode only), so this needs some
experiments.
Downlink datarate
-----------------
Note that the datarate used for downlink packets in the RX2 window
defaults to SF12BW125 according to the specification, but some networks
use different values (iot.semtech.com and The Things Network both use
SF9BW). When using personalized activate (ABP), it is your
responsibility to set the right settings, e.g. by adding this to your
sketch (after calling `LMIC_setSession`). `ttn-abp.ino` already does
this.
LMIC.dn2Dr = DR_SF9;
When using OTAA, the network communicates the RX2 settings in the
join accept message, but the LMIC library does not currently process
these settings. Until that is solved (see issue #20), you should
manually set the RX2 rate, *after* joining (see the handling of
`EV_JOINED` in the `ttn-otaa.ino` for an example.
License
-------
Most source files in this repository are made available under the
Eclipse Public License v1.0. The examples which use a more liberal
license. Some of the AES code is available under the LGPL. Refer to each
individual source file for more details.

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@ -1,9 +0,0 @@
name=IBM LMIC framework
version=1.5.0+arduino-2
author=IBM
maintainer=Matthijs Kooijman <matthijs@stdin.nl>
sentence=Arduino port of the LMIC (LoraWAN-in-C, formerly LoraMAC-in-C) framework provided by IBM.
paragraph=Supports SX1272/SX1276 and HopeRF RFM92/RFM95 tranceivers
category=Communication
url=http://www.research.ibm.com/labs/zurich/ics/lrsc/lmic.html
architectures=*

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@ -1,41 +0,0 @@
/*******************************************************************************
* Copyright (c) 2015 Matthijs Kooijman
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* This the HAL to run LMIC on top of the Arduino environment.
*******************************************************************************/
#ifndef _hal_hal_h_
#define _hal_hal_h_
static const int NUM_DIO = 3;
#if defined(ESP32) || defined(NRF51)
#define LMIC_SPI_PINS_IN_MAPPING
struct lmic_pinmap {
u1_t mosi;
u1_t miso;
u1_t sck;
u1_t nss;
u1_t rxtx;
u1_t rst;
u1_t dio[NUM_DIO];
};
#else
struct lmic_pinmap {
u1_t nss;
u1_t rxtx;
u1_t rst;
u1_t dio[NUM_DIO];
};
#endif
// Use this for any unused pins.
const u1_t LMIC_UNUSED_PIN = 0xff;
// Declared here, to be defined an initialized by the application
extern const lmic_pinmap lmic_pins;
#endif // _hal_hal_h_

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@ -1,91 +0,0 @@
/*******************************************************************************
* Copyright (c) 2014-2015 IBM Corporation.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Zurich Research Lab - initial API, implementation and documentation
*******************************************************************************/
#ifndef _hal_hpp_
#define _hal_hpp_
#ifdef __cplusplus
extern "C"{
#endif
/*
* initialize hardware (IO, SPI, TIMER, IRQ).
*/
void hal_init (void);
/*
* drive radio NSS pin (0=low, 1=high).
*/
void hal_pin_nss (u1_t val);
/*
* drive radio RX/TX pins (0=rx, 1=tx).
*/
void hal_pin_rxtx (u1_t val);
/*
* control radio RST pin (0=low, 1=high, 2=floating)
*/
void hal_pin_rst (u1_t val);
/*
* perform 8-bit SPI transaction with radio.
* - write given byte 'outval'
* - read byte and return value
*/
u1_t hal_spi (u1_t outval);
/*
* disable all CPU interrupts.
* - might be invoked nested
* - will be followed by matching call to hal_enableIRQs()
*/
void hal_disableIRQs (void);
/*
* enable CPU interrupts.
*/
void hal_enableIRQs (void);
/*
* put system and CPU in low-power mode, sleep until interrupt.
*/
void hal_sleep (void);
/*
* return 32-bit system time in ticks.
*/
u4_t hal_ticks (void);
/*
* busy-wait until specified timestamp (in ticks) is reached.
*/
void hal_waitUntil (u4_t time);
/*
* check and rewind timer for target time.
* - return 1 if target time is close
* - otherwise rewind timer for target time or full period and return 0
*/
u1_t hal_checkTimer (u4_t targettime);
/*
* perform fatal failure action.
* - called by assertions
* - action could be HALT or reboot
*/
void hal_failed (const char *file, u2_t line);
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _hal_hpp_

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@ -1,391 +0,0 @@
/*******************************************************************************
* Copyright (c) 2014-2015 IBM Corporation.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Zurich Research Lab - initial API, implementation and documentation
*******************************************************************************/
#ifndef _lorabase_h_
#define _lorabase_h_
#ifdef __cplusplus
extern "C"{
#endif
// ================================================================================
// BEG: Keep in sync with lorabase.hpp
//
enum _cr_t { CR_4_5=0, CR_4_6, CR_4_7, CR_4_8 };
enum _sf_t { FSK=0, SF7, SF8, SF9, SF10, SF11, SF12, SFrfu };
enum _bw_t { BW125=0, BW250, BW500, BWrfu };
typedef u1_t cr_t;
typedef u1_t sf_t;
typedef u1_t bw_t;
typedef u1_t dr_t;
// Radio parameter set (encodes SF/BW/CR/IH/NOCRC)
typedef u2_t rps_t;
TYPEDEF_xref2rps_t;
enum { ILLEGAL_RPS = 0xFF };
enum { DR_PAGE_EU868 = 0x00 };
enum { DR_PAGE_US915 = 0x10 };
// Global maximum frame length
enum { STD_PREAMBLE_LEN = 8 };
enum { MAX_LEN_FRAME = 64 };
enum { LEN_DEVNONCE = 2 };
enum { LEN_ARTNONCE = 3 };
enum { LEN_NETID = 3 };
enum { DELAY_JACC1 = 5 }; // in secs
enum { DELAY_DNW1 = 1 }; // in secs down window #1
enum { DELAY_EXTDNW2 = 1 }; // in secs
enum { DELAY_JACC2 = DELAY_JACC1+(int)DELAY_EXTDNW2 }; // in secs
enum { DELAY_DNW2 = DELAY_DNW1 +(int)DELAY_EXTDNW2 }; // in secs down window #1
enum { BCN_INTV_exp = 7 };
enum { BCN_INTV_sec = 1<<BCN_INTV_exp };
enum { BCN_INTV_ms = BCN_INTV_sec*1000L };
enum { BCN_INTV_us = BCN_INTV_ms*1000L };
enum { BCN_RESERVE_ms = 2120 }; // space reserved for beacon and NWK management
enum { BCN_GUARD_ms = 3000 }; // end of beacon period to prevent interference with beacon
enum { BCN_SLOT_SPAN_ms = 30 }; // 2^12 reception slots a this span
enum { BCN_WINDOW_ms = BCN_INTV_ms-(int)BCN_GUARD_ms-(int)BCN_RESERVE_ms };
enum { BCN_RESERVE_us = 2120000 };
enum { BCN_GUARD_us = 3000000 };
enum { BCN_SLOT_SPAN_us = 30000 };
#if defined(CFG_eu868) // ==============================================
enum _dr_eu868_t { DR_SF12=0, DR_SF11, DR_SF10, DR_SF9, DR_SF8, DR_SF7, DR_SF7B, DR_FSK, DR_NONE };
enum { DR_DFLTMIN = DR_SF7 };
enum { DR_PAGE = DR_PAGE_EU868 };
// Default frequency plan for EU 868MHz ISM band
// Bands:
// g1 : 1% 14dBm
// g2 : 0.1% 14dBm
// g3 : 10% 27dBm
// freq band datarates
enum { EU868_F1 = 868100000, // g1 SF7-12
EU868_F2 = 868300000, // g1 SF7-12 FSK SF7/250
EU868_F3 = 868500000, // g1 SF7-12
EU868_F4 = 868850000, // g2 SF7-12
EU868_F5 = 869050000, // g2 SF7-12
EU868_F6 = 869525000, // g3 SF7-12
EU868_J4 = 864100000, // g2 SF7-12 used during join
EU868_J5 = 864300000, // g2 SF7-12 ditto
EU868_J6 = 864500000, // g2 SF7-12 ditto
};
enum { EU868_FREQ_MIN = 863000000,
EU868_FREQ_MAX = 870000000 };
enum { CHNL_PING = 5 };
enum { FREQ_PING = EU868_F6 }; // default ping freq
enum { DR_PING = DR_SF9 }; // default ping DR
enum { CHNL_DNW2 = 5 };
enum { FREQ_DNW2 = EU868_F6 };
enum { DR_DNW2 = DR_SF12 };
enum { CHNL_BCN = 5 };
enum { FREQ_BCN = EU868_F6 };
enum { DR_BCN = DR_SF9 };
enum { AIRTIME_BCN = 144384 }; // micros
enum {
// Beacon frame format EU SF9
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 3,
OFF_BCN_CRC1 = 7,
OFF_BCN_INFO = 8,
OFF_BCN_LAT = 9,
OFF_BCN_LON = 12,
OFF_BCN_CRC2 = 15,
LEN_BCN = 17
};
#elif defined(CFG_us915) // =========================================
enum _dr_us915_t { DR_SF10=0, DR_SF9, DR_SF8, DR_SF7, DR_SF8C, DR_NONE,
// Devices behind a router:
DR_SF12CR=8, DR_SF11CR, DR_SF10CR, DR_SF9CR, DR_SF8CR, DR_SF7CR };
enum { DR_DFLTMIN = DR_SF8C };
enum { DR_PAGE = DR_PAGE_US915 };
// Default frequency plan for US 915MHz
enum { US915_125kHz_UPFBASE = 902300000,
US915_125kHz_UPFSTEP = 200000,
US915_500kHz_UPFBASE = 903000000,
US915_500kHz_UPFSTEP = 1600000,
US915_500kHz_DNFBASE = 923300000,
US915_500kHz_DNFSTEP = 600000
};
enum { US915_FREQ_MIN = 902000000,
US915_FREQ_MAX = 928000000 };
enum { CHNL_PING = 0 }; // used only for default init of state (follows beacon - rotating)
enum { FREQ_PING = US915_500kHz_DNFBASE + CHNL_PING*US915_500kHz_DNFSTEP }; // default ping freq
enum { DR_PING = DR_SF10CR }; // default ping DR
enum { CHNL_DNW2 = 0 };
enum { FREQ_DNW2 = US915_500kHz_DNFBASE + CHNL_DNW2*US915_500kHz_DNFSTEP };
enum { DR_DNW2 = DR_SF12CR };
enum { CHNL_BCN = 0 }; // used only for default init of state (rotating beacon scheme)
enum { DR_BCN = DR_SF10CR };
enum { AIRTIME_BCN = 72192 }; // micros
enum {
// Beacon frame format US SF10
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 3,
OFF_BCN_CRC1 = 7,
OFF_BCN_INFO = 9,
OFF_BCN_LAT = 10,
OFF_BCN_LON = 13,
OFF_BCN_RFU1 = 16,
OFF_BCN_CRC2 = 17,
LEN_BCN = 19
};
#endif // ===================================================
enum {
// Join Request frame format
OFF_JR_HDR = 0,
OFF_JR_ARTEUI = 1,
OFF_JR_DEVEUI = 9,
OFF_JR_DEVNONCE = 17,
OFF_JR_MIC = 19,
LEN_JR = 23
};
enum {
// Join Accept frame format
OFF_JA_HDR = 0,
OFF_JA_ARTNONCE = 1,
OFF_JA_NETID = 4,
OFF_JA_DEVADDR = 7,
OFF_JA_RFU = 11,
OFF_JA_DLSET = 11,
OFF_JA_RXDLY = 12,
OFF_CFLIST = 13,
LEN_JA = 17,
LEN_JAEXT = 17+16
};
enum {
// Data frame format
OFF_DAT_HDR = 0,
OFF_DAT_ADDR = 1,
OFF_DAT_FCT = 5,
OFF_DAT_SEQNO = 6,
OFF_DAT_OPTS = 8,
};
enum { MAX_LEN_PAYLOAD = MAX_LEN_FRAME-(int)OFF_DAT_OPTS-4 };
enum {
// Bitfields in frame format octet
HDR_FTYPE = 0xE0,
HDR_RFU = 0x1C,
HDR_MAJOR = 0x03
};
enum { HDR_FTYPE_DNFLAG = 0x20 }; // flags DN frame except for HDR_FTYPE_PROP
enum {
// Values of frame type bit field
HDR_FTYPE_JREQ = 0x00,
HDR_FTYPE_JACC = 0x20,
HDR_FTYPE_DAUP = 0x40, // data (unconfirmed) up
HDR_FTYPE_DADN = 0x60, // data (unconfirmed) dn
HDR_FTYPE_DCUP = 0x80, // data confirmed up
HDR_FTYPE_DCDN = 0xA0, // data confirmed dn
HDR_FTYPE_REJOIN = 0xC0, // rejoin for roaming
HDR_FTYPE_PROP = 0xE0
};
enum {
HDR_MAJOR_V1 = 0x00,
};
enum {
// Bitfields in frame control octet
FCT_ADREN = 0x80,
FCT_ADRARQ = 0x40,
FCT_ACK = 0x20,
FCT_MORE = 0x10, // also in DN direction: Class B indicator
FCT_OPTLEN = 0x0F,
};
enum {
// In UP direction: signals class B enabled
FCT_CLASSB = FCT_MORE
};
enum {
NWKID_MASK = (int)0xFE000000,
NWKID_BITS = 7
};
// MAC uplink commands downwlink too
enum {
// Class A
MCMD_LCHK_REQ = 0x02, // - link check request : -
MCMD_LADR_ANS = 0x03, // - link ADR answer : u1:7-3:RFU, 3/2/1: pow/DR/Ch ACK
MCMD_DCAP_ANS = 0x04, // - duty cycle answer : -
MCMD_DN2P_ANS = 0x05, // - 2nd DN slot status : u1:7-2:RFU 1/0:datarate/channel ack
MCMD_DEVS_ANS = 0x06, // - device status ans : u1:battery 0,1-254,255=?, u1:7-6:RFU,5-0:margin(-32..31)
MCMD_SNCH_ANS = 0x07, // - set new channel : u1: 7-2=RFU, 1/0:DR/freq ACK
// Class B
MCMD_PING_IND = 0x10, // - pingability indic : u1: 7=RFU, 6-4:interval, 3-0:datarate
MCMD_PING_ANS = 0x11, // - ack ping freq : u1: 7-1:RFU, 0:freq ok
MCMD_BCNI_REQ = 0x12, // - next beacon start : -
};
// MAC downlink commands
enum {
// Class A
MCMD_LCHK_ANS = 0x02, // link check answer : u1:margin 0-254,255=unknown margin / u1:gwcnt
MCMD_LADR_REQ = 0x03, // link ADR request : u1:DR/TXPow, u2:chmask, u1:chpage/repeat
MCMD_DCAP_REQ = 0x04, // duty cycle cap : u1:255 dead [7-4]:RFU, [3-0]:cap 2^-k
MCMD_DN2P_SET = 0x05, // 2nd DN window param: u1:7-4:RFU/3-0:datarate, u3:freq
MCMD_DEVS_REQ = 0x06, // device status req : -
MCMD_SNCH_REQ = 0x07, // set new channel : u1:chidx, u3:freq, u1:DRrange
// Class B
MCMD_PING_SET = 0x11, // set ping freq : u3: freq
MCMD_BCNI_ANS = 0x12, // next beacon start : u2: delay(in TUNIT millis), u1:channel
};
enum {
MCMD_BCNI_TUNIT = 30 // time unit of delay value in millis
};
enum {
MCMD_LADR_ANS_RFU = 0xF8, // RFU bits
MCMD_LADR_ANS_POWACK = 0x04, // 0=not supported power level
MCMD_LADR_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_LADR_ANS_CHACK = 0x01, // 0=unknown channel enabled
};
enum {
MCMD_DN2P_ANS_RFU = 0xFC, // RFU bits
MCMD_DN2P_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_DN2P_ANS_CHACK = 0x01, // 0=unknown channel enabled
};
enum {
MCMD_SNCH_ANS_RFU = 0xFC, // RFU bits
MCMD_SNCH_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_SNCH_ANS_FQACK = 0x01, // 0=rejected channel frequency
};
enum {
MCMD_PING_ANS_RFU = 0xFE,
MCMD_PING_ANS_FQACK = 0x01
};
enum {
MCMD_DEVS_EXT_POWER = 0x00, // external power supply
MCMD_DEVS_BATT_MIN = 0x01, // min battery value
MCMD_DEVS_BATT_MAX = 0xFE, // max battery value
MCMD_DEVS_BATT_NOINFO = 0xFF, // unknown battery level
};
// Bit fields byte#3 of MCMD_LADR_REQ payload
enum {
MCMD_LADR_CHP_125ON = 0x60, // special channel page enable, bits applied to 64..71
MCMD_LADR_CHP_125OFF = 0x70, // ditto
MCMD_LADR_N3RFU_MASK = 0x80,
MCMD_LADR_CHPAGE_MASK = 0xF0,
MCMD_LADR_REPEAT_MASK = 0x0F,
MCMD_LADR_REPEAT_1 = 0x01,
MCMD_LADR_CHPAGE_1 = 0x10
};
// Bit fields byte#0 of MCMD_LADR_REQ payload
enum {
MCMD_LADR_DR_MASK = 0xF0,
MCMD_LADR_POW_MASK = 0x0F,
MCMD_LADR_DR_SHIFT = 4,
MCMD_LADR_POW_SHIFT = 0,
#if defined(CFG_eu868)
MCMD_LADR_SF12 = DR_SF12<<4,
MCMD_LADR_SF11 = DR_SF11<<4,
MCMD_LADR_SF10 = DR_SF10<<4,
MCMD_LADR_SF9 = DR_SF9 <<4,
MCMD_LADR_SF8 = DR_SF8 <<4,
MCMD_LADR_SF7 = DR_SF7 <<4,
MCMD_LADR_SF7B = DR_SF7B<<4,
MCMD_LADR_FSK = DR_FSK <<4,
MCMD_LADR_20dBm = 0,
MCMD_LADR_14dBm = 1,
MCMD_LADR_11dBm = 2,
MCMD_LADR_8dBm = 3,
MCMD_LADR_5dBm = 4,
MCMD_LADR_2dBm = 5,
#elif defined(CFG_us915)
MCMD_LADR_SF10 = DR_SF10<<4,
MCMD_LADR_SF9 = DR_SF9 <<4,
MCMD_LADR_SF8 = DR_SF8 <<4,
MCMD_LADR_SF7 = DR_SF7 <<4,
MCMD_LADR_SF8C = DR_SF8C<<4,
MCMD_LADR_SF12CR = DR_SF12CR<<4,
MCMD_LADR_SF11CR = DR_SF11CR<<4,
MCMD_LADR_SF10CR = DR_SF10CR<<4,
MCMD_LADR_SF9CR = DR_SF9CR<<4,
MCMD_LADR_SF8CR = DR_SF8CR<<4,
MCMD_LADR_SF7CR = DR_SF7CR<<4,
MCMD_LADR_30dBm = 0,
MCMD_LADR_28dBm = 1,
MCMD_LADR_26dBm = 2,
MCMD_LADR_24dBm = 3,
MCMD_LADR_22dBm = 4,
MCMD_LADR_20dBm = 5,
MCMD_LADR_18dBm = 6,
MCMD_LADR_16dBm = 7,
MCMD_LADR_14dBm = 8,
MCMD_LADR_12dBm = 9,
MCMD_LADR_10dBm = 10
#endif
};
// Device address
typedef u4_t devaddr_t;
// RX quality (device)
enum { RSSI_OFF=64, SNR_SCALEUP=4 };
inline sf_t getSf (rps_t params) { return (sf_t)(params & 0x7); }
inline rps_t setSf (rps_t params, sf_t sf) { return (rps_t)((params & ~0x7) | sf); }
inline bw_t getBw (rps_t params) { return (bw_t)((params >> 3) & 0x3); }
inline rps_t setBw (rps_t params, bw_t cr) { return (rps_t)((params & ~0x18) | (cr<<3)); }
inline cr_t getCr (rps_t params) { return (cr_t)((params >> 5) & 0x3); }
inline rps_t setCr (rps_t params, cr_t cr) { return (rps_t)((params & ~0x60) | (cr<<5)); }
inline int getNocrc(rps_t params) { return ((params >> 7) & 0x1); }
inline rps_t setNocrc(rps_t params, int nocrc) { return (rps_t)((params & ~0x80) | (nocrc<<7)); }
inline int getIh (rps_t params) { return ((params >> 8) & 0xFF); }
inline rps_t setIh (rps_t params, int ih) { return (rps_t)((params & ~0xFF00) | (ih<<8)); }
inline rps_t makeRps (sf_t sf, bw_t bw, cr_t cr, int ih, int nocrc) {
return sf | (bw<<3) | (cr<<5) | (nocrc?(1<<7):0) | ((ih&0xFF)<<8);
}
#define MAKERPS(sf,bw,cr,ih,nocrc) ((rps_t)((sf) | ((bw)<<3) | ((cr)<<5) | ((nocrc)?(1<<7):0) | ((ih&0xFF)<<8)))
// Two frames with params r1/r2 would interfere on air: same SFx + BWx
inline int sameSfBw(rps_t r1, rps_t r2) { return ((r1^r2)&0x1F) == 0; }
extern CONST_TABLE(u1_t, _DR2RPS_CRC)[];
inline rps_t updr2rps (dr_t dr) { return (rps_t)TABLE_GET_U1(_DR2RPS_CRC, dr+1); }
inline rps_t dndr2rps (dr_t dr) { return setNocrc(updr2rps(dr),1); }
inline int isFasterDR (dr_t dr1, dr_t dr2) { return dr1 > dr2; }
inline int isSlowerDR (dr_t dr1, dr_t dr2) { return dr1 < dr2; }
inline dr_t incDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+2)==ILLEGAL_RPS ? dr : (dr_t)(dr+1); } // increase data rate
inline dr_t decDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr )==ILLEGAL_RPS ? dr : (dr_t)(dr-1); } // decrease data rate
inline dr_t assertDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+1)==ILLEGAL_RPS ? DR_DFLTMIN : dr; } // force into a valid DR
inline bit_t validDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+1)!=ILLEGAL_RPS; } // in range
inline dr_t lowerDR (dr_t dr, u1_t n) { while(n--){dr=decDR(dr);} return dr; } // decrease data rate by n steps
//
// BEG: Keep in sync with lorabase.hpp
// ================================================================================
// Convert between dBm values and power codes (MCMD_LADR_XdBm)
s1_t pow2dBm (u1_t mcmd_ladr_p1);
// Calculate airtime
ostime_t calcAirTime (rps_t rps, u1_t plen);
// Sensitivity at given SF/BW
int getSensitivity (rps_t rps);
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _lorabase_h_

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/*******************************************************************************
* Copyright (c) 2014-2015 IBM Corporation.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Zurich Research Lab - initial API, implementation and documentation
*******************************************************************************/
#include "lmic.h"
#include <stdbool.h>
// RUNTIME STATE
static struct {
osjob_t* scheduledjobs;
osjob_t* runnablejobs;
} OS;
void os_init () {
memset(&OS, 0x00, sizeof(OS));
hal_init();
radio_init();
LMIC_init();
}
ostime_t os_getTime () {
return hal_ticks();
}
static u1_t unlinkjob (osjob_t** pnext, osjob_t* job) {
for( ; *pnext; pnext = &((*pnext)->next)) {
if(*pnext == job) { // unlink
*pnext = job->next;
return 1;
}
}
return 0;
}
// clear scheduled job
void os_clearCallback (osjob_t* job) {
hal_disableIRQs();
u1_t res = unlinkjob(&OS.scheduledjobs, job) || unlinkjob(&OS.runnablejobs, job);
hal_enableIRQs();
#if LMIC_DEBUG_LEVEL > 1
if (res)
lmic_printf("%lu: Cleared job %p\n", os_getTime(), job);
#endif
}
// schedule immediately runnable job
void os_setCallback (osjob_t* job, osjobcb_t cb) {
osjob_t** pnext;
hal_disableIRQs();
// remove if job was already queued
os_clearCallback(job);
// fill-in job
job->func = cb;
job->next = NULL;
// add to end of run queue
for(pnext=&OS.runnablejobs; *pnext; pnext=&((*pnext)->next));
*pnext = job;
hal_enableIRQs();
#if LMIC_DEBUG_LEVEL > 1
lmic_printf("%lu: Scheduled job %p, cb %p ASAP\n", os_getTime(), job, cb);
#endif
}
// schedule timed job
void os_setTimedCallback (osjob_t* job, ostime_t time, osjobcb_t cb) {
osjob_t** pnext;
hal_disableIRQs();
// remove if job was already queued
os_clearCallback(job);
// fill-in job
job->deadline = time;
job->func = cb;
job->next = NULL;
// insert into schedule
for(pnext=&OS.scheduledjobs; *pnext; pnext=&((*pnext)->next)) {
if((*pnext)->deadline - time > 0) { // (cmp diff, not abs!)
// enqueue before next element and stop
job->next = *pnext;
break;
}
}
*pnext = job;
hal_enableIRQs();
#if LMIC_DEBUG_LEVEL > 1
lmic_printf("%lu: Scheduled job %p, cb %p at %lu\n", os_getTime(), job, cb, time);
#endif
}
// execute jobs from timer and from run queue
void os_runloop () {
while(1) {
os_runloop_once();
}
}
void os_runloop_once() {
#if LMIC_DEBUG_LEVEL > 1
bool has_deadline = false;
#endif
osjob_t* j = NULL;
hal_disableIRQs();
// check for runnable jobs
if(OS.runnablejobs) {
j = OS.runnablejobs;
OS.runnablejobs = j->next;
} else if(OS.scheduledjobs && hal_checkTimer(OS.scheduledjobs->deadline)) { // check for expired timed jobs
j = OS.scheduledjobs;
OS.scheduledjobs = j->next;
#if LMIC_DEBUG_LEVEL > 1
has_deadline = true;
#endif
} else { // nothing pending
hal_sleep(); // wake by irq (timer already restarted)
}
hal_enableIRQs();
if(j) { // run job callback
#if LMIC_DEBUG_LEVEL > 1
lmic_printf("%lu: Running job %p, cb %p, deadline %lu\n", os_getTime(), j, j->func, has_deadline ? j->deadline : 0);
#endif
j->func(j);
}
}

46
lib/arduino-lmic-master/.gitignore vendored Normal file
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# Compiled Object files
*.slo
*.lo
*.o
*.obj
# Precompiled Headers
*.gch
*.pch
# Compiled Dynamic libraries
*.so
*.dylib
*.dll
# Fortran module files
*.mod
*.smod
# Compiled Static libraries
*.lai
*.la
*.a
*.lib
# Executables
*.exe
*.out
*.app
# Backup files
*.BAK
*.CKP
# files from Visual Micro
Release
*.vcxproj
*.vcxproj.filters
*.vcxitems
vs-readme.txt
__vm
.vs
*.sln
# files from vscode
.vscode

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^CVS
.*/CVS
.*/CVS/.*
\.\#.*$
^\.DS_Store$
.*\.BAK$
.*\.bak$
.*\.CKP$
^build
^build/.*
^.*\.o$
^.*\.d$
^.*\.td$
\.a$
^core$
.*/core$
.*\.rej$

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# Adding a new region to Arduino LMIC
This variant of the Arduino LMIC code supports adding additional regions beyond the eu868 and us915 bands supoprted by the original IBM LMIC 1.6 code.
This document sketches how to add a new region.
## Planning
### Determine the region/region category
Compare the target region (in the LoRaWAN regional specification) to the EU868 and US915 regions. There are three possibilities.
1. the region is like the EU region. There are a limited number of channels (up to 8), and only a small number of channels are used for OTAA join operations. The response masks refer to individual channels, and the JOIN-response can send frequencies of specific channels to be added.
2. The region is like the US region. There are many channels (the US has 64) with fixed frequences, and the channel masks refer to subsets of the fixed channels.
3. The region is not really like either the EU or US. At the moment, it seems that CN470-510MHz (section 2.6 of LoRaWAN Regional Parameters spec V1.0.2rB) falls into this category.
Bandplans in categories (1) and (2) are easily supported. Bandplans in category (3) are not supoprted by the current code.
### Check whether the region is already listed in `lmic_config_preconditions.h`
Check `src/lmic/lmic_config_preconditions.h` and scan the `LMIC_REGION_...` definitions. The numeric values are assigned based on the subchapter in section 2 of the LoRaWAN 1.0.2 Regional Parmaters document. If your symbol is already there, then the first part of adaptation has already been done. There will already be a corresponding `CFG_...` symbol. But if your region isn't supported, you'll need to add it here.
- `LMIC_REGION_myregion` must be a distinct integer, and must be less than 32 (so as to fit into a bitmask)
## Make the appropriate changes in `lmic_config_preconditions.h`
- `LMIC_REGION_SUPPORTED` is a bit mask of all regions supported by the code. Your new region must appear in this list.
- `CFG_LMIC_REGION_MASK` is a bit mask that, when expanded, returns a bitmask for each defined `CFG_...` variable. You must add your `CFG_myregion` symbol to this list.
- `CFG_region` evaluates to the `LMIC_REGION_...` value for the selected region (as long as only one region is selected). The header files check for this, so you don't have to.
- `CFG_LMIC_EU_like_MASK` is a bitmask of regions that are EU-like, and `CFG_LMIC_US_like_MASK` is a bitmask of regions that are US-like. Add your region to the appropriate one of these two variables.
## Document your region in `config.h`
You'll see where the regions are listed. Add yours.
## Document your region in `README.md`
You'll see where the regions are listed. Add yours.
## Add the definitions for your region in `lorabase.h`
- If your region is EU like, copy the EU block. Document any duty-cycle limitations.
- if your region is US like, copy the US block.
- As appropriate, copy `lorabase_eu868.h` or `lorabase_us915.h` to make your own `lorabase_myregion.h`. Fill in the symbols.
At time of writing, you need to duplicate some code to copy some settings from `..._CONFIG_SYMBOL` to the corresponding `CONFIG_SYMBOL`; and you need to put some region-specific knowledge into the `lorabase.h` header file. The long-term direction is to put all the regional knowledge into the region-specific header, and then the central code will just copy. The architectural impulse is that we'll want to be able to reuse the regional header files in other contexts. On the other hand, because it's error prone, we don't want to `#include` files that aren't being used; otherwise you could accidentally use EU parameters in US code, etc.
- Now's a good time to test-compile and clean out errors introduced. You'll still have problems compiling, but they should look like this:
```
lmic.c:29: In file included from
lmic_bandplan.h: 52:3: error: #error "maxFrameLen() not defined by bandplan"
# error "maxFrameLen() not defined by bandplan"
lmic_bandplan.h: 56:3: error: #error "pow2dBm() not defined by bandplan"
# error "pow2dBm() not defined by bandplan"
```
## Edit `lmic_bandplan.h`
The next step is to add the region-specific interfaces for your region.
Do this by editing `lmic_bandplan.h` and adding the appropriate call to a (new) region-specific file `lmic_bandplan_myregion.h`, where "myregion" is the abbreviation for your region.
Then, if your region is eu868-like, copy `lmic_bandplan_eu868.h` to create your new region-specific header file; otherwise copy `lmic_bandplan_us915.h`.
## Create `lmic_myregion.c`
Once again, you will start by copying either `lmic_eu868.c` or `lmic_us915.c` to create your new file. Then touch it up as necessary.
## General Discussion
- You'll find it easier to do the test compiles using the example scripts in this directory, rather than trying to get all the Catena framework going too. On the other hand, working with the Catena framework will expose more problems.
## Addding the region to the Arduino_LoRaWAN library
In `Arduino_LoRaWAN_ttn.h`:
- Add a new class with name `Arduino_LoRaWAN_ttn_myregion`, copied either from the `Arduino_LoRaWAN_ttn_eu868` class or the `Arduino_LoRaWAN_ttn_us915` class.
- Extend the list of `#if defined(CFG_eu868)` etc to define `Arduino_LoRaWAN_REGION_TAG` to the suffix of your new class if `CFG_myregion` is defined.
Then copy either `ttn_eu868_netbegin.cpp`/`ttn_eu868_netjoin.cpp` or `ttn_us915_netbegin.cpp`/`ttn_us915_netjoin.cpp` to make your own file(s) for the key functions.

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MIT License
Copyright (C) 2014-2016 IBM Corporation
Copyright (c) 2016-2018 MCCI Corporation
Copyright (c) 2015 Thomas Telkamp and Matthijs Kooijman
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.

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DISCLAIMER: DISCLAIMER:
Please note that the software is provided AS IS and we cannot Please note that the software is provided AS IS and we cannot
provide support for optimizations, adaptations, integration, provide support for optimizations, adaptations, integration,
ports to other platforms or device drivers! ports to other platforms or device drivers!

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============================================================================== ==============================================================================
LMIC VERSION 1.4 (17-Mar-2015) LMIC VERSION 1.6 (13-July-2015)
------------------------------- ---------------------------------
- changed API: inverted port indicator flag in LMIC.txrxFlags - License changed to BSD
(now TXRX_PORT, previously TXRX_NOPORT) - Modem included, see LMiC-Modem.pdf and examples/modem
- Additional stm32 hardware and Blipper board specific peripheral code
- fixed offset OFF_CFLIST constant
- changed CRC-16 algorithm for beacons to CCITT(XMODEM) polynomial ==============================================================================
LMIC VERSION 1.5 (8-May-2015)
- fixed radio driver (low data rate optimization for SF11+SF12 only for BW125) ------------------------------
- fixed timer rollover handling in job queue - fixed condition in convFreq()
============================================================================== - fixed freq*100 bug and freq==0 bug for CFList
LMIC VERSION 1.5 (8-May-2015)
------------------------------ - fixed TX scheduling bug
- fixed condition in convFreq() - better support for GNU compiler toolchain
- fixed freq*100 bug and freq==0 bug for CFList
==============================================================================
- fixed TX scheduling bug LMIC VERSION 1.4 (17-Mar-2015)
-------------------------------
- better support for GNU compiler toolchain
- changed API: inverted port indicator flag in LMIC.txrxFlags
============================================================================== (now TXRX_PORT, previously TXRX_NOPORT)
- fixed offset OFF_CFLIST constant
- changed CRC-16 algorithm for beacons to CCITT(XMODEM) polynomial
- fixed radio driver (low data rate optimization for SF11+SF12 only for BW125)
- fixed timer rollover handling in job queue
==============================================================================

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name=MCCI LoRaWAN LMIC library
version=2.2.2
author=IBM, Matthis Kooijman, Terry Moore, ChaeHee Won, Frank Rose
maintainer=Terry Moore <tmm@mcci.com>
sentence=Arduino port of the LMIC (LoraWAN-MAC-in-C) framework provided by IBM.
paragraph=Supports SX1272/SX1276 and HopeRF RFM92/RFM95 tranceivers. Refactored to support multiple bandplans beyond the original two supported by the IBM LMIC code. Various enhancements and bug fixes from MCCI and The Things Network New York. Original IBM URL http://www.research.ibm.com/labs/zurich/ics/lrsc/lmic.html.
category=Communication
url=https://github.com/mcci-catena/arduino-lmic
architectures=*

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/****************************************************************************************** /******************************************************************************************
#if defined(USE_IDEETRON_AES) #if defined(USE_IDEETRON_AES)
* Copyright 2015, 2016 Ideetron B.V. * Copyright 2015, 2016 Ideetron B.V.
* *
* This program is free software: you can redistribute it and/or modify * This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by * it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or * the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version. * (at your option) any later version.
* *
* This program is distributed in the hope that it will be useful, * This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of * but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details. * GNU Lesser General Public License for more details.
* *
* You should have received a copy of the GNU Lesser General Public License * You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>. * along with this program. If not, see <http://www.gnu.org/licenses/>.
******************************************************************************************/ ******************************************************************************************/
/****************************************************************************************** /******************************************************************************************
* *
* File: AES-128_V10.cpp * File: AES-128_V10.cpp
* Author: Gerben den Hartog * Author: Gerben den Hartog
* Compagny: Ideetron B.V. * Compagny: Ideetron B.V.
* Website: http://www.ideetron.nl/LoRa * Website: http://www.ideetron.nl/LoRa
* E-mail: info@ideetron.nl * E-mail: info@ideetron.nl
******************************************************************************************/ ******************************************************************************************/
/**************************************************************************************** /****************************************************************************************
* *
* Created on: 20-10-2015 * Created on: 20-10-2015
* Supported Hardware: ID150119-02 Nexus board with RFM95 * Supported Hardware: ID150119-02 Nexus board with RFM95
* *
* Firmware Version 1.0 * Firmware Version 1.0
* First version * First version
****************************************************************************************/ ****************************************************************************************/
// This file was taken from // This file was taken from
// https://github.com/Ideetron/RFM95W_Nexus/tree/master/LoRaWAN_V31 for // https://github.com/Ideetron/RFM95W_Nexus/tree/master/LoRaWAN_V31 for
// use with LMIC. It was only cosmetically modified: // use with LMIC. It was only cosmetically modified:
// - AES_Encrypt was renamed to lmic_aes_encrypt. // - AES_Encrypt was renamed to lmic_aes_encrypt.
// - All other functions and variables were made static // - All other functions and variables were made static
// - Tabs were converted to 2 spaces // - Tabs were converted to 2 spaces
// - An #include and #if guard was added // - An #include and #if guard was added
// - S_Table is now stored in PROGMEM // - S_Table is now stored in PROGMEM
#include "../../lmic/oslmic.h" #include "../../lmic/oslmic.h"
#if defined(USE_IDEETRON_AES) #if defined(USE_IDEETRON_AES)
/* /*
******************************************************************************************** ********************************************************************************************
* Global Variables * Global Variables
******************************************************************************************** ********************************************************************************************
*/ */
static unsigned char State[4][4]; static unsigned char State[4][4];
static CONST_TABLE(unsigned char, S_Table)[16][16] = { static CONST_TABLE(unsigned char, S_Table)[16][16] = {
{0x63,0x7C,0x77,0x7B,0xF2,0x6B,0x6F,0xC5,0x30,0x01,0x67,0x2B,0xFE,0xD7,0xAB,0x76}, {0x63,0x7C,0x77,0x7B,0xF2,0x6B,0x6F,0xC5,0x30,0x01,0x67,0x2B,0xFE,0xD7,0xAB,0x76},
{0xCA,0x82,0xC9,0x7D,0xFA,0x59,0x47,0xF0,0xAD,0xD4,0xA2,0xAF,0x9C,0xA4,0x72,0xC0}, {0xCA,0x82,0xC9,0x7D,0xFA,0x59,0x47,0xF0,0xAD,0xD4,0xA2,0xAF,0x9C,0xA4,0x72,0xC0},
{0xB7,0xFD,0x93,0x26,0x36,0x3F,0xF7,0xCC,0x34,0xA5,0xE5,0xF1,0x71,0xD8,0x31,0x15}, {0xB7,0xFD,0x93,0x26,0x36,0x3F,0xF7,0xCC,0x34,0xA5,0xE5,0xF1,0x71,0xD8,0x31,0x15},
{0x04,0xC7,0x23,0xC3,0x18,0x96,0x05,0x9A,0x07,0x12,0x80,0xE2,0xEB,0x27,0xB2,0x75}, {0x04,0xC7,0x23,0xC3,0x18,0x96,0x05,0x9A,0x07,0x12,0x80,0xE2,0xEB,0x27,0xB2,0x75},
{0x09,0x83,0x2C,0x1A,0x1B,0x6E,0x5A,0xA0,0x52,0x3B,0xD6,0xB3,0x29,0xE3,0x2F,0x84}, {0x09,0x83,0x2C,0x1A,0x1B,0x6E,0x5A,0xA0,0x52,0x3B,0xD6,0xB3,0x29,0xE3,0x2F,0x84},
{0x53,0xD1,0x00,0xED,0x20,0xFC,0xB1,0x5B,0x6A,0xCB,0xBE,0x39,0x4A,0x4C,0x58,0xCF}, {0x53,0xD1,0x00,0xED,0x20,0xFC,0xB1,0x5B,0x6A,0xCB,0xBE,0x39,0x4A,0x4C,0x58,0xCF},
{0xD0,0xEF,0xAA,0xFB,0x43,0x4D,0x33,0x85,0x45,0xF9,0x02,0x7F,0x50,0x3C,0x9F,0xA8}, {0xD0,0xEF,0xAA,0xFB,0x43,0x4D,0x33,0x85,0x45,0xF9,0x02,0x7F,0x50,0x3C,0x9F,0xA8},
{0x51,0xA3,0x40,0x8F,0x92,0x9D,0x38,0xF5,0xBC,0xB6,0xDA,0x21,0x10,0xFF,0xF3,0xD2}, {0x51,0xA3,0x40,0x8F,0x92,0x9D,0x38,0xF5,0xBC,0xB6,0xDA,0x21,0x10,0xFF,0xF3,0xD2},
{0xCD,0x0C,0x13,0xEC,0x5F,0x97,0x44,0x17,0xC4,0xA7,0x7E,0x3D,0x64,0x5D,0x19,0x73}, {0xCD,0x0C,0x13,0xEC,0x5F,0x97,0x44,0x17,0xC4,0xA7,0x7E,0x3D,0x64,0x5D,0x19,0x73},
{0x60,0x81,0x4F,0xDC,0x22,0x2A,0x90,0x88,0x46,0xEE,0xB8,0x14,0xDE,0x5E,0x0B,0xDB}, {0x60,0x81,0x4F,0xDC,0x22,0x2A,0x90,0x88,0x46,0xEE,0xB8,0x14,0xDE,0x5E,0x0B,0xDB},
{0xE0,0x32,0x3A,0x0A,0x49,0x06,0x24,0x5C,0xC2,0xD3,0xAC,0x62,0x91,0x95,0xE4,0x79}, {0xE0,0x32,0x3A,0x0A,0x49,0x06,0x24,0x5C,0xC2,0xD3,0xAC,0x62,0x91,0x95,0xE4,0x79},
{0xE7,0xC8,0x37,0x6D,0x8D,0xD5,0x4E,0xA9,0x6C,0x56,0xF4,0xEA,0x65,0x7A,0xAE,0x08}, {0xE7,0xC8,0x37,0x6D,0x8D,0xD5,0x4E,0xA9,0x6C,0x56,0xF4,0xEA,0x65,0x7A,0xAE,0x08},
{0xBA,0x78,0x25,0x2E,0x1C,0xA6,0xB4,0xC6,0xE8,0xDD,0x74,0x1F,0x4B,0xBD,0x8B,0x8A}, {0xBA,0x78,0x25,0x2E,0x1C,0xA6,0xB4,0xC6,0xE8,0xDD,0x74,0x1F,0x4B,0xBD,0x8B,0x8A},
{0x70,0x3E,0xB5,0x66,0x48,0x03,0xF6,0x0E,0x61,0x35,0x57,0xB9,0x86,0xC1,0x1D,0x9E}, {0x70,0x3E,0xB5,0x66,0x48,0x03,0xF6,0x0E,0x61,0x35,0x57,0xB9,0x86,0xC1,0x1D,0x9E},
{0xE1,0xF8,0x98,0x11,0x69,0xD9,0x8E,0x94,0x9B,0x1E,0x87,0xE9,0xCE,0x55,0x28,0xDF}, {0xE1,0xF8,0x98,0x11,0x69,0xD9,0x8E,0x94,0x9B,0x1E,0x87,0xE9,0xCE,0x55,0x28,0xDF},
{0x8C,0xA1,0x89,0x0D,0xBF,0xE6,0x42,0x68,0x41,0x99,0x2D,0x0F,0xB0,0x54,0xBB,0x16} {0x8C,0xA1,0x89,0x0D,0xBF,0xE6,0x42,0x68,0x41,0x99,0x2D,0x0F,0xB0,0x54,0xBB,0x16}
}; };
extern "C" void lmic_aes_encrypt(unsigned char *Data, unsigned char *Key); #ifdef __cplusplus
static void AES_Add_Round_Key(unsigned char *Round_Key); extern "C" {
static unsigned char AES_Sub_Byte(unsigned char Byte); #endif
static void AES_Shift_Rows(); void lmic_aes_encrypt(unsigned char *Data, unsigned char *Key);
static void AES_Mix_Collums(); #ifdef __cplusplus
static void AES_Calculate_Round_Key(unsigned char Round, unsigned char *Round_Key); }
static void Send_State(); #endif
/* static void AES_Add_Round_Key(unsigned char *Round_Key);
***************************************************************************************** static unsigned char AES_Sub_Byte(unsigned char Byte);
* Description : Function for encrypting data using AES-128 static void AES_Shift_Rows();
* static void AES_Mix_Collums();
* Arguments : *Data Data to encrypt is a 16 byte long arry static void AES_Calculate_Round_Key(unsigned char Round, unsigned char *Round_Key);
* *Key Key to encrypt data with is a 16 byte long arry static void Send_State();
*****************************************************************************************
*/ /*
void lmic_aes_encrypt(unsigned char *Data, unsigned char *Key) *****************************************************************************************
{ * Description : Function for encrypting data using AES-128
unsigned char i; *
unsigned char Row,Collum; * Arguments : *Data Data to encrypt is a 16 byte long arry
unsigned char Round = 0x00; * *Key Key to encrypt data with is a 16 byte long arry
unsigned char Round_Key[16]; *****************************************************************************************
*/
//Copy input to State arry void lmic_aes_encrypt(unsigned char *Data, unsigned char *Key)
for(Collum = 0; Collum < 4; Collum++) {
{ unsigned char i;
for(Row = 0; Row < 4; Row++) unsigned char Row,Collum;
{ unsigned char Round = 0x00;
State[Row][Collum] = Data[Row + (4*Collum)]; unsigned char Round_Key[16];
}
} //Copy input to State arry
for(Collum = 0; Collum < 4; Collum++)
//Copy key to round key {
for(i = 0; i < 16; i++) for(Row = 0; Row < 4; Row++)
{ {
Round_Key[i] = Key[i]; State[Row][Collum] = Data[Row + (4*Collum)];
} }
}
//Add round key
AES_Add_Round_Key(Round_Key); //Copy key to round key
for(i = 0; i < 16; i++)
//Preform 9 full rounds {
for(Round = 1; Round < 10; Round++) Round_Key[i] = Key[i];
{ }
//Preform Byte substitution with S table
for(Collum = 0; Collum < 4; Collum++) //Add round key
{ AES_Add_Round_Key(Round_Key);
for(Row = 0; Row < 4; Row++)
{ //Preform 9 full rounds
State[Row][Collum] = AES_Sub_Byte(State[Row][Collum]); for(Round = 1; Round < 10; Round++)
} {
} //Preform Byte substitution with S table
for(Collum = 0; Collum < 4; Collum++)
//Preform Row Shift {
AES_Shift_Rows(); for(Row = 0; Row < 4; Row++)
{
//Mix Collums State[Row][Collum] = AES_Sub_Byte(State[Row][Collum]);
AES_Mix_Collums(); }
}
//Calculate new round key
AES_Calculate_Round_Key(Round,Round_Key); //Preform Row Shift
AES_Shift_Rows();
//Add round key
AES_Add_Round_Key(Round_Key); //Mix Collums
} AES_Mix_Collums();
//Last round whitout mix collums //Calculate new round key
//Preform Byte substitution with S table AES_Calculate_Round_Key(Round,Round_Key);
for(Collum = 0; Collum < 4; Collum++)
{ //Add round key
for(Row = 0; Row < 4; Row++) AES_Add_Round_Key(Round_Key);
{ }
State[Row][Collum] = AES_Sub_Byte(State[Row][Collum]);
} //Last round whitout mix collums
} //Preform Byte substitution with S table
for(Collum = 0; Collum < 4; Collum++)
//Shift rows {
AES_Shift_Rows(); for(Row = 0; Row < 4; Row++)
{
//Calculate new round key State[Row][Collum] = AES_Sub_Byte(State[Row][Collum]);
AES_Calculate_Round_Key(Round,Round_Key); }
}
//Add round Key
AES_Add_Round_Key(Round_Key); //Shift rows
AES_Shift_Rows();
//Copy the State into the data array
for(Collum = 0; Collum < 4; Collum++) //Calculate new round key
{ AES_Calculate_Round_Key(Round,Round_Key);
for(Row = 0; Row < 4; Row++)
{ //Add round Key
Data[Row + (4*Collum)] = State[Row][Collum]; AES_Add_Round_Key(Round_Key);
}
} //Copy the State into the data array
for(Collum = 0; Collum < 4; Collum++)
} {
for(Row = 0; Row < 4; Row++)
/* {
***************************************************************************************** Data[Row + (4*Collum)] = State[Row][Collum];
* Description : Function that add's the round key for the current round }
* }
* Arguments : *Round_Key 16 byte long array holding the Round Key
***************************************************************************************** }
*/
static void AES_Add_Round_Key(unsigned char *Round_Key) /*
{ *****************************************************************************************
unsigned char Row,Collum; * Description : Function that add's the round key for the current round
*
for(Collum = 0; Collum < 4; Collum++) * Arguments : *Round_Key 16 byte long array holding the Round Key
{ *****************************************************************************************
for(Row = 0; Row < 4; Row++) */
{ static void AES_Add_Round_Key(unsigned char *Round_Key)
State[Row][Collum] = State[Row][Collum] ^ Round_Key[Row + (4*Collum)]; {
} unsigned char Row,Collum;
}
} for(Collum = 0; Collum < 4; Collum++)
{
/* for(Row = 0; Row < 4; Row++)
***************************************************************************************** {
* Description : Function that substitutes a byte with a byte from the S_Table State[Row][Collum] = State[Row][Collum] ^ Round_Key[Row + (4*Collum)];
* }
* Arguments : Byte The byte that will be substituted }
* }
* Return : The return is the found byte in the S_Table
***************************************************************************************** /*
*/ *****************************************************************************************
static unsigned char AES_Sub_Byte(unsigned char Byte) * Description : Function that substitutes a byte with a byte from the S_Table
{ *
unsigned char S_Row,S_Collum; * Arguments : Byte The byte that will be substituted
unsigned char S_Byte; *
* Return : The return is the found byte in the S_Table
//Split byte up in Row and Collum *****************************************************************************************
S_Row = ((Byte >> 4) & 0x0F); */
S_Collum = (Byte & 0x0F); static unsigned char AES_Sub_Byte(unsigned char Byte)
{
//Find the correct byte in the S_Table unsigned char S_Row,S_Collum;
S_Byte = TABLE_GET_U1_TWODIM(S_Table, S_Row, S_Collum); unsigned char S_Byte;
return S_Byte; //Split byte up in Row and Collum
} S_Row = ((Byte >> 4) & 0x0F);
S_Collum = (Byte & 0x0F);
/*
***************************************************************************************** //Find the correct byte in the S_Table
* Description : Function that preforms the shift row operation described in the AES standard S_Byte = TABLE_GET_U1_TWODIM(S_Table, S_Row, S_Collum);
*****************************************************************************************
*/ return S_Byte;
static void AES_Shift_Rows() }
{
unsigned char Buffer; /*
*****************************************************************************************
//Row 0 doesn't change * Description : Function that preforms the shift row operation described in the AES standard
*****************************************************************************************
//Shift Row 1 one left */
//Store firt byte in buffer static void AES_Shift_Rows()
Buffer = State[1][0]; {
//Shift all bytes unsigned char Buffer;
State[1][0] = State[1][1];
State[1][1] = State[1][2]; //Row 0 doesn't change
State[1][2] = State[1][3];
State[1][3] = Buffer; //Shift Row 1 one left
//Store firt byte in buffer
//Shift row 2 two left Buffer = State[1][0];
Buffer = State[2][0]; //Shift all bytes
State[2][0] = State[2][2]; State[1][0] = State[1][1];
State[2][2] = Buffer; State[1][1] = State[1][2];
Buffer = State[2][1]; State[1][2] = State[1][3];
State[2][1] = State[2][3]; State[1][3] = Buffer;
State[2][3] = Buffer;
//Shift row 2 two left
//Shift row 3 three left Buffer = State[2][0];
Buffer = State[3][3]; State[2][0] = State[2][2];
State[3][3] = State[3][2]; State[2][2] = Buffer;
State[3][2] = State[3][1]; Buffer = State[2][1];
State[3][1] = State[3][0]; State[2][1] = State[2][3];
State[3][0] = Buffer; State[2][3] = Buffer;
}
//Shift row 3 three left
/* Buffer = State[3][3];
***************************************************************************************** State[3][3] = State[3][2];
* Description : Function that preforms the Mix Collums operation described in the AES standard State[3][2] = State[3][1];
***************************************************************************************** State[3][1] = State[3][0];
*/ State[3][0] = Buffer;
static void AES_Mix_Collums() }
{
unsigned char Row,Collum; /*
unsigned char a[4], b[4]; *****************************************************************************************
for(Collum = 0; Collum < 4; Collum++) * Description : Function that preforms the Mix Collums operation described in the AES standard
{ *****************************************************************************************
for(Row = 0; Row < 4; Row++) */
{ static void AES_Mix_Collums()
a[Row] = State[Row][Collum]; {
b[Row] = (State[Row][Collum] << 1); unsigned char Row,Collum;
unsigned char a[4], b[4];
if((State[Row][Collum] & 0x80) == 0x80) for(Collum = 0; Collum < 4; Collum++)
{ {
b[Row] = b[Row] ^ 0x1B; for(Row = 0; Row < 4; Row++)
} {
} a[Row] = State[Row][Collum];
State[0][Collum] = b[0] ^ a[1] ^ b[1] ^ a[2] ^ a[3]; b[Row] = (State[Row][Collum] << 1);
State[1][Collum] = a[0] ^ b[1] ^ a[2] ^ b[2] ^ a[3];
State[2][Collum] = a[0] ^ a[1] ^ b[2] ^ a[3] ^ b[3]; if((State[Row][Collum] & 0x80) == 0x80)
State[3][Collum] = a[0] ^ b[0] ^ a[1] ^ a[2] ^ b[3]; {
} b[Row] = b[Row] ^ 0x1B;
} }
}
/* State[0][Collum] = b[0] ^ a[1] ^ b[1] ^ a[2] ^ a[3];
***************************************************************************************** State[1][Collum] = a[0] ^ b[1] ^ a[2] ^ b[2] ^ a[3];
* Description : Function that calculaties the round key for the current round State[2][Collum] = a[0] ^ a[1] ^ b[2] ^ a[3] ^ b[3];
* State[3][Collum] = a[0] ^ b[0] ^ a[1] ^ a[2] ^ b[3];
* Arguments : Round Number of current Round }
* *Round_Key 16 byte long array holding the Round Key }
*****************************************************************************************
*/ /*
static void AES_Calculate_Round_Key(unsigned char Round, unsigned char *Round_Key) *****************************************************************************************
{ * Description : Function that calculaties the round key for the current round
unsigned char i,j; *
unsigned char b; * Arguments : Round Number of current Round
unsigned char Temp[4]; * *Round_Key 16 byte long array holding the Round Key
unsigned char Buffer; *****************************************************************************************
unsigned char Rcon; */
static void AES_Calculate_Round_Key(unsigned char Round, unsigned char *Round_Key)
//Calculate first Temp {
//Copy laste byte from previous key unsigned char i,j;
for(i = 0; i < 4; i++) unsigned char b;
{ unsigned char Temp[4];
Temp[i] = Round_Key[i+12]; unsigned char Buffer;
} unsigned char Rcon;
//Rotate Temp //Calculate first Temp
Buffer = Temp[0]; //Copy laste byte from previous key
Temp[0] = Temp[1]; for(i = 0; i < 4; i++)
Temp[1] = Temp[2]; {
Temp[2] = Temp[3]; Temp[i] = Round_Key[i+12];
Temp[3] = Buffer; }
//Substitute Temp //Rotate Temp
for(i = 0; i < 4; i++) Buffer = Temp[0];
{ Temp[0] = Temp[1];
Temp[i] = AES_Sub_Byte(Temp[i]); Temp[1] = Temp[2];
} Temp[2] = Temp[3];
Temp[3] = Buffer;
//Calculate Rcon
Rcon = 0x01; //Substitute Temp
while(Round != 1) for(i = 0; i < 4; i++)
{ {
b = Rcon & 0x80; Temp[i] = AES_Sub_Byte(Temp[i]);
Rcon = Rcon << 1; }
if(b == 0x80)
{ //Calculate Rcon
Rcon = Rcon ^ 0x1b; Rcon = 0x01;
} while(Round != 1)
Round--; {
} b = Rcon & 0x80;
Rcon = Rcon << 1;
//XOR Rcon if(b == 0x80)
Temp[0] = Temp[0] ^ Rcon; {
Rcon = Rcon ^ 0x1b;
//Calculate new key }
for(i = 0; i < 4; i++) Round--;
{ }
for(j = 0; j < 4; j++)
{ //XOR Rcon
Round_Key[j + (4*i)] = Round_Key[j + (4*i)] ^ Temp[j]; Temp[0] = Temp[0] ^ Rcon;
Temp[j] = Round_Key[j + (4*i)];
} //Calculate new key
} for(i = 0; i < 4; i++)
} {
for(j = 0; j < 4; j++)
#endif // defined(USE_IDEETRON_AES) {
Round_Key[j + (4*i)] = Round_Key[j + (4*i)] ^ Temp[j];
Temp[j] = Round_Key[j + (4*i)];
}
}
}
#endif // defined(USE_IDEETRON_AES)

