/**************************************************************************/ /*! @file dcd_nrf5x.c @author hathach @section LICENSE Software License Agreement (BSD License) Copyright (c) 2018, hathach (tinyusb.org) All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /**************************************************************************/ #include "tusb_option.h" #if MODE_DEVICE_SUPPORTED && CFG_TUSB_MCU == OPT_MCU_NRF5X #include "nrf.h" #include "nrf_power.h" #include "nrf_usbd.h" #include "nrf_clock.h" #include "device/dcd.h" #include "device/usbd_pvt.h" // to use defer function helper /*------------------------------------------------------------------*/ /* 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 = 0x1FFBFCUL }; /*------------------------------------------------------------------*/ /* VARIABLE DECLARATION *------------------------------------------------------------------*/ typedef struct { uint8_t* buffer; uint16_t total_len; uint16_t actual_len; uint8_t mps; // max packet size // nrf52840 will auto ACK OUT packet after DMA is done volatile bool data_received; // indicate packet is already ACK } nom_xfer_t; /*static*/ struct { struct { uint8_t* buffer; uint16_t total_len; uint16_t actual_len; uint8_t dir; }control; // Non control: 7 endpoints IN & OUT (offset 1) nom_xfer_t xfer[7][2]; volatile bool dma_running; }_dcd; void bus_reset(void) { 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; varclr_(&_dcd); } /*------------------------------------------------------------------*/ /* Controller API *------------------------------------------------------------------*/ bool dcd_init (uint8_t rhport) { (void) rhport; return true; } void dcd_connect (uint8_t rhport) { } void dcd_disconnect (uint8_t rhport) { } void dcd_set_address (uint8_t rhport, uint8_t dev_addr) { (void) rhport; // Set Address is automatically update by hw controller } void dcd_set_config (uint8_t rhport, uint8_t config_num) { (void) rhport; (void) config_num; // Nothing to do } /*------------------------------------------------------------------*/ /* Control *------------------------------------------------------------------*/ static void edpt_dma_start(volatile uint32_t* reg_startep) { // Only one dma can be active if ( _dcd.dma_running ) { if (SCB->ICSR & SCB_ICSR_VECTACTIVE_Msk) { // If called within ISR, use usbd task to defer later usbd_defer_func( (osal_task_func_t) edpt_dma_start, (void*) reg_startep, true ); return; } else { // Otherwise simply block wait while ( _dcd.dma_running ) { } } } _dcd.dma_running = true; (*reg_startep) = 1; __ISB(); __DSB(); } static void edpt_dma_end(void) { TU_ASSERT(_dcd.dma_running, ); _dcd.dma_running = false; } static void xact_control_start(void) { // Each transaction is up to 64 bytes uint8_t const xact_len = min16_of(_dcd.control.total_len-_dcd.control.actual_len, MAX_PACKET_SIZE); if ( _dcd.control.dir == TUSB_DIR_OUT ) { // TODO control out NRF_USBD->EPOUT[0].PTR = (uint32_t) _dcd.control.buffer; NRF_USBD->EPOUT[0].MAXCNT = xact_len; NRF_USBD->TASKS_EP0RCVOUT = 1; __ISB(); __DSB(); }else { NRF_USBD->EPIN[0].PTR = (uint32_t) _dcd.control.buffer; NRF_USBD->EPIN[0].MAXCNT = xact_len; edpt_dma_start(&NRF_USBD->TASKS_STARTEPIN[0]); } _dcd.control.buffer += xact_len; _dcd.control.actual_len += xact_len; } bool dcd_control_xfer (uint8_t rhport, tusb_dir_t dir, uint8_t * buffer, uint16_t length) { (void) rhport; if ( length ) { // Data Phase _dcd.control.total_len = length; _dcd.control.actual_len = 