nodemcu-firmware/app/modules/si7021.c

//***************************************************************************
// Si7021 module for ESP8266 with nodeMCU
// fetchbot @github
// MIT license, http://opensource.org/licenses/MIT
//***************************************************************************

#include "module.h"
#include "lauxlib.h"
#include "platform.h"
#include "osapi.h"

//***************************************************************************
// I2C ADDRESS DEFINITON
//***************************************************************************

#define SI7021_I2C_ADDRESS				(0x40)

//***************************************************************************
// COMMAND DEFINITON
//***************************************************************************

#define SI7021_CMD_MEASURE_RH_HOLD		(0xE5)
#define SI7021_CMD_MEASURE_RH_NOHOLD	(0xF5)
#define SI7021_CMD_MEASURE_TEMP_HOLD	(0xE3)
#define SI7021_CMD_MEASURE_TEMP_NOHOLD	(0xF3)
#define SI7021_CMD_READ_PREV_TEMP		(0xE0)
#define SI7021_CMD_RESET				(0xFE)
#define SI7021_CMD_WRITE_RHT_REG		(0xE6)
#define SI7021_CMD_READ_RHT_REG			(0xE7)
#define SI7021_CMD_WRITE_HEATER_REG		(0x51)
#define SI7021_CMD_READ_HEATER_REG		(0x11)
#define SI7021_CMD_ID1					(0xFA0F)
#define SI7021_CMD_ID2					(0xFCC9)
#define SI7021_CMD_FIRM_REV				(0x84B8)

//***************************************************************************
// REGISTER DEFINITON
//***************************************************************************

#define SI7021_RH12_TEMP14				(0x00)
#define SI7021_RH08_TEMP12				(0x01)
#define SI7021_RH10_TEMP13				(0x80)
#define SI7021_RH11_TEMP11				(0x81)
#define SI7021_HEATER_ENABLE			(0x04)
#define SI7021_HEATER_DISABLE			(0x00)

//***************************************************************************

static const uint32_t si7021_i2c_id = 0;
static uint8_t si7021_i2c_addr = SI7021_I2C_ADDRESS;
static uint8_t si7021_res = 0x00;
static uint8_t si7021_config = 0x3A;
static uint8_t si7021_heater = 0x00;
static uint8_t si7021_heater_setting = 0x00;

static uint8_t write_byte(uint8_t reg) {
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);
	platform_i2c_send_byte(si7021_i2c_id, reg);
	platform_i2c_send_stop(si7021_i2c_id);
}

static uint8_t write_reg(uint8_t reg, uint8_t data) {
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);
	platform_i2c_send_byte(si7021_i2c_id, reg);
	platform_i2c_send_byte(si7021_i2c_id, data);
	platform_i2c_send_stop(si7021_i2c_id);
}

static uint8_t read_reg(uint8_t reg, uint8_t *buf, uint8_t size) {
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);
	platform_i2c_send_byte(si7021_i2c_id, reg);
	platform_i2c_send_stop(si7021_i2c_id);
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_RECEIVER);
	os_delay_us(25000);
	while (size-- > 0)
		*buf++ = platform_i2c_recv_byte(si7021_i2c_id, size > 0);
	platform_i2c_send_stop(si7021_i2c_id);
	return 1;
}

static uint8_t read_serial(uint16_t reg, uint8_t *buf, uint8_t size) {
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);
	platform_i2c_send_byte(si7021_i2c_id, (uint8_t)(reg >> 8));
	platform_i2c_send_byte(si7021_i2c_id, (uint8_t)(reg & 0xFF));
	// platform_i2c_send_stop(si7021_i2c_id);
	platform_i2c_send_start(si7021_i2c_id);
	platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_RECEIVER);
	while (size-- > 0)
		*buf++ = platform_i2c_recv_byte(si7021_i2c_id, size > 0);
	platform_i2c_send_stop(si7021_i2c_id);
	return 1;
}

// CRC8
uint8_t si7021_crc8(uint8_t crc, uint8_t *buf, uint8_t size) {
	while (size--) {
		crc ^= *buf++;
		for (uint8_t i = 0; i < 8; i++) {
			if (crc & 0x80) {
				crc = (crc << 1) ^ 0x31;
			} else crc <<= 1;
		}
	}
	return crc;
}

static int si7021_lua_setup(lua_State* L) {

	write_byte(SI7021_CMD_RESET);
	os_delay_us(50000);