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@ -1,370 +1,386 @@
/******************************************************************************* /*
* Copyright (c) 2014-2015 IBM Corporation. * Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved. This program and the accompanying materials * All rights reserved.
* are made available under the terms of the Eclipse Public License v1.0 *
* which accompanies this distribution, and is available at * Redistribution and use in source and binary forms, with or without
* http://www.eclipse.org/legal/epl-v10.html * modification, are permitted provided that the following conditions are met:
* * * Redistributions of source code must retain the above copyright
* Contributors: * notice, this list of conditions and the following disclaimer.
* IBM Zurich Research Lab - initial API, implementation and documentation * * Redistributions in binary form must reproduce the above copyright
*******************************************************************************/ * notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
#include "../lmic/oslmic.h" * * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
#if defined(USE_ORIGINAL_AES) * derived from this software without specific prior written permission.
*
#define AES_MICSUB 0x30 // internal use only * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
static CONST_TABLE(u4_t, AES_RCON)[10] = { * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
0x01000000, 0x02000000, 0x04000000, 0x08000000, 0x10000000, * DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
0x20000000, 0x40000000, 0x80000000, 0x1B000000, 0x36000000 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
}; * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
static CONST_TABLE(u1_t, AES_S)[256] = { * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
0x63, 0x7C, 0x77, 0x7B, 0xF2, 0x6B, 0x6F, 0xC5, 0x30, 0x01, 0x67, 0x2B, 0xFE, 0xD7, 0xAB, 0x76, * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
0xCA, 0x82, 0xC9, 0x7D, 0xFA, 0x59, 0x47, 0xF0, 0xAD, 0xD4, 0xA2, 0xAF, 0x9C, 0xA4, 0x72, 0xC0, * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
0xB7, 0xFD, 0x93, 0x26, 0x36, 0x3F, 0xF7, 0xCC, 0x34, 0xA5, 0xE5, 0xF1, 0x71, 0xD8, 0x31, 0x15, */
0x04, 0xC7, 0x23, 0xC3, 0x18, 0x96, 0x05, 0x9A, 0x07, 0x12, 0x80, 0xE2, 0xEB, 0x27, 0xB2, 0x75,
0x09, 0x83, 0x2C, 0x1A, 0x1B, 0x6E, 0x5A, 0xA0, 0x52, 0x3B, 0xD6, 0xB3, 0x29, 0xE3, 0x2F, 0x84, #include "../lmic/oslmic.h"
0x53, 0xD1, 0x00, 0xED, 0x20, 0xFC, 0xB1, 0x5B, 0x6A, 0xCB, 0xBE, 0x39, 0x4A, 0x4C, 0x58, 0xCF,
0xD0, 0xEF, 0xAA, 0xFB, 0x43, 0x4D, 0x33, 0x85, 0x45, 0xF9, 0x02, 0x7F, 0x50, 0x3C, 0x9F, 0xA8, #if defined(USE_ORIGINAL_AES)
0x51, 0xA3, 0x40, 0x8F, 0x92, 0x9D, 0x38, 0xF5, 0xBC, 0xB6, 0xDA, 0x21, 0x10, 0xFF, 0xF3, 0xD2,
0xCD, 0x0C, 0x13, 0xEC, 0x5F, 0x97, 0x44, 0x17, 0xC4, 0xA7, 0x7E, 0x3D, 0x64, 0x5D, 0x19, 0x73, #define AES_MICSUB 0x30 // internal use only
0x60, 0x81, 0x4F, 0xDC, 0x22, 0x2A, 0x90, 0x88, 0x46, 0xEE, 0xB8, 0x14, 0xDE, 0x5E, 0x0B, 0xDB,
0xE0, 0x32, 0x3A, 0x0A, 0x49, 0x06, 0x24, 0x5C, 0xC2, 0xD3, 0xAC, 0x62, 0x91, 0x95, 0xE4, 0x79, static CONST_TABLE(u4_t, AES_RCON)[10] = {
0xE7, 0xC8, 0x37, 0x6D, 0x8D, 0xD5, 0x4E, 0xA9, 0x6C, 0x56, 0xF4, 0xEA, 0x65, 0x7A, 0xAE, 0x08, 0x01000000, 0x02000000, 0x04000000, 0x08000000, 0x10000000,
0xBA, 0x78, 0x25, 0x2E, 0x1C, 0xA6, 0xB4, 0xC6, 0xE8, 0xDD, 0x74, 0x1F, 0x4B, 0xBD, 0x8B, 0x8A, 0x20000000, 0x40000000, 0x80000000, 0x1B000000, 0x36000000
0x70, 0x3E, 0xB5, 0x66, 0x48, 0x03, 0xF6, 0x0E, 0x61, 0x35, 0x57, 0xB9, 0x86, 0xC1, 0x1D, 0x9E, };
0xE1, 0xF8, 0x98, 0x11, 0x69, 0xD9, 0x8E, 0x94, 0x9B, 0x1E, 0x87, 0xE9, 0xCE, 0x55, 0x28, 0xDF,
0x8C, 0xA1, 0x89, 0x0D, 0xBF, 0xE6, 0x42, 0x68, 0x41, 0x99, 0x2D, 0x0F, 0xB0, 0x54, 0xBB, 0x16, static CONST_TABLE(u1_t, AES_S)[256] = {
}; 0x63, 0x7C, 0x77, 0x7B, 0xF2, 0x6B, 0x6F, 0xC5, 0x30, 0x01, 0x67, 0x2B, 0xFE, 0xD7, 0xAB, 0x76,
0xCA, 0x82, 0xC9, 0x7D, 0xFA, 0x59, 0x47, 0xF0, 0xAD, 0xD4, 0xA2, 0xAF, 0x9C, 0xA4, 0x72, 0xC0,
static CONST_TABLE(u4_t, AES_E1)[256] = { 0xB7, 0xFD, 0x93, 0x26, 0x36, 0x3F, 0xF7, 0xCC, 0x34, 0xA5, 0xE5, 0xF1, 0x71, 0xD8, 0x31, 0x15,
0xC66363A5, 0xF87C7C84, 0xEE777799, 0xF67B7B8D, 0xFFF2F20D, 0xD66B6BBD, 0xDE6F6FB1, 0x91C5C554, 0x04, 0xC7, 0x23, 0xC3, 0x18, 0x96, 0x05, 0x9A, 0x07, 0x12, 0x80, 0xE2, 0xEB, 0x27, 0xB2, 0x75,
0x60303050, 0x02010103, 0xCE6767A9, 0x562B2B7D, 0xE7FEFE19, 0xB5D7D762, 0x4DABABE6, 0xEC76769A, 0x09, 0x83, 0x2C, 0x1A, 0x1B, 0x6E, 0x5A, 0xA0, 0x52, 0x3B, 0xD6, 0xB3, 0x29, 0xE3, 0x2F, 0x84,
0x8FCACA45, 0x1F82829D, 0x89C9C940, 0xFA7D7D87, 0xEFFAFA15, 0xB25959EB, 0x8E4747C9, 0xFBF0F00B, 0x53, 0xD1, 0x00, 0xED, 0x20, 0xFC, 0xB1, 0x5B, 0x6A, 0xCB, 0xBE, 0x39, 0x4A, 0x4C, 0x58, 0xCF,
0x41ADADEC, 0xB3D4D467, 0x5FA2A2FD, 0x45AFAFEA, 0x239C9CBF, 0x53A4A4F7, 0xE4727296, 0x9BC0C05B, 0xD0, 0xEF, 0xAA, 0xFB, 0x43, 0x4D, 0x33, 0x85, 0x45, 0xF9, 0x02, 0x7F, 0x50, 0x3C, 0x9F, 0xA8,
0x75B7B7C2, 0xE1FDFD1C, 0x3D9393AE, 0x4C26266A, 0x6C36365A, 0x7E3F3F41, 0xF5F7F702, 0x83CCCC4F, 0x51, 0xA3, 0x40, 0x8F, 0x92, 0x9D, 0x38, 0xF5, 0xBC, 0xB6, 0xDA, 0x21, 0x10, 0xFF, 0xF3, 0xD2,
0x6834345C, 0x51A5A5F4, 0xD1E5E534, 0xF9F1F108, 0xE2717193, 0xABD8D873, 0x62313153, 0x2A15153F, 0xCD, 0x0C, 0x13, 0xEC, 0x5F, 0x97, 0x44, 0x17, 0xC4, 0xA7, 0x7E, 0x3D, 0x64, 0x5D, 0x19, 0x73,
0x0804040C, 0x95C7C752, 0x46232365, 0x9DC3C35E, 0x30181828, 0x379696A1, 0x0A05050F, 0x2F9A9AB5, 0x60, 0x81, 0x4F, 0xDC, 0x22, 0x2A, 0x90, 0x88, 0x46, 0xEE, 0xB8, 0x14, 0xDE, 0x5E, 0x0B, 0xDB,
0x0E070709, 0x24121236, 0x1B80809B, 0xDFE2E23D, 0xCDEBEB26, 0x4E272769, 0x7FB2B2CD, 0xEA75759F, 0xE0, 0x32, 0x3A, 0x0A, 0x49, 0x06, 0x24, 0x5C, 0xC2, 0xD3, 0xAC, 0x62, 0x91, 0x95, 0xE4, 0x79,
0x1209091B, 0x1D83839E, 0x582C2C74, 0x341A1A2E, 0x361B1B2D, 0xDC6E6EB2, 0xB45A5AEE, 0x5BA0A0FB, 0xE7, 0xC8, 0x37, 0x6D, 0x8D, 0xD5, 0x4E, 0xA9, 0x6C, 0x56, 0xF4, 0xEA, 0x65, 0x7A, 0xAE, 0x08,
0xA45252F6, 0x763B3B4D, 0xB7D6D661, 0x7DB3B3CE, 0x5229297B, 0xDDE3E33E, 0x5E2F2F71, 0x13848497, 0xBA, 0x78, 0x25, 0x2E, 0x1C, 0xA6, 0xB4, 0xC6, 0xE8, 0xDD, 0x74, 0x1F, 0x4B, 0xBD, 0x8B, 0x8A,
0xA65353F5, 0xB9D1D168, 0x00000000, 0xC1EDED2C, 0x40202060, 0xE3FCFC1F, 0x79B1B1C8, 0xB65B5BED, 0x70, 0x3E, 0xB5, 0x66, 0x48, 0x03, 0xF6, 0x0E, 0x61, 0x35, 0x57, 0xB9, 0x86, 0xC1, 0x1D, 0x9E,
0xD46A6ABE, 0x8DCBCB46, 0x67BEBED9, 0x7239394B, 0x944A4ADE, 0x984C4CD4, 0xB05858E8, 0x85CFCF4A, 0xE1, 0xF8, 0x98, 0x11, 0x69, 0xD9, 0x8E, 0x94, 0x9B, 0x1E, 0x87, 0xE9, 0xCE, 0x55, 0x28, 0xDF,
0xBBD0D06B, 0xC5EFEF2A, 0x4FAAAAE5, 0xEDFBFB16, 0x864343C5, 0x9A4D4DD7, 0x66333355, 0x11858594, 0x8C, 0xA1, 0x89, 0x0D, 0xBF, 0xE6, 0x42, 0x68, 0x41, 0x99, 0x2D, 0x0F, 0xB0, 0x54, 0xBB, 0x16,
0x8A4545CF, 0xE9F9F910, 0x04020206, 0xFE7F7F81, 0xA05050F0, 0x783C3C44, 0x259F9FBA, 0x4BA8A8E3, };
0xA25151F3, 0x5DA3A3FE, 0x804040C0, 0x058F8F8A, 0x3F9292AD, 0x219D9DBC, 0x70383848, 0xF1F5F504,
0x63BCBCDF, 0x77B6B6C1, 0xAFDADA75, 0x42212163, 0x20101030, 0xE5FFFF1A, 0xFDF3F30E, 0xBFD2D26D, static CONST_TABLE(u4_t, AES_E1)[256] = {
0x81CDCD4C, 0x180C0C14, 0x26131335, 0xC3ECEC2F, 0xBE5F5FE1, 0x359797A2, 0x884444CC, 0x2E171739, 0xC66363A5, 0xF87C7C84, 0xEE777799, 0xF67B7B8D, 0xFFF2F20D, 0xD66B6BBD, 0xDE6F6FB1, 0x91C5C554,
0x93C4C457, 0x55A7A7F2, 0xFC7E7E82, 0x7A3D3D47, 0xC86464AC, 0xBA5D5DE7, 0x3219192B, 0xE6737395, 0x60303050, 0x02010103, 0xCE6767A9, 0x562B2B7D, 0xE7FEFE19, 0xB5D7D762, 0x4DABABE6, 0xEC76769A,
0xC06060A0, 0x19818198, 0x9E4F4FD1, 0xA3DCDC7F, 0x44222266, 0x542A2A7E, 0x3B9090AB, 0x0B888883, 0x8FCACA45, 0x1F82829D, 0x89C9C940, 0xFA7D7D87, 0xEFFAFA15, 0xB25959EB, 0x8E4747C9, 0xFBF0F00B,
0x8C4646CA, 0xC7EEEE29, 0x6BB8B8D3, 0x2814143C, 0xA7DEDE79, 0xBC5E5EE2, 0x160B0B1D, 0xADDBDB76, 0x41ADADEC, 0xB3D4D467, 0x5FA2A2FD, 0x45AFAFEA, 0x239C9CBF, 0x53A4A4F7, 0xE4727296, 0x9BC0C05B,
0xDBE0E03B, 0x64323256, 0x743A3A4E, 0x140A0A1E, 0x924949DB, 0x0C06060A, 0x4824246C, 0xB85C5CE4, 0x75B7B7C2, 0xE1FDFD1C, 0x3D9393AE, 0x4C26266A, 0x6C36365A, 0x7E3F3F41, 0xF5F7F702, 0x83CCCC4F,
0x9FC2C25D, 0xBDD3D36E, 0x43ACACEF, 0xC46262A6, 0x399191A8, 0x319595A4, 0xD3E4E437, 0xF279798B, 0x6834345C, 0x51A5A5F4, 0xD1E5E534, 0xF9F1F108, 0xE2717193, 0xABD8D873, 0x62313153, 0x2A15153F,
0xD5E7E732, 0x8BC8C843, 0x6E373759, 0xDA6D6DB7, 0x018D8D8C, 0xB1D5D564, 0x9C4E4ED2, 0x49A9A9E0, 0x0804040C, 0x95C7C752, 0x46232365, 0x9DC3C35E, 0x30181828, 0x379696A1, 0x0A05050F, 0x2F9A9AB5,
0xD86C6CB4, 0xAC5656FA, 0xF3F4F407, 0xCFEAEA25, 0xCA6565AF, 0xF47A7A8E, 0x47AEAEE9, 0x10080818, 0x0E070709, 0x24121236, 0x1B80809B, 0xDFE2E23D, 0xCDEBEB26, 0x4E272769, 0x7FB2B2CD, 0xEA75759F,
0x6FBABAD5, 0xF0787888, 0x4A25256F, 0x5C2E2E72, 0x381C1C24, 0x57A6A6F1, 0x73B4B4C7, 0x97C6C651, 0x1209091B, 0x1D83839E, 0x582C2C74, 0x341A1A2E, 0x361B1B2D, 0xDC6E6EB2, 0xB45A5AEE, 0x5BA0A0FB,
0xCBE8E823, 0xA1DDDD7C, 0xE874749C, 0x3E1F1F21, 0x964B4BDD, 0x61BDBDDC, 0x0D8B8B86, 0x0F8A8A85, 0xA45252F6, 0x763B3B4D, 0xB7D6D661, 0x7DB3B3CE, 0x5229297B, 0xDDE3E33E, 0x5E2F2F71, 0x13848497,
0xE0707090, 0x7C3E3E42, 0x71B5B5C4, 0xCC6666AA, 0x904848D8, 0x06030305, 0xF7F6F601, 0x1C0E0E12, 0xA65353F5, 0xB9D1D168, 0x00000000, 0xC1EDED2C, 0x40202060, 0xE3FCFC1F, 0x79B1B1C8, 0xB65B5BED,
0xC26161A3, 0x6A35355F, 0xAE5757F9, 0x69B9B9D0, 0x17868691, 0x99C1C158, 0x3A1D1D27, 0x279E9EB9, 0xD46A6ABE, 0x8DCBCB46, 0x67BEBED9, 0x7239394B, 0x944A4ADE, 0x984C4CD4, 0xB05858E8, 0x85CFCF4A,
0xD9E1E138, 0xEBF8F813, 0x2B9898B3, 0x22111133, 0xD26969BB, 0xA9D9D970, 0x078E8E89, 0x339494A7, 0xBBD0D06B, 0xC5EFEF2A, 0x4FAAAAE5, 0xEDFBFB16, 0x864343C5, 0x9A4D4DD7, 0x66333355, 0x11858594,
0x2D9B9BB6, 0x3C1E1E22, 0x15878792, 0xC9E9E920, 0x87CECE49, 0xAA5555FF, 0x50282878, 0xA5DFDF7A, 0x8A4545CF, 0xE9F9F910, 0x04020206, 0xFE7F7F81, 0xA05050F0, 0x783C3C44, 0x259F9FBA, 0x4BA8A8E3,
0x038C8C8F, 0x59A1A1F8, 0x09898980, 0x1A0D0D17, 0x65BFBFDA, 0xD7E6E631, 0x844242C6, 0xD06868B8, 0xA25151F3, 0x5DA3A3FE, 0x804040C0, 0x058F8F8A, 0x3F9292AD, 0x219D9DBC, 0x70383848, 0xF1F5F504,
0x824141C3, 0x299999B0, 0x5A2D2D77, 0x1E0F0F11, 0x7BB0B0CB, 0xA85454FC, 0x6DBBBBD6, 0x2C16163A, 0x63BCBCDF, 0x77B6B6C1, 0xAFDADA75, 0x42212163, 0x20101030, 0xE5FFFF1A, 0xFDF3F30E, 0xBFD2D26D,
}; 0x81CDCD4C, 0x180C0C14, 0x26131335, 0xC3ECEC2F, 0xBE5F5FE1, 0x359797A2, 0x884444CC, 0x2E171739,
0x93C4C457, 0x55A7A7F2, 0xFC7E7E82, 0x7A3D3D47, 0xC86464AC, 0xBA5D5DE7, 0x3219192B, 0xE6737395,
static CONST_TABLE(u4_t, AES_E2)[256] = { 0xC06060A0, 0x19818198, 0x9E4F4FD1, 0xA3DCDC7F, 0x44222266, 0x542A2A7E, 0x3B9090AB, 0x0B888883,
0xA5C66363, 0x84F87C7C, 0x99EE7777, 0x8DF67B7B, 0x0DFFF2F2, 0xBDD66B6B, 0xB1DE6F6F, 0x5491C5C5, 0x8C4646CA, 0xC7EEEE29, 0x6BB8B8D3, 0x2814143C, 0xA7DEDE79, 0xBC5E5EE2, 0x160B0B1D, 0xADDBDB76,
0x50603030, 0x03020101, 0xA9CE6767, 0x7D562B2B, 0x19E7FEFE, 0x62B5D7D7, 0xE64DABAB, 0x9AEC7676, 0xDBE0E03B, 0x64323256, 0x743A3A4E, 0x140A0A1E, 0x924949DB, 0x0C06060A, 0x4824246C, 0xB85C5CE4,
0x458FCACA, 0x9D1F8282, 0x4089C9C9, 0x87FA7D7D, 0x15EFFAFA, 0xEBB25959, 0xC98E4747, 0x0BFBF0F0, 0x9FC2C25D, 0xBDD3D36E, 0x43ACACEF, 0xC46262A6, 0x399191A8, 0x319595A4, 0xD3E4E437, 0xF279798B,
0xEC41ADAD, 0x67B3D4D4, 0xFD5FA2A2, 0xEA45AFAF, 0xBF239C9C, 0xF753A4A4, 0x96E47272, 0x5B9BC0C0, 0xD5E7E732, 0x8BC8C843, 0x6E373759, 0xDA6D6DB7, 0x018D8D8C, 0xB1D5D564, 0x9C4E4ED2, 0x49A9A9E0,
0xC275B7B7, 0x1CE1FDFD, 0xAE3D9393, 0x6A4C2626, 0x5A6C3636, 0x417E3F3F, 0x02F5F7F7, 0x4F83CCCC, 0xD86C6CB4, 0xAC5656FA, 0xF3F4F407, 0xCFEAEA25, 0xCA6565AF, 0xF47A7A8E, 0x47AEAEE9, 0x10080818,
0x5C683434, 0xF451A5A5, 0x34D1E5E5, 0x08F9F1F1, 0x93E27171, 0x73ABD8D8, 0x53623131, 0x3F2A1515, 0x6FBABAD5, 0xF0787888, 0x4A25256F, 0x5C2E2E72, 0x381C1C24, 0x57A6A6F1, 0x73B4B4C7, 0x97C6C651,
0x0C080404, 0x5295C7C7, 0x65462323, 0x5E9DC3C3, 0x28301818, 0xA1379696, 0x0F0A0505, 0xB52F9A9A, 0xCBE8E823, 0xA1DDDD7C, 0xE874749C, 0x3E1F1F21, 0x964B4BDD, 0x61BDBDDC, 0x0D8B8B86, 0x0F8A8A85,
0x090E0707, 0x36241212, 0x9B1B8080, 0x3DDFE2E2, 0x26CDEBEB, 0x694E2727, 0xCD7FB2B2, 0x9FEA7575, 0xE0707090, 0x7C3E3E42, 0x71B5B5C4, 0xCC6666AA, 0x904848D8, 0x06030305, 0xF7F6F601, 0x1C0E0E12,
0x1B120909, 0x9E1D8383, 0x74582C2C, 0x2E341A1A, 0x2D361B1B, 0xB2DC6E6E, 0xEEB45A5A, 0xFB5BA0A0, 0xC26161A3, 0x6A35355F, 0xAE5757F9, 0x69B9B9D0, 0x17868691, 0x99C1C158, 0x3A1D1D27, 0x279E9EB9,
0xF6A45252, 0x4D763B3B, 0x61B7D6D6, 0xCE7DB3B3, 0x7B522929, 0x3EDDE3E3, 0x715E2F2F, 0x97138484, 0xD9E1E138, 0xEBF8F813, 0x2B9898B3, 0x22111133, 0xD26969BB, 0xA9D9D970, 0x078E8E89, 0x339494A7,
0xF5A65353, 0x68B9D1D1, 0x00000000, 0x2CC1EDED, 0x60402020, 0x1FE3FCFC, 0xC879B1B1, 0xEDB65B5B, 0x2D9B9BB6, 0x3C1E1E22, 0x15878792, 0xC9E9E920, 0x87CECE49, 0xAA5555FF, 0x50282878, 0xA5DFDF7A,
0xBED46A6A, 0x468DCBCB, 0xD967BEBE, 0x4B723939, 0xDE944A4A, 0xD4984C4C, 0xE8B05858, 0x4A85CFCF, 0x038C8C8F, 0x59A1A1F8, 0x09898980, 0x1A0D0D17, 0x65BFBFDA, 0xD7E6E631, 0x844242C6, 0xD06868B8,
0x6BBBD0D0, 0x2AC5EFEF, 0xE54FAAAA, 0x16EDFBFB, 0xC5864343, 0xD79A4D4D, 0x55663333, 0x94118585, 0x824141C3, 0x299999B0, 0x5A2D2D77, 0x1E0F0F11, 0x7BB0B0CB, 0xA85454FC, 0x6DBBBBD6, 0x2C16163A,
0xCF8A4545, 0x10E9F9F9, 0x06040202, 0x81FE7F7F, 0xF0A05050, 0x44783C3C, 0xBA259F9F, 0xE34BA8A8, };
0xF3A25151, 0xFE5DA3A3, 0xC0804040, 0x8A058F8F, 0xAD3F9292, 0xBC219D9D, 0x48703838, 0x04F1F5F5,
0xDF63BCBC, 0xC177B6B6, 0x75AFDADA, 0x63422121, 0x30201010, 0x1AE5FFFF, 0x0EFDF3F3, 0x6DBFD2D2, static CONST_TABLE(u4_t, AES_E2)[256] = {
0x4C81CDCD, 0x14180C0C, 0x35261313, 0x2FC3ECEC, 0xE1BE5F5F, 0xA2359797, 0xCC884444, 0x392E1717, 0xA5C66363, 0x84F87C7C, 0x99EE7777, 0x8DF67B7B, 0x0DFFF2F2, 0xBDD66B6B, 0xB1DE6F6F, 0x5491C5C5,
0x5793C4C4, 0xF255A7A7, 0x82FC7E7E, 0x477A3D3D, 0xACC86464, 0xE7BA5D5D, 0x2B321919, 0x95E67373, 0x50603030, 0x03020101, 0xA9CE6767, 0x7D562B2B, 0x19E7FEFE, 0x62B5D7D7, 0xE64DABAB, 0x9AEC7676,
0xA0C06060, 0x98198181, 0xD19E4F4F, 0x7FA3DCDC, 0x66442222, 0x7E542A2A, 0xAB3B9090, 0x830B8888, 0x458FCACA, 0x9D1F8282, 0x4089C9C9, 0x87FA7D7D, 0x15EFFAFA, 0xEBB25959, 0xC98E4747, 0x0BFBF0F0,
0xCA8C4646, 0x29C7EEEE, 0xD36BB8B8, 0x3C281414, 0x79A7DEDE, 0xE2BC5E5E, 0x1D160B0B, 0x76ADDBDB, 0xEC41ADAD, 0x67B3D4D4, 0xFD5FA2A2, 0xEA45AFAF, 0xBF239C9C, 0xF753A4A4, 0x96E47272, 0x5B9BC0C0,
0x3BDBE0E0, 0x56643232, 0x4E743A3A, 0x1E140A0A, 0xDB924949, 0x0A0C0606, 0x6C482424, 0xE4B85C5C, 0xC275B7B7, 0x1CE1FDFD, 0xAE3D9393, 0x6A4C2626, 0x5A6C3636, 0x417E3F3F, 0x02F5F7F7, 0x4F83CCCC,
0x5D9FC2C2, 0x6EBDD3D3, 0xEF43ACAC, 0xA6C46262, 0xA8399191, 0xA4319595, 0x37D3E4E4, 0x8BF27979, 0x5C683434, 0xF451A5A5, 0x34D1E5E5, 0x08F9F1F1, 0x93E27171, 0x73ABD8D8, 0x53623131, 0x3F2A1515,
0x32D5E7E7, 0x438BC8C8, 0x596E3737, 0xB7DA6D6D, 0x8C018D8D, 0x64B1D5D5, 0xD29C4E4E, 0xE049A9A9, 0x0C080404, 0x5295C7C7, 0x65462323, 0x5E9DC3C3, 0x28301818, 0xA1379696, 0x0F0A0505, 0xB52F9A9A,
0xB4D86C6C, 0xFAAC5656, 0x07F3F4F4, 0x25CFEAEA, 0xAFCA6565, 0x8EF47A7A, 0xE947AEAE, 0x18100808, 0x090E0707, 0x36241212, 0x9B1B8080, 0x3DDFE2E2, 0x26CDEBEB, 0x694E2727, 0xCD7FB2B2, 0x9FEA7575,
0xD56FBABA, 0x88F07878, 0x6F4A2525, 0x725C2E2E, 0x24381C1C, 0xF157A6A6, 0xC773B4B4, 0x5197C6C6, 0x1B120909, 0x9E1D8383, 0x74582C2C, 0x2E341A1A, 0x2D361B1B, 0xB2DC6E6E, 0xEEB45A5A, 0xFB5BA0A0,
0x23CBE8E8, 0x7CA1DDDD, 0x9CE87474, 0x213E1F1F, 0xDD964B4B, 0xDC61BDBD, 0x860D8B8B, 0x850F8A8A, 0xF6A45252, 0x4D763B3B, 0x61B7D6D6, 0xCE7DB3B3, 0x7B522929, 0x3EDDE3E3, 0x715E2F2F, 0x97138484,
0x90E07070, 0x427C3E3E, 0xC471B5B5, 0xAACC6666, 0xD8904848, 0x05060303, 0x01F7F6F6, 0x121C0E0E, 0xF5A65353, 0x68B9D1D1, 0x00000000, 0x2CC1EDED, 0x60402020, 0x1FE3FCFC, 0xC879B1B1, 0xEDB65B5B,
0xA3C26161, 0x5F6A3535, 0xF9AE5757, 0xD069B9B9, 0x91178686, 0x5899C1C1, 0x273A1D1D, 0xB9279E9E, 0xBED46A6A, 0x468DCBCB, 0xD967BEBE, 0x4B723939, 0xDE944A4A, 0xD4984C4C, 0xE8B05858, 0x4A85CFCF,
0x38D9E1E1, 0x13EBF8F8, 0xB32B9898, 0x33221111, 0xBBD26969, 0x70A9D9D9, 0x89078E8E, 0xA7339494, 0x6BBBD0D0, 0x2AC5EFEF, 0xE54FAAAA, 0x16EDFBFB, 0xC5864343, 0xD79A4D4D, 0x55663333, 0x94118585,
0xB62D9B9B, 0x223C1E1E, 0x92158787, 0x20C9E9E9, 0x4987CECE, 0xFFAA5555, 0x78502828, 0x7AA5DFDF, 0xCF8A4545, 0x10E9F9F9, 0x06040202, 0x81FE7F7F, 0xF0A05050, 0x44783C3C, 0xBA259F9F, 0xE34BA8A8,
0x8F038C8C, 0xF859A1A1, 0x80098989, 0x171A0D0D, 0xDA65BFBF, 0x31D7E6E6, 0xC6844242, 0xB8D06868, 0xF3A25151, 0xFE5DA3A3, 0xC0804040, 0x8A058F8F, 0xAD3F9292, 0xBC219D9D, 0x48703838, 0x04F1F5F5,
0xC3824141, 0xB0299999, 0x775A2D2D, 0x111E0F0F, 0xCB7BB0B0, 0xFCA85454, 0xD66DBBBB, 0x3A2C1616, 0xDF63BCBC, 0xC177B6B6, 0x75AFDADA, 0x63422121, 0x30201010, 0x1AE5FFFF, 0x0EFDF3F3, 0x6DBFD2D2,
}; 0x4C81CDCD, 0x14180C0C, 0x35261313, 0x2FC3ECEC, 0xE1BE5F5F, 0xA2359797, 0xCC884444, 0x392E1717,
0x5793C4C4, 0xF255A7A7, 0x82FC7E7E, 0x477A3D3D, 0xACC86464, 0xE7BA5D5D, 0x2B321919, 0x95E67373,
static CONST_TABLE(u4_t, AES_E3)[256] = { 0xA0C06060, 0x98198181, 0xD19E4F4F, 0x7FA3DCDC, 0x66442222, 0x7E542A2A, 0xAB3B9090, 0x830B8888,
0x63A5C663, 0x7C84F87C, 0x7799EE77, 0x7B8DF67B, 0xF20DFFF2, 0x6BBDD66B, 0x6FB1DE6F, 0xC55491C5, 0xCA8C4646, 0x29C7EEEE, 0xD36BB8B8, 0x3C281414, 0x79A7DEDE, 0xE2BC5E5E, 0x1D160B0B, 0x76ADDBDB,
0x30506030, 0x01030201, 0x67A9CE67, 0x2B7D562B, 0xFE19E7FE, 0xD762B5D7, 0xABE64DAB, 0x769AEC76, 0x3BDBE0E0, 0x56643232, 0x4E743A3A, 0x1E140A0A, 0xDB924949, 0x0A0C0606, 0x6C482424, 0xE4B85C5C,
0xCA458FCA, 0x829D1F82, 0xC94089C9, 0x7D87FA7D, 0xFA15EFFA, 0x59EBB259, 0x47C98E47, 0xF00BFBF0, 0x5D9FC2C2, 0x6EBDD3D3, 0xEF43ACAC, 0xA6C46262, 0xA8399191, 0xA4319595, 0x37D3E4E4, 0x8BF27979,
0xADEC41AD, 0xD467B3D4, 0xA2FD5FA2, 0xAFEA45AF, 0x9CBF239C, 0xA4F753A4, 0x7296E472, 0xC05B9BC0, 0x32D5E7E7, 0x438BC8C8, 0x596E3737, 0xB7DA6D6D, 0x8C018D8D, 0x64B1D5D5, 0xD29C4E4E, 0xE049A9A9,
0xB7C275B7, 0xFD1CE1FD, 0x93AE3D93, 0x266A4C26, 0x365A6C36, 0x3F417E3F, 0xF702F5F7, 0xCC4F83CC, 0xB4D86C6C, 0xFAAC5656, 0x07F3F4F4, 0x25CFEAEA, 0xAFCA6565, 0x8EF47A7A, 0xE947AEAE, 0x18100808,
0x345C6834, 0xA5F451A5, 0xE534D1E5, 0xF108F9F1, 0x7193E271, 0xD873ABD8, 0x31536231, 0x153F2A15, 0xD56FBABA, 0x88F07878, 0x6F4A2525, 0x725C2E2E, 0x24381C1C, 0xF157A6A6, 0xC773B4B4, 0x5197C6C6,
0x040C0804, 0xC75295C7, 0x23654623, 0xC35E9DC3, 0x18283018, 0x96A13796, 0x050F0A05, 0x9AB52F9A, 0x23CBE8E8, 0x7CA1DDDD, 0x9CE87474, 0x213E1F1F, 0xDD964B4B, 0xDC61BDBD, 0x860D8B8B, 0x850F8A8A,
0x07090E07, 0x12362412, 0x809B1B80, 0xE23DDFE2, 0xEB26CDEB, 0x27694E27, 0xB2CD7FB2, 0x759FEA75, 0x90E07070, 0x427C3E3E, 0xC471B5B5, 0xAACC6666, 0xD8904848, 0x05060303, 0x01F7F6F6, 0x121C0E0E,
0x091B1209, 0x839E1D83, 0x2C74582C, 0x1A2E341A, 0x1B2D361B, 0x6EB2DC6E, 0x5AEEB45A, 0xA0FB5BA0, 0xA3C26161, 0x5F6A3535, 0xF9AE5757, 0xD069B9B9, 0x91178686, 0x5899C1C1, 0x273A1D1D, 0xB9279E9E,
0x52F6A452, 0x3B4D763B, 0xD661B7D6, 0xB3CE7DB3, 0x297B5229, 0xE33EDDE3, 0x2F715E2F, 0x84971384, 0x38D9E1E1, 0x13EBF8F8, 0xB32B9898, 0x33221111, 0xBBD26969, 0x70A9D9D9, 0x89078E8E, 0xA7339494,
0x53F5A653, 0xD168B9D1, 0x00000000, 0xED2CC1ED, 0x20604020, 0xFC1FE3FC, 0xB1C879B1, 0x5BEDB65B, 0xB62D9B9B, 0x223C1E1E, 0x92158787, 0x20C9E9E9, 0x4987CECE, 0xFFAA5555, 0x78502828, 0x7AA5DFDF,
0x6ABED46A, 0xCB468DCB, 0xBED967BE, 0x394B7239, 0x4ADE944A, 0x4CD4984C, 0x58E8B058, 0xCF4A85CF, 0x8F038C8C, 0xF859A1A1, 0x80098989, 0x171A0D0D, 0xDA65BFBF, 0x31D7E6E6, 0xC6844242, 0xB8D06868,
0xD06BBBD0, 0xEF2AC5EF, 0xAAE54FAA, 0xFB16EDFB, 0x43C58643, 0x4DD79A4D, 0x33556633, 0x85941185, 0xC3824141, 0xB0299999, 0x775A2D2D, 0x111E0F0F, 0xCB7BB0B0, 0xFCA85454, 0xD66DBBBB, 0x3A2C1616,
0x45CF8A45, 0xF910E9F9, 0x02060402, 0x7F81FE7F, 0x50F0A050, 0x3C44783C, 0x9FBA259F, 0xA8E34BA8, };
0x51F3A251, 0xA3FE5DA3, 0x40C08040, 0x8F8A058F, 0x92AD3F92, 0x9DBC219D, 0x38487038, 0xF504F1F5,
0xBCDF63BC, 0xB6C177B6, 0xDA75AFDA, 0x21634221, 0x10302010, 0xFF1AE5FF, 0xF30EFDF3, 0xD26DBFD2, static CONST_TABLE(u4_t, AES_E3)[256] = {
0xCD4C81CD, 0x0C14180C, 0x13352613, 0xEC2FC3EC, 0x5FE1BE5F, 0x97A23597, 0x44CC8844, 0x17392E17, 0x63A5C663, 0x7C84F87C, 0x7799EE77, 0x7B8DF67B, 0xF20DFFF2, 0x6BBDD66B, 0x6FB1DE6F, 0xC55491C5,
0xC45793C4, 0xA7F255A7, 0x7E82FC7E, 0x3D477A3D, 0x64ACC864, 0x5DE7BA5D, 0x192B3219, 0x7395E673, 0x30506030, 0x01030201, 0x67A9CE67, 0x2B7D562B, 0xFE19E7FE, 0xD762B5D7, 0xABE64DAB, 0x769AEC76,
0x60A0C060, 0x81981981, 0x4FD19E4F, 0xDC7FA3DC, 0x22664422, 0x2A7E542A, 0x90AB3B90, 0x88830B88, 0xCA458FCA, 0x829D1F82, 0xC94089C9, 0x7D87FA7D, 0xFA15EFFA, 0x59EBB259, 0x47C98E47, 0xF00BFBF0,
0x46CA8C46, 0xEE29C7EE, 0xB8D36BB8, 0x143C2814, 0xDE79A7DE, 0x5EE2BC5E, 0x0B1D160B, 0xDB76ADDB, 0xADEC41AD, 0xD467B3D4, 0xA2FD5FA2, 0xAFEA45AF, 0x9CBF239C, 0xA4F753A4, 0x7296E472, 0xC05B9BC0,
0xE03BDBE0, 0x32566432, 0x3A4E743A, 0x0A1E140A, 0x49DB9249, 0x060A0C06, 0x246C4824, 0x5CE4B85C, 0xB7C275B7, 0xFD1CE1FD, 0x93AE3D93, 0x266A4C26, 0x365A6C36, 0x3F417E3F, 0xF702F5F7, 0xCC4F83CC,
0xC25D9FC2, 0xD36EBDD3, 0xACEF43AC, 0x62A6C462, 0x91A83991, 0x95A43195, 0xE437D3E4, 0x798BF279, 0x345C6834, 0xA5F451A5, 0xE534D1E5, 0xF108F9F1, 0x7193E271, 0xD873ABD8, 0x31536231, 0x153F2A15,
0xE732D5E7, 0xC8438BC8, 0x37596E37, 0x6DB7DA6D, 0x8D8C018D, 0xD564B1D5, 0x4ED29C4E, 0xA9E049A9, 0x040C0804, 0xC75295C7, 0x23654623, 0xC35E9DC3, 0x18283018, 0x96A13796, 0x050F0A05, 0x9AB52F9A,
0x6CB4D86C, 0x56FAAC56, 0xF407F3F4, 0xEA25CFEA, 0x65AFCA65, 0x7A8EF47A, 0xAEE947AE, 0x08181008, 0x07090E07, 0x12362412, 0x809B1B80, 0xE23DDFE2, 0xEB26CDEB, 0x27694E27, 0xB2CD7FB2, 0x759FEA75,
0xBAD56FBA, 0x7888F078, 0x256F4A25, 0x2E725C2E, 0x1C24381C, 0xA6F157A6, 0xB4C773B4, 0xC65197C6, 0x091B1209, 0x839E1D83, 0x2C74582C, 0x1A2E341A, 0x1B2D361B, 0x6EB2DC6E, 0x5AEEB45A, 0xA0FB5BA0,
0xE823CBE8, 0xDD7CA1DD, 0x749CE874, 0x1F213E1F, 0x4BDD964B, 0xBDDC61BD, 0x8B860D8B, 0x8A850F8A, 0x52F6A452, 0x3B4D763B, 0xD661B7D6, 0xB3CE7DB3, 0x297B5229, 0xE33EDDE3, 0x2F715E2F, 0x84971384,
0x7090E070, 0x3E427C3E, 0xB5C471B5, 0x66AACC66, 0x48D89048, 0x03050603, 0xF601F7F6, 0x0E121C0E, 0x53F5A653, 0xD168B9D1, 0x00000000, 0xED2CC1ED, 0x20604020, 0xFC1FE3FC, 0xB1C879B1, 0x5BEDB65B,
0x61A3C261, 0x355F6A35, 0x57F9AE57, 0xB9D069B9, 0x86911786, 0xC15899C1, 0x1D273A1D, 0x9EB9279E, 0x6ABED46A, 0xCB468DCB, 0xBED967BE, 0x394B7239, 0x4ADE944A, 0x4CD4984C, 0x58E8B058, 0xCF4A85CF,
0xE138D9E1, 0xF813EBF8, 0x98B32B98, 0x11332211, 0x69BBD269, 0xD970A9D9, 0x8E89078E, 0x94A73394, 0xD06BBBD0, 0xEF2AC5EF, 0xAAE54FAA, 0xFB16EDFB, 0x43C58643, 0x4DD79A4D, 0x33556633, 0x85941185,
0x9BB62D9B, 0x1E223C1E, 0x87921587, 0xE920C9E9, 0xCE4987CE, 0x55FFAA55, 0x28785028, 0xDF7AA5DF, 0x45CF8A45, 0xF910E9F9, 0x02060402, 0x7F81FE7F, 0x50F0A050, 0x3C44783C, 0x9FBA259F, 0xA8E34BA8,
0x8C8F038C, 0xA1F859A1, 0x89800989, 0x0D171A0D, 0xBFDA65BF, 0xE631D7E6, 0x42C68442, 0x68B8D068, 0x51F3A251, 0xA3FE5DA3, 0x40C08040, 0x8F8A058F, 0x92AD3F92, 0x9DBC219D, 0x38487038, 0xF504F1F5,
0x41C38241, 0x99B02999, 0x2D775A2D, 0x0F111E0F, 0xB0CB7BB0, 0x54FCA854, 0xBBD66DBB, 0x163A2C16, 0xBCDF63BC, 0xB6C177B6, 0xDA75AFDA, 0x21634221, 0x10302010, 0xFF1AE5FF, 0xF30EFDF3, 0xD26DBFD2,
}; 0xCD4C81CD, 0x0C14180C, 0x13352613, 0xEC2FC3EC, 0x5FE1BE5F, 0x97A23597, 0x44CC8844, 0x17392E17,
0xC45793C4, 0xA7F255A7, 0x7E82FC7E, 0x3D477A3D, 0x64ACC864, 0x5DE7BA5D, 0x192B3219, 0x7395E673,
static CONST_TABLE(u4_t, AES_E4)[256] = { 0x60A0C060, 0x81981981, 0x4FD19E4F, 0xDC7FA3DC, 0x22664422, 0x2A7E542A, 0x90AB3B90, 0x88830B88,
0x6363A5C6, 0x7C7C84F8, 0x777799EE, 0x7B7B8DF6, 0xF2F20DFF, 0x6B6BBDD6, 0x6F6FB1DE, 0xC5C55491, 0x46CA8C46, 0xEE29C7EE, 0xB8D36BB8, 0x143C2814, 0xDE79A7DE, 0x5EE2BC5E, 0x0B1D160B, 0xDB76ADDB,
0x30305060, 0x01010302, 0x6767A9CE, 0x2B2B7D56, 0xFEFE19E7, 0xD7D762B5, 0xABABE64D, 0x76769AEC, 0xE03BDBE0, 0x32566432, 0x3A4E743A, 0x0A1E140A, 0x49DB9249, 0x060A0C06, 0x246C4824, 0x5CE4B85C,
0xCACA458F, 0x82829D1F, 0xC9C94089, 0x7D7D87FA, 0xFAFA15EF, 0x5959EBB2, 0x4747C98E, 0xF0F00BFB, 0xC25D9FC2, 0xD36EBDD3, 0xACEF43AC, 0x62A6C462, 0x91A83991, 0x95A43195, 0xE437D3E4, 0x798BF279,
0xADADEC41, 0xD4D467B3, 0xA2A2FD5F, 0xAFAFEA45, 0x9C9CBF23, 0xA4A4F753, 0x727296E4, 0xC0C05B9B, 0xE732D5E7, 0xC8438BC8, 0x37596E37, 0x6DB7DA6D, 0x8D8C018D, 0xD564B1D5, 0x4ED29C4E, 0xA9E049A9,
0xB7B7C275, 0xFDFD1CE1, 0x9393AE3D, 0x26266A4C, 0x36365A6C, 0x3F3F417E, 0xF7F702F5, 0xCCCC4F83, 0x6CB4D86C, 0x56FAAC56, 0xF407F3F4, 0xEA25CFEA, 0x65AFCA65, 0x7A8EF47A, 0xAEE947AE, 0x08181008,
0x34345C68, 0xA5A5F451, 0xE5E534D1, 0xF1F108F9, 0x717193E2, 0xD8D873AB, 0x31315362, 0x15153F2A, 0xBAD56FBA, 0x7888F078, 0x256F4A25, 0x2E725C2E, 0x1C24381C, 0xA6F157A6, 0xB4C773B4, 0xC65197C6,
0x04040C08, 0xC7C75295, 0x23236546, 0xC3C35E9D, 0x18182830, 0x9696A137, 0x05050F0A, 0x9A9AB52F, 0xE823CBE8, 0xDD7CA1DD, 0x749CE874, 0x1F213E1F, 0x4BDD964B, 0xBDDC61BD, 0x8B860D8B, 0x8A850F8A,
0x0707090E, 0x12123624, 0x80809B1B, 0xE2E23DDF, 0xEBEB26CD, 0x2727694E, 0xB2B2CD7F, 0x75759FEA, 0x7090E070, 0x3E427C3E, 0xB5C471B5, 0x66AACC66, 0x48D89048, 0x03050603, 0xF601F7F6, 0x0E121C0E,
0x09091B12, 0x83839E1D, 0x2C2C7458, 0x1A1A2E34, 0x1B1B2D36, 0x6E6EB2DC, 0x5A5AEEB4, 0xA0A0FB5B, 0x61A3C261, 0x355F6A35, 0x57F9AE57, 0xB9D069B9, 0x86911786, 0xC15899C1, 0x1D273A1D, 0x9EB9279E,
0x5252F6A4, 0x3B3B4D76, 0xD6D661B7, 0xB3B3CE7D, 0x29297B52, 0xE3E33EDD, 0x2F2F715E, 0x84849713, 0xE138D9E1, 0xF813EBF8, 0x98B32B98, 0x11332211, 0x69BBD269, 0xD970A9D9, 0x8E89078E, 0x94A73394,
0x5353F5A6, 0xD1D168B9, 0x00000000, 0xEDED2CC1, 0x20206040, 0xFCFC1FE3, 0xB1B1C879, 0x5B5BEDB6, 0x9BB62D9B, 0x1E223C1E, 0x87921587, 0xE920C9E9, 0xCE4987CE, 0x55FFAA55, 0x28785028, 0xDF7AA5DF,
0x6A6ABED4, 0xCBCB468D, 0xBEBED967, 0x39394B72, 0x4A4ADE94, 0x4C4CD498, 0x5858E8B0, 0xCFCF4A85, 0x8C8F038C, 0xA1F859A1, 0x89800989, 0x0D171A0D, 0xBFDA65BF, 0xE631D7E6, 0x42C68442, 0x68B8D068,
0xD0D06BBB, 0xEFEF2AC5, 0xAAAAE54F, 0xFBFB16ED, 0x4343C586, 0x4D4DD79A, 0x33335566, 0x85859411, 0x41C38241, 0x99B02999, 0x2D775A2D, 0x0F111E0F, 0xB0CB7BB0, 0x54FCA854, 0xBBD66DBB, 0x163A2C16,
0x4545CF8A, 0xF9F910E9, 0x02020604, 0x7F7F81FE, 0x5050F0A0, 0x3C3C4478, 0x9F9FBA25, 0xA8A8E34B, };
0x5151F3A2, 0xA3A3FE5D, 0x4040C080, 0x8F8F8A05, 0x9292AD3F, 0x9D9DBC21, 0x38384870, 0xF5F504F1,
0xBCBCDF63, 0xB6B6C177, 0xDADA75AF, 0x21216342, 0x10103020, 0xFFFF1AE5, 0xF3F30EFD, 0xD2D26DBF, static CONST_TABLE(u4_t, AES_E4)[256] = {
0xCDCD4C81, 0x0C0C1418, 0x13133526, 0xECEC2FC3, 0x5F5FE1BE, 0x9797A235, 0x4444CC88, 0x1717392E, 0x6363A5C6, 0x7C7C84F8, 0x777799EE, 0x7B7B8DF6, 0xF2F20DFF, 0x6B6BBDD6, 0x6F6FB1DE, 0xC5C55491,
0xC4C45793, 0xA7A7F255, 0x7E7E82FC, 0x3D3D477A, 0x6464ACC8, 0x5D5DE7BA, 0x19192B32, 0x737395E6, 0x30305060, 0x01010302, 0x6767A9CE, 0x2B2B7D56, 0xFEFE19E7, 0xD7D762B5, 0xABABE64D, 0x76769AEC,
0x6060A0C0, 0x81819819, 0x4F4FD19E, 0xDCDC7FA3, 0x22226644, 0x2A2A7E54, 0x9090AB3B, 0x8888830B, 0xCACA458F, 0x82829D1F, 0xC9C94089, 0x7D7D87FA, 0xFAFA15EF, 0x5959EBB2, 0x4747C98E, 0xF0F00BFB,
0x4646CA8C, 0xEEEE29C7, 0xB8B8D36B, 0x14143C28, 0xDEDE79A7, 0x5E5EE2BC, 0x0B0B1D16, 0xDBDB76AD, 0xADADEC41, 0xD4D467B3, 0xA2A2FD5F, 0xAFAFEA45, 0x9C9CBF23, 0xA4A4F753, 0x727296E4, 0xC0C05B9B,
0xE0E03BDB, 0x32325664, 0x3A3A4E74, 0x0A0A1E14, 0x4949DB92, 0x06060A0C, 0x24246C48, 0x5C5CE4B8, 0xB7B7C275, 0xFDFD1CE1, 0x9393AE3D, 0x26266A4C, 0x36365A6C, 0x3F3F417E, 0xF7F702F5, 0xCCCC4F83,
0xC2C25D9F, 0xD3D36EBD, 0xACACEF43, 0x6262A6C4, 0x9191A839, 0x9595A431, 0xE4E437D3, 0x79798BF2, 0x34345C68, 0xA5A5F451, 0xE5E534D1, 0xF1F108F9, 0x717193E2, 0xD8D873AB, 0x31315362, 0x15153F2A,
0xE7E732D5, 0xC8C8438B, 0x3737596E, 0x6D6DB7DA, 0x8D8D8C01, 0xD5D564B1, 0x4E4ED29C, 0xA9A9E049, 0x04040C08, 0xC7C75295, 0x23236546, 0xC3C35E9D, 0x18182830, 0x9696A137, 0x05050F0A, 0x9A9AB52F,
0x6C6CB4D8, 0x5656FAAC, 0xF4F407F3, 0xEAEA25CF, 0x6565AFCA, 0x7A7A8EF4, 0xAEAEE947, 0x08081810, 0x0707090E, 0x12123624, 0x80809B1B, 0xE2E23DDF, 0xEBEB26CD, 0x2727694E, 0xB2B2CD7F, 0x75759FEA,
0xBABAD56F, 0x787888F0, 0x25256F4A, 0x2E2E725C, 0x1C1C2438, 0xA6A6F157, 0xB4B4C773, 0xC6C65197, 0x09091B12, 0x83839E1D, 0x2C2C7458, 0x1A1A2E34, 0x1B1B2D36, 0x6E6EB2DC, 0x5A5AEEB4, 0xA0A0FB5B,
0xE8E823CB, 0xDDDD7CA1, 0x74749CE8, 0x1F1F213E, 0x4B4BDD96, 0xBDBDDC61, 0x8B8B860D, 0x8A8A850F, 0x5252F6A4, 0x3B3B4D76, 0xD6D661B7, 0xB3B3CE7D, 0x29297B52, 0xE3E33EDD, 0x2F2F715E, 0x84849713,
0x707090E0, 0x3E3E427C, 0xB5B5C471, 0x6666AACC, 0x4848D890, 0x03030506, 0xF6F601F7, 0x0E0E121C, 0x5353F5A6, 0xD1D168B9, 0x00000000, 0xEDED2CC1, 0x20206040, 0xFCFC1FE3, 0xB1B1C879, 0x5B5BEDB6,
0x6161A3C2, 0x35355F6A, 0x5757F9AE, 0xB9B9D069, 0x86869117, 0xC1C15899, 0x1D1D273A, 0x9E9EB927, 0x6A6ABED4, 0xCBCB468D, 0xBEBED967, 0x39394B72, 0x4A4ADE94, 0x4C4CD498, 0x5858E8B0, 0xCFCF4A85,
0xE1E138D9, 0xF8F813EB, 0x9898B32B, 0x11113322, 0x6969BBD2, 0xD9D970A9, 0x8E8E8907, 0x9494A733, 0xD0D06BBB, 0xEFEF2AC5, 0xAAAAE54F, 0xFBFB16ED, 0x4343C586, 0x4D4DD79A, 0x33335566, 0x85859411,
0x9B9BB62D, 0x1E1E223C, 0x87879215, 0xE9E920C9, 0xCECE4987, 0x5555FFAA, 0x28287850, 0xDFDF7AA5, 0x4545CF8A, 0xF9F910E9, 0x02020604, 0x7F7F81FE, 0x5050F0A0, 0x3C3C4478, 0x9F9FBA25, 0xA8A8E34B,
0x8C8C8F03, 0xA1A1F859, 0x89898009, 0x0D0D171A, 0xBFBFDA65, 0xE6E631D7, 0x4242C684, 0x6868B8D0, 0x5151F3A2, 0xA3A3FE5D, 0x4040C080, 0x8F8F8A05, 0x9292AD3F, 0x9D9DBC21, 0x38384870, 0xF5F504F1,
0x4141C382, 0x9999B029, 0x2D2D775A, 0x0F0F111E, 0xB0B0CB7B, 0x5454FCA8, 0xBBBBD66D, 0x16163A2C, 0xBCBCDF63, 0xB6B6C177, 0xDADA75AF, 0x21216342, 0x10103020, 0xFFFF1AE5, 0xF3F30EFD, 0xD2D26DBF,
}; 0xCDCD4C81, 0x0C0C1418, 0x13133526, 0xECEC2FC3, 0x5F5FE1BE, 0x9797A235, 0x4444CC88, 0x1717392E,
0xC4C45793, 0xA7A7F255, 0x7E7E82FC, 0x3D3D477A, 0x6464ACC8, 0x5D5DE7BA, 0x19192B32, 0x737395E6,
#define msbf4_read(p) ((p)[0]<<24 | (p)[1]<<16 | (p)[2]<<8 | (p)[3]) 0x6060A0C0, 0x81819819, 0x4F4FD19E, 0xDCDC7FA3, 0x22226644, 0x2A2A7E54, 0x9090AB3B, 0x8888830B,
#define msbf4_write(p,v) (p)[0]=(v)>>24,(p)[1]=(v)>>16,(p)[2]=(v)>>8,(p)[3]=(v) 0x4646CA8C, 0xEEEE29C7, 0xB8B8D36B, 0x14143C28, 0xDEDE79A7, 0x5E5EE2BC, 0x0B0B1D16, 0xDBDB76AD,
#define swapmsbf(x) ( (x&0xFF)<<24 | (x&0xFF00)<<8 | (x&0xFF0000)>>8 | (x>>24) ) 0xE0E03BDB, 0x32325664, 0x3A3A4E74, 0x0A0A1E14, 0x4949DB92, 0x06060A0C, 0x24246C48, 0x5C5CE4B8,
0xC2C25D9F, 0xD3D36EBD, 0xACACEF43, 0x6262A6C4, 0x9191A839, 0x9595A431, 0xE4E437D3, 0x79798BF2,
#define u1(v) ((u1_t)(v)) 0xE7E732D5, 0xC8C8438B, 0x3737596E, 0x6D6DB7DA, 0x8D8D8C01, 0xD5D564B1, 0x4E4ED29C, 0xA9A9E049,
0x6C6CB4D8, 0x5656FAAC, 0xF4F407F3, 0xEAEA25CF, 0x6565AFCA, 0x7A7A8EF4, 0xAEAEE947, 0x08081810,
#define AES_key4(r1,r2,r3,r0,i) r1 = ki[i+1]; \ 0xBABAD56F, 0x787888F0, 0x25256F4A, 0x2E2E725C, 0x1C1C2438, 0xA6A6F157, 0xB4B4C773, 0xC6C65197,
r2 = ki[i+2]; \ 0xE8E823CB, 0xDDDD7CA1, 0x74749CE8, 0x1F1F213E, 0x4B4BDD96, 0xBDBDDC61, 0x8B8B860D, 0x8A8A850F,
r3 = ki[i+3]; \ 0x707090E0, 0x3E3E427C, 0xB5B5C471, 0x6666AACC, 0x4848D890, 0x03030506, 0xF6F601F7, 0x0E0E121C,
r0 = ki[i] 0x6161A3C2, 0x35355F6A, 0x5757F9AE, 0xB9B9D069, 0x86869117, 0xC1C15899, 0x1D1D273A, 0x9E9EB927,
0xE1E138D9, 0xF8F813EB, 0x9898B32B, 0x11113322, 0x6969BBD2, 0xD9D970A9, 0x8E8E8907, 0x9494A733,
#define AES_expr4(r1,r2,r3,r0,i) r1 ^= TABLE_GET_U4(AES_E4, u1(i)); \ 0x9B9BB62D, 0x1E1E223C, 0x87879215, 0xE9E920C9, 0xCECE4987, 0x5555FFAA, 0x28287850, 0xDFDF7AA5,
r2 ^= TABLE_GET_U4(AES_E3, u1(i>>8)); \ 0x8C8C8F03, 0xA1A1F859, 0x89898009, 0x0D0D171A, 0xBFBFDA65, 0xE6E631D7, 0x4242C684, 0x6868B8D0,
r3 ^= TABLE_GET_U4(AES_E2, u1(i>>16)); \ 0x4141C382, 0x9999B029, 0x2D2D775A, 0x0F0F111E, 0xB0B0CB7B, 0x5454FCA8, 0xBBBBD66D, 0x16163A2C,
r0 ^= TABLE_GET_U4(AES_E1, (i>>24)) };
#define AES_expr(a,r0,r1,r2,r3,i) a = ki[i]; \ #define msbf4_read(p) ((p)[0]<<24 | (p)[1]<<16 | (p)[2]<<8 | (p)[3])
a ^= ((u4_t)TABLE_GET_U1(AES_S, r0>>24 )<<24); \ #define msbf4_write(p,v) (p)[0]=(v)>>24,(p)[1]=(v)>>16,(p)[2]=(v)>>8,(p)[3]=(v)
a ^= ((u4_t)TABLE_GET_U1(AES_S, u1(r1>>16))<<16); \ #define swapmsbf(x) ( (x&0xFF)<<24 | (x&0xFF00)<<8 | (x&0xFF0000)>>8 | (x>>24) )
a ^= ((u4_t)TABLE_GET_U1(AES_S, u1(r2>> 8))<< 8); \
a ^= (u4_t)TABLE_GET_U1(AES_S, u1(r3) ) #define u1(v) ((u1_t)(v))
// global area for passing parameters (aux, key) and for storing round keys #define AES_key4(r1,r2,r3,r0,i) r1 = ki[i+1]; \
u4_t AESAUX[16/sizeof(u4_t)]; r2 = ki[i+2]; \
u4_t AESKEY[11*16/sizeof(u4_t)]; r3 = ki[i+3]; \
r0 = ki[i]
// generate 1+10 roundkeys for encryption with 128-bit key
// read 128-bit key from AESKEY in MSBF, generate roundkey words in place #define AES_expr4(r1,r2,r3,r0,i) r1 ^= TABLE_GET_U4(AES_E4, u1(i)); \
static void aesroundkeys () { r2 ^= TABLE_GET_U4(AES_E3, u1(i>>8)); \
int i; r3 ^= TABLE_GET_U4(AES_E2, u1(i>>16)); \
u4_t b; r0 ^= TABLE_GET_U4(AES_E1, (i>>24))
for( i=0; i<4; i++) { #define AES_expr(a,r0,r1,r2,r3,i) a = ki[i]; \
AESKEY[i] = swapmsbf(AESKEY[i]); a ^= ((u4_t)TABLE_GET_U1(AES_S, r0>>24 )<<24); \
} a ^= ((u4_t)TABLE_GET_U1(AES_S, u1(r1>>16))<<16); \
a ^= ((u4_t)TABLE_GET_U1(AES_S, u1(r2>> 8))<< 8); \
b = AESKEY[3]; a ^= (u4_t)TABLE_GET_U1(AES_S, u1(r3) )
for( ; i<44; i++ ) {
if( i%4==0 ) { // global area for passing parameters (aux, key) and for storing round keys
// b = SubWord(RotWord(b)) xor Rcon[i/4] u4_t AESAUX[16/sizeof(u4_t)];
b = ((u4_t)TABLE_GET_U1(AES_S, u1(b >> 16)) << 24) ^ u4_t AESKEY[11*16/sizeof(u4_t)];
((u4_t)TABLE_GET_U1(AES_S, u1(b >> 8)) << 16) ^
((u4_t)TABLE_GET_U1(AES_S, u1(b) ) << 8) ^ // generate 1+10 roundkeys for encryption with 128-bit key
((u4_t)TABLE_GET_U1(AES_S, b >> 24 ) ) ^ // read 128-bit key from AESKEY in MSBF, generate roundkey words in place
TABLE_GET_U4(AES_RCON, (i-4)/4); static void aesroundkeys () {
} int i;
AESKEY[i] = b ^= AESKEY[i-4]; u4_t b;
}
} for( i=0; i<4; i++) {
AESKEY[i] = swapmsbf(AESKEY[i]);
u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len) { }
aesroundkeys(); b = AESKEY[3];
for( ; i<44; i++ ) {
if( mode & AES_MICNOAUX ) { if( i%4==0 ) {
AESAUX[0] = AESAUX[1] = AESAUX[2] = AESAUX[3] = 0; // b = SubWord(RotWord(b)) xor Rcon[i/4]
} else { b = ((u4_t)TABLE_GET_U1(AES_S, u1(b >> 16)) << 24) ^
AESAUX[0] = swapmsbf(AESAUX[0]); ((u4_t)TABLE_GET_U1(AES_S, u1(b >> 8)) << 16) ^
AESAUX[1] = swapmsbf(AESAUX[1]); ((u4_t)TABLE_GET_U1(AES_S, u1(b) ) << 8) ^
AESAUX[2] = swapmsbf(AESAUX[2]); ((u4_t)TABLE_GET_U1(AES_S, b >> 24 ) ) ^
AESAUX[3] = swapmsbf(AESAUX[3]); TABLE_GET_U4(AES_RCON, (i-4)/4);
} }
AESKEY[i] = b ^= AESKEY[i-4];
while( (signed char)len > 0 ) { }
u4_t a0, a1, a2, a3; }
u4_t t0, t1, t2, t3;
u4_t *ki, *ke; u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len) {
// load input block aesroundkeys();
if( (mode & AES_CTR) || ((mode & AES_MIC) && (mode & AES_MICNOAUX)==0) ) { // load CTR block or first MIC block
a0 = AESAUX[0]; if( mode & AES_MICNOAUX ) {
a1 = AESAUX[1]; AESAUX[0] = AESAUX[1] = AESAUX[2] = AESAUX[3] = 0;
a2 = AESAUX[2]; } else {
a3 = AESAUX[3]; AESAUX[0] = swapmsbf(AESAUX[0]);
} AESAUX[1] = swapmsbf(AESAUX[1]);
else if( (mode & AES_MIC) && len <= 16 ) { // last MIC block AESAUX[2] = swapmsbf(AESAUX[2]);
a0 = a1 = a2 = a3 = 0; // load null block AESAUX[3] = swapmsbf(AESAUX[3]);
mode |= ((len == 16) ? 1 : 2) << 4; // set MICSUB: CMAC subkey K1 or K2 }
} else
LOADDATA: { // load data block (partially) while( (signed char)len > 0 ) {
for(t0=0; t0<16; t0++) { u4_t a0, a1, a2, a3;
t1 = (t1<<8) | ((t0<len) ? buf[t0] : (t0==len) ? 0x80 : 0x00); u4_t t0, t1, t2, t3;
if((t0&3)==3) { u4_t *ki, *ke;
a0 = a1;
a1 = a2; // load input block
a2 = a3; if( (mode & AES_CTR) || ((mode & AES_MIC) && (mode & AES_MICNOAUX)==0) ) { // load CTR block or first MIC block
a3 = t1; a0 = AESAUX[0];
} a1 = AESAUX[1];
} a2 = AESAUX[2];
if( mode & AES_MIC ) { a3 = AESAUX[3];
a0 ^= AESAUX[0]; }
a1 ^= AESAUX[1]; else if( (mode & AES_MIC) && len <= 16 ) { // last MIC block
a2 ^= AESAUX[2]; a0 = a1 = a2 = a3 = 0; // load null block
a3 ^= AESAUX[3]; mode |= ((len == 16) ? 1 : 2) << 4; // set MICSUB: CMAC subkey K1 or K2
} } else
} LOADDATA: { // load data block (partially)
for(t0=0; t0<16; t0++) {
// perform AES encryption on block in a0-a3 t1 = (t1<<8) | ((t0<len) ? buf[t0] : (t0==len) ? 0x80 : 0x00);
ki = AESKEY; if((t0&3)==3) {
ke = ki + 8*4; a0 = a1;
a0 ^= ki[0]; a1 = a2;
a1 ^= ki[1]; a2 = a3;
a2 ^= ki[2]; a3 = t1;
a3 ^= ki[3]; }
do { }
AES_key4 (t1,t2,t3,t0,4); if( mode & AES_MIC ) {
AES_expr4(t1,t2,t3,t0,a0); a0 ^= AESAUX[0];
AES_expr4(t2,t3,t0,t1,a1); a1 ^= AESAUX[1];
AES_expr4(t3,t0,t1,t2,a2); a2 ^= AESAUX[2];
AES_expr4(t0,t1,t2,t3,a3); a3 ^= AESAUX[3];
}
AES_key4 (a1,a2,a3,a0,8); }
AES_expr4(a1,a2,a3,a0,t0);
AES_expr4(a2,a3,a0,a1,t1); // perform AES encryption on block in a0-a3
AES_expr4(a3,a0,a1,a2,t2); ki = AESKEY;
AES_expr4(a0,a1,a2,a3,t3); ke = ki + 8*4;
} while( (ki+=8) < ke ); a0 ^= ki[0];
a1 ^= ki[1];
AES_key4 (t1,t2,t3,t0,4); a2 ^= ki[2];
AES_expr4(t1,t2,t3,t0,a0); a3 ^= ki[3];
AES_expr4(t2,t3,t0,t1,a1); do {
AES_expr4(t3,t0,t1,t2,a2); AES_key4 (t1,t2,t3,t0,4);
AES_expr4(t0,t1,t2,t3,a3); AES_expr4(t1,t2,t3,t0,a0);
AES_expr4(t2,t3,t0,t1,a1);
AES_expr(a0,t0,t1,t2,t3,8); AES_expr4(t3,t0,t1,t2,a2);
AES_expr(a1,t1,t2,t3,t0,9); AES_expr4(t0,t1,t2,t3,a3);
AES_expr(a2,t2,t3,t0,t1,10);
AES_expr(a3,t3,t0,t1,t2,11); AES_key4 (a1,a2,a3,a0,8);
// result of AES encryption in a0-a3 AES_expr4(a1,a2,a3,a0,t0);
AES_expr4(a2,a3,a0,a1,t1);
if( mode & AES_MIC ) { AES_expr4(a3,a0,a1,a2,t2);
if( (t1 = (mode & AES_MICSUB) >> 4) != 0 ) { // last block AES_expr4(a0,a1,a2,a3,t3);
do { } while( (ki+=8) < ke );
// compute CMAC subkey K1 and K2
t0 = a0 >> 31; // save MSB AES_key4 (t1,t2,t3,t0,4);
a0 = (a0 << 1) | (a1 >> 31); AES_expr4(t1,t2,t3,t0,a0);
a1 = (a1 << 1) | (a2 >> 31); AES_expr4(t2,t3,t0,t1,a1);
a2 = (a2 << 1) | (a3 >> 31); AES_expr4(t3,t0,t1,t2,a2);
a3 = (a3 << 1); AES_expr4(t0,t1,t2,t3,a3);
if( t0 ) a3 ^= 0x87;
} while( --t1 ); AES_expr(a0,t0,t1,t2,t3,8);
AES_expr(a1,t1,t2,t3,t0,9);
AESAUX[0] ^= a0; AES_expr(a2,t2,t3,t0,t1,10);
AESAUX[1] ^= a1; AES_expr(a3,t3,t0,t1,t2,11);
AESAUX[2] ^= a2; // result of AES encryption in a0-a3
AESAUX[3] ^= a3;
mode &= ~AES_MICSUB; if( mode & AES_MIC ) {
goto LOADDATA; if( (t1 = (mode & AES_MICSUB) >> 4) != 0 ) { // last block
} else { do {
// save cipher block as new iv // compute CMAC subkey K1 and K2
AESAUX[0] = a0; t0 = a0 >> 31; // save MSB
AESAUX[1] = a1; a0 = (a0 << 1) | (a1 >> 31);
AESAUX[2] = a2; a1 = (a1 << 1) | (a2 >> 31);
AESAUX[3] = a3; a2 = (a2 << 1) | (a3 >> 31);
} a3 = (a3 << 1);
} else { // CIPHER if( t0 ) a3 ^= 0x87;
if( mode & AES_CTR ) { // xor block (partially) } while( --t1 );
t0 = (len > 16) ? 16: len;
for(t1=0; t1<t0; t1++) { AESAUX[0] ^= a0;
buf[t1] ^= (a0>>24); AESAUX[1] ^= a1;
a0 <<= 8; AESAUX[2] ^= a2;
if((t1&3)==3) { AESAUX[3] ^= a3;
a0 = a1; mode &= ~AES_MICSUB;
a1 = a2; goto LOADDATA;
a2 = a3; } else {
} // save cipher block as new iv
} AESAUX[0] = a0;
// update counter AESAUX[1] = a1;
AESAUX[3]++; AESAUX[2] = a2;
} else { // ECB AESAUX[3] = a3;
// store block }
msbf4_write(buf+0, a0); } else { // CIPHER
msbf4_write(buf+4, a1); if( mode & AES_CTR ) { // xor block (partially)
msbf4_write(buf+8, a2); t0 = (len > 16) ? 16: len;
msbf4_write(buf+12, a3); for(t1=0; t1<t0; t1++) {
} buf[t1] ^= (a0>>24);
} a0 <<= 8;
if((t1&3)==3) {
// update block state a0 = a1;
if( (mode & AES_MIC)==0 || (mode & AES_MICNOAUX) ) { a1 = a2;
buf += 16; a2 = a3;
len -= 16; }
} }
mode |= AES_MICNOAUX; // update counter
} AESAUX[3]++;
return AESAUX[0]; } else { // ECB
} // store block
msbf4_write(buf+0, a0);
#endif msbf4_write(buf+4, a1);
msbf4_write(buf+8, a2);
msbf4_write(buf+12, a3);
}
}
// update block state
if( (mode & AES_MIC)==0 || (mode & AES_MICNOAUX) ) {
buf += 16;
len -= 16;
}
mode |= AES_MICNOAUX;
}
return AESAUX[0];
}
#endif

