/* usb_dc_kinetis.c - Kinetis USBFSOTG usb device driver */ /* * Copyright (c) 2017 PHYTEC Messtechnik GmbH * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nxp_kinetis_usbd #include #include #include #include #include #include #include #define LOG_LEVEL CONFIG_USB_DRIVER_LOG_LEVEL #include #include LOG_MODULE_REGISTER(usb_dc_kinetis); #define NUM_OF_EP_MAX DT_INST_PROP(0, num_bidir_endpoints) #define BD_OWN_MASK (1 << 5) #define BD_DATA01_MASK (1 << 4) #define BD_KEEP_MASK (1 << 3) #define BD_NINC_MASK (1 << 2) #define BD_DTS_MASK (1 << 1) #define BD_STALL_MASK (1 << 0) #define KINETIS_SETUP_TOKEN 0x0d #define KINETIS_IN_TOKEN 0x09 #define KINETIS_OUT_TOKEN 0x01 #define USBFSOTG_PERID 0x04 #define USBFSOTG_REV 0x33 #define KINETIS_EP_NUMOF_MASK 0xf #define KINETIS_ADDR2IDX(addr) ((addr) & (KINETIS_EP_NUMOF_MASK)) /* * Buffer Descriptor (BD) entry provides endpoint buffer control * information for USBFS controller. Every endpoint direction requires * two BD entries. */ struct buf_descriptor { union { uint32_t bd_fields; struct { uint32_t reserved_1_0 : 2; uint32_t tok_pid : 4; uint32_t data01 : 1; uint32_t own : 1; uint32_t reserved_15_8 : 8; uint32_t bc : 16; } get __packed; struct { uint32_t reserved_1_0 : 2; uint32_t bd_ctrl : 6; uint32_t reserved_15_8 : 8; uint32_t bc : 16; } set __packed; } __packed; uint32_t buf_addr; } __packed; /* * Buffer Descriptor Table for the endpoints buffer management. * The driver configuration with 16 fully bidirectional endpoints would require * four BD entries per endpoint and 512 bytes of memory. */ static struct buf_descriptor __aligned(512) bdt[(NUM_OF_EP_MAX) * 2 * 2]; #define BD_IDX_EP0TX_EVEN 2 #define BD_IDX_EP0TX_ODD 3 #define EP_BUF_NUMOF_BLOCKS (NUM_OF_EP_MAX / 2) K_HEAP_DEFINE(ep_buf_pool, 512 * EP_BUF_NUMOF_BLOCKS + 128); struct ep_mem_block { void *data; }; struct usb_ep_ctrl_data { struct ep_status { uint16_t in_enabled : 1; uint16_t out_enabled : 1; uint16_t in_data1 : 1; uint16_t out_data1 : 1; uint16_t in_odd : 1; uint16_t out_odd : 1; uint16_t in_stalled : 1; uint16_t out_stalled : 1; } status; uint16_t mps_in; uint16_t mps_out; struct ep_mem_block mblock_in; struct ep_mem_block mblock_out; usb_dc_ep_callback cb_in; usb_dc_ep_callback cb_out; }; #define USBD_THREAD_STACK_SIZE 1024 struct usb_device_data { usb_dc_status_callback status_cb; uint8_t address; uint32_t bd_active; struct usb_ep_ctrl_data ep_ctrl[NUM_OF_EP_MAX]; bool attached; K_KERNEL_STACK_MEMBER(thread_stack, USBD_THREAD_STACK_SIZE); struct k_thread thread; }; static struct usb_device_data dev_data; #define USB_DC_CB_TYPE_MGMT 0 #define USB_DC_CB_TYPE_EP 1 struct cb_msg { uint8_t ep; uint8_t type; uint32_t cb; }; K_MSGQ_DEFINE(usb_dc_msgq, sizeof(struct cb_msg), 10, 4); static void usb_kinetis_isr_handler(void); /* * This function returns the BD element index based