#include "usbd_core.h" #include "usb_rp2040_reg.h" #ifndef USBD_IRQHandler #define USBD_IRQHandler isr_irq5 #endif #ifndef USB_NUM_BIDIR_ENDPOINTS #define USB_NUM_BIDIR_ENDPOINTS 16 #endif #ifndef FORCE_VBUS_DETECT #define FORCE_VBUS_DETECT 1 #endif /* Endpoint state */ struct usb_dc_ep_state { uint16_t ep_mps; /* Endpoint max packet size */ uint8_t ep_type; /* Endpoint type */ uint8_t ep_stalled; /* Endpoint stall flag */ uint8_t ep_enable; /* Endpoint enable */ uint8_t ep_addr; /* Endpoint address */ uint8_t *xfer_buf; uint32_t xfer_len; uint32_t actual_xfer_len; /** * For rp2040 */ volatile uint32_t *endpoint_control; /*!< Endpoint control register */ volatile uint32_t *buffer_control; /*!< Buffer control register */ uint8_t *dpram_data_buf; /*!< Buffer pointer in usb dpram */ uint8_t next_pid; /*!< Toggle after each packet (unless replying to a SETUP) */ }; /* Driver state */ struct rp2040_udc { volatile uint8_t dev_addr; struct usb_dc_ep_state in_ep[USB_NUM_BIDIR_ENDPOINTS]; /*!< IN endpoint parameters*/ struct usb_dc_ep_state out_ep[USB_NUM_BIDIR_ENDPOINTS]; /*!< OUT endpoint parameters */ struct usb_setup_packet setup; /*!< Setup package that may be used in interrupt processing (outside the protocol stack) */ } g_rp2040_udc; static uint8_t *next_buffer_ptr; /** * @brief Take a buffer pointer located in the USB RAM and return as an offset of the RAM. * * @param buf * @return uint32_t */ static inline uint32_t usb_buffer_offset(volatile uint8_t *buf) { return (uint32_t)buf ^ (uint32_t)usb_dpram; } /** * @brief Alloc the endpoint dpram and set up ep (if applicable. Not valid for EP0). * * @param ep */ static int8_t rp2040_usb_config_ep(struct usb_dc_ep_state *ep) { if (!ep->endpoint_control) { USB_LOG_WRN("Not valid for EP0 \r\n"); return 0; } /*!< size must be multiple of 64 */ uint16_t size = ((ep->ep_mps + 64 - 1) / 64) * 64; /*!< Get current buffer ptr */ ep->dpram_data_buf = next_buffer_ptr; /*!< Update the next buffer ptr */ next_buffer_ptr += size; if (((uint32_t)next_buffer_ptr & 0b111111u) != 0) { USB_LOG_ERR("DPRAM Not 64 byte aligned \r\n"); return -1; } uint32_t dpram_offset = usb_buffer_offset(ep->dpram_data_buf); if (dpram_offset > USB_DPRAM_MAX) { USB_LOG_ERR("DPRAM overflow \r\n"); return -2; } USB_LOG_INFO("Alloced %d bytes at offset 0x%x (0x%p)\r\n", size, dpram_offset, ep->dpram_data_buf); /*!< Enable ep and perbuffer trigger interrupt */ volatile uint32_t reg = EP_CTRL_ENABLE_BITS | EP_CTRL_INTERRUPT_PER_BUFFER | ((ep->ep_type) << EP_CTRL_BUFFER_TYPE_LSB) | dpram_offset; *ep->endpoint_control = reg; return 0; } static void rp2040_usb_init(void) { /*!< Reset usb controller */ reset_block(RESETS_RESET_USBCTRL_BITS); unreset_block_wait(RESETS_RESET_USBCTRL_BITS); /*!< Clear any previous state just in case */ memset(usb_hw, 0, sizeof(*usb_hw)); memset(usb_dpram, 0, sizeof(*usb_dpram)); /*!< Mux the controller to the onboard usb phy */ usb_hw->muxing = USB_USB_MUXING_TO_PHY_BITS | USB_USB_MUXING_SOFTCON_BITS; } int usb_dc_init(void) { memset(&g_rp2040_udc, 0, sizeof(struct rp2040_udc)); rp2040_usb_init(); #if FORCE_VBUS_DETECT /*!