0; _dcd.control.buffer = buffer; _dcd.control.dir = (uint8_t) dir; xact_control_start(); }else { // Status Phase NRF_USBD->TASKS_EP0STATUS = 1; __ISB(); __DSB(); } return true; } /*------------------------------------------------------------------*/ /* *------------------------------------------------------------------*/ static inline nom_xfer_t* get_td(uint8_t epnum, uint8_t dir) { return &_dcd.xfer[epnum-1][dir]; } /*------------- Bulk/Int OUT transfer -------------*/ /** * Prepare Bulk/Int out transaction, Endpoint start to accept/ACK Data * @param epnum */ static void xact_out_prepare(uint8_t epnum) { // Write zero value to SIZE register will allow hw to ACK (accept data) // If it is not already done by DMA NRF_USBD->SIZE.EPOUT[epnum] = 0; __ISB(); __DSB(); } static void xact_out_dma(uint8_t epnum) { nom_xfer_t* xfer = get_td(epnum, TUSB_DIR_OUT); uint8_t const xact_len = NRF_USBD->SIZE.EPOUT[epnum]; // Trigger DMA move data from Endpoint -> SRAM NRF_USBD->EPOUT[epnum].PTR = (uint32_t) xfer->buffer; NRF_USBD->EPOUT[epnum].MAXCNT = xact_len; edpt_dma_start(&NRF_USBD->TASKS_STARTEPOUT[epnum]); xfer->buffer += xact_len; xfer->actual_len += xact_len; } /*------------- Bulk/Int IN transfer -------------*/ /** * Prepare Bulk/Int in transaction, use DMA to transfer data from Memory -> Endpoint * @param epnum */ static void xact_in_prepare(uint8_t epnum) { nom_xfer_t* xfer = get_td(epnum, TUSB_DIR_IN); // Each transaction is up to Max Packet Size uint8_t const xact_len = min16_of(xfer->total_len - xfer->actual_len, xfer->mps); NRF_USBD->EPIN[epnum].PTR = (uint32_t) xfer->buffer; NRF_USBD->EPIN[epnum].MAXCNT = xact_len; xfer->buffer += xact_len; edpt_dma_start(&NRF_USBD->TASKS_STARTEPIN[epnum]); } bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * desc_edpt) { (void) rhport; uint8_t const epnum = edpt_number(desc_edpt->bEndpointAddress); uint8_t const dir = edpt_dir(desc_edpt->bEndpointAddress); _dcd.xfer[epnum-1][dir].mps = desc_edpt->wMaxPacketSize.size; if ( dir == TUSB_DIR_OUT ) { NRF_USBD->INTENSET = BIT_(USBD_INTEN_ENDEPOUT0_Pos + epnum); NRF_USBD->EPOUTEN |= BIT_(epnum); }else { NRF_USBD->INTENSET = BIT_(USBD_INTEN_ENDEPIN0_Pos + epnum); NRF_USBD->EPINEN |= BIT_(epnum); } __ISB(); __DSB(); return true; } bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes) { (void) rhport; uint8_t const epnum = edpt_number(ep_addr); uint8_t const dir = edpt_dir(ep_addr); nom_xfer_t* xfer = get_td(epnum, dir); xfer->buffer = buffer; xfer->total_len = total_bytes; xfer->actual_len = 0; if ( dir == TUSB_DIR_OUT ) { if ( xfer->data_received ) { // nrf52840 auto ACK OUT packet after DMA is done // Data already received previously --> trigger DMA to copy to SRAM xact_out_dma(epnum); }else { xact_out_prepare(epnum); } }else { xact_in_prepare(epnum); } return true; } void dcd_edpt_stall (uint8_t rhport, uint8_t ep_addr) { (void) rhport; if ( ep_addr == 0) { NRF_USBD->TASKS_EP0STALL = 1; }else { NRF_USBD->EPSTALL = (USBD_EPSTALL_STALL_Stall << USBD_EPSTALL_STALL_Pos) | ep_addr; } __ISB(); __DSB(); } void dcd_edpt_clear_stall (uint8_t rhport, uint8_t ep_addr) { (void) rhport; if ( ep_addr ) { NRF_USBD->EPSTALL = (USBD_EPSTALL_STALL_UnStall << USBD_EPSTALL_STALL_Pos) | ep_addr; } } bool dcd_edpt_busy (uint8_t rhport, uint8_t ep_addr) { (void) rhport; // USBD shouldn't check control endpoint state if ( 0 == ep_addr ) return false; uint8_t const epnum = edpt_number(ep_addr); uint8_t const dir = edpt_dir(ep_addr); nom_xfer_t* xfer = get_td(epnum, dir); return