on * endpoint address and the odd bit. */ static inline uint8_t get_bdt_idx(uint8_t ep, uint8_t odd) { if (ep & USB_EP_DIR_IN) { return ((((KINETIS_ADDR2IDX(ep)) * 4) + 2 + (odd & 1))); } return ((((KINETIS_ADDR2IDX(ep)) * 4) + (odd & 1))); } static int kinetis_usb_init(void) { #if !DT_INST_PROP(0, no_voltage_regulator) /* enable USB voltage regulator */ SIM->SOPT1 |= SIM_SOPT1_USBREGEN_MASK; #endif USB0->USBTRC0 |= USB_USBTRC0_USBRESET_MASK; k_busy_wait(2000); USB0->CTL = 0; /* enable USB module, AKA USBEN bit in CTL1 register */ USB0->CTL |= USB_CTL_USBENSOFEN_MASK; if ((USB0->PERID != USBFSOTG_PERID) || (USB0->REV != USBFSOTG_REV)) { return -1; } USB0->BDTPAGE1 = (uint8_t)(((uint32_t)bdt) >> 8); USB0->BDTPAGE2 = (uint8_t)(((uint32_t)bdt) >> 16); USB0->BDTPAGE3 = (uint8_t)(((uint32_t)bdt) >> 24); /* clear interrupt flags */ USB0->ISTAT = 0xFF; /* enable reset interrupt */ USB0->INTEN = USB_INTEN_USBRSTEN_MASK; USB0->USBCTRL = USB_USBCTRL_PDE_MASK; LOG_DBG(""); return 0; } int usb_dc_reset(void) { for (uint8_t i = 0; i < 16; i++) { USB0->ENDPOINT[i].ENDPT = 0; } dev_data.bd_active = 0U; dev_data.address = 0U; USB0->CTL |= USB_CTL_ODDRST_MASK; USB0->CTL &= ~USB_CTL_ODDRST_MASK; /* Clear interrupt status flags */ USB0->ISTAT = 0xFF; /* Clear error flags */ USB0->ERRSTAT = 0xFF; /* Enable all error interrupt sources */ USB0->ERREN = 0xFF; /* Reset default address */ USB0->ADDR = 0x00; USB0->INTEN = (USB_INTEN_USBRSTEN_MASK | USB_INTEN_TOKDNEEN_MASK | USB_INTEN_SLEEPEN_MASK | USB_INTEN_SOFTOKEN_MASK | USB_INTEN_STALLEN_MASK | USB_INTEN_ERROREN_MASK); LOG_DBG(""); return 0; } int usb_dc_attach(void) { if (dev_data.attached) { LOG_WRN("already attached"); } kinetis_usb_init(); /* * Call usb_dc_reset here because the device stack does not make it * after USB_DC_RESET status event. */ usb_dc_reset(); dev_data.attached = 1; LOG_DBG("attached"); /* non-OTG device mode, enable DP Pullup */ USB0->CONTROL = USB_CONTROL_DPPULLUPNONOTG_MASK; return 0; } int usb_dc_detach(void) { LOG_DBG(""); /* disable USB and DP Pullup */ USB0->CTL &= ~USB_CTL_USBENSOFEN_MASK; USB0->CONTROL &= ~USB_CONTROL_DPPULLUPNONOTG_MASK; return 0; } int usb_dc_set_address(const uint8_t addr) { LOG_DBG(""); if (!dev_data.attached) { return -EINVAL; } /* * The device stack tries to set the address before * sending the ACK with ZLP, which is totally stupid, * as workaround the address will be buffered and * placed later inside isr handler (see KINETIS_IN_TOKEN). */ dev_data.address = 0x80 | (addr & 0x7f); return 0; } int usb_dc_ep_check_cap(const struct usb_dc_ep_cfg_data * const cfg) { uint8_t ep_idx = USB_EP_GET_IDX(cfg->ep_addr); if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("endpoint index/address out of range"); return -EINVAL; } switch (cfg->ep_type) { case USB_DC_EP_CONTROL: if (cfg->ep_mps > USB_MAX_CTRL_MPS) { return -EINVAL; } return 0; case USB_DC_EP_BULK: if (cfg->ep_mps > USB_MAX_FS_BULK_MPS) { return -EINVAL; } break; case USB_DC_EP_INTERRUPT: if (cfg->ep_mps > USB_MAX_FS_INT_MPS) { return -EINVAL; } break; case USB_DC_EP_ISOCHRONOUS: if (cfg->ep_mps > USB_MAX_FS_ISO_MPS) { return -EINVAL; } break; default: LOG_ERR("Unknown endpoint type!"); return -EINVAL; } if (ep_idx & BIT(0)) { if (USB_EP_GET_DIR(cfg->ep_addr) != USB_EP_DIR_IN) { LOG_INF("pre-selected as IN endpoint"); return -1; } } else { if (USB_EP_GET_DIR(cfg->ep_addr) != USB_EP_DIR_OUT) { LOG_INF("pre-selected as OUT endpoint"); return -1; } } return 0; } int usb_dc_ep_configure(const struct usb_dc_ep_cfg_data * const cfg) { uint8_t ep_idx = USB_EP_GET_IDX(cfg->ep_addr); struct usb_ep_ctrl_data *ep_ctrl; struct ep_mem_block *block; uint8_t idx_even; uint8_t idx_odd; if (usb_dc_ep_check_cap(cfg)) { return -EINVAL; } idx_even = get_bdt_idx(cfg->ep_addr, 0); idx_odd = get_bdt_idx(cfg->ep_addr, 1); ep_ctrl = &dev_data.ep_ctrl[ep_idx]; if (ep_idx && (dev_data.ep_ctrl[ep_idx].status.in_enabled || dev_data.ep_ctrl[ep_idx].status.out_enabled)) { LOG_WRN("endpoint already configured"); return -EALREADY; } LOG_DBG("ep %x, mps %d, type %d", cfg->ep_addr, cfg->ep_mps, cfg->ep_type); if (USB_EP_DIR_IS_OUT(cfg->ep_addr)) { block = &(ep_ctrl->mblock_out); } else { block = &(ep_ctrl->mblock_in); } if (bdt[idx_even].buf_addr) { k_heap_free(&ep_buf_pool, block->data); } USB0->ENDPOINT[ep_idx].ENDPT = 0; (void)memset(&bdt[idx_even], 0, sizeof(struct buf_descriptor)); (void)memset(&bdt[idx_odd], 0, sizeof(struct buf_descriptor)); block->data = k_heap_alloc(&ep_buf_pool, cfg->ep_mps * 2U, K_NO_WAIT); if (block->data != NULL) { (void)memset(block->data, 0, cfg->ep_mps * 2U); } else { LOG_ERR("Memory allocation time-out"); return -ENOMEM; } bdt[idx_even].buf_addr = (uint32_t)block->data; LOG_INF("idx_even %x", (uint32_t)block->data); bdt[idx_odd].buf_addr = (uint32_t)((uint8_t *)block->data + cfg->ep_mps); LOG_INF("idx_odd %x", (uint32_t)((uint8_t *)block->data + cfg->ep_mps)); if (cfg->ep_addr & USB_EP_DIR_IN) { dev_data.ep_ctrl[ep_idx].mps_in = cfg->ep_mps; } else { dev_data.ep_ctrl[ep_idx].mps_out = cfg->ep_mps; } bdt[idx_even].set.bc = cfg->ep_mps; bdt[idx_odd].set.bc = cfg->ep_mps; dev_data.ep_ctrl[ep_idx].status.out_data1 = false; dev_data.ep_ctrl[ep_idx].status.in_data1 = false; switch (cfg->ep_type) { case USB_DC_EP_CONTROL: LOG_DBG("configure control endpoint"); USB0->ENDPOINT[ep_idx].ENDPT |= (USB_ENDPT_EPHSHK_MASK | USB_ENDPT_EPRXEN_MASK | USB_ENDPT_EPTXEN_MASK); break; case USB_DC_EP_BULK: case USB_DC_EP_INTERRUPT: USB0->ENDPOINT[ep_idx].ENDPT |= USB_ENDPT_EPHSHK_MASK; if (USB_EP_DIR_IS_OUT(cfg->ep_addr)) { USB0->ENDPOINT[ep_idx].ENDPT |= USB_ENDPT_EPRXEN_MASK; } else { USB0->ENDPOINT[ep_idx].ENDPT |= USB_ENDPT_EPTXEN_MASK; } break; case