< Force VBUS detect so the device thinks it is plugged into a host */ usb_hw->pwr = USB_USB_PWR_VBUS_DETECT_BITS | USB_USB_PWR_VBUS_DETECT_OVERRIDE_EN_BITS; #endif /** * Initializes the USB peripheral for device mode and enables it. * Don't need to enable the pull up here. Force VBUS */ usb_hw->main_ctrl = USB_MAIN_CTRL_CONTROLLER_EN_BITS; /** * Enable individual controller IRQS here. Processor interrupt enable will be used * for the global interrupt enable... * Note: Force VBUS detect cause disconnection not detectable */ usb_hw->sie_ctrl = USB_SIE_CTRL_EP0_INT_1BUF_BITS; usb_hw->inte = USB_INTS_BUFF_STATUS_BITS | USB_INTS_BUS_RESET_BITS | USB_INTS_SETUP_REQ_BITS | USB_INTS_DEV_SUSPEND_BITS | USB_INTS_DEV_RESUME_FROM_HOST_BITS | (FORCE_VBUS_DETECT ? 0 : USB_INTS_DEV_CONN_DIS_BITS); /** * Enable interrupt * Clear pending before enable * (if IRQ is actually asserted, it will immediately re-pend) */ *((io_rw_32 *)(PPB_BASE + M0PLUS_NVIC_ICPR_OFFSET)) = 1 << 5; *((io_rw_32 *)(PPB_BASE + M0PLUS_NVIC_ISER_OFFSET)) = 1 << 5; usb_hw_set->sie_ctrl = USB_SIE_CTRL_PULLUP_EN_BITS; return 0; } /** * @brief Starts a transfer on a given endpoint. * * @param ep, the endpoint configuration. * @param buf, the data buffer to send. Only applicable if the endpoint is TX * @param len, the length of the data in buf (this example limits max len to one packet - 64 bytes) */ static void usb_start_transfer(struct usb_dc_ep_state *ep, uint8_t *buf, uint16_t len) { /*!< Prepare buffer control register value */ uint32_t val = len | USB_BUF_CTRL_AVAIL; if (len < ep->ep_mps) { val |= USB_BUF_CTRL_LAST; } if (USB_EP_DIR_IS_IN(ep->ep_addr)) { /*!< Need to copy the data from the user buffer to the usb memory */ if (buf != NULL) { memcpy((void *)ep->dpram_data_buf, (void *)buf, len); } /*!< Mark as full */ val |= USB_BUF_CTRL_FULL; } else { } /*!< Set pid and flip for next transfer */ val |= ep->next_pid ? USB_BUF_CTRL_DATA1_PID : USB_BUF_CTRL_DATA0_PID; ep->next_pid ^= 1u; /** * !Need delay some cycles * nop for some clk_sys cycles to ensure that at least one clk_usb cycle has passed. For example if clk_sys was running * at 125MHz and clk_usb was running at 48MHz then 125/48 rounded up would be 3 nop instructions */ *ep->buffer_control = val & ~USB_BUF_CTRL_AVAIL; __asm volatile( "b 1f\n" "1: b 1f\n" "1: b 1f\n" "1: b 1f\n" "1: b 1f\n" "1: b 1f\n" "1: b 1f\n" "1:\n" : : : "memory"); *ep->buffer_control = val; } int usb_dc_deinit(void) { return 0; } int usbd_set_address(const uint8_t addr) { if (addr != 0) { g_rp2040_udc.dev_addr = addr; } return 0; } uint8_t usbd_get_port_speed(const uint8_t port) { return USB_SPEED_FULL; } int usbd_ep_open(const struct usbd_endpoint_cfg *ep_cfg) { uint8_t ep_idx = USB_EP_GET_IDX(ep_cfg->ep_addr); if (ep_idx == 0) { /** * A device must support Endpoint 0 so that it can reply to SETUP packets and be enumerated. As a result, there is no * endpoint control register for EP0. Its buffers begin at 0x100. All other endpoints can have either single or dual buffers * and are mapped at the base address programmed. As EP0 has no endpoint control register, the interrupt enable * controls for EP0 come from SIE_CTRL. */ g_rp2040_udc.out_ep[ep_idx].endpoint_control = NULL; g_rp2040_udc.out_ep[ep_idx].dpram_data_buf = (uint8_t *)&usb_dpram->ep0_buf_a[0]; g_rp2040_udc.in_ep[ep_idx].endpoint_control = NULL; g_rp2040_udc.in_ep[ep_idx].dpram_data_buf = (uint8_t *)&usb_dpram->ep0_buf_a[0]; } if (USB_EP_DIR_IS_OUT(ep_cfg->ep_addr)) { g_rp2040_udc.out_ep[ep_idx].ep_mps = ep_cfg->ep_mps; g_rp2040_udc.out_ep[ep_idx].ep_type = ep_cfg->ep_type; g_rp2040_udc.out_ep[ep_idx].ep_addr = ep_cfg->ep_addr; g_rp2040_udc.out_ep[ep_idx].ep_enable = true; /*!< Get control reg */ g_rp2040_udc.out_ep[ep_idx].buffer_control = &usb_dpram->ep_buf_ctrl[ep_idx].out; /*!< Clear control reg */ *(g_rp2040_udc.out_ep[ep_idx].buffer_control) = 0; if (ep_idx != 0) { g_rp2040_udc.out_ep[ep_idx].endpoint_control = &usb_dpram->ep_ctrl[ep_idx - 1].out; /** * Allocate a buffer on DPRAM for the endpoint */ return rp2040_usb_config_ep(&g_rp2040_udc.out_ep[ep_idx]); } } else { g_rp2040_udc.in_ep[ep_idx].ep_mps = ep_cfg->ep_mps; g_rp2040_udc.in_ep[ep_idx].ep_type = ep_cfg->ep_type; g_rp2040_udc.in_ep[ep_idx].ep_addr = ep_cfg->ep_addr; g_rp2040_udc.in_ep[ep_idx].ep_enable = true; /*!< Get control reg */ g_rp2040_udc.in_ep[ep_idx].buffer_control = &usb_dpram->ep_buf_ctrl[ep_idx].in; /*!< Clear control reg */ *(g_rp2040_udc.in_ep[ep_idx].buffer_control) = 0; if (ep_idx != 0) { g_rp2040_udc.in_ep[ep_idx].endpoint_control = &usb_dpram->ep_ctrl[ep_idx - 1].in; /** * Allocate a buffer on DPRAM for the endpoint */ return rp2040_usb_config_ep(&g_rp2040_udc.in_ep[ep_idx]); } } return 0; } int usbd_ep_close(const uint8_t ep) { /*!< Ep id */ uint16_t size = 0; uint8_t epid = USB_EP_GET_IDX(ep); if (USB_EP_DIR_IS_IN(ep)) { /*!< In */ size = ((g_rp2040_udc.in_ep[epid].ep_mps + 64 - 1) / 64) * 64; memset(g_rp2040_udc.in_ep[epid].dpram_data_buf, 0, size); next_buffer_ptr -= size; g_rp2040_udc.in_ep[epid].ep_enable = false; } else if (USB_EP_DIR_IS_OUT(ep)) { /*!< Out */ size = ((g_rp2040_udc.out_ep[epid].ep_mps + 64 - 1) / 64) * 64; memset(g_rp2040_udc.out_ep[epid].dpram_data_buf, 0, size); next_buffer_ptr -= size; g_rp2040_udc.out_ep[epid].ep_enable = false; } return 0; } int usbd_ep_set_stall(const uint8_t ep) { if (USB_EP_GET_IDX(ep) == 0) { /** * A stall on EP0 has to be armed so it can be cleared on the next setup packet */ usb_hw_set->ep_stall_arm = (USB_EP_DIR_IS_IN(ep)) ? USB_EP_STALL_ARM_EP0_IN_BITS : USB_EP_STALL_ARM_EP0_OUT_BITS; } if (USB_EP_DIR_IS_OUT(ep)) { *(g_rp2040_udc.out_ep[USB_EP_GET_IDX(ep)].buffer_control) = USB_BUF_CTRL_STALL; } else { *(g_rp2040_udc.in_ep[USB_EP_GET_IDX(ep)].buffer_control) = USB_BUF_CTRL_STALL; } return 0; } int usbd_ep_clear_stall(const uint8_t ep) { volatile uint32_t value = 0; if (USB_EP_GET_IDX(ep)) { if (USB_EP_DIR_IS_OUT(ep)) { g_rp2040_udc.out_ep[USB_EP_GET_IDX(ep)].next_pid = 0; value = *(g_rp2040_udc.out_ep[USB_EP_GET_IDX(ep)].buffer_control) & (~USB_BUF_CTRL_STALL); *(g_rp2040_udc.out_ep[USB_EP_GET_IDX(ep)].buffer_control) = value; } else { g_rp2040_udc.in_ep[USB_EP_GET_IDX(ep)].next_pid = 0; value = *(g_rp2040_udc.in_ep[USB_EP_GET_IDX(ep)].buffer_control) & (~USB_BUF_CTRL_STALL); *(g_rp2040_udc.in_ep[USB_EP_GET_IDX(ep)].buffer_control) = value; } } return 