circuitpython/ports/espressif/cam.c

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// Copyright 2019 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <stdio.h>
#include <string.h>
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "driver/i2s.h"
#include "esp_system.h"
#include "esp_log.h"
#include "soc/i2s_struct.h"
#include "soc/apb_ctrl_reg.h"
#include "esp32s2/rom/lldesc.h"
#include "esp32s2/rom/cache.h"
#include "soc/dport_access.h"
#include "soc/dport_reg.h"
#include "driver/ledc.h"
#include "cam.h"
#include "hal/gpio_ll.h"
static const char *TAG = "cam";
#define CAM_DMA_MAX_SIZE (4095)
typedef enum {
CAM_IN_SUC_EOF_EVENT = 0,
CAM_VSYNC_EVENT
} cam_event_t;
typedef struct {
uint8_t *frame_buffer;
size_t len;
} frame_buffer_event_t;
typedef struct {
uint32_t buffer_size;
uint32_t half_buffer_size;
uint32_t node_cnt;
uint32_t half_node_cnt;
uint32_t dma_size;
uint32_t cnt;
uint32_t total_cnt;
lldesc_t *dma;
uint8_t *buffer;
uint8_t *frame1_buffer;
uint8_t *frame2_buffer;
uint8_t frame1_buffer_en;
uint8_t frame2_buffer_en;
uint8_t jpeg_mode;
uint8_t vsync_pin;
uint8_t vsync_invert;
uint8_t hsync_invert;
QueueHandle_t event_queue;
QueueHandle_t frame_buffer_queue;
TaskHandle_t task_handle;
intr_handle_t intr_handle;
} cam_obj_t;
static cam_obj_t *cam_obj = NULL;
void IRAM_ATTR cam_isr(void *arg) {
cam_event_t cam_event = {0};
BaseType_t HPTaskAwoken = pdFALSE;
typeof(I2S0.int_st) int_st = I2S0.int_st;
I2S0.int_clr.val = int_st.val;
if (int_st.in_suc_eof) {
cam_event = CAM_IN_SUC_EOF_EVENT;
xQueueSendFromISR(cam_obj->event_queue, (void *)&cam_event, &HPTaskAwoken);
}
if (HPTaskAwoken == pdTRUE) {
portYIELD_FROM_ISR();
}
}
void IRAM_ATTR cam_vsync_isr(void *arg) {
cam_event_t cam_event = {0};
BaseType_t HPTaskAwoken = pdFALSE;
/*!< filter */
ets_delay_us(1);
if (gpio_ll_get_level(&GPIO, cam_obj->vsync_pin) == !cam_obj->vsync_invert) {
cam_event = CAM_VSYNC_EVENT;
xQueueSendFromISR(cam_obj->event_queue, (void *)&cam_event, &HPTaskAwoken);
}
if (HPTaskAwoken == pdTRUE) {
portYIELD_FROM_ISR();
}
}
static void cam_config(const cam_config_t *config) {
/*!<Enable I2S periph */
periph_module_enable(PERIPH_I2S0_MODULE);
/*!< Configure the clock */
#if 0
I2S0.clkm_conf.val = 0;
I2S0.clkm_conf.clkm_div_num = 2; // <--- this should set the low 8 bits, but doesn't somehow
I2S0.clkm_conf.clkm_div_b = 0;
I2S0.clkm_conf.clkm_div_a = 0;
I2S0.clkm_conf.clk_sel = 2;
I2S0.clkm_conf.clk_en = 1;
#else
// The above code should set the clock to this value .. however, it sets it to 0x0050_0000 instead, the "clkm_div_num" value missing!