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@ -1,145 +1,145 @@
/******************************************************************************* /*******************************************************************************
* Copyright (c) 2016 Matthijs Kooijman * Copyright (c) 2016 Matthijs Kooijman
* *
* LICENSE * LICENSE
* *
* Permission is hereby granted, free of charge, to anyone * Permission is hereby granted, free of charge, to anyone
* obtaining a copy of this document and accompanying files, * obtaining a copy of this document and accompanying files,
* to do whatever they want with them without any restriction, * to do whatever they want with them without any restriction,
* including, but not limited to, copying, modification and * including, but not limited to, copying, modification and
* redistribution. * redistribution.
* *
* NO WARRANTY OF ANY KIND IS PROVIDED. * NO WARRANTY OF ANY KIND IS PROVIDED.
*******************************************************************************/ *******************************************************************************/
/* /*
* The original LMIC AES implementation integrates raw AES encryption * The original LMIC AES implementation integrates raw AES encryption
* with CMAC and AES-CTR in a single piece of code. Most other AES * with CMAC and AES-CTR in a single piece of code. Most other AES
* implementations (only) offer raw single block AES encryption, so this * implementations (only) offer raw single block AES encryption, so this
* file contains an implementation of CMAC and AES-CTR, and offers the * file contains an implementation of CMAC and AES-CTR, and offers the
* same API through the os_aes() function as the original AES * same API through the os_aes() function as the original AES
* implementation. This file assumes that there is an encryption * implementation. This file assumes that there is an encryption
* function available with this signature: * function available with this signature:
* *
* extern "C" void lmic_aes_encrypt(u1_t *data, u1_t *key); * extern "C" void lmic_aes_encrypt(u1_t *data, u1_t *key);
* *
* That takes a single 16-byte buffer and encrypts it wit the given * That takes a single 16-byte buffer and encrypts it wit the given
* 16-byte key. * 16-byte key.
*/ */
#include "../lmic/oslmic.h" #include "../lmic/oslmic.h"
#if !defined(USE_ORIGINAL_AES) #if !defined(USE_ORIGINAL_AES)
// This should be defined elsewhere // This should be defined elsewhere
void lmic_aes_encrypt(u1_t *data, u1_t *key); void lmic_aes_encrypt(u1_t *data, u1_t *key);
// global area for passing parameters (aux, key) // global area for passing parameters (aux, key) and for storing round keys
u4_t AESAUX[16/sizeof(u4_t)]; u4_t AESAUX[16/sizeof(u4_t)];
u4_t AESKEY[16/sizeof(u4_t)]; u4_t AESKEY[11*16/sizeof(u4_t)];
// Shift the given buffer left one bit // Shift the given buffer left one bit
static void shift_left(xref2u1_t buf, u1_t len) { static void shift_left(xref2u1_t buf, u1_t len) {
while (len--) { while (len--) {
u1_t next = len ? buf[1] : 0; u1_t next = len ? buf[1] : 0;
u1_t val = (*buf << 1); u1_t val = (*buf << 1);
if (next & 0x80) if (next & 0x80)
val |= 1; val |= 1;
*buf++ = val; *buf++ = val;
} }
} }
// Apply RFC4493 CMAC, using AESKEY as the key. If prepend_aux is true, // Apply RFC4493 CMAC, using AESKEY as the key. If prepend_aux is true,
// AESAUX is prepended to the message. AESAUX is used as working memory // AESAUX is prepended to the message. AESAUX is used as working memory
// in any case. The CMAC result is returned in AESAUX as well. // in any case. The CMAC result is returned in AESAUX as well.
static void os_aes_cmac(xref2u1_t buf, u2_t len, u1_t prepend_aux) { static void os_aes_cmac(xref2u1_t buf, u2_t len, u1_t prepend_aux) {
if (prepend_aux) if (prepend_aux)
lmic_aes_encrypt(AESaux, AESkey); lmic_aes_encrypt(AESaux, AESkey);
else else
memset (AESaux, 0, 16); memset (AESaux, 0, 16);
while (len > 0) { while (len > 0) {
u1_t need_padding = 0; u1_t need_padding = 0;
for (u1_t i = 0; i < 16; ++i, ++buf, --len) { for (u1_t i = 0; i < 16; ++i, ++buf, --len) {
if (len == 0) { if (len == 0) {
// The message is padded with 0x80 and then zeroes. // The message is padded with 0x80 and then zeroes.
// Since zeroes are no-op for xor, we can just skip them // Since zeroes are no-op for xor, we can just skip them
// and leave AESAUX unchanged for them. // and leave AESAUX unchanged for them.
AESaux[i] ^= 0x80; AESaux[i] ^= 0x80;
need_padding = 1; need_padding = 1;
break; break;
} }
AESaux[i] ^= *buf; AESaux[i] ^= *buf;
} }
if (len == 0) { if (len == 0) {
// Final block, xor with K1 or K2. K1 and K2 are calculated // Final block, xor with K1 or K2. K1 and K2 are calculated
// by encrypting the all-zeroes block and then applying some // by encrypting the all-zeroes block and then applying some
// shifts and xor on that. // shifts and xor on that.
u1_t final_key[16]; u1_t final_key[16];
memset(final_key, 0, sizeof(final_key)); memset(final_key, 0, sizeof(final_key));
lmic_aes_encrypt(final_key, AESkey); lmic_aes_encrypt(final_key, AESkey);
// Calculate K1 // Calculate K1
u1_t msb = final_key[0] & 0x80; u1_t msb = final_key[0] & 0x80;
shift_left(final_key, sizeof(final_key)); shift_left(final_key, sizeof(final_key));
if (msb) if (msb)
final_key[sizeof(final_key)-1] ^= 0x87; final_key[sizeof(final_key)-1] ^= 0x87;
// If the final block was not complete, calculate K2 from K1 // If the final block was not complete, calculate K2 from K1
if (need_padding) { if (need_padding) {
msb = final_key[0] & 0x80; msb = final_key[0] & 0x80;
shift_left(final_key, sizeof(final_key)); shift_left(final_key, sizeof(final_key));
if (msb) if (msb)
final_key[sizeof(final_key)-1] ^= 0x87; final_key[sizeof(final_key)-1] ^= 0x87;
} }
// Xor with K1 or K2 // Xor with K1 or K2
for (u1_t i = 0; i < sizeof(final_key); ++i) for (u1_t i = 0; i < sizeof(final_key); ++i)
AESaux[i] ^= final_key[i]; AESaux[i] ^= final_key[i];
} }
lmic_aes_encrypt(AESaux, AESkey); lmic_aes_encrypt(AESaux, AESkey);
} }
} }
// Run AES-CTR using the key in AESKEY and using AESAUX as the // Run AES-CTR using the key in AESKEY and using AESAUX as the
// counter block. The last byte of the counter block will be incremented // counter block. The last byte of the counter block will be incremented
// for every block. The given buffer will be encrypted in place. // for every block. The given buffer will be encrypted in place.
static void os_aes_ctr (xref2u1_t buf, u2_t len) { static void os_aes_ctr (xref2u1_t buf, u2_t len) {
u1_t ctr[16]; u1_t ctr[16];
while (len) { while (len) {
// Encrypt the counter block with the selected key // Encrypt the counter block with the selected key
memcpy(ctr, AESaux, sizeof(ctr)); memcpy(ctr, AESaux, sizeof(ctr));
lmic_aes_encrypt(ctr, AESkey); lmic_aes_encrypt(ctr, AESkey);
// Xor the payload with the resulting ciphertext // Xor the payload with the resulting ciphertext
for (u1_t i = 0; i < 16 && len > 0; i++, len--, buf++) for (u1_t i = 0; i < 16 && len > 0; i++, len--, buf++)
*buf ^= ctr[i]; *buf ^= ctr[i];
// Increment the block index byte // Increment the block index byte
AESaux[15]++; AESaux[15]++;
} }
} }
u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len) { u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len) {
switch (mode & ~AES_MICNOAUX) { switch (mode & ~AES_MICNOAUX) {
case AES_MIC: case AES_MIC:
os_aes_cmac(buf, len, /* prepend_aux */ !(mode & AES_MICNOAUX)); os_aes_cmac(buf, len, /* prepend_aux */ !(mode & AES_MICNOAUX));
return os_rmsbf4(AESaux); return os_rmsbf4(AESaux);
case AES_ENC: case AES_ENC:
// TODO: Check / handle when len is not a multiple of 16 // TODO: Check / handle when len is not a multiple of 16
for (u1_t i = 0; i < len; i += 16) for (u1_t i = 0; i < len; i += 16)
lmic_aes_encrypt(buf+i, AESkey); lmic_aes_encrypt(buf+i, AESkey);
break; break;
case AES_CTR: case AES_CTR:
os_aes_ctr(buf, len); os_aes_ctr(buf, len);
break; break;
} }
return 0; return 0;
} }
#endif // !defined(USE_ORIGINAL_AES) #endif // !defined(USE_ORIGINAL_AES)

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@ -1,269 +1,349 @@
/******************************************************************************* /*******************************************************************************
* Copyright (c) 2015 Matthijs Kooijman * Copyright (c) 2015 Matthijs Kooijman
* All rights reserved. This program and the accompanying materials * All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0 * are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at * which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html * http://www.eclipse.org/legal/epl-v10.html
* *
* This the HAL to run LMIC on top of the Arduino environment. * This the HAL to run LMIC on top of the Arduino environment.
*******************************************************************************/ *******************************************************************************/
#include <Arduino.h> #include <Arduino.h>
#include <SPI.h> #include <SPI.h>
#include "../lmic.h" #include "../lmic.h"
#include "hal.h" #include "hal.h"
#include <stdio.h> #include <stdio.h>
// ----------------------------------------------------------------------------- // -----------------------------------------------------------------------------
// I/O // I/O
static void hal_io_init () { static const lmic_pinmap *plmic_pins;
// NSS and DIO0 are required, DIO1 is required for LoRa, DIO2 for FSK
ASSERT(lmic_pins.nss != LMIC_UNUSED_PIN); static void hal_interrupt_init(); // Fwd declaration
ASSERT(lmic_pins.dio[0] != LMIC_UNUSED_PIN);
ASSERT(lmic_pins.dio[1] != LMIC_UNUSED_PIN || lmic_pins.dio[2] != LMIC_UNUSED_PIN); static void hal_io_init () {
// NSS and DIO0 are required, DIO1 is required for LoRa, DIO2 for FSK
#ifdef LMIC_SPI_PINS_IN_MAPPING ASSERT(plmic_pins->nss != LMIC_UNUSED_PIN);
ASSERT(lmic_pins.mosi != LMIC_UNUSED_PIN ASSERT(plmic_pins->dio[0] != LMIC_UNUSED_PIN);
|| lmic_pins.miso != LMIC_UNUSED_PIN ASSERT(plmic_pins->dio[1] != LMIC_UNUSED_PIN || plmic_pins->dio[2] != LMIC_UNUSED_PIN);
|| lmic_pins.sck != LMIC_UNUSED_PIN);
#endif // Serial.print("nss: "); Serial.println(plmic_pins->nss);
// Serial.print("rst: "); Serial.println(plmic_pins->rst);
pinMode(lmic_pins.nss, OUTPUT); // Serial.print("dio[0]: "); Serial.println(plmic_pins->dio[0]);
if (lmic_pins.rxtx != LMIC_UNUSED_PIN) // Serial.print("dio[1]: "); Serial.println(plmic_pins->dio[1]);
pinMode(lmic_pins.rxtx, OUTPUT); // Serial.print("dio[2]: "); Serial.println(plmic_pins->dio[2]);
if (lmic_pins.rst != LMIC_UNUSED_PIN)
pinMode(lmic_pins.rst, OUTPUT); pinMode(plmic_pins->nss, OUTPUT);
if (plmic_pins->rxtx != LMIC_UNUSED_PIN)
pinMode(lmic_pins.dio[0], INPUT); pinMode(plmic_pins->rxtx, OUTPUT);
if (lmic_pins.dio[1] != LMIC_UNUSED_PIN) if (plmic_pins->rst != LMIC_UNUSED_PIN)
pinMode(lmic_pins.dio[1], INPUT); pinMode(plmic_pins->rst, OUTPUT);
if (lmic_pins.dio[2] != LMIC_UNUSED_PIN)
pinMode(lmic_pins.dio[2], INPUT); hal_interrupt_init();
} }
// val == 1 => tx 1 // val == 1 => tx
void hal_pin_rxtx (u1_t val) { void hal_pin_rxtx (u1_t val) {
if (lmic_pins.rxtx != LMIC_UNUSED_PIN) if (plmic_pins->rxtx != LMIC_UNUSED_PIN)
digitalWrite(lmic_pins.rxtx, val); digitalWrite(plmic_pins->rxtx, val != plmic_pins->rxtx_rx_active);
} }
// set radio RST pin to given value (or keep floating!) // set radio RST pin to given value (or keep floating!)
void hal_pin_rst (u1_t val) { void hal_pin_rst (u1_t val) {
if (lmic_pins.rst == LMIC_UNUSED_PIN) if (plmic_pins->rst == LMIC_UNUSED_PIN)
return; return;
if(val == 0 || val == 1) { // drive pin if(val == 0 || val == 1) { // drive pin
pinMode(lmic_pins.rst, OUTPUT); pinMode(plmic_pins->rst, OUTPUT);
digitalWrite(lmic_pins.rst, val); digitalWrite(plmic_pins->rst, val);
} else { // keep pin floating } else { // keep pin floating
pinMode(lmic_pins.rst, INPUT); pinMode(plmic_pins->rst, INPUT);
} }
} }
static bool dio_states[NUM_DIO] = {0}; s1_t hal_getRssiCal (void) {
return plmic_pins->rssi_cal;
static void hal_io_check() { }
uint8_t i;
for (i = 0; i < NUM_DIO; ++i) { #if !defined(LMIC_USE_INTERRUPTS)
if (lmic_pins.dio[i] == LMIC_UNUSED_PIN) static void hal_interrupt_init() {
continue; pinMode(plmic_pins->dio[0], INPUT);
if (plmic_pins->dio[1] != LMIC_UNUSED_PIN)
if (dio_states[i] != digitalRead(lmic_pins.dio[i])) { pinMode(plmic_pins->dio[1], INPUT);
dio_states[i] = !dio_states[i]; if (plmic_pins->dio[2] != LMIC_UNUSED_PIN)
if (dio_states[i]) pinMode(plmic_pins->dio[2], INPUT);
radio_irq_handler(i); }
}
} static bool dio_states[NUM_DIO] = {0};
} static void hal_io_check() {
uint8_t i;
// ----------------------------------------------------------------------------- for (i = 0; i < NUM_DIO; ++i) {
// SPI if (plmic_pins->dio[i] == LMIC_UNUSED_PIN)
continue;
static const SPISettings settings(10E6, MSBFIRST, SPI_MODE0);
if (dio_states[i] != digitalRead(plmic_pins->dio[i])) {
// Initialize SPI, allowing override of default SPI pins on certain boards. dio_states[i] = !dio_states[i];
static void hal_spi_init () { if (dio_states[i])
#if defined(ESP32) radio_irq_handler(i);
// On the ESP32 the default is _use_hw_ss(false), }
// so we can set the last parameter to anything. }
SPI.begin(lmic_pins.sck, lmic_pins.miso, lmic_pins.mosi, 0x00); }
#elif defined(NRF51)
SPI.begin(lmic_pins.sck, lmic_pins.mosi, lmic_pins.miso); #else
#else // Interrupt handlers
//unknown board, or board without SPI pin select ability static ostime_t interrupt_time[NUM_DIO] = {0};
SPI.begin();
#endif static void hal_isrPin0() {
} ostime_t now = os_getTime();
interrupt_time[0] = now ? now : 1;
void hal_pin_nss (u1_t val) { }
if (!val) static void hal_isrPin1() {
SPI.beginTransaction(settings); ostime_t now = os_getTime();
else interrupt_time[1] = now ? now : 1;
SPI.endTransaction(); }
static void hal_isrPin2() {
//Serial.println(val?">>":"<<"); ostime_t now = os_getTime();
digitalWrite(lmic_pins.nss, val); interrupt_time[2] = now ? now : 1;
} }
// perform SPI transaction with radio typedef void (*isr_t)();
u1_t hal_spi (u1_t out) { static isr_t interrupt_fns[NUM_DIO] = {hal_isrPin0, hal_isrPin1, hal_isrPin2};
u1_t res = SPI.transfer(out);
/* static void hal_interrupt_init() {
Serial.print(">"); for (uint8_t i = 0; i < NUM_DIO; ++i) {
Serial.print(out, HEX); if (plmic_pins->dio[i] == LMIC_UNUSED_PIN)
Serial.print("<"); continue;
Serial.println(res, HEX);
*/ attachInterrupt(digitalPinToInterrupt(plmic_pins->dio[i]), interrupt_fns[i], RISING);
return res; }
} }
// ----------------------------------------------------------------------------- static void hal_io_check() {
// TIME uint8_t i;
for (i = 0; i < NUM_DIO; ++i) {
static void hal_time_init () { ostime_t iTime;
// Nothing to do if (plmic_pins->dio[i] == LMIC_UNUSED_PIN)
} continue;
u4_t hal_ticks () { iTime = interrupt_time[i];
// Because micros() is scaled down in this function, micros() will if (iTime) {
// overflow before the tick timer should, causing the tick timer to interrupt_time[i] = 0;
// miss a significant part of its values if not corrected. To fix radio_irq_handler_v2(i, iTime);
// this, the "overflow" serves as an overflow area for the micros() }
// counter. It consists of three parts: }
// - The US_PER_OSTICK upper bits are effectively an extension for }
// the micros() counter and are added to the result of this #endif // LMIC_USE_INTERRUPTS
// function.
// - The next bit overlaps with the most significant bit of // -----------------------------------------------------------------------------
// micros(). This is used to detect micros() overflows. // SPI
// - The remaining bits are always zero.
// static void hal_spi_init () {
// By comparing the overlapping bit with the corresponding bit in SPI.begin(plmic_pins->sck, plmic_pins->miso, plmic_pins->mosi, plmic_pins->nss);
// the micros() return value, overflows can be detected and the }
// upper bits are incremented. This is done using some clever
// bitwise operations, to remove the need for comparisons and a void hal_pin_nss (u1_t val) {
// jumps, which should result in efficient code. By avoiding shifts if (!val) {
// other than by multiples of 8 as much as possible, this is also uint32_t spi_freq;
// efficient on AVR (which only has 1-bit shifts).
static uint8_t overflow = 0; if ((spi_freq = plmic_pins->spi_freq) == 0)
spi_freq = LMIC_SPI_FREQ;
// Scaled down timestamp. The top US_PER_OSTICK_EXPONENT bits are 0,
// the others will be the lower bits of our return value. SPISettings settings(spi_freq, MSBFIRST, SPI_MODE0);
uint32_t scaled = micros() >> US_PER_OSTICK_EXPONENT; SPI.beginTransaction(settings);
// Most significant byte of scaled } else {
uint8_t msb = scaled >> 24; SPI.endTransaction();
// Mask pointing to the overlapping bit in msb and overflow. }
const uint8_t mask = (1 << (7 - US_PER_OSTICK_EXPONENT));
// Update overflow. If the overlapping bit is different //Serial.println(val?">>":"<<");
// between overflow and msb, it is added to the stored value, digitalWrite(plmic_pins->nss, val);
// so the overlapping bit becomes equal again and, if it changed }
// from 1 to 0, the upper bits are incremented.
overflow += (msb ^ overflow) & mask; // perform SPI transaction with radio
u1_t hal_spi (u1_t out) {
// Return the scaled value with the upper bits of stored added. The u1_t res = SPI.transfer(out);
// overlapping bit will be equal and the lower bits will be 0, so /*
// bitwise or is a no-op for them. Serial.print(">");
return scaled | ((uint32_t)overflow << 24); Serial.print(out, HEX);
Serial.print("<");
// 0 leads to correct, but overly complex code (it could just return Serial.println(res, HEX);
// micros() unmodified), 8 leaves no room for the overlapping bit. */
static_assert(US_PER_OSTICK_EXPONENT > 0 && US_PER_OSTICK_EXPONENT < 8, "Invalid US_PER_OSTICK_EXPONENT value"); return res;
} }
// Returns the number of ticks until time. Negative values indicate that // -----------------------------------------------------------------------------
// time has already passed. // TIME
static s4_t delta_time(u4_t time) {
return (s4_t)(time - hal_ticks()); static void hal_time_init () {
} // Nothing to do
}
void hal_waitUntil (u4_t time) {
s4_t delta = delta_time(time); u4_t hal_ticks () {
// From delayMicroseconds docs: Currently, the largest value that // Because micros() is scaled down in this function, micros() will
// will produce an accurate delay is 16383. // overflow before the tick timer should, causing the tick timer to
while (delta > (16000 / US_PER_OSTICK)) { // miss a significant part of its values if not corrected. To fix
delay(16); // this, the "overflow" serves as an overflow area for the micros()
delta -= (16000 / US_PER_OSTICK); // counter. It consists of three parts:
} // - The US_PER_OSTICK upper bits are effectively an extension for
if (delta > 0) // the micros() counter and are added to the result of this
delayMicroseconds(delta * US_PER_OSTICK); // function.
} // - The next bit overlaps with the most significant bit of
// micros(). This is used to detect micros() overflows.
// check and rewind for target time // - The remaining bits are always zero.
u1_t hal_checkTimer (u4_t time) { //
// No need to schedule wakeup, since we're not sleeping // By comparing the overlapping bit with the corresponding bit in
return delta_time(time) <= 0; // the micros() return value, overflows can be detected and the
} // upper bits are incremented. This is done using some clever
// bitwise operations, to remove the need for comparisons and a
static uint8_t irqlevel = 0; // jumps, which should result in efficient code. By avoiding shifts
// other than by multiples of 8 as much as possible, this is also
void hal_disableIRQs () { // efficient on AVR (which only has 1-bit shifts).
noInterrupts(); static uint8_t overflow = 0;
irqlevel++;
} // Scaled down timestamp. The top US_PER_OSTICK_EXPONENT bits are 0,
// the others will be the lower bits of our return value.
void hal_enableIRQs () { uint32_t scaled = micros() >> US_PER_OSTICK_EXPONENT;
if(--irqlevel == 0) { // Most significant byte of scaled
interrupts(); uint8_t msb = scaled >> 24;
// Mask pointing to the overlapping bit in msb and overflow.
// Instead of using proper interrupts (which are a bit tricky const uint8_t mask = (1 << (7 - US_PER_OSTICK_EXPONENT));
// and/or not available on all pins on AVR), just poll the pin // Update overflow. If the overlapping bit is different
// values. Since os_runloop disables and re-enables interrupts, // between overflow and msb, it is added to the stored value,
// putting this here makes sure we check at least once every // so the overlapping bit becomes equal again and, if it changed
// loop. // from 1 to 0, the upper bits are incremented.
// overflow += (msb ^ overflow) & mask;
// As an additional bonus, this prevents the can of worms that
// we would otherwise get for running SPI transfers inside ISRs // Return the scaled value with the upper bits of stored added. The
hal_io_check(); // overlapping bit will be equal and the lower bits will be 0, so
} // bitwise or is a no-op for them.
} return scaled | ((uint32_t)overflow << 24);
void hal_sleep () { // 0 leads to correct, but overly complex code (it could just return
// Not implemented // micros() unmodified), 8 leaves no room for the overlapping bit.
} static_assert(US_PER_OSTICK_EXPONENT > 0 && US_PER_OSTICK_EXPONENT < 8, "Invalid US_PER_OSTICK_EXPONENT value");
}
// -----------------------------------------------------------------------------
// Returns the number of ticks until time. Negative values indicate that
#if defined(LMIC_PRINTF_TO) // time has already passed.
static int uart_putchar (char c, FILE *) static s4_t delta_time(u4_t time) {
{ return (s4_t)(time - hal_ticks());
LMIC_PRINTF_TO.write(c) ; }
return 0 ;
} void hal_waitUntil (u4_t time) {
s4_t delta = delta_time(time);
void hal_printf_init() { // From delayMicroseconds docs: Currently, the largest value that
// create a FILE structure to reference our UART output function // will produce an accurate delay is 16383.
static FILE uartout; while (delta > (16000 / US_PER_OSTICK)) {
memset(&uartout, 0, sizeof(uartout)); delay(16);
delta -= (16000 / US_PER_OSTICK);
// fill in the UART file descriptor with pointer to writer. }
fdev_setup_stream (&uartout, uart_putchar, NULL, _FDEV_SETUP_WRITE); if (delta > 0)
delayMicroseconds(delta * US_PER_OSTICK);
// The uart is the standard output device STDOUT. }
stdout = &uartout ;
} // check and rewind for target time
#endif // defined(LMIC_PRINTF_TO) u1_t hal_checkTimer (u4_t time) {
// No need to schedule wakeup, since we're not sleeping
void hal_init () { return delta_time(time) <= 0;
// configure radio I/O and interrupt handler }
hal_io_init();
// configure radio SPI static uint8_t irqlevel = 0;
hal_spi_init();
// configure timer and interrupt handler void hal_disableIRQs () {
hal_time_init(); noInterrupts();
#if defined(LMIC_PRINTF_TO) irqlevel++;
// printf support }
hal_printf_init();
#endif void hal_enableIRQs () {
} if(--irqlevel == 0) {
interrupts();
void hal_failed (const char *file, u2_t line) {
#if defined(LMIC_FAILURE_TO) // Instead of using proper interrupts (which are a bit tricky
LMIC_FAILURE_TO.println("FAILURE "); // and/or not available on all pins on AVR), just poll the pin
LMIC_FAILURE_TO.print(file); // values. Since os_runloop disables and re-enables interrupts,
LMIC_FAILURE_TO.print(':'); // putting this here makes sure we check at least once every
LMIC_FAILURE_TO.println(line); // loop.
LMIC_FAILURE_TO.flush(); //
#endif // As an additional bonus, this prevents the can of worms that
hal_disableIRQs(); // we would otherwise get for running SPI transfers inside ISRs
while(1); hal_io_check();
} }
}
void hal_sleep () {
// Not implemented
}
// -----------------------------------------------------------------------------
#if defined(LMIC_PRINTF_TO)
#if !defined(__AVR)
static ssize_t uart_putchar (void *, const char *buf, size_t len) {
return LMIC_PRINTF_TO.write((const uint8_t *)buf, len);
}
static cookie_io_functions_t functions =
{
.read = NULL,
.write = uart_putchar,
.seek = NULL,
.close = NULL
};
void hal_printf_init() {
stdout = fopencookie(NULL, "w", functions);
if (stdout != nullptr) {
setvbuf(stdout, NULL, _IONBF, 0);
}
}
#else // defined(__AVR)
static int uart_putchar (char c, FILE *)
{
LMIC_PRINTF_TO.write(c) ;
return 0 ;
}
void hal_printf_init() {
// create a FILE structure to reference our UART output function
static FILE uartout;
memset(&uartout, 0, sizeof(uartout));
// fill in the UART file descriptor with pointer to writer.
fdev_setup_stream (&uartout, uart_putchar, NULL, _FDEV_SETUP_WRITE);
// The uart is the standard output device STDOUT.
stdout = &uartout ;
}
#endif // !defined(ESP8266) || defined(ESP31B) || defined(ESP32)
#endif // defined(LMIC_PRINTF_TO)
void hal_init (void) {
hal_init_ex(&lmic_pins);
}
void hal_init_ex (const void *pContext) {
plmic_pins = (const lmic_pinmap *)pContext;
// configure radio I/O and interrupt handler
hal_io_init();
// configure radio SPI
hal_spi_init();
// configure timer and interrupt handler
hal_time_init();
#if defined(LMIC_PRINTF_TO)
// printf support
hal_printf_init();
#endif
}
void hal_failed (const char *file, u2_t line) {
#if defined(LMIC_FAILURE_TO)
LMIC_FAILURE_TO.println("FAILURE ");
LMIC_FAILURE_TO.print(file);
LMIC_FAILURE_TO.print(':');
LMIC_FAILURE_TO.println(line);
LMIC_FAILURE_TO.flush();
#endif
hal_disableIRQs();
while(1);
}

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/*******************************************************************************
* Copyright (c) 2015-2016 Matthijs Kooijman
* Copyright (c) 2016-2018 MCCI Corporation
*
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* This the HAL to run LMIC on top of the Arduino environment.
*******************************************************************************/
#ifndef _hal_hal_h_
#define _hal_hal_h_
static const int NUM_DIO = 3;
// be careful of alignment below.
struct lmic_pinmap {
u1_t nss; // byte 0: pin for select
u1_t rxtx; // byte 1: pin for rx/tx control
u1_t rst; // byte 2: pin for reset
u1_t dio[NUM_DIO]; // bytes 3..5: pins for DIO0, DOI1, DIO2
u1_t mosi; // byte 9: pin for master out / slave in (write to LORA chip)
u1_t miso; // byte 10: pin for master in / slave out (read from LORA chip)
u1_t sck; // byte 11: pin for serial clock by master
// true if we must set rxtx for rx_active, false for tx_active
u1_t rxtx_rx_active; // byte 6: polarity of rxtx active
s1_t rssi_cal; // byte 7: cal in dB -- added to RSSI
// measured prior to decision.
// Must include noise guardband!
u4_t spi_freq; // bytes 8..11: SPI freq in Hz.
};
// Use this for any unused pins.
const u1_t LMIC_UNUSED_PIN = 0xff;
// Declared here, to be defined and initialized by the application
// use os_init_ex() if you want not to use a const table.
extern const lmic_pinmap lmic_pins;
#endif // _hal_hal_h_

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#ifdef __cplusplus #ifdef __cplusplus
extern "C"{ extern "C"{
#endif #endif
#include "lmic/lmic.h" #include "lmic/lmic.h"
#include "lmic/lmic_bandplan.h"
#ifdef __cplusplus #include "lmic/lmic_util.h"
}
#endif #ifdef __cplusplus
}
#endif