0; } int usbd_ep_is_stalled(const uint8_t ep, uint8_t *stalled) { return 0; } int usbd_ep_start_write(const uint8_t ep, const uint8_t *data, uint32_t data_len) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (!data && data_len) { return -1; } if (!g_rp2040_udc.in_ep[ep_idx].ep_enable) { return -2; } g_rp2040_udc.in_ep[ep_idx].xfer_buf = (uint8_t *)data; g_rp2040_udc.in_ep[ep_idx].xfer_len = data_len; g_rp2040_udc.in_ep[ep_idx].actual_xfer_len = 0; if (data_len == 0) { usb_start_transfer(&g_rp2040_udc.in_ep[ep_idx], NULL, 0); return 0; } else { /*!< Not zlp */ data_len = MIN(data_len, g_rp2040_udc.in_ep[ep_idx].ep_mps); usb_start_transfer(&g_rp2040_udc.in_ep[ep_idx], g_rp2040_udc.in_ep[ep_idx].xfer_buf, data_len); } return 0; } int usbd_ep_start_read(const uint8_t ep, uint8_t *data, uint32_t data_len) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (!data && data_len) { return -1; } if (!g_rp2040_udc.out_ep[ep_idx].ep_enable) { return -2; } g_rp2040_udc.out_ep[ep_idx].xfer_buf = (uint8_t *)data; g_rp2040_udc.out_ep[ep_idx].xfer_len = data_len; g_rp2040_udc.out_ep[ep_idx].actual_xfer_len = 0; if (data_len == 0) { usb_start_transfer(&g_rp2040_udc.out_ep[ep_idx], NULL, 0); return 0; } else { /*!< Not zlp */ data_len = MIN(data_len, g_rp2040_udc.out_ep[ep_idx].ep_mps); usb_start_transfer(&g_rp2040_udc.out_ep[ep_idx], g_rp2040_udc.out_ep[ep_idx].xfer_buf, data_len); } return 0; } /** * @brief Notify an endpoint that a transfer has completed. * * @param ep, the endpoint to notify. */ static void usb_handle_ep_buff_done(struct usb_dc_ep_state *ep) { uint32_t buffer_control = *ep->buffer_control; /*!< Get the transfer length for this endpoint */ uint16_t read_count = buffer_control & USB_BUF_CTRL_LEN_MASK; /*!< Call that endpoints buffer done handler */ if (ep->ep_addr == 0x80) { /*!< EP0 In */ /** * Determine the current setup direction */ switch (g_rp2040_udc.setup.bmRequestType >> USB_REQUEST_DIR_SHIFT) { case 1: /*!< Get */ if (g_rp2040_udc.in_ep[0].xfer_len > g_rp2040_udc.in_ep[0].ep_mps) { g_rp2040_udc.in_ep[0].xfer_len -= g_rp2040_udc.in_ep[0].ep_mps; g_rp2040_udc.in_ep[0].actual_xfer_len += g_rp2040_udc.in_ep[0].ep_mps; usbd_event_ep_in_complete_handler(0 | 0x80, g_rp2040_udc.in_ep[0].actual_xfer_len); } else { g_rp2040_udc.in_ep[0].actual_xfer_len += g_rp2040_udc.in_ep[0].xfer_len; g_rp2040_udc.in_ep[0].xfer_len = 0; /** * EP0 In complete and host will send a out token to get 0 length packet * In the next usbd_event_ep_in_complete_handler, stack will start read 0 length packet * and host must send data1 packet.We resest the ep0 next_pid = 1 in setup interrupt head. */ usbd_event_ep_in_complete_handler(0 | 0x80, g_rp2040_udc.in_ep[0].actual_xfer_len); } break; case 0: /*!< Set */ if (g_rp2040_udc.dev_addr > 0) { usb_hw->dev_addr_ctrl = g_rp2040_udc.dev_addr; g_rp2040_udc.dev_addr = 0; } else { /*!< Normal status stage // Setup out...out in */ /** * Perpar for next setup */ } break; } } else if (ep->ep_addr == 0x00) { /*!< EP0 Out */ memcpy(g_rp2040_udc.out_ep[0].xfer_buf, g_rp2040_udc.out_ep[0].dpram_data_buf, read_count); if (read_count == 0) { /*!