Adds class implementation for use STM32F4xx OTG_HS in FS mode
Fork of USBDevice by
targets/TARGET_NXP/USBHAL_LPC40.cpp
- Committer:
- ua1arn
- Date:
- 2018-08-03
- Revision:
- 78:b881d8ac258a
- Parent:
- 71:53949e6131f6
File content as of revision 78:b881d8ac258a:
/* Copyright (c) 2010-2011 mbed.org, MIT License * * 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. */ #if defined(TARGET_LPC4088) || defined(TARGET_LPC4088_DM) #include "USBHAL.h" // Get endpoint direction #define IN_EP(endpoint) ((endpoint) & 1U ? true : false) #define OUT_EP(endpoint) ((endpoint) & 1U ? false : true) // Convert physical endpoint number to register bit #define EP(endpoint) (1UL<<endpoint) // Power Control for Peripherals register #define PCUSB (1UL<<31) // USB Clock Control register #define DEV_CLK_EN (1UL<<1) #define PORT_CLK_EN (1UL<<3) #define AHB_CLK_EN (1UL<<4) // USB Clock Status register #define DEV_CLK_ON (1UL<<1) #define AHB_CLK_ON (1UL<<4) // USB Device Interupt registers #define FRAME (1UL<<0) #define EP_FAST (1UL<<1) #define EP_SLOW (1UL<<2) #define DEV_STAT (1UL<<3) #define CCEMPTY (1UL<<4) #define CDFULL (1UL<<5) #define RxENDPKT (1UL<<6) #define TxENDPKT (1UL<<7) #define EP_RLZED (1UL<<8) #define ERR_INT (1UL<<9) // USB Control register #define RD_EN (1<<0) #define WR_EN (1<<1) #define LOG_ENDPOINT(endpoint) ((endpoint>>1)<<2) // USB Receive Packet Length register #define DV (1UL<<10) #define PKT_RDY (1UL<<11) #define PKT_LNGTH_MASK (0x3ff) // Serial Interface Engine (SIE) #define SIE_WRITE (0x01) #define SIE_READ (0x02) #define SIE_COMMAND (0x05) #define SIE_CMD_CODE(phase, data) ((phase<<8)|(data<<16)) // SIE Command codes #define SIE_CMD_SET_ADDRESS (0xD0) #define SIE_CMD_CONFIGURE_DEVICE (0xD8) #define SIE_CMD_SET_MODE (0xF3) #define SIE_CMD_READ_FRAME_NUMBER (0xF5) #define SIE_CMD_READ_TEST_REGISTER (0xFD) #define SIE_CMD_SET_DEVICE_STATUS (0xFE) #define SIE_CMD_GET_DEVICE_STATUS (0xFE) #define SIE_CMD_GET_ERROR_CODE (0xFF) #define SIE_CMD_READ_ERROR_STATUS (0xFB) #define SIE_CMD_SELECT_ENDPOINT(endpoint) (0x00+endpoint) #define SIE_CMD_SELECT_ENDPOINT_CLEAR_INTERRUPT(endpoint) (0x40+endpoint) #define SIE_CMD_SET_ENDPOINT_STATUS(endpoint) (0x40+endpoint) #define SIE_CMD_CLEAR_BUFFER (0xF2) #define SIE_CMD_VALIDATE_BUFFER (0xFA) // SIE Device Status register #define SIE_DS_CON (1<<0) #define SIE_DS_CON_CH (1<<1) #define SIE_DS_SUS (1<<2) #define SIE_DS_SUS_CH (1<<3) #define SIE_DS_RST (1<<4) // SIE Device Set Address register #define SIE_DSA_DEV_EN (1<<7) // SIE Configue Device register #define SIE_CONF_DEVICE (1<<0) // Select Endpoint register #define SIE_SE_FE (1<<0) #define SIE_SE_ST (1<<1) #define SIE_SE_STP (1<<2) #define SIE_SE_PO (1<<3) #define SIE_SE_EPN (1<<4) #define SIE_SE_B_1_FULL (1<<5) #define SIE_SE_B_2_FULL (1<<6) // Set Endpoint Status command #define SIE_SES_ST (1<<0) #define SIE_SES_DA (1<<5) #define SIE_SES_RF_MO (1<<6) #define SIE_SES_CND_ST (1<<7) USBHAL * USBHAL::instance; static volatile int epComplete; static uint32_t endpointStallState; static void SIECommand(uint32_t command) { // The command phase of a SIE transaction LPC_USB->DevIntClr = CCEMPTY; LPC_USB->CmdCode = SIE_CMD_CODE(SIE_COMMAND, command); while (!