xfer->actual_len < xfer->total_len; } /*------------------------------------------------------------------*/ /* *------------------------------------------------------------------*/ void USBD_IRQHandler(void) { uint32_t const inten = NRF_USBD->INTEN; uint32_t int_status = 0; volatile uint32_t* regevt = &NRF_USBD->EVENTS_USBRESET; for(int i=0; i<32; i++) { if ( BIT_TEST_(inten, i) && regevt[i] ) { int_status |= BIT_(i); // event clear regevt[i] = 0; __ISB(); __DSB(); } } /*------------- Interrupt Processing -------------*/ if ( int_status & USBD_INTEN_USBRESET_Msk ) { bus_reset(); dcd_bus_event(0, USBD_BUS_EVENT_RESET); } if ( int_status & EDPT_END_ALL_MASK ) { // DMA complete move data from SRAM -> Endpoint edpt_dma_end(); } /*------------- Control Transfer -------------*/ if ( int_status & USBD_INTEN_EP0SETUP_Msk ) { uint8_t 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 }; dcd_setup_received(0, setup); } if ( int_status & USBD_INTEN_EP0DATADONE_Msk ) { if ( _dcd.control.dir == TUSB_DIR_OUT ) { // Control OUT: data from Host -> Endpoint // Trigger DMA to move Endpoint -> SRAM edpt_dma_start(&NRF_USBD->TASKS_STARTEPOUT[0]); }else { // Control IN: data transferred from Endpoint -> Host if ( _dcd.control.actual_len < _dcd.control.total_len ) { xact_control_start(); }else { // Control IN complete dcd_control_complete(0, _dcd.control.actual_len); } } } // Control OUT: data from Endpoint -> SRAM if ( int_status & USBD_INTEN_ENDEPOUT0_Msk) { if ( _dcd.control.actual_len < _dcd.control.total_len ) { xact_control_start(); }else { // Control OUT complete dcd_control_complete(0, _dcd.control.actual_len); } } /*------------- Bulk/Interrupt Transfer -------------*/ /* Bulk/Int OUT: data from DMA -> SRAM * 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 */ for(uint8_t epnum=1; epnum<8; epnum++) { if ( BIT_TEST_(int_status, USBD_INTEN_ENDEPOUT0_Pos+epnum) ) { nom_xfer_t* xfer = get_td(epnum, TUSB_DIR_OUT); uint8_t const xact_len = NRF_USBD->EPOUT[epnum].AMOUNT; xfer->data_received = false; // Transfer complete if transaction len < Max Packet Size or total len is transferred if ( (xact_len == xfer->mps) && (xfer->actual_len < xfer->total_len) ) { // Prepare for next transaction xact_out_prepare(epnum); }else { xfer->total_len = xfer->actual_len; // BULK/INT OUT complete dcd_xfer_complete(0, epnum, xfer->actual_len, true); } } // Ended event for Bulk/Int : nothing to do } if ( int_status & USBD_INTEN_EPDATA_Msk) { uint32_t data_status = NRF_USBD->EPDATASTATUS; nrf_usbd_epdatastatus_clear(data_status); // Bulk/Int In: data from Endpoint -> Host for(uint8_t epnum=1; epnum<8; epnum++) { if ( BIT_TEST_(data_status, epnum ) ) { nom_xfer_t* xfer = get_td(epnum, TUSB_DIR_IN); xfer->actual_len += NRF_USBD->EPIN[epnum].MAXCNT; if ( xfer->actual_len < xfer->total_len ) { // prepare next transaction xact_in_prepare(epnum); } else { // Bulk/Int IN complete dcd_xfer_complete(0, epnum | TUSB_DIR_IN_MASK, xfer->actual_len, true); } } } // Bulk/Int OUT: data from Host -> Endpoint for(uint8_t epnum=1; epnum<8; epnum++) { if ( BIT_TEST_(data_status, 16+epnum ) ) { nom_xfer_t* xfer = get_td(epnum, TUSB_DIR_OUT); if (xfer->actual_len < xfer->total_len) { xact_out_dma(epnum); }else { // Data overflow !!! Nah, nrf52840 will auto ACK OUT packet after DMA is done // Mark this endpoint with data received xfer->data_received = true; } } } } // SOF interrupt if ( int_status & USBD_INTEN_SOF_Msk ) { dcd_bus_event(0, USBD_BUS_EVENT_SOF); } } #endif