	// check for device on i2c bus
	uint8_t buf_r[1];
	read_reg(SI7021_CMD_READ_RHT_REG, buf_r, 1);
	if (buf_r[0] != 0x3A)
		return luaL_error(L, "found no device");

	return 0;
}

// Change sensor settings and returns them
// Lua: 	res, vdds, heater[, heater_set] = si7021.settings(RESOLUTION[,HEATER,HEATER_SETTING])
static int si7021_lua_setting(lua_State* L) {

	// check variable
	if (!lua_isnumber(L, 1)) {
		return luaL_error(L, "wrong arg range");
	}

	si7021_res = luaL_checkinteger(L, 1);
	if (!((si7021_res == SI7021_RH12_TEMP14) || (si7021_res == SI7021_RH08_TEMP12) || (si7021_res == SI7021_RH10_TEMP13) || (si7021_res == SI7021_RH11_TEMP11))) {
		return luaL_error(L, "Invalid argument: resolution");
	}

	si7021_config = (si7021_res | 0x3A);
	write_reg(SI7021_CMD_WRITE_RHT_REG,si7021_config);

	// Parse optional parameters
	if (lua_isnumber(L, 2)) {

		if (!lua_isnumber(L, 2) || !lua_isnumber(L, 3)) {
			return luaL_error(L, "wrong arg range");
		}

		si7021_heater = luaL_checkinteger(L, 2);
		if (!((si7021_heater == SI7021_HEATER_ENABLE) || (si7021_heater == SI7021_HEATER_DISABLE))) {
			return luaL_error(L, "Invalid argument: heater");
		}

		si7021_heater_setting = luaL_checkinteger(L, 3);
		if ((si7021_heater_setting < 0x00) || (si7021_heater_setting > 0x0F)) {
			return luaL_error(L, "Invalid argument: heater_setting");
		}

		si7021_config = (si7021_res | si7021_heater | 0x3A);
		write_reg(SI7021_CMD_WRITE_RHT_REG,si7021_config);
		write_reg(SI7021_CMD_WRITE_HEATER_REG,(si7021_heater_setting & 0x0F));
	}

	uint8_t buf_c[1];
	uint8_t buf_h[1];
	read_reg(SI7021_CMD_READ_RHT_REG, buf_c, 1);
	read_reg(SI7021_CMD_READ_HEATER_REG, buf_h, 1);

	lua_pushinteger(L, ((buf_c[0] >> 6) + (buf_c[0] & 0x01)));
	lua_pushinteger(L, ((buf_c[0] >> 6) & 0x01));
	lua_pushinteger(L, ((buf_c[0] >> 2) & 0x01));
	lua_pushinteger(L, (buf_h[0] & 0x0F));

	return 4;
}

// Reads sensor values from device and returns them
// Lua: 	hum, temp, humdec, tempdec = si7021.read()
static int si7021_lua_read(lua_State* L) {

	uint8_t buf_h[3];	// first two byte data, third byte crc
	read_reg(SI7021_CMD_MEASURE_RH_HOLD, buf_h, 3);
	if (buf_h[2] != si7021_crc8(0, buf_h, 2))	//crc check
		return luaL_error(L, "crc error");
	lua_Float hum = (uint16_t)((buf_h[0] << 8) | buf_h[1]);
	hum = ((hum * 125) / 65536 - 6);
	int humdec = (int)((hum - (int)hum) * 1000);

	uint8_t buf_t[2];	// two byte data, no crc on combined temp measurement
	read_reg(SI7021_CMD_READ_PREV_TEMP, buf_t, 2);
	lua_Float temp = (uint16_t)((buf_t[0] << 8) | buf_t[1]);
	temp = ((temp * 175.72) / 65536 - 46.85);
	int tempdec = (int)((temp - (int)temp) * 1000);

	lua_pushnumber(L, hum);
	lua_pushnumber(L, temp);
	lua_pushinteger(L, humdec);
	lua_pushinteger(L, tempdec);

