/* * The MIT License (MIT) * * Copyright (c) 2019 Ha Thach (tinyusb.org) * * 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. */ #include "tusb_option.h" #if CFG_TUD_ENABLED && CFG_TUSB_MCU == OPT_MCU_NRF5X #include #include "nrf.h" #include "nrf_clock.h" #include "nrf_power.h" #include "nrfx_usbd_errata.h" #include "device/dcd.h" // TODO remove later #include "device/usbd.h" #include "device/usbd_pvt.h" // to use defer function helper #if CFG_TUSB_OS == OPT_OS_MYNEWT #include "mcu/mcu.h" #endif /*------------------------------------------------------------------*/ /* MACRO TYPEDEF CONSTANT ENUM *------------------------------------------------------------------*/ enum { // Max allowed by USB specs MAX_PACKET_SIZE = 64, // Mask of all END event (IN & OUT) for all endpoints. ENDEPIN0-7, ENDEPOUT0-7, ENDISOIN, ENDISOOUT EDPT_END_ALL_MASK = (0xff << USBD_INTEN_ENDEPIN0_Pos) | (0xff << USBD_INTEN_ENDEPOUT0_Pos) | USBD_INTENCLR_ENDISOIN_Msk | USBD_INTEN_ENDISOOUT_Msk }; enum { EP_ISO_NUM = 8, // Endpoint number is fixed (8) for ISOOUT and ISOIN EP_CBI_COUNT = 8 // Control Bulk Interrupt endpoints count }; // Transfer Descriptor typedef struct { uint8_t* buffer; uint16_t total_len; volatile uint16_t actual_len; uint16_t mps; // max packet size // nRF will auto accept OUT packet after DMA is done // indicate packet is already ACK volatile bool data_received; volatile bool started; // Set to true when data was transferred from RAM to ISO IN output buffer. // New data can be put in ISO IN output buffer after SOF. bool iso_in_transfer_ready; } xfer_td_t; // Data for managing dcd static struct { // All 8 endpoints including control IN & OUT (offset 1) // +1 for ISO endpoints xfer_td_t xfer[EP_CBI_COUNT + 1][2]; // nRF can only carry one DMA at a time, this is used to guard the access to EasyDMA atomic_bool dma_running; }_dcd; /*------------------------------------------------------------------*/ /* Control / Bulk / Interrupt (CBI) Transfer *------------------------------------------------------------------*/ // NVIC_GetEnableIRQ is only available in CMSIS v5 #ifndef NVIC_GetEnableIRQ static inline uint32_t NVIC_GetEnableIRQ(IRQn_Type IRQn) { if ((int32_t)(IRQn) >= 0) { return((uint32_t)(((NVIC->ISER[(((uint32_t)(int32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)(int32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL)); } else { return(0U); } } #endif // check if we are in ISR TU_ATTR_ALWAYS_INLINE static inline bool is_in_isr(void) { return (SCB->ICSR & SCB_ICSR_VECTACTIVE_Msk) ? true : false; } // helper to start DMA static void start_dma(volatile uint32_t* reg_startep) { (*reg_startep) = 1; __ISB(); __DSB(); // TASKS_EP0STATUS, TASKS_EP0RCVOUT seem to need EasyDMA to be available // However these don't trigger any DMA transfer and got ENDED event subsequently // Therefore dma_pending is corrected right away if ( (reg_startep == &NRF_USBD->TASKS_EP0STATUS) || (reg_startep == &NRF_USBD->TASKS_EP0RCVOUT) ) { atomic_flag_clear(&_dcd.dma_running); } } static void edpt_dma_start(volatile uint32_t* reg_startep) { if ( atomic_flag_test_and_set(&_dcd.dma_running) ) { usbd_defer_func((osal_task_func_t) edpt_dma_start, (void*) (uintptr_t) reg_startep, true); }else { start_dma(reg_startep); } } // DMA is complete static void edpt_dma_end(void) { TU_ASSERT(_dcd.dma_running, ); atomic_flag_clear(&_dcd.dma_running); } // helper getting td static inline xfer_td_t* get_td(uint8_t epnum, uint8_t dir) { return &_dcd.xfer[epnum][dir]; } static void xact_out_dma(uint8_t epnum); // Function wraps xact_out_dma which wants uint8_t while usbd_defer_func wants void (*)(void *) static void xact_out_dma_wrapper(void *epnum) { xact_out_dma((uint8_t)((uintptr_t)epnum)); } // Start DMA to move data from Endpoint -> RAM static void xact_out_dma(uint8_t epnum) { xfer_td_t* xfer = get_td(epnum, TUSB_DIR_OUT); uint32_t xact_len; // DMA can't be active during read of SIZE.EPOUT or SIZE.ISOOUT, so try to lock, // If already running defer call regardless if it was called from ISR or task, if ( atomic_flag_test_and_set(&_dcd.dma_running) ) { usbd_defer_func((osal_task_func_t)xact_out_dma_wrapper, (void *)(uint32_t)epnum, is_in_isr()); return; } if (epnum == EP_ISO_NUM) { xact_len = NRF_USBD->SIZE.ISOOUT; // If ZERO bit is set, ignore ISOOUT length if (xact_len & USBD_SIZE_ISOOUT_ZERO_Msk) { xact_len = 0; atomic_flag_clear(&_dcd.dma_running); } else { // Trigger DMA move data from Endpoint -> SRAM NRF_USBD->ISOOUT.PTR = (uint32_t) xfer->buffer; NRF_USBD->ISOOUT.MAXCNT = xact_len; start_dma(&NRF_USBD->TASKS_STARTISOOUT); } } else { // limit xact len to remaining length xact_len = tu_min16((uint16_t) NRF_USBD->SIZE.EPOUT[epnum], xfer->total_len - xfer->actual_len); // Trigger DMA move data from Endpoint -> SRAM NRF_USBD->EPOUT[epnum].PTR = (uint32_t) xfer->buffer; NRF_USBD->EPOUT[epnum].MAXCNT = xact_len; start_dma(&NRF_USBD->TASKS_STARTEPOUT[epnum]); } } // Prepare for a CBI transaction IN, call at the start // it start DMA to transfer data from RAM -> Endpoint static void xact_in_dma(uint8_t epnum) { xfer_td_t* xfer = get_td(epnum, TUSB_DIR_IN); // Each transaction is up to Max Packet Size uint16_t const xact_len = tu_min16(xfer->total_len - xfer->actual_len, xfer->mps); NRF_USBD->EPIN[epnum].PTR = (uint32_t) xfer->buffer; NRF_USBD->EPIN[epnum].MAXCNT = xact_len; edpt_dma_start(&NRF_USBD->TASKS_STARTEPIN[epnum]); } //--------------------------------------------------------------------+ // Controller API //--------------------------------------------------------------------+ void dcd_init (uint8_t rhport) { TU_LOG1("dcd init\r\n"); (void) rhport; } 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; (void) dev_addr; // Set Address is automatically update by hw controller, nothing to do // Enable usbevent for suspend and resume detection // Since the bus signal D+/D- are stable now. // Clear current pending first NRF_USBD->EVENTCAUSE |= NRF_USBD->EVENTCAUSE; NRF_USBD->EVENTS_USBEVENT = 0; NRF_USBD->INTENSET = USBD_INTEN_USBEVENT_Msk; } void dcd_remote_wakeup(uint8_t rhport) { (void) rhport; // Bring controller out of low power mode // will start wakeup when USBWUALLOWED is set NRF_USBD->LOWPOWER = 0; } // disconnect by disabling internal pull-up resistor on D+/D- void dcd_disconnect(uint8_t rhport) { (void) rhport; NRF_USBD->USBPULLUP = 0; // Disable Pull-up does not trigger Power USB Removed, in fact it have no // impact on the USB Power status at all -> need to submit unplugged event to the stack. dcd_event_bus_signal(0, DCD_EVENT_UNPLUGGED, false); } // connect by enabling internal pull-up resistor on D+/D- void dcd_connect(uint8_t rhport) { (void) rhport; NRF_USBD->USBPULLUP = 1; } void dcd_sof_enable(uint8_t rhport, bool en) { (void) rhport; (void) en; // TODO implement later } //--------------------------------------------------------------------+ // Endpoint API //--------------------------------------------------------------------+ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt) { (void) rhport; uint8_t