// it's not clear why this behavior arises
I2S0.clkm_conf.val = 0x00500002;
#endif
/*!< Configuration sampling rate */
I2S0.sample_rate_conf.val = 0;
I2S0.sample_rate_conf.tx_bck_div_num = 2;
I2S0.sample_rate_conf.tx_bits_mod = 8;
I2S0.sample_rate_conf.rx_bck_div_num = 1;
I2S0.sample_rate_conf.rx_bits_mod = config->bit_width;
/*!< Configuration data format */
I2S0.conf.val = 0;
I2S0.conf.tx_right_first = 1;
I2S0.conf.tx_msb_right = 1;
I2S0.conf.tx_dma_equal = 1;
I2S0.conf.rx_right_first = 1;
I2S0.conf.rx_msb_right = 1;
I2S0.conf.rx_dma_equal = 1;
I2S0.conf1.val = 0;
I2S0.conf1.tx_pcm_bypass = 1;
I2S0.conf1.tx_stop_en = 1;
I2S0.conf1.rx_pcm_bypass = 1;
I2S0.conf2.val = 0;
I2S0.conf2.cam_sync_fifo_reset = 1;
I2S0.conf2.cam_sync_fifo_reset = 0;
I2S0.conf2.lcd_en = 1;
I2S0.conf2.camera_en = 1;
I2S0.conf2.i_v_sync_filter_en = 1;
I2S0.conf2.i_v_sync_filter_thres = 1;
I2S0.conf_chan.val = 0;
I2S0.conf_chan.tx_chan_mod = 1;
I2S0.conf_chan.rx_chan_mod = 1;
I2S0.fifo_conf.val = 0;
I2S0.fifo_conf.rx_fifo_mod_force_en = 1;
I2S0.fifo_conf.rx_data_num = 32;
I2S0.fifo_conf.rx_fifo_mod = 2;
I2S0.fifo_conf.tx_fifo_mod_force_en = 1;
I2S0.fifo_conf.tx_data_num = 32;
I2S0.fifo_conf.tx_fifo_mod = 2;
I2S0.fifo_conf.dscr_en = 1;
I2S0.lc_conf.out_rst = 1;
I2S0.lc_conf.out_rst = 0;
I2S0.lc_conf.in_rst = 1;
I2S0.lc_conf.in_rst = 0;
I2S0.timing.val = 0;
I2S0.int_ena.val = 0;
I2S0.int_clr.val = ~0;
I2S0.lc_conf.check_owner = 0;
I2S0.conf.rx_start = 1;
}
static void cam_set_pin(const cam_config_t *config) {
gpio_config_t io_conf = {0};
io_conf.intr_type = config->vsync_invert ? GPIO_PIN_INTR_NEGEDGE : GPIO_PIN_INTR_POSEDGE;
io_conf.pin_bit_mask = 1 << config->pin.vsync;
io_conf.mode = GPIO_MODE_INPUT;
io_conf.pull_up_en = 1;
io_conf.pull_down_en = 0;
gpio_config(&io_conf);
gpio_install_isr_service(0);
gpio_isr_handler_add(config->pin.vsync, cam_vsync_isr, NULL);
gpio_intr_disable(config->pin.vsync);
PIN_FUNC_SELECT(GPIO_PIN_MUX_REG[config->pin.pclk], PIN_FUNC_GPIO);
gpio_set_direction(config->pin.pclk, GPIO_MODE_INPUT);
gpio_set_pull_mode(config->pin.pclk, GPIO_FLOATING);
gpio_matrix_in(config->pin.pclk, I2S0I_WS_IN_IDX, false);
PIN_FUNC_SELECT(GPIO_PIN_MUX_REG[config->pin.vsync], PIN_FUNC_GPIO);
gpio_set_direction(config->pin.vsync, GPIO_MODE_INPUT);
gpio_set_pull_mode(config->pin.vsync, GPIO_FLOATING);
gpio_matrix_in(config->pin.vsync, I2S0I_V_SYNC_IDX, config->vsync_invert);
PIN_FUNC_SELECT(GPIO_PIN_MUX_REG[config->pin.hsync], PIN_FUNC_GPIO);
gpio_set_direction(config->pin.hsync, GPIO_MODE_INPUT);
gpio_set_pull_mode(config->pin.hsync, GPIO_FLOATING);
gpio_matrix_in(config->pin.hsync, I2S0I_H_SYNC_IDX, config->hsync_invert);
for (int i = 0; i < config->bit_width; i++) {
PIN_FUNC_SELECT(GPIO_PIN_MUX_REG[config->pin_data[i]], PIN_FUNC_GPIO);
