nodemcu-firmware/components/modules/spi_master.c

339 lines
9.0 KiB
C

// Module for interfacing with the SPI master hardware
#include <string.h>
#include "module.h"
#include "lauxlib.h"
#include "lextra.h"
#include "driver/spi_master.h"
#include "esp_heap_caps.h"
#include "esp_log.h"
#include "spi_common.h"
#include "common.h"
#define SPI_MASTER_TAG "spi.master"
#define UD_HOST_STR "spi.master"
#define UD_DEVICE_STR "spi.device"
static int no_err( esp_err_t err )
{
switch (err)
{
default:
ESP_LOGI(SPI_MASTER_TAG, "unknown error");
return 0;
case ESP_ERR_INVALID_ARG:
ESP_LOGI(SPI_MASTER_TAG, "invalid argument");
return 0;
case ESP_ERR_INVALID_STATE:
ESP_LOGI(SPI_MASTER_TAG, "internal logic error");
return 0;
case ESP_ERR_NO_MEM:
ESP_LOGI(SPI_MASTER_TAG, "no memory");
return 0;
case ESP_OK:
return 1;
}
}
// ****************************************************************************
// Device related functions
//
typedef struct {
spi_device_handle_t device;
int host_ref, host;
} lspi_device_t;
#define GET_UD_DEVICE \
lspi_device_t *ud = (lspi_device_t *)luaL_checkudata( L, 1, UD_DEVICE_STR );
static int lspi_device_free( lua_State *L )
{
GET_UD_DEVICE;
if (ud->device) {
spi_bus_remove_device( ud->device );
ud->device = NULL;
// unref host to unblock automatic gc from this object
luaL_unref( L, LUA_REGISTRYINDEX, ud->host_ref );
ud->host_ref = LUA_NOREF;
}
return 0;
}
// Lua:
// recv = dev:transfer(trans_desc)
// recv = dev:transfer(data)
static int lspi_device_transfer( lua_State *L )
{
GET_UD_DEVICE;
int stack = 1;
luaL_argcheck( L, ud->device, stack, "no device" );
spi_transaction_t trans;
memset( &trans, 0, sizeof( trans ) );
size_t data_len, rx_len;
const char *data;
int type = lua_type( L, ++stack );
luaL_argcheck( L, type == LUA_TSTRING || type == LUA_TTABLE, stack, "string or table expected" );
if (type == LUA_TSTRING) {
data = luaL_checklstring( L, stack, &data_len );
rx_len = data_len;
} else {
const char * const options[] = {"std", "dio", "qio"};
const uint32_t options_flags[] = {0, SPI_TRANS_MODE_DIO, SPI_TRANS_MODE_QIO};
// temporarily copy option table to top of stack for opt_ functions
lua_pushvalue( L, stack );
//
trans.cmd = opt_checkint( L, "cmd", 0 );
trans.addr = opt_checkint( L, "addr", 0 );
//
rx_len = opt_checkint( L, "rxlen", 0 );
//
trans.flags |= opt_checkbool( L, "addr_mode", false ) ? SPI_TRANS_MODE_DIOQIO_ADDR : 0;
//
lua_getfield( L, stack, "mode" );
trans.flags |= options_flags[ luaL_checkoption( L, -1, options[0], options ) ];
//
data_len = 0;
data = opt_checklstring( L, "txdata", "", &data_len );
lua_settop( L, stack );
}
const char *msg = NULL;
trans.length = data_len * 8;
if (data_len == 0) {
//no MOSI phase requested
trans.tx_buffer = NULL;
} else if (data_len <=4 ) {
// use local tx data buffer
trans.flags |= SPI_TRANS_USE_TXDATA;
memcpy( trans.tx_data, data, data_len );
} else {