const ep_addr = desc_edpt->bEndpointAddress; uint8_t const epnum = tu_edpt_number(ep_addr); uint8_t const dir = tu_edpt_dir(ep_addr); _dcd.xfer[epnum][dir].mps = tu_edpt_packet_size(desc_edpt); if (desc_edpt->bmAttributes.xfer != TUSB_XFER_ISOCHRONOUS) { if (dir == TUSB_DIR_OUT) { NRF_USBD->INTENSET = TU_BIT(USBD_INTEN_ENDEPOUT0_Pos + epnum); NRF_USBD->EPOUTEN |= TU_BIT(epnum); // Write any value to SIZE register will allow nRF to ACK/accept data NRF_USBD->SIZE.EPOUT[epnum] = 0; }else { NRF_USBD->INTENSET = TU_BIT(USBD_INTEN_ENDEPIN0_Pos + epnum); NRF_USBD->EPINEN |= TU_BIT(epnum); } } else { TU_ASSERT(epnum == EP_ISO_NUM); if (dir == TUSB_DIR_OUT) { // SPLIT ISO buffer when ISO IN endpoint is already opened. if (_dcd.xfer[EP_ISO_NUM][TUSB_DIR_IN].mps) NRF_USBD->ISOSPLIT = USBD_ISOSPLIT_SPLIT_HalfIN; // Clear old events NRF_USBD->EVENTS_ENDISOOUT = 0; // Clear SOF event in case interrupt was not enabled yet. if ((NRF_USBD->INTEN & USBD_INTEN_SOF_Msk) == 0) NRF_USBD->EVENTS_SOF = 0; // Enable SOF and ISOOUT interrupts, and ISOOUT endpoint. NRF_USBD->INTENSET = USBD_INTENSET_ENDISOOUT_Msk | USBD_INTENSET_SOF_Msk; NRF_USBD->EPOUTEN |= USBD_EPOUTEN_ISOOUT_Msk; } else { NRF_USBD->EVENTS_ENDISOIN = 0; // SPLIT ISO buffer when ISO OUT endpoint is already opened. if (_dcd.xfer[EP_ISO_NUM][TUSB_DIR_OUT].mps) NRF_USBD->ISOSPLIT = USBD_ISOSPLIT_SPLIT_HalfIN; // Clear SOF event in case interrupt was not enabled yet. if ((NRF_USBD->INTEN & USBD_INTEN_SOF_Msk) == 0) NRF_USBD->EVENTS_SOF = 0; // Enable SOF and ISOIN interrupts, and ISOIN endpoint. NRF_USBD->INTENSET = USBD_INTENSET_ENDISOIN_Msk | USBD_INTENSET_SOF_Msk; NRF_USBD->EPINEN |= USBD_EPINEN_ISOIN_Msk; } } // clear stall and reset DataToggle NRF_USBD->EPSTALL = (USBD_EPSTALL_STALL_UnStall << USBD_EPSTALL_STALL_Pos) | ep_addr; NRF_USBD->DTOGGLE = (USBD_DTOGGLE_VALUE_Data0 << USBD_DTOGGLE_VALUE_Pos) | ep_addr; __ISB(); __DSB(); return true; } void dcd_edpt_close_all (uint8_t rhport) { // disable interrupt to prevent race condition dcd_int_disable(rhport); // disable all non-control (bulk + interrupt) endpoints for ( uint8_t ep = 1; ep < EP_CBI_COUNT; ep++ ) { NRF_USBD->INTENCLR = TU_BIT(USBD_INTEN_ENDEPOUT0_Pos + ep) | TU_BIT(USBD_INTEN_ENDEPIN0_Pos + ep); NRF_USBD->TASKS_STARTEPIN[ep] = 0; NRF_USBD->TASKS_STARTEPOUT[ep] = 0; tu_memclr(_dcd.xfer[ep], 2*sizeof(xfer_td_t)); } // disable both ISO NRF_USBD->INTENCLR = USBD_INTENCLR_SOF_Msk | USBD_INTENCLR_ENDISOOUT_Msk | USBD_INTENCLR_ENDISOIN_Msk; NRF_USBD->ISOSPLIT = USBD_ISOSPLIT_SPLIT_OneDir; NRF_USBD->TASKS_STARTISOIN = 0; NRF_USBD->TASKS_STARTISOOUT = 0; tu_memclr(_dcd.xfer[EP_ISO_NUM], 2*sizeof(xfer_td_t)); // de-activate all non-control NRF_USBD->EPOUTEN = 1UL; NRF_USBD->EPINEN = 1UL; dcd_int_enable(rhport); } void dcd_edpt_close (uint8_t rhport, uint8_t ep_addr) { (void) rhport; uint8_t const epnum = tu_edpt_number(ep_addr); uint8_t const dir = tu_edpt_dir(ep_addr); if (epnum != EP_ISO_NUM) { // CBI if (dir == TUSB_DIR_OUT) { NRF_USBD->INTENCLR = TU_BIT(USBD_INTEN_ENDEPOUT0_Pos + epnum); NRF_USBD->EPOUTEN &= ~TU_BIT(epnum); } else { NRF_USBD->INTENCLR = TU_BIT(USBD_INTEN_ENDEPIN0_Pos + epnum); NRF_USBD->EPINEN &= ~TU_BIT(epnum); } } else { _dcd.xfer[EP_ISO_NUM][dir].mps = 0; // ISO if (dir == TUSB_DIR_OUT) { NRF_USBD->INTENCLR = USBD_INTENCLR_ENDISOOUT_Msk; NRF_USBD->EPOUTEN &= ~USBD_EPOUTEN_ISOOUT_Msk; NRF_USBD->EVENTS_ENDISOOUT = 0; } else { NRF_USBD->INTENCLR = USBD_INTENCLR_ENDISOIN_Msk; NRF_USBD->EPINEN &= ~USBD_EPINEN_ISOIN_Msk; } // One of the ISO endpoints closed, no need to split buffers any more. NRF_USBD->ISOSPLIT = USBD_ISOSPLIT_SPLIT_OneDir; // When both ISO endpoint are close there is no need for SOF any more. if (_dcd.xfer[EP_ISO_NUM][TUSB_DIR_IN].mps + _dcd.xfer[EP_ISO_NUM][TUSB_DIR_OUT].mps == 0) NRF_USBD->INTENCLR = USBD_INTENCLR_SOF_Msk; } _dcd.xfer[epnum][dir].started = false; __ISB(); __DSB(); } bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes) { (void) rhport; uint8_t const epnum = tu_edpt_number(ep_addr); uint8_t const dir = tu_edpt_dir(ep_addr); xfer_td_t* xfer = get_td(epnum, dir); TU_ASSERT(!xfer->started); xfer->buffer = buffer; xfer->total_len = total_bytes; xfer->actual_len = 0; // Control endpoint with zero-length packet and opposite direction to 1st request byte --> status stage bool const control_status = (epnum == 0 && total_bytes == 0 && dir != tu_edpt_dir(NRF_USBD->BMREQUESTTYPE)); if ( control_status ) { // Status Phase also requires EasyDMA has to be available as well !!!! edpt_dma_start(&NRF_USBD->TASKS_EP0STATUS); // The nRF doesn't interrupt on status transmit so we queue up a success response. dcd_event_xfer_complete(0, ep_addr, 0, XFER_RESULT_SUCCESS, is_in_isr()); } else if ( dir == TUSB_DIR_OUT ) { xfer->started = true; if ( epnum == 0 ) { // Accept next Control Out packet. TASKS_EP0RCVOUT also require EasyDMA edpt_dma_start(&NRF_USBD->TASKS_EP0RCVOUT); }else { // started just set, it could start DMA transfer if interrupt was trigger after this line // code only needs to start transfer (from Endpoint to RAM) when data_received was set // before started was set. If started is NOT set but data_received is, it means that // current transfer was already finished and next data is already present in endpoint and // can be consumed by future transfer __ISB(); __DSB(); if ( xfer->data_received && xfer->started ) { // Data is already received previously // start DMA to copy to SRAM xfer->data_received = false; xact_out_dma(epnum); } else { // nRF auto accept next Bulk/Interrupt OUT packet // nothing to do } } } else { // Start DMA to copy data from RAM -> Endpoint xact_in_dma(epnum); } return true; } void dcd_edpt_stall (uint8_t rhport, uint8_t ep_addr) { (void) rhport; uint8_t const epnum = tu_edpt_number(ep_addr); uint8_t const dir = tu_edpt_dir(ep_addr); xfer_td_t* xfer = get_td(epnum, dir); if ( epnum == 0 ) { NRF_USBD->TASKS_EP0STALL = 1; }else if (epnum != EP_ISO_NUM) { NRF_USBD->EPSTALL = (USBD_EPSTALL_STALL_Stall << USBD_EPSTALL_STALL_Pos) | ep_addr; // Note: nRF can auto ACK packet OUT before get stalled. // There maybe data in endpoint fifo already, we need to pull it out if ( (dir == TUSB_DIR_OUT) && xfer->data_received ) { xfer->data_received = false; xact_out_dma(epnum); } } __ISB(); __DSB(); } void dcd_edpt_clear_stall (uint8_t rhport, uint8_t ep_addr) { (void) rhport; uint8_t const epnum = tu_edpt_number(ep_addr); uint8_t const dir = tu_edpt_dir(ep_addr); if ( epnum != 0 && epnum != EP_ISO_NUM ) { // reset data toggle to DATA0 // First write this register with VALUE=Nop to select the endpoint, then either read it to get the status from // VALUE, or write it again with VALUE=Data0 or Data1 NRF_USBD->DTOGGLE = ep_addr; NRF_USBD->DTOGGLE = (USBD_DTOGGLE_VALUE_Data0 << USBD_DTOGGLE_VALUE_Pos) | ep_addr; // clear stall NRF_USBD->EPSTALL = (USBD_EPSTALL_STALL_UnStall << USBD_EPSTALL_STALL_Pos) | ep_addr; // Write any value to