/* * SPDX-FileCopyrightText: 2021-2022 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include "sdkconfig.h" #if CONFIG_LCD_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_lcd_panel_io_interface.h" #include "esp_lcd_panel_io.h" #include "hal/spi_ll.h" #include "driver/spi_master.h" #include "driver/gpio.h" #include "esp_log.h" #include "esp_check.h" #include "esp_lcd_common.h" #define LCD_SPI_MAX_DATA_SIZE (SPI_LL_DATA_MAX_BIT_LEN / 8) static const char *TAG = "lcd_panel.io.spi"; static esp_err_t panel_io_spi_tx_param(esp_lcd_panel_io_t *io, int lcd_cmd, const void *param, size_t param_size); static esp_err_t panel_io_spi_tx_color(esp_lcd_panel_io_t *io, int lcd_cmd, const void *color, size_t color_size); static esp_err_t panel_io_spi_del(esp_lcd_panel_io_t *io); static void lcd_spi_pre_trans_cb(spi_transaction_t *trans); static void lcd_spi_post_trans_color_cb(spi_transaction_t *trans); typedef struct { spi_transaction_t base; struct { unsigned int dc_gpio_level: 1; unsigned int en_trans_done_cb: 1; } flags; } lcd_spi_trans_descriptor_t; typedef struct { esp_lcd_panel_io_t base; // Base class of generic lcd panel io spi_device_handle_t spi_dev; // SPI device handle int dc_gpio_num; // D/C line GPIO number esp_lcd_panel_io_color_trans_done_cb_t on_color_trans_done; // User register's callback, invoked when color data trans done void *user_ctx; // User's private data, passed directly to callback on_color_trans_done size_t queue_size; // Size of transaction queue size_t num_trans_inflight; // Number of transactions that are undergoing (the descriptor not recycled yet) int lcd_cmd_bits; // Bit width of LCD command int lcd_param_bits; // Bit width of LCD parameter struct { unsigned int dc_as_cmd_phase: 1; // D/C line value is encoded into SPI transaction command phase unsigned int dc_data_level: 1; // Indicates the level of DC line when tranfering data unsigned int octal_mode: 1; // Indicates whether the transmitting is enabled with octal mode (8 data lines) } flags; lcd_spi_trans_descriptor_t trans_pool[]; // Transaction pool } esp_lcd_panel_io_spi_t; esp_err_t esp_lcd_new_panel_io_spi(esp_lcd_spi_bus_handle_t bus, const esp_lcd_panel_io_spi_config_t *io_config, esp_lcd_panel_io_handle_t *ret_io) { #if CONFIG_LCD_ENABLE_DEBUG_LOG esp_log_level_set(TAG, ESP_LOG_DEBUG); #endif esp_err_t ret = ESP_OK; esp_lcd_panel_io_spi_t *spi_panel_io = NULL; ESP_GOTO_ON_FALSE(bus && io_config && ret_io, ESP_ERR_INVALID_ARG, err, TAG, "invalid argument"); ESP_GOTO_ON_FALSE(!(io_config->flags.dc_as_cmd_phase && io_config->dc_gpio_num >= 0), ESP_ERR_INVALID_ARG, err, TAG, "invalid DC mode"); spi_panel_io = calloc(1, sizeof(esp_lcd_panel_io_spi_t) + sizeof(lcd_spi_trans_descriptor_t) * io_config->trans_queue_depth); ESP_GOTO_ON_FALSE(spi_panel_io, ESP_ERR_NO_MEM, err, TAG, "no mem for spi panel io"); spi_device_interface_config_t devcfg = { .flags = SPI_DEVICE_HALFDUPLEX, // only use TX path, so half duplex is enough .clock_speed_hz = io_config->pclk_hz, .mode = io_config->spi_mode, .spics_io_num = io_config->cs_gpio_num, .queue_size = io_config->trans_queue_depth, .command_bits = io_config->flags.dc_as_cmd_phase ? 