	return 4;
}

// Reads electronic serial number from device and returns them
// Lua: 	serial = si7021.serial()
static int si7021_lua_serial(lua_State* L) {

	uint32_t serial_a;
	uint8_t crc = 0;
	uint8_t buf_s_1[8];	// every second byte contains crc
	read_serial(SI7021_CMD_ID1, buf_s_1, 8);
	for(uint8_t i = 0; i <= 6; i+=2) {
		crc = si7021_crc8(crc, buf_s_1+i, 1);
		if (buf_s_1[i+1] != crc)
			return luaL_error(L, "crc error");
		serial_a = (serial_a << 8) + buf_s_1[i];
	}

	uint32_t serial_b;
	crc = 0;
	uint8_t buf_s_2[6]; // every third byte contains crc
	read_serial(SI7021_CMD_ID2, buf_s_2, 6);
	for(uint8_t i = 0; i <=3; i+=3) {
		crc = si7021_crc8(crc, buf_s_2+i, 2);
		if (buf_s_2[i+2] != crc)
			return luaL_error(L, "crc error");
		serial_b = (serial_b << 16) + (buf_s_2[i] << 8) + buf_s_2[i+1];
	}

	lua_pushinteger(L, serial_a);
	lua_pushinteger(L, serial_b);

	return 2;
}

// Reads electronic firmware revision from device and returns them
// Lua: 	firmware = si7021.firmware()
static int si7021_lua_firmware(lua_State* L) {

	uint8_t firmware;
	uint8_t buf_f[1];
	read_serial(SI7021_CMD_FIRM_REV, buf_f, 1);
	firmware = buf_f[0];

	lua_pushinteger(L, firmware);

	return 1;
}

LROT_BEGIN(si7021, NULL, 0)
  LROT_FUNCENTRY( setup, si7021_lua_setup )
  LROT_FUNCENTRY( setting, si7021_lua_setting )
  LROT_FUNCENTRY( read, si7021_lua_read )
  LROT_FUNCENTRY( serial, si7021_lua_serial )
  LROT_FUNCENTRY( firmware, si7021_lua_firmware )
  LROT_NUMENTRY( RH12_TEMP14, SI7021_RH12_TEMP14 )
  LROT_NUMENTRY( RH08_TEMP12, SI7021_RH08_TEMP12 )
  LROT_NUMENTRY( RH10_TEMP13, SI7021_RH10_TEMP13 )
  LROT_NUMENTRY( RH11_TEMP11, SI7021_RH11_TEMP11 )
  LROT_NUMENTRY( HEATER_ENABLE, SI7021_HEATER_ENABLE )
  LROT_NUMENTRY( HEATER_DISABLE, SI7021_HEATER_DISABLE )
LROT_END(si7021, NULL, 0)


NODEMCU_MODULE(SI7021, "si7021", si7021, NULL);
add si7021 module (#1921) * add si7021 module * add settings function for resolution and heater 2017-04-27 23:16:33 +02:00			`//***************************************************************************`
			`// Si7021 module for ESP8266 with nodeMCU`
			`// fetchbot @github`
			`// MIT license, http://opensource.org/licenses/MIT`
			`//***************************************************************************`

			`#include "module.h"`
			`#include "lauxlib.h"`
			`#include "platform.h"`
			`#include "osapi.h"`

			`//***************************************************************************`
			`// I2C ADDRESS DEFINITON`
			`//***************************************************************************`

			`#define SI7021_I2C_ADDRESS (0x40)`

			`//***************************************************************************`
			`// COMMAND DEFINITON`
			`//***************************************************************************`

			`#define SI7021_CMD_MEASURE_RH_HOLD (0xE5)`
			`#define SI7021_CMD_MEASURE_RH_NOHOLD (0xF5)`
			`#define SI7021_CMD_MEASURE_TEMP_HOLD (0xE3)`
			`#define SI7021_CMD_MEASURE_TEMP_NOHOLD (0xF3)`
			`#define SI7021_CMD_READ_PREV_TEMP (0xE0)`
			`#define SI7021_CMD_RESET (0xFE)`
			`#define SI7021_CMD_WRITE_RHT_REG (0xE6)`
			`#define SI7021_CMD_READ_RHT_REG (0xE7)`
			`#define SI7021_CMD_WRITE_HEATER_REG (0x51)`
			`#define SI7021_CMD_READ_HEATER_REG (0x11)`
			`#define SI7021_CMD_ID1 (0xFA0F)`
			`#define SI7021_CMD_ID2 (0xFCC9)`
			`#define SI7021_CMD_FIRM_REV (0x84B8)`