USB_DC_EP_ISOCHRONOUS: if (USB_EP_DIR_IS_OUT(cfg->ep_addr)) { USB0->ENDPOINT[ep_idx].ENDPT |= USB_ENDPT_EPRXEN_MASK; } else { USB0->ENDPOINT[ep_idx].ENDPT |= USB_ENDPT_EPTXEN_MASK; } break; default: return -EINVAL; } return 0; } int usb_dc_ep_set_stall(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint8_t bd_idx; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } LOG_DBG("ep %x, idx %d", ep, ep_idx); if (USB_EP_DIR_IS_OUT(ep)) { dev_data.ep_ctrl[ep_idx].status.out_stalled = 1U; bd_idx = get_bdt_idx(ep, ~dev_data.ep_ctrl[ep_idx].status.out_odd); } else { dev_data.ep_ctrl[ep_idx].status.in_stalled = 1U; bd_idx = get_bdt_idx(ep, dev_data.ep_ctrl[ep_idx].status.in_odd); } bdt[bd_idx].set.bd_ctrl = BD_STALL_MASK | BD_DTS_MASK | BD_OWN_MASK; return 0; } int usb_dc_ep_clear_stall(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint8_t bd_idx; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } LOG_DBG("ep %x, idx %d", ep, ep_idx); USB0->ENDPOINT[ep_idx].ENDPT &= ~USB_ENDPT_EPSTALL_MASK; if (USB_EP_DIR_IS_OUT(ep)) { dev_data.ep_ctrl[ep_idx].status.out_stalled = 0U; dev_data.ep_ctrl[ep_idx].status.out_data1 = false; bd_idx = get_bdt_idx(ep, ~dev_data.ep_ctrl[ep_idx].status.out_odd); bdt[bd_idx].set.bd_ctrl = 0U; bdt[bd_idx].set.bd_ctrl = BD_DTS_MASK | BD_OWN_MASK; } else { dev_data.ep_ctrl[ep_idx].status.in_stalled = 0U; dev_data.ep_ctrl[ep_idx].status.in_data1 = false; bd_idx = get_bdt_idx(ep, dev_data.ep_ctrl[ep_idx].status.in_odd); bdt[bd_idx].set.bd_ctrl = 0U; } /* Resume TX token processing, see USBx_CTL field descriptions */ if (ep == 0U) { USB0->CTL &= ~USB_CTL_TXSUSPENDTOKENBUSY_MASK; } return 0; } int usb_dc_ep_is_stalled(const uint8_t ep, uint8_t *const stalled) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } LOG_DBG("ep %x, idx %d", ep_idx, ep); if (!stalled) { return -EINVAL; } *stalled = 0U; if (USB_EP_DIR_IS_OUT(ep)) { *stalled = dev_data.ep_ctrl[ep_idx].status.out_stalled; } else { *stalled = dev_data.ep_ctrl[ep_idx].status.in_stalled; } uint8_t bd_idx = get_bdt_idx(ep, dev_data.ep_ctrl[ep_idx].status.in_odd); LOG_WRN("active bd ctrl: %x", bdt[bd_idx].set.bd_ctrl); bd_idx = get_bdt_idx(ep, ~dev_data.ep_ctrl[ep_idx].status.in_odd); LOG_WRN("next bd ctrl: %x", bdt[bd_idx].set.bd_ctrl); return 0; } int usb_dc_ep_halt(const uint8_t ep) { return usb_dc_ep_set_stall(ep); } int usb_dc_ep_enable(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint8_t idx_even; uint8_t idx_odd; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } idx_even = get_bdt_idx(ep, 0); idx_odd = get_bdt_idx(ep, 1); if (ep_idx && (dev_data.ep_ctrl[ep_idx].status.in_enabled || dev_data.ep_ctrl[ep_idx].status.out_enabled)) { LOG_WRN("endpoint 0x%x already enabled", ep); return -EALREADY; } if (USB_EP_DIR_IS_OUT(ep)) { bdt[idx_even].set.bd_ctrl = BD_DTS_MASK | BD_OWN_MASK; bdt[idx_odd].set.bd_ctrl = 0U; dev_data.ep_ctrl[ep_idx].status.out_odd = 0U; dev_data.ep_ctrl[ep_idx].status.out_stalled = 0U; dev_data.ep_ctrl[ep_idx].status.out_data1 = false; dev_data.ep_ctrl[ep_idx].status.out_enabled = true; } else { bdt[idx_even].bd_fields = 0U; bdt[idx_odd].bd_fields = 0U; dev_data.ep_ctrl[ep_idx].status.in_odd = 0U; dev_data.ep_ctrl[ep_idx].status.in_stalled = 0U; dev_data.ep_ctrl[ep_idx].status.in_data1 = false; dev_data.ep_ctrl[ep_idx].status.in_enabled = true; } LOG_INF("ep 0x%x, ep_idx %d", ep, ep_idx); return 0; } int usb_dc_ep_disable(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint8_t idx_even; uint8_t idx_odd; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } idx_even = get_bdt_idx(ep, 0); idx_odd = get_bdt_idx(ep, 1); LOG_INF("ep %x, idx %d", ep_idx, ep); bdt[idx_even].bd_fields = 0U; bdt[idx_odd].bd_fields = 0U; if (USB_EP_DIR_IS_OUT(ep)) { dev_data.ep_ctrl[ep_idx].status.out_enabled = false; } else { dev_data.ep_ctrl[ep_idx].status.in_enabled = false; } return 0; } int usb_dc_ep_flush(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } LOG_DBG("ep %x, idx %d", ep_idx, ep); return 0; } int usb_dc_ep_write(const uint8_t ep, const uint8_t *const data, const uint32_t data_len, uint32_t * const ret_bytes) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint32_t len_to_send = data_len; uint8_t odd; uint8_t bd_idx; uint8_t *bufp; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } odd = dev_data.ep_ctrl[ep_idx].status.in_odd; bd_idx = get_bdt_idx(ep, odd); bufp = (uint8_t *)bdt[bd_idx].buf_addr; if (USB_EP_GET_DIR(ep) != USB_EP_DIR_IN) { LOG_ERR("Wrong endpoint direction"); return -EINVAL; } if (dev_data.ep_ctrl[ep_idx].status.in_stalled) { LOG_WRN("endpoint is stalled"); return -EBUSY; } while (bdt[bd_idx].get.own) { LOG_DBG("ep 0x%x is busy", ep); k_yield(); } LOG_DBG("bd idx %x bufp %p odd %d", bd_idx, bufp, odd); if (data_len > dev_data.ep_ctrl[ep_idx].mps_in) { len_to_send = dev_data.ep_ctrl[ep_idx].mps_in; } bdt[bd_idx].set.bc = len_to_send; for (uint32_t n = 0; n < len_to_send; n++) { bufp[n] = data[n]; } dev_data.ep_ctrl[ep_idx].status.in_odd = ~odd; if (dev_data.ep_ctrl[ep_idx].status.in_data1) { bdt[bd_idx].set.bd_ctrl = BD_DTS_MASK | BD_DATA01_MASK | BD_OWN_MASK; } else { bdt[bd_idx].set.bd_ctrl = BD_DTS_MASK | BD_OWN_MASK; } /* Toggle next Data1 */ dev_data.ep_ctrl[ep_idx].status.in_data1 ^= 1; LOG_DBG("ep 0x%x write %d bytes from %d", ep, len_to_send, data_len); if (ret_bytes) { *ret_bytes = len_to_send; } return 0; } int usb_dc_ep_read_wait(uint8_t ep, uint8_t *data, uint32_t max_data_len, uint32_t *read_bytes) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint32_t data_len; uint8_t bd_idx; uint8_t *bufp; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } /* select the index of active endpoint buffer */ bd_idx = get_bdt_idx(ep, dev_data.ep_ctrl[ep_idx].status.out_odd); bufp = (uint8_t *)bdt[bd_idx].buf_addr; if (USB_EP_GET_DIR(ep) != USB_EP_DIR_OUT) { LOG_ERR("Wrong endpoint direction"); return -EINVAL; } if (dev_data.ep_ctrl[ep_idx].status.out_stalled) { LOG_WRN("endpoint is stalled"); return -EBUSY; } /* Allow to read 0 bytes */ if (!data && max_data_len) { LOG_ERR("Wrong arguments"); return -EINVAL; } while (bdt[bd_idx].get.own) { LOG_ERR("Endpoint is occupied by the controller"); return -EBUSY; } data_len = bdt[bd_idx].get.bc; if (!data && !max_data_len) { /* * When both buffer and max data to read are zero return * the available data in buffer. */ if (read_bytes) { *read_bytes = data_len; } return 0; } if (data_len > max_data_len) { LOG_WRN("Not enough room to copy all the data!"); data_len = max_data_len; } if (data != NULL) { for (uint32_t i = 0; i < data_len; i++) { data[i] = bufp[i]; } } LOG_DBG("Read idx %d, req %d, read %d bytes", bd_idx, max_data_len, data_len); if (read_bytes) { *read_bytes = data_len; } return 0; } int usb_dc_ep_read_continue(uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); uint8_t bd_idx; if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } bd_idx = get_bdt_idx(ep, dev_data.ep_ctrl[ep_idx].status.out_odd); if (USB_EP_GET_DIR(ep) != USB_EP_DIR_OUT) { LOG_ERR("Wrong endpoint direction"); return -EINVAL; } if (bdt[bd_idx].get.own) { /* May occur when usb_transfer initializes the OUT transfer */ LOG_WRN("Current buffer is claimed by the controller"); return 0; } /* select the index of the next endpoint buffer */ bd_idx = get_bdt_idx(ep, ~dev_data.ep_ctrl[ep_idx].status.out_odd); /* Update next toggle bit */ dev_data.ep_ctrl[ep_idx].status.out_data1 ^= 1; bdt[bd_idx].set.bc = dev_data.ep_ctrl[ep_idx].mps_out; /* Reset next buffer descriptor and set next toggle bit */ if (dev_data.ep_ctrl[ep_idx].status.out_data1) { bdt[bd_idx].set.bd_ctrl = BD_DTS_MASK | BD_DATA01_MASK | BD_OWN_MASK; } else { bdt[bd_idx].set.bd_ctrl = BD_DTS_MASK | BD_OWN_MASK; } /* Resume TX token processing, see USBx_CTL field descriptions */ if (ep_idx == 0U) { USB0->CTL &= ~USB_CTL_TXSUSPENDTOKENBUSY_MASK; } LOG_DBG("idx next %x", bd_idx); return 0; } int usb_dc_ep_read(const uint8_t ep, uint8_t *const data, const uint32_t max_data_len, uint32_t *const read_bytes) { int retval = usb_dc_ep_read_wait(ep, data, max_data_len, read_bytes); if (retval) { return retval; } if (!data && !max_data_len) { /* When both buffer and max data to read are zero the above * call would fetch the data len and we simply return. */ return 0; } if (usb_dc_ep_read_continue(ep) != 0) { return -EINVAL; } LOG_DBG(""); return 0; } int usb_dc_ep_set_callback(const uint8_t ep, const usb_dc_ep_callback cb) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } if (!dev_data.attached) { return -EINVAL; } if (ep & USB_EP_DIR_IN) { dev_data.ep_ctrl[ep_idx].cb_in = cb; } else { dev_data.ep_ctrl[ep_idx].cb_out = cb; } LOG_DBG("ep_idx %x", ep_idx); return 0; } void usb_dc_set_status_callback(const usb_dc_status_callback cb) { LOG_DBG(""); dev_data.status_cb = cb; } int usb_dc_ep_mps(const uint8_t ep) { uint8_t ep_idx = USB_EP_GET_IDX(ep); if (ep_idx > (NUM_OF_EP_MAX - 1)) { LOG_ERR("Wrong endpoint index/address"); return -EINVAL; } if (ep & USB_EP_DIR_IN) { return dev_data.ep_ctrl[ep_idx].mps_in; } else { return dev_data.ep_ctrl[ep_idx].mps_out; } } static inline void reenable_control_endpoints(void) { struct usb_dc_ep_cfg_data ep_cfg; /* Reconfigure control endpoint 0 after a reset */ ep_cfg.ep_addr = USB_CONTROL_EP_OUT; ep_cfg.ep_mps = USB_CONTROL_EP_MPS; ep_cfg.ep_type = USB_DC_EP_CONTROL; usb_dc_ep_configure(&ep_cfg); ep_cfg.ep_addr = USB_CONTROL_EP_IN; usb_dc_ep_configure(&ep_cfg); /* Enable both endpoint directions */ usb_dc_ep_enable(USB_CONTROL_EP_OUT); usb_dc_ep_enable(USB_CONTROL_EP_IN); } static void usb_kinetis_isr_handler(void) { uint8_t istatus = USB0->ISTAT; uint8_t status = USB0->STAT; struct cb_msg msg; if (istatus & USB_ISTAT_USBRST_MASK) { dev_data.address = 0U; USB0->ADDR = (uint8_t)0; /* * Device reset is not possible because the stack does not * configure the endpoints after the USB_DC_RESET event, * therefore, we must re-enable the default control 0 endpoint * after a reset event */ USB0->CTL |= USB_CTL_ODDRST_MASK; USB0->CTL &= ~USB_CTL_ODDRST_MASK; reenable_control_endpoints(); msg.ep = 0U; msg.type = USB_DC_CB_TYPE_MGMT; msg.cb = USB_DC_RESET; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); } if (istatus == USB_ISTAT_ERROR_MASK) { USB0->ERRSTAT = 0xFF; msg.ep = 0U; msg.type = USB_DC_CB_TYPE_MGMT; msg.cb = USB_DC_ERROR; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); } if (istatus & USB_ISTAT_STALL_MASK) { if (dev_data.ep_ctrl[0].status.out_stalled) { usb_dc_ep_clear_stall(0); } if (dev_data.ep_ctrl[0].status.in_stalled) { usb_dc_ep_clear_stall(0x80); } } if (istatus & USB_ISTAT_TOKDNE_MASK) { uint8_t ep_idx = status >> USB_STAT_ENDP_SHIFT; uint8_t ep = ((status << 4) & USB_EP_DIR_IN) | ep_idx; uint8_t odd = (status & USB_STAT_ODD_MASK) >> USB_STAT_ODD_SHIFT; uint8_t idx = get_bdt_idx(ep, odd); uint8_t token_pid = bdt[idx].get.tok_pid; msg.ep = ep; msg.type = USB_DC_CB_TYPE_EP; switch (token_pid) { case KINETIS_SETUP_TOKEN: dev_data.ep_ctrl[ep_idx].status.out_odd = odd; /* clear tx entries */ bdt[BD_IDX_EP0TX_EVEN].bd_fields = 0U; bdt[BD_IDX_EP0TX_ODD].bd_fields = 0U; /* * Set/Reset here the toggle bits for control endpoint * because the device stack does not care about it. */ dev_data.ep_ctrl[ep_idx].status.in_data1 = true; dev_data.ep_ctrl[ep_idx].status.out_data1 = false; dev_data.ep_ctrl[ep_idx].status.out_odd = odd; msg.cb = USB_DC_EP_SETUP; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); break; case