// use DMA'able buffer
if ((trans.tx_buffer = heap_caps_malloc( data_len, MALLOC_CAP_DMA ))) {
memcpy( (void *)trans.tx_buffer, data, data_len );
} else {
msg = "no memory";
goto free_mem;
}
}
trans.rxlength = rx_len * 8;
if (rx_len == 0) {
// no MISO phase requested
trans.rx_buffer = NULL;
} else if (rx_len <= 4) {
// use local rx data buffer
trans.flags |= SPI_TRANS_USE_RXDATA;
} else {
// use DMA'able buffer
if (!(trans.rx_buffer = heap_caps_malloc( rx_len, MALLOC_CAP_DMA ))) {
msg = "no mem";
goto free_mem;
}
}
// finally perform the transaction
if (no_err( spi_device_transmit( ud->device, &trans ) )) {
// evaluate receive data
if (trans.flags & SPI_TRANS_USE_RXDATA) {
lua_pushlstring( L, (const char *)&(trans.rx_data[0]), rx_len );
} else {
lua_pushlstring( L, trans.rx_buffer, rx_len );
}
} else
msg = "transfer failed";
free_mem:
if (!(trans.flags & SPI_TRANS_USE_TXDATA) && trans.tx_buffer)
heap_caps_free( (void *)trans.tx_buffer );
if (!(trans.flags & SPI_TRANS_USE_RXDATA) && trans.rx_buffer)
heap_caps_free( (void *)trans.rx_buffer );
if (msg)
return luaL_error( L, msg );
return 1;
}
LROT_BEGIN(lspi_device, NULL, LROT_MASK_GC_INDEX)
LROT_FUNCENTRY( __gc, lspi_device_free )
LROT_TABENTRY( __index, lspi_device )
LROT_FUNCENTRY( transfer, lspi_device_transfer )
LROT_FUNCENTRY( remove, lspi_device_free )
LROT_END(lspi_device, NULL, LROT_MASK_GC_INDEX)
// ****************************************************************************
// Host related functions
//
#define GET_UD_HOST \
lspi_host_t *ud = (lspi_host_t *)luaL_checkudata( L, 1, UD_HOST_STR );
//
#define CONFIG_BUS_PIN_FROM_FIELD(pin) \
config.pin ## _io_num = opt_checkint( L, #pin, -1 );
//
#define CONFIG_DEVICE_FROM_INT_FIELD(field) \
config.field = opt_checkint( L, #field, 0 );
#define CONFIG_DEVICE_FROM_BOOL_FIELD(field, mask) \
config.flags |= opt_checkbool( L, #field, false ) ? mask : 0;
static int lspi_host_free( lua_State *L )
{
GET_UD_HOST;
if (ud->host >= 0) {
spi_bus_free( ud->host );
ud->host = -1;
}
return 0;
}
// Lua: master = spi.master(host, config)
int lspi_master( lua_State *L )
{
int stack = 0;
int top = lua_gettop( L );
int host = luaL_checkint( L, ++stack );
luaL_argcheck( L,
host == SPI1_HOST || host == SPI2_HOST || host == SPI2_HOST,
stack,
"invalid host" );
if (lua_type( L, ++stack ) != LUA_TTABLE) {
// no configuration table provided
// assume that host is already initialized and just provide the object
lspi_host_t *ud = (lspi_host_t *)lua_newuserdata( L, sizeof( lspi_host_t ) );
luaL_getmetatable( L, UD_HOST_STR );
lua_setmetatable( L, -2 );
ud->host = host;
return 1;
}
spi_bus_config_t config;
memset( &config, 0, sizeof( config ) );
// temporarily copy option table to top of stack for opt_ functions
lua_pushvalue( L, stack );
CONFIG_BUS_PIN_FROM_FIELD(sclk);
CONFIG_BUS_PIN_FROM_FIELD(mosi);
CONFIG_BUS_PIN_FROM_FIELD(miso);
