#include "c_stdlib.h" #include "c_string.h" #include "lualib.h" #include "lauxlib.h" #include "lrotable.h" #include "module.h" #include "platform.h" #include "user_interface.h" #define NOP asm volatile(" nop \n\t") static inline void apa102_send_byte(uint32_t data_pin, uint32_t clock_pin, uint8_t byte) { int i; for (i = 0; i < 8; i++) { if (byte & 0x80) { GPIO_OUTPUT_SET(data_pin, PLATFORM_GPIO_HIGH); // Set pin high } else { GPIO_OUTPUT_SET(data_pin, PLATFORM_GPIO_LOW); // Set pin low } GPIO_OUTPUT_SET(clock_pin, PLATFORM_GPIO_HIGH); // Set pin high byte <<= 1; NOP; NOP; GPIO_OUTPUT_SET(clock_pin, PLATFORM_GPIO_LOW); // Set pin low NOP; NOP; } } static void apa102_send_buffer(uint32_t data_pin, uint32_t clock_pin, uint32_t *buf, uint32_t nbr_frames) { int i; // Send 32-bit Start Frame that's all 0x00 apa102_send_byte(data_pin, clock_pin, 0x00); apa102_send_byte(data_pin, clock_pin, 0x00); apa102_send_byte(data_pin, clock_pin, 0x00); apa102_send_byte(data_pin, clock_pin, 0x00); // Send 32-bit LED Frames for (i = 0; i < nbr_frames; i++) { uint8_t *byte = (uint8_t *) buf++; // Set the first 3 bits of that byte to 1. // This makes the lua interface easier to use since you // don't have to worry about creating invalid LED Frames. byte[0] |= 0xE0; apa102_send_byte(data_pin, clock_pin, byte[0]); apa102_send_byte(data_pin, clock_pin, byte[1]); apa102_send_byte(data_pin, clock_pin, byte[2]); apa102_send_byte(data_pin, clock_pin, byte[3]); } // Send 32-bit End Frames uint32_t required_postamble_frames = (nbr_frames + 1) / 2; for (i = 0; i < required_postamble_frames; i++) { apa102_send_byte(data_pin, clock_pin, 0xFF); apa102_send_byte(data_pin, clock_pin, 0xFF); apa102_send_byte(data_pin, clock_pin, 0xFF); apa102_send_byte(data_pin, clock_pin, 0xFF); } } // Lua: apa102.write(data_pin, clock_pin, "string") // Byte quads in the string are interpreted as (brightness, B, G, R) values. // Only the first 5 bits of the brightness value is actually used (0-31). // This function does not corrupt your buffer. // // apa102.write(1, 3, string.char(31, 0, 255, 0)) uses GPIO5 for DATA and GPIO0 for CLOCK and sets the first LED green, with the brightness 31 (out of 0-32) // apa102.write(5, 6, string.char(255, 0, 0, 255):rep(10)) uses GPIO14 for DATA and GPIO12 for CLOCK and sets ten LED to red, with the brightness 31 (out of 0-32). // Brightness values are clamped to 0-31. static int apa102_write(lua_State* L) { uint8_t data_pin = luaL_checkinteger(L, 1); MOD_CHECK_ID(gpio, data_pin); uint32_t alt_data_pin = pin_num[data_pin]; uint8_t clock_pin = luaL_checkinteger(L, 2); MOD_CHECK_ID(gpio, clock_pin); uint32_t alt_clock_pin = pin_num[clock_pin]; size_t buf_len; const char *buf = luaL_checklstring(L, 3, &buf_len); uint32_t nbr_frames = buf_len / 4; if (nbr_frames > 100000) { return luaL_error(L, "The supplied buffer is too long, and might cause the callback watchdog to bark."); } // Initialize the output pins platform_gpio_mode(data_pin, PLATFORM_GPIO_OUTPUT, PLATFORM_GPIO_FLOAT); GPIO_OUTPUT_SET(alt_data_pin, PLATFORM_GPIO_HIGH); // Set pin high platform_gpio_mode(clock_pin, PLATFORM_GPIO_OUTPUT, PLATFORM_GPIO_FLOAT); GPIO_OUTPUT_SET(alt_clock_pin, PLATFORM_GPIO_LOW); // Set pin low // Send the buffers apa102_send_buffer(alt_data_pin, alt_clock_pin, (uint32_t *) buf, (uint32_t) nbr_frames); return 0; } LROT_PUBLIC_BEGIN(apa102) LROT_FUNCENTRY( write, apa102_write ) LROT_END( apa102, NULL, 0 ) LUALIB_API int luaopen_apa102(lua_State *L) { LREGISTER(L, "apa102", apa102_map); return 0; } NODEMCU_MODULE(APA102, "apa102", apa102, luaopen_apa102);