gpio_set_direction(config->pin_data[i], GPIO_MODE_INPUT);
gpio_set_pull_mode(config->pin_data[i], GPIO_FLOATING);
/*!< High position alignment, IN16 is always the highest bit */
/*!< Fifo accesses data by bit, and when rx_bits_mod is 8, the data needs to be aligned by 8 bits */
gpio_matrix_in(config->pin_data[i], I2S0I_DATA_IN0_IDX + (16 - config->bit_width) + i, false);
}
gpio_matrix_in(GPIO_FUNC_IN_HIGH, I2S0I_H_ENABLE_IDX, false);
ESP_LOGI(TAG, "cam_set_pin\n");
}
static void cam_vsync_intr_enable(uint8_t en) {
if (en) {
gpio_intr_enable(cam_obj->vsync_pin);
} else {
gpio_intr_disable(cam_obj->vsync_pin);
}
}
static void cam_dma_stop(void) {
if (I2S0.int_ena.in_suc_eof == 1) {
I2S0.conf.rx_start = 0;
I2S0.int_ena.in_suc_eof = 0;
I2S0.int_clr.in_suc_eof = 1;
I2S0.in_link.stop = 1;
}
}
static void cam_dma_start(void) {
if (I2S0.int_ena.in_suc_eof == 0) {
I2S0.int_clr.in_suc_eof = 1;
I2S0.int_ena.in_suc_eof = 1;
I2S0.conf.rx_reset = 1;
I2S0.conf.rx_reset = 0;
I2S0.conf.rx_fifo_reset = 1;
I2S0.conf.rx_fifo_reset = 0;
I2S0.lc_conf.in_rst = 1;
I2S0.lc_conf.in_rst = 0;
I2S0.lc_conf.ahbm_fifo_rst = 1;
I2S0.lc_conf.ahbm_fifo_rst = 0;
I2S0.lc_conf.ahbm_rst = 1;
I2S0.lc_conf.ahbm_rst = 0;
I2S0.in_link.start = 1;
I2S0.conf.rx_start = 1;
if (cam_obj->jpeg_mode) {
/*!< Manually give the vsync data for the first frame */
gpio_matrix_in(cam_obj->vsync_pin, I2S0I_V_SYNC_IDX, !cam_obj->vsync_invert);
gpio_matrix_in(cam_obj->vsync_pin, I2S0I_V_SYNC_IDX, cam_obj->vsync_invert);
}
}
}
void cam_stop(void) {
cam_vsync_intr_enable(0);
cam_dma_stop();
}
void cam_start(void) {
cam_vsync_intr_enable(1);
}
typedef enum {
CAM_STATE_IDLE = 0,
CAM_STATE_READ_BUF1 = 1,
CAM_STATE_READ_BUF2 = 2,
} cam_state_t;
/*!<Copy fram from DMA buffer to fram buffer */
static void cam_task(void *arg) {
int state = CAM_STATE_IDLE;
cam_event_t cam_event = {0};
frame_buffer_event_t frame_buffer_event = {0};
xQueueReset(cam_obj->event_queue);
while (1) {
xQueueReceive(cam_obj->event_queue, (void *)&cam_event, portMAX_DELAY);
switch (state) {
case CAM_STATE_IDLE: {
if (cam_event == CAM_VSYNC_EVENT) {
if (cam_obj->frame1_buffer_en) {
cam_dma_start();
cam_vsync_intr_enable(0);
state = CAM_STATE_READ_BUF1;
} else if (cam_obj->frame2_buffer_en) {
cam_dma_start();
cam_vsync_intr_enable(0);
state = CAM_STATE_READ_BUF2;
}
cam_obj->cnt = 0;
}
}
break;
case CAM_STATE_READ_BUF1: {
if (cam_event == CAM_IN_SUC_EOF_EVENT) {
if (cam_obj->cnt == 0) {
cam_vsync_intr_enable(1); /*!< CAM real start is required to receive the first buf data and then turn on the vsync interrupt */
}
memcpy(&cam_obj->frame1_buffer[cam_obj->cnt * cam_obj->half_buffer_size], &cam_obj->buffer[(cam_obj->cnt % 2) * cam_obj->half_buffer_size], cam_obj->half_buffer_size);
if (cam_obj->jpeg_mode) {
if (cam_obj->frame1_buffer_en == 0) {