KINETIS_OUT_TOKEN: dev_data.ep_ctrl[ep_idx].status.out_odd = odd; msg.cb = USB_DC_EP_DATA_OUT; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); break; case KINETIS_IN_TOKEN: /* SET ADDRESS workaround */ if (dev_data.address & 0x80) { USB0->ADDR = dev_data.address & 0x7f; dev_data.address = 0U; } msg.cb = USB_DC_EP_DATA_IN; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); break; default: break; } } if (istatus & USB_ISTAT_SLEEP_MASK) { /* Enable resume interrupt */ USB0->INTEN |= USB_INTEN_RESUMEEN_MASK; msg.ep = 0U; msg.type = USB_DC_CB_TYPE_MGMT; msg.cb = USB_DC_SUSPEND; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); } if (istatus & USB_ISTAT_RESUME_MASK) { /* Disable resume interrupt */ USB0->INTEN &= ~USB_INTEN_RESUMEEN_MASK; msg.ep = 0U; msg.type = USB_DC_CB_TYPE_MGMT; msg.cb = USB_DC_RESUME; k_msgq_put(&usb_dc_msgq, &msg, K_NO_WAIT); } /* Clear interrupt status bits */ USB0->ISTAT = istatus; } /* * This thread is only used to not run the USB device stack and endpoint * callbacks in the ISR context, which happens when an callback function * is called. TODO: something similar should be implemented in the USB * device stack so that it can be used by all drivers. */ static void usb_kinetis_thread_main(void *arg1, void *unused1, void *unused2) { ARG_UNUSED(arg1); ARG_UNUSED(unused1); ARG_UNUSED(unused2); struct cb_msg msg; uint8_t ep_idx; while (true) { k_msgq_get(&usb_dc_msgq, &msg, K_FOREVER); ep_idx = USB_EP_GET_IDX(msg.ep); if (msg.type == USB_DC_CB_TYPE_EP) { switch (msg.cb) { case USB_DC_EP_SETUP: if (dev_data.ep_ctrl[ep_idx].cb_out) { dev_data.ep_ctrl[ep_idx].cb_out(msg.ep, USB_DC_EP_SETUP); } break; case USB_DC_EP_DATA_OUT: if (dev_data.ep_ctrl[ep_idx].cb_out) { dev_data.ep_ctrl[ep_idx].cb_out(msg.ep, USB_DC_EP_DATA_OUT); } break; case USB_DC_EP_DATA_IN: if (dev_data.ep_ctrl[ep_idx].cb_in) { dev_data.ep_ctrl[ep_idx].cb_in(msg.ep, USB_DC_EP_DATA_IN); } break; default: LOG_ERR("unknown msg"); break; } } else if (dev_data.status_cb) { switch (msg.cb) { case USB_DC_RESET: dev_data.status_cb(USB_DC_RESET, NULL); break; case USB_DC_ERROR: dev_data.status_cb(USB_DC_ERROR, NULL); break; case USB_DC_SUSPEND: dev_data.status_cb(USB_DC_SUSPEND, NULL); break; case USB_DC_RESUME: dev_data.status_cb(USB_DC_RESUME, NULL); break; default: LOG_ERR("unknown msg"); break; } } } } static int usb_kinetis_init(void) { (void)memset(bdt, 0, sizeof(bdt)); k_thread_create(&dev_data.thread, dev_data.thread_stack, USBD_THREAD_STACK_SIZE, usb_kinetis_thread_main, NULL, NULL, NULL, K_PRIO_COOP(2), 0, K_NO_WAIT); k_thread_name_set(&dev_data.thread, "usb_kinetis"); IRQ_CONNECT(DT_INST_IRQN(0), DT_INST_IRQ(0, priority), usb_kinetis_isr_handler, 0, 0); irq_enable(DT_INST_IRQN(0)); return 0; } SYS_INIT(usb_kinetis_init, POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE);