/* * Copyright (c) 2022-2024 HPMicro * * SPDX-License-Identifier: BSD-3-Clause * */ #include "usbd_core.h" #include "hpm_usb_device.h" #ifndef USB_NUM_BIDIR_ENDPOINTS #define USB_NUM_BIDIR_ENDPOINTS CONFIG_USBDEV_EP_NUM #endif /* USBSTS, USBINTR */ enum { intr_usb = HPM_BITSMASK(1, 0), intr_error = HPM_BITSMASK(1, 1), intr_port_change = HPM_BITSMASK(1, 2), intr_reset = HPM_BITSMASK(1, 6), intr_sof = HPM_BITSMASK(1, 7), intr_suspend = HPM_BITSMASK(1, 8), intr_nak = HPM_BITSMASK(1, 16) }; /* Endpoint state */ struct hpm_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 *xfer_buf; uint32_t xfer_len; uint32_t actual_xfer_len; }; /*---------------------------------------------------------------------* * Variable Definitions *---------------------------------------------------------------------*/ /* Driver state */ struct hpm_udc { usb_device_handle_t *handle; bool is_suspend; struct hpm_ep_state in_ep[USB_NUM_BIDIR_ENDPOINTS]; /*!< IN endpoint parameters*/ struct hpm_ep_state out_ep[USB_NUM_BIDIR_ENDPOINTS]; /*!< OUT endpoint parameters */ } g_hpm_udc[CONFIG_USBDEV_MAX_BUS]; static ATTR_PLACE_AT_NONCACHEABLE_WITH_ALIGNMENT(USB_SOC_DCD_DATA_RAM_ADDRESS_ALIGNMENT) dcd_data_t _dcd_data0; #ifdef HPM_USB1_BASE static ATTR_PLACE_AT_NONCACHEABLE_WITH_ALIGNMENT(USB_SOC_DCD_DATA_RAM_ADDRESS_ALIGNMENT) dcd_data_t _dcd_data1; #endif static ATTR_PLACE_AT_NONCACHEABLE usb_device_handle_t usb_device_handle[CONFIG_USBDEV_MAX_BUS]; static uint32_t _dcd_irqnum[CONFIG_USBDEV_MAX_BUS]; static uint8_t _dcd_busid[CONFIG_USBDEV_MAX_BUS]; /* Index to bit position in register */ static inline uint8_t ep_idx2bit(uint8_t ep_idx) { return ep_idx / 2 + ((ep_idx % 2) ? 16 : 0); } void usbd_execute_test_mode(uint8_t busid, uint8_t test_mode) { usb_set_port_test_mode(g_hpm_udc[busid].handle->regs, test_mode); } int usb_dc_init(uint8_t busid) { memset(&g_hpm_udc[busid], 0, sizeof(struct hpm_udc)); g_hpm_udc[busid].handle = &usb_device_handle[busid]; g_hpm_udc[busid].handle->regs = (USB_Type *)g_usbdev_bus[busid].reg_base; if (g_usbdev_bus[busid].reg_base == HPM_USB0_BASE) { _dcd_irqnum[busid] = IRQn_USB0; _dcd_busid[0] = busid; } else { #ifdef HPM_USB1_BASE if (g_usbdev_bus[busid].reg_base == HPM_USB1_BASE) { _dcd_irqnum[busid] = IRQn_USB1; _dcd_busid[1] = busid; } #endif } if (busid == 0) { g_hpm_udc[busid].handle->dcd_data = &_dcd_data0; } else if (busid == 1) { #ifdef HPM_USB1_BASE g_hpm_udc[busid].handle->dcd_data = &_dcd_data1; #endif } else { ; } uint32_t int_mask; int_mask = (USB_USBINTR_UE_MASK | USB_USBINTR_UEE_MASK | USB_USBINTR_SLE_MASK | USB_USBINTR_PCE_MASK | USB_USBINTR_URE_MASK); usb_device_init(g_hpm_udc[busid].handle, int_mask); intc_m_enable_irq(_dcd_irqnum[busid]); return 0; } int usb_dc_deinit(uint8_t busid) { intc_m_disable_irq(_dcd_irqnum[busid]); usb_device_deinit(g_hpm_udc[busid].handle); return 0; } int usbd_set_address(uint8_t busid, const uint8_t addr) { usb_device_handle_t *handle = g_hpm_udc[busid].handle; usb_dcd_set_address(handle->regs, addr); return 0; } int usbd_set_remote_wakeup(uint8_t busid) { USB_Type *ptr; ptr = g_hpm_udc[busid].handle->regs; if (!usb_get_suspend_status(ptr)) { return -1; } usb_force_port_resume(ptr); return 0; } uint8_t usbd_get_port_speed(uint8_t busid) { uint8_t speed; speed = usb_get_port_speed(g_hpm_udc[busid].handle->regs); if (speed == 0x00) { return USB_SPEED_FULL; } if (speed == 0x01) { return USB_SPEED_LOW; } if (speed == 0x02) { return USB_SPEED_HIGH; } return 0; } int usbd_ep_open(uint8_t busid, const struct usb_endpoint_descriptor *ep) { usb_endpoint_config_t tmp_ep_cfg; usb_device_handle_t *handle = g_hpm_udc[busid].handle; uint8_t ep_idx = USB_EP_GET_IDX(ep->bEndpointAddress); tmp_ep_cfg.xfer = USB_GET_ENDPOINT_TYPE(ep->bmAttributes); tmp_ep_cfg.ep_addr = ep->bEndpointAddress; tmp_ep_cfg.max_packet_size = ep->wMaxPacketSize; usb_device_edpt_open(handle, &tmp_ep_cfg); if (USB_EP_DIR_IS_OUT(ep->bEndpointAddress)) { g_hpm_udc[busid].out_ep[ep_idx].ep_mps = USB_GET_MAXPACKETSIZE(ep->wMaxPacketSize); g_hpm_udc[busid].out_ep[ep_idx].ep_type = USB_GET_ENDPOINT_TYPE(ep->bmAttributes); g_hpm_udc[busid].out_ep[ep_idx].ep_enable = true; } else { g_hpm_udc[busid].in_ep[ep_idx].ep_mps = USB_GET_MAXPACKETSIZE(ep->wMaxPacketSize); g_hpm_udc[busid].in_ep[ep_idx].ep_type = USB_GET_ENDPOINT_TYPE(ep->bmAttributes); g_hpm_udc[busid].in_ep[ep_idx].ep_enable = true; } return 0; } int usbd_ep_close(uint8_t busid, const uint8_t ep) { usb_device_handle_t *handle = g_hpm_udc[busid].handle; uint8_t ep_idx = USB_EP_GET_IDX(ep); if (USB_EP_DIR_IS_OUT(ep)) { g_hpm_udc[busid].out_ep[ep_idx].ep_enable = false; } else { g_hpm_udc[busid].in_ep[ep_idx].ep_enable = false; } usb_device_edpt_close(handle, ep); return 0; } int usbd_ep_set_stall(uint8_t busid, const uint8_t ep) { usb_device_handle_t *handle = g_hpm_udc[busid].handle; usb_device_edpt_stall(handle, ep); return 0; } int usbd_ep_clear_stall(uint8_t busid, const uint8_t ep) { usb_device_handle_t *handle = g_hpm_udc[busid].handle; usb_device_edpt_clear_stall(handle, ep); return 0; } int usbd_ep_is_stalled(uint8_t busid, const uint8_t ep, uint8_t *stalled) { usb_device_handle_t *handle = g_hpm_udc[busid].handle; *stalled = usb_device_edpt_check_stall(handle, ep); return 0; } int usbd_ep_start_write(uint8_t busid, const uint8_t ep, const uint8_t *data, uint32_t data_len) { uint8_t ep_idx = USB_EP_GET_IDX(ep); usb_device_handle_t *handle = g_hpm_udc[busid].handle; if (!data && data_len) { return -1; } if (!g_hpm_udc[busid].in_ep[ep_idx].ep_enable) { return -2; } g_hpm_udc[busid].in_ep[ep_idx].xfer_buf = (uint8_t *)data; g_hpm_udc[busid].in_ep[ep_idx].xfer_len = data_len; g_hpm_udc[busid].in_ep[ep_idx].actual_xfer_len = 0; usb_device_edpt_xfer(handle, ep, (uint8_t *)data, data_len); return 0; } int usbd_ep_start_read(uint8_t busid, const uint8_t ep, uint8_t *data, uint32_t data_len) { uint8_t ep_idx = USB_EP_GET_IDX(ep); usb_device_handle_t *handle = g_hpm_udc[busid].handle; if (!data && data_len) { return -1; } if (!g_hpm_udc[busid].out_ep[ep_idx].ep_enable) { return -2; } g_hpm_udc[busid].out_ep[ep_idx].xfer_buf = (uint8_t *)data; g_hpm_udc[busid].out_ep[ep_idx].xfer_len = data_len; g_hpm_udc[busid].out_ep[ep_idx].actual_xfer_len = 0; usb_device_edpt_xfer(handle, ep, data, data_len); return 0; } void USBD_IRQHandler(uint8_t busid) { uint32_t int_status; usb_device_handle_t *handle = g_hpm_udc[busid].handle; uint32_t transfer_len; bool ep_cb_req; /* Acknowledge handled interrupt */ int_status = usb_device_status_flags(handle); int_status &= usb_device_interrupts(handle); usb_device_clear_status_flags(handle, int_status); if (int_status & intr_error) { USB_LOG_ERR("usbd intr error!\r\n"); } if (int_status & intr_reset) { g_hpm_udc[busid].is_suspend = false; memset(g_hpm_udc[busid].in_ep, 0, sizeof(struct hpm_ep_state) * USB_NUM_BIDIR_ENDPOINTS); memset(g_hpm_udc[busid].out_ep, 0, sizeof(struct hpm_ep_state) * USB_NUM_BIDIR_ENDPOINTS); usbd_event_reset_handler(busid); usb_device_bus_reset(handle, 64); } if (int_status & intr_suspend) { if (usb_device_get_suspend_status(handle)) { /* Note: Host may delay more than 3 ms before and/or after bus reset before doing enumeration. */ if (usb_device_get_address(handle)) { g_hpm_udc[busid].is_suspend = true; usbd_event_suspend_handler(busid); } } else { } } if (int_status & intr_port_change) { if (!usb_device_get_port_ccs(handle)) { usbd_event_disconnect_handler(busid); } else { if (g_hpm_udc[busid].is_suspend) { g_hpm_udc[busid].is_suspend = false; usbd_event_resume_handler(busid); } usbd_event_connect_handler(busid); } } if (int_status & intr_usb) { uint32_t const edpt_complete = usb_device_get_edpt_complete_status(handle); usb_device_clear_edpt_complete_status(handle, edpt_complete); uint32_t edpt_setup_status = usb_device_get_setup_status(handle); if (edpt_setup_status) { /*------------- Set up Received -------------*/ usb_device_clear_setup_status(handle, edpt_setup_status); dcd_qhd_t *qhd0 = usb_device_qhd_get(handle, 0); usbd_event_ep0_setup_complete_handler(busid, (uint8_t *)&qhd0->setup_request); } if (edpt_complete) { for (uint8_t ep_idx = 0; ep_idx < USB_SOS_DCD_MAX_QHD_COUNT; ep_idx++) { if (edpt_complete & (1 << ep_idx2bit(ep_idx))) { transfer_len = 0; ep_cb_req = true; /* Failed QTD also get ENDPTCOMPLETE set */ dcd_qtd_t *p_qtd = usb_device_qtd_get(handle, ep_idx); while (1) { if (p_qtd->halted || p_qtd->xact_err || p_qtd->buffer_err) { USB_LOG_ERR("usbd transfer error!\r\n"); ep_cb_req = false; break; } else if (p_qtd->active) { ep_cb_req = false; break; } else { transfer_len += p_qtd->expected_bytes - p_qtd->total_bytes; } if (p_qtd->next == USB_SOC_DCD_QTD_NEXT_INVALID) { break; } else { p_qtd = (dcd_qtd_t *)p_qtd->next; } } if (ep_cb_req) { uint8_t const ep_addr = (ep_idx / 2) | ((ep_idx & 0x01) ? 0x80 : 0); if (ep_addr & 0x80) { usbd_event_ep_in_complete_handler(busid, ep_addr, transfer_len); } else { usbd_event_ep_out_complete_handler(busid, ep_addr, transfer_len); } } } } } } } #if !defined(USBD_USE_CUSTOM_ISR) || !USBD_USE_CUSTOM_ISR SDK_DECLARE_EXT_ISR_M(IRQn_USB0, isr_usbd0) void isr_usbd0(void) { USBD_IRQHandler(_dcd_busid[0]); } #ifdef HPM_USB1_BASE SDK_DECLARE_EXT_ISR_M(IRQn_USB1, isr_usbd1) void isr_usbd1(void) { USBD_IRQHandler(_dcd_busid[1]); } #endif #endif