cam_dma_stop();
}
} else {
if (cam_obj->cnt == cam_obj->total_cnt - 1) {
cam_obj->frame1_buffer_en = 0;
}
}
if (cam_obj->frame1_buffer_en == 0) {
frame_buffer_event.frame_buffer = cam_obj->frame1_buffer;
frame_buffer_event.len = (cam_obj->cnt + 1) * cam_obj->half_buffer_size;
xQueueSend(cam_obj->frame_buffer_queue, (void *)&frame_buffer_event, portMAX_DELAY);
state = CAM_STATE_IDLE;
} else {
cam_obj->cnt++;
}
} else if (cam_event == CAM_VSYNC_EVENT) {
if (cam_obj->jpeg_mode) {
cam_obj->frame1_buffer_en = 0;
}
}
}
break;
case CAM_STATE_READ_BUF2: {
if (cam_event == CAM_IN_SUC_EOF_EVENT) {
if (cam_obj->cnt == 0) {
cam_vsync_intr_enable(1); /*!< CAM real start is required to receive the first buf data and then turn on the vsync interrupt */
}
memcpy(&cam_obj->frame2_buffer[cam_obj->cnt * cam_obj->half_buffer_size], &cam_obj->buffer[(cam_obj->cnt % 2) * cam_obj->half_buffer_size], cam_obj->half_buffer_size);
if (cam_obj->jpeg_mode) {
if (cam_obj->frame2_buffer_en == 0) {
cam_dma_stop();
}
} else {
if (cam_obj->cnt == cam_obj->total_cnt - 1) {
cam_obj->frame2_buffer_en = 0;
}
}
if (cam_obj->frame2_buffer_en == 0) {
frame_buffer_event.frame_buffer = cam_obj->frame2_buffer;
frame_buffer_event.len = (cam_obj->cnt + 1) * cam_obj->half_buffer_size;
xQueueSend(cam_obj->frame_buffer_queue, (void *)&frame_buffer_event, portMAX_DELAY);
state = CAM_STATE_IDLE;
} else {
cam_obj->cnt++;
}
} else if (cam_event == CAM_VSYNC_EVENT) {
if (cam_obj->jpeg_mode) {
cam_obj->frame2_buffer_en = 0;
}
}
}
break;
}
}
}
size_t cam_take(uint8_t **buffer_p) {
frame_buffer_event_t frame_buffer_event;
xQueueReceive(cam_obj->frame_buffer_queue, (void *)&frame_buffer_event, portMAX_DELAY);
*buffer_p = frame_buffer_event.frame_buffer;
return frame_buffer_event.len;
}
bool cam_ready(void) {
frame_buffer_event_t frame_buffer_event;
BaseType_t result = xQueuePeek(cam_obj->frame_buffer_queue, (void *)&frame_buffer_event, 0);
return result != pdFALSE;
}
void cam_give(uint8_t *buffer) {
if (buffer == cam_obj->frame1_buffer) {
cam_obj->frame1_buffer_en = 1;
} else if (buffer == cam_obj->frame2_buffer) {
cam_obj->frame2_buffer_en = 1;
}
}
void cam_dma_config(const cam_config_t *config) {
int cnt = 0;
if (config->mode.jpeg) {
cam_obj->buffer_size = 2048;
cam_obj->half_buffer_size = cam_obj->buffer_size / 2;
cam_obj->dma_size = 1024;
} else {
for (cnt = 0;; cnt++) { /*!< Find the divisible buffer size */
if ((config->size * 2) % (config->max_buffer_size - cnt) == 0) {
break;
}
}
cam_obj->buffer_size = config->max_buffer_size - cnt;
cam_obj->half_buffer_size = cam_obj->buffer_size / 2;
for (cnt = 0;; cnt++) { /*!< Look for divisible dma sizes */
if ((cam_obj->half_buffer_size) % (CAM_DMA_MAX_SIZE - cnt) == 0) {
break;
}
}
cam_obj->dma_size = CAM_DMA_MAX_SIZE - cnt;
}