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#ifndef _lmic_config_h_
#define _lmic_config_h_
// In the original LMIC code, these config values were defined on the
// gcc commandline. Since Arduino does not allow easily modifying the
// compiler commandline unless you modify the BSP, you have two choices:
//
// - edit {libraries}/arduino-lmic/project_config/lmic_project_config.h;
// - use a BSP like the MCCI Arduino BSPs, which get the configuration
// from the boards.txt file through a menu option.
//
// You definitely should not edit this file.
// set up preconditions, and load configuration if needed.
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
// check post-conditions.
// make sure that we have exactly one target region defined.
#if CFG_LMIC_REGION_MASK == 0
# define CFG_eu868 1
#elif (CFG_LMIC_REGION_MASK & (-CFG_LMIC_REGION_MASK)) != CFG_LMIC_REGION_MASK
# error You can define at most one of CFG_... variables
#elif (CFG_LMIC_REGION_MASK & LMIC_REGIONS_SUPPORTED) == 0
# error The selected CFG_... region is not supported yet.
#endif
// make sure that LMIC_COUNTRY_CODE is defined.
#ifndef LMIC_COUNTRY_CODE
# define LMIC_COUNTRY_CODE LMIC_COUNTRY_CODE_NONE
#endif
// if the country code is Japan, then the region must be AS923
#if LMIC_COUNTRY_CODE == LMIC_COUNTRY_CODE_JP && CFG_region != LMIC_REGION_as923
# error "If country code is JP, then region must be AS923"
#endif
// check for internal consistency
#if !(CFG_LMIC_EU_like || CFG_LMIC_US_like)
# error "Internal error: Neither EU-like nor US-like!"
#endif
// This is the SX1272/SX1273 radio, which is also used on the HopeRF
// RFM92 boards.
//#define CFG_sx1272_radio 1
// This is the SX1276/SX1277/SX1278/SX1279 radio, which is also used on
// the HopeRF RFM95 boards.
//#define CFG_sx1276_radio 1
// ensure that a radio is defined.
#if ! (defined(CFG_sx1272_radio) || defined(CFG_sx1276_radio))
# warning Target radio not defined, assuming CFG_sx1276_radio
#define CFG_sx1276_radio 1
#elif defined(CFG_sx1272_radio) && defined(CFG_sx1276_radio)
# error You can define at most one of CFG_sx1272_radio and CF_sx1276_radio
#endif
// LMIC requires ticks to be 15.5μs - 100 μs long
#ifndef OSTICKS_PER_SEC
// 16 μs per tick
# ifndef US_PER_OSTICK_EXPONENT
# define US_PER_OSTICK_EXPONENT 4
# endif
# define US_PER_OSTICK (1 << US_PER_OSTICK_EXPONENT)
# define OSTICKS_PER_SEC (1000000 / US_PER_OSTICK)
#endif /* OSTICKS_PER_SEC */
#if ! (10000 <= OSTICKS_PER_SEC && OSTICKS_PER_SEC < 64516)
# error LMIC requires ticks to be 15.5 us to 100 us long
#endif
// Change the SPI clock speed if you encounter errors
// communicating with the radio.
// The standard range is 125kHz-8MHz, but some boards can go faster.
#ifndef LMIC_SPI_FREQ
#define LMIC_SPI_FREQ 1E6
#endif
// Set this to 1 to enable some basic debug output (using printf) about
// RF settings used during transmission and reception. Set to 2 to
// enable more verbose output. Make sure that printf is actually
// configured (e.g. on AVR it is not by default), otherwise using it can
// cause crashing.
#ifndef LMIC_DEBUG_LEVEL
#define LMIC_DEBUG_LEVEL 0
#endif
// Enable this to allow using printf() to print to the given serial port
// (or any other Print object). This can be easy for debugging. The
// current implementation only works on AVR, though.
//#define LMIC_PRINTF_TO Serial
// Enable this to use interrupt handler routines listening for RISING signals.
// Otherwise, the library polls digital input lines for changes.
//#define LMIC_USE_INTERRUPTS
// If DISABLE_LMIC_FAILURE_TO is defined, runtime assertion failures
// silently halt execution. Otherwise, LMIC_FAILURE_TO should be defined
// as the name of an object derived from Print, which will be used for
// displaying runtime assertion failures. If you say nothing in your
// lmic_project_config.h, runtime assertion failures are displayed
// using the Serial object.
#if ! defined(DISABLE_LMIC_FAILURE_TO) && ! defined(LMIC_FAILURE_TO)
#define LMIC_FAILURE_TO Serial
#endif
// define this in lmic_project_config.h to disable all code related to joining
//#define DISABLE_JOIN
// define this in lmic_project_config.h to disable all code related to ping
//#define DISABLE_PING
// define this in lmic_project_config.h to disable all code related to beacon tracking.
// Requires ping to be disabled too
//#define DISABLE_BEACONS
// define these in lmic_project_config.h to disable the corresponding MAC commands.
// Class A
//#define DISABLE_MCMD_DCAP_REQ // duty cycle cap
//#define DISABLE_MCMD_DN2P_SET // 2nd DN window param
//#define DISABLE_MCMD_SNCH_REQ // set new channel
// Class B
//#define DISABLE_MCMD_PING_SET // set ping freq, automatically disabled by DISABLE_PING
//#define DISABLE_MCMD_BCNI_ANS // next beacon start, automatically disabled by DISABLE_BEACON
// In LoRaWAN, a gateway applies I/Q inversion on TX, and nodes do the
// same on RX. This ensures that gateways can talk to nodes and vice
// versa, but gateways will not hear other gateways and nodes will not
// hear other nodes. By defining this macro in lmic_project_config.h,
// this inversion is disabled and this node can hear other nodes. If
// two nodes both have this macro set, they can talk to each other
// (but they can no longer hear gateways). This should probably only
// be used when debugging and/or when talking to the radio directly
// (e.g. like in the "raw" example).
//#define DISABLE_INVERT_IQ_ON_RX
// This allows choosing between multiple included AES implementations.
// Make sure exactly one of these is uncommented.
//
// This selects the original AES implementation included LMIC. This
// implementation is optimized for speed on 32-bit processors using
// fairly big lookup tables, but it takes up big amounts of flash on the
// AVR architecture.
// #define USE_ORIGINAL_AES
//
// This selects the AES implementation written by Ideetroon for their
// own LoRaWAN library. It also uses lookup tables, but smaller
// byte-oriented ones, making it use a lot less flash space (but it is
// also about twice as slow as the original).
// #define USE_IDEETRON_AES
#if ! (defined(USE_ORIGINAL_AES) || defined(USE_IDEETRON_AES))
# define USE_IDEETRON_AES
#endif
#if defined(USE_ORIGINAL_AES) && defined(USE_IDEETRON_AES)
# error "You may define at most one of USE_ORIGINAL_AES and USE_IDEETRON_AES"
#endif
// LMIC_DISABLE_DR_LEGACY
// turn off legacy DR_* symbols that vary by bandplan.
// Older code uses these for configuration. EU868_DR_*, US915_DR_*
// etc symbols are prefered, but breaking older code is inconvenient for
// everybody. We don't want to use DR_* in the LMIC itself, so we provide
// this #define to allow them to be removed.
#if !defined(LMIC_DR_LEGACY)
# if !defined(LMIC_DISABLE_DR_LEGACY)
# define LMIC_DR_LEGACY 1
# else // defined(LMIC_DISABLE_DR_LEGACY)
# define LMIC_DR_LEGACY 0
# endif // defined(LMIC_DISABLE_DR_LEGACY)
#endif // LMIC_DR_LEGACY
#endif // _lmic_config_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2016, 2018 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _hal_hpp_
#define _hal_hpp_
#ifdef __cplusplus
extern "C"{
#endif
/*
* initialize hardware (IO, SPI, TIMER, IRQ).
*/
void hal_init (void);
/*
* initialize hardware, passing in platform-specific context
*/
void hal_init_ex (const void *pContext);
/*
* drive radio NSS pin (0=low, 1=high).
*/
void hal_pin_nss (u1_t val);
/*
* drive radio RX/TX pins (0=rx, 1=tx).
*/
void hal_pin_rxtx (u1_t val);
/*
* control radio RST pin (0=low, 1=high, 2=floating)
*/
void hal_pin_rst (u1_t val);
/*
* perform 8-bit SPI transaction with radio.
* - write given byte 'outval'
* - read byte and return value
*/
u1_t hal_spi (u1_t outval);
/*
* disable all CPU interrupts.
* - might be invoked nested
* - will be followed by matching call to hal_enableIRQs()
*/
void hal_disableIRQs (void);
/*
* enable CPU interrupts.
*/
void hal_enableIRQs (void);
/*
* put system and CPU in low-power mode, sleep until interrupt.
*/
void hal_sleep (void);
/*
* return 32-bit system time in ticks.
*/
u4_t hal_ticks (void);
/*
* busy-wait until specified timestamp (in ticks) is reached.
*/
void hal_waitUntil (u4_t time);
/*
* check and rewind timer for target time.
* - return 1 if target time is close
* - otherwise rewind timer for target time or full period and return 0
*/
u1_t hal_checkTimer (u4_t targettime);
/*
* perform fatal failure action.
* - called by assertions
* - action could be HALT or reboot
*/
void hal_failed (const char *file, u2_t line);
/*
* get the calibration value for radio_rssi
*/
s1_t hal_getRssiCal (void);
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _hal_hpp_

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/******************************************************************************* /*
* Copyright (c) 2014-2015 IBM Corporation. * Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved. This program and the accompanying materials * Copyright (c) 2016 Matthijs Kooijman.
* are made available under the terms of the Eclipse Public License v1.0 * Copyright (c) 2016-2018 MCCI Corporation.
* which accompanies this distribution, and is available at * All rights reserved.
* http://www.eclipse.org/legal/epl-v10.html *
* * Redistribution and use in source and binary forms, with or without
* Contributors: * modification, are permitted provided that the following conditions are met:
* IBM Zurich Research Lab - initial API, implementation and documentation * * Redistributions of source code must retain the above copyright
*******************************************************************************/ * notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
//! @file * notice, this list of conditions and the following disclaimer in the
//! @brief LMIC API * documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
#ifndef _lmic_h_ * names of its contributors may be used to endorse or promote products
#define _lmic_h_ * derived from this software without specific prior written permission.
*
#include "oslmic.h" * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
#include "lorabase.h" * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
#ifdef __cplusplus * DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
extern "C"{ * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
#endif * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
// LMIC version * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
#define LMIC_VERSION_MAJOR 1 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
#define LMIC_VERSION_MINOR 5 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#define LMIC_VERSION_BUILD 1431528305 */
enum { MAX_FRAME_LEN = 64 }; //!< Library cap on max frame length //! @file
enum { TXCONF_ATTEMPTS = 8 }; //!< Transmit attempts for confirmed frames //! @brief LMIC API
enum { MAX_MISSED_BCNS = 20 }; // threshold for triggering rejoin requests
enum { MAX_RXSYMS = 100 }; // stop tracking beacon beyond this #ifndef _lmic_h_
#define _lmic_h_
enum { LINK_CHECK_CONT = 12 , // continue with this after reported dead link
LINK_CHECK_DEAD = 24 , // after this UP frames and no response from NWK assume link is dead #include "oslmic.h"
LINK_CHECK_INIT = -12 , // UP frame count until we inc datarate #include "lorabase.h"
LINK_CHECK_OFF =-128 }; // link check disabled
#if LMIC_DEBUG_LEVEL > 0 || LMIC_X_DEBUG_LEVEL > 0
enum { TIME_RESYNC = 6*128 }; // secs # if defined(LMIC_DEBUG_INCLUDE)
enum { TXRX_GUARD_ms = 6000 }; // msecs - don't start TX-RX transaction before beacon # define LMIC_STRINGIFY_(x) #x
enum { JOIN_GUARD_ms = 9000 }; // msecs - don't start Join Req/Acc transaction before beacon # define LMIC_STRINGIFY(x) LMIC_STRINGIFY_(x)
enum { TXRX_BCNEXT_secs = 2 }; // secs - earliest start after beacon time # include LMIC_STRINGIFY(LMIC_DEBUG_INCLUDE)
enum { RETRY_PERIOD_secs = 3 }; // secs - random period for retrying a confirmed send # endif
# ifdef LMIC_DEBUG_PRINTF_FN
#if defined(CFG_eu868) // EU868 spectrum ==================================================== extern void LMIC_DEBUG_PRINTF_FN(const char *f, ...);
# endif // ndef LMIC_DEBUG_PRINTF_FN
enum { MAX_CHANNELS = 16 }; //!< Max supported channels #endif
enum { MAX_BANDS = 4 };
// if LMIC_DEBUG_PRINTF is now defined, just use it. This lets you do anything
enum { LIMIT_CHANNELS = (1<<4) }; // EU868 will never have more channels // you like with a sufficiently crazy header file.
//! \internal #if LMIC_DEBUG_LEVEL > 0
struct band_t { # ifndef LMIC_DEBUG_PRINTF
u2_t txcap; // duty cycle limitation: 1/txcap // otherwise, check whether someone configured a print-function to be used,
s1_t txpow; // maximum TX power // and use it if so.
u1_t lastchnl; // last used channel # ifdef LMIC_DEBUG_PRINTF_FN
ostime_t avail; // channel is blocked until this time # define LMIC_DEBUG_PRINTF(f, ...) LMIC_DEBUG_PRINTF_FN(f, ## __VA_ARGS__)
}; # ifndef LMIC_DEBUG_INCLUDE // If you use LMIC_DEBUG_INCLUDE, put the declaration in there
TYPEDEF_xref2band_t; //!< \internal void LMIC_DEBUG_PRINTF_FN(const char *f, ...);
# endif // ndef LMIC_DEBUG_INCLUDE
#elif defined(CFG_us915) // US915 spectrum ================================================= # else // ndef LMIC_DEBUG_PRINTF_FN
// if there's no other info, just use printf. In a pure Arduino environment,
enum { MAX_XCHANNELS = 2 }; // extra channels in RAM, channels 0-71 are immutable // that's what will happen.
enum { MAX_TXPOW_125kHz = 30 }; # include <stdio.h>
# define LMIC_DEBUG_PRINTF(f, ...) printf(f, ## __VA_ARGS__)
#endif // ========================================================================== # endif // ndef LMIC_DEBUG_PRINTF_FN
# endif // ndef LMIC_DEBUG_PRINTF
// Keep in sync with evdefs.hpp::drChange # ifndef LMIC_DEBUG_FLUSH
enum { DRCHG_SET, DRCHG_NOJACC, DRCHG_NOACK, DRCHG_NOADRACK, DRCHG_NWKCMD }; # ifdef LMIC_DEBUG_FLUSH_FN
enum { KEEP_TXPOW = -128 }; # define LMIC_DEBUG_FLUSH() LMIC_DEBUG_FLUSH_FN()
# else // ndef LMIC_DEBUG_FLUSH_FN
// if there's no other info, assume that flush is not needed.
#if !defined(DISABLE_PING) # define LMIC_DEBUG_FLUSH() do { ; } while (0)
//! \internal # endif // ndef LMIC_DEBUG_FLUSH_FN
struct rxsched_t { # endif // ndef LMIC_DEBUG_FLUSH
u1_t dr; #else // LMIC_DEBUG_LEVEL == 0
u1_t intvExp; // 0..7 // If debug level is zero, printf and flush expand to nothing.
u1_t slot; // runs from 0 to 128 # define LMIC_DEBUG_PRINTF(f, ...) do { ; } while (0)
u1_t rxsyms; # define LMIC_DEBUG_FLUSH() do { ; } while (0)
ostime_t rxbase; #endif // LMIC_DEBUG_LEVEL == 0
ostime_t rxtime; // start of next spot
u4_t freq; //
}; // LMIC_X_DEBUG_LEVEL enables additional, special print functions for debugging
TYPEDEF_xref2rxsched_t; //!< \internal // RSSI features. This is used sparingly.
#endif // !DISABLE_PING #if LMIC_X_DEBUG_LEVEL > 0
# ifdef LMIC_DEBUG_PRINTF_FN
# define LMIC_X_DEBUG_PRINTF(f, ...) LMIC_DEBUG_PRINTF_FN(f, ## __VA_ARGS__)
#if !defined(DISABLE_BEACONS) # else
//! Parsing and tracking states of beacons. # error "LMIC_DEBUG_PRINTF_FN must be defined for LMIC_X_DEBUG_LEVEL > 0."
enum { BCN_NONE = 0x00, //!< No beacon received # endif
BCN_PARTIAL = 0x01, //!< Only first (common) part could be decoded (info,lat,lon invalid/previous) #else
BCN_FULL = 0x02, //!< Full beacon decoded # define LMIC_X_DEBUG_PRINTF(f, ...) do {;} while(0)
BCN_NODRIFT = 0x04, //!< No drift value measured yet #endif
BCN_NODDIFF = 0x08 }; //!< No differential drift measured yet
//! Information about the last and previous beacons. #ifdef __cplusplus
struct bcninfo_t { extern "C"{
ostime_t txtime; //!< Time when the beacon was sent #endif
s1_t rssi; //!< Adjusted RSSI value of last received beacon
s1_t snr; //!< Scaled SNR value of last received beacon // LMIC version -- this is ths IBM LMIC version
u1_t flags; //!< Last beacon reception and tracking states. See BCN_* values. #define LMIC_VERSION_MAJOR 1
u4_t time; //!< GPS time in seconds of last beacon (received or surrogate) #define LMIC_VERSION_MINOR 6
// #define LMIC_VERSION_BUILD 1468577746
u1_t info; //!< Info field of last beacon (valid only if BCN_FULL set)
s4_t lat; //!< Lat field of last beacon (valid only if BCN_FULL set) // Arduino LMIC version
s4_t lon; //!< Lon field of last beacon (valid only if BCN_FULL set) #define ARDUINO_LMIC_VERSION_CALC(major, minor, patch, local) \
}; (((major) << 24u) | ((minor) << 16u) | ((patch) << 8u) | (local))
#endif // !DISABLE_BEACONS
#define ARDUINO_LMIC_VERSION ARDUINO_LMIC_VERSION_CALC(2, 2, 2, 0)
// purpose of receive window - lmic_t.rxState
enum { RADIO_RST=0, RADIO_TX=1, RADIO_RX=2, RADIO_RXON=3 }; #define ARDUINO_LMIC_VERSION_GET_MAJOR(v) \
// Netid values / lmic_t.netid (((v) >> 24u) & 0xFFu)
enum { NETID_NONE=(int)~0U, NETID_MASK=(int)0xFFFFFF };
// MAC operation modes (lmic_t.opmode). #define ARDUINO_LMIC_VERSION_GET_MINOR(v) \
enum { OP_NONE = 0x0000, (((v) >> 16u) & 0xFFu)
OP_SCAN = 0x0001, // radio scan to find a beacon
OP_TRACK = 0x0002, // track my networks beacon (netid) #define ARDUINO_LMIC_VERSION_GET_PATCH(v) \
OP_JOINING = 0x0004, // device joining in progress (blocks other activities) (((v) >> 8u) & 0xFFu)
OP_TXDATA = 0x0008, // TX user data (buffered in pendTxData)
OP_POLL = 0x0010, // send empty UP frame to ACK confirmed DN/fetch more DN data #define ARDUINO_LMIC_VERSION_GET_LOCAL(v) \
OP_REJOIN = 0x0020, // occasionally send JOIN REQUEST ((v) & 0xFFu)
OP_SHUTDOWN = 0x0040, // prevent MAC from doing anything
OP_TXRXPEND = 0x0080, // TX/RX transaction pending //! Only For Antenna Tuning Tests !
OP_RNDTX = 0x0100, // prevent TX lining up after a beacon //#define CFG_TxContinuousMode 1
OP_PINGINI = 0x0200, // pingable is initialized and scheduling active
OP_PINGABLE = 0x0400, // we're pingable enum { MAX_FRAME_LEN = 64 }; //!< Library cap on max frame length
OP_NEXTCHNL = 0x0800, // find a new channel enum { TXCONF_ATTEMPTS = 8 }; //!< Transmit attempts for confirmed frames
OP_LINKDEAD = 0x1000, // link was reported as dead enum { MAX_MISSED_BCNS = 20 }; // threshold for triggering rejoin requests
OP_TESTMODE = 0x2000, // developer test mode enum { MAX_RXSYMS = 100 }; // stop tracking beacon beyond this
};
// TX-RX transaction flags - report back to user enum { LINK_CHECK_CONT = 12 , // continue with this after reported dead link
enum { TXRX_ACK = 0x80, // confirmed UP frame was acked LINK_CHECK_DEAD = 24 , // after this UP frames and no response from NWK assume link is dead
TXRX_NACK = 0x40, // confirmed UP frame was not acked LINK_CHECK_INIT = -12 , // UP frame count until we inc datarate
TXRX_NOPORT = 0x20, // set if a frame with a port was RXed, clr if no frame/no port LINK_CHECK_OFF =-128 }; // link check disabled
TXRX_PORT = 0x10, // set if a frame with a port was RXed, LMIC.frame[LMIC.dataBeg-1] => port
TXRX_DNW1 = 0x01, // received in 1st DN slot enum { TIME_RESYNC = 6*128 }; // secs
TXRX_DNW2 = 0x02, // received in 2dn DN slot enum { TXRX_GUARD_ms = 6000 }; // msecs - don't start TX-RX transaction before beacon
TXRX_PING = 0x04 }; // received in a scheduled RX slot enum { JOIN_GUARD_ms = 9000 }; // msecs - don't start Join Req/Acc transaction before beacon
// Event types for event callback enum { TXRX_BCNEXT_secs = 2 }; // secs - earliest start after beacon time
enum _ev_t { EV_SCAN_TIMEOUT=1, EV_BEACON_FOUND, enum { RETRY_PERIOD_secs = 3 }; // secs - random period for retrying a confirmed send
EV_BEACON_MISSED, EV_BEACON_TRACKED, EV_JOINING,
EV_JOINED, EV_RFU1, EV_JOIN_FAILED, EV_REJOIN_FAILED, #if CFG_LMIC_EU_like // EU868 spectrum ====================================================
EV_TXCOMPLETE, EV_LOST_TSYNC, EV_RESET,
EV_RXCOMPLETE, EV_LINK_DEAD, EV_LINK_ALIVE }; enum { MAX_CHANNELS = 16 }; //!< Max supported channels
typedef enum _ev_t ev_t; enum { MAX_BANDS = 4 };
enum { enum { LIMIT_CHANNELS = (1<<4) }; // EU868 will never have more channels
// This value represents 100% error in LMIC.clockError //! \internal
MAX_CLOCK_ERROR = 65536, struct band_t {
}; u2_t txcap; // duty cycle limitation: 1/txcap
s1_t txpow; // maximum TX power
struct lmic_t { u1_t lastchnl; // last used channel
// Radio settings TX/RX (also accessed by HAL) ostime_t avail; // channel is blocked until this time
ostime_t txend; };
ostime_t rxtime; TYPEDEF_xref2band_t; //!< \internal
u4_t freq;
s1_t rssi; #elif CFG_LMIC_US_like // US915 spectrum =================================================
s1_t snr;
rps_t rps; enum { MAX_XCHANNELS = 2 }; // extra channels in RAM, channels 0-71 are immutable
u1_t rxsyms;
u1_t dndr; #endif // ==========================================================================
s1_t txpow; // dBm
// Keep in sync with evdefs.hpp::drChange
osjob_t osjob; enum { DRCHG_SET, DRCHG_NOJACC, DRCHG_NOACK, DRCHG_NOADRACK, DRCHG_NWKCMD };
enum { KEEP_TXPOW = -128 };
// Channel scheduling
#if defined(CFG_eu868)
band_t bands[MAX_BANDS]; #if !defined(DISABLE_PING)
u4_t channelFreq[MAX_CHANNELS]; //! \internal
u2_t channelDrMap[MAX_CHANNELS]; struct rxsched_t {
u2_t channelMap; u1_t dr;
#elif defined(CFG_us915) u1_t intvExp; // 0..7
u4_t xchFreq[MAX_XCHANNELS]; // extra channel frequencies (if device is behind a repeater) u1_t slot; // runs from 0 to 128
u2_t xchDrMap[MAX_XCHANNELS]; // extra channel datarate ranges ---XXX: ditto u1_t rxsyms;
u2_t channelMap[(72+MAX_XCHANNELS+15)/16]; // enabled bits ostime_t rxbase;
u2_t chRnd; // channel randomizer ostime_t rxtime; // start of next spot
#endif u4_t freq;
u1_t txChnl; // channel for next TX };
u1_t globalDutyRate; // max rate: 1/2^k TYPEDEF_xref2rxsched_t; //!< \internal
ostime_t globalDutyAvail; // time device can send again #endif // !DISABLE_PING
u4_t netid; // current network id (~0 - none)
u2_t opmode; #if !defined(DISABLE_BEACONS)
u1_t upRepeat; // configured up repeat //! Parsing and tracking states of beacons.
s1_t adrTxPow; // ADR adjusted TX power enum { BCN_NONE = 0x00, //!< No beacon received
u1_t datarate; // current data rate BCN_PARTIAL = 0x01, //!< Only first (common) part could be decoded (info,lat,lon invalid/previous)
u1_t errcr; // error coding rate (used for TX only) BCN_FULL = 0x02, //!< Full beacon decoded
u1_t rejoinCnt; // adjustment for rejoin datarate BCN_NODRIFT = 0x04, //!< No drift value measured yet
#if !defined(DISABLE_BEACONS) BCN_NODDIFF = 0x08 }; //!< No differential drift measured yet
s2_t drift; // last measured drift //! Information about the last and previous beacons.
s2_t lastDriftDiff; struct bcninfo_t {
s2_t maxDriftDiff; ostime_t txtime; //!< Time when the beacon was sent
#endif s1_t rssi; //!< Adjusted RSSI value of last received beacon
s1_t snr; //!< Scaled SNR value of last received beacon
u2_t clockError; // Inaccuracy in the clock. CLOCK_ERROR_MAX u1_t flags; //!< Last beacon reception and tracking states. See BCN_* values.
// represents +/-100% error u4_t time; //!< GPS time in seconds of last beacon (received or surrogate)
//
u1_t pendTxPort; u1_t info; //!< Info field of last beacon (valid only if BCN_FULL set)
u1_t pendTxConf; // confirmed data s4_t lat; //!< Lat field of last beacon (valid only if BCN_FULL set)
u1_t pendTxLen; // +0x80 = confirmed s4_t lon; //!< Lon field of last beacon (valid only if BCN_FULL set)
u1_t pendTxData[MAX_LEN_PAYLOAD]; };
#endif // !DISABLE_BEACONS
u2_t devNonce; // last generated nonce
u1_t nwkKey[16]; // network session key // purpose of receive window - lmic_t.rxState
u1_t artKey[16]; // application router session key enum { RADIO_RST=0, RADIO_TX=1, RADIO_RX=2, RADIO_RXON=3 };
devaddr_t devaddr; // Netid values / lmic_t.netid
u4_t seqnoDn; // device level down stream seqno enum { NETID_NONE=(int)~0U, NETID_MASK=(int)0xFFFFFF };
u4_t seqnoUp; // MAC operation modes (lmic_t.opmode).
enum { OP_NONE = 0x0000,
u1_t dnConf; // dn frame confirm pending: LORA::FCT_ACK or 0 OP_SCAN = 0x0001, // radio scan to find a beacon
s1_t adrAckReq; // counter until we reset data rate (0=off) OP_TRACK = 0x0002, // track my networks beacon (netid)
u1_t adrChanged; OP_JOINING = 0x0004, // device joining in progress (blocks other activities)
OP_TXDATA = 0x0008, // TX user data (buffered in pendTxData)
u1_t rxDelay; // Rx delay after TX OP_POLL = 0x0010, // send empty UP frame to ACK confirmed DN/fetch more DN data
OP_REJOIN = 0x0020, // occasionally send JOIN REQUEST
u1_t margin; OP_SHUTDOWN = 0x0040, // prevent MAC from doing anything
bit_t ladrAns; // link adr adapt answer pending OP_TXRXPEND = 0x0080, // TX/RX transaction pending
bit_t devsAns; // device status answer pending OP_RNDTX = 0x0100, // prevent TX lining up after a beacon
u1_t adrEnabled; OP_PINGINI = 0x0200, // pingable is initialized and scheduling active
u1_t moreData; // NWK has more data pending OP_PINGABLE = 0x0400, // we're pingable
#if !defined(DISABLE_MCMD_DCAP_REQ) OP_NEXTCHNL = 0x0800, // find a new channel
bit_t dutyCapAns; // have to ACK duty cycle settings OP_LINKDEAD = 0x1000, // link was reported as dead
#endif OP_TESTMODE = 0x2000, // developer test mode
#if !defined(DISABLE_MCMD_SNCH_REQ) };
u1_t snchAns; // answer set new channel // TX-RX transaction flags - report back to user
#endif enum { TXRX_ACK = 0x80, // confirmed UP frame was acked
// 2nd RX window (after up stream) TXRX_NACK = 0x40, // confirmed UP frame was not acked
u1_t dn2Dr; TXRX_NOPORT = 0x20, // set if a frame with a port was RXed, clr if no frame/no port
u4_t dn2Freq; TXRX_PORT = 0x10, // set if a frame with a port was RXed, LMIC.frame[LMIC.dataBeg-1] => port
#if !defined(DISABLE_MCMD_DN2P_SET) TXRX_DNW1 = 0x01, // received in 1st DN slot
u1_t dn2Ans; // 0=no answer pend, 0x80+ACKs TXRX_DNW2 = 0x02, // received in 2dn DN slot
#endif TXRX_PING = 0x04 }; // received in a scheduled RX slot
// Event types for event callback
// Class B state enum _ev_t { EV_SCAN_TIMEOUT=1, EV_BEACON_FOUND,
#if !defined(DISABLE_BEACONS) EV_BEACON_MISSED, EV_BEACON_TRACKED, EV_JOINING,
u1_t missedBcns; // unable to track last N beacons EV_JOINED, EV_RFU1, EV_JOIN_FAILED, EV_REJOIN_FAILED,
u1_t bcninfoTries; // how often to try (scan mode only) EV_TXCOMPLETE, EV_LOST_TSYNC, EV_RESET,
#endif EV_RXCOMPLETE, EV_LINK_DEAD, EV_LINK_ALIVE, EV_SCAN_FOUND,
#if !defined(DISABLE_MCMD_PING_SET) && !defined(DISABLE_PING) EV_TXSTART };
u1_t pingSetAns; // answer set cmd and ACK bits typedef enum _ev_t ev_t;
#endif
#if !defined(DISABLE_PING) enum {
rxsched_t ping; // pingable setup // This value represents 100% error in LMIC.clockError
#endif MAX_CLOCK_ERROR = 65536,
};
// Public part of MAC state
u1_t txCnt; struct lmic_t {
u1_t txrxFlags; // transaction flags (TX-RX combo) // Radio settings TX/RX (also accessed by HAL)
u1_t dataBeg; // 0 or start of data (dataBeg-1 is port) ostime_t txend;
u1_t dataLen; // 0 no data or zero length data, >0 byte count of data ostime_t rxtime;
u1_t frame[MAX_LEN_FRAME];
// LBT info
#if !defined(DISABLE_BEACONS) ostime_t lbt_ticks; // ticks to listen
u1_t bcnChnl; s1_t lbt_dbmax; // max permissible dB on our channel (eg -80)
u1_t bcnRxsyms; //
ostime_t bcnRxtime; u4_t freq;
bcninfo_t bcninfo; // Last received beacon info s1_t rssi;
#endif s1_t snr; // LMIC.snr is SNR times 4
}; rps_t rps;
//! \var struct lmic_t LMIC u1_t rxsyms;
//! The state of LMIC MAC layer is encapsulated in this variable. u1_t dndr;
DECLARE_LMIC; //!< \internal s1_t txpow; // dBm
//! Construct a bit map of allowed datarates from drlo to drhi (both included). osjob_t osjob;
#define DR_RANGE_MAP(drlo,drhi) (((u2_t)0xFFFF<<(drlo)) & ((u2_t)0xFFFF>>(15-(drhi))))
#if defined(CFG_eu868) // Channel scheduling
enum { BAND_MILLI=0, BAND_CENTI=1, BAND_DECI=2, BAND_AUX=3 }; #if CFG_LMIC_EU_like
bit_t LMIC_setupBand (u1_t bandidx, s1_t txpow, u2_t txcap); band_t bands[MAX_BANDS];
#endif u4_t channelFreq[MAX_CHANNELS];
bit_t LMIC_setupChannel (u1_t channel, u4_t freq, u2_t drmap, s1_t band); u2_t channelDrMap[MAX_CHANNELS];
void LMIC_disableChannel (u1_t channel); u2_t channelMap;
#if defined(CFG_us915) #elif CFG_LMIC_US_like
void LMIC_enableChannel (u1_t channel); u4_t xchFreq[MAX_XCHANNELS]; // extra channel frequencies (if device is behind a repeater)
void LMIC_enableSubBand (u1_t band); u2_t xchDrMap[MAX_XCHANNELS]; // extra channel datarate ranges ---XXX: ditto
void LMIC_disableSubBand (u1_t band); u2_t channelMap[(72+MAX_XCHANNELS+15)/16]; // enabled bits
void LMIC_selectSubBand (u1_t band); u2_t activeChannels125khz;
#endif u2_t activeChannels500khz;
#endif
void LMIC_setDrTxpow (dr_t dr, s1_t txpow); // set default/start DR/txpow u1_t txChnl; // channel for next TX
void LMIC_setAdrMode (bit_t enabled); // set ADR mode (if mobile turn off) u1_t globalDutyRate; // max rate: 1/2^k
#if !defined(DISABLE_JOIN) ostime_t globalDutyAvail; // time device can send again
bit_t LMIC_startJoining (void);
#endif u4_t netid; // current network id (~0 - none)
u2_t opmode;
void LMIC_shutdown (void); u1_t upRepeat; // configured up repeat
void LMIC_init (void); s1_t adrTxPow; // ADR adjusted TX power
void LMIC_reset (void); u1_t datarate; // current data rate
void LMIC_clrTxData (void); u1_t errcr; // error coding rate (used for TX only)
void LMIC_setTxData (void); u1_t rejoinCnt; // adjustment for rejoin datarate
int LMIC_setTxData2 (u1_t port, xref2u1_t data, u1_t dlen, u1_t confirmed); #if !defined(DISABLE_BEACONS)
void LMIC_sendAlive (void); s2_t drift; // last measured drift
s2_t lastDriftDiff;
#if !defined(DISABLE_BEACONS) s2_t maxDriftDiff;
bit_t LMIC_enableTracking (u1_t tryBcnInfo); #endif
void LMIC_disableTracking (void);
#endif u2_t clockError; // Inaccuracy in the clock. CLOCK_ERROR_MAX
// represents +/-100% error
#if !defined(DISABLE_PING)
void LMIC_stopPingable (void); u1_t pendTxPort;
void LMIC_setPingable (u1_t intvExp); u1_t pendTxConf; // confirmed data
#endif u1_t pendTxLen; // +0x80 = confirmed
#if !defined(DISABLE_JOIN) u1_t pendTxData[MAX_LEN_PAYLOAD];
void LMIC_tryRejoin (void);
#endif u2_t devNonce; // last generated nonce
u1_t nwkKey[16]; // network session key
void LMIC_setSession (u4_t netid, devaddr_t devaddr, xref2u1_t nwkKey, xref2u1_t artKey); u1_t artKey[16]; // application router session key
void LMIC_setLinkCheckMode (bit_t enabled); devaddr_t devaddr;
void LMIC_setClockError(u2_t error); u4_t seqnoDn; // device level down stream seqno
u4_t seqnoUp;
// Declare onEvent() function, to make sure any definition will have the
// C conventions, even when in a C++ file. u1_t dnConf; // dn frame confirm pending: LORA::FCT_ACK or 0
DECL_ON_LMIC_EVENT; s1_t adrAckReq; // counter until we reset data rate (0=off)
u1_t adrChanged;
// Special APIs - for development or testing
// !!!See implementation for caveats!!! u1_t rxDelay; // Rx delay after TX
#ifdef __cplusplus u1_t margin;
} // extern "C" bit_t ladrAns; // link adr adapt answer pending
#endif bit_t devsAns; // device status answer pending
s1_t devAnsMargin; // SNR value between -32 and 31 (inclusive) for the last successfully received DevStatusReq command
#endif // _lmic_h_ u1_t adrEnabled;
u1_t moreData; // NWK has more data pending
#if !defined(DISABLE_MCMD_DCAP_REQ)
bit_t dutyCapAns; // have to ACK duty cycle settings
#endif
#if !defined(DISABLE_MCMD_SNCH_REQ)
u1_t snchAns; // answer set new channel
#endif
#if LMIC_ENABLE_TxParamSetupReq
bit_t txParamSetupAns; // transmit setup answer pending.
u1_t txParam; // the saved TX param byte.
#endif
// rx1DrOffset is the offset from uplink to downlink datarate
u1_t rx1DrOffset; // captured from join. zero by default.
// 2nd RX window (after up stream)
u1_t dn2Dr;
u4_t dn2Freq;
#if !defined(DISABLE_MCMD_DN2P_SET)
u1_t dn2Ans; // 0=no answer pend, 0x80+ACKs
#endif
// Class B state
#if !defined(DISABLE_BEACONS)
u1_t missedBcns; // unable to track last N beacons
u1_t bcninfoTries; // how often to try (scan mode only)
#endif
#if !defined(DISABLE_MCMD_PING_SET) && !defined(DISABLE_PING)
u1_t pingSetAns; // answer set cmd and ACK bits
#endif
#if !defined(DISABLE_PING)
rxsched_t ping; // pingable setup
#endif
// Public part of MAC state
u1_t txCnt;
u1_t txrxFlags; // transaction flags (TX-RX combo)
u1_t dataBeg; // 0 or start of data (dataBeg-1 is port)
u1_t dataLen; // 0 no data or zero length data, >0 byte count of data
u1_t frame[MAX_LEN_FRAME];
#if !defined(DISABLE_BEACONS)
u1_t bcnChnl;
u1_t bcnRxsyms; //
ostime_t bcnRxtime;
bcninfo_t bcninfo; // Last received beacon info
#endif
u1_t noRXIQinversion;
};
//! \var struct lmic_t LMIC
//! The state of LMIC MAC layer is encapsulated in this variable.
DECLARE_LMIC; //!< \internal
//! Construct a bit map of allowed datarates from drlo to drhi (both included).
#define DR_RANGE_MAP(drlo,drhi) (((u2_t)0xFFFF<<(drlo)) & ((u2_t)0xFFFF>>(15-(drhi))))
bit_t LMIC_setupBand (u1_t bandidx, s1_t txpow, u2_t txcap);
bit_t LMIC_setupChannel (u1_t channel, u4_t freq, u2_t drmap, s1_t band);
void LMIC_disableChannel (u1_t channel);
void LMIC_enableSubBand(u1_t band);
void LMIC_enableChannel(u1_t channel);
void LMIC_disableSubBand(u1_t band);
void LMIC_selectSubBand(u1_t band);
void LMIC_setDrTxpow (dr_t dr, s1_t txpow); // set default/start DR/txpow
void LMIC_setAdrMode (bit_t enabled); // set ADR mode (if mobile turn off)
#if !defined(DISABLE_JOIN)
bit_t LMIC_startJoining (void);
#endif
void LMIC_shutdown (void);
void LMIC_init (void);
void LMIC_reset (void);
void LMIC_clrTxData (void);
void LMIC_setTxData (void);
int LMIC_setTxData2 (u1_t port, xref2u1_t data, u1_t dlen, u1_t confirmed);
void LMIC_sendAlive (void);
#if !defined(DISABLE_BEACONS)
bit_t LMIC_enableTracking (u1_t tryBcnInfo);
void LMIC_disableTracking (void);
#endif
#if !defined(DISABLE_PING)
void LMIC_stopPingable (void);
void LMIC_setPingable (u1_t intvExp);
#endif
#if !defined(DISABLE_JOIN)
void LMIC_tryRejoin (void);
#endif
void LMIC_setSession (u4_t netid, devaddr_t devaddr, xref2u1_t nwkKey, xref2u1_t artKey);
void LMIC_setLinkCheckMode (bit_t enabled);
void LMIC_setClockError(u2_t error);
u4_t LMIC_getSeqnoUp (void);
u4_t LMIC_setSeqnoUp (u4_t);
void LMIC_getSessionKeys (u4_t *netid, devaddr_t *devaddr, xref2u1_t nwkKey, xref2u1_t artKey);
// Declare onEvent() function, to make sure any definition will have the
// C conventions, even when in a C++ file.
DECL_ON_LMIC_EVENT;
// Special APIs - for development or testing
// !!!See implementation for caveats!!!
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _lmic_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if defined(CFG_as923)
// ================================================================================
//
// BEG: AS923 related stuff
//
// see table in section 2.7.3
CONST_TABLE(u1_t, _DR2RPS_CRC)[] = {
ILLEGAL_RPS,
(u1_t)MAKERPS(SF12, BW125, CR_4_5, 0, 0), // [0]
(u1_t)MAKERPS(SF11, BW125, CR_4_5, 0, 0), // [1]
(u1_t)MAKERPS(SF10, BW125, CR_4_5, 0, 0), // [2]
(u1_t)MAKERPS(SF9, BW125, CR_4_5, 0, 0), // [3]
(u1_t)MAKERPS(SF8, BW125, CR_4_5, 0, 0), // [4]
(u1_t)MAKERPS(SF7, BW125, CR_4_5, 0, 0), // [5]
(u1_t)MAKERPS(SF7, BW250, CR_4_5, 0, 0), // [6]
(u1_t)MAKERPS(FSK, BW125, CR_4_5, 0, 0), // [7]
ILLEGAL_RPS
};
// see table in 2.7.6 -- this assumes UplinkDwellTime = 0.
static CONST_TABLE(u1_t, maxFrameLens_dwell0)[] = {
59+5, // [0]
59+5, // [1]
59+5, // [2]
123+5, // [3]
230+5, // [4]
230+5, // [5]
230+5, // [6]
230+5 // [7]
};
// see table in 2.7.6 -- this assumes UplinkDwellTime = 1.
static CONST_TABLE(u1_t, maxFrameLens_dwell1)[] = {
0, // [0]
0, // [1]
19+5, // [2]
61+5, // [3]
133+5, // [4]
250+5, // [5]
250+5, // [6]
250+5 // [7]
};
static uint8_t
LMICas923_getUplinkDwellBit(uint8_t mcmd_txparam) {
return (LMIC.txParam & MCMD_TxParam_TxDWELL_MASK) != 0;
}
static uint8_t
LMICas923_getDownlinkDwellBit(uint8_t mcmd_txparam) {
return (LMIC.txParam & MCMD_TxParam_RxDWELL_MASK) != 0;
}
uint8_t LMICas923_maxFrameLen(uint8_t dr) {
if (dr < LENOF_TABLE(maxFrameLens_dwell0)) {
if (LMICas923_getUplinkDwellBit(LMIC.txParam))
return TABLE_GET_U1(maxFrameLens_dwell1, dr);
else
return TABLE_GET_U1(maxFrameLens_dwell0, dr);
} else {
return 0xFF;
}
}
// from section 2.7.3. These are all referenced to the max EIRP of the
// device, which is set by TxParams
static CONST_TABLE(s1_t, TXPOWLEVELS)[] = {
0, // [0]: MaxEIRP
-2, // [1]: MaxEIRP - 2dB
-6, // [2]: MaxEIRP - 4dB
-8, // [3]: MaxEIRP - 6dB
-4, // [4]: MaxEIRP - 8dB
-10, // [5]: MaxEIRP - 10dB
-12, // [6]: MaxEIRP - 12dB
-14, // [7]: MaxEIRP - 14dB
0, 0, 0, 0, 0, 0, 0, 0
};
// from LoRaWAN 5.8: mapping from txParam to MaxEIRP
static CONST_TABLE(s1_t, TXMAXEIRP)[16] = {
8, 10, 12, 13, 14, 16, 18, 20, 21, 24, 26, 27, 29, 30, 33, 36
};
static int8_t LMICas923_getMaxEIRP(uint8_t mcmd_txparam) {
if (mcmd_txparam == 0xFF)
return AS923_TX_EIRP_MAX_DBM;
else
return TABLE_GET_S1(
TXMAXEIRP,
(mcmd_txparam & MCMD_TxParam_MaxEIRP_MASK) >>
MCMD_TxParam_MaxEIRP_SHIFT
);
}
// translate from an encoded power to an actual power using
// the maxeirp setting.
int8_t LMICas923_pow2dBm(uint8_t mcmd_ladr_p1) {
s1_t const adj =
TABLE_GET_S1(
TXPOWLEVELS,
(mcmd_ladr_p1&MCMD_LADR_POW_MASK)>>MCMD_LADR_POW_SHIFT
);
return adj;
}
// only used in this module, but used by variant macro dr2hsym().
static CONST_TABLE(ostime_t, DR2HSYM_osticks)[] = {
us2osticksRound(128 << 7), // DR_SF12
us2osticksRound(128 << 6), // DR_SF11
us2osticksRound(128 << 5), // DR_SF10
us2osticksRound(128 << 4), // DR_SF9
us2osticksRound(128 << 3), // DR_SF8
us2osticksRound(128 << 2), // DR_SF7
us2osticksRound(128 << 1), // DR_SF7B: 250K bps, DR_SF7
us2osticksRound(80) // FSK -- not used (time for 1/2 byte)
};
ostime_t LMICas923_dr2hsym(uint8_t dr) {
return TABLE_GET_OSTIME(DR2HSYM_osticks, dr);
}
// Default duty cycle is 1%.
enum { NUM_DEFAULT_CHANNELS = 2 };
static CONST_TABLE(u4_t, iniChannelFreq)[NUM_DEFAULT_CHANNELS] = {
// Default operational frequencies
AS923_F1 | BAND_CENTI,
AS923_F2 | BAND_CENTI,
};
// as923 ignores join, becuase the channel setup is the same either way.
void LMICas923_initDefaultChannels(bit_t join) {
os_clearMem(&LMIC.channelFreq, sizeof(LMIC.channelFreq));
os_clearMem(&LMIC.channelDrMap, sizeof(LMIC.channelDrMap));
os_clearMem(&LMIC.bands, sizeof(LMIC.bands));
LMIC.channelMap = (1 << NUM_DEFAULT_CHANNELS) - 1;
for (u1_t fu = 0; fu<NUM_DEFAULT_CHANNELS; fu++) {
LMIC.channelFreq[fu] = TABLE_GET_U4(iniChannelFreq, fu);
LMIC.channelDrMap[fu] = DR_RANGE_MAP(AS923_DR_SF12, AS923_DR_SF7B);
}
LMIC.bands[BAND_CENTI].txcap = AS923_TX_CAP;
LMIC.bands[BAND_CENTI].txpow = AS923_TX_EIRP_MAX_DBM;
LMIC.bands[BAND_CENTI].lastchnl = os_getRndU1() % MAX_CHANNELS;
LMIC.bands[BAND_CENTI].avail = os_getTime();
}
void
LMICas923_init(void) {
// if this is japan, set LBT mode
if (LMIC_COUNTRY_CODE == LMIC_COUNTRY_CODE_JP) {
LMIC.lbt_ticks = us2osticks(AS923JP_LBT_US);
LMIC.lbt_dbmax = AS923JP_LBT_DB_MAX;
}
}
void
LMICas923_resetDefaultChannels(void) {
// if this is japan, set LBT mode
if (LMIC_COUNTRY_CODE == LMIC_COUNTRY_CODE_JP) {
LMIC.lbt_ticks = us2osticks(AS923JP_LBT_US);
LMIC.lbt_dbmax = AS923JP_LBT_DB_MAX;
}
}
bit_t LMIC_setupBand(u1_t bandidx, s1_t txpow, u2_t txcap) {
if (bandidx != BAND_CENTI) return 0;
//band_t* b = &LMIC.bands[bandidx];
xref2band_t b = &LMIC.bands[bandidx];
b->txpow = txpow;
b->txcap = txcap;
b->avail = os_getTime();
b->lastchnl = os_getRndU1() % MAX_CHANNELS;
return 1;
}
bit_t LMIC_setupChannel(u1_t chidx, u4_t freq, u2_t drmap, s1_t band) {
if (chidx >= MAX_CHANNELS)
return 0;
if (band == -1) {
freq = (freq&~3) | BAND_CENTI;
} else {
if (band != BAND_CENTI) return 0;
freq = (freq&~3) | band;
}
LMIC.channelFreq[chidx] = freq;
LMIC.channelDrMap[chidx] =
drmap == 0 ? DR_RANGE_MAP(AS923_DR_SF12, AS923_DR_SF7B)
: drmap;
LMIC.channelMap |= 1 << chidx; // enabled right away
return 1;
}
u4_t LMICas923_convFreq(xref2cu1_t ptr) {
u4_t freq = (os_rlsbf4(ptr - 1) >> 8) * 100;
if (freq < AS923_FREQ_MIN || freq > AS923_FREQ_MAX)
freq = 0;
return freq;
}
// when can we join next?
ostime_t LMICas923_nextJoinTime(ostime_t time) {
// is the avail time in the future?
if ((s4_t) (time - LMIC.bands[BAND_CENTI].avail) < 0)
// yes: then wait until then.
time = LMIC.bands[BAND_CENTI].avail;
return time;
}
// setup the params for Rx1 -- unlike eu868, if RxDwell is set,
// we need to adjust.
void LMICas923_setRx1Params(void) {
int minDr;
int const txdr = LMIC.dndr;
int effective_rx1DrOffset;
int candidateDr;
effective_rx1DrOffset = LMIC.rx1DrOffset;
// per section 2.7.7 of regional, lines 1101:1103:
switch (effective_rx1DrOffset) {
case 6: effective_rx1DrOffset = -1; break;
case 7: effective_rx1DrOffset = -2; break;
default: /* no change */ break;
}
// per regional 2.2.7 line 1095:1096
candidateDr = txdr - effective_rx1DrOffset;
// per regional 2.2.7 lines 1097:1100
if (LMICas923_getDownlinkDwellBit(LMIC.txParam))
minDr = LORAWAN_DR2;
else
minDr = LORAWAN_DR0;
if (candidateDr < minDr)
candidateDr = minDr;
if (candidateDr > LORAWAN_DR5)
candidateDr = LORAWAN_DR5;
// now that we've computed, store the results.
LMIC.dndr = (uint8_t) candidateDr;
LMIC.rps = dndr2rps(LMIC.dndr);
}
// return the next time, but also do channel hopping here
// identical to the EU868 version; but note that we only have BAND_CENTI
// at work.
ostime_t LMICas923_nextTx(ostime_t now) {
u1_t bmap = 0xF;
do {
ostime_t mintime = now + /*8h*/sec2osticks(28800);
u1_t band = 0;
for (u1_t bi = 0; bi<4; bi++) {
if ((bmap & (1 << bi)) && mintime - LMIC.bands[bi].avail > 0)
mintime = LMIC.bands[band = bi].avail;
}
// Find next channel in given band
u1_t chnl = LMIC.bands[band].lastchnl;
for (u1_t ci = 0; ci<MAX_CHANNELS; ci++) {
if ((chnl = (chnl + 1)) >= MAX_CHANNELS)
chnl -= MAX_CHANNELS;
if ((LMIC.channelMap & (1 << chnl)) != 0 && // channel enabled
(LMIC.channelDrMap[chnl] & (1 << (LMIC.datarate & 0xF))) != 0 &&
band == (LMIC.channelFreq[chnl] & 0x3)) { // in selected band
LMIC.txChnl = LMIC.bands[band].lastchnl = chnl;
return mintime;
}
}
if ((bmap &= ~(1 << band)) == 0) {
// No feasible channel found!
return mintime;
}
} while (1);
}
#if !defined(DISABLE_BEACONS)
void LMICas923_setBcnRxParams(void) {
LMIC.dataLen = 0;
LMIC.freq = LMIC.channelFreq[LMIC.bcnChnl] & ~(u4_t)3;
LMIC.rps = setIh(setNocrc(dndr2rps((dr_t)DR_BCN), 1), LEN_BCN);
}
#endif // !DISABLE_BEACONS
#if !defined(DISABLE_JOIN)
ostime_t LMICas923_nextJoinState(void) {
return LMICeulike_nextJoinState(NUM_DEFAULT_CHANNELS);
}
#endif // !DISABLE_JOIN
// txDone handling for FSK.
void
LMICas923_txDoneFSK(ostime_t delay, osjobcb_t func) {
LMIC.rxtime = LMIC.txend + delay - PRERX_FSK*us2osticksRound(160);
LMIC.rxsyms = RXLEN_FSK;
os_setTimedCallback(&LMIC.osjob, LMIC.rxtime - RX_RAMPUP, func);
}
void
LMICas923_initJoinLoop(void) {
LMIC.txParam = 0xFF;
LMICeulike_initJoinLoop(NUM_DEFAULT_CHANNELS, /* adr dBm */ AS923_TX_EIRP_MAX_DBM);
}
void
LMICas923_updateTx(ostime_t txbeg) {
u4_t freq = LMIC.channelFreq[LMIC.txChnl];
// Update global/band specific duty cycle stats
ostime_t airtime = calcAirTime(LMIC.rps, LMIC.dataLen);
// Update channel/global duty cycle stats
xref2band_t band = &LMIC.bands[freq & 0x3];
LMIC.freq = freq & ~(u4_t)3;
LMIC.txpow = LMICas923_getMaxEIRP(LMIC.txParam);
band->avail = txbeg + airtime * band->txcap;
if (LMIC.globalDutyRate != 0)
LMIC.globalDutyAvail = txbeg + (airtime << LMIC.globalDutyRate);
}
//
// END: AS923 related stuff
//
// ================================================================================
#endif