			`//***************************************************************************`
			`// REGISTER DEFINITON`
			`//***************************************************************************`

			`#define SI7021_RH12_TEMP14 (0x00)`
			`#define SI7021_RH08_TEMP12 (0x01)`
			`#define SI7021_RH10_TEMP13 (0x80)`
			`#define SI7021_RH11_TEMP11 (0x81)`
			`#define SI7021_HEATER_ENABLE (0x04)`
			`#define SI7021_HEATER_DISABLE (0x00)`

			`//***************************************************************************`

			`static const uint32_t si7021_i2c_id = 0;`
			`static uint8_t si7021_i2c_addr = SI7021_I2C_ADDRESS;`
			`static uint8_t si7021_res = 0x00;`
			`static uint8_t si7021_config = 0x3A;`
			`static uint8_t si7021_heater = 0x00;`
			`static uint8_t si7021_heater_setting = 0x00;`

			`static uint8_t write_byte(uint8_t reg) {`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);`
			`platform_i2c_send_byte(si7021_i2c_id, reg);`
			`platform_i2c_send_stop(si7021_i2c_id);`
			`}`

			`static uint8_t write_reg(uint8_t reg, uint8_t data) {`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);`
			`platform_i2c_send_byte(si7021_i2c_id, reg);`
			`platform_i2c_send_byte(si7021_i2c_id, data);`
			`platform_i2c_send_stop(si7021_i2c_id);`
			`}`

			`static uint8_t read_reg(uint8_t reg, uint8_t *buf, uint8_t size) {`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);`
			`platform_i2c_send_byte(si7021_i2c_id, reg);`
			`platform_i2c_send_stop(si7021_i2c_id);`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_RECEIVER);`
			`os_delay_us(25000);`
			`while (size-- > 0)`
			`*buf++ = platform_i2c_recv_byte(si7021_i2c_id, size > 0);`
			`platform_i2c_send_stop(si7021_i2c_id);`
			`return 1;`
			`}`

			`static uint8_t read_serial(uint16_t reg, uint8_t *buf, uint8_t size) {`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_TRANSMITTER);`
			`platform_i2c_send_byte(si7021_i2c_id, (uint8_t)(reg >> 8));`
			`platform_i2c_send_byte(si7021_i2c_id, (uint8_t)(reg & 0xFF));`
			`// platform_i2c_send_stop(si7021_i2c_id);`
			`platform_i2c_send_start(si7021_i2c_id);`
			`platform_i2c_send_address(si7021_i2c_id, si7021_i2c_addr, PLATFORM_I2C_DIRECTION_RECEIVER);`
			`while (size-- > 0)`
			`*buf++ = platform_i2c_recv_byte(si7021_i2c_id, size > 0);`
			`platform_i2c_send_stop(si7021_i2c_id);`
			`return 1;`
			`}`

			`// CRC8`
			`uint8_t si7021_crc8(uint8_t crc, uint8_t *buf, uint8_t size) {`
			`while (size--) {`
			`crc ^= *buf++;`
			`for (uint8_t i = 0; i < 8; i++) {`
			`if (crc & 0x80) {`
			`crc = (crc << 1) ^ 0x31;`
			`} else crc <<= 1;`
			`}`
			`}`
			`return crc;`
			`}`

			`static int si7021_lua_setup(lua_State* L) {`

			`write_byte(SI7021_CMD_RESET);`
			`os_delay_us(50000);`

			`// check for device on i2c bus`
			`uint8_t buf_r[1];`
			`read_reg(SI7021_CMD_READ_RHT_REG, buf_r, 1);`
			`if (buf_r[0] != 0x3A)`
			`return luaL_error(L, "found no device");`

			`return 0;`
			`}`

			`// Change sensor settings and returns them`
			`// Lua: res, vdds, heater[, heater_set] = si7021.settings(RESOLUTION[,HEATER,HEATER_SETTING])`
			`static int si7021_lua_setting(lua_State* L) {`

