/* * SPDX-FileCopyrightText: 2022-2024 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include "sdkconfig.h" #if CONFIG_RMT_ENABLE_DEBUG_LOG // The local log level must be defined before including esp_log.h // Set the maximum log level for this source file #define LOG_LOCAL_LEVEL ESP_LOG_DEBUG #endif #include "esp_log.h" #include "esp_check.h" #include "driver/rmt_encoder.h" #include "rmt_private.h" #include "hal/hal_utils.h" static const char *TAG = "rmt"; typedef struct rmt_bytes_encoder_t { rmt_encoder_t base; // encoder base class size_t last_bit_index; // index of the encoding bit position in the encoding byte size_t last_byte_index; // index of the encoding byte in the primary stream rmt_symbol_word_t bit0; // bit zero representing rmt_symbol_word_t bit1; // bit one representing struct { uint32_t msb_first: 1; // encode MSB firstly } flags; } rmt_bytes_encoder_t; typedef struct rmt_copy_encoder_t { rmt_encoder_t base; // encoder base class size_t last_symbol_index; // index of symbol position in the primary stream } rmt_copy_encoder_t; typedef struct rmt_simple_encoder_t { rmt_encoder_t base; // encoder base class size_t last_symbol_index; // index of symbol position in the primary stream rmt_encode_simple_cb_t callback; //callback to call to encode void *arg; // opaque callback argument rmt_symbol_word_t *ovf_buf; //overflow buffer size_t ovf_buf_size; //size, in elements, of overflow buffer size_t ovf_buf_fill_len; //how much actual info the overflow buffer has size_t ovf_buf_parsed_pos; //up to where we moved info from the ovf buf to the rmt bool callback_done; //true if we can't call the callback for more data anymore. } rmt_simple_encoder_t; static esp_err_t rmt_bytes_encoder_reset(rmt_encoder_t *encoder) { rmt_bytes_encoder_t *bytes_encoder = __containerof(encoder, rmt_bytes_encoder_t, base); // reset index to zero bytes_encoder->last_bit_index = 0; bytes_encoder->last_byte_index = 0; return ESP_OK; } static size_t IRAM_ATTR rmt_encode_bytes(rmt_encoder_t *encoder, rmt_channel_handle_t channel, const void *primary_data, size_t data_size, rmt_encode_state_t *ret_state) { rmt_bytes_encoder_t *bytes_encoder = __containerof(encoder, rmt_bytes_encoder_t, base); rmt_tx_channel_t *tx_chan = __containerof(channel, rmt_tx_channel_t, base); const uint8_t *raw_data = (const uint8_t *)primary_data; rmt_encode_state_t state = RMT_ENCODING_RESET; rmt_dma_descriptor_t *desc0 = NULL; rmt_dma_descriptor_t *desc1 = NULL; size_t byte_index = bytes_encoder->last_byte_index; size_t bit_index = bytes_encoder->last_bit_index; // how many symbols will be generated by the encoder size_t mem_want = (data_size - byte_index - 1) * 8 + (8 - bit_index); // how many symbols we can save for this round size_t mem_have = tx_chan->mem_end - tx_chan->mem_off; // where to put the encoded symbols? DMA buffer or RMT HW memory rmt_symbol_word_t *mem_to_nc = NULL; if (channel->dma_chan) { mem_to_nc = tx_chan->dma_mem_base_nc; } else { mem_to_nc = channel->hw_mem_base; } // how many symbols will be encoded in this round size_t encode_len = MIN(mem_want, mem_have); bool encoding_truncated = mem_have < mem_want; bool encoding_space_free = mem_have > mem_want; if (channel->dma_chan) { // mark the start descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc0 = &tx_chan->dma_nodes_nc[0]; } else { desc0 = &tx_chan->dma_nodes_nc[1]; } } size_t len = encode_len; while (len > 0) { // start