1 : 0, // whether to encode DC line into command transaction .pre_cb = lcd_spi_pre_trans_cb, // pre-transaction callback, mainly control DC gpio level .post_cb = io_config->on_color_trans_done ? lcd_spi_post_trans_color_cb : NULL, // post-transaction, where we invoke user registered "on_color_trans_done()" }; ret = spi_bus_add_device((spi_host_device_t)bus, &devcfg, &spi_panel_io->spi_dev); ESP_GOTO_ON_ERROR(ret, err, TAG, "adding spi device to bus failed"); // if the DC line is not encoded into any spi transaction phase or it's not controlled by SPI peripheral if (io_config->dc_gpio_num >= 0) { gpio_config_t io_conf = { .mode = GPIO_MODE_OUTPUT, .pin_bit_mask = 1ULL << io_config->dc_gpio_num, }; ESP_GOTO_ON_ERROR(gpio_config(&io_conf), err, TAG, "configure GPIO for D/C line failed"); } spi_panel_io->flags.dc_as_cmd_phase = io_config->flags.dc_as_cmd_phase; spi_panel_io->flags.dc_data_level = !io_config->flags.dc_low_on_data; spi_panel_io->flags.octal_mode = io_config->flags.octal_mode; spi_panel_io->on_color_trans_done = io_config->on_color_trans_done; spi_panel_io->user_ctx = io_config->user_ctx; spi_panel_io->lcd_cmd_bits = io_config->lcd_cmd_bits; spi_panel_io->lcd_param_bits = io_config->lcd_param_bits; spi_panel_io->dc_gpio_num = io_config->dc_gpio_num; spi_panel_io->queue_size = io_config->trans_queue_depth; spi_panel_io->base.tx_param = panel_io_spi_tx_param; spi_panel_io->base.tx_color = panel_io_spi_tx_color; spi_panel_io->base.del = panel_io_spi_del; *ret_io = &(spi_panel_io->base); ESP_LOGD(TAG, "new spi lcd panel io @%p", spi_panel_io); return ESP_OK; err: if (spi_panel_io) { if (io_config->dc_gpio_num >= 0) { gpio_reset_pin(io_config->dc_gpio_num); } free(spi_panel_io); } return ret; } static esp_err_t panel_io_spi_del(esp_lcd_panel_io_t *io) { esp_err_t ret = ESP_OK; spi_transaction_t *spi_trans = NULL; esp_lcd_panel_io_spi_t *spi_panel_io = __containerof(io, esp_lcd_panel_io_spi_t, base); // wait all pending transaction to finish size_t num_trans_inflight = spi_panel_io->num_trans_inflight; for (size_t i = 0; i < num_trans_inflight; i++) { ret = spi_device_get_trans_result(spi_panel_io->spi_dev, &spi_trans, portMAX_DELAY); ESP_GOTO_ON_ERROR(ret, err, TAG, "recycle spi transactions failed"); spi_panel_io->num_trans_inflight--; } spi_bus_remove_device(spi_panel_io->spi_dev); if (spi_panel_io->dc_gpio_num >= 0) { gpio_reset_pin(spi_panel_io->dc_gpio_num); } ESP_LOGD(TAG, "del lcd panel io spi @%p", spi_panel_io); free(spi_panel_io); err: return ret; } static void spi_lcd_prepare_cmd_buffer(esp_lcd_panel_io_spi_t *panel_io, const void *cmd) { uint8_t *from = (uint8_t *)cmd; // LCD is big-endian, e.g. to send command 0x1234, byte 0x12 should appear on the bus first // However, the SPI peripheral will send 0x34 first, so we reversed the order below if (panel_io->lcd_cmd_bits > 8) { int start = 0; int end = panel_io->lcd_cmd_bits / 8 - 1; lcd_com_reverse_buffer_bytes(from, start, end); } } static void spi_lcd_prepare_param_buffer(esp_lcd_panel_io_spi_t *panel_io, const void *param, size_t param_size) { uint8_t *from = (uint8_t *)param; int param_width = panel_io->lcd_param_bits / 8; size_t param_num = param_size / param_width; // LCD is big-endian, e.g. to send command 0x1234, byte 0x12 should appear on the bus first // However, the SPI peripheral will send 0x34 first, so we reversed the order below if (panel_io->lcd_param_bits > 8) { for (size_t i = 0; i < param_num; i++) { int start = i * param_width; int end = start + param_width - 1; lcd_com_reverse_buffer_bytes(from, start, end); } } } static esp_err_t panel_io_spi_tx_param(esp_lcd_panel_io_t *io, int lcd_cmd, const void *param, size_t param_size) { esp_err_t ret = ESP_OK; spi_transaction_t *spi_trans = NULL; lcd_spi_trans_descriptor_t *lcd_trans = NULL; esp_lcd_panel_io_spi_t *spi_panel_io = __containerof(io, esp_lcd_panel_io_spi_t, base); // before issue a polling transaction, need to wait queued transactions finished size_t num_trans_inflight = spi_panel_io->num_trans_inflight; for (size_t i = 0; i < num_trans_inflight; i++) { ret = spi_device_get_trans_result(spi_panel_io->spi_dev, &spi_trans, portMAX_DELAY); ESP_GOTO_ON_ERROR(ret, err, TAG, "recycle spi transactions failed"); spi_panel_io->num_trans_inflight--; } lcd_trans = &spi_panel_io->trans_pool[0]; memset(lcd_trans, 0, sizeof(lcd_spi_trans_descriptor_t)); spi_lcd_prepare_cmd_buffer(spi_panel_io, &lcd_cmd); lcd_trans->base.user = spi_panel_io; lcd_trans->flags.dc_gpio_level = !spi_panel_io->flags.dc_data_level; // set D/C line to command mode lcd_trans->base.length = spi_panel_io->lcd_cmd_bits; lcd_trans->base.tx_buffer = &lcd_cmd; if (spi_panel_io->flags.octal_mode) { // use 8 lines for transmitting command, address and data lcd_trans->base.flags |= (SPI_TRANS_MULTILINE_CMD | SPI_TRANS_MULTILINE_ADDR | SPI_TRANS_MODE_OCT); } if (spi_panel_io->flags.dc_as_cmd_phase) { // encoding DC value to SPI command phase when necessary lcd_trans->base.cmd = !spi_panel_io->flags.dc_data_level; } // command is short, using polling mode ret = spi_device_polling_transmit(spi_panel_io->spi_dev, &lcd_trans->base); ESP_GOTO_ON_ERROR(ret, err, TAG, "spi transmit (polling) command failed"); if (param && param_size) { spi_lcd_prepare_param_buffer(spi_panel_io, param, param_size); lcd_trans->flags.dc_gpio_level = spi_panel_io->flags.dc_data_level; // set D/C line to data mode lcd_trans->base.length = param_size * 8; // transaction length is in bits lcd_trans->base.tx_buffer = param; if (spi_panel_io->flags.dc_as_cmd_phase) { // encoding DC value to SPI command phase when necessary lcd_trans->base.cmd = spi_panel_io->flags.dc_data_level; } // parameter is usually short, using polling mode ret = spi_device_polling_transmit(spi_panel_io->spi_dev, &lcd_trans->base); ESP_GOTO_ON_ERROR(ret, err, TAG, "spi transmit (polling) param failed"); } err: return ret; } static esp_err_t panel_io_spi_tx_color(esp_lcd_panel_io_t *io, int lcd_cmd, const void *color, size_t color_size) { esp_err_t ret = ESP_OK; spi_transaction_t *spi_trans = NULL; lcd_spi_trans_descriptor_t *lcd_trans = NULL; esp_lcd_panel_io_spi_t *spi_panel_io = __containerof(io, esp_lcd_panel_io_spi_t, base); // before issue a polling transaction, need to wait queued transactions finished size_t num_trans_inflight = spi_panel_io->num_trans_inflight; for (size_t i = 0; i < num_trans_inflight; i++) { ret = spi_device_get_trans_result(spi_panel_io->spi_dev, &spi_trans, portMAX_DELAY); ESP_GOTO_ON_ERROR(ret, err, TAG, "recycle spi transactions failed"); spi_panel_io->num_trans_inflight--; } lcd_trans = &spi_panel_io->trans_pool[0]; memset(lcd_trans, 0, sizeof(lcd_spi_trans_descriptor_t)); spi_lcd_prepare_cmd_buffer(spi_panel_io, &lcd_cmd); lcd_trans->base.user = spi_panel_io; lcd_trans->flags.dc_gpio_level = !spi_panel_io->flags.dc_data_level; // set D/C line to command mode lcd_trans->base.length = spi_panel_io->lcd_cmd_bits; lcd_trans->base.tx_buffer = &lcd_cmd; if (spi_panel_io->flags.dc_as_cmd_phase) { // encoding DC value to SPI command