SIZE register will allow nRF to ACK/accept data if (dir == TUSB_DIR_OUT) NRF_USBD->SIZE.EPOUT[epnum] = 0; __ISB(); __DSB(); } } /*------------------------------------------------------------------*/ /* Interrupt Handler *------------------------------------------------------------------*/ void bus_reset(void) { // 6.35.6 USB controller automatically disabled all endpoints (except control) NRF_USBD->EPOUTEN = 1UL; NRF_USBD->EPINEN = 1UL; for(int i=0; i<8; i++) { NRF_USBD->TASKS_STARTEPIN[i] = 0; NRF_USBD->TASKS_STARTEPOUT[i] = 0; } NRF_USBD->TASKS_STARTISOIN = 0; NRF_USBD->TASKS_STARTISOOUT = 0; // Clear USB Event Interrupt NRF_USBD->EVENTS_USBEVENT = 0; NRF_USBD->EVENTCAUSE |= NRF_USBD->EVENTCAUSE; // Reset interrupt NRF_USBD->INTENCLR = NRF_USBD->INTEN; NRF_USBD->INTENSET = USBD_INTEN_USBRESET_Msk | USBD_INTEN_USBEVENT_Msk | USBD_INTEN_EPDATA_Msk | USBD_INTEN_EP0SETUP_Msk | USBD_INTEN_EP0DATADONE_Msk | USBD_INTEN_ENDEPIN0_Msk | USBD_INTEN_ENDEPOUT0_Msk; tu_varclr(&_dcd); _dcd.xfer[0][TUSB_DIR_IN].mps = MAX_PACKET_SIZE; _dcd.xfer[0][TUSB_DIR_OUT].mps = MAX_PACKET_SIZE; } void dcd_int_handler(uint8_t rhport) { (void) rhport; uint32_t const inten = NRF_USBD->INTEN; uint32_t int_status = 0; volatile uint32_t* regevt = &NRF_USBD->EVENTS_USBRESET; for(uint8_t i=0; iactual_len = NRF_USBD->ISOIN.AMOUNT; // Data transferred from RAM to endpoint output buffer. // Next transfer can be scheduled after SOF. xfer->iso_in_transfer_ready = true; } if ( int_status & USBD_INTEN_SOF_Msk ) { bool iso_enabled = false; // ISOOUT: Transfer data gathered in previous frame from buffer to RAM if (NRF_USBD->EPOUTEN & USBD_EPOUTEN_ISOOUT_Msk) { iso_enabled = true; xact_out_dma(EP_ISO_NUM); } // ISOIN: Notify client that data was transferred if (NRF_USBD->EPINEN & USBD_EPINEN_ISOIN_Msk) { iso_enabled = true; xfer_td_t* xfer = get_td(EP_ISO_NUM, TUSB_DIR_IN); if ( xfer->iso_in_transfer_ready ) { xfer->iso_in_transfer_ready = false; dcd_event_xfer_complete(0, EP_ISO_NUM | TUSB_DIR_IN_MASK, xfer->actual_len, XFER_RESULT_SUCCESS, true); } } if ( !iso_enabled ) { // ISO endpoint is not used, SOF is only enabled one-time for remote wakeup // so we disable it now NRF_USBD->INTENCLR = USBD_INTENSET_SOF_Msk; } dcd_event_bus_signal(0, DCD_EVENT_SOF, true); } if ( int_status & USBD_INTEN_USBEVENT_Msk ) { TU_LOG(2, "EVENTCAUSE = 0x%04lX\r\n", NRF_USBD->EVENTCAUSE); enum { EVT_CAUSE_MASK = USBD_EVENTCAUSE_SUSPEND_Msk | USBD_EVENTCAUSE_RESUME_Msk | USBD_EVENTCAUSE_USBWUALLOWED_Msk }; uint32_t const evt_cause = NRF_USBD->EVENTCAUSE & EVT_CAUSE_MASK; NRF_USBD->EVENTCAUSE = evt_cause; // clear interrupt if ( evt_cause & USBD_EVENTCAUSE_SUSPEND_Msk ) { // Put controller into low power mode // Leave HFXO disable to application, since it may be used by other peripherals NRF_USBD->LOWPOWER = 1; dcd_event_bus_signal(0, DCD_EVENT_SUSPEND, true); } if ( evt_cause & USBD_EVENTCAUSE_USBWUALLOWED_Msk ) { // USB is out of low power mode, and wakeup is allowed // Initiate RESUME signal NRF_USBD->DPDMVALUE = USBD_DPDMVALUE_STATE_Resume; NRF_USBD->TASKS_DPDMDRIVE = 1; // There is no Resume interrupt for remote wakeup, enable SOF for to report bus ready state // Clear SOF event in case interrupt was not enabled yet. if ((NRF_USBD->INTEN & USBD_INTEN_SOF_Msk) == 0) NRF_USBD->EVENTS_SOF = 0; NRF_USBD->INTENSET = USBD_INTENSET_SOF_Msk; } if ( evt_cause & USBD_EVENTCAUSE_RESUME_Msk ) { dcd_event_bus_signal(0, DCD_EVENT_RESUME, true); } } // Setup tokens are specific to the Control endpoint. if ( int_status & USBD_INTEN_EP0SETUP_Msk ) { uint8_t const setup[8] = { NRF_USBD->BMREQUESTTYPE , NRF_USBD->BREQUEST, NRF_USBD->WVALUEL , NRF_USBD->WVALUEH, NRF_USBD->WINDEXL , NRF_USBD->WINDEXH , NRF_USBD->WLENGTHL, NRF_USBD->WLENGTHH }; // nrf5x hw auto handle set address, there is no need to inform usb stack tusb_control_request_t const * request = (tusb_control_request_t const *) setup; if ( !