			`// check variable`
			`if (!lua_isnumber(L, 1)) {`
			`return luaL_error(L, "wrong arg range");`
			`}`

			`si7021_res = luaL_checkinteger(L, 1);`
			`if (!((si7021_res == SI7021_RH12_TEMP14) \|\| (si7021_res == SI7021_RH08_TEMP12) \|\| (si7021_res == SI7021_RH10_TEMP13) \|\| (si7021_res == SI7021_RH11_TEMP11))) {`
			`return luaL_error(L, "Invalid argument: resolution");`
			`}`

			`si7021_config = (si7021_res \| 0x3A);`
			`write_reg(SI7021_CMD_WRITE_RHT_REG,si7021_config);`

			`// Parse optional parameters`
			`if (lua_isnumber(L, 2)) {`

			`if (!lua_isnumber(L, 2) \|\| !lua_isnumber(L, 3)) {`
			`return luaL_error(L, "wrong arg range");`
			`}`

			`si7021_heater = luaL_checkinteger(L, 2);`
			`if (!((si7021_heater == SI7021_HEATER_ENABLE) \|\| (si7021_heater == SI7021_HEATER_DISABLE))) {`
			`return luaL_error(L, "Invalid argument: heater");`
			`}`

			`si7021_heater_setting = luaL_checkinteger(L, 3);`
			`if ((si7021_heater_setting < 0x00) \|\| (si7021_heater_setting > 0x0F)) {`
			`return luaL_error(L, "Invalid argument: heater_setting");`
			`}`

			`si7021_config = (si7021_res \| si7021_heater \| 0x3A);`
			`write_reg(SI7021_CMD_WRITE_RHT_REG,si7021_config);`
			`write_reg(SI7021_CMD_WRITE_HEATER_REG,(si7021_heater_setting & 0x0F));`
			`}`

			`uint8_t buf_c[1];`
			`uint8_t buf_h[1];`
			`read_reg(SI7021_CMD_READ_RHT_REG, buf_c, 1);`
			`read_reg(SI7021_CMD_READ_HEATER_REG, buf_h, 1);`

			`lua_pushinteger(L, ((buf_c[0] >> 6) + (buf_c[0] & 0x01)));`
			`lua_pushinteger(L, ((buf_c[0] >> 6) & 0x01));`
			`lua_pushinteger(L, ((buf_c[0] >> 2) & 0x01));`
			`lua_pushinteger(L, (buf_h[0] & 0x0F));`

			`return 4;`
			`}`

			`// Reads sensor values from device and returns them`
			`// Lua: hum, temp, humdec, tempdec = si7021.read()`
			`static int si7021_lua_read(lua_State* L) {`

			`uint8_t buf_h[3]; // first two byte data, third byte crc`
			`read_reg(SI7021_CMD_MEASURE_RH_HOLD, buf_h, 3);`
			`if (buf_h[2] != si7021_crc8(0, buf_h, 2)) //crc check`
			`return luaL_error(L, "crc error");`
First phase of number to integer conversion (#3221) 2020-08-29 18:48:24 +02:00			`lua_Float hum = (uint16_t)((buf_h[0] << 8) \| buf_h[1]);`
add si7021 module (#1921) * add si7021 module * add settings function for resolution and heater 2017-04-27 23:16:33 +02:00			`hum = ((hum * 125) / 65536 - 6);`
			`int humdec = (int)((hum - (int)hum) * 1000);`

			`uint8_t buf_t[2]; // two byte data, no crc on combined temp measurement`
			`read_reg(SI7021_CMD_READ_PREV_TEMP, buf_t, 2);`
First phase of number to integer conversion (#3221) 2020-08-29 18:48:24 +02:00			`lua_Float temp = (uint16_t)((buf_t[0] << 8) \| buf_t[1]);`
add si7021 module (#1921) * add si7021 module * add settings function for resolution and heater 2017-04-27 23:16:33 +02:00			`temp = ((temp * 175.72) / 65536 - 46.85);`
			`int tempdec = (int)((temp - (int)temp) * 1000);`

			`lua_pushnumber(L, hum);`
			`lua_pushnumber(L, temp);`
			`lua_pushinteger(L, humdec);`
			`lua_pushinteger(L, tempdec);`