< Normal status stage // Setup in...in out */ /** * Perpar for next setup */ } g_rp2040_udc.out_ep[0].actual_xfer_len += read_count; g_rp2040_udc.out_ep[0].xfer_len -= read_count; usbd_event_ep_out_complete_handler(0x00, g_rp2040_udc.out_ep[0].actual_xfer_len); } else { /*!< Others ep */ uint16_t data_len = 0; if (USB_EP_DIR_IS_OUT(ep->ep_addr)) { /*!< flip the pid */ memcpy(g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].xfer_buf, g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].dpram_data_buf, read_count); g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].xfer_buf += read_count; g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].actual_xfer_len += read_count; g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].xfer_len -= read_count; if (read_count < g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].ep_mps || g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].xfer_len == 0) { /*!< Out complete */ usbd_event_ep_out_complete_handler(ep->ep_addr, g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].actual_xfer_len); } else { /*!< Need read again */ data_len = MIN(g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].xfer_len, g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f].ep_mps); usb_start_transfer(&g_rp2040_udc.out_ep[(ep->ep_addr) & 0x0f], NULL, data_len); } } else { if (g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_len > g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].ep_mps) { /*!< Need tx again */ g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_len -= g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].ep_mps; g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_buf += g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].ep_mps; g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].actual_xfer_len += g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].ep_mps; data_len = MIN(g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_len, g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].ep_mps); usb_start_transfer(&g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f], g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_buf, data_len); } else { /*!< In complete */ g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].actual_xfer_len += g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_len; g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].xfer_len = 0; usbd_event_ep_in_complete_handler(ep->ep_addr, g_rp2040_udc.in_ep[(ep->ep_addr) & 0x0f].actual_xfer_len); } } } } /** * @brief Find the endpoint configuration for a specified endpoint number and * direction and notify it that a transfer has completed. * * @param ep_num * @param in */ static void usb_handle_buff_done(uint8_t ep_num, bool in) { uint8_t ep_addr = ep_num | (in ? USB_EP_DIR_IN : 0); if (USB_EP_DIR_IS_OUT(ep_addr)) { usb_handle_ep_buff_done(&g_rp2040_udc.out_ep[ep_num]); } else { usb_handle_ep_buff_done(&g_rp2040_udc.in_ep[ep_num]); } } /** * @brief Handle a "buffer status" irq. This means that one or more * buffers have been sent / received. Notify each endpoint where this * is the case. */ static void usb_handle_buff_status() { uint32_t buffers = usb_hw->buf_status; uint32_t remaining_buffers = buffers; uint32_t bit = 1u; for (uint8_t i = 0; remaining_buffers && i < USB_NUM_ENDPOINTS * 2; i++) { if (remaining_buffers & bit) { /*!