// Module for interfacing with GPIO #include "module.h" #include "lauxlib.h" #include "lmem.h" #include "platform.h" #include "user_interface.h" #include "c_types.h" #include "c_string.h" #include "gpio.h" #define PULLUP PLATFORM_GPIO_PULLUP #define FLOAT PLATFORM_GPIO_FLOAT #define OUTPUT PLATFORM_GPIO_OUTPUT #define OPENDRAIN PLATFORM_GPIO_OPENDRAIN #define INPUT PLATFORM_GPIO_INPUT #define INTERRUPT PLATFORM_GPIO_INT #define HIGH PLATFORM_GPIO_HIGH #define LOW PLATFORM_GPIO_LOW #ifdef GPIO_INTERRUPT_ENABLE // We also know that the non-level interrupt types are < LOLEVEL, and that // HILEVEL is > LOLEVEL. Since this is burned into the hardware it is not // going to change. #define INTERRUPT_TYPE_IS_LEVEL(x) ((x) >= GPIO_PIN_INTR_LOLEVEL) static int gpio_cb_ref[GPIO_PIN_NUM]; // This task is scheduled by the ISR and is used // to initiate the Lua-land gpio.trig() callback function // It also re-enables the pin interrupt, so that we get another callback queued static void gpio_intr_callback_task (task_param_t param, uint8 priority) { unsigned pin = param >> 1; unsigned level = param & 1; UNUSED(priority); NODE_DBG("pin:%d, level:%d \n", pin, level); if(gpio_cb_ref[pin] != LUA_NOREF) { // GPIO callbacks are run in L0 and inlcude the level as a parameter lua_State *L = lua_getstate(); NODE_DBG("Calling: %08x\n", gpio_cb_ref[pin]); // if (!INTERRUPT_TYPE_IS_LEVEL(pin_int_type[pin])) { // Edge triggered -- re-enable the interrupt platform_gpio_intr_init(pin, pin_int_type[pin]); } // Do the actual callback lua_rawgeti(L, LUA_REGISTRYINDEX, gpio_cb_ref[pin]); lua_pushinteger(L, level); lua_call(L, 1, 0); if (INTERRUPT_TYPE_IS_LEVEL(pin_int_type[pin])) { // Level triggered -- re-enable the callback platform_gpio_intr_init(pin, pin_int_type[pin]); } } } // Lua: trig( pin, type, function ) static int lgpio_trig( lua_State* L ) { unsigned pin = luaL_checkinteger( L, 1 ); static const char * const opts[] = {"none", "up", "down", "both", "low", "high", NULL}; static const int opts_type[] = { GPIO_PIN_INTR_DISABLE, GPIO_PIN_INTR_POSEDGE, GPIO_PIN_INTR_NEGEDGE, GPIO_PIN_INTR_ANYEDGE, GPIO_PIN_INTR_LOLEVEL, GPIO_PIN_INTR_HILEVEL }; luaL_argcheck(L, platform_gpio_exists(pin) && pin>0, 1, "Invalid interrupt pin"); int old_pin_ref = gpio_cb_ref[pin]; int type = opts_type[luaL_checkoption(L, 2, "none", opts)]; if (type == GPIO_PIN_INTR_DISABLE) { // "none" clears the callback gpio_cb_ref[pin] = LUA_NOREF; } else if (lua_gettop(L)==2 && old_pin_ref != LUA_NOREF) { // keep the old one if no callback old_pin_ref = LUA_NOREF; } else if (lua_type(L, 3) == LUA_TFUNCTION || lua_type(L, 3) == LUA_TLIGHTFUNCTION) { // set up the new callback if present lua_pushvalue(L, 3); gpio_cb_ref[pin] = luaL_ref(L, LUA_REGISTRYINDEX); } else { // invalid combination, so clear down any old callback and throw an error if(old_pin_ref != LUA_NOREF) luaL_unref(L, LUA_REGISTRYINDEX, old_pin_ref); luaL_argcheck(L, 0, 3, "invalid callback type"); } // unreference any overwritten callback if(old_pin_ref != LUA_NOREF) luaL_unref(L, LUA_REGISTRYINDEX, old_pin_ref); NODE_DBG("Pin data: %d %d %08x, %d %d %d, %08x\n", pin, type, pin_mux[pin], pin_num[pin], pin_func[pin], pin_int_type[pin], gpio_cb_ref[pin]); platform_gpio_intr_init(pin, type); return 0; } #endif // Lua: mode( pin, mode, pullup ) static int lgpio_mode( lua_State* L ) { unsigned pin = luaL_checkinteger( L, 1 ); unsigned mode = luaL_checkinteger( L, 2 ); unsigned pullup = luaL_optinteger( L, 3, FLOAT ); luaL_argcheck(L, platform_gpio_exists(pin) && (mode!=INTERRUPT || pin>0), 1, "Invalid pin"); luaL_argcheck(L, mode==OUTPUT || mode==OPENDRAIN || mode==INPUT #ifdef GPIO_INTERRUPT_ENABLE || mode==INTERRUPT #endif , 2, "wrong arg type" ); if(pullup!