from last time truncated encoding uint8_t cur_byte = raw_data[byte_index]; // bit-wise reverse if (bytes_encoder->flags.msb_first) { cur_byte = hal_utils_bitwise_reverse8(cur_byte); } while ((len > 0) && (bit_index < 8)) { if (cur_byte & (1 << bit_index)) { mem_to_nc[tx_chan->mem_off++] = bytes_encoder->bit1; } else { mem_to_nc[tx_chan->mem_off++] = bytes_encoder->bit0; } len--; bit_index++; } if (bit_index >= 8) { byte_index++; bit_index = 0; } } if (channel->dma_chan) { // mark the end descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc1 = &tx_chan->dma_nodes_nc[0]; } else { desc1 = &tx_chan->dma_nodes_nc[1]; } // cross line, means desc0 has prepared with sufficient data buffer if (desc0 != desc1) { desc0->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc0->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } } if (encoding_truncated) { // this encoding has not finished yet, save the truncated position bytes_encoder->last_bit_index = bit_index; bytes_encoder->last_byte_index = byte_index; } else { // reset internal index if encoding session has finished bytes_encoder->last_bit_index = 0; bytes_encoder->last_byte_index = 0; state |= RMT_ENCODING_COMPLETE; } if (!encoding_space_free) { // no more free memory, the caller should yield state |= RMT_ENCODING_MEM_FULL; } // reset offset pointer when exceeds maximum range if (tx_chan->mem_off >= tx_chan->ping_pong_symbols * 2) { if (channel->dma_chan) { desc1->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc1->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } tx_chan->mem_off = 0; } *ret_state = state; return encode_len; } static esp_err_t rmt_copy_encoder_reset(rmt_encoder_t *encoder) { rmt_copy_encoder_t *copy_encoder = __containerof(encoder, rmt_copy_encoder_t, base); copy_encoder->last_symbol_index = 0; return ESP_OK; } static size_t IRAM_ATTR rmt_encode_copy(rmt_encoder_t *encoder, rmt_channel_handle_t channel, const void *primary_data, size_t data_size, rmt_encode_state_t *ret_state) { rmt_copy_encoder_t *copy_encoder = __containerof(encoder, rmt_copy_encoder_t, base); rmt_tx_channel_t *tx_chan = __containerof(channel, rmt_tx_channel_t, base); rmt_symbol_word_t *symbols = (rmt_symbol_word_t *)primary_data; rmt_encode_state_t state = RMT_ENCODING_RESET; rmt_dma_descriptor_t *desc0 = NULL; rmt_dma_descriptor_t *desc1 = NULL; size_t symbol_index = copy_encoder->last_symbol_index; // how many symbols will be copied by the encoder size_t mem_want = (data_size / 4 - symbol_index); // how many symbols we can save for this round size_t mem_have = tx_chan->mem_end - tx_chan->mem_off; // where to put the encoded symbols? DMA buffer or RMT HW memory rmt_symbol_word_t *mem_to_nc = NULL; if (channel->dma_chan) { mem_to_nc = tx_chan->dma_mem_base_nc; } else { mem_to_nc = channel->hw_mem_base; } // how many symbols will be encoded in this round size_t encode_len = MIN(mem_want, mem_have); bool encoding_truncated = mem_have < mem_want; bool encoding_space_free = mem_have > mem_want; if (channel->dma_chan) { // mark the start descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc0 = &tx_chan->dma_nodes_nc[0]; } else { desc0 = &tx_chan->dma_nodes_nc[1]; } } size_t len = encode_len; while (len > 0) { mem_to_nc[tx_chan->mem_off++] = symbols[symbol_index++]; len--; } if (channel->dma_chan) { // mark the end descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc1 = &tx_chan->dma_nodes_nc[0]; } else { desc1 = &tx_chan->dma_nodes_nc[1]; } // cross line, means desc0 has prepared with sufficient data buffer if (desc0 != desc1) { desc0->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc0->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } } if (encoding_truncated) { // this encoding has not finished yet, save the truncated position copy_encoder->last_symbol_index = symbol_index; } else { // reset internal index if encoding session has finished copy_encoder->last_symbol_index = 0; state |= RMT_ENCODING_COMPLETE; } if (!encoding_space_free) { // no more free memory, the caller should yield state |= RMT_ENCODING_MEM_FULL; } // reset offset pointer when exceeds maximum range if (tx_chan->mem_off >= tx_chan->ping_pong_symbols * 2) { if (channel->dma_chan) { desc1->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc1->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } tx_chan->mem_off = 0; } *ret_state = state; return encode_len; } static size_t IRAM_ATTR rmt_encode_simple(rmt_encoder_t *encoder, rmt_channel_handle_t channel, const void *data, size_t data_size, rmt_encode_state_t *ret_state) { rmt_simple_encoder_t *simple_encoder = __containerof(encoder, rmt_simple_encoder_t, base); rmt_tx_channel_t *tx_chan = __containerof(channel, rmt_tx_channel_t, base); rmt_encode_state_t state = RMT_ENCODING_RESET; rmt_dma_descriptor_t *desc0 = NULL; rmt_dma_descriptor_t *desc1 = NULL; // where to put the encoded symbols? DMA buffer or RMT HW memory rmt_symbol_word_t *mem_to_nc = NULL; if (channel->dma_chan) { mem_to_nc = tx_chan->dma_mem_base_nc; } else { mem_to_nc = channel->hw_mem_base; } if (channel->dma_chan) { // mark the start descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc0 = &tx_chan->dma_nodes_nc[0]; } else { desc0 = &tx_chan->dma_nodes_nc[1]; } } // While we're not done, we need to use the callback to fill the RMT memory until it is // exactly entirely full. We cannot do that if the RMT memory still has N free spaces // but the encoder callback needs more than N spaces to properly encode a symbol. // In order to work around that, if we detect that situation we let the encoder // encode into an overflow buffer, then we use the contents of that buffer to fill // those last N spaces. On the next call, we will first output the rest of the // overflow buffer before again using the callback to continue filling the RMT // buffer. // Note the next code is in a while loop to properly handle 'unsure' callbacks that // e.g. return 0 with a free buffer size of M, but then return less than M symbols // when then called with a larger buffer. size_t encode_len = 0; //total amount of symbols written to rmt memory bool is_done = false; while (tx_chan->mem_off < tx_chan->mem_end) { if (simple_encoder->ovf_buf_parsed_pos < simple_encoder->ovf_buf_fill_len) { // Overflow buffer has data from the previous encoding call. Copy one entry // from that. mem_to_nc[tx_chan->mem_off++] = simple_encoder->ovf_buf[simple_encoder->ovf_buf_parsed_pos++]; encode_len++; } else { // Overflow buffer is empty, so we don't need to empty that first. if (simple_encoder->callback_done) { // We cannot call the callback anymore and the overflow buffer // is empty, so we're done with the transaction. is_done = true; break; } // Try to have the callback write the data directly into RMT memory. size_t enc_size = simple_encoder->callback(data, data_size, simple_encoder->last_symbol_index, tx_chan->mem_end - tx_chan->mem_off, &mem_to_nc[tx_chan->mem_off], &is_done, simple_encoder->arg); encode_len += enc_size; tx_chan->mem_off += enc_size; simple_encoder->last_symbol_index += enc_size; if (is_done) { break; // we're done, no more data to write to RMT memory. } if (enc_size == 0) { // The encoder does not have enough space in RMT memory to encode its thing, // but the RMT memory is not filled out entirely. Encode into the overflow // buffer so the next iterations of the loop can fill out the RMT buffer // from that. enc_size = simple_encoder->callback(data, data_size, simple_encoder->last_symbol_index, simple_encoder->ovf_buf_size, simple_encoder->ovf_buf, &is_done, simple_encoder->arg); simple_encoder->last_symbol_index += enc_size; //Note we do *not* update encode_len here as the data isn't going to the RMT yet. simple_encoder->ovf_buf_fill_len = enc_size; simple_encoder->ovf_buf_parsed_pos = 0; if (is_done) { // If the encoder is done, we cannot call the callback anymore, but we still // need to handle any data in the overflow buffer. simple_encoder->callback_done = true; } else { if (enc_size == 0) { //According to the callback docs, this is illegal. //Report this. EARLY_LOGE as we're running from an ISR. ESP_EARLY_LOGE(TAG, "rmt_encoder_simple: encoder callback returned 0 when fed a buffer of config::min_chunk_size!"); //Then abort the transaction. is_done = true; break; } } } } } if (channel->dma_chan) { // mark the end descriptor if (tx_chan->mem_off < tx_chan->ping_pong_symbols) { desc1 = &tx_chan->dma_nodes_nc[0]; } else { desc1 = &tx_chan->dma_nodes_nc[1]; } // cross line, means desc0 has prepared with sufficient data buffer if (desc0 != desc1) { desc0->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc0->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } } if (is_done) { // reset internal index if encoding session has finished simple_encoder->last_symbol_index = 0; state |= RMT_ENCODING_COMPLETE; } else { // no more free memory, the caller should yield state |= RMT_ENCODING_MEM_FULL; } // reset offset pointer when exceeds maximum range if (tx_chan->mem_off >= tx_chan->ping_pong_symbols * 2) { if (channel->dma_chan) { desc1->dw0.length = tx_chan->ping_pong_symbols * sizeof(rmt_symbol_word_t); desc1->dw0.owner = DMA_DESCRIPTOR_BUFFER_OWNER_DMA; } tx_chan->mem_off = 0; } *ret_state = state; return encode_len; } static esp_err_t rmt_del_bytes_encoder(rmt_encoder_t *encoder) { rmt_bytes_encoder_t *bytes_encoder = __containerof(encoder, rmt_bytes_encoder_t, base); free(bytes_encoder); return ESP_OK; } static esp_err_t rmt_del_copy_encoder(rmt_encoder_t *encoder) { rmt_copy_encoder_t *copy_encoder = __containerof(encoder, rmt_copy_encoder_t, base); free(copy_encoder); return ESP_OK; } static esp_err_t rmt_simple_encoder_reset(rmt_encoder_t *encoder) { rmt_simple_encoder_t *simple_encoder = __containerof(encoder, rmt_simple_encoder_t, base); simple_encoder->last_symbol_index = 0; simple_encoder->ovf_buf_fill_len = 0; simple_encoder->ovf_buf_parsed_pos = 0; simple_encoder->callback_done = false; return ESP_OK; } static esp_err_t rmt_del_simple_encoder(rmt_encoder_t *encoder) { rmt_simple_encoder_t *simple_encoder = __containerof(encoder, rmt_simple_encoder_t, base); if (simple_encoder->ovf_buf) { free(simple_encoder->ovf_buf); } free(simple_encoder); return ESP_OK; } esp_err_t rmt_new_bytes_encoder(const