/* * The MIT License (MIT) * * Copyright (c) 2020 Peter Lawrence * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. * * This file is part of the TinyUSB stack. */ /* Theory of operation: The NUC505 USBD peripheral has twelve "EP"s, where each is simplex, in addition to dedicated support for the control endpoint (EP0). The non-user endpoints are referred to as "user" EPs in this code, and follow the datasheet nomenclature of EPA through EPL. */ #include "tusb_option.h" #if CFG_TUD_ENABLED && (CFG_TUSB_MCU == OPT_MCU_NUC505) #include "device/dcd.h" #include "NUC505Series.h" /* * The DMA functionality of the USBD peripheral does not appear to succeed with * transfer lengths that are longer (> 64 bytes) and are not a multiple of 4. * Keep disabled for now. */ #define USE_DMA 0 /* rather important info unfortunately not provided by device include files */ #define USBD_BUF_SIZE 2048 /* how much USB buffer space there is */ #define USBD_MAX_DMA_LEN 0x1000 /* max bytes that can be DMAed at one time */ enum ep_enum { PERIPH_EPA = 0, PERIPH_EPB = 1, PERIPH_EPC = 2, PERIPH_EPD = 3, PERIPH_EPE = 4, PERIPH_EPF = 5, PERIPH_EPG = 6, PERIPH_EPH = 7, PERIPH_EPI = 8, PERIPH_EPJ = 9, PERIPH_EPK = 10, PERIPH_EPL = 11, PERIPH_MAX_EP, }; static const uint8_t epcfg_eptype_table[] = { [TUSB_XFER_CONTROL] = 0, /* won't happen, since control EPs have dedicated registers */ [TUSB_XFER_ISOCHRONOUS] = 3 << USBD_EPCFG_EPTYPE_Pos, [TUSB_XFER_BULK] = 1 << USBD_EPCFG_EPTYPE_Pos, [TUSB_XFER_INTERRUPT] = 2 << USBD_EPCFG_EPTYPE_Pos, }; static const uint8_t eprspctl_eptype_table[] = { [TUSB_XFER_CONTROL] = 0, /* won't happen, since control EPs have dedicated registers */ [TUSB_XFER_ISOCHRONOUS] = 2 << USBD_EPRSPCTL_MODE_Pos, /* Fly Mode */ [TUSB_XFER_BULK] = 0 << USBD_EPRSPCTL_MODE_Pos, /* Auto-Validate Mode */ [TUSB_XFER_INTERRUPT] = 1 << USBD_EPRSPCTL_MODE_Pos, /* Manual-Validate Mode */ }; /* set by dcd_set_address() */ static volatile uint8_t assigned_address; /* reset by bus_reset(), this is used by dcd_edpt_open() to assign USBD peripheral buffer addresses */ static uint32_t bufseg_addr; /* RAM table needed to track ongoing transfers performed by dcd_edpt_xfer(), dcd_userEP_in_xfer(), and the ISR */ static struct xfer_ctl_t { uint8_t *data_ptr; /* data_ptr tracks where to next copy data to (for OUT) or from (for IN) */ // tu_fifo_t* ff; // TODO support dcd_edpt_xfer_fifo API union { uint16_t in_remaining_bytes; /* for IN endpoints, we track how many bytes are left to transfer */ uint16_t out_bytes_so_far; /* but for OUT endpoints, we track how many bytes we've transferred so far */ }; uint16_t max_packet_size; /* needed since device driver only finds out this at runtime */ uint16_t total_bytes; /* quantity needed to pass as argument to