< clear this in advance */ usb_hw_clear->buf_status = bit; /*!< IN transfer for even i, OUT transfer for odd i */ usb_handle_buff_done(i >> 1u, !(i & 1u)); remaining_buffers &= ~bit; } bit <<= 1u; } } void USBD_IRQHandler(void) { uint32_t const status = usb_hw->ints; uint32_t handled = 0; if (status & USB_INTS_BUFF_STATUS_BITS) { handled |= USB_INTS_BUFF_STATUS_BITS; usb_handle_buff_status(); } if (status & USB_INTS_SETUP_REQ_BITS) { handled |= USB_INTS_SETUP_REQ_BITS; memcpy((uint8_t *)&g_rp2040_udc.setup, (uint8_t const *)&usb_dpram->setup_packet, 8); /** * reset pid to both 1 (data and ack) */ g_rp2040_udc.in_ep[0].next_pid = 1; g_rp2040_udc.out_ep[0].next_pid = 1; usbd_event_ep0_setup_complete_handler((uint8_t *)&g_rp2040_udc.setup); usb_hw_clear->sie_status = USB_SIE_STATUS_SETUP_REC_BITS; } #if FORCE_VBUS_DETECT == 0 /** * Since we force VBUS detect On, device will always think it is connected and * couldn't distinguish between disconnect and suspend */ if (status & USB_INTS_DEV_CONN_DIS_BITS) { handled |= USB_INTS_DEV_CONN_DIS_BITS; if (usb_hw->sie_status & USB_SIE_STATUS_CONNECTED_BITS) { /*!< Connected: nothing to do */ } else { /*!< Disconnected */ } usb_hw_clear->sie_status = USB_SIE_STATUS_CONNECTED_BITS; } #endif /** * SE0 for 2.5 us or more (will last at least 10ms) */ if (status & USB_INTS_BUS_RESET_BITS) { handled |= USB_INTS_BUS_RESET_BITS; usb_hw->dev_addr_ctrl = 0; for (uint8_t i = 0; i < USB_NUM_BIDIR_ENDPOINTS - 1; i++) { /*!< Start at ep1 */ usb_dpram->ep_ctrl[i].in = 0; usb_dpram->ep_ctrl[i].out = 0; } /*!< reclaim buffer space */ next_buffer_ptr = &usb_dpram->epx_data[0]; usbd_event_reset_handler(); usb_hw_clear->sie_status = USB_SIE_STATUS_BUS_RESET_BITS; #if CHERRYUSB_OPT_RP2040_USB_DEVICE_ENUMERATION_FIX /** * Only run enumeration walk-around if pull up is enabled */ if (usb_hw->sie_ctrl & USB_SIE_CTRL_PULLUP_EN_BITS) rp2040_usb_device_enumeration_fix(); #endif } /** * Note from pico datasheet 4.1.2.6.4 (v1.2) * If you enable the suspend interrupt, it is likely you will see a suspend interrupt when * the device is first connected but the bus is idle. The bus can be idle for a few ms before * the host begins sending start of frame packets. You will also see a suspend interrupt * when the device is disconnected if you do not have a VBUS detect circuit connected. This is * because without VBUS detection, it is impossible to tell the difference between * being disconnected and suspended. */ if (status & USB_INTS_DEV_SUSPEND_BITS) { handled |= USB_INTS_DEV_SUSPEND_BITS; /*!< Suspend */ usb_hw_clear->sie_status = USB_SIE_STATUS_SUSPENDED_BITS; } if (status & USB_INTS_DEV_RESUME_FROM_HOST_BITS) { handled |= USB_INTS_DEV_RESUME_FROM_HOST_BITS; /*!< Resume */ usb_hw_clear->sie_status = USB_SIE_STATUS_RESUME_BITS; } if (status ^ handled) { USB_LOG_INFO("Unhandled IRQ 0x%x\n", (uint32_t)(status ^ handled)); } }