/* * geany_encoding=koi8-r * usb_lib.c * * Copyright 2018 Edward V. Emelianov * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, * MA 02110-1301, USA. * */ #include #include "usb_lib.h" #include // memcpy #include "usart.h" static ep_t endpoints[ENDPOINTS_NUM]; //static uint8_t set_featuring; static usb_dev_t USB_Dev; static usb_LineCoding lineCoding = {115200, 0, 0, 8}; static config_pack_t setup_packet; static uint8_t ep0databuf[EP0DATABUF_SIZE]; static uint8_t ep0dbuflen = 0; usb_LineCoding getLineCoding(){return lineCoding;} // definition of parts common for USB_DeviceDescriptor & USB_DeviceQualifierDescriptor #define bcdUSB_L 0x00 #define bcdUSB_H 0x02 #define bDeviceClass 0 #define bDeviceSubClass 0 #define bDeviceProtocol 0 #define bNumConfigurations 1 static const uint8_t USB_DeviceDescriptor[] = { 18, // bLength 0x01, // bDescriptorType - Device descriptor bcdUSB_L, // bcdUSB_L - 2.00 bcdUSB_H, // bcdUSB_H bDeviceClass, // bDeviceClass - USB_COMM bDeviceSubClass, // bDeviceSubClass bDeviceProtocol, // bDeviceProtocol USB_EP0_BUFSZ, // bMaxPacketSize0 0x5e, // idVendor: Microsoft 0x04, // idVendor_H 0x5c, // idProduct: Office Keyboard (106/109) 0x00, // idProduct_H 0x00, // bcdDevice_Ver_L 0x02, // bcdDevice_Ver_H 0x01, // iManufacturer 0x02, // iProduct 0x03, // iSerialNumber bNumConfigurations // bNumConfigurations }; static const uint8_t USB_DeviceQualifierDescriptor[] = { 10, //bLength 0x06, // bDescriptorType - Device qualifier bcdUSB_L, // bcdUSB_L bcdUSB_H, // bcdUSB_H bDeviceClass, // bDeviceClass bDeviceSubClass, // bDeviceSubClass bDeviceProtocol, // bDeviceProtocol USB_EP0_BUFSZ, // bMaxPacketSize0 bNumConfigurations, // bNumConfigurations 0x00 // Reserved }; static const uint8_t HID_ReportDescriptor[] = { 0x05, 0x01, /* Usage Page (Generic Desktop) */ 0x09, 0x02, /* Usage (Mouse) */ 0xA1, 0x01, /* Collection (Application) */ 0x09, 0x01, /* Usage (Pointer) */ 0xA1, 0x00, /* Collection (Physical) */ 0x85, 0x01, /* Report ID */ 0x05, 0x09, /* Usage Page (Buttons) */ 0x19, 0x01, /* Usage Minimum (01) */ 0x29, 0x03, /* Usage Maximum (03) */ 0x15, 0x00, /* Logical Minimum (0) */ 0x25, 0x01, /* Logical Maximum (0) */ 0x95, 0x03, /* Report Count (3) */ 0x75, 0x01, /* Report Size (1) */ 0x81, 0x02, /* Input (Data, Variable, Absolute) */ 0x95, 0x01, /* Report Count (1) */ 0x75, 0x05, /* Report Size (5) */ 0x81, 0x01, /* Input (Constant) ;5 bit padding */ 0x05, 0x01, /* Usage Page (Generic Desktop) */ 0x09, 0x30, /* Usage (X) */ 0x09, 0x31, /* Usage (Y) */ 0x15, 0x81, /* Logical Minimum (-127) */ 0x25, 0x7F, /* Logical Maximum (127) */ 0x75, 0x08, /* Report Size (8) */ 0x95, 0x02, /* Report Count (2) */ 0x81, 0x06, /* Input (Data, Variable, Relative) */ 0xC0, 0xC0,/* End Collection,End Collection */ // 0x09, 0x06, /* Usage (Keyboard) */ 0xA1, 0x01, /* Collection (Application) */ 0x85, 0x02, /* Report ID */ 0x05, 0x07, /* Usage (Key codes) */ 0x19, 0xE0, /* Usage Minimum (224) */ 0x29, 0xE7, /* Usage Maximum (231) */ 0x15, 0x00, /* Logical Minimum (0) */ 0x25, 0x01, /* Logical Maximum (1) */ 0x75, 0x01, /* Report Size (1) */ 0x95, 0x08, /* Report Count (8) */ 0x81, 0x02, /* Input (Data, Variable, Absolute) */ 0x95, 0x01, /* Report Count (1) */ 0x75, 0x08, /* Report Size (8) */ 0x81, 0x01, /* Input (Constant) ;5 bit padding */ 0x95, 0x05, /* Report Count (5) */ 0x75, 0x01, /* Report Size (1) */ 0x05, 0x08, /* Usage Page (Page# for LEDs) */ 0x19, 0x01, /* Usage Minimum (01) */ 0x29, 0x05, /* Usage Maximum (05) */ 0x91, 0x02, /* Output (Data, Variable, Absolute) */ 0x95, 0x01, /* Report Count (1) */ 0x75, 0x03, /* Report Size (3) */ 0x91, 0x01, /* Output (Constant) */ 0x95, 0x06, /* Report Count (1) */ 0x75, 0x08, /* Report Size (3) */ 0x15, 0x00, /* Logical Minimum (0) */ 0x25, 0x65, /* Logical Maximum (101) */ 0x05, 0x07, /* Usage (Key codes) */ 0x19, 0x00, /* Usage Minimum (00) */ 0x29, 0x65, /* Usage Maximum (101) */ 0x81, 0x00, /* Input (Data, Array) */ 0xC0 /* End Collection,End Collection */ }; #if 0 const uint8_t HID_ReportDescriptor[] = { 0x05, 0x01, /* Usage Page (Generic Desktop) */ 0x09, 0x06, /* Usage (Keyboard) */ 0xA1, 0x01, /* Collection (Application) */ 0x05, 0x07, /* Usage (Key codes) */ 0x19, 0xE0, /* Usage Minimum (224) */ 0x29, 0xE7, /* Usage Maximum (231) */ 0x15, 0x00, /* Logical Minimum (0) */ 0x25, 0x01, /* Logical Maximum (1) */ 0x75, 0x01, /* Report Size (1) */ 0x95, 0x08, /* Report Count (8) */ 0x81, 0x02, /* Input (Data, Variable, Absolute) */ 0x95, 0x01, /* Report Count (1) */ 0x75, 0x08, /* Report Size (8) */ 0x81, 0x01, /* Input (Constant) ;5 bit padding */ 0x95, 0x05, /* Report Count (5) */ 0x75, 0x01, /* Report Size (1) */ 0x05, 0x08, /* Usage Page (Page# for LEDs) */ 0x19, 0x01, /* Usage Minimum (01) */ 0x29, 0x05, /* Usage Maximum (05) */ 0x91, 0x02, /* Output (Data, Variable, Absolute) */ 0x95, 0x01, /* Report Count (1) */ 0x75, 0x03, /* Report Size (3) */ 0x91, 0x01, /* Output (Constant) */ 0x95, 0x06, /* Report Count (1) */ 0x75, 0x08, /* Report Size (3) */ 0x15, 0x00, /* Logical Minimum (0) */ 0x25, 0x65, /* Logical Maximum (101) */ 0x05, 0x07, /* Usage (Key codes) */ 0x19, 0x00, /* Usage Minimum (00) */ 0x29, 0x65, /* Usage Maximum (101) */ 0x81, 0x00, /* Input (Data, Array) */ 0x09, 0x05, /* Usage (Vendor Defined) */ 0x15, 0x00, /* Logical Minimum (0)) */ 0x26, 0xFF, 0x00, /* Logical Maximum (255)) */ 0x75, 0x08, /* Report Count (2)) */ 0x95, 0x02, /* Report Size (8 bit)) */ 0xB1, 0x02, /* Feature (Data, Variable, Absolute) */ 0xC0 /* End Collection,End Collection */ }; #endif static const uint8_t USB_ConfigDescriptor[] = { /*Configuration Descriptor*/ 0x09, /* bLength: Configuration Descriptor size */ 0x02, /* bDescriptorType: Configuration */ 34, /* wTotalLength */ 0x00, 0x01, /* bNumInterfaces: 1 interface */ 0x01, /* bConfigurationValue: Configuration value */ 0x00, /* iConfiguration: Index of string descriptor describing the configuration */ 0xa0, /* bmAttributes - Bus powered */ 0x32, /* MaxPower 100 mA */ /*Interface Descriptor */ 0x09, /* bLength: Interface Descriptor size */ 0x04, /* bDescriptorType: Interface */ 0x00, /* bInterfaceNumber: Number of Interface */ 0x00, /* bAlternateSetting: Alternate setting */ 0x01, /* bNumEndpoints: 1 endpoint used */ 0x03, /* bInterfaceClass: USB_CLASS_HID */ 0x01, /* bInterfaceSubClass: boot */ 0x01, /* bInterfaceProtocol: keyboard */ 0x00, /* iInterface: */ /* HID device descriptor */ 0x09, /* bLength: HID Device Descriptor size */ 0x21, /* bDescriptorType: HID */ 0x10, /* bcdHID: 1.10 */ 0x01, /* bcdHIDH */ 0x00, /* bCountryCode: Not supported */ 0x01, /* bNumDescriptors: 1 */ 0x22, /* bDescriptorType: Report */ sizeof(HID_ReportDescriptor), /* wDescriptorLength */ 0x00, /* wDescriptorLengthH */ /*Endpoint 1 Descriptor*/ 0x07, /* bLength: Endpoint Descriptor size */ 0x05, /* bDescriptorType: Endpoint */ 0x81, /* bEndpointAddress IN1 */ 0x03, /* bmAttributes: Interrupt */ USB_TXBUFSZ, /* wMaxPacketSize LO: */ 0x00, /* wMaxPacketSize HI: */ 0x01, /* bInterval: */ }; _USB_LANG_ID_(USB_StringLangDescriptor, LANG_US); // these descriptors are not used in PL2303 emulator! _USB_STRING_(USB_StringSerialDescriptor, u"0"); _USB_STRING_(USB_StringManufacturingDescriptor, u"SAO RAS"); _USB_STRING_(USB_StringProdDescriptor, u"HID mouse+keyboard"); #ifdef EBUG uint8_t _2wr = 0; #define WRITEDUMP(str) do{MSG(str); _2wr = 1;}while(0) #else #define WRITEDUMP(str) #endif static void wr0(const uint8_t *buf, uint16_t size){ if(setup_packet.wLength < size) size = setup_packet.wLength; EP_WriteIRQ(0, buf, size); } static inline void get_descriptor(){ switch(setup_packet.wValue){ case DEVICE_DESCRIPTOR: WRITEDUMP("DEVICE_DESCRIPTOR"); wr0(USB_DeviceDescriptor, sizeof(USB_DeviceDescriptor)); break; case CONFIGURATION_DESCRIPTOR: WRITEDUMP("CONFIGURATION_DESCRIPTOR"); wr0(USB_ConfigDescriptor, sizeof(USB_ConfigDescriptor)); break; case STRING_LANG_DESCRIPTOR: WRITEDUMP("STRING_LANG_DESCRIPTOR"); wr0((const uint8_t *)&USB_StringLangDescriptor, STRING_LANG_DESCRIPTOR_SIZE_BYTE); break; case STRING_MAN_DESCRIPTOR: WRITEDUMP("STRING_MAN_DESCRIPTOR"); wr0((const uint8_t *)&USB_StringManufacturingDescriptor, USB_StringManufacturingDescriptor.bLength); break; case STRING_PROD_DESCRIPTOR: WRITEDUMP("STRING_PROD_DESCRIPTOR"); wr0((const uint8_t *)&USB_StringProdDescriptor, USB_StringProdDescriptor.bLength); break; case STRING_SN_DESCRIPTOR: WRITEDUMP("STRING_SN_DESCRIPTOR"); wr0((const uint8_t *)&USB_StringSerialDescriptor, USB_StringSerialDescriptor.bLength); break; case DEVICE_QUALIFIER_DESCRIPTOR: WRITEDUMP("DEVICE_QUALIFIER_DESCRIPTOR"); wr0(USB_DeviceQualifierDescriptor, USB_DeviceQualifierDescriptor[0]); break; default: WRITEDUMP("UNK_DES"); break; } } static uint8_t configuration = 0; // reply for GET_CONFIGURATION (==1 if configured) static inline void std_d2h_req(){ uint16_t status = 0; // bus powered switch(setup_packet.bRequest){ case GET_DESCRIPTOR: get_descriptor(); break; case GET_STATUS: WRITEDUMP("GET_STATUS"); EP_WriteIRQ(0, (uint8_t *)&status, 2); // send status: Bus Powered break; case GET_CONFIGURATION: WRITEDUMP("GET_CONFIGURATION"); EP_WriteIRQ(0, &configuration, 1); break; default: WRITEDUMP("80:WR_REQ"); break; } } static inline void std_h2d_req(){ switch(setup_packet.bRequest){ case SET_ADDRESS: WRITEDUMP("SET_ADDRESS"); // new address will be assigned later - after acknowlegement or request to host