(TUSB_REQ_RCPT_DEVICE == request->bmRequestType_bit.recipient && TUSB_REQ_TYPE_STANDARD == request->bmRequestType_bit.type && TUSB_REQ_SET_ADDRESS == request->bRequest) ) { dcd_event_setup_received(0, setup, true); } } if ( int_status & EDPT_END_ALL_MASK ) { // DMA complete move data from SRAM <-> Endpoint // Must before endpoint transfer handling edpt_dma_end(); } //--------------------------------------------------------------------+ /* Control/Bulk/Interrupt (CBI) Transfer * * Data flow is: * (bus) (dma) * Host <-------> Endpoint <-------> RAM * * For CBI OUT: * - Host -> Endpoint * EPDATA (or EP0DATADONE) interrupted, check EPDATASTATUS.EPOUT[i] * to start DMA. For Bulk/Interrupt, this step can occur automatically (without sw), * which means data may or may not be ready (out_received flag). * - Endpoint -> RAM * ENDEPOUT[i] interrupted, transaction complete, sw prepare next transaction * * For CBI IN: * - RAM -> Endpoint * ENDEPIN[i] interrupted indicate DMA is complete. HW will start * to move data to host * - Endpoint -> Host * EPDATA (or EP0DATADONE) interrupted, check EPDATASTATUS.EPIN[i]. * Transaction is complete, sw prepare next transaction * * Note: in both Control In and Out of Data stage from Host <-> Endpoint * EP0DATADONE will be set as interrupt source */ //--------------------------------------------------------------------+ /* CBI OUT: Endpoint -> SRAM (aka transaction complete) * Note: Since nRF controller auto ACK next packet without SW awareness * We must handle this stage before Host -> Endpoint just in case 2 event happens at once * * ISO OUT: Transaction must fit in single packet, it can be shorter then total * len if Host decides to sent fewer bytes, it this case transaction is also * complete and next transfer is not initiated here like for CBI. */ for(uint8_t epnum=0; epnumEPOUT[epnum].AMOUNT; xfer->buffer += xact_len; xfer->actual_len += xact_len; // Transfer complete if transaction len < Max Packet Size or total len is transferred if ( (epnum != EP_ISO_NUM) && (xact_len == xfer->mps) && (xfer->actual_len < xfer->total_len) ) { if ( epnum == 0 ) { // Accept next Control Out packet. TASKS_EP0RCVOUT also require EasyDMA edpt_dma_start(&NRF_USBD->TASKS_EP0RCVOUT); }else { // nRF auto accept next Bulk/Interrupt OUT packet // nothing to do } }else { TU_ASSERT(xfer->started,); xfer->total_len = xfer->actual_len; xfer->started = false; // CBI OUT complete dcd_event_xfer_complete(0, epnum, xfer->actual_len, XFER_RESULT_SUCCESS, true); } } // Ended event for CBI IN : nothing to do } // Endpoint <-> Host ( In & OUT ) if ( int_status & (USBD_INTEN_EPDATA_Msk | USBD_INTEN_EP0DATADONE_Msk) ) { uint32_t data_status = NRF_USBD->EPDATASTATUS; NRF_USBD->EPDATASTATUS = data_status; __ISB(); __DSB(); // EP0DATADONE is set with either Control Out on IN Data // Since EPDATASTATUS cannot be used to determine whether it is control OUT or IN. // We will use BMREQUESTTYPE in setup packet to determine the direction bool const is_control_in = (int_status & USBD_INTEN_EP0DATADONE_Msk) && (NRF_USBD->BMREQUESTTYPE & TUSB_DIR_IN_MASK); bool const is_control_out = (int_status & USBD_INTEN_EP0DATADONE_Msk) && !