wifi-tally_Oostendam/nodemcu-firmware/app/modules/somfy.c

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2021-09-27 19:52:27 +00:00
// ***************************************************************************
// Somfy module for ESP8266 with NodeMCU
//
// Written by Lukas Voborsky, @voborsky
// based on https://github.com/Nickduino/Somfy_Remote
// Somfy protocol description: https://pushstack.wordpress.com/somfy-rts-protocol/
// and discussion: https://forum.arduino.cc/index.php?topic=208346.0
//
// MIT license, http://opensource.org/licenses/MIT
// ***************************************************************************
//#define NODE_DEBUG
#include <stdint.h>
#include "os_type.h"
#include "osapi.h"
#include "sections.h"
#include "module.h"
#include "lauxlib.h"
#include "lmem.h"
#include "platform.h"
#include "task/task.h"
#include "hw_timer.h"
#include "user_interface.h"
#define SYMBOL 640 // symbol width in microseconds
#define SOMFY_UP 0x2
#define SOMFY_STOP 0x1
#define SOMFY_DOWN 0x4
#define SOMFY_PROG 0x8
#define DIRECT_WRITE_LOW(pin) (GPIO_OUTPUT_SET(GPIO_ID_PIN(pin_num[pin]), 0))
#define DIRECT_WRITE_HIGH(pin) (GPIO_OUTPUT_SET(GPIO_ID_PIN(pin_num[pin]), 1))
static const os_param_t TIMER_OWNER = 0x736f6d66; // "somf"
static task_handle_t done_taskid;
static uint8_t pin;
static uint8_t frame[7];
static uint8_t sync;
static uint8_t repeat;
//static uint32_t delay[10] = {9415, 89565, 4*SYMBOL, 4*SYMBOL, 4*SYMBOL, 4550, SYMBOL, SYMBOL, SYMBOL, 30415}; // in us
// the `delay` array of constants must be in RAM as it is accessed from the timer interrupt
static const RAM_CONST_SECTION_ATTR uint32_t delay[10] = {US_TO_RTC_TIMER_TICKS(9415), US_TO_RTC_TIMER_TICKS(89565), US_TO_RTC_TIMER_TICKS(4*SYMBOL), US_TO_RTC_TIMER_TICKS(4*SYMBOL), US_TO_RTC_TIMER_TICKS(4*SYMBOL), US_TO_RTC_TIMER_TICKS(4550), US_TO_RTC_TIMER_TICKS(SYMBOL), US_TO_RTC_TIMER_TICKS(SYMBOL), US_TO_RTC_TIMER_TICKS(SYMBOL), US_TO_RTC_TIMER_TICKS(30415)}; // in ticks (no need to recalculate)
static uint8_t repeatindex;
static uint8_t signalindex;
static uint8_t subindex;
static uint8_t bitcondition;
int lua_done_ref; // callback when transmission is done
void buildFrame(uint8_t *frame, uint64_t remote, uint8_t button, uint16_t code) {
// NODE_DBG("remote: %x\n", remote);
// NODE_DBG("button: %x\n", button);
// NODE_DBG("rolling code: %x\n", code);
frame[0] = 0xA7; // Encryption key. Doesn't matter much
frame[1] = button << 4; // Which button did you press? The 4 LSB will be the checksum
frame[2] = code >> 8; // Rolling code (big endian)
frame[3] = code; // Rolling code
frame[4] = remote >> 16; // Remote address
frame[5] = remote >> 8; // Remote address
frame[6] = remote; // Remote address
// frame[7] = 0x80;
// frame[8] = 0x0;
// frame[9] = 0x0;
// NODE_DBG("Frame:\t\t\t%02x %02x %02x %02x %02x %02x %02x\n", frame[0], frame[1], frame[2], frame[3], frame[4], frame[5], frame[6]);
// Checksum calculation: a XOR of all the nibbles
uint8_t checksum = 0;
for(uint8_t i = 0; i < 7; i++) {
checksum = checksum ^ frame[i] ^ (frame[i] >> 4);
}
checksum &= 0b1111; // We keep the last 4 bits only
//Checksum integration
frame[1] |= checksum; // If a XOR of all the nibbles is equal to 0, the blinds will consider the checksum ok.
// NODE_DBG("With checksum:\t%02x %02x %02x %02x %02x %02x %02x\n", frame[0], frame[1], frame[2], frame[3], frame[4], frame[5], frame[6]);
// Obfuscation: a XOR of all the uint8_ts
for(uint8_t i = 1; i < 7; i++) {
frame[i] ^= frame[i-1];
}
// NODE_DBG("Obfuscated:\t\t%02x %02x %02x %02x %02x %02x %02x\n", frame[0], frame[1], frame[2], frame[3], frame[4], frame[5], frame[6]);
}
static void somfy_transmissionDone (task_param_t arg)
{
lua_State *L = lua_getstate();
lua_rawgeti (L, LUA_REGISTRYINDEX, lua_done_ref);
luaL_unref (L, LUA_REGISTRYINDEX, lua_done_ref);
lua_done_ref = LUA_NOREF;
luaL_pcallx (L, 0, 0);
}
static void ICACHE_RAM_ATTR sendCommand(os_param_t p) {
(void) p;
// NODE_DBG("%d\t%d\n", signalindex, subindex);
switch (signalindex) {
case 0:
subindex = 0;
if(sync == 2) { // Only with the first frame.