dcd_event_xfer_complete() (for IN endpoints) */ uint8_t ep_addr; bool dma_requested; } xfer_table[PERIPH_MAX_EP]; /* in addition to xfer_table, additional bespoke bookkeeping is maintained for control EP0 IN */ static struct { uint8_t *data_ptr; uint16_t in_remaining_bytes; uint16_t total_bytes; } ctrl_in_xfer; static volatile struct xfer_ctl_t *current_dma_xfer; /* local helper functions */ static void usb_attach(void) { USBD->PHYCTL |= USBD_PHYCTL_DPPUEN_Msk; } static void usb_detach(void) { USBD->PHYCTL &= ~USBD_PHYCTL_DPPUEN_Msk; } static void usb_control_send_zlp(void) { USBD->CEPINTSTS = USBD_CEPINTSTS_STSDONEIF_Msk; USBD->CEPCTL = 0; /* clear NAKCLR bit */ USBD->CEPINTEN = USBD_CEPINTEN_STSDONEIEN_Msk; } /* map 8-bit ep_addr into peripheral endpoint index (PERIPH_EPA...) */ static USBD_EP_T *ep_entry(uint8_t ep_addr, bool add) { USBD_EP_T *ep; enum ep_enum ep_index; struct xfer_ctl_t *xfer; for (ep_index = PERIPH_EPA, xfer = &xfer_table[PERIPH_EPA], ep = USBD->EP; ep_index < PERIPH_MAX_EP; ep_index++, xfer++, ep++) { if (add) { /* take first peripheral endpoint that is unused */ if (0 == (ep->EPCFG & USBD_EPCFG_EPEN_Msk)) return ep; } else { /* find a peripheral endpoint that matches ep_addr */ if (xfer->ep_addr == ep_addr) return ep; } } return NULL; } /* perform a non-control IN endpoint transfer; this is called by the ISR */ static void dcd_userEP_in_xfer(struct xfer_ctl_t *xfer, USBD_EP_T *ep) { uint16_t const bytes_now = tu_min16(xfer->in_remaining_bytes, xfer->max_packet_size); /* precompute what amount of data will be left */ xfer->in_remaining_bytes -= bytes_now; /* if there will be no more data to send, we replace the BUFEMPTYIF EP interrupt with TXPKIF; that way, we alert TinyUSB as soon as this last packet has been sent */ if (0 == xfer->in_remaining_bytes) { ep->EPINTSTS = USBD_EPINTSTS_TXPKIF_Msk; ep->EPINTEN = USBD_EPINTEN_TXPKIEN_Msk; } /* provided buffers are thankfully 32-bit aligned, allowing most data to be transferred as 32-bit */ #if 0 // TODO support dcd_edpt_xfer_fifo API if (xfer->ff) { tu_fifo_read_n_const_addr_full_words(xfer->ff, (void *) (&ep->EPDAT_BYTE), bytes_now); } else #endif { uint16_t countdown = bytes_now; while (countdown > 3) { uint32_t u32; memcpy(&u32, xfer->data_ptr, 4); ep->EPDAT = u32; xfer->data_ptr += 4; countdown -= 4; } while (countdown--) ep->EPDAT_BYTE = *xfer->data_ptr++; } /* for short packets, we must nudge the peripheral to say 'that's all folks' */ if (bytes_now != xfer->max_packet_size) ep->EPRSPCTL = USBD_EPRSPCTL_SHORTTXEN_Msk; } /* called by dcd_init() as well as by the ISR during a USB bus reset */ static void bus_reset(void) { for (enum ep_enum ep_index = PERIPH_EPA; ep_index < PERIPH_MAX_EP; ep_index++) { USBD->EP[ep_index].EPCFG = 0; xfer_table[ep_index].dma_requested = false; } USBD->DMACNT = 0; USBD->DMACTL = USBD_DMACTL_DMARST_Msk; USBD->DMACTL = 0; /* allocate the default EP0 endpoints */ USBD->CEPBUFSTART = 0; USBD->CEPBUFEND = 0 + CFG_TUD_ENDPOINT0_SIZE - 1; /* USB RAM beyond what we've allocated above is available to the user */ bufseg_addr = CFG_TUD_ENDPOINT0_SIZE; /* Reset USB device address */ USBD->FADDR = 0; current_dma_xfer = NULL; } #if USE_DMA /* this must only be called by the ISR; it does its best to share the single DMA engine across all user EPs (IN and OUT) */ static void service_dma(void) { if (current_dma_xfer) return; enum ep_enum ep_index; struct xfer_ctl_t *xfer; USBD_EP_T *ep; for (ep_index = PERIPH_EPA, xfer = &xfer_table[PERIPH_EPA], ep = &USBD->EP[PERIPH_EPA]; ep_index < PERIPH_MAX_EP; ep_index++, xfer++, ep++) { uint16_t const available_bytes = ep->EPDATCNT & USBD_EPDATCNT_DATCNT_Msk; if (!xfer->dma_requested || !available_bytes) continue; /* instruct DMA to copy the data from the PC to the previously provided buffer when the bus interrupt DMADONEIEN subsequently fires, the transfer will have finished */ USBD->DMACTL = xfer->ep_addr & USBD_DMACTL_EPNUM_Msk; USBD->DMAADDR = (uint32_t)xfer->data_ptr; USBD->DMACNT = available_bytes; USBD->BUSINTSTS = USBD_BUSINTSTS_DMADONEIF_Msk; xfer->out_bytes_so_far += available_bytes; current_dma_xfer = xfer; USBD->DMACTL |= USBD_DMACTL_DMAEN_Msk; return; } } #endif /* centralized location for USBD interrupt enable bit masks */ static const uint32_t enabled_irqs = USBD_GINTEN_USBIEN_Msk | \ USBD_GINTEN_EPAIEN_Msk | USBD_GINTEN_EPBIEN_Msk | USBD_GINTEN_EPCIEN_Msk | USBD_GINTEN_EPDIEN_Msk | USBD_GINTEN_EPEIEN_Msk | USBD_GINTEN_EPFIEN_Msk | \ USBD_GINTEN_EPGIEN_Msk | USBD_GINTEN_EPHIEN_Msk | USBD_GINTEN_EPIIEN_Msk | USBD_GINTEN_EPJIEN_Msk | USBD_GINTEN_EPKIEN_Msk | USBD_GINTEN_EPLIEN_Msk | \ USBD_GINTEN_CEPIEN_Msk; /* NUC505 TinyUSB API driver implementation */ void dcd_init(uint8_t rhport) { (void) rhport; /* configure interrupts in their initial state; BUSINTEN and CEPINTEN will be subsequently and dynamically re-written as needed */ USBD->GINTEN = enabled_irqs; USBD->BUSINTEN = USBD_BUSINTEN_RSTIEN_Msk | USBD_BUSINTEN_VBUSDETIEN_Msk | USBD_BUSINTEN_RESUMEIEN_Msk | USBD_BUSINTEN_DMADONEIEN_Msk; USBD->CEPINTEN = 0; bus_reset(); usb_attach(); } void dcd_int_enable(uint8_t rhport) { (void) rhport; NVIC_EnableIRQ(USBD_IRQn); } void dcd_int_disable(uint8_t rhport) { (void) rhport; NVIC_DisableIRQ(USBD_IRQn); } void dcd_set_address(uint8_t rhport, uint8_t dev_addr) { (void) rhport; usb_control_send_zlp(); /* SET_ADDRESS is the one exception where TinyUSB doesn't use dcd_edpt_xfer() to generate a ZLP */ assigned_address = dev_addr; } void dcd_remote_wakeup(uint8_t rhport) { (void) rhport; USBD->OPER |= USBD_OPER_RESUMEEN_Msk; } bool