// Copyright 2019-2020 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 #include #include #include #include "sdkconfig.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "freertos/semphr.h" #include "esp_system.h" #include "esp_intr_alloc.h" #include "esp_private/usb_console.h" #include "soc/periph_defs.h" #include "soc/rtc_cntl_reg.h" #include "soc/usb_struct.h" #include "soc/usb_reg.h" #include "soc/spinlock.h" #include "hal/soc_hal.h" #include "esp_rom_uart.h" #include "esp_rom_sys.h" #include "esp32s2/rom/usb/usb_dc.h" #include "esp32s2/rom/usb/cdc_acm.h" #include "esp32s2/rom/usb/usb_dfu.h" #include "esp32s2/rom/usb/usb_device.h" #include "esp32s2/rom/usb/usb_os_glue.h" #include "esp32s2/rom/usb/usb_persist.h" #include "esp32s2/rom/usb/chip_usb_dw_wrapper.h" #define CDC_WORK_BUF_SIZE (ESP_ROM_CDC_ACM_WORK_BUF_MIN + CONFIG_ESP_CONSOLE_USB_CDC_RX_BUF_SIZE) typedef enum { REBOOT_NONE, REBOOT_NORMAL, REBOOT_BOOTLOADER, REBOOT_BOOTLOADER_DFU, } reboot_type_t; static reboot_type_t s_queue_reboot = REBOOT_NONE; static int s_prev_rts_state; static intr_handle_t s_usb_int_handle; static cdc_acm_device *s_cdc_acm_device; static char s_usb_tx_buf[ACM_BYTES_PER_TX]; static size_t s_usb_tx_buf_pos; static uint8_t cdcmem[CDC_WORK_BUF_SIZE]; static esp_usb_console_cb_t s_rx_cb; static esp_usb_console_cb_t s_tx_cb; static void *s_cb_arg; #ifdef CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF static portMUX_TYPE s_write_lock = portMUX_INITIALIZER_UNLOCKED; void esp_usb_console_write_char(char c); #define ISR_FLAG ESP_INTR_FLAG_IRAM #else #define ISR_FLAG 0 #endif // CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF /* Optional write lock routines; used only if esp_rom_printf output via CDC is enabled */ static inline void write_lock_acquire(void); static inline void write_lock_release(void); /* The two functions below need to be revisited in the multicore case */ _Static_assert(SOC_CPU_CORES_NUM == 1, "usb_osglue_*_int is not multicore capable"); /* Called by ROM to disable the interrupts * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_osglue_dis_int(void) { if (s_usb_int_handle) { esp_intr_disable(s_usb_int_handle); } } /* Called by ROM to enable the interrupts * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_osglue_ena_int(void) { if (s_usb_int_handle) { esp_intr_enable(s_usb_int_handle); } } /* Delay function called by ROM USB driver. * Non-static to allow placement into IRAM by ldgen. */ int esp_usb_console_osglue_wait_proc(int delay_us) { if (xTaskGetSchedulerState() != taskSCHEDULER_RUNNING || !xPortCanYield()) { esp_rom_delay_us(delay_us); return delay_us; } if (delay_us == 0) { /* We should effectively yield */ vPortYield(); return 1; } else { /* Just delay */ int ticks = MAX(delay_us / (portTICK_PERIOD_MS * 1000), 1); vTaskDelay(ticks); return ticks * portTICK_PERIOD_MS * 1000; } } /* Called by ROM CDC ACM driver from interrupt context./ * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_cdc_acm_cb(cdc_acm_device *dev, int status) { if (status == USB_DC_RESET || status == USB_DC_CONNECTED) { s_prev_rts_state = 0; } else if (status == ACM_STATUS_LINESTATE_CHANGED) { uint32_t rts, dtr; cdc_acm_line_ctrl_get(dev, LINE_CTRL_RTS, &rts); cdc_acm_line_ctrl_get(dev, LINE_CTRL_DTR, &dtr); if (!rts && s_prev_rts_state) { if (dtr) { s_queue_reboot = REBOOT_BOOTLOADER; } else { s_queue_reboot = REBOOT_NORMAL; } } s_prev_rts_state = rts; } else if (status == ACM_STATUS_RX && s_rx_cb) { (*s_rx_cb)(s_cb_arg); } else if (status == ACM_STATUS_TX && s_tx_cb) { (*s_tx_cb)(s_cb_arg); } } /* Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_dfu_detach_cb(int timeout) { s_queue_reboot = REBOOT_BOOTLOADER_DFU; } /* USB interrupt handler, forward the call to the ROM