rmt_bytes_encoder_config_t *config, rmt_encoder_handle_t *ret_encoder) { esp_err_t ret = ESP_OK; ESP_GOTO_ON_FALSE(config && ret_encoder, ESP_ERR_INVALID_ARG, err, TAG, "invalid argument"); rmt_bytes_encoder_t *encoder = rmt_alloc_encoder_mem(sizeof(rmt_bytes_encoder_t)); ESP_GOTO_ON_FALSE(encoder, ESP_ERR_NO_MEM, err, TAG, "no mem for bytes encoder"); encoder->base.encode = rmt_encode_bytes; encoder->base.del = rmt_del_bytes_encoder; encoder->base.reset = rmt_bytes_encoder_reset; encoder->bit0 = config->bit0; encoder->bit1 = config->bit1; encoder->flags.msb_first = config->flags.msb_first; // return general encoder handle *ret_encoder = &encoder->base; ESP_LOGD(TAG, "new bytes encoder @%p", encoder); err: return ret; } esp_err_t rmt_bytes_encoder_update_config(rmt_encoder_handle_t bytes_encoder, const rmt_bytes_encoder_config_t *config) { ESP_RETURN_ON_FALSE(bytes_encoder && config, ESP_ERR_INVALID_ARG, TAG, "invalid argument"); rmt_bytes_encoder_t *encoder = __containerof(bytes_encoder, rmt_bytes_encoder_t, base); encoder->bit0 = config->bit0; encoder->bit1 = config->bit1; encoder->flags.msb_first = config->flags.msb_first; return ESP_OK; } esp_err_t rmt_new_copy_encoder(const rmt_copy_encoder_config_t *config, rmt_encoder_handle_t *ret_encoder) { esp_err_t ret = ESP_OK; ESP_GOTO_ON_FALSE(config && ret_encoder, ESP_ERR_INVALID_ARG, err, TAG, "invalid argument"); rmt_copy_encoder_t *encoder = rmt_alloc_encoder_mem(sizeof(rmt_copy_encoder_t)); ESP_GOTO_ON_FALSE(encoder, ESP_ERR_NO_MEM, err, TAG, "no mem for copy encoder"); encoder->base.encode = rmt_encode_copy; encoder->base.del = rmt_del_copy_encoder; encoder->base.reset = rmt_copy_encoder_reset; // return general encoder handle *ret_encoder = &encoder->base; ESP_LOGD(TAG, "new copy encoder @%p", encoder); err: return ret; } esp_err_t rmt_new_simple_encoder(const rmt_simple_encoder_config_t *config, rmt_encoder_handle_t *ret_encoder) { esp_err_t ret = ESP_OK; rmt_simple_encoder_t *encoder = NULL; ESP_GOTO_ON_FALSE(config && ret_encoder, ESP_ERR_INVALID_ARG, err, TAG, "invalid argument"); encoder = rmt_alloc_encoder_mem(sizeof(rmt_simple_encoder_t)); ESP_GOTO_ON_FALSE(encoder, ESP_ERR_NO_MEM, err, TAG, "no mem for simple encoder"); encoder->base.encode = rmt_encode_simple; encoder->base.del = rmt_del_simple_encoder; encoder->base.reset = rmt_simple_encoder_reset; encoder->callback = config->callback; encoder->arg = config->arg; size_t min_chunk_size = config->min_chunk_size; if (min_chunk_size == 0) { min_chunk_size = 64; } encoder->ovf_buf = rmt_alloc_encoder_mem(min_chunk_size * sizeof(rmt_symbol_word_t)); ESP_GOTO_ON_FALSE(encoder->ovf_buf, ESP_ERR_NO_MEM, err, TAG, "no mem for simple encoder overflow buffer"); encoder->ovf_buf_size = min_chunk_size; encoder->ovf_buf_fill_len = 0; encoder->ovf_buf_parsed_pos = 0; // return general encoder handle *ret_encoder = &encoder->base; ESP_LOGD(TAG, "new simple encoder @%p", encoder); return ret; err: if (encoder) { free(encoder); } return ret; } esp_err_t rmt_del_encoder(rmt_encoder_handle_t encoder) { ESP_RETURN_ON_FALSE(encoder, ESP_ERR_INVALID_ARG, TAG, "invalid argument"); return encoder->del(encoder); } esp_err_t rmt_encoder_reset(rmt_encoder_handle_t encoder) { ESP_RETURN_ON_FALSE(encoder, ESP_ERR_INVALID_ARG, TAG, "invalid argument"); return encoder->reset(encoder); } void *rmt_alloc_encoder_mem(size_t size) { return heap_caps_calloc(1, size, RMT_MEM_ALLOC_CAPS); }