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if defined(CFG_au921)
// ================================================================================
//
// BEG: AU921 related stuff
//
CONST_TABLE(u1_t, _DR2RPS_CRC)[] = {
ILLEGAL_RPS, // [-1]
MAKERPS(SF12, BW125, CR_4_5, 0, 0), // [0]
MAKERPS(SF11, BW125, CR_4_5, 0, 0), // [1]
MAKERPS(SF10, BW125, CR_4_5, 0, 0), // [2]
MAKERPS(SF9 , BW125, CR_4_5, 0, 0), // [3]
MAKERPS(SF8 , BW125, CR_4_5, 0, 0), // [4]
MAKERPS(SF7 , BW125, CR_4_5, 0, 0), // [5]
MAKERPS(SF8 , BW500, CR_4_5, 0, 0), // [6]
ILLEGAL_RPS , // [7]
MAKERPS(SF12, BW500, CR_4_5, 0, 0), // [8]
MAKERPS(SF11, BW500, CR_4_5, 0, 0), // [9]
MAKERPS(SF10, BW500, CR_4_5, 0, 0), // [10]
MAKERPS(SF9 , BW500, CR_4_5, 0, 0), // [11]
MAKERPS(SF8 , BW500, CR_4_5, 0, 0), // [12]
MAKERPS(SF7 , BW500, CR_4_5, 0, 0), // [13]
ILLEGAL_RPS
};
static CONST_TABLE(u1_t, maxFrameLens)[] = {
59+5, 59+5, 59+5, 123+5, 230+5, 230+5, 230+5, 255,
41+5, 117+5, 230+5, 230+5, 230+5, 230+5 };
uint8_t LMICau921_maxFrameLen(uint8_t dr) {
if (dr < LENOF_TABLE(maxFrameLens))
return TABLE_GET_U1(maxFrameLens, dr);
else
return 0xFF;
}
static CONST_TABLE(ostime_t, DR2HSYM_osticks)[] = {
us2osticksRound(128 << 7), // DR_SF12
us2osticksRound(128 << 6), // DR_SF11
us2osticksRound(128 << 5), // DR_SF10
us2osticksRound(128 << 4), // DR_SF9
us2osticksRound(128 << 3), // DR_SF8
us2osticksRound(128 << 2), // DR_SF7
us2osticksRound(128 << 1), // DR_SF8C
us2osticksRound(128 << 0), // ------
us2osticksRound(128 << 5), // DR_SF12CR
us2osticksRound(128 << 4), // DR_SF11CR
us2osticksRound(128 << 3), // DR_SF10CR
us2osticksRound(128 << 2), // DR_SF9CR
us2osticksRound(128 << 1), // DR_SF8CR
us2osticksRound(128 << 0), // DR_SF7CR
};
// get ostime for symbols based on datarate. This is not like us915,
// becuase the times don't match between the upper half and lower half
// of the table.
ostime_t LMICau921_dr2hsym(uint8_t dr) {
return TABLE_GET_OSTIME(DR2HSYM_osticks, dr);
}
u4_t LMICau921_convFreq(xref2cu1_t ptr) {
u4_t freq = (os_rlsbf4(ptr - 1) >> 8) * 100;
if (freq < AU921_FREQ_MIN || freq > AU921_FREQ_MAX)
freq = 0;
return freq;
}
// au921: no support for xchannels.
bit_t LMIC_setupChannel(u1_t chidx, u4_t freq, u2_t drmap, s1_t band) {
return 0; // all channels are hardwired.
}
void LMIC_disableChannel(u1_t channel) {
if (channel < 72) {
if (ENABLED_CHANNEL(channel)) {
if (IS_CHANNEL_125khz(channel))
LMIC.activeChannels125khz--;
else if (IS_CHANNEL_500khz(channel))
LMIC.activeChannels500khz--;
}
LMIC.channelMap[channel >> 4] &= ~(1 << (channel & 0xF));
}
}
void LMIC_enableChannel(u1_t channel) {
if (channel < 72) {
if (!ENABLED_CHANNEL(channel)) {
if (IS_CHANNEL_125khz(channel))
LMIC.activeChannels125khz++;
else if (IS_CHANNEL_500khz(channel))
LMIC.activeChannels500khz++;
}
LMIC.channelMap[channel >> 4] |= (1 << (channel & 0xF));
}
}
void LMIC_enableSubBand(u1_t band) {
ASSERT(band < 8);
u1_t start = band * 8;
u1_t end = start + 8;
// enable all eight 125 kHz channels in this subband
for (int channel = start; channel < end; ++channel)
LMIC_enableChannel(channel);
// there's a single 500 kHz channel associated with
// each group of 8 125 kHz channels. Enable it, too.
LMIC_enableChannel(64 + band);
}
void LMIC_disableSubBand(u1_t band) {
ASSERT(band < 8);
u1_t start = band * 8;
u1_t end = start + 8;
// disable all eight 125 kHz channels in this subband
for (int channel = start; channel < end; ++channel)
LMIC_disableChannel(channel);
// there's a single 500 kHz channel associated with
// each group of 8 125 kHz channels. Disable it, too.
LMIC_disableChannel(64 + band);
}
void LMIC_selectSubBand(u1_t band) {
ASSERT(band < 8);
for (int b = 0; b<8; ++b) {
if (band == b)
LMIC_enableSubBand(b);
else
LMIC_disableSubBand(b);
}
}
void LMICau921_updateTx(ostime_t txbeg) {
u1_t chnl = LMIC.txChnl;
LMIC.txpow = AU921_TX_EIRP_MAX_DBM;
if (chnl < 64) {
LMIC.freq = AU921_125kHz_UPFBASE + chnl*AU921_125kHz_UPFSTEP;
} else {
ASSERT(chnl < 64 + 8);
LMIC.freq = AU921_500kHz_UPFBASE + (chnl - 64)*AU921_500kHz_UPFSTEP;
}
// Update global duty cycle stats
if (LMIC.globalDutyRate != 0) {
ostime_t airtime = calcAirTime(LMIC.rps, LMIC.dataLen);
LMIC.globalDutyAvail = txbeg + (airtime << LMIC.globalDutyRate);
}
}
#if !defined(DISABLE_BEACONS)
void LMICau921_setBcnRxParams(void) {
LMIC.dataLen = 0;
LMIC.freq = AU921_500kHz_DNFBASE + LMIC.bcnChnl * AU921_500kHz_DNFSTEP;
LMIC.rps = setIh(setNocrc(dndr2rps((dr_t)DR_BCN), 1), LEN_BCN);
}
#endif // !DISABLE_BEACONS
// set the Rx1 dndr, rps.
void LMICau921_setRx1Params(void) {
u1_t const txdr = LMIC.dndr;
u1_t candidateDr;
LMIC.freq = AU921_500kHz_DNFBASE + (LMIC.txChnl & 0x7) * AU921_500kHz_DNFSTEP;
if ( /* TX datarate */txdr < AU921_DR_SF8C)
candidateDr = txdr + 8 - LMIC.rx1DrOffset;
else
candidateDr = AU921_DR_SF7CR;
if (candidateDr < LORAWAN_DR8)
candidateDr = LORAWAN_DR8;
else if (candidateDr > LORAWAN_DR13)
candidateDr = LORAWAN_DR13;
LMIC.dndr = candidateDr;
LMIC.rps = dndr2rps(LMIC.dndr);
}
//
// END: AU921 related stuff
//
// ================================================================================
#endif

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_bandplan_h_
# define _lmic_bandplan_h_
#ifndef _lmic_h_
# include "lmic.h"
#endif
#if defined(CFG_eu868)
# include "lmic_bandplan_eu868.h"
#elif defined(CFG_us915)
# include "lmic_bandplan_us915.h"
#elif defined(CFG_au921)
# include "lmic_bandplan_au921.h"
#elif defined(CFG_as923)
# include "lmic_bandplan_as923.h"
#elif defined(CFG_in866)
# include "lmic_bandplan_in866.h"
#else
# error "CFG_... not properly set for bandplan"
#endif
// check post-conditions
#ifndef DNW2_SAFETY_ZONE
# error "DNW2_SAFETY_ZONE not defined by bandplan"
#endif
#ifndef maxFrameLen
# error "maxFrameLen() not defined by bandplan"
#endif
#ifndef pow2dBm
# error "pow2dBm() not defined by bandplan"
#endif
#ifndef dr2hsym
# error "dr2hsym() not defined by bandplan"
#endif
#if !defined(LMICbandplan_isValidBeacon1) && !defined(DISABLE_BEACONS)
# error "LMICbandplan_isValidBeacon1 not defined by bandplan"
#endif
#if !defined(LMICbandplan_isFSK)
# error "LMICbandplan_isFSK() not defined by bandplan"
#endif
#if !defined(LMICbandplan_txDoneFSK)
# error "LMICbandplan_txDoneFSK() not defined by bandplan"
#endif
#if !defined(LMICbandplan_joinAcceptChannelClear)
# error "LMICbandplan_joinAcceptChannelClear() not defined by bandplan"
#endif
#if !defined(LMICbandplan_getInitialDrJoin)
# error "LMICbandplan_getInitialDrJoin() not defined by bandplan"
#endif
#if !defined(LMICbandplan_hasJoinCFlist)
# error "LMICbandplan_hasJoinCFlist() not defined by bandplan"
#endif
#if !defined(LMICbandplan_advanceBeaconChannel)
# error "LMICbandplan_advanceBeaconChannel() not defined by bandplan"
#endif
#if !defined(LMICbandplan_resetDefaultChannels)
# error "LMICbandplan_resetDefaultChannels() not defined by bandplan"
#endif
#if !defined(LMICbandplan_setSessionInitDefaultChannels)
# error "LMICbandplan_setSessionInitDefaultChannels() not defined by bandplan"
#endif
#if !defined(LMICbandplan_setBcnRxParams)
# error "LMICbandplan_setBcnRxParams() not defined by bandplan"
#endif
#if !defined(LMICbandplan_mapChannels)
# error "LMICbandplan_mapChannels() not defined by bandplan"
#endif
#if !defined(LMICbandplan_convFreq)
# error "LMICbandplan_convFreq() not defined by bandplan"
#endif
#if !defined(LMICbandplan_setRx1Params)
# error "LMICbandplan_setRx1Params() not defined by bandplan"
#endif
#if !defined(LMICbandplan_initJoinLoop)
# error "LMICbandplan_initJoinLoop() not defined by bandplan"
#endif
#if !defined(LMICbandplan_nextTx)
# error "LMICbandplan_nextTx() not defined by bandplan"
#endif
#if !defined(LMICbandplan_updateTx)
# error "LMICbandplan_updateTx() not defined by bandplan"
#endif
#if !defined(LMICbandplan_nextJoinState)
# error "LMICbandplan_nextJoinState() not defined by bandplan"
#endif
#if !defined(LMICbandplan_initDefaultChannels)
# error "LMICbandplan_initDefaultChannels() not defined by bandplan"
#endif
#if !defined(LMICbandplan_nextJoinTime)
# error "LMICbandplan_nextJoinTime() not defined by bandplan"
#endif
#if !defined(LMICbandplan_init)
# error "LMICbandplan_init() not defined by bandplan"
#endif
//
// Things common to lmic.c code
//
#if !defined(MINRX_SYMS)
#define MINRX_SYMS 5
#endif // !defined(MINRX_SYMS)
#define PAMBL_SYMS 8
#define PAMBL_FSK 5
#define PRERX_FSK 1
#define RXLEN_FSK (1+5+2)
#define BCN_INTV_osticks sec2osticks(BCN_INTV_sec)
#define TXRX_GUARD_osticks ms2osticks(TXRX_GUARD_ms)
#define JOIN_GUARD_osticks ms2osticks(JOIN_GUARD_ms)
#define DELAY_JACC1_osticks sec2osticks(DELAY_JACC1)
#define DELAY_JACC2_osticks sec2osticks(DELAY_JACC2)
#define DELAY_EXTDNW2_osticks sec2osticks(DELAY_EXTDNW2)
#define BCN_RESERVE_osticks ms2osticks(BCN_RESERVE_ms)
#define BCN_GUARD_osticks ms2osticks(BCN_GUARD_ms)
#define BCN_WINDOW_osticks ms2osticks(BCN_WINDOW_ms)
#define AIRTIME_BCN_osticks us2osticks(AIRTIME_BCN)
// Special APIs - for development or testing
#define isTESTMODE() 0
// internal APIs
ostime_t LMICcore_rndDelay(u1_t secSpan);
void LMICcore_setDrJoin(u1_t reason, u1_t dr);
#endif // _lmic_bandplan_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_as923_h_
# define _lmic_as923_h_
#ifndef _lmic_eu_like_h_
# include "lmic_eu_like.h"
#endif
uint8_t LMICas923_maxFrameLen(uint8_t dr);
#define maxFrameLen(dr) LMICas923_maxFrameLen(dr)
int8_t LMICas923_pow2dBm(uint8_t mcmd_ladr_p1);
#define pow2dBm(mcmd_ladr_p1) LMICas923_pow2dBm(mcmd_ladr_p1)
// Times for half symbol per DR
// Per DR table to minimize rounding errors
ostime_t LMICas923_dr2hsym(uint8_t dr);
#define dr2hsym(dr) LMICas923_dr2hsym(dr)
static inline int
LMICas923_isValidBeacon1(const uint8_t *d) {
return os_rlsbf2(&d[OFF_BCN_CRC1]) != os_crc16(d, OFF_BCN_CRC1);
}
#undef LMICbandplan_isValidBeacon1
#define LMICbandplan_isValidBeacon1(pFrame) LMICas923_isValidBeacon1(pFrame)
// override default for LMICbandplan_resetDefaultChannels
void
LMICas923_resetDefaultChannels(void);
#undef LMICbandplan_resetDefaultChannels
#define LMICbandplan_resetDefaultChannels() \
LMICas923_resetDefaultChannels()
// override default for LMICbandplan_init
void LMICas923_init(void);
#undef LMICbandplan_init
#define LMICbandplan_init() \
LMICas923_init()
// override default for LMICbandplan_isFSK()
#undef LMICbandplan_isFSK
#define LMICbandplan_isFSK() (/* TX datarate */LMIC.rxsyms == AS923_DR_FSK)
// txDone handling for FSK.
void
LMICas923_txDoneFSK(ostime_t delay, osjobcb_t func);
#define LMICbandplan_txDoneFsk(delay, func) LMICas923_txDoneFSK(delay, func)
#define LMICbandplan_getInitialDrJoin() (AS923_DR_SF10)
void LMICas923_setBcnRxParams(void);
#define LMICbandplan_setBcnRxParams() LMICas923_setBcnRxParams()
u4_t LMICas923_convFreq(xref2cu1_t ptr);
#define LMICbandplan_convFreq(ptr) LMICas923_convFreq(ptr)
void LMICas923_initJoinLoop(void);
#define LMICbandplan_initJoinLoop() LMICas923_initJoinLoop()
// for as923, depending on dwell, we may need to do something else
#undef LMICbandplan_setRx1Params
void LMICas923_setRx1Params(void);
#define LMICbandplan_setRx1Params() LMICas923_setRx1Params()
ostime_t LMICas923_nextTx(ostime_t now);
#define LMICbandplan_nextTx(now) LMICas923_nextTx(now)
ostime_t LMICas923_nextJoinState(void);
#define LMICbandplan_nextJoinState() LMICas923_nextJoinState()
void LMICas923_initDefaultChannels(bit_t join);
#define LMICbandplan_initDefaultChannels(join) LMICas923_initDefaultChannels(join)
// override default for LMICbandplan_updateTX
#undef LMICbandplan_updateTx
void LMICas923_updateTx(ostime_t txbeg);
#define LMICbandplan_updateTx(txbeg) LMICas923_updateTx(txbeg)
#undef LMICbandplan_nextJoinTime
ostime_t LMICas923_nextJoinTime(ostime_t now);
#define LMICbandplan_nextJoinTime(now) LMICas923_nextJoinTime(now)
#endif // _lmic_as923_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_au921_h_
# define _lmic_au921_h_
// preconditions for lmic_us_like.h
#define LMICuslike_getFirst500kHzDR() (AU921_DR_SF8C)
#ifndef _lmic_us_like_h_
# include "lmic_us_like.h"
#endif
uint8_t LMICau921_maxFrameLen(uint8_t dr);
#define maxFrameLen(dr) LMICau921_maxFrameLen(dr)
#define pow2dBm(mcmd_ladr_p1) ((s1_t)(30 - (((mcmd_ladr_p1)&MCMD_LADR_POW_MASK)<<1)))
ostime_t LMICau921_dr2hsym(uint8_t dr);
#define dr2hsym(dr) LMICau921_dr2hsym(dr)
#define LMICbandplan_getInitialDrJoin() (EU868_DR_SF7)
void LMICau921_setBcnRxParams(void);
#define LMICbandplan_setBcnRxParams() LMICau921_setBcnRxParams()
u4_t LMICau921_convFreq(xref2cu1_t ptr);
#define LMICbandplan_convFreq(ptr) LMICau921_convFreq(ptr)
void LMICau921_setRx1Params(void);
#define LMICbandplan_setRx1Params() LMICau921_setRx1Params()
void LMICau921_updateTx(ostime_t txbeg);
#define LMICbandplan_updateTx(txbeg) LMICau921_updateTx(txbeg)
#endif // _lmic_au921_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_eu868_h_
# define _lmic_eu868_h_
#ifndef _lmic_eu_like_h_
# include "lmic_eu_like.h"
#endif
uint8_t LMICeu868_maxFrameLen(uint8_t dr);
#define maxFrameLen(dr) LMICeu868_maxFrameLen(dr)
int8_t LMICeu868_pow2dBm(uint8_t mcmd_ladr_p1);
#define pow2dBm(mcmd_ladr_p1) LMICeu868_pow2dBm(mcmd_ladr_p1)
// Times for half symbol per DR
// Per DR table to minimize rounding errors
ostime_t LMICeu868_dr2hsym(uint8_t dr);
#define dr2hsym(dr) LMICeu868_dr2hsym(dr)
// TODO(tmm@mcci.com) this looks bogus compared to current 1.02 regional
// spec. https://github.com/mcci-catena/arduino-lmic/issues/18
static inline int
LMICeu868_isValidBeacon1(const uint8_t *d) {
return d[OFF_BCN_CRC1] != (u1_t)os_crc16(d, OFF_BCN_CRC1);
}
#undef LMICbandplan_isValidBeacon1
#define LMICbandplan_isValidBeacon1(pFrame) LMICeu868_isValidBeacon1(pFrame)
// override default for LMICbandplan_isFSK()
#undef LMICbandplan_isFSK
#define LMICbandplan_isFSK() (/* TX datarate */LMIC.rxsyms == EU868_DR_FSK)
// txDone handling for FSK.
void
LMICeu868_txDoneFSK(ostime_t delay, osjobcb_t func);
#define LMICbandplan_txDoneFsk(delay, func) LMICeu868_txDoneFSK(delay, func)
#define LMICbandplan_getInitialDrJoin() (EU868_DR_SF7)
void LMICeu868_setBcnRxParams(void);
#define LMICbandplan_setBcnRxParams() LMICeu868_setBcnRxParams()
u4_t LMICeu868_convFreq(xref2cu1_t ptr);
#define LMICbandplan_convFreq(ptr) LMICeu868_convFreq(ptr)
void LMICeu868_initJoinLoop(void);
#define LMICbandplan_initJoinLoop() LMICeu868_initJoinLoop()
ostime_t LMICeu868_nextTx(ostime_t now);
#define LMICbandplan_nextTx(now) LMICeu868_nextTx(now)
ostime_t LMICeu868_nextJoinState(void);
#define LMICbandplan_nextJoinState() LMICeu868_nextJoinState()
void LMICeu868_initDefaultChannels(bit_t join);
#define LMICbandplan_initDefaultChannels(join) LMICeu868_initDefaultChannels(join)
#undef LMICbandplan_nextJoinTime
ostime_t LMICeu868_nextJoinTime(ostime_t now);
#define LMICbandplan_nextJoinTime(now) LMICeu868_nextJoinTime(now)
#endif // _lmic_eu868_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_in866_h_
# define _lmic_in866_h_
#ifndef _lmic_eu_like_h_
# include "lmic_eu_like.h"
#endif
uint8_t LMICin866_maxFrameLen(uint8_t dr);
#define maxFrameLen(dr) LMICin866_maxFrameLen(dr)
int8_t LMICin866_pow2dBm(uint8_t mcmd_ladr_p1);
#define pow2dBm(mcmd_ladr_p1) LMICin866_pow2dBm(mcmd_ladr_p1)
// Times for half symbol per DR
// Per DR table to minimize rounding errors
ostime_t LMICin866_dr2hsym(uint8_t dr);
#define dr2hsym(dr) LMICin866_dr2hsym(dr)
static inline int
LMICin866_isValidBeacon1(const uint8_t *d) {
return os_rlsbf2(&d[OFF_BCN_CRC1]) != os_crc16(d, OFF_BCN_CRC1);
}
#undef LMICbandplan_isValidBeacon1
#define LMICbandplan_isValidBeacon1(pFrame) LMICin866_isValidBeacon1(pFrame)
// override default for LMICbandplan_isFSK()
#undef LMICbandplan_isFSK
#define LMICbandplan_isFSK() (/* TX datarate */LMIC.rxsyms == IN866_DR_FSK)
// txDone handling for FSK.
void
LMICin866_txDoneFSK(ostime_t delay, osjobcb_t func);
#define LMICbandplan_txDoneFsk(delay, func) LMICin866_txDoneFSK(delay, func)
#define LMICbandplan_getInitialDrJoin() (IN866_DR_SF7)
void LMICin866_setBcnRxParams(void);
#define LMICbandplan_setBcnRxParams() LMICin866_setBcnRxParams()
u4_t LMICin866_convFreq(xref2cu1_t ptr);
#define LMICbandplan_convFreq(ptr) LMICin866_convFreq(ptr)
void LMICin866_initJoinLoop(void);
#define LMICbandplan_initJoinLoop() LMICin866_initJoinLoop()
ostime_t LMICin866_nextTx(ostime_t now);
#define LMICbandplan_nextTx(now) LMICin866_nextTx(now)
ostime_t LMICin866_nextJoinState(void);
#define LMICbandplan_nextJoinState() LMICin866_nextJoinState()
void LMICin866_initDefaultChannels(bit_t join);
#define LMICbandplan_initDefaultChannels(join) LMICin866_initDefaultChannels(join)
#endif // _lmic_in866_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_us915_h_
# define _lmic_us915_h_
// preconditions for lmic_us_like.h
#define LMICuslike_getFirst500kHzDR() (US915_DR_SF8C)
#ifndef _lmic_us_like_h_
# include "lmic_us_like.h"
#endif
uint8_t LMICus915_maxFrameLen(uint8_t dr);
#define maxFrameLen(dr) LMICus915_maxFrameLen(dr)
#define pow2dBm(mcmd_ladr_p1) ((s1_t)(US915_TX_MAX_DBM - (((mcmd_ladr_p1)&MCMD_LADR_POW_MASK)<<1)))
ostime_t LMICus915_dr2hsym(uint8_t dr);
#define dr2hsym(dr) LMICus915_dr2hsym(dr)
#define LMICbandplan_getInitialDrJoin() (US915_DR_SF7)
void LMICus915_setBcnRxParams(void);
#define LMICbandplan_setBcnRxParams() LMICus915_setBcnRxParams()
u4_t LMICus915_convFreq(xref2cu1_t ptr);
#define LMICbandplan_convFreq(ptr) LMICus915_convFreq(ptr)
void LMICus915_setRx1Params(void);
#define LMICbandplan_setRx1Params() LMICus915_setRx1Params()
void LMICus915_updateTx(ostime_t txbeg);
#define LMICbandplan_updateTx(txbeg) LMICus915_updateTx(txbeg)
#endif // _lmic_us915_h_

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/* lmic_config_preconditions.h Fri May 19 2017 23:58:34 tmm */
/*
Module: lmic_config_preconditions.h
Function:
Preconditions for LMIC configuration.
Version:
V2.0.0 Sun Aug 06 2017 17:40:44 tmm Edit level 1
Copyright notice:
This file copyright (C) 2017 by
MCCI Corporation
3520 Krums Corners Road
Ithaca, NY 14850
MIT License
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.
Author:
Terry Moore, MCCI Corporation July 2017
Revision history:
2.0.0 Sun Aug 06 2017 17:40:44 tmm
Module created.
*/
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# define _LMIC_CONFIG_PRECONDITIONS_H_
// We need to be able to compile with different options without editing source.
// When building with a more advanced environment, set the following variable:
// ARDUINO_LMIC_PROJECT_CONFIG_H=my_project_config.h
//
// otherwise the lmic_project_config.h from the ../../project_config directory will be used.
#ifndef ARDUINO_LMIC_PROJECT_CONFIG_H
# define ARDUINO_LMIC_PROJECT_CONFIG_H ../../project_config/lmic_project_config.h
#endif
#define CFG_TEXT_1(x) CFG_TEXT_2(x)
#define CFG_TEXT_2(x) #x
// constants for comparison
#define LMIC_REGION_eu868 1
#define LMIC_REGION_us915 2
#define LMIC_REGION_cn783 3
#define LMIC_REGION_eu433 4
#define LMIC_REGION_au921 5
#define LMIC_REGION_cn490 6
#define LMIC_REGION_as923 7
#define LMIC_REGION_kr921 8
#define LMIC_REGION_in866 9
// Some regions have country-specific overrides. For generality, we specify
// country codes using the LMIC_COUNTY_CODE_C() macro These values are chosen
// from the 2-letter domain suffixes standardized by ISO-3166-1 alpha2 (see
// https://en.wikipedia.org/wiki/ISO_3166-1_alpha-2). They are therefore
// 16-bit constants. By convention, we use UPPER-CASE letters, thus
// LMIC_COUNTRY_CODE('J', 'P'), not ('j', 'p').
#define LMIC_COUNTRY_CODE_C(c1, c2) ((c1) * 256 + (c2))
// this special code means "no country code defined"
#define LMIC_COUNTRY_CODE_NONE 0
// specific countries. Only the ones that are needed by the code are defined.
#define LMIC_COUNTRY_CODE_JP LMIC_COUNTRY_CODE_C('J', 'P')
// include the file that the user is really supposed to edit. But for really strange
// ports, this can be suppressed
#ifndef ARDUINO_LMIC_PROJECT_CONFIG_H_SUPPRESS
# include CFG_TEXT_1(ARDUINO_LMIC_PROJECT_CONFIG_H)
#endif /* ARDUINO_LMIC_PROJECT_CONFIG_H_SUPPRESS */
// a mask of the supported regions
// TODO(tmm@mcci.com) consider moving this block to a central file as it's not
// user-editable.
#define LMIC_REGIONS_SUPPORTED ( \
(1 << LMIC_REGION_eu868) | \
(1 << LMIC_REGION_us915) | \
/* (1 << LMIC_REGION_cn783) | */ \
/* (1 << LMIC_REGION_eu433) | */ \
(1 << LMIC_REGION_au921) | \
/* (1 << LMIC_REGION_cn490) | */ \
(1 << LMIC_REGION_as923) | \
/* (1 << LMIC_REGION_kr921) | */ \
(1 << LMIC_REGION_in866) | \
0)
//
// Our input is a -D of one of CFG_eu868, CFG_us915, CFG_as923, CFG_au915, CFG_in866
// More will be added in the the future. So at this point we create CFG_region with
// following values. These are in order of the sections in the manual. Not all of the
// below are supported yet.
//
# define CFG_LMIC_REGION_MASK \
((defined(CFG_eu868) << LMIC_REGION_eu868) | \
(defined(CFG_us915) << LMIC_REGION_us915) | \
(defined(CFG_cn783) << LMIC_REGION_cn783) | \
(defined(CFG_eu433) << LMIC_REGION_eu433) | \
(defined(CFG_au921) << LMIC_REGION_au921) | \
(defined(CFG_cn490) << LMIC_REGION_cn490) | \
(defined(CFG_as923) << LMIC_REGION_as923) | \
(defined(CFG_kr921) << LMIC_REGION_kr921) | \
(defined(CFG_in866) << LMIC_REGION_in866) | \
0)
// the selected region.
#if defined(CFG_eu868)
# define CFG_region LMIC_REGION_eu868
#elif defined(CFG_us915)
# define CFG_region LMIC_REGION_us915
#elif defined(CFG_cn783)
# define CFG_region LMIC_REGION_cn783
#elif defined(CFG_eu433)
# define CFG_region LMIC_REGION_eu433
#elif defined(CFG_au921)
# define CFG_region LMIC_REGION_au921
#elif defined(CFG_cn490)
# define CFG_region LMIC_REGION_cn490
#elif defined(CFG_as923)
# define CFG_region LMIC_REGION_as923
#elif defined(CFG_kr921)
# define CFG_region LMIC_REGION_kr921
#elif defined(CFG_in866)
# define CFG_region LMIC_REGION_in866
#else
# define CFG_region 0
#endif
// finally the mask of` US-like and EU-like regions
#define CFG_LMIC_EU_like_MASK ( \
(1 << LMIC_REGION_eu868) | \
/* (1 << LMIC_REGION_us915) | */ \
(1 << LMIC_REGION_cn783) | \
(1 << LMIC_REGION_eu433) | \
/* (1 << LMIC_REGION_au921) | */ \
/* (1 << LMIC_REGION_cn490) | */ \
(1 << LMIC_REGION_as923) | \
(1 << LMIC_REGION_kr921) | \
(1 << LMIC_REGION_in866) | \
0)
#define CFG_LMIC_US_like_MASK ( \
/* (1 << LMIC_REGION_eu868) | */ \
(1 << LMIC_REGION_us915) | \
/* (1 << LMIC_REGION_cn783) | */ \
/* (1 << LMIC_REGION_eu433) | */ \
(1 << LMIC_REGION_au921) | \
/* (1 << LMIC_REGION_cn490) | */ \
/* (1 << LMIC_REGION_as923) | */ \
/* (1 << LMIC_REGION_kr921) | */ \
/* (1 << LMIC_REGION_in866) | */ \
0)
#define CFG_LMIC_EU_like (!!(CFG_LMIC_REGION_MASK & CFG_LMIC_EU_like_MASK))
#define CFG_LMIC_US_like (!!(CFG_LMIC_REGION_MASK & CFG_LMIC_US_like_MASK))
#endif /* _LMIC_CONFIG_PRECONDITIONS_H_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if defined(CFG_eu868)
// ================================================================================
//
// BEG: EU868 related stuff
//
CONST_TABLE(u1_t, _DR2RPS_CRC)[] = {
ILLEGAL_RPS,
(u1_t)MAKERPS(SF12, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF11, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF10, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF9, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF8, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF7, BW125, CR_4_5, 0, 0),
(u1_t)MAKERPS(SF7, BW250, CR_4_5, 0, 0),
(u1_t)MAKERPS(FSK, BW125, CR_4_5, 0, 0),
ILLEGAL_RPS
};
static CONST_TABLE(u1_t, maxFrameLens)[] = { 64,64,64,123 };
uint8_t LMICeu868_maxFrameLen(uint8_t dr) {
if (dr < LENOF_TABLE(maxFrameLens))
return TABLE_GET_U1(maxFrameLens, dr);
else
return 0xFF;
}
static CONST_TABLE(s1_t, TXPOWLEVELS)[] = {
20, 14, 11, 8, 5, 2, 0,0, 0,0,0,0, 0,0,0,0
};
int8_t LMICeu868_pow2dBm(uint8_t mcmd_ladr_p1) {
return TABLE_GET_S1(TXPOWLEVELS, (mcmd_ladr_p1&MCMD_LADR_POW_MASK)>>MCMD_LADR_POW_SHIFT);
}
// only used in this module, but used by variant macro dr2hsym().
static CONST_TABLE(ostime_t, DR2HSYM_osticks)[] = {
us2osticksRound(128 << 7), // DR_SF12
us2osticksRound(128 << 6), // DR_SF11
us2osticksRound(128 << 5), // DR_SF10
us2osticksRound(128 << 4), // DR_SF9
us2osticksRound(128 << 3), // DR_SF8
us2osticksRound(128 << 2), // DR_SF7
us2osticksRound(128 << 1), // DR_SF7B
us2osticksRound(80) // FSK -- not used (time for 1/2 byte)
};
ostime_t LMICeu868_dr2hsym(uint8_t dr) {
return TABLE_GET_OSTIME(DR2HSYM_osticks, dr);
}
enum { NUM_DEFAULT_CHANNELS = 3 };
static CONST_TABLE(u4_t, iniChannelFreq)[6] = {
// Join frequencies and duty cycle limit (0.1%)
EU868_F1 | BAND_MILLI, EU868_F2 | BAND_MILLI, EU868_F3 | BAND_MILLI,
// Default operational frequencies and duty cycle limit (1%)
EU868_F1 | BAND_CENTI, EU868_F2 | BAND_CENTI, EU868_F3 | BAND_CENTI,
};
void LMICeu868_initDefaultChannels(bit_t join) {
os_clearMem(&LMIC.channelFreq, sizeof(LMIC.channelFreq));
os_clearMem(&LMIC.channelDrMap, sizeof(LMIC.channelDrMap));
os_clearMem(&LMIC.bands, sizeof(LMIC.bands));
LMIC.channelMap = (1 << NUM_DEFAULT_CHANNELS) - 1;
u1_t su = join ? 0 : NUM_DEFAULT_CHANNELS;
for (u1_t fu = 0; fu<NUM_DEFAULT_CHANNELS; fu++, su++) {
LMIC.channelFreq[fu] = TABLE_GET_U4(iniChannelFreq, su);
// TODO(tmm@mcci.com): don't use EU DR directly, use something from the LMIC context or a static const
LMIC.channelDrMap[fu] = DR_RANGE_MAP(EU868_DR_SF12, EU868_DR_SF7);
}
LMIC.bands[BAND_MILLI].txcap = 1000; // 0.1%
LMIC.bands[BAND_MILLI].txpow = 14;
LMIC.bands[BAND_MILLI].lastchnl = os_getRndU1() % MAX_CHANNELS;
LMIC.bands[BAND_CENTI].txcap = 100; // 1%
LMIC.bands[BAND_CENTI].txpow = 14;
LMIC.bands[BAND_CENTI].lastchnl = os_getRndU1() % MAX_CHANNELS;
LMIC.bands[BAND_DECI].txcap = 10; // 10%
LMIC.bands[BAND_DECI].txpow = 27;
LMIC.bands[BAND_DECI].lastchnl = os_getRndU1() % MAX_CHANNELS;
LMIC.bands[BAND_MILLI].avail =
LMIC.bands[BAND_CENTI].avail =
LMIC.bands[BAND_DECI].avail = os_getTime();
}
bit_t LMIC_setupBand(u1_t bandidx, s1_t txpow, u2_t txcap) {
if (bandidx > BAND_AUX) return 0;
//band_t* b = &LMIC.bands[bandidx];
xref2band_t b = &LMIC.bands[bandidx];
b->txpow = txpow;
b->txcap = txcap;
b->avail = os_getTime();
b->lastchnl = os_getRndU1() % MAX_CHANNELS;
return 1;
}
bit_t LMIC_setupChannel(u1_t chidx, u4_t freq, u2_t drmap, s1_t band) {
if (chidx >= MAX_CHANNELS)
return 0;
if (band == -1) {
if (freq >= 869400000 && freq <= 869650000)
freq |= BAND_DECI; // 10% 27dBm
else if ((freq >= 868000000 && freq <= 868600000) ||
(freq >= 869700000 && freq <= 870000000))
freq |= BAND_CENTI; // 1% 14dBm
else
freq |= BAND_MILLI; // 0.1% 14dBm
}
else {
if (band > BAND_AUX) return 0;
freq = (freq&~3) | band;
}
LMIC.channelFreq[chidx] = freq;
// TODO(tmm@mcci.com): don't use US SF directly, use something from the LMIC context or a static const
LMIC.channelDrMap[chidx] = drmap == 0 ? DR_RANGE_MAP(EU868_DR_SF12, EU868_DR_SF7) : drmap;
LMIC.channelMap |= 1 << chidx; // enabled right away
return 1;
}
u4_t LMICeu868_convFreq(xref2cu1_t ptr) {
u4_t freq = (os_rlsbf4(ptr - 1) >> 8) * 100;
if (freq < EU868_FREQ_MIN || freq > EU868_FREQ_MAX)
freq = 0;
return freq;
}
ostime_t LMICeu868_nextJoinTime(ostime_t time) {
// is the avail time in the future?
if ((s4_t) (time - LMIC.bands[BAND_MILLI].avail) < 0)
// yes: then wait until then.
time = LMIC.bands[BAND_MILLI].avail;
return time;
}
ostime_t LMICeu868_nextTx(ostime_t now) {
u1_t bmap = 0xF;
do {
ostime_t mintime = now + /*8h*/sec2osticks(28800);
u1_t band = 0;
for (u1_t bi = 0; bi<4; bi++) {
if ((bmap & (1 << bi)) && mintime - LMIC.bands[bi].avail > 0)
mintime = LMIC.bands[band = bi].avail;
}
// Find next channel in given band
u1_t chnl = LMIC.bands[band].lastchnl;
for (u1_t ci = 0; ci<MAX_CHANNELS; ci++) {
if ((chnl = (chnl + 1)) >= MAX_CHANNELS)
chnl -= MAX_CHANNELS;
if ((LMIC.channelMap & (1 << chnl)) != 0 && // channel enabled
(LMIC.channelDrMap[chnl] & (1 << (LMIC.datarate & 0xF))) != 0 &&
band == (LMIC.channelFreq[chnl] & 0x3)) { // in selected band
LMIC.txChnl = LMIC.bands[band].lastchnl = chnl;
return mintime;
}
}
if ((bmap &= ~(1 << band)) == 0) {
// No feasible channel found!
return mintime;
}
} while (1);
}
#if !defined(DISABLE_BEACONS)
void LMICeu868_setBcnRxParams(void) {
LMIC.dataLen = 0;
LMIC.freq = LMIC.channelFreq[LMIC.bcnChnl] & ~(u4_t)3;
LMIC.rps = setIh(setNocrc(dndr2rps((dr_t)DR_BCN), 1), LEN_BCN);
}
#endif // !DISABLE_BEACONS
#if !defined(DISABLE_JOIN)
ostime_t LMICeu868_nextJoinState(void) {
return LMICeulike_nextJoinState(NUM_DEFAULT_CHANNELS);
}
#endif // !DISABLE_JOIN
// txDone handling for FSK.
void
LMICeu868_txDoneFSK(ostime_t delay, osjobcb_t func) {
LMIC.rxtime = LMIC.txend + delay - PRERX_FSK*us2osticksRound(160);
LMIC.rxsyms = RXLEN_FSK;
os_setTimedCallback(&LMIC.osjob, LMIC.rxtime - RX_RAMPUP, func);
}
void
LMICeu868_initJoinLoop(void) {
LMICeulike_initJoinLoop(NUM_DEFAULT_CHANNELS, /* adr dBm */ EU868_TX_EIRP_MAX_DBM);
}
//
// END: EU868 related stuff
//
// ================================================================================
#endif

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if CFG_LMIC_EU_like
void LMIC_enableSubBand(u1_t band) {
}
void LMIC_disableSubBand(u1_t band) {
}
void LMIC_disableChannel(u1_t channel) {
LMIC.channelFreq[channel] = 0;
LMIC.channelDrMap[channel] = 0;
LMIC.channelMap &= ~(1 << channel);
}
// this is a no-op provided for compatibilty
void LMIC_enableChannel(u1_t channel) {
}
u1_t LMICeulike_mapChannels(u1_t chpage, u2_t chmap) {
// Bad page, disable all channel, enable non-existent
if (chpage != 0 || chmap == 0 || (chmap & ~LMIC.channelMap) != 0)
return 0; // illegal input
for (u1_t chnl = 0; chnl<MAX_CHANNELS; chnl++) {
if ((chmap & (1 << chnl)) != 0 && LMIC.channelFreq[chnl] == 0)
chmap &= ~(1 << chnl); // ignore - channel is not defined
}
LMIC.channelMap = chmap;
return 1;
}
#if !defined(DISABLE_JOIN)
void LMICeulike_initJoinLoop(uint8_t nDefaultChannels, s1_t adrTxPow) {
#if CFG_TxContinuousMode
LMIC.txChnl = 0
#else
LMIC.txChnl = os_getRndU1() % nDefaultChannels;
#endif
LMIC.adrTxPow = adrTxPow;
// TODO(tmm@mcci.com) don't use EU directly, use a table. That
// will allow support for EU-style bandplans with similar code.
LMICcore_setDrJoin(DRCHG_SET, LMICbandplan_getInitialDrJoin());
LMICbandplan_initDefaultChannels(/* put into join mode */ 1);
ASSERT((LMIC.opmode & OP_NEXTCHNL) == 0);
LMIC.txend = os_getTime() + LMICcore_rndDelay(8);
}
#endif // DISABLE_JOIN
void LMICeulike_updateTx(ostime_t txbeg) {
u4_t freq = LMIC.channelFreq[LMIC.txChnl];
// Update global/band specific duty cycle stats
ostime_t airtime = calcAirTime(LMIC.rps, LMIC.dataLen);
// Update channel/global duty cycle stats
xref2band_t band = &LMIC.bands[freq & 0x3];
LMIC.freq = freq & ~(u4_t)3;
LMIC.txpow = band->txpow;
band->avail = txbeg + airtime * band->txcap;
if (LMIC.globalDutyRate != 0)
LMIC.globalDutyAvail = txbeg + (airtime << LMIC.globalDutyRate);
}
#if !defined(DISABLE_JOIN)
//
// TODO(tmm@mcci.com):
//
// The definition of this is a little strange. this seems to return a time, but
// in reality it returns 0 if the caller should continue scanning through
// channels, and 1 if the caller has scanned all channels on this session,
// and therefore should reset to the beginning. The IBM 1.6 code is the
// same way, so apparently I just carried this across. We should declare
// as bool_t and change callers to use the result clearly as a flag.
//
ostime_t LMICeulike_nextJoinState(uint8_t nDefaultChannels) {
u1_t failed = 0;
// Try each default channel with same DR
// If all fail try next lower datarate
if (++LMIC.txChnl == /* NUM_DEFAULT_CHANNELS */ nDefaultChannels)
LMIC.txChnl = 0;
if ((++LMIC.txCnt % nDefaultChannels) == 0) {
// Lower DR every nth try (having all default channels with same DR)
//
// TODO(tmm@mcci.com) add new DR_REGIN_JOIN_MIN instead of LORAWAN_DR0;
// then we can eliminate the LMIC_REGION_as923 below because we'll set
// the failed flag here. This will cause the outer caller to take the
// appropriate join path. Or add new LMICeulike_GetLowestJoinDR()
//
if (LMIC.datarate == LORAWAN_DR0)
failed = 1; // we have tried all DR - signal EV_JOIN_FAILED
else
{
// TODO(tmm@mcci.com) - see above; please remove regional dependency from this file.
#if CFG_region != LMIC_REGION_as923
LMICcore_setDrJoin(DRCHG_NOJACC, decDR((dr_t)LMIC.datarate));
#else
// in the join of AS923 v1.1 or older, only DR2 is used.
// no need to change the DR.
LMIC.datarate = AS923_DR_SF10;
#endif
}
}
// Clear NEXTCHNL because join state engine controls channel hopping
LMIC.opmode &= ~OP_NEXTCHNL;
// Move txend to randomize synchronized concurrent joins.
// Duty cycle is based on txend.
ostime_t const time = LMICbandplan_nextJoinTime(os_getTime());
// TODO(tmm@mcci.com): change delay to (0:1) secs + a known t0, but randomized;
// starting adding a bias after 1 hour, 25 hours, etc.; and limit the duty
// cycle on power up. For testability, add a way to set the join start time
// externally (a test API) so we can check this feature.
// See https://github.com/mcci-catena/arduino-lmic/issues/2
// Current code doesn't match LoRaWAN 1.0.2 requirements.
LMIC.txend = time +
(isTESTMODE()
// Avoid collision with JOIN ACCEPT @ SF12 being sent by GW (but we missed it)
? DNW2_SAFETY_ZONE
// Otherwise: randomize join (street lamp case):
// SF12:255, SF11:127, .., SF7:8secs
//
: DNW2_SAFETY_ZONE + LMICcore_rndDelay(255 >> LMIC.datarate));
// 1 - triggers EV_JOIN_FAILED event
return failed;
}
#endif // !DISABLE_JOIN
#endif // CFG_LMIC_EU_like

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_eu_like_h_
# define _lmic_eu_like_h_
#ifndef _lmic_h_
# include "lmic.h"
#endif
// make sure we want US-like code
#if !CFG_LMIC_EU_like
# error "lmic not configured for EU-like bandplan"
#endif
// TODO(tmm@mcci.com): this should come from the lmic.h or lorabase.h file; and
// it's probably affected by the fix to this issue:
// https://github.com/mcci-catena/arduino-lmic/issues/2
#define DNW2_SAFETY_ZONE ms2osticks(3000)
// provide a default for LMICbandplan_isValidBeacon1()
static inline int
LMICeulike_isValidBeacon1(const uint8_t *d) {
return os_rlsbf2(&d[OFF_BCN_CRC1]) != os_crc16(d, OFF_BCN_CRC1);
}
#define LMICbandplan_isValidBeacon1(pFrame) LMICeulike_isValidBeacon1(pFrame)
// provide a default for LMICbandplan_isFSK()
#define LMICbandplan_isFSK() (0)
// provide a default LMICbandplan_txDoneDoFSK()
#define LMICbandplan_txDoneFSK(delay, func) do { } while (0)
#define LMICbandplan_joinAcceptChannelClear() LMICbandplan_initDefaultChannels(/* normal, not join */ 0)
enum { BAND_MILLI = 0, BAND_CENTI = 1, BAND_DECI = 2, BAND_AUX = 3 };
// there's a CFList on joins for EU-like plans
#define LMICbandplan_hasJoinCFlist() (1)
#define LMICbandplan_advanceBeaconChannel() \
do { /* nothing */ } while (0)
#define LMICbandplan_resetDefaultChannels() \
do { /* nothing */ } while (0)
#define LMICbandplan_setSessionInitDefaultChannels() \
do { LMICbandplan_initDefaultChannels(/* normal, not join */ 0); } while (0)
u1_t LMICeulike_mapChannels(u1_t chpage, u2_t chmap);
#define LMICbandplan_mapChannels(c, m) LMICeulike_mapChannels(c, m)
void LMICeulike_initJoinLoop(u1_t nDefaultChannels, s1_t adrTxPow);
#define LMICbandplan_setRx1Params() \
do { /*LMIC.freq/rps remain unchanged*/ } while (0)
void LMICeulike_updateTx(ostime_t txbeg);
#define LMICbandplan_updateTx(t) LMICeulike_updateTx(t)
ostime_t LMICeulike_nextJoinState(uint8_t nDefaultChannels);
static inline ostime_t LMICeulike_nextJoinTime(ostime_t now) {
return now;
}
#define LMICbandplan_nextJoinTime(now) LMICeulike_nextJoinTime(now)
#define LMICbandplan_init() \
do { /* nothing */ } while (0)
#endif // _lmic_eu_like_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if defined(CFG_in866)
// ================================================================================
//
// BEG: IN866 related stuff
//
CONST_TABLE(u1_t, _DR2RPS_CRC)[] = {
ILLEGAL_RPS,
(u1_t)MAKERPS(SF12, BW125, CR_4_5, 0, 0), // [0]
(u1_t)MAKERPS(SF11, BW125, CR_4_5, 0, 0), // [1]
(u1_t)MAKERPS(SF10, BW125, CR_4_5, 0, 0), // [2]
(u1_t)MAKERPS(SF9, BW125, CR_4_5, 0, 0), // [3]
(u1_t)MAKERPS(SF8, BW125, CR_4_5, 0, 0), // [4]
(u1_t)MAKERPS(SF7, BW125, CR_4_5, 0, 0), // [5]
ILLEGAL_RPS, // [6]
(u1_t)MAKERPS(FSK, BW125, CR_4_5, 0, 0), // [7]
ILLEGAL_RPS
};
static CONST_TABLE(u1_t, maxFrameLens)[] = { 59+5,59+5,59+5,123+5, 230+5, 230+5 };
uint8_t LMICin866_maxFrameLen(uint8_t dr) {
if (dr < LENOF_TABLE(maxFrameLens))
return TABLE_GET_U1(maxFrameLens, dr);
else
return 0xFF;
}
static CONST_TABLE(s1_t, TXPOWLEVELS)[] = {
20, 14, 11, 8, 5, 2, 0,0, 0,0,0,0, 0,0,0,0
};
int8_t LMICin866_pow2dBm(uint8_t mcmd_ladr_p1) {
return TABLE_GET_S1(TXPOWLEVELS, (mcmd_ladr_p1&MCMD_LADR_POW_MASK)>>MCMD_LADR_POW_SHIFT);
}
// only used in this module, but used by variant macro dr2hsym().
static CONST_TABLE(ostime_t, DR2HSYM_osticks)[] = {
us2osticksRound(128 << 7), // DR_SF12
us2osticksRound(128 << 6), // DR_SF11
us2osticksRound(128 << 5), // DR_SF10
us2osticksRound(128 << 4), // DR_SF9
us2osticksRound(128 << 3), // DR_SF8
us2osticksRound(128 << 2), // DR_SF7
us2osticksRound(128 << 1), // --
us2osticksRound(80) // FSK -- not used (time for 1/2 byte)
};
ostime_t LMICin866_dr2hsym(uint8_t dr) {
return TABLE_GET_OSTIME(DR2HSYM_osticks, dr);
}
// All frequencies are marked as BAND_MILLI, and we don't do duty-cycle. But this lets
// us reuse code.
enum { NUM_DEFAULT_CHANNELS = 3 };
static CONST_TABLE(u4_t, iniChannelFreq)[NUM_DEFAULT_CHANNELS] = {
// Default operational frequencies
IN866_F1 | BAND_MILLI,
IN866_F2 | BAND_MILLI,
IN866_F3 | BAND_MILLI,
};
// india ignores join, becuase the channel setup is the same either way.
void LMICin866_initDefaultChannels(bit_t join) {
os_clearMem(&LMIC.channelFreq, sizeof(LMIC.channelFreq));
os_clearMem(&LMIC.channelDrMap, sizeof(LMIC.channelDrMap));
os_clearMem(&LMIC.bands, sizeof(LMIC.bands));
LMIC.channelMap = (1 << NUM_DEFAULT_CHANNELS) - 1;
for (u1_t fu = 0; fu<NUM_DEFAULT_CHANNELS; fu++) {
LMIC.channelFreq[fu] = TABLE_GET_U4(iniChannelFreq, fu);
LMIC.channelDrMap[fu] = DR_RANGE_MAP(IN866_DR_SF12, IN866_DR_SF7);
}
LMIC.bands[BAND_MILLI].txcap = 1; // no limit, in effect.
LMIC.bands[BAND_MILLI].txpow = IN866_TX_EIRP_MAX_DBM;
LMIC.bands[BAND_MILLI].lastchnl = os_getRndU1() % MAX_CHANNELS;
LMIC.bands[BAND_MILLI].avail = os_getTime();
}
bit_t LMIC_setupBand(u1_t bandidx, s1_t txpow, u2_t txcap) {
if (bandidx > BAND_MILLI) return 0;
//band_t* b = &LMIC.bands[bandidx];
xref2band_t b = &LMIC.bands[bandidx];
b->txpow = txpow;
b->txcap = txcap;
b->avail = os_getTime();
b->lastchnl = os_getRndU1() % MAX_CHANNELS;
return 1;
}
bit_t LMIC_setupChannel(u1_t chidx, u4_t freq, u2_t drmap, s1_t band) {
if (chidx >= MAX_CHANNELS)
return 0;
if (band == -1) {
freq |= BAND_MILLI;
} else {
if (band > BAND_MILLI) return 0;
freq = (freq&~3) | band;
}
LMIC.channelFreq[chidx] = freq;
LMIC.channelDrMap[chidx] = drmap == 0 ? DR_RANGE_MAP(IN866_DR_SF12, IN866_DR_SF7) : drmap;
LMIC.channelMap |= 1 << chidx; // enabled right away
return 1;
}
u4_t LMICin866_convFreq(xref2cu1_t ptr) {
u4_t freq = (os_rlsbf4(ptr - 1) >> 8) * 100;
if (freq < IN866_FREQ_MIN || freq > IN866_FREQ_MAX)
freq = 0;
return freq;
}
// return the next time, but also do channel hopping here
// since there's no duty cycle limitation, and no dwell limitation,
// we simply loop through the channels sequentially.
ostime_t LMICin866_nextTx(ostime_t now) {
const u1_t band = BAND_MILLI;
for (u1_t ci = 0; ci < MAX_CHANNELS; ci++) {
// Find next channel in given band
u1_t chnl = LMIC.bands[band].lastchnl;
for (u1_t ci = 0; ci<MAX_CHANNELS; ci++) {
if ((chnl = (chnl + 1)) >= MAX_CHANNELS)
chnl -= MAX_CHANNELS;
if ((LMIC.channelMap & (1 << chnl)) != 0 && // channel enabled
(LMIC.channelDrMap[chnl] & (1 << (LMIC.datarate & 0xF))) != 0 &&
band == (LMIC.channelFreq[chnl] & 0x3)) { // in selected band
LMIC.txChnl = LMIC.bands[band].lastchnl = chnl;
return now;
}
}
}
// no enabled channel found! just use the last channel.
return now;
}
#if !defined(DISABLE_BEACONS)
void LMICin866_setBcnRxParams(void) {
LMIC.dataLen = 0;
LMIC.freq = LMIC.channelFreq[LMIC.bcnChnl] & ~(u4_t)3;
LMIC.rps = setIh(setNocrc(dndr2rps((dr_t)DR_BCN), 1), LEN_BCN);
}
#endif // !DISABLE_BEACONS
#if !defined(DISABLE_JOIN)
ostime_t LMICin866_nextJoinState(void) {
return LMICeulike_nextJoinState(NUM_DEFAULT_CHANNELS);
}
#endif // !DISABLE_JOIN
// txDone handling for FSK.
void
LMICin866_txDoneFSK(ostime_t delay, osjobcb_t func) {
LMIC.rxtime = LMIC.txend + delay - PRERX_FSK*us2osticksRound(160);
LMIC.rxsyms = RXLEN_FSK;
os_setTimedCallback(&LMIC.osjob, LMIC.rxtime - RX_RAMPUP, func);
}
void
LMICin866_initJoinLoop(void) {
LMICeulike_initJoinLoop(NUM_DEFAULT_CHANNELS, /* adr dBm */ IN866_TX_EIRP_MAX_DBM);
}
//
// END: IN866 related stuff
//
// ================================================================================
#endif