//Wake-up pulse & Silence
DIRECT_WRITE_HIGH(pin);
signalindex++;
// delayMicroseconds(9415);
break;
} else {
signalindex++; signalindex++; //no break means: go directly to step 3
}
case 1:
//Wake-up pulse & Silence
DIRECT_WRITE_LOW(pin);
signalindex++;
// delayMicroseconds(89565);
break;
case 2:
signalindex++;
// no break means go directly to step 3
// a "useless" step to allow repeating the hardware sync w/o the silence after wake-up pulse
case 3:
// Hardware sync: two sync for the first frame, seven for the following ones.
DIRECT_WRITE_HIGH(pin);
signalindex++;
// delayMicroseconds(4*SYMBOL);
break;
case 4:
DIRECT_WRITE_LOW(pin);
subindex++;
if (subindex < sync) {signalindex--;} else {signalindex++;}
// delayMicroseconds(4*SYMBOL);
break;
case 5:
// Software sync
DIRECT_WRITE_HIGH(pin);
signalindex++;
// delayMicroseconds(4550);
break;
case 6:
DIRECT_WRITE_LOW(pin);
signalindex++;
subindex=0;
// delayMicroseconds(SYMBOL);
break;
case 7:
//Data: bits are sent one by one, starting with the MSB.
bitcondition = ((frame[subindex/8] >> (7 - (subindex%8))) & 1) == 1;
if(bitcondition) {
DIRECT_WRITE_LOW(pin);
}
else {
DIRECT_WRITE_HIGH(pin);
}
signalindex++;
// delayMicroseconds(SYMBOL);
break;
case 8:
//Data: bits are sent one by one, starting with the MSB.
if(bitcondition) {
DIRECT_WRITE_HIGH(pin);
}
else {
DIRECT_WRITE_LOW(pin);
}
if (subindex<56) {
subindex++;
signalindex--;
}
else {
signalindex++;
}
// delayMicroseconds(SYMBOL);
break;
case 9:
DIRECT_WRITE_LOW(pin);
signalindex++;
// delayMicroseconds(30415); // Inter-frame silence
break;
case 10:
repeatindex++;
if (repeatindex<repeat) {
DIRECT_WRITE_HIGH(pin); //start repeat from step 3, but don't wait as after step 1
signalindex=4; subindex=0; sync=7;
} else {
platform_hw_timer_close(TIMER_OWNER);
if (lua_done_ref != LUA_NOREF) {
task_post_low (done_taskid, (task_param_t)0);
}
}
break;
}
if (signalindex<10) {
platform_hw_timer_arm_ticks(TIMER_OWNER, delay[signalindex-1]);
}
}
static int somfy_lua_sendcommand(lua_State* L) { // pin, remote, command, rolling_code, num_repeat, callback
if (!lua_isnumber(L, 4)) {
return luaL_error(L, "wrong arg range");
}
pin = luaL_checkinteger(L, 1);
uint64_t remote = luaL_checkinteger(L, 2);
uint8_t cmd = luaL_checkinteger(L, 3);
uint16_t code = luaL_checkinteger(L, 4);
repeat=luaL_optint( L, 5, 2 );
luaL_argcheck(L, platform_gpio_exists(pin), 1, "Invalid pin");
luaL_unref(L, LUA_REGISTRYINDEX, lua_done_ref);
if (!lua_isnoneornil(L, 6)) {
lua_pushvalue(L, 6);
lua_done_ref = luaL_ref(L, LUA_REGISTRYINDEX);
} else {
lua_done_ref = LUA_NOREF;
}
MOD_CHECK_ID(gpio, pin);
platform_gpio_mode(pin, PLATFORM_GPIO_OUTPUT, PLATFORM_GPIO_PULLUP);
buildFrame(frame, remote, cmd, code);
if (!platform_hw_timer_init(TIMER_OWNER, FRC1_SOURCE, TRUE)) {
// Failed to init the timer
luaL_error(L, "Unable to initialize timer");
}
platform_hw_timer_set_func(TIMER_OWNER, sendCommand, 0);
sync=2;
signalindex=0; repeatindex=0;
sendCommand(0);
return 0;
}
LROT_BEGIN(somfy, NULL, 0)
LROT_NUMENTRY( UP, SOMFY_UP )
LROT_NUMENTRY( DOWN, SOMFY_DOWN )
LROT_NUMENTRY( PROG, SOMFY_PROG )
LROT_NUMENTRY( STOP, SOMFY_STOP )
LROT_FUNCENTRY( sendcommand, somfy_lua_sendcommand )
LROT_END(somfy, NULL, 0)
int luaopen_somfy( lua_State *L ) {
done_taskid = task_get_id((task_callback_t) somfy_transmissionDone);
return 0;
}
NODEMCU_MODULE(SOMFY, "somfy", somfy, luaopen_somfy);