driver. * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_interrupt(void *arg) { usb_dc_check_poll_for_interrupts(); /* Restart can be requested from esp_usb_console_cdc_acm_cb or esp_usb_console_dfu_detach_cb */ if (s_queue_reboot != REBOOT_NONE) { esp_restart(); } } /* Call the USB interrupt handler while any interrupts are pending, * but not more than a few times. * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_poll_interrupts(void) { const int max_poll_count = 10; for (int i = 0; (USB0.gintsts & USB0.gintmsk) != 0 && i < max_poll_count; i++) { usb_dc_check_poll_for_interrupts(); } } /* This function gets registered as a restart handler. * Prepares USB peripheral for restart and sets up persistence. * Non-static to allow placement into IRAM by ldgen. */ void esp_usb_console_before_restart(void) { esp_usb_console_poll_interrupts(); usb_dc_prepare_persist(); if (s_queue_reboot == REBOOT_BOOTLOADER) { chip_usb_set_persist_flags(USBDC_PERSIST_ENA); REG_WRITE(RTC_CNTL_OPTION1_REG, RTC_CNTL_FORCE_DOWNLOAD_BOOT); } else if (s_queue_reboot == REBOOT_BOOTLOADER_DFU) { chip_usb_set_persist_flags(USBDC_BOOT_DFU); REG_WRITE(RTC_CNTL_OPTION1_REG, RTC_CNTL_FORCE_DOWNLOAD_BOOT); } else { chip_usb_set_persist_flags(USBDC_PERSIST_ENA); esp_usb_console_poll_interrupts(); } } /* Reset some static state in ROM, which survives when going from the * 2nd stage bootloader into the app. This cleans some variables which * indicates that the driver is already initialized, allowing us to * initialize it again, in the app. */ static void esp_usb_console_rom_cleanup(void) { extern char rom_usb_dev, rom_usb_dev_end; extern char rom_usb_dw_ctrl, rom_usb_dw_ctrl_end; uart_acm_dev = NULL; memset((void *) &rom_usb_dev, 0, &rom_usb_dev_end - &rom_usb_dev); memset((void *) &rom_usb_dw_ctrl, 0, &rom_usb_dw_ctrl_end - &rom_usb_dw_ctrl); } esp_err_t esp_usb_console_init(void) { esp_err_t err; err = esp_register_shutdown_handler(esp_usb_console_before_restart); if (err != ESP_OK) { return err; } esp_usb_console_rom_cleanup(); /* Install OS hooks */ rom_usb_osglue.int_dis_proc = esp_usb_console_osglue_dis_int; rom_usb_osglue.int_ena_proc = esp_usb_console_osglue_ena_int; rom_usb_osglue.wait_proc = esp_usb_console_osglue_wait_proc; /* Install interrupt. * In case of ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF: * Note that this the interrupt handler has to be placed into IRAM because * the interrupt handler can also be called in polling mode, when * interrupts are disabled, and a write to USB is performed with cache disabled. * Since the handler function is in IRAM, we can register the interrupt as IRAM capable. * It is not because we actually need the interrupt to work with cache disabled! */ err = esp_intr_alloc(ETS_USB_INTR_SOURCE, ISR_FLAG | ESP_INTR_FLAG_INTRDISABLED, esp_usb_console_interrupt, NULL, &s_usb_int_handle); if (err != ESP_OK) { esp_unregister_shutdown_handler(esp_usb_console_before_restart); return err; } /* Initialize USB / CDC */ s_cdc_acm_device = cdc_acm_init(cdcmem, CDC_WORK_BUF_SIZE); usb_dc_check_poll_for_interrupts(); /* Set callback for handling DTR/RTS lines and TX/RX events */ cdc_acm_irq_callback_set(s_cdc_acm_device, esp_usb_console_cdc_acm_cb); cdc_acm_irq_state_enable(s_cdc_acm_device); /* Set callback for handling DFU detach */ usb_dfu_set_detach_cb(esp_usb_console_dfu_detach_cb); /* Enable interrupts on USB peripheral side */ USB0.gahbcfg |= USB_GLBLLNTRMSK_M; /* Enable the interrupt handler */ esp_intr_enable(s_usb_int_handle); #ifdef CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF /* Install esp_rom_printf handler */ ets_install_putc1(&esp_usb_console_write_char); #endif // CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF return ESP_OK; } /* Non-static to allow placement into IRAM by