USB_Dev.USB_Addr = setup_packet.wValue; break; case SET_CONFIGURATION: WRITEDUMP("SET_CONFIGURATION"); // Now device configured USB_Dev.USB_Status = USB_CONFIGURE_STATE; configuration = setup_packet.wValue; break; default: WRITEDUMP("0:WR_REQ"); break; } } static uint16_t WriteHID_descriptor(uint16_t status){ uint16_t rest = sizeof(HID_ReportDescriptor); uint8_t *ptr = (uint8_t*)HID_ReportDescriptor; while(rest){ uint16_t l = rest; if(l > endpoints[0].txbufsz) l = endpoints[0].txbufsz; EP_WriteIRQ(0, ptr, l); ptr += l; rest -= l; MSG("Sent\n"); uint8_t needzlp = (l == endpoints[0].txbufsz) ? 1 : 0; if(rest || needzlp){ // send last data buffer status = SET_NAK_RX(status); status = SET_VALID_TX(status); status = KEEP_DTOG_TX(status); status = KEEP_DTOG_RX(status); status = CLEAR_CTR_RX(status); status = CLEAR_CTR_TX(status); USB->ISTR = 0; USB->EPnR[0] = status; uint32_t ctr = 1000000; while(--ctr && (USB->ISTR & USB_ISTR_CTR) == 0); if((USB->ISTR & USB_ISTR_CTR) == 0){MSG("ERR\n")}; USB->ISTR = 0; status = USB->EPnR[0]; if(needzlp) EP_WriteIRQ(0, (uint8_t*)0, 0); } } return status; } /* bmRequestType: 76543210 7 direction: 0 - host->device, 1 - device->host 65 type: 0 - standard, 1 - class, 2 - vendor 4..0 getter: 0 - device, 1 - interface, 2 - endpoint, 3 - other */ /** * Endpoint0 (control) handler * @param ep - endpoint state * @return data written to EP0R */ static uint16_t EP0_Handler(ep_t ep){ uint16_t epstatus = ep.status; // EP0R on input -> return this value after modifications uint8_t reqtype = setup_packet.bmRequestType & 0x7f; uint8_t dev2host = (setup_packet.bmRequestType & 0x80) ? 1 : 0; if ((ep.rx_flag) && (ep.setup_flag)){ switch(reqtype){ case STANDARD_DEVICE_REQUEST_TYPE: // standard device request if(dev2host){ std_d2h_req(); }else{ std_h2d_req(); // send ZLP EP_WriteIRQ(0, (uint8_t *)0, 0); } epstatus = SET_NAK_RX(epstatus); epstatus = SET_VALID_TX(epstatus); break; case STANDARD_INTERFACE_REQUEST_TYPE: if(dev2host && setup_packet.bRequest == GET_DESCRIPTOR){ if(setup_packet.wValue == HID_REPORT_DESCRIPTOR){ WRITEDUMP("HID_REPORT"); epstatus = WriteHID_descriptor(epstatus); } } epstatus = SET_NAK_RX(epstatus); epstatus = SET_VALID_TX(epstatus); break; case STANDARD_ENDPOINT_REQUEST_TYPE: // standard endpoint request if (setup_packet.bRequest == CLEAR_FEATURE){ printu(setup_packet.wValue); //WRITEDUMP("CLEAR_FEATURE"); // send ZLP EP_WriteIRQ(0, (uint8_t *)0, 0); epstatus = SET_NAK_RX(epstatus); epstatus = SET_VALID_TX(epstatus); }else{ WRITEDUMP("02:WR_REQ"); } break; case CONTROL_REQUEST_TYPE: if (setup_packet.bRequest == SET_IDLE_REQUEST){ EP_WriteIRQ(0, (uint8_t *)0, 0); epstatus = SET_NAK_RX(epstatus); epstatus = SET_VALID_TX(epstatus); WRITEDUMP("SET_IDLE_REQUEST"); } else if (setup_packet.bRequest == SET_FEAUTRE){ WRITEDUMP("SET_FEAUTRE"); //set_featuring = 1; epstatus = SET_VALID_RX(epstatus); epstatus = KEEP_STAT_TX(epstatus); } break; default: WRITEDUMP("Bad request"); EP_WriteIRQ(0, (uint8_t *)0, 0); epstatus = SET_NAK_RX(epstatus); epstatus = SET_VALID_TX(epstatus); } }else if (ep.rx_flag || ep.tx_flag){ // got data over EP0 or host