CONFIG_BUS_PIN_FROM_FIELD(quadwp);
CONFIG_BUS_PIN_FROM_FIELD(quadhd);
lua_settop( L, top );
int use_dma = luaL_optint( L, ++stack, 1 );
luaL_argcheck( L, use_dma >= 0 && use_dma <= 2, stack, "out of range" );
if (no_err( spi_bus_initialize( host, &config, use_dma ) )) {
lspi_host_t *ud = (lspi_host_t *)lua_newuserdata( L, sizeof( lspi_host_t ) );
luaL_getmetatable( L, UD_HOST_STR );
lua_setmetatable( L, -2 );
ud->host = host;
return 1;
}
return luaL_error( L, "bus init failed" );
}
// Lua: dev = master:device(config)
static int lspi_host_device( lua_State *L )
{
GET_UD_HOST;
int stack = 1;
luaL_argcheck( L, ud->host >= 0, stack, "no active bus host" );
luaL_checktype( L, ++stack, LUA_TTABLE );
spi_device_interface_config_t config;
memset( &config, 0, sizeof( config ) );
// temporarily copy option table to top of stack for opt_ functions
lua_pushvalue( L, stack );
// mandatory fields
config.mode = (uint8_t)opt_checkint_range( L, "mode", -1, 0, 3 );
//
config.clock_speed_hz = opt_checkint_range( L, "freq", -1, 0, SPI_MASTER_FREQ_80M );
//
// optional fields
config.spics_io_num = opt_checkint( L, "cs", -1 );
CONFIG_DEVICE_FROM_INT_FIELD(command_bits);
CONFIG_DEVICE_FROM_INT_FIELD(address_bits);
CONFIG_DEVICE_FROM_INT_FIELD(dummy_bits);
CONFIG_DEVICE_FROM_INT_FIELD(cs_ena_pretrans);
CONFIG_DEVICE_FROM_INT_FIELD(cs_ena_posttrans);
CONFIG_DEVICE_FROM_INT_FIELD(duty_cycle_pos);
CONFIG_DEVICE_FROM_BOOL_FIELD(tx_lsb_first, SPI_DEVICE_TXBIT_LSBFIRST);
CONFIG_DEVICE_FROM_BOOL_FIELD(rx_lsb_first, SPI_DEVICE_RXBIT_LSBFIRST);
CONFIG_DEVICE_FROM_BOOL_FIELD(wire3, SPI_DEVICE_3WIRE);
CONFIG_DEVICE_FROM_BOOL_FIELD(positive_cs, SPI_DEVICE_POSITIVE_CS);
CONFIG_DEVICE_FROM_BOOL_FIELD(halfduplex, SPI_DEVICE_HALFDUPLEX);
CONFIG_DEVICE_FROM_BOOL_FIELD(clk_as_cs, SPI_DEVICE_CLK_AS_CS);
lua_settop( L, stack );
//
// fill remaining config entries
config.queue_size = 1;
lspi_device_t *dev = (lspi_device_t *)lua_newuserdata( L, sizeof( lspi_device_t ) );
dev->device = NULL;
if (no_err( spi_bus_add_device( ud->host, &config, &(dev->device) ) )) {
luaL_getmetatable( L, UD_DEVICE_STR );
lua_setmetatable( L, -2 );
// reference host object to avoid automatic gc
lua_pushvalue( L, 1 );
dev->host_ref = luaL_ref( L, LUA_REGISTRYINDEX );
dev->host = ud->host;
return 1;
}
lua_pop( L, 1 );
return luaL_error( L, "failed to add device" );
}
LROT_BEGIN(lspi_master, NULL, LROT_MASK_GC_INDEX)
LROT_FUNCENTRY( __gc, lspi_host_free )
LROT_TABENTRY( __index, lspi_master )
LROT_FUNCENTRY( device, lspi_host_device )
LROT_FUNCENTRY( close, lspi_host_free )
LROT_END(lspi_master, NULL, LROT_MASK_GC_INDEX)
// ****************************************************************************
// Generic
//
int luaopen_spi_master( lua_State *L ) {
luaL_rometatable(L, UD_HOST_STR, LROT_TABLEREF(lspi_master));
luaL_rometatable(L, UD_DEVICE_STR, LROT_TABLEREF(lspi_device));
return 0;
}