phase when necessary lcd_trans->base.cmd = !spi_panel_io->flags.dc_data_level; } if (spi_panel_io->flags.octal_mode) { // use 8 lines for transmitting command, address and data lcd_trans->base.flags |= (SPI_TRANS_MULTILINE_CMD | SPI_TRANS_MULTILINE_ADDR | SPI_TRANS_MODE_OCT); } // command is short, using polling mode ret = spi_device_polling_transmit(spi_panel_io->spi_dev, &lcd_trans->base); ESP_GOTO_ON_ERROR(ret, err, TAG, "spi transmit (polling) command failed"); // split to chunks if required: // the SPI bus has a maximum transaction size determined by SPI_USR_MOSI_DBITLEN's bit width do { size_t chunk_size = color_size; if (spi_panel_io->num_trans_inflight < spi_panel_io->queue_size) { // get the next available transaction lcd_trans = &spi_panel_io->trans_pool[spi_panel_io->num_trans_inflight]; } else { // transaction pool has used up, recycle one transaction ret = spi_device_get_trans_result(spi_panel_io->spi_dev, &spi_trans, portMAX_DELAY); ESP_GOTO_ON_ERROR(ret, err, TAG, "recycle spi transactions failed"); lcd_trans = __containerof(spi_trans, lcd_spi_trans_descriptor_t, base); spi_panel_io->num_trans_inflight--; } memset(lcd_trans, 0, sizeof(lcd_spi_trans_descriptor_t)); // SPI per-transfer size has its limitation, if the color buffer is too big, we need to split it into multiple trunks if (chunk_size > LCD_SPI_MAX_DATA_SIZE) { // cap the transfer size to the maximum supported by the bus chunk_size = LCD_SPI_MAX_DATA_SIZE; } else { // mark en_trans_done_cb only at the last round to avoid premature completion callback lcd_trans->flags.en_trans_done_cb = 1; } lcd_trans->base.user = spi_panel_io; lcd_trans->flags.dc_gpio_level = spi_panel_io->flags.dc_data_level; // set D/C line to data mode lcd_trans->base.length = chunk_size * 8; // transaction length is in bits lcd_trans->base.tx_buffer = color; if (spi_panel_io->flags.dc_as_cmd_phase) { // encoding DC value to SPI command phase when necessary lcd_trans->base.cmd = spi_panel_io->flags.dc_data_level; } if (spi_panel_io->flags.octal_mode) { // use 8 lines for transmitting command, address and data lcd_trans->base.flags |= (SPI_TRANS_MULTILINE_CMD | SPI_TRANS_MULTILINE_ADDR | SPI_TRANS_MODE_OCT); } // color data is usually large, using queue+blocking mode ret = spi_device_queue_trans(spi_panel_io->spi_dev, &lcd_trans->base, portMAX_DELAY); ESP_GOTO_ON_ERROR(ret, err, TAG, "spi transmit (queue) color failed"); spi_panel_io->num_trans_inflight++; // move on to the next chunk color = (const uint8_t *)color + chunk_size; color_size -= chunk_size; } while (color_size > 0); // continue while we have remaining data to transmit err: return ret; } static void lcd_spi_pre_trans_cb(spi_transaction_t *trans) { esp_lcd_panel_io_spi_t *spi_panel_io = trans->user; lcd_spi_trans_descriptor_t *lcd_trans = __containerof(trans, lcd_spi_trans_descriptor_t, base); if (spi_panel_io->dc_gpio_num >= 0) { // set D/C line level if necessary gpio_set_level(spi_panel_io->dc_gpio_num, lcd_trans->flags.dc_gpio_level); } } static void lcd_spi_post_trans_color_cb(spi_transaction_t *trans) { esp_lcd_panel_io_spi_t *spi_panel_io = trans->user; lcd_spi_trans_descriptor_t *lcd_trans = __containerof(trans, lcd_spi_trans_descriptor_t, base); if (lcd_trans->flags.en_trans_done_cb) { if (spi_panel_io->on_color_trans_done) { spi_panel_io->on_color_trans_done(&spi_panel_io->base, NULL, spi_panel_io->user_ctx); } } }