cam_obj->node_cnt = (cam_obj->buffer_size) / cam_obj->dma_size; /*!< Number of DMA nodes */
cam_obj->half_node_cnt = cam_obj->node_cnt / 2;
cam_obj->total_cnt = (config->size * 2) / cam_obj->half_buffer_size; /*!< Number of interrupt copies produced. Ping pong copies */
ESP_LOGI(TAG, "cam_buffer_size: %d, cam_dma_size: %d, cam_dma_node_cnt: %d, cam_total_cnt: %d\n", cam_obj->buffer_size, cam_obj->dma_size, cam_obj->node_cnt, cam_obj->total_cnt);
cam_obj->dma = (lldesc_t *)heap_caps_realloc(cam_obj->dma, cam_obj->node_cnt * sizeof(lldesc_t), MALLOC_CAP_DMA);
cam_obj->buffer = (uint8_t *)heap_caps_realloc(cam_obj->buffer, cam_obj->buffer_size * sizeof(uint8_t), MALLOC_CAP_DMA);
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for (uint32_t x = 0; x < cam_obj->node_cnt; x++) {
cam_obj->dma[x].size = cam_obj->dma_size;
cam_obj->dma[x].length = cam_obj->dma_size;
cam_obj->dma[x].eof = 0;
cam_obj->dma[x].owner = 1;
cam_obj->dma[x].buf = (cam_obj->buffer + cam_obj->dma_size * x);
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cam_obj->dma[x].empty = (intptr_t)&cam_obj->dma[(x + 1) % cam_obj->node_cnt];
}
I2S0.in_link.addr = ((uint32_t)&cam_obj->dma[0]) & 0xfffff;
I2S0.rx_eof_num = cam_obj->half_buffer_size; /*!< Ping-pong operation */
}
esp_err_t cam_deinit() {
if (!cam_obj) {
return ESP_FAIL;
}
cam_stop();
gpio_isr_handler_remove(cam_obj->vsync_pin);
esp_intr_free(cam_obj->intr_handle);
vTaskDelete(cam_obj->task_handle);
vQueueDelete(cam_obj->event_queue);
vQueueDelete(cam_obj->frame_buffer_queue);
free(cam_obj->dma);
free(cam_obj->buffer);
free(cam_obj);
cam_obj = NULL;
return ESP_OK;
}
esp_err_t cam_init(const cam_config_t *config) {
cam_obj = (cam_obj_t *)heap_caps_calloc(1, sizeof(cam_obj_t), MALLOC_CAP_DMA);
if (!cam_obj) {
ESP_LOGI(TAG, "camera object malloc error\n");
return ESP_FAIL;
}
cam_obj->frame1_buffer = config->frame1_buffer;
cam_obj->frame2_buffer = config->frame2_buffer;
cam_obj->jpeg_mode = config->mode.jpeg;
cam_obj->vsync_pin = config->pin.vsync;
cam_obj->vsync_invert = config->vsync_invert;
cam_obj->hsync_invert = config->hsync_invert;
cam_set_pin(config);
cam_config(config);
cam_dma_config(config);
cam_obj->event_queue = xQueueCreate(2, sizeof(cam_event_t));
cam_obj->frame_buffer_queue = xQueueCreate(2, sizeof(frame_buffer_event_t));
if (cam_obj->frame1_buffer != NULL) {
ESP_LOGI(TAG, "frame1_buffer_en\n");
cam_obj->frame1_buffer_en = 1;
} else {
cam_obj->frame1_buffer_en = 0;
}
if (cam_obj->frame2_buffer != NULL) {
ESP_LOGI(TAG, "frame2_buffer_en\n");
cam_obj->frame2_buffer_en = 1;
} else {
cam_obj->frame2_buffer_en = 0;
}
esp_intr_alloc(ETS_I2S0_INTR_SOURCE, 0, cam_isr, NULL, &cam_obj->intr_handle);
xTaskCreate(cam_task, "cam_task", config->task_stack, NULL, config->task_pri, &cam_obj->task_handle);
return ESP_OK;
}