(NRF_USBD->BMREQUESTTYPE & TUSB_DIR_IN_MASK); // CBI In: Endpoint -> Host (transaction complete) for(uint8_t epnum=0; epnumEPIN[epnum].AMOUNT; xfer->buffer += xact_len; xfer->actual_len += xact_len; if ( xfer->actual_len < xfer->total_len ) { // Start DMA to copy next data packet xact_in_dma(epnum); } else { // CBI IN complete dcd_event_xfer_complete(0, epnum | TUSB_DIR_IN_MASK, xfer->actual_len, XFER_RESULT_SUCCESS, true); } } } // CBI OUT: Host -> Endpoint for(uint8_t epnum=0; epnumstarted && xfer->actual_len < xfer->total_len ) { xact_out_dma(epnum); }else { // Data overflow !!! Nah, nRF will auto accept next Bulk/Interrupt OUT packet // Mark this endpoint with data received xfer->data_received = true; } } } } } //--------------------------------------------------------------------+ // HFCLK helper //--------------------------------------------------------------------+ #ifdef SOFTDEVICE_PRESENT // For enable/disable hfclk with SoftDevice #include "nrf_mbr.h" #include "nrf_sdm.h" #include "nrf_soc.h" #ifndef SD_MAGIC_NUMBER #define SD_MAGIC_NUMBER 0x51B1E5DB #endif static inline bool is_sd_existed(void) { return *((uint32_t*)(SOFTDEVICE_INFO_STRUCT_ADDRESS+4)) == SD_MAGIC_NUMBER; } // check if SD is existed and enabled static inline bool is_sd_enabled(void) { if ( !is_sd_existed() ) return false; uint8_t sd_en = false; (void) sd_softdevice_is_enabled(&sd_en); return sd_en; } #endif static bool hfclk_running(void) { #ifdef SOFTDEVICE_PRESENT if ( is_sd_enabled() ) { uint32_t is_running = 0; (void) sd_clock_hfclk_is_running(&is_running); return (is_running ? true : false); } #endif return nrf_clock_hf_is_running(NRF_CLOCK, NRF_CLOCK_HFCLK_HIGH_ACCURACY); } static void hfclk_enable(void) { #if CFG_TUSB_OS == OPT_OS_MYNEWT usb_clock_request(); return; #else // already running, nothing to do if ( hfclk_running() ) return; #ifdef SOFTDEVICE_PRESENT if ( is_sd_enabled() ) { (void)sd_clock_hfclk_request(); return; } #endif nrf_clock_event_clear(NRF_CLOCK, NRF_CLOCK_EVENT_HFCLKSTARTED); nrf_clock_task_trigger(NRF_CLOCK, NRF_CLOCK_TASK_HFCLKSTART); #endif } static void hfclk_disable(void) { #if CFG_TUSB_OS == OPT_OS_MYNEWT usb_clock_release(); return; #else #ifdef SOFTDEVICE_PRESENT if ( is_sd_enabled() ) { (void)sd_clock_hfclk_release(); return; } #endif nrf_clock_task_trigger(NRF_CLOCK, NRF_CLOCK_TASK_HFCLKSTOP); #endif } // Power & Clock Peripheral on nRF5x to manage USB // // USB Bus power is managed by Power module, there are 3 VBUS power events: // Detected, Ready, Removed. Upon these power events, This function will // enable ( or disable ) usb & hfclk peripheral, set the usb pin pull up // accordingly to the controller Startup/Standby Sequence in USBD 51.4 specs. // // Therefore this function must be called to handle USB power event by // - nrfx_power_usbevt_init() : if Softdevice is not used or enabled // - SoftDevice SOC event : if SD is used and enabled void tusb_hal_nrf_power_event (uint32_t event) { // Value is chosen to be as same as NRFX_POWER_USB_EVT_* in nrfx_power.h enum { USB_EVT_DETECTED = 0, USB_EVT_REMOVED = 1, USB_EVT_READY = 2 }; #if CFG_TUSB_DEBUG >= 2 const char* const power_evt_str[] = { "Detected", "Removed", "Ready" }; TU_LOG(2, "Power USB event: %s\r\n", power_evt_str[event]); #endif switch ( event ) { case USB_EVT_DETECTED: if ( !NRF_USBD->ENABLE ) { // Prepare for receiving READY event: disable interrupt