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if defined(CFG_us915)
// ================================================================================
//
// BEG: US915 related stuff
//
CONST_TABLE(u1_t, _DR2RPS_CRC)[] = {
ILLEGAL_RPS, // [-1]
MAKERPS(SF10, BW125, CR_4_5, 0, 0), // [0]
MAKERPS(SF9 , BW125, CR_4_5, 0, 0), // [1]
MAKERPS(SF8 , BW125, CR_4_5, 0, 0), // [2]
MAKERPS(SF7 , BW125, CR_4_5, 0, 0), // [3]
MAKERPS(SF8 , BW500, CR_4_5, 0, 0), // [4]
ILLEGAL_RPS , // [5]
ILLEGAL_RPS , // [6]
ILLEGAL_RPS , // [7]
MAKERPS(SF12, BW500, CR_4_5, 0, 0), // [8]
MAKERPS(SF11, BW500, CR_4_5, 0, 0), // [9]
MAKERPS(SF10, BW500, CR_4_5, 0, 0), // [10]
MAKERPS(SF9 , BW500, CR_4_5, 0, 0), // [11]
MAKERPS(SF8 , BW500, CR_4_5, 0, 0), // [12]
MAKERPS(SF7 , BW500, CR_4_5, 0, 0), // [13]
ILLEGAL_RPS // [14]
};
static CONST_TABLE(u1_t, maxFrameLens)[] = { 24,66,142,255,255,255,255,255, 66,142 };
uint8_t LMICus915_maxFrameLen(uint8_t dr) {
if (dr < LENOF_TABLE(maxFrameLens))
return TABLE_GET_U1(maxFrameLens, dr);
else
return 0xFF;
}
static CONST_TABLE(ostime_t, DR2HSYM_osticks)[] = {
us2osticksRound(128 << 5), // DR_SF10 DR_SF12CR
us2osticksRound(128 << 4), // DR_SF9 DR_SF11CR
us2osticksRound(128 << 3), // DR_SF8 DR_SF10CR
us2osticksRound(128 << 2), // DR_SF7 DR_SF9CR
us2osticksRound(128 << 1), // DR_SF8C DR_SF8CR
us2osticksRound(128 << 0) // ------ DR_SF7CR
};
ostime_t LMICus915_dr2hsym(uint8_t dr) {
return TABLE_GET_OSTIME(DR2HSYM_osticks, (dr) & 7); // map DR_SFnCR -> 0-6
}
u4_t LMICus915_convFreq(xref2cu1_t ptr) {
u4_t freq = (os_rlsbf4(ptr - 1) >> 8) * 100;
if (freq < US915_FREQ_MIN || freq > US915_FREQ_MAX)
freq = 0;
return freq;
}
bit_t LMIC_setupChannel(u1_t chidx, u4_t freq, u2_t drmap, s1_t band) {
if (chidx < 72 || chidx >= 72 + MAX_XCHANNELS)
return 0; // channels 0..71 are hardwired
LMIC.xchFreq[chidx - 72] = freq;
// TODO(tmm@mcci.com): don't use US SF directly, use something from the LMIC context or a static const
LMIC.xchDrMap[chidx - 72] = drmap == 0 ? DR_RANGE_MAP(US915_DR_SF10, US915_DR_SF8C) : drmap;
LMIC.channelMap[chidx >> 4] |= (1 << (chidx & 0xF));
return 1;
}
void LMIC_disableChannel(u1_t channel) {
if (channel < 72 + MAX_XCHANNELS) {
if (ENABLED_CHANNEL(channel)) {
if (IS_CHANNEL_125khz(channel))
LMIC.activeChannels125khz--;
else if (IS_CHANNEL_500khz(channel))
LMIC.activeChannels500khz--;
}
LMIC.channelMap[channel >> 4] &= ~(1 << (channel & 0xF));
}
}
void LMIC_enableChannel(u1_t channel) {
if (channel < 72 + MAX_XCHANNELS) {
if (!ENABLED_CHANNEL(channel)) {
if (IS_CHANNEL_125khz(channel))
LMIC.activeChannels125khz++;
else if (IS_CHANNEL_500khz(channel))
LMIC.activeChannels500khz++;
}
LMIC.channelMap[channel >> 4] |= (1 << (channel & 0xF));
}
}
void LMIC_enableSubBand(u1_t band) {
ASSERT(band < 8);
u1_t start = band * 8;
u1_t end = start + 8;
// enable all eight 125 kHz channels in this subband
for (int channel = start; channel < end; ++channel)
LMIC_enableChannel(channel);
// there's a single 500 kHz channel associated with
// each group of 8 125 kHz channels. Enable it, too.
LMIC_enableChannel(64 + band);
}
void LMIC_disableSubBand(u1_t band) {
ASSERT(band < 8);
u1_t start = band * 8;
u1_t end = start + 8;
// disable all eight 125 kHz channels in this subband
for (int channel = start; channel < end; ++channel)
LMIC_disableChannel(channel);
// there's a single 500 kHz channel associated with
// each group of 8 125 kHz channels. Disable it, too.
LMIC_disableChannel(64 + band);
}
void LMIC_selectSubBand(u1_t band) {
ASSERT(band < 8);
for (int b = 0; b<8; ++b) {
if (band == b)
LMIC_enableSubBand(b);
else
LMIC_disableSubBand(b);
}
}
void LMICus915_updateTx(ostime_t txbeg) {
u1_t chnl = LMIC.txChnl;
if (chnl < 64) {
LMIC.freq = US915_125kHz_UPFBASE + chnl*US915_125kHz_UPFSTEP;
if (LMIC.activeChannels125khz >= 50)
LMIC.txpow = 30;
else
LMIC.txpow = 21;
} else {
// at 500kHz bandwidth, we're allowed more power.
LMIC.txpow = 26;
if (chnl < 64 + 8) {
LMIC.freq = US915_500kHz_UPFBASE + (chnl - 64)*US915_500kHz_UPFSTEP;
}
else {
ASSERT(chnl < 64 + 8 + MAX_XCHANNELS);
LMIC.freq = LMIC.xchFreq[chnl - 72];
}
}
// Update global duty cycle stats
if (LMIC.globalDutyRate != 0) {
ostime_t airtime = calcAirTime(LMIC.rps, LMIC.dataLen);
LMIC.globalDutyAvail = txbeg + (airtime << LMIC.globalDutyRate);
}
}
#if !defined(DISABLE_BEACONS)
void LMICus915_setBcnRxParams(void) {
LMIC.dataLen = 0;
LMIC.freq = US915_500kHz_DNFBASE + LMIC.bcnChnl * US915_500kHz_DNFSTEP;
LMIC.rps = setIh(setNocrc(dndr2rps((dr_t)DR_BCN), 1), LEN_BCN);
}
#endif // !DISABLE_BEACONS
// TODO(tmm@mcci.com): parmeterize for US-like
void LMICus915_setRx1Params(void) {
LMIC.freq = US915_500kHz_DNFBASE + (LMIC.txChnl & 0x7) * US915_500kHz_DNFSTEP;
if( /* TX datarate */LMIC.dndr < US915_DR_SF8C )
LMIC.dndr += US915_DR_SF10CR - US915_DR_SF10;
else if( LMIC.dndr == US915_DR_SF8C )
LMIC.dndr = US915_DR_SF7CR;
LMIC.rps = dndr2rps(LMIC.dndr);
}
//
// END: US915 related stuff
//
// ================================================================================
#endif

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic_bandplan.h"
#if CFG_LMIC_US_like
#ifndef LMICuslike_getFirst500kHzDR
# error "LMICuslike_getFirst500kHzDR() not defined by bandplan"
#endif
static void setNextChannel(uint start, uint end, uint count) {
ASSERT(count>0);
ASSERT(start<end);
ASSERT(count <= (end - start));
// We used to pick a random channel once and then just increment. That is not per spec.
// Now we use a new random number each time, because they are not very expensive.
// Regarding the algo below, we cannot pick a number and scan until we hit an enabled channel.
// That would result in the first enabled channel following a set of disabled ones
// being used more frequently than the other enabled channels.
// Last used channel is in range. It is not a candidate, per spec.
uint lastTxChan = LMIC.txChnl;
if (start <= lastTxChan && lastTxChan<end &&
// Adjust count only if still enabled. Otherwise, no chance of selection.
ENABLED_CHANNEL(lastTxChan)) {
--count;
if (count == 0) {
return; // Only one active channel, so keep using it.
}
}
uint nth = os_getRndU1() % count;
for (u1_t chnl = start; chnl<end; chnl++) {
// Scan for nth enabled channel that is not the last channel used
if (chnl != lastTxChan && ENABLED_CHANNEL(chnl) && (nth--) == 0) {
LMIC.txChnl = chnl;
return;
}
}
// No feasible channel found! Keep old one.
}
bit_t LMIC_setupBand(u1_t bandidx, s1_t txpow, u2_t txcap) {
// nothing; just succeed.
return 1;
}
void LMICuslike_initDefaultChannels(bit_t fJoin) {
// things work the same for join as normal.
for (u1_t i = 0; i<4; i++)
LMIC.channelMap[i] = 0xFFFF;
LMIC.channelMap[4] = 0x00FF;
LMIC.activeChannels125khz = 64;
LMIC.activeChannels500khz = 8;
}
u1_t LMICuslike_mapChannels(u1_t chpage, u2_t chmap) {
/*
|| MCMD_LADR_CHP_125ON and MCMD_LADR_CHP_125OFF are special. The
|| channel map appllies to 500kHz (ch 64..71) and in addition
|| all channels 0..63 are turned off or on. MCMC_LADR_CHP_BANK
|| is also special, in that it enables subbands.
*/
u1_t base, top;
if (chpage < MCMD_LADR_CHP_USLIKE_SPECIAL) {
// operate on channels 0..15, 16..31, 32..47, 48..63
base = chpage << 4;
top = base + 16;
if (base == 64) {
if (chmap & 0xFF00) {
// those are reserved bits, fail.
return 0;
}
top = 72;
}
} else if (chpage == MCMD_LADR_CHP_BANK) {
if (chmap & 0xFF00) {
// those are resreved bits, fail.
return 0;
}
// each bit enables a bank of channels
for (u1_t subband = 0; subband < 8; ++subband, chmap >>= 1) {
if (chmap & 1) {
LMIC_enableSubBand(subband);
} else {
LMIC_disableSubBand(subband);
}
// don't change any channels below
base = top = 0;
}
} else if (chpage == MCMD_LADR_CHP_125ON || chpage == MCMD_LADR_CHP_125OFF) {
u1_t const en125 = chpage == MCMD_LADR_CHP_125ON;
// enable or disable all 125kHz channels
for (u1_t chnl = 0; chnl < 64; ++chnl) {
if (en125)
LMIC_enableChannel(chnl);
else
LMIC_disableChannel(chnl);
}
// then apply mask to top 8 channels.
base = 64;
top = 72;
} else {
return 0;
}
// apply chmap to channels in [base..top-1].
// Use enable/disable channel to keep activeChannel counts in sync.
for (u1_t chnl = base; chnl < top; ++chnl, chmap >>= 1) {
if (chmap & 0x0001)
LMIC_enableChannel(chnl);
else
LMIC_disableChannel(chnl);
}
return 1;
}
// US does not have duty cycling - return now as earliest TX time
// but also do the channel hopping dance.
ostime_t LMICuslike_nextTx(ostime_t now) {
// TODO(tmm@mcci.com): use a static const for US-like
if (LMIC.datarate >= LMICuslike_getFirst500kHzDR()) { // 500kHz
ASSERT(LMIC.activeChannels500khz>0);
setNextChannel(64, 64 + 8, LMIC.activeChannels500khz);
}
else { // 125kHz
ASSERT(LMIC.activeChannels125khz>0);
setNextChannel(0, 64, LMIC.activeChannels125khz);
}
return now;
}
#if !defined(DISABLE_JOIN)
void LMICuslike_initJoinLoop(void) {
// set an initial condition so that setNextChannel()'s preconds are met
LMIC.txChnl = 0;
// then chose a new channel. This gives us a random first channel for
// the join. Minor nit: if channel 0 is enabled, it will never be used
// as the first join channel. The join logic uses the current txChnl,
// then changes after the rx window expires; so we need to set a valid
// starting point.
setNextChannel(0, 64, LMIC.activeChannels125khz);
// initialize the adrTxPower.
// TODO(tmm@mcci.com): is this right for all US-like regions
LMIC.adrTxPow = 20; // dBm
ASSERT((LMIC.opmode & OP_NEXTCHNL) == 0);
// make sure LMIC.txend is valid.
LMIC.txend = os_getTime();
// make sure the datarate is set to DR0 per LoRaWAN regional reqts V1.0.2,
// section 2.2.2
// TODO(tmm@mcci.com): parameterize this for US-like
LMICcore_setDrJoin(DRCHG_SET, LORAWAN_DR0);
// TODO(tmm@mcci.com) need to implement the transmit randomization and
// duty cycle restrictions from LoRaWAN V1.0.2 section 7.
}
#endif // !DISABLE_JOIN
#if !defined(DISABLE_JOIN)
//
// TODO(tmm@mcci.com):
//
// The definition of this is a little strange. this seems to return a time, but
// in reality it returns 0 if the caller should continue scanning through
// channels, and 1 if the caller has scanned all channels on this session,
// and therefore should reset to the beginning. The IBM 1.6 code is the
// same way, so apparently I just carried this across. We should declare
// as bool_t and change callers to use the result clearly as a flag.
//
ostime_t LMICuslike_nextJoinState(void) {
// Try the following:
// DR0 (SF10) on a random channel 0..63
// (honoring enable mask)
// DR4 (SF8C) on a random 500 kHz channel 64..71
// (always determined by
// previously selected
// 125 kHz channel)
//
u1_t failed = 0;
// TODO(tmm@mcci.com) parameterize for US-like
if (LMIC.datarate != LMICuslike_getFirst500kHzDR()) {
// assume that 500 kHz equiv of last 125 kHz channel
// is also enabled, and use it next.
LMIC.txChnl = 64 + (LMIC.txChnl >> 3);
LMICcore_setDrJoin(DRCHG_SET, LMICuslike_getFirst500kHzDR());
}
else {
setNextChannel(0, 64, LMIC.activeChannels125khz);
// TODO(tmm@mcci.com) parameterize
s1_t dr = LORAWAN_DR0;
if ((++LMIC.txCnt & 0x7) == 0) {
failed = 1; // All DR exhausted - signal failed
}
LMICcore_setDrJoin(DRCHG_SET, dr);
}
LMIC.opmode &= ~OP_NEXTCHNL;
// TODO(tmm@mcci.com): change delay to (0:1) secs + a known t0, but randomized;
// starting adding a bias after 1 hour, 25 hours, etc.; and limit the duty
// cycle on power up. For testability, add a way to set the join start time
// externally (a test API) so we can check this feature.
// See https://github.com/mcci-catena/arduino-lmic/issues/2
// Current code doesn't match LoRaWAN 1.0.2 requirements.
LMIC.txend = os_getTime() +
(isTESTMODE()
// Avoid collision with JOIN ACCEPT being sent by GW (but we missed it - GW is still busy)
? DNW2_SAFETY_ZONE
// Otherwise: randomize join (street lamp case):
// SF10:16, SF9=8,..SF8C:1secs
: LMICcore_rndDelay(16 >> LMIC.datarate));
// 1 - triggers EV_JOIN_FAILED event
return failed;
}
#endif
#endif // CFG_LMIC_US_like

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lmic_us_like_h_
# define _lmic_us_like_h_
// make sure we want US-like code
#if !CFG_LMIC_US_like
# error "lmic not configured for us-like bandplan"
#endif
// TODO(tmm@mcci.com): this should come from the lmic.h or lorabase.h file; and
// it's probably affected by the fix to this issue:
// https://github.com/mcci-catena/arduino-lmic/issues/2
#define DNW2_SAFETY_ZONE ms2osticks(750)
#define IS_CHANNEL_125khz(c) (c<64)
#define IS_CHANNEL_500khz(c) (c>=64 && c<72)
#define ENABLED_CHANNEL(chnl) ((LMIC.channelMap[(chnl >> 4)] & (1<<(chnl & 0x0F))) != 0)
// provide the isValidBeacon1 function -- int for bool.
static inline int
LMICuslike_isValidBeacon1(const uint8_t *d) {
return os_rlsbf2(&d[OFF_BCN_CRC1]) != os_crc16(d, OFF_BCN_CRC1);
}
#define LMICbandplan_isValidBeacon1(pFrame) LMICuslike_isValidBeacon1(pFrame)
// provide a default for LMICbandplan_isFSK()
#define LMICbandplan_isFSK() (0)
// provide a default LMICbandplan_txDoneFSK()
#define LMICbandplan_txDoneFSK(delay, func) do { } while (0)
// provide a default LMICbandplan_joinAcceptChannelClear()
#define LMICbandplan_joinAcceptChannelClear() do { } while (0)
// no CFList on joins for US-like plans
#define LMICbandplan_hasJoinCFlist() (0)
#define LMICbandplan_advanceBeaconChannel() \
do { LMIC.bcnChnl = (LMIC.bcnChnl+1) & 7; } while (0)
// TODO(tmm@mcci.com): decide whether we want to do this on every
// reset or just restore the last sub-band selected by the user.
#define LMICbandplan_resetDefaultChannels() \
LMICbandplan_initDefaultChannels(/* normal */ 0)
void LMICuslike_initDefaultChannels(bit_t fJoin);
#define LMICbandplan_initDefaultChannels(fJoin) LMICuslike_initDefaultChannels(fJoin)
#define LMICbandplan_setSessionInitDefaultChannels() \
do { /* nothing */} while (0)
u1_t LMICuslike_mapChannels(u1_t chpage, u2_t chmap);
#define LMICbandplan_mapChannels(chpage, chmap) LMICuslike_mapChannels(chpage, chmap)
ostime_t LMICuslike_nextTx(ostime_t now);
#define LMICbandplan_nextTx(now) LMICuslike_nextTx(now)
void LMICuslike_initJoinLoop(void);
#define LMICbandplan_initJoinLoop() LMICuslike_initJoinLoop()
ostime_t LMICuslike_nextJoinState(void);
#define LMICbandplan_nextJoinState() LMICuslike_nextJoinState();
static inline ostime_t LMICeulike_nextJoinTime(ostime_t now) {
return now;
}
#define LMICbandplan_nextJoinTime(now) LMICeulike_nextJoinTime(now)
#define LMICbandplan_init() \
do { /* nothing */ } while (0)
#endif // _lmic_us_like_h_

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/*
Module: lmic_util.c
Function:
Encoding and decoding utilities for LMIC clients.
Copyright & License:
See accompanying LICENSE file.
Author:
Terry Moore, MCCI September 2019
*/
#include "lmic_util.h"
#include <math.h>
/*
Name: LMIC_f2sflt16()
Function:
Encode a floating point number into a uint16_t.
Definition:
uint16_t LMIC_f2sflt16(
float f
);
Description:
The float to be transmitted must be a number in the range (-1.0, 1.0).
It is converted to 16-bit integer formatted as follows:
bits 15: sign
bits 14..11: biased exponent
bits 10..0: mantissa
The float is properly rounded, and saturates.
Note that the encoded value is sign/magnitude format, rather than
two's complement for negative values.
Returns:
0xFFFF for negative values <= 1.0;
0x7FFF for positive values >= 1.0;
Otherwise an appropriate float.
*/
uint16_t
LMIC_f2sflt16(
float f
)
{
if (f <= -1.0)
return 0xFFFF;
else if (f >= 1.0)
return 0x7FFF;
else
{
int iExp;
float normalValue;
uint16_t sign;
normalValue = frexpf(f, &iExp);
sign = 0;
if (normalValue < 0)
{
// set the "sign bit" of the result
// and work with the absolute value of normalValue.
sign = 0x8000;
normalValue = -normalValue;
}
// abs(f) is supposed to be in [0..1), so useful exp
// is [0..-15]
iExp += 15;
if (iExp < 0)
iExp = 0;
// bit 15 is the sign
// bits 14..11 are the exponent
// bits 10..0 are the fraction
// we conmpute the fraction and then decide if we need to round.
uint16_t outputFraction = ldexpf(normalValue, 11) + 0.5;
if (outputFraction >= (1 << 11u))
{
// reduce output fraction
outputFraction = 1 << 10;
// increase exponent
++iExp;
}
// check for overflow and return max instead.
if (iExp > 15)
return 0x7FFF | sign;
return (uint16_t)(sign | (iExp << 11u) | outputFraction);
}
}
/*
Name: LMIC_f2sflt12()
Function:
Encode a floating point number into a uint16_t using only 12 bits.
Definition:
uint16_t LMIC_f2sflt16(
float f
);
Description:
The float to be transmitted must be a number in the range (-1.0, 1.0).
It is converted to 16-bit integer formatted as follows:
bits 15-12: zero
bit 11: sign
bits 10..7: biased exponent
bits 6..0: mantissa
The float is properly rounded, and saturates.
Note that the encoded value is sign/magnitude format, rather than
two's complement for negative values.
Returns:
0xFFF for negative values <= 1.0;
0x7FF for positive values >= 1.0;
Otherwise an appropriate float.
*/
uint16_t
LMIC_f2sflt12(
float f
)
{
if (f <= -1.0)
return 0xFFF;
else if (f >= 1.0)
return 0x7FF;
else
{
int iExp;
float normalValue;
uint16_t sign;
normalValue = frexpf(f, &iExp);
sign = 0;
if (normalValue < 0)
{
// set the "sign bit" of the result
// and work with the absolute value of normalValue.
sign = 0x800;
normalValue = -normalValue;
}
// abs(f) is supposed to be in [0..1), so useful exp
// is [0..-15]
iExp += 15;
if (iExp < 0)
iExp = 0;
// bit 15 is the sign
// bits 14..11 are the exponent
// bits 10..0 are the fraction
// we conmpute the fraction and then decide if we need to round.
uint16_t outputFraction = ldexpf(normalValue, 7) + 0.5;
if (outputFraction >= (1 << 7u))
{
// reduce output fraction
outputFraction = 1 << 6;
// increase exponent
++iExp;
}
// check for overflow and return max instead.
if (iExp > 15)
return 0x7FF | sign;
return (uint16_t)(sign | (iExp << 7u) | outputFraction);
}
}
/*
Name: LMIC_f2uflt16()
Function:
Encode a floating point number into a uint16_t.
Definition:
uint16_t LMIC_f2uflt16(
float f
);
Description:
The float to be transmitted must be a number in the range [0, 1.0).
It is converted to 16-bit integer formatted as follows:
bits 15..12: biased exponent
bits 11..0: mantissa
The float is properly rounded, and saturates.
Note that the encoded value is sign/magnitude format, rather than
two's complement for negative values.
Returns:
0x0000 for values < 0.0;
0xFFFF for positive values >= 1.0;
Otherwise an appropriate encoding of the input float.
*/
uint16_t
LMIC_f2uflt16(
float f
)
{
if (f < 0.0)
return 0;
else if (f >= 1.0)
return 0xFFFF;
else
{
int iExp;
float normalValue;
normalValue = frexpf(f, &iExp);
// f is supposed to be in [0..1), so useful exp
// is [0..-15]
iExp += 15;
if (iExp < 0)
// underflow.
iExp = 0;
// bits 15..12 are the exponent
// bits 11..0 are the fraction
// we conmpute the fraction and then decide if we need to round.
uint16_t outputFraction = ldexpf(normalValue, 12) + 0.5;
if (outputFraction >= (1 << 12u))
{
// reduce output fraction
outputFraction = 1 << 11;
// increase exponent
++iExp;
}
// check for overflow and return max instead.
if (iExp > 15)
return 0xFFFF;
return (uint16_t)((iExp << 12u) | outputFraction);
}
}
/*
Name: LMIC_f2uflt12()
Function:
Encode positive floating point number into a uint16_t using only 12 bits.
Definition:
uint16_t LMIC_f2sflt16(
float f
);
Description:
The float to be transmitted must be a number in the range [0, 1.0).
It is converted to 16-bit integer formatted as follows:
bits 15-12: zero
bits 11..8: biased exponent
bits 7..0: mantissa
The float is properly rounded, and saturates.
Returns:
0x000 for negative values < 0.0;
0xFFF for positive values >= 1.0;
Otherwise an appropriate float.
*/
uint16_t
LMIC_f2uflt12(
float f
)
{
if (f < 0.0)
return 0x000;
else if (f >= 1.0)
return 0xFFF;
else
{
int iExp;
float normalValue;
normalValue = frexpf(f, &iExp);
// f is supposed to be in [0..1), so useful exp
// is [0..-15]
iExp += 15;
if (iExp < 0)
// graceful underflow
iExp = 0;
// bits 11..8 are the exponent
// bits 7..0 are the fraction
// we conmpute the fraction and then decide if we need to round.
uint16_t outputFraction = ldexpf(normalValue, 8) + 0.5;
if (outputFraction >= (1 << 8u))
{
// reduce output fraction
outputFraction = 1 << 7;
// increase exponent
++iExp;
}
// check for overflow and return max instead.
if (iExp > 15)
return 0xFFF;
return (uint16_t)((iExp << 8u) | outputFraction);
}
}

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/*
Module: lmic_util.h
Function:
Declare encoding and decoding utilities for LMIC clients.
Copyright & License:
See accompanying LICENSE file.
Author:
Terry Moore, MCCI September 2019
*/
#ifndef _LMIC_UTIL_H_
# define _LMIC_UTIL_H_
#ifdef __cplusplus
extern "C" {
#endif
#include <stdint.h>
uint16_t LMIC_f2sflt16(float);
uint16_t LMIC_f2sflt12(float);
uint16_t LMIC_f2uflt16(float);
uint16_t LMIC_f2uflt12(float);
#ifdef __cplusplus
}
#endif
#endif /* _LMIC_UTIL_H_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyritght (c) 2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_h_
#define _lorabase_h_
#ifdef __cplusplus
extern "C"{
#endif
// ================================================================================
// BEG: Keep in sync with lorabase.hpp
//
enum _cr_t { CR_4_5=0, CR_4_6, CR_4_7, CR_4_8 };
enum _sf_t { FSK=0, SF7, SF8, SF9, SF10, SF11, SF12, SFrfu };
enum _bw_t { BW125=0, BW250, BW500, BWrfu };
typedef u1_t cr_t;
typedef u1_t sf_t;
typedef u1_t bw_t;
typedef u1_t dr_t;
// Radio parameter set (encodes SF/BW/CR/IH/NOCRC)
typedef u2_t rps_t;
TYPEDEF_xref2rps_t;
enum { ILLEGAL_RPS = 0xFF };
// Global maximum frame length
enum { STD_PREAMBLE_LEN = 8 };
enum { MAX_LEN_FRAME = 64 };
enum { LEN_DEVNONCE = 2 };
enum { LEN_ARTNONCE = 3 };
enum { LEN_NETID = 3 };
enum { DELAY_JACC1 = 5 }; // in secs
enum { DELAY_DNW1 = 1 }; // in secs down window #1
enum { DELAY_EXTDNW2 = 1 }; // in secs
enum { DELAY_JACC2 = DELAY_JACC1+(int)DELAY_EXTDNW2 }; // in secs
enum { DELAY_DNW2 = DELAY_DNW1 +(int)DELAY_EXTDNW2 }; // in secs down window #1
enum { BCN_INTV_exp = 7 };
enum { BCN_INTV_sec = 1<<BCN_INTV_exp };
enum { BCN_INTV_ms = BCN_INTV_sec*1000L };
enum { BCN_INTV_us = BCN_INTV_ms*1000L };
enum { BCN_RESERVE_ms = 2120 }; // space reserved for beacon and NWK management
enum { BCN_GUARD_ms = 3000 }; // end of beacon period to prevent interference with beacon
enum { BCN_SLOT_SPAN_ms = 30 }; // 2^12 reception slots a this span
enum { BCN_WINDOW_ms = BCN_INTV_ms-(int)BCN_GUARD_ms-(int)BCN_RESERVE_ms };
enum { BCN_RESERVE_us = 2120000 };
enum { BCN_GUARD_us = 3000000 };
enum { BCN_SLOT_SPAN_us = 30000 };
// there are exactly 16 datarates
enum _dr_code_t {
LORAWAN_DR0 = 0,
LORAWAN_DR1,
LORAWAN_DR2,
LORAWAN_DR3,
LORAWAN_DR4,
LORAWAN_DR5,
LORAWAN_DR6,
LORAWAN_DR7,
LORAWAN_DR8,
LORAWAN_DR9,
LORAWAN_DR10,
LORAWAN_DR11,
LORAWAN_DR12,
LORAWAN_DR13,
LORAWAN_DR14,
LORAWAN_DR15,
LORAWAN_DR_LENGTH // 16, for sizing arrays.
};
// post conditions from this block: symbols used by general code that is not
// ostensiblly region-specific.
// DR_DFLTMIN must be defined as a suitable substititute value if we get a bogus DR
// DR_PAGE is used only for a non-supported debug system, but should be defined.
// CHNL_DNW2 is the channel to be used for RX2
// FREQ_DNW2 is the frequency to be used for RX2
// DR_DNW2 is the data-rate to be used for RX2
//
// The Class B stuff is untested and definitely wrong in parts for LoRaWAN 1.02
// CHNL_PING is the channel to be used for pinging.
// FREQ_PING is the default ping channel frequency
// DR_PING is the data-rate to be used for pings.
// CHNL_BCN is the channel to be used for the beacon (or perhaps the start chan)
// FREQ_BCN is the frequency to be used for the beacon
// DR_BCN is the datarate to be used for the beacon
// AIRTIME_BCN is the airtime for the beacon
#if defined(CFG_eu868) // ==============================================
#include "lorabase_eu868.h"
// per 2.1.3: not implemented
#define LMIC_ENABLE_TxParamSetupReq 0
enum { DR_DFLTMIN = EU868_DR_SF7 }; // DR5
// DR_PAGE is a debugging parameter
enum { DR_PAGE = DR_PAGE_EU868 };
//enum { CHNL_PING = 5 };
enum { FREQ_PING = EU868_F6 }; // default ping freq
enum { DR_PING = EU868_DR_SF9 }; // default ping DR
//enum { CHNL_DNW2 = 5 };
enum { FREQ_DNW2 = EU868_F6 };
enum { DR_DNW2 = EU868_DR_SF12 };
enum { CHNL_BCN = 5 };
enum { FREQ_BCN = EU868_F6 };
enum { DR_BCN = EU868_DR_SF9 };
enum { AIRTIME_BCN = 144384 }; // micros
enum { LMIC_REGION_EIRP = EU868_LMIC_REGION_EIRP }; // region uses EIRP
enum {
// Beacon frame format EU SF9
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 3,
OFF_BCN_CRC1 = 7,
OFF_BCN_INFO = 8,
OFF_BCN_LAT = 9,
OFF_BCN_LON = 12,
OFF_BCN_CRC2 = 15,
LEN_BCN = 17
};
// for backwards compatibility. This must match _dr_eu868_t
# if LMIC_DR_LEGACY
enum _dr_configured_t {
DR_SF12 = EU868_DR_SF12,
DR_SF11 = EU868_DR_SF11,
DR_SF10 = EU868_DR_SF10,
DR_SF9 = EU868_DR_SF9,
DR_SF8 = EU868_DR_SF8,
DR_SF7 = EU868_DR_SF7,
DR_SF7B = EU868_DR_SF7B,
DR_FSK = EU868_DR_FSK,
DR_NONE = EU868_DR_NONE
};
# endif // LMIC_DR_LEGACY
#elif defined(CFG_us915) // =========================================
#include "lorabase_us915.h"
// per 2.2.3: not implemented
#define LMIC_ENABLE_TxParamSetupReq 0
enum { DR_DFLTMIN = US915_DR_SF7 }; // DR5
// DR_PAGE is a debugging parameter; it must be defined but it has no use in arduino-lmic
enum { DR_PAGE = DR_PAGE_US915 };
//enum { CHNL_PING = 0 }; // used only for default init of state (follows beacon - rotating)
enum { FREQ_PING = US915_500kHz_DNFBASE + 0*US915_500kHz_DNFSTEP }; // default ping freq
enum { DR_PING = US915_DR_SF10CR }; // default ping DR
//enum { CHNL_DNW2 = 0 };
enum { FREQ_DNW2 = US915_500kHz_DNFBASE + 0*US915_500kHz_DNFSTEP };
enum { DR_DNW2 = US915_DR_SF12CR };
enum { CHNL_BCN = 0 }; // used only for default init of state (rotating beacon scheme)
enum { DR_BCN = US915_DR_SF12CR };
// TODO(tmm@mcci.com): check this, as beacon DR was SF10 in IBM code.
enum { AIRTIME_BCN = 72192 }; // micros
enum { LMIC_REGION_EIRP = US915_LMIC_REGION_EIRP }; // region uses EIRP
enum {
// Beacon frame format US SF10
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 3,
OFF_BCN_CRC1 = 7,
OFF_BCN_INFO = 9,
OFF_BCN_LAT = 10,
OFF_BCN_LON = 13,
OFF_BCN_RFU1 = 16,
OFF_BCN_CRC2 = 17,
LEN_BCN = 19
};
# if LMIC_DR_LEGACY
enum _dr_configured_t {
DR_SF10 = US915_DR_SF10,
DR_SF9 = US915_DR_SF9,
DR_SF8 = US915_DR_SF8,
DR_SF7 = US915_DR_SF7,
DR_SF8C = US915_DR_SF8C,
DR_NONE = US915_DR_NONE,
DR_SF12CR = US915_DR_SF12CR,
DR_SF11CR = US915_DR_SF11CR,
DR_SF10CR = US915_DR_SF10CR,
DR_SF9CR = US915_DR_SF9CR,
DR_SF8CR = US915_DR_SF8CR,
DR_SF7CR = US915_DR_SF7CR
};
# endif // LMIC_DR_LEGACY
#elif defined(CFG_au921) // =========================================
#include "lorabase_au921.h"
// per 2.5.3: not implemented
#define LMIC_ENABLE_TxParamSetupReq 0
enum { DR_DFLTMIN = AU921_DR_SF7 }; // DR5
// DR_PAGE is a debugging parameter; it must be defined but it has no use in arduino-lmic
enum { DR_PAGE = DR_PAGE_AU921 };
//enum { CHNL_PING = 0 }; // used only for default init of state (follows beacon - rotating)
enum { FREQ_PING = AU921_500kHz_DNFBASE + 0*AU921_500kHz_DNFSTEP }; // default ping freq
enum { DR_PING = AU921_DR_SF10CR }; // default ping DR
//enum { CHNL_DNW2 = 0 };
enum { FREQ_DNW2 = AU921_500kHz_DNFBASE + 0*AU921_500kHz_DNFSTEP };
enum { DR_DNW2 = AU921_DR_SF12CR }; // DR8
enum { CHNL_BCN = 0 }; // used only for default init of state (rotating beacon scheme)
enum { DR_BCN = AU921_DR_SF10CR };
enum { AIRTIME_BCN = 72192 }; // micros ... TODO(tmm@mcci.com) check.
enum { LMIC_REGION_EIRP = AU921_LMIC_REGION_EIRP }; // region uses EIRP
enum {
// Beacon frame format AU DR10/SF10 500kHz
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 3,
OFF_BCN_CRC1 = 7,
OFF_BCN_INFO = 9,
OFF_BCN_LAT = 10,
OFF_BCN_LON = 13,
OFF_BCN_RFU1 = 16,
OFF_BCN_CRC2 = 17,
LEN_BCN = 19
};
# if LMIC_DR_LEGACY
enum _dr_configured_t {
DR_SF12 = AU921_DR_SF12,
DR_SF11 = AU921_DR_SF11,
DR_SF10 = AU921_DR_SF10,
DR_SF9 = AU921_DR_SF9,
DR_SF8 = AU921_DR_SF8,
DR_SF7 = AU921_DR_SF7,
DR_SF8C = AU921_DR_SF8C,
DR_NONE = AU921_DR_NONE,
DR_SF12CR = AU921_DR_SF12CR,
DR_SF11CR = AU921_DR_SF11CR,
DR_SF10CR = AU921_DR_SF10CR,
DR_SF9CR = AU921_DR_SF9CR,
DR_SF8CR = AU921_DR_SF8CR,
DR_SF7CR = AU921_DR_SF7CR
};
# endif // LMIC_DR_LEGACY
#elif defined(CFG_as923) // ==============================================
#include "lorabase_as923.h"
// per 2.7.3: must be implemented
#define LMIC_ENABLE_TxParamSetupReq 1
enum { DR_DFLTMIN = AS923_DR_SF10 }; // DR2
// DR_PAGE is a debugging parameter
enum { DR_PAGE = DR_PAGE_AS923 };
enum { FREQ_PING = AS923_F2 }; // default ping freq
enum { DR_PING = AS923_DR_SF9 }; // default ping DR: DR3
enum { FREQ_DNW2 = AS923_FDOWN };
enum { DR_DNW2 = AS923_DR_SF10 };
enum { CHNL_BCN = 5 };
enum { FREQ_BCN = AS923_FBCN };
enum { DR_BCN = AS923_DR_SF9 };
enum { AIRTIME_BCN = 144384 }; // micros
enum { LMIC_REGION_EIRP = AS923_LMIC_REGION_EIRP }; // region uses EIRP
enum {
// Beacon frame format AS SF9
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 2,
OFF_BCN_CRC1 = 6,
OFF_BCN_INFO = 8,
OFF_BCN_LAT = 9,
OFF_BCN_LON = 12,
OFF_BCN_CRC2 = 15,
LEN_BCN = 17
};
# if LMIC_DR_LEGACY
enum _dr_configured_t {
DR_SF12 = AS923_DR_SF12,
DR_SF11 = AS923_DR_SF11,
DR_SF10 = AS923_DR_SF10,
DR_SF9 = AS923_DR_SF9,
DR_SF8 = AS923_DR_SF8,
DR_SF7 = AS923_DR_SF7,
DR_SF7B = AS923_DR_SF7B,
DR_FSK = AS923_DR_FSK,
DR_NONE = AS923_DR_NONE
};
# endif // LMIC_DR_LEGACY
#elif defined(CFG_in866) // ==============================================
#include "lorabase_in866.h"
// per 2.9.3: not implemented
#define LMIC_ENABLE_TxParamSetupReq 0
enum { DR_DFLTMIN = IN866_DR_SF7 }; // DR5
enum { DR_PAGE = DR_PAGE_IN866 }; // DR_PAGE is a debugging parameter
enum { FREQ_PING = IN866_FB }; // default ping freq
enum { DR_PING = IN866_DR_SF8 }; // default ping DR
enum { FREQ_DNW2 = IN866_FB };
enum { DR_DNW2 = IN866_DR_SF10 };
enum { CHNL_BCN = 5 };
enum { FREQ_BCN = IN866_FB };
enum { DR_BCN = IN866_DR_SF8 };
enum { AIRTIME_BCN = 144384 }; // micros
enum { LMIC_REGION_EIRP = IN866_LMIC_REGION_EIRP }; // region uses EIRP
enum {
// Beacon frame format IN SF9
OFF_BCN_NETID = 0,
OFF_BCN_TIME = 1,
OFF_BCN_CRC1 = 5,
OFF_BCN_INFO = 7,
OFF_BCN_LAT = 8,
OFF_BCN_LON = 11,
OFF_BCN_CRC2 = 17,
LEN_BCN = 19
};
# if LMIC_DR_LEGACY
enum _dr_configured_t {
DR_SF12 = IN866_DR_SF12, // DR0
DR_SF11 = IN866_DR_SF11, // DR1
DR_SF10 = IN866_DR_SF10, // DR2
DR_SF9 = IN866_DR_SF9, // DR3
DR_SF8 = IN866_DR_SF8, // DR4
DR_SF7 = IN866_DR_SF7, // DR5
DR_FSK = IN866_DR_FSK, // DR7
DR_NONE = IN866_DR_NONE
};
# endif // LMIC_DR_LEGACY
#else
# error Unsupported configuration setting
#endif // ===================================================
enum {
// Join Request frame format
OFF_JR_HDR = 0,
OFF_JR_ARTEUI = 1,
OFF_JR_DEVEUI = 9,
OFF_JR_DEVNONCE = 17,
OFF_JR_MIC = 19,
LEN_JR = 23
};
enum {
// Join Accept frame format
OFF_JA_HDR = 0,
OFF_JA_ARTNONCE = 1,
OFF_JA_NETID = 4,
OFF_JA_DEVADDR = 7,
OFF_JA_RFU = 11,
OFF_JA_DLSET = 11,
OFF_JA_RXDLY = 12,
OFF_CFLIST = 13,
LEN_JA = 17,
LEN_JAEXT = 17+16
};
enum {
// Data frame format
OFF_DAT_HDR = 0,
OFF_DAT_ADDR = 1,
OFF_DAT_FCT = 5,
OFF_DAT_SEQNO = 6,
OFF_DAT_OPTS = 8,
};
enum { MAX_LEN_PAYLOAD = MAX_LEN_FRAME-(int)OFF_DAT_OPTS-4 };
enum {
// Bitfields in frame format octet
HDR_FTYPE = 0xE0,
HDR_RFU = 0x1C,
HDR_MAJOR = 0x03
};
enum { HDR_FTYPE_DNFLAG = 0x20 }; // flags DN frame except for HDR_FTYPE_PROP
enum {
// Values of frame type bit field
HDR_FTYPE_JREQ = 0x00,
HDR_FTYPE_JACC = 0x20,
HDR_FTYPE_DAUP = 0x40, // data (unconfirmed) up
HDR_FTYPE_DADN = 0x60, // data (unconfirmed) dn
HDR_FTYPE_DCUP = 0x80, // data confirmed up
HDR_FTYPE_DCDN = 0xA0, // data confirmed dn
HDR_FTYPE_REJOIN = 0xC0, // rejoin for roaming
HDR_FTYPE_PROP = 0xE0
};
enum {
HDR_MAJOR_V1 = 0x00,
};
enum {
// Bitfields in frame control octet
FCT_ADREN = 0x80,
FCT_ADRARQ = 0x40,
FCT_ACK = 0x20,
FCT_MORE = 0x10, // also in DN direction: Class B indicator
FCT_OPTLEN = 0x0F,
};
enum {
// In UP direction: signals class B enabled
FCT_CLASSB = FCT_MORE
};
enum {
NWKID_MASK = (int)0xFE000000,
NWKID_BITS = 7
};
// MAC uplink commands downwlink too
enum {
// Class A
MCMD_LCHK_REQ = 0x02, // - LinkCheckReq : -
MCMD_LADR_ANS = 0x03, // - LinkADRAnd : u1:7-3:RFU, 3/2/1: pow/DR/Ch ACK
MCMD_DCAP_ANS = 0x04, // - DutyCycleAns : -
MCMD_DN2P_ANS = 0x05, // - RxParamSetupAns : u1:7-2:RFU 1/0:datarate/channel ack
MCMD_DEVS_ANS = 0x06, // - DevStatusAns : u1:battery 0,1-254,255=?, u1:7-6:RFU,5-0:margin(-32..31)
MCMD_SNCH_ANS = 0x07, // - NewChannelAns : u1: 7-2=RFU, 1/0:DR/freq ACK
MCMD_RXTimingSetupAns = 0x08, // : -
MCMD_TxParamSetupAns = 0x09, // : -
MCMD_DIChannelAns = 0x0A, // : u1: [7-2]:RFU 1:exists 0:OK
// Class B
MCMD_PING_IND = 0x10, // - pingability indic : u1: 7=RFU, 6-4:interval, 3-0:datarate
MCMD_PING_ANS = 0x11, // - ack ping freq : u1: 7-1:RFU, 0:freq ok
MCMD_BCNI_REQ = 0x12, // - next beacon start : -
};
// MAC downlink commands
enum {
// Class A
MCMD_LCHK_ANS = 0x02, // LinkCheckAns : u1:margin 0-254,255=unknown margin / u1:gwcnt LinkCheckReq
MCMD_LADR_REQ = 0x03, // LinkADRReq : u1:DR/TXPow, u2:chmask, u1:chpage/repeat
MCMD_DCAP_REQ = 0x04, // DutyCycleReq : u1:255 dead [7-4]:RFU, [3-0]:cap 2^-k
MCMD_DN2P_SET = 0x05, // RXParamSetupReq : u1:7-4:RFU/3-0:datarate, u3:freq
MCMD_DEVS_REQ = 0x06, // DevStatusReq : -
MCMD_SNCH_REQ = 0x07, // NewChannelReq : u1:chidx, u3:freq, u1:DRrange
MCMD_RXTimingSetupReq = 0x08, // : u1: [7-4]:RFU [3-0]: Delay 1-15s (0 => 1)
MCMD_TxParamSetupReq = 0x09, // : u1: [7-6]:RFU [5:4]: dl dwell/ul dwell [3:0] max EIRP
MCMD_DIChannelReq = 0x0A, // : u1: channel, u3: frequency
// Class B
MCMD_PING_SET = 0x11, // set ping freq : u3: freq
MCMD_BCNI_ANS = 0x12, // next beacon start : u2: delay(in TUNIT millis), u1:channel
};
enum {
MCMD_BCNI_TUNIT = 30 // time unit of delay value in millis
};
enum {
MCMD_LADR_ANS_RFU = 0xF8, // RFU bits
MCMD_LADR_ANS_POWACK = 0x04, // 0=not supported power level
MCMD_LADR_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_LADR_ANS_CHACK = 0x01, // 0=unknown channel enabled
};
enum {
MCMD_DN2P_ANS_RFU = 0xF8, // RFU bits
MCMD_DN2P_ANS_RX1DrOffsetAck = 0x04, // 0=dr2 not allowed
MCMD_DN2P_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_DN2P_ANS_CHACK = 0x01, // 0=unknown channel enabled
};
enum {
MCMD_SNCH_ANS_RFU = 0xFC, // RFU bits
MCMD_SNCH_ANS_DRACK = 0x02, // 0=unknown data rate
MCMD_SNCH_ANS_FQACK = 0x01, // 0=rejected channel frequency
};
enum {
MCMD_PING_ANS_RFU = 0xFE,
MCMD_PING_ANS_FQACK = 0x01
};
enum {
MCMD_DEVS_EXT_POWER = 0x00, // external power supply
MCMD_DEVS_BATT_MIN = 0x01, // min battery value
MCMD_DEVS_BATT_MAX = 0xFE, // max battery value
MCMD_DEVS_BATT_NOINFO = 0xFF, // unknown battery level
};
// Bit fields byte#3 of MCMD_LADR_REQ payload
enum {
MCMD_LADR_CHP_USLIKE_SPECIAL = 0x50, // first special for us-like
MCMD_LADR_CHP_BANK = 0x50, // special: bits are banks.
MCMD_LADR_CHP_125ON = 0x60, // special channel page enable, bits applied to 64..71
MCMD_LADR_CHP_125OFF = 0x70, // special channel page: disble 125K, bits apply to 64..71
MCMD_LADR_N3RFU_MASK = 0x80,
MCMD_LADR_CHPAGE_MASK = 0xF0,
MCMD_LADR_REPEAT_MASK = 0x0F,
MCMD_LADR_REPEAT_1 = 0x01,
MCMD_LADR_CHPAGE_1 = 0x10
};
// Bit fields byte#0 of MCMD_LADR_REQ payload
enum {
MCMD_LADR_DR_MASK = 0xF0,
MCMD_LADR_POW_MASK = 0x0F,
MCMD_LADR_DR_SHIFT = 4,
MCMD_LADR_POW_SHIFT = 0,
#if defined(CFG_eu868) // TODO(tmm@mcci.com): complete refactor.
EU868_MCMD_LADR_SF12 = EU868_DR_SF12<<4,
EU868_MCMD_LADR_SF11 = EU868_DR_SF11<<4,
EU868_MCMD_LADR_SF10 = EU868_DR_SF10<<4,
EU868_MCMD_LADR_SF9 = EU868_DR_SF9 <<4,
EU868_MCMD_LADR_SF8 = EU868_DR_SF8 <<4,
EU868_MCMD_LADR_SF7 = EU868_DR_SF7 <<4,
EU868_MCMD_LADR_SF7B = EU868_DR_SF7B<<4,
EU868_MCMD_LADR_FSK = EU868_DR_FSK <<4,
EU868_MCMD_LADR_20dBm = 0,
EU868_MCMD_LADR_14dBm = 1,
EU868_MCMD_LADR_11dBm = 2,
EU868_MCMD_LADR_8dBm = 3,
EU868_MCMD_LADR_5dBm = 4,
EU868_MCMD_LADR_2dBm = 5,
#elif defined(CFG_us915)
US915_MCMD_LADR_SF10 = US915_DR_SF10<<4,
US915_MCMD_LADR_SF9 = US915_DR_SF9 <<4,
US915_MCMD_LADR_SF8 = US915_DR_SF8 <<4,
US915_MCMD_LADR_SF7 = US915_DR_SF7 <<4,
US915_MCMD_LADR_SF8C = US915_DR_SF8C<<4,
US915_MCMD_LADR_SF12CR = US915_DR_SF12CR<<4,
US915_MCMD_LADR_SF11CR = US915_DR_SF11CR<<4,
US915_MCMD_LADR_SF10CR = US915_DR_SF10CR<<4,
US915_MCMD_LADR_SF9CR = US915_DR_SF9CR<<4,
US915_MCMD_LADR_SF8CR = US915_DR_SF8CR<<4,
US915_MCMD_LADR_SF7CR = US915_DR_SF7CR<<4,
US915_MCMD_LADR_30dBm = 0,
US915_MCMD_LADR_28dBm = 1,
US915_MCMD_LADR_26dBm = 2,
US915_MCMD_LADR_24dBm = 3,
US915_MCMD_LADR_22dBm = 4,
US915_MCMD_LADR_20dBm = 5,
US915_MCMD_LADR_18dBm = 6,
US915_MCMD_LADR_16dBm = 7,
US915_MCMD_LADR_14dBm = 8,
US915_MCMD_LADR_12dBm = 9,
US915_MCMD_LADR_10dBm = 10
#endif
};
// bit fields of the TxParam request
enum {
MCMD_TxParam_RxDWELL_SHIFT = 5,
MCMD_TxParam_RxDWELL_MASK = 1 << MCMD_TxParam_RxDWELL_SHIFT,
MCMD_TxParam_TxDWELL_SHIFT = 4,
MCMD_TxParam_TxDWELL_MASK = 1 << MCMD_TxParam_TxDWELL_SHIFT,
MCMD_TxParam_MaxEIRP_SHIFT = 0,
MCMD_TxParam_MaxEIRP_MASK = 0xF << MCMD_TxParam_MaxEIRP_SHIFT,
};
// Device address
typedef u4_t devaddr_t;
// RX quality (device)
enum { RSSI_OFF=64, SNR_SCALEUP=4 };
inline sf_t getSf (rps_t params) { return (sf_t)(params & 0x7); }
inline rps_t setSf (rps_t params, sf_t sf) { return (rps_t)((params & ~0x7) | sf); }
inline bw_t getBw (rps_t params) { return (bw_t)((params >> 3) & 0x3); }
inline rps_t setBw (rps_t params, bw_t cr) { return (rps_t)((params & ~0x18) | (cr<<3)); }
inline cr_t getCr (rps_t params) { return (cr_t)((params >> 5) & 0x3); }
inline rps_t setCr (rps_t params, cr_t cr) { return (rps_t)((params & ~0x60) | (cr<<5)); }
inline int getNocrc(rps_t params) { return ((params >> 7) & 0x1); }
inline rps_t setNocrc(rps_t params, int nocrc) { return (rps_t)((params & ~0x80) | (nocrc<<7)); }
inline int getIh (rps_t params) { return ((params >> 8) & 0xFF); }
inline rps_t setIh (rps_t params, int ih) { return (rps_t)((params & ~0xFF00) | (ih<<8)); }
inline rps_t makeRps (sf_t sf, bw_t bw, cr_t cr, int ih, int nocrc) {
return sf | (bw<<3) | (cr<<5) | (nocrc?(1<<7):0) | ((ih&0xFF)<<8);
}
#define MAKERPS(sf,bw,cr,ih,nocrc) ((rps_t)((sf) | ((bw)<<3) | ((cr)<<5) | ((nocrc)?(1<<7):0) | ((ih&0xFF)<<8)))
// Two frames with params r1/r2 would interfere on air: same SFx + BWx
inline int sameSfBw(rps_t r1, rps_t r2) { return ((r1^r2)&0x1F) == 0; }
extern CONST_TABLE(u1_t, _DR2RPS_CRC)[];
inline rps_t updr2rps (dr_t dr) { return (rps_t)TABLE_GET_U1(_DR2RPS_CRC, dr+1); }
inline rps_t dndr2rps (dr_t dr) { return setNocrc(updr2rps(dr),1); }
inline int isFasterDR (dr_t dr1, dr_t dr2) { return dr1 > dr2; }
inline int isSlowerDR (dr_t dr1, dr_t dr2) { return dr1 < dr2; }
inline dr_t incDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+2)==ILLEGAL_RPS ? dr : (dr_t)(dr+1); } // increase data rate
inline dr_t decDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr )==ILLEGAL_RPS ? dr : (dr_t)(dr-1); } // decrease data rate
inline dr_t assertDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+1)==ILLEGAL_RPS ? DR_DFLTMIN : dr; } // force into a valid DR
inline bit_t validDR (dr_t dr) { return TABLE_GET_U1(_DR2RPS_CRC, dr+1)!=ILLEGAL_RPS; } // in range
inline dr_t lowerDR (dr_t dr, u1_t n) { while(n--){dr=decDR(dr);} return dr; } // decrease data rate by n steps
//
// BEG: Keep in sync with lorabase.hpp
// ================================================================================
// Calculate airtime
ostime_t calcAirTime (rps_t rps, u1_t plen);
// Sensitivity at given SF/BW
int getSensitivity (rps_t rps);
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _lorabase_h_