=FLOAT) pullup = PULLUP; NODE_DBG("pin,mode,pullup= %d %d %d\n",pin,mode,pullup); NODE_DBG("Pin data at mode: %d %08x, %d %d %d, %08x\n", pin, pin_mux[pin], pin_num[pin], pin_func[pin], pin_int_type[pin], gpio_cb_ref[pin]); #ifdef GPIO_INTERRUPT_ENABLE if (mode != INTERRUPT){ // disable interrupt if(gpio_cb_ref[pin] != LUA_NOREF){ luaL_unref(L, LUA_REGISTRYINDEX, gpio_cb_ref[pin]); gpio_cb_ref[pin] = LUA_NOREF; } } #endif if( platform_gpio_mode( pin, mode, pullup ) < 0 ) return luaL_error( L, "wrong pin num." ); return 0; } // Lua: read( pin ) static int lgpio_read( lua_State* L ) { unsigned pin = luaL_checkinteger( L, 1 ); MOD_CHECK_ID( gpio, pin ); lua_pushinteger( L, platform_gpio_read( pin ) ); return 1; } // Lua: write( pin, level ) static int lgpio_write( lua_State* L ) { unsigned pin = luaL_checkinteger( L, 1 ); unsigned level = luaL_checkinteger( L, 2 ); MOD_CHECK_ID( gpio, pin ); luaL_argcheck(L, level==HIGH || level==LOW, 2, "wrong level type" ); platform_gpio_write(pin, level); return 0; } #define DELAY_TABLE_MAX_LEN 256 #define delayMicroseconds os_delay_us // Lua: serout( pin, firstLevel, delay_table, [repeatNum] ) // -- serout( pin, firstLevel, delay_table, [repeatNum] ) // gpio.mode(1,gpio.OUTPUT,gpio.PULLUP) // gpio.serout(1,1,{30,30,60,60,30,30}) -- serial one byte, b10110010 // gpio.serout(1,1,{30,70},8) -- serial 30% pwm 10k, lasts 8 cycles // gpio.serout(1,1,{3,7},8) -- serial 30% pwm 100k, lasts 8 cycles // gpio.serout(1,1,{0,0},8) -- serial 50% pwm as fast as possible, lasts 8 cycles // gpio.mode(1,gpio.OUTPUT,gpio.PULLUP) // gpio.serout(1,0,{20,10,10,20,10,10,10,100}) -- sim uart one byte 0x5A at about 100kbps // gpio.serout(1,1,{8,18},8) -- serial 30% pwm 38k, lasts 8 cycles static int lgpio_serout( lua_State* L ) { unsigned clocks_per_us = system_get_cpu_freq(); unsigned pin = luaL_checkinteger( L, 1 ); unsigned level = luaL_checkinteger( L, 2 ); unsigned repeats = luaL_optint( L, 4, 1 ); unsigned table_len, i, j; luaL_argcheck(L, platform_gpio_exists(pin), 1, "Invalid pin"); luaL_argcheck(L, level==HIGH || level==LOW, 2, "Wrong arg type" ); luaL_argcheck(L, lua_istable( L, 3 ) && ((table_len = lua_objlen( L, 3 )= 256" ); uint32 *delay_table = luaM_newvector(L, table_len*repeats, uint32); for( i = 1; i <= table_len; i++ ) { lua_rawgeti( L, 3, i + 1 ); unsigned delay = (unsigned) luaL_checkinteger( L, -1 ); if (delay > 1000000) return luaL_error( L, "delay %u must be < 1,000,000 us", i ); delay_table[i-1] = delay; lua_pop( L, 1 ); } for( i = 0; i <= repeats; i++ ) { if (!i) // skip the first loop (presumably this is some form of icache priming??). continue; for( j = 0;j < table_len; j++ ){ /* Direct Write is a ROM function which already disables interrupts for the atomic bit */ GPIO_OUTPUT_SET(GPIO_ID_PIN(pin_num[pin]), level); delayMicroseconds(delay_table[j]); level = level==LOW ? HIGH : LOW; } } luaM_freearray(L, delay_table, table_len, uint32); return 0; } #undef DELAY_TABLE_MAX_LEN // Module function map static const LUA_REG_TYPE gpio_map[] = { { LSTRKEY( "mode" ), LFUNCVAL( lgpio_mode ) }, { LSTRKEY( "read" ), LFUNCVAL( lgpio_read ) }, { LSTRKEY( "write" ), LFUNCVAL( lgpio_write ) }, { LSTRKEY( "serout" ), LFUNCVAL( lgpio_serout ) }, #ifdef GPIO_INTERRUPT_ENABLE { LSTRKEY( "trig" ), LFUNCVAL( lgpio_trig ) }, { LSTRKEY( "INT" ), LNUMVAL( INTERRUPT ) }, #endif { LSTRKEY( "OUTPUT" ), LNUMVAL( OUTPUT ) }, { LSTRKEY( "OPENDRAIN" ), LNUMVAL( OPENDRAIN ) }, { LSTRKEY( "INPUT" ), LNUMVAL( INPUT ) }, { LSTRKEY( "HIGH" ), LNUMVAL( HIGH ) }, { LSTRKEY( "LOW" ), LNUMVAL( LOW ) }, { LSTRKEY( "FLOAT" ), LNUMVAL( FLOAT ) }, { LSTRKEY( "PULLUP" ), LNUMVAL( PULLUP ) }, { LNILKEY, LNILVAL } }; int luaopen_gpio( lua_State *L ) { #ifdef GPIO_INTERRUPT_ENABLE int i; for(i=0;i