acknowlegement || package transmitted if(ep.rx_flag){ /*if (set_featuring){ set_featuring = 0; // here we can do something with ep.rx_buf - set_feature }*/ // Close transaction #ifdef EBUG hexdump(ep.rx_buf, ep.rx_cnt); #endif }else{ // tx // now we can change address after enumeration if ((USB->DADDR & USB_DADDR_ADD) != USB_Dev.USB_Addr){ USB->DADDR = USB_DADDR_EF | USB_Dev.USB_Addr; // change state to ADRESSED USB_Dev.USB_Status = USB_ADRESSED_STATE; } } // end of transaction epstatus = CLEAR_DTOG_RX(epstatus); epstatus = CLEAR_DTOG_TX(epstatus); epstatus = SET_VALID_RX(epstatus); epstatus = SET_VALID_TX(epstatus); } #ifdef EBUG if(_2wr){ usart_putchar(' '); if (ep.rx_flag) usart_putchar('r'); else usart_putchar('t'); printu(setup_packet.wLength); if(ep.setup_flag) usart_putchar('s'); usart_putchar(' '); usart_putchar('I'); printu(setup_packet.wIndex); usart_putchar('V'); printu(setup_packet.wValue); usart_putchar('R'); printu(setup_packet.bRequest); usart_putchar('T'); printu(setup_packet.bmRequestType); usart_putchar(' '); usart_putchar('0' + ep0dbuflen); usart_putchar(' '); hexdump(ep0databuf, ep0dbuflen); usart_putchar('\n'); _2wr = 0; } #endif return epstatus; } #undef WRITEDUMP static uint16_t lastaddr = USB_EP0_BASEADDR; /** * Endpoint initialisation * !!! when working with CAN bus change USB_BTABLE_SIZE to 768 !!! * @param number - EP num (0...7) * @param type - EP type (EP_TYPE_BULK, EP_TYPE_CONTROL, EP_TYPE_ISO, EP_TYPE_INTERRUPT) * @param txsz - transmission buffer size @ USB/CAN buffer * @param rxsz - reception buffer size @ USB/CAN buffer * @param uint16_t (*func)(ep_t *ep) - EP handler function * @return 0 if all OK */ int EP_Init(uint8_t number, uint8_t type, uint16_t txsz, uint16_t rxsz, uint16_t (*func)(ep_t ep)){ if(number >= ENDPOINTS_NUM) return 4; // out of configured amount if(txsz > USB_BTABLE_SIZE || rxsz > USB_BTABLE_SIZE) return 1; // buffer too large if(lastaddr + txsz + rxsz >= USB_BTABLE_SIZE) return 2; // out of btable USB->EPnR[number] = (type << 9) | (number & USB_EPnR_EA); USB->EPnR[number] ^= USB_EPnR_STAT_RX | USB_EPnR_STAT_TX_1; if(rxsz & 1 || rxsz > 992) return 3; // wrong rx buffer size uint16_t countrx = 0; if(rxsz < 64) countrx = rxsz / 2; else{ if(rxsz & 0x1f) return 3; // should be multiple of 32 countrx = 31 + rxsz / 32; } USB_BTABLE->EP[number].USB_ADDR_TX = lastaddr; endpoints[number].tx_buf = (uint16_t *)(USB_BTABLE_BASE + lastaddr); endpoints[number].txbufsz = txsz; lastaddr += txsz; USB_BTABLE->EP[number].USB_COUNT_TX = 0; USB_BTABLE->EP[number].USB_ADDR_RX = lastaddr; endpoints[number].rx_buf = (uint8_t *)(USB_BTABLE_BASE + lastaddr); lastaddr += rxsz; // buffer size: Table127 of RM USB_BTABLE->EP[number].USB_COUNT_RX = countrx << 10; endpoints[number].func = func; return 0; } // standard IRQ handler void usb_isr(){ // disallow interrupts USB->CNTR = 0; if (USB->ISTR & USB_ISTR_RESET){ USB->ISTR = 0; // Endpoint 0 - CONTROL // ON USB LS size of EP0 may be 8 bytes, but on FS it should be 64 bytes! lastaddr = USB_EP0_BASEADDR; // roll back to beginning of buffer EP_Init(0, EP_TYPE_CONTROL, USB_EP0_BUFSZ, USB_EP0_BUFSZ, EP0_Handler); // clear address, leave only enable bit USB->DADDR = USB_DADDR_EF; // state is default - wait for enumeration USB_Dev.USB_Status = USB_DEFAULT_STATE; } if(USB->ISTR & USB_ISTR_CTR){ // EP number uint8_t n = USB->ISTR & USB_ISTR_EPID; // copy status register uint16_t epstatus = USB->EPnR[n]; // Calculate flags endpoints[n].rx_flag = (epstatus & USB_EPnR_CTR_RX) ? 