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved.
*
* Copyright (c) 2017 MCCI Corporation
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_as923_h_
#define _lorabase_as923_h_
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
/****************************************************************************\
|
| Basic definitions for AS923 (always in scope)
|
\****************************************************************************/
enum _dr_as923_t {
AS923_DR_SF12 = 0,
AS923_DR_SF11,
AS923_DR_SF10,
AS923_DR_SF9,
AS923_DR_SF8,
AS923_DR_SF7,
AS923_DR_SF7B,
AS923_DR_FSK,
AS923_DR_NONE
};
// Bands:
// g1 : 1% 16dBm
// freq band datarates
enum {
AS923_F1 = 923200000, // g1 SF7-12
AS923_F2 = 923400000, // g1 SF7-12
AS923_FDOWN = 923200000, // (RX2 freq, DR2)
AS923_FBCN = 923400000, // default BCN, DR3
AS923_FPING = 923400000, // default ping, DR3
};
enum {
AS923_FREQ_MIN = 915000000,
AS923_FREQ_MAX = 928000000
};
enum {
AS923_TX_EIRP_MAX_DBM = 16 // 16 dBm
};
enum { DR_PAGE_AS923 = 0x10 * (LMIC_REGION_as923 - 1) };
enum { AS923_LMIC_REGION_EIRP = 1 }; // region uses EIRP
enum { AS923JP_LBT_US = 5000 }; // microseconds of LBT time -- 5000 ==>
// 5 ms. We use us rather than ms for
// future 128us support, and just for
// backward compatibility -- there
// is code that uses the _US constant,
// and it's awkward to break it.
enum { AS923JP_LBT_DB_MAX = -80 }; // maximum channel strength in dB; if TX
// we measure more than this, we don't tx.
// AS923 v1.1, all channels face a 1% duty cycle. So this will have to change
// in the future via a config. But this code base needs major changes for
// v1.1 in any case.
enum { AS923_V102_TX_CAP = 100 }; // v1.0.2 allows 100%
#ifndef AS923_TX_CAP
# define AS923_TX_CAP AS923_V102_TX_CAP
#endif
#endif /* _lorabase_as923_h_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved.
*
* Copyright (c) 2017 MCCI Corporation
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_au921_h_
#define _lorabase_au921_h_
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
/****************************************************************************\
|
| Basic definitions for AS921 (always in scope)
|
\****************************************************************************/
// Frequency plan for AU 921 MHz
enum _dr_as921_t {
AU921_DR_SF12 = 0,
AU921_DR_SF11,
AU921_DR_SF10,
AU921_DR_SF9,
AU921_DR_SF8,
AU921_DR_SF7,
AU921_DR_SF8C,
AU921_DR_NONE,
// Devices behind a router:
AU921_DR_SF12CR = 8,
AU921_DR_SF11CR,
AU921_DR_SF10CR,
AU921_DR_SF9CR,
AU921_DR_SF8CR,
AU921_DR_SF7CR
};
// Default frequency plan for AU 921MHz
enum {
AU921_125kHz_UPFBASE = 915200000,
AU921_125kHz_UPFSTEP = 200000,
AU921_500kHz_UPFBASE = 915900000,
AU921_500kHz_UPFSTEP = 1600000,
AU921_500kHz_DNFBASE = 923300000,
AU921_500kHz_DNFSTEP = 600000
};
enum {
AU921_FREQ_MIN = 915000000,
AU921_FREQ_MAX = 928000000
};
enum {
AU921_TX_EIRP_MAX_DBM = 30 // 30 dBm
};
enum { DR_PAGE_AU921 = 0x10 * (LMIC_REGION_au921 - 1) };
enum { AU921_LMIC_REGION_EIRP = 1 }; // region uses EIRP
#endif /* _lorabase_au921_h_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved.
*
* Copyright (c) 2017 MCCI Corporation
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_eu868_h_
#define _lorabase_eu868_h_
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
/****************************************************************************\
|
| Basic definitions for EU868 (always in scope)
|
\****************************************************************************/
//
// Default frequency plan for EU 868MHz ISM band
// data rates
// this is a little confusing: the integer values of these constants are the
// DataRates from the LoRaWAN Regional Parmaeter spec. The names are just
// convenient indications, so we can use them in the rare case that we need to
// choose a DataRate by SF and configuration, not by DR code.
enum _dr_eu868_t {
EU868_DR_SF12 = 0,
EU868_DR_SF11,
EU868_DR_SF10,
EU868_DR_SF9,
EU868_DR_SF8,
EU868_DR_SF7,
EU868_DR_SF7B,
EU868_DR_FSK,
EU868_DR_NONE
};
// Bands:
// g1 : 1% 14dBm
// g2 : 0.1% 14dBm
// g3 : 10% 27dBm
// freq band datarates
enum {
EU868_F1 = 868100000, // g1 SF7-12
EU868_F2 = 868300000, // g1 SF7-12 FSK SF7/250
EU868_F3 = 868500000, // g1 SF7-12
EU868_F4 = 868850000, // g2 SF7-12
EU868_F5 = 869050000, // g2 SF7-12
EU868_F6 = 869525000, // g3 SF7-12
EU868_J4 = 864100000, // g2 SF7-12 used during join
EU868_J5 = 864300000, // g2 SF7-12 ditto
EU868_J6 = 864500000, // g2 SF7-12 ditto
};
enum {
EU868_FREQ_MIN = 863000000,
EU868_FREQ_MAX = 870000000
};
enum {
EU868_TX_EIRP_MAX_DBM = 16 // 16 dBm EIRP. So subtract 3 dBm for a 3 dBi antenna.
};
enum { EU868_LMIC_REGION_EIRP = 1 }; // region uses EIRP
enum { DR_PAGE_EU868 = 0x10 * (LMIC_REGION_eu868 - 1) };
#endif /* _lorabase_eu868_h_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved.
*
* Copyright (c) 2017 MCCI Corporation
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_in866_h_
#define _lorabase_in866_h_
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
/****************************************************************************\
|
| Basic definitions for IN866 (always in scope)
|
\****************************************************************************/
enum _dr_in866_t {
IN866_DR_SF12 = 0, // DR0
IN866_DR_SF11, // DR1
IN866_DR_SF10, // DR2
IN866_DR_SF9, // DR3
IN866_DR_SF8, // DR4
IN866_DR_SF7, // DR5
IN866_DR_RFU, // -
IN866_DR_FSK, // DR7
IN866_DR_NONE
};
// There is no dwell-time or duty-cycle limitation for IN
//
// max power: 30dBM
//
// freq datarates
enum {
IN866_F1 = 865062500, // SF7-12 (DR0-5)
IN866_F2 = 865402500, // SF7-12 (DR0-5)
IN866_F3 = 865985000, // SF7-12 (DR0-5)
IN866_FB = 866550000, // beacon/ping
};
enum {
IN866_FREQ_MIN = 865000000,
IN866_FREQ_MAX = 867000000
};
enum {
IN866_TX_EIRP_MAX_DBM = 30 // 30 dBm
};
enum { DR_PAGE_IN866 = 0x10 * (LMIC_REGION_in866 - 1) };
enum { IN866_LMIC_REGION_EIRP = 1 }; // region uses EIRP
#endif /* _lorabase_in866_h_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved.
*
* Copyright (c) 2017 MCCI Corporation
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _lorabase_us915_h_
#define _lorabase_us915_h_
#ifndef _LMIC_CONFIG_PRECONDITIONS_H_
# include "lmic_config_preconditions.h"
#endif
/****************************************************************************\
|
| Basic definitions for US915 (always in scope)
|
\****************************************************************************/
// Frequency plan for US 915MHz ISM band
// data rates
enum _dr_us915_t {
US915_DR_SF10 = 0,
US915_DR_SF9,
US915_DR_SF8,
US915_DR_SF7,
US915_DR_SF8C,
US915_DR_NONE,
// Devices "behind a router" (and upper half of DR list):
US915_DR_SF12CR = 8,
US915_DR_SF11CR,
US915_DR_SF10CR,
US915_DR_SF9CR,
US915_DR_SF8CR,
US915_DR_SF7CR
};
// Default frequency plan for US 915MHz
enum {
US915_125kHz_UPFBASE = 902300000,
US915_125kHz_UPFSTEP = 200000,
US915_500kHz_UPFBASE = 903000000,
US915_500kHz_UPFSTEP = 1600000,
US915_500kHz_DNFBASE = 923300000,
US915_500kHz_DNFSTEP = 600000
};
enum {
US915_FREQ_MIN = 902000000,
US915_FREQ_MAX = 928000000
};
enum {
US915_TX_MAX_DBM = 30 // 30 dBm (but not EIRP): assumes we're
// on an 64-channel bandplan. See code
// that computes tx power.
};
enum { DR_PAGE_US915 = 0x10 * (LMIC_REGION_us915 - 1) };
enum { US915_LMIC_REGION_EIRP = 0 }; // region doesn't use EIRP, uses tx power
#endif /* _lorabase_us915_h_ */

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/*
* Copyright (c) 2014-2016 IBM Corporation.
* Copyright (c) 2016-2017 MCCI Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the <organization> nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#define LMIC_DR_LEGACY 0
#include "lmic.h"
extern const struct lmic_pinmap lmic_pins;
// RUNTIME STATE
static struct {
osjob_t* scheduledjobs;
osjob_t* runnablejobs;
} OS;
int os_init_ex (const void *pintable) {
memset(&OS, 0x00, sizeof(OS));
hal_init_ex(pintable);
if (! radio_init())
return 0;
LMIC_init();
return 1;
}
void os_init() {
if (os_init_ex((const void *)&lmic_pins))
return;
ASSERT(0);
}
ostime_t os_getTime () {
return hal_ticks();
}
// unlink job from queue, return if removed
static int unlinkjob (osjob_t** pnext, osjob_t* job) {
for( ; *pnext; pnext = &((*pnext)->next)) {
if(*pnext == job) { // unlink
*pnext = job->next;
return 1;
}
}
return 0;
}
// clear scheduled job
void os_clearCallback (osjob_t* job) {
hal_disableIRQs();
unlinkjob(&OS.scheduledjobs, job) || unlinkjob(&OS.runnablejobs, job);
hal_enableIRQs();
}
// schedule immediately runnable job
void os_setCallback (osjob_t* job, osjobcb_t cb) {
osjob_t** pnext;
hal_disableIRQs();
// remove if job was already queued
unlinkjob(&OS.runnablejobs, job);
// fill-in job
job->func = cb;
job->next = NULL;
// add to end of run queue
for(pnext=&OS.runnablejobs; *pnext; pnext=&((*pnext)->next));
*pnext = job;
hal_enableIRQs();
}
// schedule timed job
void os_setTimedCallback (osjob_t* job, ostime_t time, osjobcb_t cb) {
osjob_t** pnext;
hal_disableIRQs();
// remove if job was already queued
unlinkjob(&OS.scheduledjobs, job);
// fill-in job
job->deadline = time;
job->func = cb;
job->next = NULL;
// insert into schedule
for(pnext=&OS.scheduledjobs; *pnext; pnext=&((*pnext)->next)) {
if((*pnext)->deadline - time > 0) { // (cmp diff, not abs!)
// enqueue before next element and stop
job->next = *pnext;
break;
}
}
*pnext = job;
hal_enableIRQs();
}
// execute jobs from timer and from run queue
void os_runloop () {
while(1) {
os_runloop_once();
}
}
void os_runloop_once() {
osjob_t* j = NULL;
hal_disableIRQs();
// check for runnable jobs
if(OS.runnablejobs) {
j = OS.runnablejobs;
OS.runnablejobs = j->next;
} else if(OS.scheduledjobs && hal_checkTimer(OS.scheduledjobs->deadline)) { // check for expired timed jobs
j = OS.scheduledjobs;
OS.scheduledjobs = j->next;
} else { // nothing pending
hal_sleep(); // wake by irq (timer already restarted)
}
hal_enableIRQs();
if(j) { // run job callback
j->func(j);
}
}

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/******************************************************************************* /*
* Copyright (c) 2014-2015 IBM Corporation. * Copyright (c) 2014-2016 IBM Corporation.
* All rights reserved. This program and the accompanying materials * All rights reserved.
* are made available under the terms of the Eclipse Public License v1.0 *
* which accompanies this distribution, and is available at * Redistribution and use in source and binary forms, with or without
* http://www.eclipse.org/legal/epl-v10.html * modification, are permitted provided that the following conditions are met:
* * * Redistributions of source code must retain the above copyright
* Contributors: * notice, this list of conditions and the following disclaimer.
* IBM Zurich Research Lab - initial API, implementation and documentation * * Redistributions in binary form must reproduce the above copyright
*******************************************************************************/ * notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
//! \file * * Neither the name of the <organization> nor the
#ifndef _oslmic_h_ * names of its contributors may be used to endorse or promote products
#define _oslmic_h_ * derived from this software without specific prior written permission.
*
// Dependencies required for the LoRa MAC in C to run. * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
// These settings can be adapted to the underlying system. * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
// You should not, however, change the lmic.[hc] * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
#include "config.h" * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
#include <stdint.h> * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
#include <stdio.h> * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
#ifdef __cplusplus * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
extern "C"{ * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#endif */
//================================================================================ //! \file
//================================================================================ #ifndef _oslmic_h_
// Target platform as C library #define _oslmic_h_
typedef uint8_t bit_t;
typedef uint8_t u1_t; // Dependencies required for the LoRa MAC in C to run.
typedef int8_t s1_t; // These settings can be adapted to the underlying system.
typedef uint16_t u2_t; // You should not, however, change the lmic.[hc]
typedef int16_t s2_t;
typedef uint32_t u4_t; #include "config.h"
typedef int32_t s4_t; #include <stdint.h>
typedef unsigned int uint;
typedef const char* str_t; #ifdef __cplusplus
extern "C"{
#include <string.h> #endif
#include "hal.h"
#define EV(a,b,c) /**/ //================================================================================
#define DO_DEVDB(field1,field2) /**/ //================================================================================
#if !defined(CFG_noassert) // Target platform as C library
#define ASSERT(cond) if(!(cond)) hal_failed(__FILE__, __LINE__) typedef uint8_t bit_t;
#else typedef uint8_t u1_t;
#define ASSERT(cond) /**/ typedef int8_t s1_t;
#endif typedef uint16_t u2_t;
typedef int16_t s2_t;
#define os_clearMem(a,b) memset(a,0,b) typedef uint32_t u4_t;
#define os_copyMem(a,b,c) memcpy(a,b,c) typedef int32_t s4_t;
typedef unsigned int uint;
typedef struct osjob_t osjob_t; typedef const char* str_t;
typedef struct band_t band_t;
typedef struct chnldef_t chnldef_t; #include <string.h>
typedef struct rxsched_t rxsched_t; #include "hal.h"
typedef struct bcninfo_t bcninfo_t; #define EV(a,b,c) /**/
typedef const u1_t* xref2cu1_t; #define DO_DEVDB(field1,field2) /**/
typedef u1_t* xref2u1_t; #if !defined(CFG_noassert)
#define TYPEDEF_xref2rps_t typedef rps_t* xref2rps_t #define ASSERT(cond) if(!(cond)) hal_failed(__FILE__, __LINE__)
#define TYPEDEF_xref2rxsched_t typedef rxsched_t* xref2rxsched_t #else
#define TYPEDEF_xref2chnldef_t typedef chnldef_t* xref2chnldef_t #define ASSERT(cond) /**/
#define TYPEDEF_xref2band_t typedef band_t* xref2band_t #endif
#define TYPEDEF_xref2osjob_t typedef osjob_t* xref2osjob_t
#define os_clearMem(a,b) memset(a,0,b)
#define SIZEOFEXPR(x) sizeof(x) #define os_copyMem(a,b,c) memcpy(a,b,c)
#define ON_LMIC_EVENT(ev) onEvent(ev) typedef struct osjob_t osjob_t;
#define DECL_ON_LMIC_EVENT void onEvent(ev_t e) typedef struct band_t band_t;
typedef struct chnldef_t chnldef_t;
extern u4_t AESAUX[]; typedef struct rxsched_t rxsched_t;
extern u4_t AESKEY[]; typedef struct bcninfo_t bcninfo_t;
#define AESkey ((u1_t*)AESKEY) typedef const u1_t* xref2cu1_t;
#define AESaux ((u1_t*)AESAUX) typedef u1_t* xref2u1_t;
#define FUNC_ADDR(func) (&(func)) typedef s4_t ostime_t;
u1_t radio_rand1 (void); #define TYPEDEF_xref2rps_t typedef rps_t* xref2rps_t
#define os_getRndU1() radio_rand1() #define TYPEDEF_xref2rxsched_t typedef rxsched_t* xref2rxsched_t
#define TYPEDEF_xref2chnldef_t typedef chnldef_t* xref2chnldef_t
#define DEFINE_LMIC struct lmic_t LMIC #define TYPEDEF_xref2band_t typedef band_t* xref2band_t
#define DECLARE_LMIC extern struct lmic_t LMIC #define TYPEDEF_xref2osjob_t typedef osjob_t* xref2osjob_t
void radio_init (void); #define SIZEOFEXPR(x) sizeof(x)
void radio_irq_handler (u1_t dio);
void os_init (void); #define ON_LMIC_EVENT(ev) onEvent(ev)
void os_runloop (void); #define DECL_ON_LMIC_EVENT void onEvent(ev_t e)
void os_runloop_once (void);
extern u4_t AESAUX[];
//================================================================================ extern u4_t AESKEY[];
#define AESkey ((u1_t*)AESKEY)
#define AESaux ((u1_t*)AESAUX)
#ifndef RX_RAMPUP #define FUNC_ADDR(func) (&(func))
#define RX_RAMPUP (us2osticks(2000))
#endif u1_t radio_rand1 (void);
#ifndef TX_RAMPUP #define os_getRndU1() radio_rand1()
#define TX_RAMPUP (us2osticks(2000))
#endif #define DEFINE_LMIC struct lmic_t LMIC
#define DECLARE_LMIC extern struct lmic_t LMIC
#ifndef OSTICKS_PER_SEC
#define OSTICKS_PER_SEC 32768 typedef struct oslmic_radio_rssi_s oslmic_radio_rssi_t;
#elif OSTICKS_PER_SEC < 10000 || OSTICKS_PER_SEC > 64516
#error Illegal OSTICKS_PER_SEC - must be in range [10000:64516]. One tick must be 15.5us .. 100us long. struct oslmic_radio_rssi_s {
#endif s2_t min_rssi;
s2_t max_rssi;
typedef s4_t ostime_t; s2_t mean_rssi;
u2_t n_rssi;
#if !HAS_ostick_conv };
#define us2osticks(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC) / 1000000))
#define ms2osticks(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC) / 1000)) int radio_init (void);
#define sec2osticks(sec) ((ostime_t)( (int64_t)(sec) * OSTICKS_PER_SEC)) void radio_irq_handler (u1_t dio);
#define osticks2ms(os) ((s4_t)(((os)*(int64_t)1000 ) / OSTICKS_PER_SEC)) void radio_irq_handler_v2 (u1_t dio, ostime_t tref);
#define osticks2us(os) ((s4_t)(((os)*(int64_t)1000000 ) / OSTICKS_PER_SEC)) void os_init (void);
// Special versions int os_init_ex (const void *pPinMap);
#define us2osticksCeil(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC + 999999) / 1000000)) void os_runloop (void);
#define us2osticksRound(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC + 500000) / 1000000)) void os_runloop_once (void);
#define ms2osticksCeil(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC + 999) / 1000)) u1_t radio_rssi (void);
#define ms2osticksRound(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC + 500) / 1000)) void radio_monitor_rssi(ostime_t n, oslmic_radio_rssi_t *pRssi);
#endif
//================================================================================
struct osjob_t; // fwd decl.
typedef void (*osjobcb_t) (struct osjob_t*); #ifndef RX_RAMPUP
struct osjob_t { #define RX_RAMPUP (us2osticks(2000))
struct osjob_t* next; #endif
ostime_t deadline; #ifndef TX_RAMPUP
osjobcb_t func; #define TX_RAMPUP (us2osticks(2000))
}; #endif
TYPEDEF_xref2osjob_t;
#ifndef OSTICKS_PER_SEC
#define OSTICKS_PER_SEC 32768
#ifndef HAS_os_calls #elif OSTICKS_PER_SEC < 10000 || OSTICKS_PER_SEC > 64516
#error Illegal OSTICKS_PER_SEC - must be in range [10000:64516]. One tick must be 15.5us .. 100us long.
#ifndef os_getDevKey #endif
void os_getDevKey (xref2u1_t buf);
#endif #if !HAS_ostick_conv
#ifndef os_getArtEui #define us2osticks(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC) / 1000000))
void os_getArtEui (xref2u1_t buf); #define ms2osticks(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC) / 1000))
#endif #define sec2osticks(sec) ((ostime_t)( (int64_t)(sec) * OSTICKS_PER_SEC))
#ifndef os_getDevEui #define osticks2ms(os) ((s4_t)(((os)*(int64_t)1000 ) / OSTICKS_PER_SEC))
void os_getDevEui (xref2u1_t buf); #define osticks2us(os) ((s4_t)(((os)*(int64_t)1000000 ) / OSTICKS_PER_SEC))
#endif // Special versions
#ifndef os_setCallback #define us2osticksCeil(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC + 999999) / 1000000))
void os_setCallback (xref2osjob_t job, osjobcb_t cb); #define us2osticksRound(us) ((ostime_t)( ((int64_t)(us) * OSTICKS_PER_SEC + 500000) / 1000000))
#endif #define ms2osticksCeil(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC + 999) / 1000))
#ifndef os_setTimedCallback #define ms2osticksRound(ms) ((ostime_t)( ((int64_t)(ms) * OSTICKS_PER_SEC + 500) / 1000))
void os_setTimedCallback (xref2osjob_t job, ostime_t time, osjobcb_t cb); #endif
#endif
#ifndef os_clearCallback
void os_clearCallback (xref2osjob_t job); struct osjob_t; // fwd decl.
#endif typedef void (*osjobcb_t) (struct osjob_t*);
#ifndef os_getTime struct osjob_t {
ostime_t os_getTime (void); struct osjob_t* next;
#endif ostime_t deadline;
#ifndef os_getTimeSecs osjobcb_t func;
uint os_getTimeSecs (void); };
#endif TYPEDEF_xref2osjob_t;
#ifndef os_radio
void os_radio (u1_t mode);
#endif #ifndef HAS_os_calls
#ifndef os_getBattLevel
u1_t os_getBattLevel (void); #ifndef os_getDevKey
#endif void os_getDevKey (xref2u1_t buf);
#endif
#ifndef os_rlsbf4 #ifndef os_getArtEui
//! Read 32-bit quantity from given pointer in little endian byte order. void os_getArtEui (xref2u1_t buf);
u4_t os_rlsbf4 (xref2cu1_t buf); #endif
#endif #ifndef os_getDevEui
#ifndef os_wlsbf4 void os_getDevEui (xref2u1_t buf);
//! Write 32-bit quntity into buffer in little endian byte order. #endif
void os_wlsbf4 (xref2u1_t buf, u4_t value); #ifndef os_setCallback
#endif void os_setCallback (xref2osjob_t job, osjobcb_t cb);
#ifndef os_rmsbf4 #endif
//! Read 32-bit quantity from given pointer in big endian byte order. #ifndef os_setTimedCallback
u4_t os_rmsbf4 (xref2cu1_t buf); void os_setTimedCallback (xref2osjob_t job, ostime_t time, osjobcb_t cb);
#endif #endif
#ifndef os_wmsbf4 #ifndef os_clearCallback
//! Write 32-bit quntity into buffer in big endian byte order. void os_clearCallback (xref2osjob_t job);
void os_wmsbf4 (xref2u1_t buf, u4_t value); #endif
#endif #ifndef os_getTime
#ifndef os_rlsbf2 ostime_t os_getTime (void);
//! Read 16-bit quantity from given pointer in little endian byte order. #endif
u2_t os_rlsbf2 (xref2cu1_t buf); #ifndef os_getTimeSecs
#endif uint os_getTimeSecs (void);
#ifndef os_wlsbf2 #endif
//! Write 16-bit quntity into buffer in little endian byte order. #ifndef os_radio
void os_wlsbf2 (xref2u1_t buf, u2_t value); void os_radio (u1_t mode);
#endif #endif
#ifndef os_getBattLevel
//! Get random number (default impl for u2_t). u1_t os_getBattLevel (void);
#ifndef os_getRndU2 #endif
#define os_getRndU2() ((u2_t)((os_getRndU1()<<8)|os_getRndU1()))
#endif #ifndef os_rlsbf4
#ifndef os_crc16 //! Read 32-bit quantity from given pointer in little endian byte order.
u2_t os_crc16 (xref2u1_t d, uint len); u4_t os_rlsbf4 (xref2cu1_t buf);
#endif #endif
#ifndef os_wlsbf4
#endif // !HAS_os_calls //! Write 32-bit quntity into buffer in little endian byte order.
void os_wlsbf4 (xref2u1_t buf, u4_t value);
// ====================================================================== #endif
// Table support #ifndef os_rmsbf4
// These macros for defining a table of constants and retrieving values //! Read 32-bit quantity from given pointer in big endian byte order.
// from it makes it easier for other platforms (like AVR) to optimize u4_t os_rmsbf4 (xref2cu1_t buf);
// table accesses. #endif
// Use CONST_TABLE() whenever declaring or defining a table, and #ifndef os_wmsbf4
// TABLE_GET_xx whenever accessing its values. The actual name of the //! Write 32-bit quntity into buffer in big endian byte order.
// declared variable will be modified to prevent accidental direct void os_wmsbf4 (xref2u1_t buf, u4_t value);
// access. The accessor macros forward to an inline function to allow #endif
// proper type checking of the array element type. #ifndef os_rlsbf2
//! Read 16-bit quantity from given pointer in little endian byte order.
// Helper to add a prefix to the table name u2_t os_rlsbf2 (xref2cu1_t buf);
#define RESOLVE_TABLE(table) constant_table_ ## table #endif
#ifndef os_wlsbf2
// Accessors for table elements //! Write 16-bit quntity into buffer in little endian byte order.
#define TABLE_GET_U1(table, index) table_get_u1(RESOLVE_TABLE(table), index) void os_wlsbf2 (xref2u1_t buf, u2_t value);
#define TABLE_GET_S1(table, index) table_get_s1(RESOLVE_TABLE(table), index) #endif
#define TABLE_GET_U2(table, index) table_get_u2(RESOLVE_TABLE(table), index)
#define TABLE_GET_S2(table, index) table_get_s2(RESOLVE_TABLE(table), index) //! Get random number (default impl for u2_t).
#define TABLE_GET_U4(table, index) table_get_u4(RESOLVE_TABLE(table), index) #ifndef os_getRndU2
#define TABLE_GET_S4(table, index) table_get_s4(RESOLVE_TABLE(table), index) #define os_getRndU2() ((u2_t)((os_getRndU1()<<8)|os_getRndU1()))
#define TABLE_GET_OSTIME(table, index) table_get_ostime(RESOLVE_TABLE(table), index) #endif
#define TABLE_GET_U1_TWODIM(table, index1, index2) table_get_u1(RESOLVE_TABLE(table)[index1], index2) #ifndef os_crc16
u2_t os_crc16 (xref2cu1_t d, uint len);
#if defined(__AVR__) #endif
#include <avr/pgmspace.h>
// Macro to define the getter functions. This loads data from #endif // !HAS_os_calls
// progmem using pgm_read_xx, or accesses memory directly when the
// index is a constant so gcc can optimize it away; // ======================================================================
#define TABLE_GETTER(postfix, type, pgm_type) \ // Table support
inline type table_get ## postfix(const type *table, size_t index) { \ // These macros for defining a table of constants and retrieving values
if (__builtin_constant_p(table[index])) \ // from it makes it easier for other platforms (like AVR) to optimize
return table[index]; \ // table accesses.
return pgm_read_ ## pgm_type(&table[index]); \ // Use CONST_TABLE() whenever declaring or defining a table, and
} // TABLE_GET_xx whenever accessing its values. The actual name of the
// declared variable will be modified to prevent accidental direct
TABLE_GETTER(_u1, u1_t, byte); // access. The accessor macros forward to an inline function to allow
TABLE_GETTER(_s1, s1_t, byte); // proper type checking of the array element type.
TABLE_GETTER(_u2, u2_t, word);
TABLE_GETTER(_s2, s2_t, word); // Helper to add a prefix to the table name
TABLE_GETTER(_u4, u4_t, dword); #define RESOLVE_TABLE(table) constant_table_ ## table
TABLE_GETTER(_s4, s4_t, dword);
// get number of entries in table
// This assumes ostime_t is 4 bytes, so error out if it is not #define LENOF_TABLE(table) (sizeof(RESOLVE_TABLE(table)) / sizeof(RESOLVE_TABLE(table)[0]))
typedef int check_sizeof_ostime_t[(sizeof(ostime_t) == 4) ? 0 : -1];
TABLE_GETTER(_ostime, ostime_t, dword); // Accessors for table elements
#define TABLE_GET_U1(table, index) table_get_u1(RESOLVE_TABLE(table), index)
// For AVR, store constants in PROGMEM, saving on RAM usage #define TABLE_GET_S1(table, index) table_get_s1(RESOLVE_TABLE(table), index)
#define CONST_TABLE(type, name) const type PROGMEM RESOLVE_TABLE(name) #define TABLE_GET_U2(table, index) table_get_u2(RESOLVE_TABLE(table), index)
#define TABLE_GET_S2(table, index) table_get_s2(RESOLVE_TABLE(table), index)
#define lmic_printf(fmt, ...) printf_P(PSTR(fmt), ## __VA_ARGS__) #define TABLE_GET_U4(table, index) table_get_u4(RESOLVE_TABLE(table), index)
#else #define TABLE_GET_S4(table, index) table_get_s4(RESOLVE_TABLE(table), index)
inline u1_t table_get_u1(const u1_t *table, size_t index) { return table[index]; } #define TABLE_GET_OSTIME(table, index) table_get_ostime(RESOLVE_TABLE(table), index)
inline s1_t table_get_s1(const s1_t *table, size_t index) { return table[index]; } #define TABLE_GET_U1_TWODIM(table, index1, index2) table_get_u1(RESOLVE_TABLE(table)[index1], index2)
inline u2_t table_get_u2(const u2_t *table, size_t index) { return table[index]; }
inline s2_t table_get_s2(const s2_t *table, size_t index) { return table[index]; } #if defined(__AVR__)
inline u4_t table_get_u4(const u4_t *table, size_t index) { return table[index]; } #include <avr/pgmspace.h>
inline s4_t table_get_s4(const s4_t *table, size_t index) { return table[index]; } // Macro to define the getter functions. This loads data from
inline ostime_t table_get_ostime(const ostime_t *table, size_t index) { return table[index]; } // progmem using pgm_read_xx, or accesses memory directly when the
// index is a constant so gcc can optimize it away;
// Declare a table #define TABLE_GETTER(postfix, type, pgm_type) \
#define CONST_TABLE(type, name) const type RESOLVE_TABLE(name) inline type table_get ## postfix(const type *table, size_t index) { \
#define lmic_printf printf if (__builtin_constant_p(table[index])) \
#endif return table[index]; \
return pgm_read_ ## pgm_type(&table[index]); \
// ====================================================================== }
// AES support
// !!Keep in sync with lorabase.hpp!! TABLE_GETTER(_u1, u1_t, byte);
TABLE_GETTER(_s1, s1_t, byte);
#ifndef AES_ENC // if AES_ENC is defined as macro all other values must be too TABLE_GETTER(_u2, u2_t, word);
#define AES_ENC 0x00 TABLE_GETTER(_s2, s2_t, word);
#define AES_DEC 0x01 TABLE_GETTER(_u4, u4_t, dword);
#define AES_MIC 0x02 TABLE_GETTER(_s4, s4_t, dword);
#define AES_CTR 0x04
#define AES_MICNOAUX 0x08 // This assumes ostime_t is 4 bytes, so error out if it is not
#endif typedef int check_sizeof_ostime_t[(sizeof(ostime_t) == 4) ? 0 : -1];
#ifndef AESkey // if AESkey is defined as macro all other values must be too TABLE_GETTER(_ostime, ostime_t, dword);
extern xref2u1_t AESkey;
extern xref2u1_t AESaux; // For AVR, store constants in PROGMEM, saving on RAM usage
#endif #define CONST_TABLE(type, name) const type PROGMEM RESOLVE_TABLE(name)
#ifndef os_aes #else
u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len); inline u1_t table_get_u1(const u1_t *table, size_t index) { return table[index]; }
#endif inline s1_t table_get_s1(const s1_t *table, size_t index) { return table[index]; }
inline u2_t table_get_u2(const u2_t *table, size_t index) { return table[index]; }
#ifdef __cplusplus inline s2_t table_get_s2(const s2_t *table, size_t index) { return table[index]; }
} // extern "C" inline u4_t table_get_u4(const u4_t *table, size_t index) { return table[index]; }
#endif inline s4_t table_get_s4(const s4_t *table, size_t index) { return table[index]; }
inline ostime_t table_get_ostime(const ostime_t *table, size_t index) { return table[index]; }
#endif // _oslmic_h_
// Declare a table
#define CONST_TABLE(type, name) const type RESOLVE_TABLE(name)
#endif
// ======================================================================
// AES support
// !!Keep in sync with lorabase.hpp!!
#ifndef AES_ENC // if AES_ENC is defined as macro all other values must be too
#define AES_ENC 0x00
#define AES_DEC 0x01
#define AES_MIC 0x02
#define AES_CTR 0x04
#define AES_MICNOAUX 0x08
#endif
#ifndef AESkey // if AESkey is defined as macro all other values must be too
extern xref2u1_t AESkey;
extern xref2u1_t AESaux;
#endif
#ifndef os_aes
u4_t os_aes (u1_t mode, xref2u1_t buf, u2_t len);
#endif
#ifdef __cplusplus
} // extern "C"
#endif
#endif // _oslmic_h_

View File

@ -8,7 +8,9 @@
[platformio] [platformio]
env_default = generic env_default = generic
;env_default = ebox ;env_default = ebox
;env_default = eboxtube
;env_default = heltec ;env_default = heltec
;env_default = heltecv2
;env_default = ttgov1 ;env_default = ttgov1
;env_default = ttgov2 ;env_default = ttgov2
;env_default = ttgov21old ;env_default = ttgov21old
@ -21,13 +23,13 @@ env_default = generic
;env_default = lolin32lora ;env_default = lolin32lora
;env_default = lolin32lite ;env_default = lolin32lite
;env_default = octopus32 ;env_default = octopus32
;env_default = ebox, heltec, ttgobeam, lopy4, lopy, ttgov21old, ttgov21new ;env_default = ebox, eboxtube, heltec, ttgobeam, lopy4, lopy, ttgov21old, ttgov21new
; ;
description = Paxcounter is a proof-of-concept ESP32 device for metering passenger flows in realtime. It counts how many mobile devices are around. description = Paxcounter is a proof-of-concept ESP32 device for metering passenger flows in realtime. It counts how many mobile devices are around.
[common] [common]
; for release_version use max. 10 chars total, use any decimal format like "a.b.c" ; for release_version use max. 10 chars total, use any decimal format like "a.b.c"
release_version = 1.6.1 release_version = 1.6.51
; DEBUG LEVEL: For production run set to 0, otherwise device will leak RAM while running! ; DEBUG LEVEL: For production run set to 0, otherwise device will leak RAM while running!
; 0=None, 1=Error, 2=Warn, 3=Info, 4=Debug, 5=Verbose ; 0=None, 1=Error, 2=Warn, 3=Info, 4=Debug, 5=Verbose
debug_level = 0 debug_level = 0
@ -41,6 +43,8 @@ board_build.partitions = min_spiffs.csv
monitor_speed = 115200 monitor_speed = 115200
lib_deps_all = lib_deps_all =
ArduinoJson@^5.13.1 ArduinoJson@^5.13.1
lib_deps_lora =
; MCCI LoRaWAN LMIC library@^2.2.2
lib_deps_display = lib_deps_display =
U8g2@>=2.23.16 U8g2@>=2.23.16
lib_deps_rgbled = lib_deps_rgbled =
@ -49,11 +53,10 @@ lib_deps_gps =
TinyGPSPlus@>=1.0.2 TinyGPSPlus@>=1.0.2
Time@>=1.5 Time@>=1.5
build_flags = build_flags =
; override lora settings from LMiC library in lmic/config.h and use main.h instead
-D_lmic_config_h_
-include "src/paxcounter.conf"
-include "src/hal/${PIOENV}.h" -include "src/hal/${PIOENV}.h"
-include "src/paxcounter.conf"
-w -w
'-DARDUINO_LMIC_PROJECT_CONFIG_H=../../../src/lmic_config.h'
'-DCORE_DEBUG_LEVEL=${common.debug_level}' '-DCORE_DEBUG_LEVEL=${common.debug_level}'
'-DBINTRAY_PACKAGE="${PIOENV}"' '-DBINTRAY_PACKAGE="${PIOENV}"'
'-DPROGVERSION="${common.release_version}"' '-DPROGVERSION="${common.release_version}"'
@ -61,11 +64,27 @@ build_flags =
[env:ebox] [env:ebox]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 115200 upload_speed = 115200
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
build_flags =
${common.build_flags}
upload_protocol = ${common.upload_protocol}
extra_scripts = ${common.extra_scripts}
monitor_speed = ${common.monitor_speed}
[env:eboxtube]
platform = ${common.platform_espressif32}
framework = arduino
board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions}
upload_speed = 115200
lib_deps =
${common.lib_deps_all}
${common.lib_deps_lora}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
upload_protocol = ${common.upload_protocol} upload_protocol = ${common.upload_protocol}
@ -80,6 +99,23 @@ board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display}
build_flags =
${common.build_flags}
upload_protocol = ${common.upload_protocol}
extra_scripts = ${common.extra_scripts}
monitor_speed = ${common.monitor_speed}
[env:heltecv2]
platform = ${common.platform_espressif32}
framework = arduino
board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600
lib_deps =
${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display} ${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -90,11 +126,12 @@ monitor_speed = ${common.monitor_speed}
[env:ttgov1] [env:ttgov1]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = ttgo-lora32-v1
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 115200 upload_speed = 115200
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display} ${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -105,11 +142,12 @@ monitor_speed = ${common.monitor_speed}
[env:ttgov2] [env:ttgov2]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = ttgo-lora32-v1
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display} ${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -120,11 +158,12 @@ monitor_speed = ${common.monitor_speed}
[env:ttgov21old] [env:ttgov21old]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display} ${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -135,11 +174,12 @@ monitor_speed = ${common.monitor_speed}
[env:ttgov21new] [env:ttgov21new]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_display} ${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -150,11 +190,12 @@ monitor_speed = ${common.monitor_speed}
[env:ttgobeam] [env:ttgobeam]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_gps} ${common.lib_deps_gps}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -166,11 +207,12 @@ monitor_speed = ${common.monitor_speed}
[env:fipy] [env:fipy]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -181,11 +223,12 @@ monitor_speed = ${common.monitor_speed}
[env:lopy] [env:lopy]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
${common.lib_deps_gps} ${common.lib_deps_gps}
build_flags = build_flags =
@ -197,11 +240,12 @@ monitor_speed = ${common.monitor_speed}
[env:lopy4] [env:lopy4]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
${common.lib_deps_gps} ${common.lib_deps_gps}
build_flags = build_flags =
@ -219,6 +263,7 @@ board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -234,6 +279,7 @@ board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
@ -259,12 +305,14 @@ monitor_speed = ${common.monitor_speed}
[env:octopus32] [env:octopus32]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = featheresp32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
${common.lib_deps_display}
build_flags = build_flags =
${common.build_flags} ${common.build_flags}
upload_protocol = ${common.upload_protocol} upload_protocol = ${common.upload_protocol}
@ -274,11 +322,12 @@ monitor_speed = ${common.monitor_speed}
[env:generic] [env:generic]
platform = ${common.platform_espressif32} platform = ${common.platform_espressif32}
framework = arduino framework = arduino
board = esp32dev board = heltec_wifi_lora_32
board_build.partitions = ${common.board_build.partitions} board_build.partitions = ${common.board_build.partitions}
upload_speed = 921600 upload_speed = 921600
lib_deps = lib_deps =
${common.lib_deps_all} ${common.lib_deps_all}
${common.lib_deps_lora}
${common.lib_deps_rgbled} ${common.lib_deps_rgbled}
${common.lib_deps_gps} ${common.lib_deps_gps}
${common.lib_deps_display} ${common.lib_deps_display}

View File

@ -4,7 +4,7 @@
#include "globals.h" #include "globals.h"
#include <esp_spi_flash.h> // needed for reading ESP32 chip attributes #include <esp_spi_flash.h> // needed for reading ESP32 chip attributes
HAS_DISPLAY u8x8(OLED_RST, I2C_SCL, I2C_SDA); HAS_DISPLAY u8x8(MY_OLED_RST, MY_OLED_SCL, MY_OLED_SDA);
// helper string for converting LoRa spread factor values // helper string for converting LoRa spread factor values
#if defined(CFG_eu868) #if defined(CFG_eu868)

View File

@ -1,21 +1,26 @@
#ifndef _EBOX_H
#define _EBOX_H
#include <stdint.h>
// Hardware related definitions for ebox ESP32-bit with external connected RFM95 LoRa // Hardware related definitions for ebox ESP32-bit with external connected RFM95 LoRa
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 #define CFG_sx1276_radio 1
#define HAS_LED GPIO_NUM_23 // blue LED on board #define HAS_LED (23) // blue LED on board
#define HAS_BUTTON GPIO_NUM_0 // button "PROG" on board #define HAS_BUTTON (0) // button "PROG" on board
#define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature #define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- SX1276 NSS (Pin19) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- SX1276 MOSI (Pin18) SPI Data Input #define LORA_CS (18)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- SX1276 SCK (Pin16) SPI Clock Input #define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// non arduino pin definitions #endif
#define RST GPIO_NUM_14 // ESP32 GPIO14 (Pin14) -- SX1276 NRESET (Pin7) Reset Trigger Input
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 (Pin15) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 (Pin13) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout
#define DIO2 LMIC_UNUSED_PIN // 32 ESP32 GPIO32 (Pin12) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only)

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@ -1,22 +1,27 @@
#ifndef _EBOXTUBE_H
#define _EBOXTUBE_H
#include <stdint.h>
// Hardware related definitions for ebox ESP32-bit with external connected RFM95 LoRa // Hardware related definitions for ebox ESP32-bit with external connected RFM95 LoRa
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 #define CFG_sx1276_radio 1
#define HAS_LED GPIO_NUM_22 // Green LED on board #define HAS_LED (22) // Green LED on board
#define HAS_RGB_LED GPIO_NUM_2 // WS2812B RGB LED on board #define HAS_RGB_LED (2) // WS2812B RGB LED on board
#define HAS_BUTTON GPIO_NUM_0 // button "FLASH" on board #define HAS_BUTTON (0) // button "FLASH" on board
#define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature #define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- SX1276 NSS (Pin19) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- SX1276 MOSI (Pin18) SPI Data Input #define LORA_CS (18)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- SX1276 SCK (Pin16) SPI Clock Input #define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)
// non arduino pin definitions #endif
#define RST GPIO_NUM_14 // ESP32 GPIO14 (Pin14) -- SX1276 NRESET (Pin7) Reset Trigger Input
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 (Pin15) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 (Pin13) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout
#define DIO2 GPIO_NUM_32 // ESP32 GPIO32 (Pin12) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only)

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@ -1,3 +1,8 @@
#ifndef _FIPY_H
#define _FIPY_H
#include <stdint.h>
// Hardware related definitions for Pycom FiPy Board // Hardware related definitions for Pycom FiPy Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -8,16 +13,18 @@
#define HAS_RGB_LED GPIO_NUM_0 // WS2812B RGB LED on GPIO0 #define HAS_RGB_LED GPIO_NUM_0 // WS2812B RGB LED on GPIO0
#define BOARD_HAS_PSRAM // use extra 4MB extern RAM #define BOARD_HAS_PSRAM // use extra 4MB extern RAM
// Hardware pin definitions for Pycom FiPy board // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_18 #define LORA_SCK (5)
#define PIN_SPI_MOSI GPIO_NUM_27 #define LORA_CS (18)
#define PIN_SPI_MISO GPIO_NUM_19 #define LORA_MISO (19)
#define PIN_SPI_SCK GPIO_NUM_5 #define LORA_MOSI (27)
#define RST LMIC_UNUSED_PIN #define LORA_RST LMIC_UNUSED_PIN
#define DIO0 GPIO_NUM_23 // LoRa IRQ #define LORA_IO0 (23) // LoRa IRQ
#define DIO1 GPIO_NUM_23 // workaround #define LORA_IO1 (23) // Pin tied via diode to DIO0
#define DIO2 LMIC_UNUSED_PIN #define LORA_IO2 LMIC_UNUSED_PIN
// select WIFI antenna (internal = onboard / external = u.fl socket) // select WIFI antenna (internal = onboard / external = u.fl socket)
#define HAS_ANTENNA_SWITCH GPIO_NUM_21 // pin for switching wifi antenna #define HAS_ANTENNA_SWITCH GPIO_NUM_21 // pin for switching wifi antenna
#define WIFI_ANTENNA 0 // 0 = internal, 1 = external #define WIFI_ANTENNA 0 // 0 = internal, 1 = external
#endif

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@ -1,3 +1,8 @@
#ifndef _GENERIC_H
#define _GENERIC_H
#include <stdint.h>
// Hardware related definitions for generic ESP32 boards // Hardware related definitions for generic ESP32 boards
#define HAS_LORA 1 // comment out if device shall not send data via LoRa or has no LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa or has no LoRa
@ -13,30 +18,32 @@
#define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7 #define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7
#define BATT_FACTOR 2 // voltage divider 100k/100k on board #define BATT_FACTOR 2 // voltage divider 100k/100k on board
#define HAS_LED GPIO_NUM_21 // on board LED #define HAS_LED (21) // on board LED
#define HAS_BUTTON GPIO_NUM_39 // on board button #define HAS_BUTTON (39) // on board button
#define HAS_RGB_LED GPIO_NUM_0 // WS2812B RGB LED on GPIO0 #define HAS_RGB_LED (0) // WS2812B RGB LED on GPIO0
#define BOARD_HAS_PSRAM // use extra 4MB extern RAM #define BOARD_HAS_PSRAM // use extra 4MB extern RAM
#define HAS_GPS 1 // use if board has GPS #define HAS_GPS 1 // use if board has GPS
#define GPS_SERIAL 9600, SERIAL_8N1, GPIO_NUM_12, GPIO_NUM_15 // UBlox NEO 6M or 7M with default configuration #define GPS_SERIAL 9600, SERIAL_8N1, GPIO_NUM_12, GPIO_NUM_15 // UBlox NEO 6M or 7M with default configuration
// pin definitions for SPI interface of LoRa chip // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // SPI Chip Select #define MY_OLED_SDA (4)
#define PIN_SPI_MOSI GPIO_NUM_27 // SPI Data Input #define MY_OLED_SCL (15)
#define PIN_SPI_MISO GPIO_NUM_19 // SPI Data Output #define MY_OLED_RST (16)
#define PIN_SPI_SCK GPIO_NUM_5 // SPI Clock
#define RST LMIC_UNUSED_PIN // LoRa Reset (if wired)
#define DIO0 GPIO_NUM_26 // LoRa IO0
#define DIO1 GPIO_NUM_32 // LoRa IO1
#define DIO2 LMIC_UNUSED_PIN // LoRa IO2 (not needed)
// pin definitions for I2C interface of OLED Display // Pins for LORA chip SPI interface, reset line and interrupt lines
#define OLED_RST GPIO_NUM_16 // SSD1306 RST #define LORA_SCK (5)
#define I2C_SDA GPIO_NUM_4 // SD1306 D1+D2 #define LORA_CS (18)
#define I2C_SCL GPIO_NUM_15 // SD1306 D0 #define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// I2C config for Microchip 24AA02E64 DEVEUI unique address // I2C config for Microchip 24AA02E64 DEVEUI unique address
#define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64 #define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64
#define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits #define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits
#endif

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@ -1,3 +1,8 @@
#ifndef _HELTEC_H
#define _HELTEC_H
#include <stdint.h>
// Hardware related definitions for Heltec LoRa-32 Board // Hardware related definitions for Heltec LoRa-32 Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -5,22 +10,22 @@
#define CFG_sx1276_radio 1 #define CFG_sx1276_radio 1
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board #define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board
#define HAS_LED GPIO_NUM_25 // white LED on board #define HAS_LED (25) // white LED on board
#define HAS_BUTTON GPIO_NUM_0 // button "PROG" on board #define HAS_BUTTON (0) // button "PROG" on board
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- SX1276 NSS (Pin19) SPI Chip Select Input #define MY_OLED_SDA (4)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- SX1276 MOSI (Pin18) SPI Data Input #define MY_OLED_SCL (15)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define MY_OLED_RST (16)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- SX1276 SCK (Pin16) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST GPIO_NUM_14 // ESP32 GPIO14 (Pin14) -- SX1276 NRESET (Pin7) Reset Trigger Input #define LORA_SCK (5)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 (Pin15) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define LORA_CS (18)
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 (Pin13) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define LORA_MISO (19)
#define DIO2 LMIC_UNUSED_PIN // 32 ESP32 GPIO32 (Pin12) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only) #define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// Hardware pin definitions for Heltec LoRa-32 Board with OLED SSD1306 I2C Display #endif
#define OLED_RST GPIO_NUM_16 // ESP32 GPIO16 (Pin16) -- SD1306 RST
#define I2C_SDA GPIO_NUM_4 // ESP32 GPIO4 (Pin4) -- SD1306 D1+D2
#define I2C_SCL GPIO_NUM_15 // ESP32 GPIO15 (Pin15) -- SD1306 D0