since we will blocking wait NRF_USBD->INTENCLR = USBD_INTEN_USBEVENT_Msk; NRF_USBD->EVENTCAUSE = USBD_EVENTCAUSE_READY_Msk; __ISB(); __DSB(); // for sync #ifdef NRF52_SERIES // NRF53 does not need this errata // ERRATA 171, 187, 166 if ( nrfx_usbd_errata_187() ) { // CRITICAL_REGION_ENTER(); if ( *((volatile uint32_t *) (0x4006EC00)) == 0x00000000 ) { *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; *((volatile uint32_t *) (0x4006ED14)) = 0x00000003; *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; } else { *((volatile uint32_t *) (0x4006ED14)) = 0x00000003; } // CRITICAL_REGION_EXIT(); } if ( nrfx_usbd_errata_171() ) { // CRITICAL_REGION_ENTER(); if ( *((volatile uint32_t *) (0x4006EC00)) == 0x00000000 ) { *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; *((volatile uint32_t *) (0x4006EC14)) = 0x000000C0; *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; } else { *((volatile uint32_t *) (0x4006EC14)) = 0x000000C0; } // CRITICAL_REGION_EXIT(); } #endif // Enable the peripheral (will cause Ready event) NRF_USBD->ENABLE = 1; __ISB(); __DSB(); // for sync // Enable HFCLK hfclk_enable(); } break; case USB_EVT_READY: // Skip if pull-up is enabled and HCLK is already running. // Application probably call this more than necessary. if ( NRF_USBD->USBPULLUP && hfclk_running() ) break; // Waiting for USBD peripheral enabled while ( !(USBD_EVENTCAUSE_READY_Msk & NRF_USBD->EVENTCAUSE) ) { } NRF_USBD->EVENTCAUSE = USBD_EVENTCAUSE_READY_Msk; __ISB(); __DSB(); // for sync #ifdef NRF52_SERIES if ( nrfx_usbd_errata_171() ) { // CRITICAL_REGION_ENTER(); if ( *((volatile uint32_t *) (0x4006EC00)) == 0x00000000 ) { *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; *((volatile uint32_t *) (0x4006EC14)) = 0x00000000; *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; } else { *((volatile uint32_t *) (0x4006EC14)) = 0x00000000; } // CRITICAL_REGION_EXIT(); } if ( nrfx_usbd_errata_187() ) { // CRITICAL_REGION_ENTER(); if ( *((volatile uint32_t *) (0x4006EC00)) == 0x00000000 ) { *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; *((volatile uint32_t *) (0x4006ED14)) = 0x00000000; *((volatile uint32_t *) (0x4006EC00)) = 0x00009375; } else { *((volatile uint32_t *) (0x4006ED14)) = 0x00000000; } // CRITICAL_REGION_EXIT(); } if ( nrfx_usbd_errata_166() ) { *((volatile uint32_t *) (NRF_USBD_BASE + 0x800)) = 0x7E3; *((volatile uint32_t *) (NRF_USBD_BASE + 0x804)) = 0x40; __ISB(); __DSB(); } #endif // ISO buffer Lower half for IN, upper half for OUT NRF_USBD->ISOSPLIT = USBD_ISOSPLIT_SPLIT_HalfIN; // Enable bus-reset interrupt NRF_USBD->INTENSET = USBD_INTEN_USBRESET_Msk; // Enable interrupt, priorities should be set by application NVIC_ClearPendingIRQ(USBD_IRQn); // Don't enable USBD interrupt yet, if dcd_init() did not finish yet // Interrupt will be enabled by tud_init(), when USB stack is ready // to handle interrupts. if (tud_inited()) { NVIC_EnableIRQ(USBD_IRQn); } // Wait for HFCLK while ( !hfclk_running() ) { } // Enable pull up NRF_USBD->USBPULLUP = 1; __ISB(); __DSB(); // for sync break; case USB_EVT_REMOVED: if ( NRF_USBD->ENABLE ) { // Abort all transfers // Disable pull up NRF_USBD->USBPULLUP = 0; __ISB(); __DSB(); // for sync // Disable Interrupt NVIC_DisableIRQ(USBD_IRQn); // disable all interrupt NRF_USBD->INTENCLR = NRF_USBD->INTEN; NRF_USBD->ENABLE = 0; __ISB(); __DSB(); // for sync hfclk_disable(); dcd_event_bus_signal(0, DCD_EVENT_UNPLUGGED, is_in_isr()); } break; default: break; } } #endif