(LPC_USB->DevIntSt & CCEMPTY)); } static void SIEWriteData(uint8_t data) { // The data write phase of a SIE transaction LPC_USB->DevIntClr = CCEMPTY; LPC_USB->CmdCode = SIE_CMD_CODE(SIE_WRITE, data); while (!(LPC_USB->DevIntSt & CCEMPTY)); } static uint8_t SIEReadData(uint32_t command) { // The data read phase of a SIE transaction LPC_USB->DevIntClr = CDFULL; LPC_USB->CmdCode = SIE_CMD_CODE(SIE_READ, command); while (!(LPC_USB->DevIntSt & CDFULL)); return (uint8_t)LPC_USB->CmdData; } static void SIEsetDeviceStatus(uint8_t status) { // Write SIE device status register SIECommand(SIE_CMD_SET_DEVICE_STATUS); SIEWriteData(status); } static uint8_t SIEgetDeviceStatus(void) { // Read SIE device status register SIECommand(SIE_CMD_GET_DEVICE_STATUS); return SIEReadData(SIE_CMD_GET_DEVICE_STATUS); } void SIEsetAddress(uint8_t address) { // Write SIE device address register SIECommand(SIE_CMD_SET_ADDRESS); SIEWriteData((address & 0x7f) | SIE_DSA_DEV_EN); } static uint8_t SIEselectEndpoint(uint8_t endpoint) { // SIE select endpoint command SIECommand(SIE_CMD_SELECT_ENDPOINT(endpoint)); return SIEReadData(SIE_CMD_SELECT_ENDPOINT(endpoint)); } static uint8_t SIEclearBuffer(void) { // SIE clear buffer command SIECommand(SIE_CMD_CLEAR_BUFFER); return SIEReadData(SIE_CMD_CLEAR_BUFFER); } static void SIEvalidateBuffer(void) { // SIE validate buffer command SIECommand(SIE_CMD_VALIDATE_BUFFER); } static void SIEsetEndpointStatus(uint8_t endpoint, uint8_t status) { // SIE set endpoint status command SIECommand(SIE_CMD_SET_ENDPOINT_STATUS(endpoint)); SIEWriteData(status); } static uint16_t SIEgetFrameNumber(void) __attribute__ ((unused)); static uint16_t SIEgetFrameNumber(void) { // Read current frame number uint16_t lowByte; uint16_t highByte; SIECommand(SIE_CMD_READ_FRAME_NUMBER); lowByte = SIEReadData(SIE_CMD_READ_FRAME_NUMBER); highByte = SIEReadData(SIE_CMD_READ_FRAME_NUMBER); return (highByte << 8) | lowByte; } static void SIEconfigureDevice(void) { // SIE Configure device command SIECommand(SIE_CMD_CONFIGURE_DEVICE); SIEWriteData(SIE_CONF_DEVICE); } static void SIEunconfigureDevice(void) { // SIE Configure device command SIECommand(SIE_CMD_CONFIGURE_DEVICE); SIEWriteData(0); } static void SIEconnect(void) { // Connect USB device uint8_t status = SIEgetDeviceStatus(); SIEsetDeviceStatus(status | SIE_DS_CON); } static void SIEdisconnect(void) { // Disconnect USB device uint8_t status = SIEgetDeviceStatus(); SIEsetDeviceStatus(status & ~SIE_DS_CON); } static uint8_t selectEndpointClearInterrupt(uint8_t endpoint) { // Implemented using using EP_INT_CLR. LPC_USB->EpIntClr = EP(endpoint); while (!