ldgen. * Must be called with the write lock held. */ ssize_t esp_usb_console_flush_internal(size_t last_write_size) { if (s_usb_tx_buf_pos == 0) { return 0; } assert(s_usb_tx_buf_pos >= last_write_size); ssize_t ret; size_t tx_buf_pos_before = s_usb_tx_buf_pos - last_write_size; int sent = cdc_acm_fifo_fill(s_cdc_acm_device, (const uint8_t*) s_usb_tx_buf, s_usb_tx_buf_pos); if (sent == last_write_size) { /* everything was sent */ ret = last_write_size; s_usb_tx_buf_pos = 0; } else if (sent == 0) { /* nothing was sent, roll back to the original state */ ret = 0; s_usb_tx_buf_pos = tx_buf_pos_before; } else { /* Some data was sent, but not all of the buffer. * We can still tell the caller that all the new data * was "sent" since it is in the buffer now. */ ret = last_write_size; memmove(s_usb_tx_buf, s_usb_tx_buf + sent, s_usb_tx_buf_pos - sent); s_usb_tx_buf_pos = s_usb_tx_buf_pos - sent; } return ret; } ssize_t esp_usb_console_flush(void) { if (s_cdc_acm_device == NULL) { return -1; } write_lock_acquire(); int ret = esp_usb_console_flush_internal(0); write_lock_release(); return ret; } ssize_t esp_usb_console_write_buf(const char* buf, size_t size) { if (s_cdc_acm_device == NULL) { return -1; } if (size == 0) { return 0; } write_lock_acquire(); ssize_t tx_buf_available = ACM_BYTES_PER_TX - s_usb_tx_buf_pos; ssize_t will_write = MIN(size, tx_buf_available); memcpy(s_usb_tx_buf + s_usb_tx_buf_pos, buf, will_write); s_usb_tx_buf_pos += will_write; ssize_t ret; if (s_usb_tx_buf_pos == ACM_BYTES_PER_TX || buf[size - 1] == '\n') { /* Buffer is full, or a newline is found. * For binary streams, we probably shouldn't do line buffering, * but text streams are likely going to be the most common case. */ ret = esp_usb_console_flush_internal(will_write); } else { /* nothing sent out yet, but all the new data is in the buffer now */ ret = will_write; } write_lock_release(); return ret; } ssize_t esp_usb_console_read_buf(char *buf, size_t buf_size) { if (s_cdc_acm_device == NULL) { return -1; } if (!esp_usb_console_read_available()) { return 0; } int bytes_read = cdc_acm_fifo_read(s_cdc_acm_device, (uint8_t*) buf, buf_size); return bytes_read; } esp_err_t esp_usb_console_set_cb(esp_usb_console_cb_t rx_cb, esp_usb_console_cb_t tx_cb, void *arg) { if (s_cdc_acm_device == NULL) { return ESP_ERR_INVALID_STATE; } s_rx_cb = rx_cb; if (s_rx_cb) { cdc_acm_irq_rx_enable(s_cdc_acm_device); } else { cdc_acm_irq_rx_disable(s_cdc_acm_device); } s_tx_cb = tx_cb; if (s_tx_cb) { cdc_acm_irq_tx_enable(s_cdc_acm_device); } else { cdc_acm_irq_tx_disable(s_cdc_acm_device); } s_cb_arg = arg; return ESP_OK; } bool esp_usb_console_read_available(void) { if (s_cdc_acm_device == NULL) { return false; } return cdc_acm_rx_fifo_cnt(s_cdc_acm_device) > 0; } bool esp_usb_console_write_available(void) { if (s_cdc_acm_device == NULL) { return false; } return cdc_acm_irq_tx_ready(s_cdc_acm_device) != 0; } #ifdef CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF /* Used as an output function by esp_rom_printf. * The LF->CRLF replacement logic replicates the one in esp_rom_uart_putc. * Not static to allow placement into IRAM by ldgen. */ void esp_usb_console_write_char(char c) { char cr = '\r'; char lf = '\n'; if (c == lf) { esp_usb_console_write_buf(&cr, 1); esp_usb_console_write_buf(&lf, 1); } else if (c == '\r') { } else { esp_usb_console_write_buf(&c, 1); } } static inline void write_lock_acquire(void) { portENTER_CRITICAL_SAFE(&s_write_lock); } static inline void write_lock_release(void) { portEXIT_CRITICAL_SAFE(&s_write_lock); } #else // CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF static inline void write_lock_acquire(void) { } static inline void write_lock_release(void) { } #endif // CONFIG_ESP_CONSOLE_USB_CDC_SUPPORT_ETS_PRINTF