dcd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const * p_endpoint_desc) { (void) rhport; USBD_EP_T *ep = ep_entry(p_endpoint_desc->bEndpointAddress, true); TU_ASSERT(ep); /* mine the data for the information we need */ int const dir = tu_edpt_dir(p_endpoint_desc->bEndpointAddress); int const size = tu_edpt_packet_size(p_endpoint_desc); tusb_xfer_type_t const type = p_endpoint_desc->bmAttributes.xfer; struct xfer_ctl_t *xfer = &xfer_table[ep - USBD->EP]; /* allocate buffer from USB RAM */ ep->EPBUFSTART = bufseg_addr; bufseg_addr += size; ep->EPBUFEND = bufseg_addr - 1; TU_ASSERT(bufseg_addr <= USBD_BUF_SIZE); ep->EPMPS = size; ep->EPRSPCTL = USB_EP_RSPCTL_FLUSH | eprspctl_eptype_table[type]; /* construct USB Configuration Register value and then write it */ uint32_t cfg = (uint32_t)tu_edpt_number(p_endpoint_desc->bEndpointAddress) << USBD_EPCFG_EPNUM_Pos; if (TUSB_DIR_IN == dir) cfg |= USBD_EPCFG_EPDIR_Msk; cfg |= epcfg_eptype_table[type] | USBD_EPCFG_EPEN_Msk; ep->EPCFG = cfg; /* make a note of the endpoint particulars */ xfer->max_packet_size = size; xfer->ep_addr = p_endpoint_desc->bEndpointAddress; return true; } void dcd_edpt_close_all (uint8_t rhport) { (void) rhport; // TODO implement dcd_edpt_close_all() } bool dcd_edpt_xfer(uint8_t rhport, uint8_t ep_addr, uint8_t *buffer, uint16_t total_bytes) { (void) rhport; if (0x80 == ep_addr) /* control EP0 IN */ { if (total_bytes) { USBD->CEPCTL = USBD_CEPCTL_FLUSH_Msk; ctrl_in_xfer.data_ptr = buffer; ctrl_in_xfer.in_remaining_bytes = total_bytes; ctrl_in_xfer.total_bytes = total_bytes; USBD->CEPINTSTS = USBD_CEPINTSTS_INTKIF_Msk; USBD->CEPINTEN = USBD_CEPINTEN_INTKIEN_Msk; } else { usb_control_send_zlp(); } } else if (0x00 == ep_addr) /* control EP0 OUT */ { if (total_bytes) { /* if TinyUSB is asking for EP0 OUT data, it is almost certainly already in the buffer */ while (total_bytes < USBD->CEPRXCNT); for (int count = 0; count < total_bytes; count++) *buffer++ = USBD->CEPDAT_BYTE; dcd_event_xfer_complete(0, ep_addr, total_bytes, XFER_RESULT_SUCCESS, true); } } else { /* mine the data for the information we need */ tusb_dir_t dir = tu_edpt_dir(ep_addr); USBD_EP_T *ep = ep_entry(ep_addr, false); TU_ASSERT(ep); struct xfer_ctl_t *xfer = &xfer_table[ep - USBD->EP]; /* store away the information we'll needing now and later */ xfer->data_ptr = buffer; // xfer->ff = NULL; // TODO support dcd_edpt_xfer_fifo API xfer->in_remaining_bytes = total_bytes; xfer->total_bytes = total_bytes; if (TUSB_DIR_IN == dir) { ep->EPINTEN = USBD_EPINTEN_BUFEMPTYIEN_Msk; } else { xfer->out_bytes_so_far = 0; ep->EPINTEN = USBD_EPINTEN_RXPKIEN_Msk; } } return true; } #if 0 // TODO support dcd_edpt_xfer_fifo API bool dcd_edpt_xfer_fifo (uint8_t rhport, uint8_t ep_addr, tu_fifo_t * ff, uint16_t total_bytes) { (void) rhport; TU_ASSERT(0x80 != ep_addr && 0x00 != ep_addr); // Must not be used for control stuff /* mine the data for the information we need */ tusb_dir_t dir = tu_edpt_dir(ep_addr); USBD_EP_T *ep = ep_entry(ep_addr, false); struct xfer_ctl_t *xfer = &xfer_table[ep - USBD->EP]; /* store away the information we'll needing now and later */ xfer->data_ptr = NULL; // Indicates a FIFO shall be used xfer->ff = ff; xfer->in_remaining_bytes = total_bytes; xfer->total_bytes = total_bytes; if (TUSB_DIR_IN == dir) { ep->EPINTEN = USBD_EPINTEN_BUFEMPTYIEN_Msk; } else { xfer->out_bytes_so_far = 0; ep->EPINTEN = USBD_EPINTEN_RXPKIEN_Msk; } return true; } #endif void dcd_edpt_stall(uint8_t rhport, uint8_t ep_addr) { (void) rhport; if (tu_edpt_number(ep_addr)) { USBD_EP_T *ep = ep_entry(ep_addr, false); TU_ASSERT(ep, ); ep->EPRSPCTL = (ep->EPRSPCTL & 0xf7) | USBD_EPRSPCTL_HALT_Msk; } else { USBD->CEPCTL = USBD_CEPCTL_STALLEN_Msk; } } void dcd_edpt_clear_stall(uint8_t rhport, uint8_t ep_addr) { (void) rhport; if (tu_edpt_number(ep_addr)) { USBD_EP_T *ep = ep_entry(ep_addr, false); TU_ASSERT(ep, ); ep->EPRSPCTL = USBD_EPRSPCTL_TOGGLE_Msk; } } void dcd_int_handler(uint8_t rhport) { (void) rhport; uint32_t status = USBD->GINTSTS; /* USB interrupt */ if (status & USBD_GINTSTS_USBIF_Msk) { uint32_t bus_state = USBD->BUSINTSTS; if (bus_state & USBD_BUSINTSTS_SOFIF_Msk) { /* Start-Of-Frame event */ dcd_event_bus_signal(0, DCD_EVENT_SOF, true); } if (bus_state & USBD_BUSINTSTS_RSTIF_Msk) { bus_reset(); USBD->CEPINTEN = USBD_CEPINTEN_SETUPPKIEN_Msk; USBD->BUSINTEN = USBD_BUSINTEN_RSTIEN_Msk | USBD_BUSINTEN_RESUMEIEN_Msk | USBD_BUSINTEN_SUSPENDIEN_Msk | USBD_BUSINTEN_DMADONEIEN_Msk; USBD->CEPINTSTS = 0x1ffc; tusb_speed_t speed = (USBD->OPER & USBD_OPER_CURSPD_Msk) ? TUSB_SPEED_HIGH : TUSB_SPEED_FULL; dcd_event_bus_reset(0, speed, true); } if (bus_state & USBD_BUSINTSTS_RESUMEIF_Msk) { USBD->BUSINTEN = USBD_BUSINTEN_RSTIEN_Msk | USBD_BUSINTEN_SUSPENDIEN_Msk | USBD_BUSINTEN_DMADONEIEN_Msk; dcd_event_bus_signal(0, DCD_EVENT_RESUME, true); } if (bus_state & USBD_BUSINTSTS_SUSPENDIF_Msk) { USBD->BUSINTEN = USBD_BUSINTEN_RSTIEN_Msk | USBD_BUSINTEN_RESUMEIEN_Msk | USBD_BUSINTEN_DMADONEIEN_Msk; dcd_event_bus_signal(0, DCD_EVENT_SUSPEND, true); } if (bus_state & USBD_BUSINTSTS_HISPDIF_Msk) { USBD->CEPINTEN = USBD_CEPINTEN_SETUPPKIEN_Msk; } if (bus_state & USBD_BUSINTSTS_DMADONEIF_Msk) { #if USE_DMA if (current_dma_xfer) { current_dma_xfer->dma_requested = false; uint16_t available_bytes = USBD->DMACNT & USBD_DMACNT_DMACNT_Msk; /* if the most recent DMA finishes the transfer, alert TinyUSB; otherwise, the next RXPKIF/INTKIF endpoint interrupt will prompt the next DMA */ if ( (current_dma_xfer->total_bytes == current_dma_xfer->out_bytes_so_far) || (available_bytes < current_dma_xfer->max_packet_size) ) { dcd_event_xfer_complete(0, current_dma_xfer->ep_addr, current_dma_xfer->out_bytes_so_far, XFER_RESULT_SUCCESS, true); } current_dma_xfer = NULL; service_dma(); } #endif } if (bus_state & USBD_BUSINTSTS_VBUSDETIF_Msk) { if (USBD->PHYCTL & USBD_PHYCTL_VBUSDET_Msk) { /* USB connect */ USBD->PHYCTL |= USBD_PHYCTL_PHYEN_Msk | USBD_PHYCTL_DPPUEN_Msk; } else { /* USB disconnect */ USBD->PHYCTL &= ~USBD_PHYCTL_DPPUEN_Msk; } } USBD->BUSINTSTS = bus_state & (USBD_BUSINTSTS_SOFIF_Msk | USBD_BUSINTSTS_RSTIF_Msk | USBD_BUSINTSTS_RESUMEIF_Msk | USBD_BUSINTSTS_SUSPENDIF_Msk | USBD_BUSINTSTS_HISPDIF_Msk | USBD_BUSINTSTS_DMADONEIF_Msk | USBD_BUSINTSTS_PHYCLKVLDIF_Msk | USBD_BUSINTSTS_VBUSDETIF_Msk); } if (status & USBD_GINTSTS_CEPIF_Msk) { uint32_t cep_state = USBD->CEPINTSTS & USBD->CEPINTEN; if (cep_state & USBD_CEPINTSTS_SETUPPKIF_Msk) { /* get SETUP packet from USB buffer */ uint8_t setup_packet[8]; setup_packet[0] = (uint8_t)(USBD->SETUP1_0 >> 0); setup_packet[1] = (uint8_t)(USBD->SETUP1_0 >> 8); setup_packet[2] = (uint8_t)(USBD->SETUP3_2 >> 0); setup_packet[3] = (uint8_t)(USBD->SETUP3_2 >> 8); setup_packet[4] = (uint8_t)(USBD->SETUP5_4 >> 0); setup_packet[5] = (uint8_t)(USBD->SETUP5_4 >> 8); setup_packet[6] = (uint8_t)(USBD->SETUP7_6 >> 0); setup_packet[7] = (uint8_t)(USBD->SETUP7_6 >> 8); dcd_event_setup_received(0, setup_packet, true); } else if (cep_state & USBD_CEPINTSTS_INTKIF_Msk) { USBD->CEPINTSTS = USBD_CEPINTSTS_TXPKIF_Msk; if (!(cep_state & USBD_CEPINTSTS_STSDONEIF_Msk)) { USBD->CEPINTEN = USBD_CEPINTEN_TXPKIEN_Msk; uint16_t bytes_now = tu_min16(ctrl_in_xfer.in_remaining_bytes, CFG_TUD_ENDPOINT0_SIZE); for (int count = 0; count < bytes_now; count++) USBD->CEPDAT_BYTE = *ctrl_in_xfer.data_ptr++; ctrl_in_xfer.in_remaining_bytes -= bytes_now; USBD_START_CEP_IN(bytes_now); } else { USBD->CEPINTEN = USBD_CEPINTEN_TXPKIEN_Msk | USBD_CEPINTEN_STSDONEIEN_Msk; } } else if (cep_state & USBD_CEPINTSTS_TXPKIF_Msk) { USBD->CEPINTSTS = USBD_CEPINTSTS_STSDONEIF_Msk; USBD_SET_CEP_STATE(USB_CEPCTL_NAKCLR); /* alert TinyUSB that the EP0 IN transfer has finished */ if ( (0 == ctrl_in_xfer.in_remaining_bytes) || (0 == ctrl_in_xfer.total_bytes) ) dcd_event_xfer_complete(0, 0x80, ctrl_in_xfer.total_bytes, XFER_RESULT_SUCCESS, true); if (ctrl_in_xfer.in_remaining_bytes) { USBD->CEPINTSTS = USBD_CEPINTSTS_INTKIF_Msk; USBD->CEPINTEN = USBD_CEPINTEN_INTKIEN_Msk; } else { /* TinyUSB does its own fragmentation and ZLP for EP0; a transfer of zero means a ZLP */ if (0 == ctrl_in_xfer.total_bytes) USBD->CEPCTL = USBD_CEPCTL_ZEROLEN_Msk; USBD->CEPINTSTS = USBD_CEPINTSTS_STSDONEIF_Msk; USBD->CEPINTEN = USBD_CEPINTEN_SETUPPKIEN_Msk | USBD_CEPINTEN_STSDONEIEN_Msk; } } else if (cep_state & USBD_CEPINTSTS_STSDONEIF_Msk) { /* given ACK from host has happened, we can now set the address (if not already done) */ if((USBD->FADDR != assigned_address) && (USBD->FADDR == 0)) { USBD->FADDR = assigned_address; for (enum ep_enum ep_index = PERIPH_EPA; ep_index < PERIPH_MAX_EP; ep_index++) { if (USBD->EP[ep_index].EPCFG & USBD_EPCFG_EPEN_Msk) USBD->EP[ep_index].EPRSPCTL = USBD_EPRSPCTL_TOGGLE_Msk; } } USBD->CEPINTEN = USBD_CEPINTEN_SETUPPKIEN_Msk; } USBD->CEPINTSTS = cep_state; return; } if (status & (USBD_GINTSTS_EPAIF_Msk | USBD_GINTSTS_EPBIF_Msk | USBD_GINTSTS_EPCIF_Msk | USBD_GINTSTS_EPDIF_Msk | USBD_GINTSTS_EPEIF_Msk | USBD_GINTSTS_EPFIF_Msk | USBD_GINTSTS_EPGIF_Msk | USBD_GINTSTS_EPHIF_Msk | USBD_GINTSTS_EPIIF_Msk | USBD_GINTSTS_EPJIF_Msk | USBD_GINTSTS_EPKIF_Msk | USBD_GINTSTS_EPLIF_Msk)) { /* service PERIPH_EPA through PERIPH_EPL */ enum ep_enum ep_index; uint32_t mask; struct xfer_ctl_t *xfer; USBD_EP_T *ep; for (ep_index = PERIPH_EPA, mask = USBD_GINTSTS_EPAIF_Msk, xfer = &xfer_table[PERIPH_EPA], ep = &USBD->EP[PERIPH_EPA]; ep_index < PERIPH_MAX_EP; ep_index++, mask <<= 1, xfer++, ep++) { if(status & mask) { uint8_t const ep_addr = xfer->ep_addr; bool const out_ep = !(ep_addr & TUSB_DIR_IN_MASK); uint32_t ep_state = ep->EPINTSTS & ep->EPINTEN; if (out_ep) { #if USE_DMA xfer->dma_requested = true; service_dma(); #else uint16_t const available_bytes = ep->EPDATCNT & USBD_EPDATCNT_DATCNT_Msk; /* copy the data from the PC to the previously provided buffer */ #if 0 // TODO support dcd_edpt_xfer_fifo API if (xfer->ff) { tu_fifo_write_n_const_addr_full_words(xfer->ff, (const void *) &ep->EPDAT_BYTE, tu_min16(available_bytes, xfer->total_bytes - xfer->out_bytes_so_far)); } else #endif { for (int count = 0; (count < available_bytes) && (xfer->out_bytes_so_far < xfer->total_bytes); count++, xfer->out_bytes_so_far++) { *xfer->data_ptr++ = ep->EPDAT_BYTE; } } /* when the transfer is finished, alert TinyUSB; otherwise, continue accepting more data */ if ( (xfer->total_bytes == xfer->out_bytes_so_far) || (available_bytes < xfer->max_packet_size) ) { dcd_event_xfer_complete(0, ep_addr, xfer->out_bytes_so_far, XFER_RESULT_SUCCESS, true); } #endif } else if (ep_state & USBD_EPINTSTS_BUFEMPTYIF_Msk) { /* send any remaining data */ dcd_userEP_in_xfer(xfer, ep); } else if (ep_state & USBD_EPINTSTS_TXPKIF_Msk) { /* alert TinyUSB that we've finished */ dcd_event_xfer_complete(0, ep_addr, xfer->total_bytes, XFER_RESULT_SUCCESS, true); ep->EPINTEN = 0; } ep->EPINTSTS = ep_state; } } } } void dcd_disconnect(uint8_t rhport) { (void) rhport; usb_detach(); } void dcd_connect(uint8_t rhport) { (void) rhport; usb_attach(); } void dcd_sof_enable(uint8_t rhport, bool en) { (void) rhport; (void) en; // TODO implement later } #endif