(LPC_USB->DevIntSt & CDFULL)); return (uint8_t)LPC_USB->CmdData; } static void enableEndpointEvent(uint8_t endpoint) { // Enable an endpoint interrupt LPC_USB->EpIntEn |= EP(endpoint); } static void disableEndpointEvent(uint8_t endpoint) __attribute__ ((unused)); static void disableEndpointEvent(uint8_t endpoint) { // Disable an endpoint interrupt LPC_USB->EpIntEn &= ~EP(endpoint); } static volatile uint32_t __attribute__((used)) dummyRead; uint32_t USBHAL::endpointReadcore(uint8_t endpoint, uint8_t *buffer) { // Read from an OUT endpoint uint32_t size; uint32_t i; uint32_t data = 0; uint8_t offset; LPC_USB->Ctrl = LOG_ENDPOINT(endpoint) | RD_EN; while (!(LPC_USB->RxPLen & PKT_RDY)); size = LPC_USB->RxPLen & PKT_LNGTH_MASK; offset = 0; if (size > 0) { for (i=0; i<size; i++) { if (offset==0) { // Fetch up to four bytes of data as a word data = LPC_USB->RxData; } // extract a byte *buffer = (data>>offset) & 0xff; buffer++; // move on to the next byte offset = (offset + 8) % 32; } } else { dummyRead = LPC_USB->RxData; } LPC_USB->Ctrl = 0; if ((endpoint >> 1) % 3 || (endpoint >> 1) == 0) { SIEselectEndpoint(endpoint); SIEclearBuffer(); } return size; } static void endpointWritecore(uint8_t endpoint, uint8_t *buffer, uint32_t size) { // Write to an IN endpoint uint32_t temp, data; uint8_t offset; LPC_USB->Ctrl = LOG_ENDPOINT(endpoint) | WR_EN; LPC_USB->TxPLen = size; offset = 0; data = 0; if (size>0) { do { // Fetch next data byte into a word-sized temporary variable temp = *buffer++; // Add to current data word temp = temp << offset; data = data | temp; // move on to the next byte offset = (offset + 8) % 32; size--; if ((offset==0) || (size==0)) { // Write the word to the endpoint LPC_USB->TxData = data; data = 0; } } while (size>0); } else { LPC_USB->TxData = 0; } // Clear WR_EN to cover zero length packet case LPC_USB->Ctrl=0; SIEselectEndpoint(endpoint); SIEvalidateBuffer(); } USBHAL::USBHAL(void) { // Disable IRQ NVIC_DisableIRQ(USB_IRQn); // fill in callback array epCallback[0] = &USBHAL::EP1_OUT_callback; epCallback[1] = &USBHAL::EP1_IN_callback; epCallback[2] = &USBHAL::EP2_OUT_callback; epCallback[3] = &USBHAL::EP2_IN_callback; epCallback[4] = &USBHAL::EP3_OUT_callback; epCallback[5] = &USBHAL::EP3_IN_callback; epCallback[6] = &USBHAL::EP4_OUT_callback; epCallback[7] = &USBHAL::EP4_IN_callback; epCallback[8] = &USBHAL::EP5_OUT_callback; epCallback[9] = &USBHAL::EP5_IN_callback; epCallback[10] = &USBHAL::EP6_OUT_callback; epCallback[11] = &USBHAL::EP6_IN_callback; epCallback[12] = &USBHAL::EP7_OUT_callback; epCallback[13] = &USBHAL::EP7_IN_callback; epCallback[14] = &USBHAL::EP8_OUT_callback; epCallback[15] = &USBHAL::EP8_IN_callback; epCallback[16] = &USBHAL::EP9_OUT_callback; epCallback[17] = &USBHAL::EP9_IN_callback; epCallback[18] = &USBHAL::EP10_OUT_callback; epCallback[19] = &USBHAL::EP10_IN_callback; epCallback[20] = &USBHAL::EP11_OUT_callback; epCallback[21] = &USBHAL::EP11_IN_callback; epCallback[22] = &USBHAL::EP12_OUT_callback; epCallback[23] = &USBHAL::EP12_IN_callback; epCallback[24] = &USBHAL::EP13_OUT_callback; epCallback[25] = &USBHAL::EP13_IN_callback; epCallback[26] = &USBHAL::EP14_OUT_callback; epCallback[27] = &USBHAL::EP14_IN_callback; epCallback[28] = &USBHAL::EP15_OUT_callback; epCallback[29] = &USBHAL::EP15_IN_callback; // Enable power to USB device controller LPC_SC->PCONP |= PCUSB; // Enable USB clocks LPC_USB->USBClkCtrl |= DEV_CLK_EN | AHB_CLK_EN | PORT_CLK_EN; while ((LPC_USB->USBClkSt & (DEV_CLK_EN | AHB_CLK_EN | PORT_CLK_EN)) != (DEV_CLK_ON | AHB_CLK_ON | PORT_CLK_EN)); // Select port USB2 LPC_USB->StCtrl |= 3; // Configure pin P0.31 to be USB2 LPC_IOCON->P0_31 &= ~0x07; LPC_IOCON->P0_31 |= 0x01; // Disconnect USB device SIEdisconnect(); // Configure pin P0.14 to be Connect LPC_IOCON->P0_14 &= ~0x07; LPC_IOCON->P0_14 |= 0x03; // Connect must be low for at least 2.5uS wait(0.3); // Set the maximum packet size for the control endpoints realiseEndpoint(EP0IN, MAX_PACKET_SIZE_EP0, 0); realiseEndpoint(EP0OUT, MAX_PACKET_SIZE_EP0, 0); // Attach IRQ instance = this; NVIC_SetVector(USB_IRQn, (uint32_t)&_usbisr); // Enable interrupts for device events and EP0 LPC_USB->DevIntEn = EP_SLOW | DEV_STAT | FRAME; enableEndpointEvent(EP0IN); enableEndpointEvent(EP0OUT); } USBHAL::~USBHAL(void) { // Ensure device disconnected SIEdisconnect(); // Disable USB interrupts NVIC_DisableIRQ(USB_IRQn); } void USBHAL::connect(void) { NVIC_EnableIRQ(USB_IRQn); // Connect USB device SIEconnect(); } void USBHAL::disconnect(void) { NVIC_DisableIRQ(USB_IRQn); // Disconnect USB device SIEdisconnect(); } void USBHAL::configureDevice(void) { SIEconfigureDevice(); } void USBHAL::unconfigureDevice(void) { SIEunconfigureDevice(); } void USBHAL::setAddress(uint8_t address) { SIEsetAddress(address); } void USBHAL::EP0setup(uint8_t *buffer) { endpointReadcore(EP0OUT, buffer); } void USBHAL::EP0read(void) { // Not required } void USBHAL::EP0readStage(void) { // Not required } uint32_t USBHAL::EP0getReadResult(uint8_t *buffer) { return endpointReadcore(EP0OUT, buffer); } void USBHAL::EP0write(uint8_t *buffer, uint32_t size) { endpointWritecore(EP0IN, buffer, size); } void USBHAL::EP0getWriteResult(void) { // Not required } void USBHAL::EP0stall(void) { // This will stall both control endpoints stallEndpoint(EP0OUT); } EP_STATUS USBHAL::endpointRead(uint8_t endpoint, uint32_t maximumSize) { return EP_PENDING; } EP_STATUS USBHAL::endpointReadResult(uint8_t endpoint, uint8_t * buffer, uint32_t *bytesRead) { //for isochronous endpoint, we don't wait an interrupt if ((endpoint >> 1) % 3 || (endpoint >> 1) == 0) { if (!(epComplete & EP(endpoint))) return EP_PENDING; } *bytesRead = endpointReadcore(endpoint, buffer); epComplete &= ~EP(endpoint); return EP_COMPLETED; } EP_STATUS USBHAL::endpointWrite(uint8_t endpoint, uint8_t *data, uint32_t size) { if (getEndpointStallState(endpoint)) { return EP_STALLED; } epComplete &= ~EP(endpoint); endpointWritecore(endpoint, data, size); return EP_PENDING; } EP_STATUS USBHAL::endpointWriteResult(uint8_t endpoint) { if (epComplete & EP(endpoint)) { epComplete &= ~EP(endpoint); return EP_COMPLETED; } return EP_PENDING; } bool USBHAL::realiseEndpoint(uint8_t endpoint, uint32_t maxPacket, uint32_t flags) { // Realise an endpoint LPC_USB->DevIntClr = EP_RLZED; LPC_USB->ReEp |= EP(endpoint); LPC_USB->EpInd = endpoint; LPC_USB->MaxPSize = maxPacket; while (!(LPC_USB->DevIntSt & EP_RLZED)); LPC_USB->DevIntClr = EP_RLZED; // Clear stall state endpointStallState &= ~EP(endpoint); enableEndpointEvent(endpoint); return true; } void USBHAL::stallEndpoint(uint8_t endpoint) { // Stall an endpoint if ( (endpoint==EP0IN) || (endpoint==EP0OUT) ) { // Conditionally stall both control endpoints SIEsetEndpointStatus(EP0OUT, SIE_SES_CND_ST); } else { SIEsetEndpointStatus(endpoint, SIE_SES_ST); // Update stall state endpointStallState |= EP(endpoint); } } void USBHAL::unstallEndpoint(uint8_t endpoint) { // Unstall an endpoint. The endpoint will also be reinitialised SIEsetEndpointStatus(endpoint, 0); // Update stall state endpointStallState &= ~EP(endpoint); } bool USBHAL::getEndpointStallState(uint8_t endpoint) { // Returns true if endpoint stalled return endpointStallState & EP(endpoint); } void USBHAL::remoteWakeup(void) { // Remote wakeup uint8_t status; // Enable USB clocks LPC_USB->USBClkCtrl |= DEV_CLK_EN | AHB_CLK_EN; while (LPC_USB->USBClkSt != (DEV_CLK_ON | AHB_CLK_ON)); status = SIEgetDeviceStatus(); SIEsetDeviceStatus(status & ~SIE_DS_SUS); } void USBHAL::_usbisr(void) { instance->usbisr(); } void USBHAL::usbisr(void) { uint8_t devStat; if (LPC_USB->DevIntSt & FRAME) { // Start of frame event SOF(SIEgetFrameNumber()); // Clear interrupt status flag LPC_USB->DevIntClr = FRAME; } if (LPC_USB->DevIntSt & DEV_STAT) { // Device Status interrupt // Must clear the interrupt status flag before reading the device status from the SIE LPC_USB->DevIntClr = DEV_STAT; // Read device status from SIE devStat = SIEgetDeviceStatus(); //printf("devStat: %d\r\n", devStat); if (devStat & SIE_DS_SUS_CH) { // Suspend status changed if((devStat & SIE_DS_SUS) != 0) { suspendStateChanged(0); } } if (devStat & SIE_DS_RST) { // Bus reset if((devStat & SIE_DS_SUS) == 0) { suspendStateChanged(1); } busReset(); } } if (LPC_USB->DevIntSt & EP_SLOW) { // (Slow) Endpoint Interrupt // Process each endpoint interrupt if (LPC_USB->EpIntSt & EP(EP0OUT)) { if (selectEndpointClearInterrupt(EP0OUT) & SIE_SE_STP) { // this is a setup packet EP0setupCallback(); } else { EP0out(); } LPC_USB->DevIntClr = EP_SLOW; } if (LPC_USB->EpIntSt & EP(EP0IN)) { selectEndpointClearInterrupt(EP0IN); LPC_USB->DevIntClr = EP_SLOW; EP0in(); } for (uint8_t num = 2; num < 16*2; num++) { if (LPC_USB->EpIntSt & EP(num)) { selectEndpointClearInterrupt(num); epComplete |= EP(num); LPC_USB->DevIntClr = EP_SLOW; if ((instance->*(epCallback[num - 2]))()) { epComplete &= ~EP(num); } } } } } #endif