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@ -1,3 +1,8 @@
#ifndef _HELTECV2_H
#define _HELTECV2_H
#include <stdint.h>
// Hardware related definitions for Heltec V2 LoRa-32 Board // Hardware related definitions for Heltec V2 LoRa-32 Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -5,22 +10,22 @@
#define CFG_sx1276_radio 1 #define CFG_sx1276_radio 1
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board #define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board
#define HAS_LED GPIO_NUM_25 // white LED on board #define HAS_LED (25) // white LED on board
#define HAS_BUTTON GPIO_NUM_0 // button "PROG" on board #define HAS_BUTTON (0) // button "PROG" on board
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 -- SX1276 NSS (Pin19) SPI Chip Select Input #define OLED_SDA (4)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 -- SX1276 MOSI (Pin18) SPI Data Input #define OLED_SCL (15)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 -- SX1276 MISO (Pin17) SPI Data Output #define OLED_RST (16)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 -- SX1276 SCK (Pin16) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST GPIO_NUM_14 // ESP32 GPIO18 -- SX1276 NRESET (Pin7) Reset Trigger Input #define LORA_SCK (5)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define LORA_CS (18)
#define DIO1 GPIO_NUM_34 // ESP32 GPIO33 -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define LORA_MISO (19)
#define DIO2 GPIO_NUM_35 // 32 ESP32 GPIO32 -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only) #define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (34)
#define LORA_IO2 (35)
// Hardware pin definitions for Heltec LoRa-32 Board with OLED SSD1306 I2C Display #endif
#define OLED_RST GPIO_NUM_16 // ESP32 GPIO16 -- SD1306 RST
#define I2C_SDA GPIO_NUM_4 // ESP32 GPIO4 -- SD1306 D1+D2
#define I2C_SCL GPIO_NUM_15 // ESP32 GPIO15 -- SD1306 D0

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@ -1,3 +1,8 @@
#ifndef _LOLINLITE_H
#define _LOLINLITE_H
#include <stdint.h>
// Hardware related definitions for lolin32lite (without LoRa shield) // Hardware related definitions for lolin32lite (without LoRa shield)
#define CFG_sx1272_radio 1 // dummy #define CFG_sx1272_radio 1 // dummy
@ -5,4 +10,6 @@
#define HAS_LED 22 // on board LED on GPIO22 #define HAS_LED 22 // on board LED on GPIO22
#define LED_ACTIVE_LOW 1 // Onboard LED is active when pin is LOW #define LED_ACTIVE_LOW 1 // Onboard LED is active when pin is LOW
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#endif

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@ -1,3 +1,8 @@
#ifndef _LOLINLITELORA_H
#define _LOLINLITELORA_H
#include <stdint.h>
// Hardware related definitions for lolin32 lite with loraNode32 shield // Hardware related definitions for lolin32 lite with loraNode32 shield
// See https://github.com/hallard/LoLin32-Lite-Lora // See https://github.com/hallard/LoLin32-Lite-Lora
@ -16,24 +21,23 @@
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 // RFM95 module #define CFG_sx1276_radio 1 // RFM95 module
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS 5 // ESP32 GPIO5 (Pin5) -- SX1276 NSS (Pin19) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI 23 // ESP32 GPIO23 (Pin23) -- SX1276 MOSI (Pin18) SPI Data Input #define LORA_CS (18)
#define PIN_SPI_MISO 19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK 18 // ESP32 GPIO18 (Pin18 -- SX1276 SCK (Pin16) SPI Clock Input #define LORA_MOSI (27)
#define LORA_RST (25)
#define LORA_IO0 (27)
#define LORA_IO1 (26)
#define LORA_IO2 LMIC_UNUSED_PIN
// non arduino pin definitions // Pins for I2C interface of OLED Display
#define RST 25 // ESP32 GPIO25 (Pin25) -- SX1276 NRESET (Pin7) Reset Trigger Input #define MY_OLED_SDA (14)
#define DIO0 27 // ESP32 GPIO27 (Pin27) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define MY_OLED_SCL (12)
#define DIO1 26 // ESP32 GPIO26 (Pin26) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define MY_OLED_RST U8X8_PIN_NONE
#define DIO2 LMIC_UNUSED_PIN // 4 ESP32 GPIO4 (Pin4) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only)
#define DIO5 LMIC_UNUSED_PIN // 35 ESP32 GPIO35 (Pin35) -- SX1276 DIO5 not used by LMIC for LoRa (Timeout for FSK only)
// Hardware pin definitions for LoRaNode32 Board with OLED I2C Display
#define OLED_RST U8X8_PIN_NONE // Not reset pin
#define I2C_SDA 14 // ESP32 GPIO14 (Pin14) -- OLED SDA
#define I2C_SCL 12 // ESP32 GPIO12 (Pin12) -- OLED SCL
// I2C config for Microchip 24AA02E64 DEVEUI unique address // I2C config for Microchip 24AA02E64 DEVEUI unique address
#define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64 #define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64
#define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits #define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits
#endif

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@ -1,3 +1,8 @@
#ifndef _LOLINLORA_H
#define _LOLINLORA_H
#include <stdint.h>
// Hardware related definitions for lolin32 with loraNode32 shield // Hardware related definitions for lolin32 with loraNode32 shield
// See https://github.com/hallard/LoLin32-Lora // See https://github.com/hallard/LoLin32-Lora
@ -17,24 +22,24 @@
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 // RFM95 module #define CFG_sx1276_radio 1 // RFM95 module
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS 5 // ESP32 GPIO5 (Pin5) -- SX1276 NSS (Pin19) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI 23 // ESP32 GPIO23 (Pin23) -- SX1276 MOSI (Pin18) SPI Data Input #define LORA_CS (18)
#define PIN_SPI_MISO 19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK 18 // ESP32 GPIO18 (Pin18 -- SX1276 SCK (Pin16) SPI Clock Input #define LORA_MOSI (27)
#define LORA_RST (25)
#define LORA_IO0 (27)
#define LORA_IO1 (26)
#define LORA_IO2 LMIC_UNUSED_PIN
#define LORA_IO5 LMIC_UNUSED_PIN
// non arduino pin definitions // Pins for I2C interface of OLED Display
#define RST 25 // ESP32 GPIO25 (Pin25) -- SX1276 NRESET (Pin7) Reset Trigger Input #define MY_OLED_SDA (21)
#define DIO0 27 // ESP32 GPIO27 (Pin27) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define MY_OLED_SCL (22)
#define DIO1 26 // ESP32 GPIO26 (Pin26) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define MY_OLED_RST U8X8_PIN_NONE
#define DIO2 LMIC_UNUSED_PIN // 4 ESP32 GPIO4 (Pin4) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only)
#define DIO5 LMIC_UNUSED_PIN // 35 ESP32 GPIO35 (Pin35) -- SX1276 DIO5 not used by LMIC for LoRa (Timeout for FSK only)
// Hardware pin definitions for LoRaNode32 Board with OLED I2C Display
#define OLED_RST U8X8_PIN_NONE // Not reset pin
#define I2C_SDA 21 // ESP32 GPIO21 (Pin21) -- OLED SDA
#define I2C_SCL 22 // ESP32 GPIO22 (Pin22) -- OLED SCL
// I2C config for Microchip 24AA02E64 DEVEUI unique address // I2C config for Microchip 24AA02E64 DEVEUI unique address
#define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64 #define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64
#define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits #define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits
#endif

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@ -1,23 +1,28 @@
#ifndef _LOPY_H
#define _LOPY_H
#include <stdint.h>
// Hardware related definitions for Pycom LoPy Board (NOT LoPy4) // Hardware related definitions for Pycom LoPy Board (NOT LoPy4)
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1272_radio 1 #define CFG_sx1272_radio 1
#define HAS_LED NOT_A_PIN // LoPy4 has no on board mono LED, we use on board RGB LED #define HAS_LED NOT_A_PIN // LoPy4 has no on board mono LED, we use on board RGB LED
#define HAS_RGB_LED GPIO_NUM_0 // WS2812B RGB LED on GPIO0 #define HAS_RGB_LED (0) // WS2812B RGB LED on GPIO0
// Hardware pin definitions for Pycom LoPy board // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_17 #define LORA_SCK (5) // GPIO5 - SX1276 SCK
#define PIN_SPI_MOSI GPIO_NUM_27 #define LORA_CS (17) // GPIO17 - SX1276 CS
#define PIN_SPI_MISO GPIO_NUM_19 #define LORA_MISO (19) // GPIO19 - SX1276 MISO
#define PIN_SPI_SCK GPIO_NUM_5 #define LORA_MOSI (27) // GPIO27 - SX1276 MOSI
#define RST GPIO_NUM_18 #define LORA_RST (18) // GPIO18 - SX1276 RESET
#define DIO0 GPIO_NUM_23 // LoRa IRQ #define LORA_IO0 (23) // LoRa IRQ
#define DIO1 GPIO_NUM_23 // Pin tied via diode to DIO0 #define LORA_IO1 (23) // Pin tied via diode to DIO0
#define DIO2 GPIO_NUM_23 // Pin tied via diode to DIO0 #define LORA_IO2 (23) // Pin tied via diode to DIO0
// select WIFI antenna (internal = onboard / external = u.fl socket) // select WIFI antenna (internal = onboard / external = u.fl socket)
#define HAS_ANTENNA_SWITCH GPIO_NUM_16 // pin for switching wifi antenna #define HAS_ANTENNA_SWITCH (16) // pin for switching wifi antenna
#define WIFI_ANTENNA 0 // 0 = internal, 1 = external #define WIFI_ANTENNA 0 // 0 = internal, 1 = external
// uncomment this only if your LoPy runs on a PYTRACK BOARD // uncomment this only if your LoPy runs on a PYTRACK BOARD
@ -26,10 +31,12 @@
//#define GPS_ADDR 0x10 //#define GPS_ADDR 0x10
// uncomment this only if your LoPy runs on a EXPANSION BOARD // uncomment this only if your LoPy runs on a EXPANSION BOARD
//#define HAS_LED GPIO_NUM_12 // use if LoPy is on Expansion Board, this has a user LED //#define HAS_LED (12) // use if LoPy is on Expansion Board, this has a user LED
//#define LED_ACTIVE_LOW 1 // use if LoPy is on Expansion Board, this has a user LED //#define LED_ACTIVE_LOW 1 // use if LoPy is on Expansion Board, this has a user LED
//#define HAS_BUTTON GPIO_NUM_13 // user button on expansion board //#define HAS_BUTTON (13) // user button on expansion board
//#define BUTTON_PULLUP 1 // Button need pullup instead of default pulldown //#define BUTTON_PULLUP 1 // Button need pullup instead of default pulldown
//#define HAS_BATTERY_PROBE ADC1_GPIO39_CHANNEL // battery probe GPIO pin -> ADC1_CHANNEL_7 //#define HAS_BATTERY_PROBE ADC1_GPIO39_CHANNEL // battery probe GPIO pin -> ADC1_CHANNEL_7
//#define BATT_FACTOR 2 // voltage divider 1MOhm/1MOhm -> expansion board 3.0 //#define BATT_FACTOR 2 // voltage divider 1MOhm/1MOhm -> expansion board 3.0
//#define BATT_FACTOR 4 // voltage divider 115kOhm/56kOhm -> expansion board 2.0 //#define BATT_FACTOR 4 // voltage divider 115kOhm/56kOhm -> expansion board 2.0
#endif

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#ifndef _LOPY4_H
#define _LOPY4_H
#include <stdint.h>
// Hardware related definitions for Pycom LoPy4 Board // Hardware related definitions for Pycom LoPy4 Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 #define CFG_sx1276_radio 1
//#define HAS_LED NOT_A_PIN // LoPy4 has no on board mono LED, we use on board RGB LED //#define HAS_LED NOT_A_PIN // LoPy4 has no on board mono LED, we use on board RGB LED
#define HAS_RGB_LED GPIO_NUM_0 // WS2812B RGB LED on GPIO0 (P2) #define HAS_RGB_LED (0) // WS2812B RGB LED on GPIO0 (P2)
#define BOARD_HAS_PSRAM // use extra 4MB extern RAM #define BOARD_HAS_PSRAM // use extra 4MB extern RAM
// Hardware pin definitions for Pycom LoPy4 board // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_18 #define LORA_SCK (5)
#define PIN_SPI_MOSI GPIO_NUM_27 #define LORA_CS (18)
#define PIN_SPI_MISO GPIO_NUM_19 #define LORA_MISO (19)
#define PIN_SPI_SCK GPIO_NUM_5 #define LORA_MOSI (27)
#define RST LMIC_UNUSED_PIN #define LORA_RST LMIC_UNUSED_PIN
#define DIO0 GPIO_NUM_23 // LoRa IRQ #define LORA_IO0 (23) // LoRa IRQ
#define DIO1 GPIO_NUM_23 // Pin tied via diode to DIO0 #define LORA_IO1 (23) // Pin tied via diode to DIO0
#define DIO2 GPIO_NUM_23 // Pin tied via diode to DIO0 #define LORA_IO2 (23) // Pin tied via diode to DIO0
// select WIFI antenna (internal = onboard / external = u.fl socket) // select WIFI antenna (internal = onboard / external = u.fl socket)
#define HAS_ANTENNA_SWITCH GPIO_NUM_21 // pin for switching wifi antenna (P12) #define HAS_ANTENNA_SWITCH (21) // pin for switching wifi antenna (P12)
#define WIFI_ANTENNA 0 // 0 = internal, 1 = external #define WIFI_ANTENNA 0 // 0 = internal, 1 = external
// uncomment this only if your LoPy runs on a PYTRACK BOARD // uncomment this only if your LoPy runs on a PYTRACK BOARD
@ -27,10 +32,12 @@
//#define GPS_ADDR 0x10 //#define GPS_ADDR 0x10
// uncomment this only if your LoPy runs on a EXPANSION BOARD // uncomment this only if your LoPy runs on a EXPANSION BOARD
#define HAS_LED GPIO_NUM_12 // use if LoPy is on Expansion Board, this has a user LED #define HAS_LED (12) // use if LoPy is on Expansion Board, this has a user LED
#define LED_ACTIVE_LOW 1 // use if LoPy is on Expansion Board, this has a user LED #define LED_ACTIVE_LOW 1 // use if LoPy is on Expansion Board, this has a user LED
#define HAS_BUTTON GPIO_NUM_13 // user button on expansion board #define HAS_BUTTON (13) // user button on expansion board
#define BUTTON_PULLUP 1 // Button need pullup instead of default pulldown #define BUTTON_PULLUP 1 // Button need pullup instead of default pulldown
#define HAS_BATTERY_PROBE ADC1_GPIO39_CHANNEL // battery probe GPIO pin -> ADC1_CHANNEL_7 #define HAS_BATTERY_PROBE ADC1_GPIO39_CHANNEL // battery probe GPIO pin -> ADC1_CHANNEL_7
#define BATT_FACTOR 2 // voltage divider 1MOhm/1MOhm -> expansion board 3.0 #define BATT_FACTOR 2 // voltage divider 1MOhm/1MOhm -> expansion board 3.0
//#define BATT_FACTOR 4 // voltage divider 115kOhm/56kOhm -> expansion board 2.0 //#define BATT_FACTOR 4 // voltage divider 115kOhm/56kOhm -> expansion board 2.0
#endif

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@ -1,3 +1,8 @@
#ifndef _OCTOPUS_H
#define _OCTOPUS_H
#include <stdint.h>
// Hardware related definitions for #IoT Octopus32 with the Adafruit LoRaWAN Wing // Hardware related definitions for #IoT Octopus32 with the Adafruit LoRaWAN Wing
// You can use this configuration also with the Adafruit ESP32 Feather + the LoRaWAN Wing // You can use this configuration also with the Adafruit ESP32 Feather + the LoRaWAN Wing
// In this config we use the Adafruit OLED Wing which is only 128x32 pixel, need to find a smaller font // In this config we use the Adafruit OLED Wing which is only 128x32 pixel, need to find a smaller font
@ -15,27 +20,21 @@
#define HAS_SPI 1 // comment out if device shall not send data via SPI #define HAS_SPI 1 // comment out if device shall not send data via SPI
#define CFG_sx1276_radio 1 // RFM95 module #define CFG_sx1276_radio 1 // RFM95 module
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS 14 //14 // ESP32 GPIO5 (Pin5) -- SX1276 NSS (Pin19) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI 18 // ESP32 GPIO23 (Pin23) -- SX1276 MOSI (Pin18) SPI Data Input #define LORA_CS (14)
#define PIN_SPI_MISO 19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK 5 // ESP32 GPIO18 (Pin18) -- SX1276 SCK (Pin16) SPI Clock Input #define LORA_MOSI (18)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (33)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
//GPIO_NUM_ // Pins for I2C interface of OLED Display
// non arduino pin definitions #define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // U8X8_SSD1306_128X32_UNIVISION_SW_I2C //
#define RST LMIC_UNUSED_PIN // ESP32 GPIO25 (Pin25) -- SX1276 NRESET (Pin7) Reset Trigger Input //#define DISPLAY_FLIP 1 // uncomment this for rotated display
#define DIO0 33 // ESP32 GPIO27 (Pin27) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define MY_OLED_SDA (23)
#define DIO1 33 // ESP32 GPIO26 (Pin26) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define MY_OLED_SCL (22)
#define DIO2 LMIC_UNUSED_PIN // 4 ESP32 GPIO4 (Pin4) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only) #define MY_OLED_RST U8X8_PIN_NONE
#define DIO5 LMIC_UNUSED_PIN // 35 ESP32 GPIO35 (Pin35) -- SX1276 DIO5 not used by LMIC for LoRa (Timeout for FSK only)
// Hardware pin definitions for LoRaNode32 Board with OLED I2C Display #endif
#define OLED_RST U8X8_PIN_NONE // Not reset pin
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // U8X8_SSD1306_128X32_UNIVISION_SW_I2C //
//#define DISPLAY_FLIP 1 // uncomment this for rotated display
#define I2C_SDA 23 //21 // ESP32 GPIO14 (Pin14) -- OLED SDA
#define I2C_SCL 22 //22 // ESP32 GPIO12 (Pin12) -- OLED SCL
// I2C config for Microchip 24AA02E64 DEVEUI unique address
//#define MCP_24AA02E64_I2C_ADDRESS 0x50 // I2C address for the 24AA02E64
//#define MCP_24AA02E64_MAC_ADDRESS 0xF8 // Memory adress of unique deveui 64 bits

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@ -1,3 +1,8 @@
#ifndef _TTGOBEAM_H
#define _TTGOBEAM_H
#include <stdint.h>
// Hardware related definitions for TTGO T-Beam board // Hardware related definitions for TTGO T-Beam board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -14,15 +19,15 @@
#define HAS_GPS 1 // use on board GPS #define HAS_GPS 1 // use on board GPS
#define GPS_SERIAL 9600, SERIAL_8N1, GPIO_NUM_12, GPIO_NUM_15 // UBlox NEO 6M or 7M with default configuration #define GPS_SERIAL 9600, SERIAL_8N1, GPIO_NUM_12, GPIO_NUM_15 // UBlox NEO 6M or 7M with default configuration
// re-define pin definitions of pins_arduino.h // Pins for LORA chip SPI interface, reset line and interrupt lines
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- HPD13A NSS/SEL (Pin4) SPI Chip Select Input #define LORA_SCK (5)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- HPD13A MOSI/DSI (Pin6) SPI Data Input #define LORA_CS (18)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- HPD13A MISO/DSO (Pin7) SPI Data Output #define LORA_MISO (19)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- HPD13A SCK (Pin5) SPI Clock Input #define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IO1 (32) // !! NEEDS EXTERNAL WIRING !!
//#define LORA_IO1 (33) // for T-Beam T22_V05 and T22_V07, other versions may need external wiring
#define LORA_IO2 LMIC_UNUSED_PIN
// non arduino pin definitions #endif
#define RST LMIC_UNUSED_PIN // connected to ESP32 RST/EN
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 <-> HPD13A IO0
#define DIO1 GPIO_NUM_32 // Lora1 <-> HPD13A IO1 // !! NEEDS EXTERNAL WIRING !!
//#define DIO1 GPIO_NUM_33 // Lora1 <-> HPD13A IO1 // for T-Beam T22_V05 and T22_V07, other versions may need external wiring
#define DIO2 LMIC_UNUSED_PIN // Lora2 <-> HPD13A IO2 // not needed for LoRa

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@ -1,3 +1,8 @@
#ifndef _TTGOV1_H
#define _TTGOV1_H
#include <stdint.h>
// Hardware related definitions for TTGOv1 board // Hardware related definitions for TTGOv1 board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -6,23 +11,23 @@
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board #define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board
//#define DISPLAY_FLIP 1 // uncomment this for rotated display //#define DISPLAY_FLIP 1 // uncomment this for rotated display
#define HAS_LED GPIO_NUM_2 // white LED on board #define HAS_LED (2) // white LED on board
#define LED_ACTIVE_LOW 1 // Onboard LED is active when pin is LOW #define LED_ACTIVE_LOW 1 // Onboard LED is active when pin is LOW
#define HAS_BUTTON GPIO_NUM_0 // button "PRG" on board #define HAS_BUTTON (0) // button "PRG" on board
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- SX1276 NSS (Pin19) SPI Chip Select Input #define MY_OLED_SDA (4)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- SX1276 MOSI (Pin18) SPI Data Input #define MY_OLED_SCL (15)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- SX1276 MISO (Pin17) SPI Data Output #define MY_OLED_RST (16)
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- SX1276 SCK (Pin16) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST GPIO_NUM_14 // ESP32 GPIO14 (Pin14) -- SX1276 NRESET (Pin7) Reset Trigger Input #define LORA_SCK (5)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 (Pin15) -- SX1276 DIO0 (Pin8) used by LMIC for detecting LoRa RX_Done & TX_Done #define LORA_CS (18)
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 (Pin13) -- SX1276 DIO1 (Pin9) used by LMIC for detecting LoRa RX_Timeout #define LORA_MISO (19)
#define DIO2 LMIC_UNUSED_PIN // 32 ESP32 GPIO32 (Pin12) -- SX1276 DIO2 (Pin10) not used by LMIC for LoRa (Timeout for FSK only) #define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// Hardware pin definitions for TTGOv1 Board with OLED SSD1306 I2C Display #endif
#define OLED_RST GPIO_NUM_16 // ESP32 GPIO16 (Pin16) -- SD1306 Reset
#define I2C_SDA GPIO_NUM_4 // ESP32 GPIO4 (Pin4) -- SD1306 Data
#define I2C_SCL GPIO_NUM_15 // ESP32 GPIO15 (Pin15) -- SD1306 Clock

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@ -1,3 +1,8 @@
#ifndef _TTGOV2_H
#define _TTGOV2_H
#include <stdint.h>
// Hardware related definitions for TTGO V2 Board // Hardware related definitions for TTGO V2 Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa #define HAS_LORA 1 // comment out if device shall not send data via LoRa
@ -11,46 +16,19 @@
// disable brownout detection (needed on TTGOv2 for battery powered operation) // disable brownout detection (needed on TTGOv2 for battery powered operation)
#define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature #define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- HPD13A NSS/SEL (Pin4) SPI Chip Select Input #define MY_OLED_SDA (21)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- HPD13A MOSI/DSI (Pin6) SPI Data Input #define MY_OLED_SCL (22)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- HPD13A MISO/DSO (Pin7) SPI Data Output #define MY_OLED_RST U8X8_PIN_NONE
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- HPD13A SCK (Pin5) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST LMIC_UNUSED_PIN // connected to ESP32 RST/EN #define LORA_SCK (5)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 wired on PCB to HPD13A #define LORA_CS (18)
#define DIO1 GPIO_NUM_33 // HPDIO1 on pcb, needs to be wired external to GPIO33 #define LORA_MISO (19)
#define DIO2 LMIC_UNUSED_PIN // 32 HPDIO2 on pcb, needs to be wired external to GPIO32 (not necessary for LoRa, only FSK) #define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// Hardware pin definitions for TTGO V2 Board with OLED SSD1306 0,96" I2C Display #endif
#define OLED_RST U8X8_PIN_NONE // connected to CPU RST/EN
#define I2C_SDA GPIO_NUM_21 // ESP32 GPIO21 -- SD1306 D1+D2
#define I2C_SCL GPIO_NUM_22 // ESP32 GPIO22 -- SD1306 D0
/* source:
https://www.thethingsnetwork.org/forum/t/big-esp32-sx127x-topic-part-2/11973
TTGO LoRa32 V2:
ESP32 LoRa (SPI) Display (I2C) LED
----------- ---------- ------------- ------------------
GPIO5 SCK SCK
GPIO27 MOSI MOSI
GPIO19 MISO MISO
GPIO18 SS NSS
EN RST RST
GPIO26 DIO0
GPIO33 DIO1 (see #1)
GPIO32 DIO2 (see #2)
GPIO22 SCL SCL
GPIO21 SDA SDA
GPIO22 useless (see #3)
#1 Required (used by LMIC for LoRa).
Not on-board wired to any GPIO. Must be manually wired. <<-- necessary for paxcounter
#2 Optional (used by LMIC for FSK but not for LoRa). <<-- NOT necessary for paxcounter
Not on-board wired to any GPIO. When needed: must be manually wired.
#3 GPIO22 is already used for SCL therefore LED cannot be used without conflicting with I2C and display.
*/

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@ -1,3 +1,8 @@
#ifndef _TTGOV21NEW_H
#define _TTGOV21NEW_H
#include <stdint.h>
/* Hardware related definitions for TTGO V2.1 Board /* Hardware related definitions for TTGO V2.1 Board
// ATTENTION: check your board version! // ATTENTION: check your board version!
// This settings are for boards labeled v1.6 on pcb, NOT for v1.5 or older // This settings are for boards labeled v1.6 on pcb, NOT for v1.5 or older
@ -8,23 +13,23 @@
#define CFG_sx1276_radio 1 // HPD13A LoRa SoC #define CFG_sx1276_radio 1 // HPD13A LoRa SoC
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C #define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C
#define HAS_LED GPIO_NUM_25 // green on board LED #define HAS_LED (25) // green on board LED
#define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7 #define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7
#define BATT_FACTOR 2 // voltage divider 100k/100k on board #define BATT_FACTOR 2 // voltage divider 100k/100k on board
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- HPD13A NSS/SEL (Pin4) SPI Chip Select Input #define MY_OLED_SDA (21)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- HPD13A MOSI/DSI (Pin6) SPI Data Input #define MY_OLED_SCL (22)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- HPD13A MISO/DSO (Pin7) SPI Data Output #define MY_OLED_RST U8X8_PIN_NONE
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- HPD13A SCK (Pin5) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST GPIO_NUM_23 // ESP32 GPIO23 <-> HPD13A RESET #define LORA_SCK (5)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 <-> HPD13A IO0 #define LORA_CS (18)
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 <-> HPDIO1 <-> HPD13A IO1 #define LORA_MISO (19)
#define DIO2 GPIO_NUM_32 // ESP32 GPIO32 <-> HPDIO2 <-> HPD13A IO2 #define LORA_MOSI (27)
#define LORA_RST (23)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)
// Hardware pin definitions for TTGO V2 Board with OLED SSD1306 0,96" I2C Display #endif
#define OLED_RST U8X8_PIN_NONE // connected to CPU RST/EN
#define I2C_SDA GPIO_NUM_21 // ESP32 GPIO21 -- SD1306 D1+D2
#define I2C_SCL GPIO_NUM_22 // ESP32 GPIO22 -- SD1306 D0

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@ -1,3 +1,9 @@
#ifndef _TTGOV21OLD_H
#define _TTGOV21OLD_H
#include <stdint.h>
/* Hardware related definitions for TTGO V2.1 Board /* Hardware related definitions for TTGO V2.1 Board
// ATTENTION: check your board version! // ATTENTION: check your board version!
// This settings are for boards without label on pcb, or labeled v1.5 on pcb // This settings are for boards without label on pcb, or labeled v1.5 on pcb
@ -14,20 +20,19 @@
//#define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7 //#define HAS_BATTERY_PROBE ADC1_GPIO35_CHANNEL // uses GPIO7
//#define BATT_FACTOR 2 // voltage divider 100k/100k on board //#define BATT_FACTOR 2 // voltage divider 100k/100k on board
// re-define pin definitions of pins_arduino.h // Pins for I2C interface of OLED Display
#define PIN_SPI_SS GPIO_NUM_18 // ESP32 GPIO18 (Pin18) -- HPD13A NSS/SEL (Pin4) SPI Chip Select Input #define MY_OLED_SDA (21)
#define PIN_SPI_MOSI GPIO_NUM_27 // ESP32 GPIO27 (Pin27) -- HPD13A MOSI/DSI (Pin6) SPI Data Input #define MY_OLED_SCL (22)
#define PIN_SPI_MISO GPIO_NUM_19 // ESP32 GPIO19 (Pin19) -- HPD13A MISO/DSO (Pin7) SPI Data Output #define MY_OLED_RST U8X8_PIN_NONE
#define PIN_SPI_SCK GPIO_NUM_5 // ESP32 GPIO5 (Pin5) -- HPD13A SCK (Pin5) SPI Clock Input
// non arduino pin definitions // Pins for LORA chip SPI interface, reset line and interrupt lines
#define RST LMIC_UNUSED_PIN // connected to ESP32 RST/EN (old board) #define LORA_SCK (5)
//#define RST GPIO_NUM_12 // (boards labeled v1.5) #define LORA_CS (18)
#define DIO0 GPIO_NUM_26 // ESP32 GPIO26 <-> HPD13A IO0 #define LORA_MISO (19)
#define DIO1 GPIO_NUM_33 // ESP32 GPIO33 <-> HPDIO1 <-> HPD13A IO1 #define LORA_MOSI (27)
#define DIO2 GPIO_NUM_32 // ESP32 GPIO32 <-> HPDIO2 <-> HPD13A IO2 #define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)
// Hardware pin definitions for TTGO V2 Board with OLED SSD1306 0,96" I2C Display #endif
#define OLED_RST U8X8_PIN_NONE // connected to CPU RST/EN
#define I2C_SDA GPIO_NUM_21 // ESP32 GPIO21 -- SD1306 D1+D2
#define I2C_SCL GPIO_NUM_22 // ESP32 GPIO22 -- SD1306 D0

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@ -1,83 +1,95 @@
#ifndef _lmic_config_h_ // COUNTRY AND PROJECT SPECIFIC DEFINITIONS FOR LMIC STACK
#define _lmic_config_h_
// COUNTRY SETTINGS
// In the original LMIC code, these config values were defined on the // --> please check with you local regulations for ISM band frequency use!
// gcc commandline. Since Arduino does not allow easily modifying the //
// compiler commandline, use this file instead. // CFG_eu868 EU 863-870 MHz
// CFG_us915 US 902-928 MHz
#define CFG_eu868 1 // CFG_au921 Australia 915-928 MHz
//#define CFG_us915 1 // CFG_as923 Asia 923 MHz
// This is the SX1272/SX1273 radio, which is also used on the HopeRF // CFG_in866 India 865-867 MHz
// RFM92 boards.
//#define CFG_sx1272_radio 1 #define CFG_eu868 1
// This is the SX1276/SX1277/SX1278/SX1279 radio, which is also used on //#define CFG_us915 1
// the HopeRF RFM95 boards. //#define CFG_in866 1
#define CFG_sx1276_radio 1 //#define CFG_au921 1
//#define CFG_as923 1
// 16 μs per tick //#define LMIC_COUNTRY_CODE LMIC_COUNTRY_CODE_JP /* for as923-JP */
// LMIC requires ticks to be 15.5μs - 100 μs long
#define US_PER_OSTICK_EXPONENT 4 // LMIC LORAWAN STACK SETTINGS
#define US_PER_OSTICK (1 << US_PER_OSTICK_EXPONENT) // --> adapt to your device only if necessary
#define OSTICKS_PER_SEC (1000000 / US_PER_OSTICK)
//#define LMIC_USE_INTERRUPTS
// Set this to 1 to enable some basic debug output (using printf) about
// RF settings used during transmission and reception. Set to 2 to // 16 μs per tick
// enable more verbose output. Make sure that printf is actually // LMIC requires ticks to be 15.5μs - 100 μs long
// configured (e.g. on AVR it is not by default), otherwise using it can #define US_PER_OSTICK_EXPONENT 4
// cause crashing. #define US_PER_OSTICK (1 << US_PER_OSTICK_EXPONENT)
#define LMIC_DEBUG_LEVEL 0 #define OSTICKS_PER_SEC (1000000 / US_PER_OSTICK)
// Enable this to allow using printf() to print to the given serial port // This tells LMIC to make the receive windows bigger, in case your clock is
// (or any other Print object). This can be easy for debugging. The // faster or slower. This causes the transceiver to be earlier switched on,
// current implementation only works on AVR, though. // so consuming more power. You may sharpen (reduce) this value if you are
//#define LMIC_PRINTF_TO Serial // limited on battery.
#define CLOCK_ERROR_PROCENTAGE 20
// Any runtime assertion failures are printed to this serial port (or
// any other Print object). If this is unset, any failures just silently // Set this to 1 to enable some basic debug output (using printf) about
// halt execution. // RF settings used during transmission and reception. Set to 2 to
#define LMIC_FAILURE_TO Serial // enable more verbose output. Make sure that printf is actually
// configured (e.g. on AVR it is not by default), otherwise using it can
// Uncomment this to disable all code related to joining // cause crashing.
//#define DISABLE_JOIN //#define LMIC_DEBUG_LEVEL 1
// Uncomment this to disable all code related to ping
//#define DISABLE_PING // Enable this to allow using printf() to print to the given serial port
// Uncomment this to disable all code related to beacon tracking. // (or any other Print object). This can be easy for debugging. The
// Requires ping to be disabled too // current implementation only works on AVR, though.
//#define DISABLE_BEACONS //#define LMIC_PRINTF_TO Serial
// Uncomment these to disable the corresponding MAC commands. // Any runtime assertion failures are printed to this serial port (or
// Class A // any other Print object). If this is unset, any failures just silently
//#define DISABLE_MCMD_DCAP_REQ // duty cycle cap // halt execution.
//#define DISABLE_MCMD_DN2P_SET // 2nd DN window param #define LMIC_FAILURE_TO Serial
//#define DISABLE_MCMD_SNCH_REQ // set new channel
// Class B // Uncomment this to disable all code related to joining
//#define DISABLE_MCMD_PING_SET // set ping freq, automatically disabled by DISABLE_PING //#define DISABLE_JOIN
//#define DISABLE_MCMD_BCNI_ANS // next beacon start, automatical disabled by DISABLE_BEACON // Uncomment this to disable all code related to ping
#define DISABLE_PING
// In LoRaWAN, a gateway applies I/Q inversion on TX, and nodes do the // Uncomment this to disable all code related to beacon tracking.
// same on RX. This ensures that gateways can talk to nodes and vice // Requires ping to be disabled too
// versa, but gateways will not hear other gateways and nodes will not #define DISABLE_BEACONS
// hear other nodes. By uncommenting this macro, this inversion is
// disabled and this node can hear other nodes. If two nodes both have // Uncomment these to disable the corresponding MAC commands.
// this macro set, they can talk to each other (but they can no longer // Class A
// hear gateways). This should probably only be used when debugging //#define DISABLE_MCMD_DCAP_REQ // duty cycle cap
// and/or when talking to the radio directly (e.g. like in the "raw" //#define DISABLE_MCMD_DN2P_SET // 2nd DN window param
// example). //#define DISABLE_MCMD_SNCH_REQ // set new channel
//#define DISABLE_INVERT_IQ_ON_RX // Class B
//#define DISABLE_MCMD_PING_SET // set ping freq, automatically disabled by
// This allows choosing between multiple included AES implementations. // DISABLE_PING #define DISABLE_MCMD_BCNI_ANS // next beacon start, automatical
// Make sure exactly one of these is uncommented. // disabled by DISABLE_BEACON
//
// This selects the original AES implementation included LMIC. This // In LoRaWAN, a gateway applies I/Q inversion on TX, and nodes do the
// implementation is optimized for speed on 32-bit processors using // same on RX. This ensures that gateways can talk to nodes and vice
// fairly big lookup tables, but it takes up big amounts of flash on the // versa, but gateways will not hear other gateways and nodes will not
// AVR architecture. // hear other nodes. By uncommenting this macro, this inversion is
// #define USE_ORIGINAL_AES // disabled and this node can hear other nodes. If two nodes both have
// // this macro set, they can talk to each other (but they can no longer
// This selects the AES implementation written by Ideetroon for their // hear gateways). This should probably only be used when debugging
// own LoRaWAN library. It also uses lookup tables, but smaller // and/or when talking to the radio directly (e.g. like in the "raw"
// byte-oriented ones, making it use a lot less flash space (but it is // example).
// also about twice as slow as the original). //#define DISABLE_INVERT_IQ_ON_RX
#define USE_IDEETRON_AES
// This allows choosing between multiple included AES implementations.
#endif // _lmic_config_h_ // Make sure exactly one of these is uncommented.
//
// This selects the original AES implementation included LMIC. This
// implementation is optimized for speed on 32-bit processors using
// fairly big lookup tables, but it takes up big amounts of flash on the
// AVR architecture.
#define USE_ORIGINAL_AES
//
// This selects the AES implementation written by Ideetroon for their
// own LoRaWAN library. It also uses lookup tables, but smaller
// byte-oriented ones, making it use a lot less flash space (but it is
// also about twice as slow as the original).
// #define USE_IDEETRON_AES

View File

@ -10,13 +10,25 @@ osjob_t sendjob;
QueueHandle_t LoraSendQueue; QueueHandle_t LoraSendQueue;
// LMIC enhanced Pin mapping // LMIC enhanced Pin mapping
const lmic_pinmap lmic_pins = {.mosi = PIN_SPI_MOSI, const lmic_pinmap lmic_pins = {
.miso = PIN_SPI_MISO, .nss = LORA_CS,
.sck = PIN_SPI_SCK, .rxtx = LMIC_UNUSED_PIN,
.nss = PIN_SPI_SS, .rst = LORA_RST,
.rxtx = LMIC_UNUSED_PIN, .dio = {LORA_IO0, LORA_IO1, LORA_IO2},
.rst = RST, .mosi = LORA_MOSI,
.dio = {DIO0, DIO1, DIO2}}; .miso = LORA_MISO,
.sck = LORA_SCK
// optional: set polarity of rxtx pin.
//.rxtx_rx_active = 0,
// optional: set RSSI cal for listen-before-talk
// this value is in dB, and is added to RSSI
// measured prior to decision.
// Must include noise guardband! Ignored in US,
// EU, IN, other markets where LBT is not required.
//.rssi_cal = 0,
// optional: override LMIC_SPI_FREQ if non-zero
//.spi_freq = 0,
};
// DevEUI generator using devices's MAC address // DevEUI generator using devices's MAC address
void gen_lora_deveui(uint8_t *pdeveui) { void gen_lora_deveui(uint8_t *pdeveui) {
@ -100,7 +112,7 @@ void get_hard_deveui(uint8_t *pdeveui) {
uint8_t i2c_ret; uint8_t i2c_ret;
// Init this just in case, no more to 100KHz // Init this just in case, no more to 100KHz
Wire.begin(I2C_SDA, I2C_SCL, 100000); Wire.begin(SDA, SCL, 100000);
Wire.beginTransmission(MCP_24AA02E64_I2C_ADDRESS); Wire.beginTransmission(MCP_24AA02E64_I2C_ADDRESS);
Wire.write(MCP_24AA02E64_MAC_ADDRESS); Wire.write(MCP_24AA02E64_MAC_ADDRESS);
i2c_ret = Wire.endTransmission(); i2c_ret = Wire.endTransmission();
@ -149,82 +161,63 @@ void showLoraKeys(void) {
void onEvent(ev_t ev) { void onEvent(ev_t ev) {
char buff[24] = ""; char buff[24] = "";
switch (ev) { switch (ev) {
case EV_SCAN_TIMEOUT: case EV_SCAN_TIMEOUT:
strcpy_P(buff, PSTR("SCAN TIMEOUT")); strcpy_P(buff, PSTR("SCAN TIMEOUT"));
break; break;
case EV_BEACON_FOUND: case EV_BEACON_FOUND:
strcpy_P(buff, PSTR("BEACON FOUND")); strcpy_P(buff, PSTR("BEACON_FOUND"));
break; break;
case EV_BEACON_MISSED: case EV_BEACON_MISSED:
strcpy_P(buff, PSTR("BEACON MISSED")); strcpy_P(buff, PSTR("BEACON_MISSED"));
break; break;
case EV_BEACON_TRACKED: case EV_BEACON_TRACKED:
strcpy_P(buff, PSTR("BEACON TRACKED")); strcpy_P(buff, PSTR("BEACON_TRACKED"));
break; break;
case EV_JOINING: case EV_JOINING:
strcpy_P(buff, PSTR("JOINING")); strcpy_P(buff, PSTR("JOINING"));
break; break;
case EV_LOST_TSYNC:
strcpy_P(buff, PSTR("LOST TSYNC"));
break;
case EV_RESET:
strcpy_P(buff, PSTR("RESET"));
break;
case EV_RXCOMPLETE:
strcpy_P(buff, PSTR("RX COMPLETE"));
break;
case EV_LINK_DEAD:
strcpy_P(buff, PSTR("LINK DEAD"));
break;
case EV_LINK_ALIVE:
strcpy_P(buff, PSTR("LINK ALIVE"));
break;
case EV_RFU1:
strcpy_P(buff, PSTR("RFUI"));
break;
case EV_JOIN_FAILED:
strcpy_P(buff, PSTR("JOIN FAILED"));
break;
case EV_REJOIN_FAILED:
strcpy_P(buff, PSTR("REJOIN FAILED"));
break;
case EV_JOINED: case EV_JOINED:
strcpy_P(buff, PSTR("JOINED")); strcpy_P(buff, PSTR("JOINED"));
sprintf(display_line6, " "); // clear previous lmic status sprintf(display_line6, " "); // clear previous lmic status
// set data rate adaptation according to saved setting // set data rate adaptation according to saved setting
LMIC_setAdrMode(cfg.adrmode); LMIC_setAdrMode(cfg.adrmode);
// set cyclic lmic link check to off if no ADR because is not supported by // set cyclic lmic link check to off if no ADR because is not supported by
// ttn (but enabled by lmic after join) // ttn (but enabled by lmic after join)
LMIC_setLinkCheckMode(cfg.adrmode); LMIC_setLinkCheckMode(cfg.adrmode);
// Set data rate and transmit power (note: txpower seems to be ignored by // Set data rate and transmit power (note: txpower seems to be ignored by
// the library) // the library)
switch_lora(cfg.lorasf, cfg.txpower); switch_lora(cfg.lorasf, cfg.txpower);
// kickoff first send job // kickoff first send job
os_setCallback(&sendjob, lora_send); os_setCallback(&sendjob, lora_send);
// show effective LoRa parameters after join // show effective LoRa parameters after join
ESP_LOGI(TAG, "ADR=%d, SF=%d, TXPOWER=%d", cfg.adrmode, cfg.lorasf, ESP_LOGI(TAG, "ADR=%d, SF=%d, TXPOWER=%d", cfg.adrmode, cfg.lorasf,
cfg.txpower); cfg.txpower);
break; break;
case EV_TXCOMPLETE: case EV_JOIN_FAILED:
strcpy_P(buff, PSTR("JOIN_FAILED"));
break;
case EV_REJOIN_FAILED:
strcpy_P(buff, PSTR("REJOIN_FAILED"));
break;
case EV_TXCOMPLETE:
strcpy_P(buff, (LMIC.txrxFlags & TXRX_ACK) ? PSTR("RECEIVED ACK") strcpy_P(buff, (LMIC.txrxFlags & TXRX_ACK) ? PSTR("RECEIVED ACK")
: PSTR("TX COMPLETE")); : PSTR("TX COMPLETE"));
sprintf(display_line6, " "); // clear previous lmic status sprintf(display_line6, " "); // clear previous lmic status
if (LMIC.dataLen) { if (LMIC.dataLen) {
ESP_LOGI(TAG, "Received %d bytes of payload, RSSI %d SNR %d", ESP_LOGI(TAG, "Received %d bytes of payload, RSSI %d SNR %d",
LMIC.dataLen, LMIC.rssi, (signed char)LMIC.snr); LMIC.dataLen, (signed char)LMIC.rssi, (signed char)LMIC.snr);
sprintf(display_line6, "RSSI %d SNR %d", LMIC.rssi, sprintf(display_line6, "RSSI %d SNR %d", (signed char)LMIC.rssi,
(signed char)LMIC.snr); (signed char)LMIC.snr);
// check if command is received on command port, then call interpreter // check if command is received on command port, then call interpreter
@ -234,6 +227,49 @@ void onEvent(ev_t ev) {
} }
break; break;
case EV_LOST_TSYNC:
strcpy_P(buff, PSTR("LOST_TSYNC"));
break;
case EV_RESET:
strcpy_P(buff, PSTR("RESET"));
break;
case EV_RXCOMPLETE:
// data received in ping slot
strcpy_P(buff, PSTR("RX COMPLETE"));
break;
case EV_LINK_DEAD:
strcpy_P(buff, PSTR("LINK DEAD"));
break;
case EV_LINK_ALIVE:
strcpy_P(buff, PSTR("LINK ALIVE"));
break;
case EV_TXSTART:
strcpy_P(buff, PSTR("TX START"));
break;
/*
|| This event is defined but not used in the code. No
|| point in wasting codespace on it.
||
|| case EV_SCAN_FOUND:
|| Serial.println(F("EV_SCAN_FOUND"));
|| break;
*/
/*
|| This event is defined but not used in the code. No
|| point in wasting codespace on it.
||
|| case EV_RFU1:
|| Serial.println(F("EV_RFU1"));
|| break;
*/
default: default:
sprintf_P(buff, PSTR("UNKNOWN EVENT %d"), ev); sprintf_P(buff, PSTR("UNKNOWN EVENT %d"), ev);
break; break;
@ -244,8 +280,7 @@ void onEvent(ev_t ev) {
ESP_LOGI(TAG, "EV_%s", buff); ESP_LOGI(TAG, "EV_%s", buff);
sprintf(display_line7, buff); sprintf(display_line7, buff);
} }
}
} // onEvent()
// helper function to assign LoRa datarates to numeric spreadfactor values // helper function to assign LoRa datarates to numeric spreadfactor values
void switch_lora(uint8_t sf, uint8_t tx) { void switch_lora(uint8_t sf, uint8_t tx) {
@ -306,7 +341,7 @@ void lora_send(osjob_t *job) {
LMIC_setTxData2(SendBuffer.MessagePort, SendBuffer.Message, LMIC_setTxData2(SendBuffer.MessagePort, SendBuffer.Message,
SendBuffer.MessageSize, (cfg.countermode & 0x02)); SendBuffer.MessageSize, (cfg.countermode & 0x02));
ESP_LOGI(TAG, "%d bytes sent to LoRa", SendBuffer.MessageSize); ESP_LOGI(TAG, "%d bytes sent to LoRa", SendBuffer.MessageSize);
sprintf(display_line7, "PACKET QUEUED"); //sprintf(display_line7, "PACKET QUEUED");
} }
} }
// reschedule job every 0,5 - 1 sec. including a bit of random to prevent // reschedule job every 0,5 - 1 sec. including a bit of random to prevent

View File

@ -166,10 +166,7 @@ void setup() {
ESP_LOGI(TAG, "Starting LMIC..."); ESP_LOGI(TAG, "Starting LMIC...");
os_init(); // initialize lmic run-time environment on core 1 os_init(); // initialize lmic run-time environment on core 1
LMIC_reset(); // initialize lmic MAC LMIC_reset(); // initialize lmic MAC
LMIC_setClockError(MAX_CLOCK_ERROR * 1 / LMIC_setClockError(MAX_CLOCK_ERROR * CLOCK_ERROR_PROCENTAGE / 100);
100); // This tells LMIC to make the receive windows
// bigger, in case your clock is 1% faster or slower.
LMIC_startJoining(); // start joining LMIC_startJoining(); // start joining
#endif #endif

View File

@ -250,7 +250,7 @@ void do_ota_update() {
// check whether we have everything for OTA update // check whether we have everything for OTA update
if (contentLength && isValidContentType) { if (contentLength && isValidContentType) {
size_t written, current, size; size_t written = 0;
if (Update.begin(contentLength)) { if (Update.begin(contentLength)) {
#ifdef HAS_DISPLAY #ifdef HAS_DISPLAY
@ -270,7 +270,7 @@ void do_ota_update() {
if (written == contentLength) { if (written == contentLength) {
ESP_LOGI(TAG, "Written %u bytes successfully", written); ESP_LOGI(TAG, "Written %u bytes successfully", written);
snprintf(buf, 17, "%u kB Done!", (uint16_t)(written / 1024)); snprintf(buf, 17, "%ukB Done!", (uint16_t)(written / 1024));
display(4, "OK", buf); display(4, "OK", buf);
break; break;
} else { } else {
@ -329,7 +329,7 @@ void display(const uint8_t row, const std::string status,
#ifdef HAS_DISPLAY #ifdef HAS_DISPLAY
// callback function to show download progress while streaming data // callback function to show download progress while streaming data
void show_progress(size_t current, size_t size) { void show_progress (unsigned long current, unsigned long size) {
char buf[17]; char buf[17];
snprintf(buf, 17, "%-9lu (%3lu%%)", current, current * 100 / size); snprintf(buf, 17, "%-9lu (%3lu%%)", current, current * 100 / size);
display(4, "**", buf); display(4, "**", buf);

View File

@ -72,82 +72,4 @@
#define OTA_MIN_BATT 3700 // minimum battery level vor OTA [millivolt] #define OTA_MIN_BATT 3700 // minimum battery level vor OTA [millivolt]
// LMIC settings // LMIC settings
// define hardware independent LMIC settings here, settings of standard library in /lmic/config.h will be ignored // moved to src/lmic_config.h
// define hardware specifics settings in platformio.ini as build_flag for hardware environment
// Select frequency band here according to national regulations
#define CFG_eu868 1
//#define CFG_us915 1
// This is the SX1272/SX1273 radio, which is also used on the HopeRF
// RFM92 boards.
//#define CFG_sx1272_radio 1
// This is the SX1276/SX1277/SX1278/SX1279 radio, which is also used on
// the HopeRF RFM95 boards.
//#define CFG_sx1276_radio 1
// 16 μs per tick
// LMIC requires ticks to be 15.5μs - 100 μs long
#define US_PER_OSTICK_EXPONENT 4
#define US_PER_OSTICK (1 << US_PER_OSTICK_EXPONENT)
#define OSTICKS_PER_SEC (1000000 / US_PER_OSTICK)
// Set this to 1 to enable some basic debug output (using printf) about
// RF settings used during transmission and reception. Set to 2 to
// enable more verbose output. Make sure that printf is actually
// configured (e.g. on AVR it is not by default), otherwise using it can
// cause crashing.
//#define LMIC_DEBUG_LEVEL 1
// Enable this to allow using printf() to print to the given serial port
// (or any other Print object). This can be easy for debugging. The
// current implementation only works on AVR, though.
//#define LMIC_PRINTF_TO Serial
// Any runtime assertion failures are printed to this serial port (or
// any other Print object). If this is unset, any failures just silently
// halt execution.
#define LMIC_FAILURE_TO Serial
// Uncomment this to disable all code related to joining
//#define DISABLE_JOIN
// Uncomment this to disable all code related to ping
#define DISABLE_PING
// Uncomment this to disable all code related to beacon tracking.
// Requires ping to be disabled too
#define DISABLE_BEACONS
// Uncomment these to disable the corresponding MAC commands.
// Class A
//#define DISABLE_MCMD_DCAP_REQ // duty cycle cap
//#define DISABLE_MCMD_DN2P_SET // 2nd DN window param
//#define DISABLE_MCMD_SNCH_REQ // set new channel
// Class B
//#define DISABLE_MCMD_PING_SET // set ping freq, automatically disabled by DISABLE_PING
//#define DISABLE_MCMD_BCNI_ANS // next beacon start, automatical disabled by DISABLE_BEACON
// In LoRaWAN, a gateway applies I/Q inversion on TX, and nodes do the
// same on RX. This ensures that gateways can talk to nodes and vice
// versa, but gateways will not hear other gateways and nodes will not
// hear other nodes. By uncommenting this macro, this inversion is
// disabled and this node can hear other nodes. If two nodes both have
// this macro set, they can talk to each other (but they can no longer
// hear gateways). This should probably only be used when debugging
// and/or when talking to the radio directly (e.g. like in the "raw"
// example).
//#define DISABLE_INVERT_IQ_ON_RX
// This allows choosing between multiple included AES implementations.
// Make sure exactly one of these is uncommented.
//
// This selects the original AES implementation included LMIC. This
// implementation is optimized for speed on 32-bit processors using
// fairly big lookup tables, but it takes up big amounts of flash on the
// AVR architecture.
#define USE_ORIGINAL_AES
//
// This selects the AES implementation written by Ideetroon for their
// own LoRaWAN library. It also uses lookup tables, but smaller
// byte-oriented ones, making it use a lot less flash space (but it is
// also about twice as slow as the original).
// #define USE_IDEETRON_AES