1 : 0; endpoints[n].setup_flag = (epstatus & USB_EPnR_SETUP) ? 1 : 0; endpoints[n].tx_flag = (epstatus & USB_EPnR_CTR_TX) ? 1 : 0; // copy received bytes amount endpoints[n].rx_cnt = USB_BTABLE->EP[n].USB_COUNT_RX & 0x3FF; // low 10 bits is counter // check direction if(USB->ISTR & USB_ISTR_DIR){ // OUT interrupt - receive data, CTR_RX==1 (if CTR_TX == 1 - two pending transactions: receive following by transmit) if(n == 0){ // control endpoint if(epstatus & USB_EPnR_SETUP){ // setup packet -> copy data to conf_pack memcpy(&setup_packet, endpoints[0].rx_buf, sizeof(setup_packet)); ep0dbuflen = 0; // interrupt handler will be called later }else if(epstatus & USB_EPnR_CTR_RX){ // data packet -> push received data to ep0databuf ep0dbuflen = endpoints[0].rx_cnt; memcpy(ep0databuf, endpoints[0].rx_buf, ep0dbuflen); } } }else{ // IN interrupt - transmit data, only CTR_TX == 1 // enumeration end could be here (if EP0) } // prepare status field for EP handler endpoints[n].status = epstatus; // call EP handler (even if it will change EPnR, it should return new status) epstatus = endpoints[n].func(endpoints[n]); // keep DTOG state epstatus = KEEP_DTOG_TX(epstatus); epstatus = KEEP_DTOG_RX(epstatus); // clear all RX/TX flags epstatus = CLEAR_CTR_RX(epstatus); epstatus = CLEAR_CTR_TX(epstatus); // refresh EPnR USB->EPnR[n] = epstatus; } // allow interrupts USB->CNTR = USB_CNTR_RESETM | USB_CNTR_CTRM; } /** * Write data to EP buffer (called from IRQ handler) * @param number - EP number * @param *buf - array with data * @param size - its size */ void EP_WriteIRQ(uint8_t number, const uint8_t *buf, uint16_t size){ uint8_t i; if(size > endpoints[number].txbufsz) size = endpoints[number].txbufsz; uint16_t N2 = (size + 1) >> 1; // the buffer is 16-bit, so we should copy data as it would be uint16_t uint16_t *buf16 = (uint16_t *)buf; for (i = 0; i < N2; i++){ endpoints[number].tx_buf[i] = buf16[i]; } USB_BTABLE->EP[number].USB_COUNT_TX = size; } /** * Write data to EP buffer (called outside IRQ handler) * @param number - EP number * @param *buf - array with data * @param size - its size */ void EP_Write(uint8_t number, const uint8_t *buf, uint16_t size){ uint16_t status = USB->EPnR[number]; EP_WriteIRQ(number, buf, size); status = SET_NAK_RX(status); status = SET_VALID_TX(status); status = KEEP_DTOG_TX(status); status = KEEP_DTOG_RX(status); USB->EPnR[number] = status; } /* * Copy data from EP buffer into user buffer area * @param *buf - user array for data * @return amount of data read */ int EP_Read(uint8_t number, uint8_t *buf){ int n = endpoints[number].rx_cnt; if(n){ for(int i = 0; i < n; ++i) buf[i] = endpoints[number].rx_buf[i]; } return n; } // USB status uint8_t USB_GetState(){ return USB_Dev.USB_Status; }