			`return 4;`
			`}`

			`// Reads electronic serial number from device and returns them`
			`// Lua: serial = si7021.serial()`
			`static int si7021_lua_serial(lua_State* L) {`

			`uint32_t serial_a;`
			`uint8_t crc = 0;`
			`uint8_t buf_s_1[8]; // every second byte contains crc`
			`read_serial(SI7021_CMD_ID1, buf_s_1, 8);`
			`for(uint8_t i = 0; i <= 6; i+=2) {`
			`crc = si7021_crc8(crc, buf_s_1+i, 1);`
			`if (buf_s_1[i+1] != crc)`
			`return luaL_error(L, "crc error");`
			`serial_a = (serial_a << 8) + buf_s_1[i];`
			`}`

			`uint32_t serial_b;`
			`crc = 0;`
			`uint8_t buf_s_2[6]; // every third byte contains crc`
			`read_serial(SI7021_CMD_ID2, buf_s_2, 6);`
			`for(uint8_t i = 0; i <=3; i+=3) {`
			`crc = si7021_crc8(crc, buf_s_2+i, 2);`
			`if (buf_s_2[i+2] != crc)`
			`return luaL_error(L, "crc error");`
			`serial_b = (serial_b << 16) + (buf_s_2[i] << 8) + buf_s_2[i+1];`
			`}`

			`lua_pushinteger(L, serial_a);`
			`lua_pushinteger(L, serial_b);`

			`return 2;`
			`}`

			`// Reads electronic firmware revision from device and returns them`
			`// Lua: firmware = si7021.firmware()`
			`static int si7021_lua_firmware(lua_State* L) {`

			`uint8_t firmware;`
			`uint8_t buf_f[1];`
			`read_serial(SI7021_CMD_FIRM_REV, buf_f, 1);`
			`firmware = buf_f[0];`

			`lua_pushinteger(L, firmware);`

			`return 1;`
			`}`

Squashed updates do get Lua51 and Lua53 working (#3075) - Lots of minor but nasty bugfixes to get all tests to run clean - core lua and test suite fixes to allow luac -F to run cleanly against test suite - next tranch to get LFS working - luac.cross -a options plus fixes from feedback - UART fixes and lua.c merge - commit of wip prior to rebaselining against current dev - more tweaks 2020-04-27 02:13:38 +02:00			`LROT_BEGIN(si7021, NULL, 0)`
Updated ROTables 1st tranch (#2742) Updated ROTables 2019-05-08 13:08:20 +02:00			`LROT_FUNCENTRY( setup, si7021_lua_setup )`
			`LROT_FUNCENTRY( setting, si7021_lua_setting )`
			`LROT_FUNCENTRY( read, si7021_lua_read )`
			`LROT_FUNCENTRY( serial, si7021_lua_serial )`
			`LROT_FUNCENTRY( firmware, si7021_lua_firmware )`
			`LROT_NUMENTRY( RH12_TEMP14, SI7021_RH12_TEMP14 )`
			`LROT_NUMENTRY( RH08_TEMP12, SI7021_RH08_TEMP12 )`
			`LROT_NUMENTRY( RH10_TEMP13, SI7021_RH10_TEMP13 )`
			`LROT_NUMENTRY( RH11_TEMP11, SI7021_RH11_TEMP11 )`
			`LROT_NUMENTRY( HEATER_ENABLE, SI7021_HEATER_ENABLE )`
			`LROT_NUMENTRY( HEATER_DISABLE, SI7021_HEATER_DISABLE )`
Squashed updates do get Lua51 and Lua53 working (#3075) - Lots of minor but nasty bugfixes to get all tests to run clean - core lua and test suite fixes to allow luac -F to run cleanly against test suite - next tranch to get LFS working - luac.cross -a options plus fixes from feedback - UART fixes and lua.c merge - commit of wip prior to rebaselining against current dev - more tweaks 2020-04-27 02:13:38 +02:00			`LROT_END(si7021, NULL, 0)`
Updated ROTables 1st tranch (#2742) Updated ROTables 2019-05-08 13:08:20 +02:00

			`NODEMCU_MODULE(SI7021, "si7021", si7021, NULL);`