/* * avrdude - A Downloader/Uploader for AVR device programmers * Copyright (C) 2005 Erik Walthinsen * Copyright (C) 2002-2004 Brian S. Dean * Copyright (C) 2006 David Moore * Copyright (C) 2006,2007 Joerg Wunsch * * 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, see . */ /* $Id: pickit2.c 2010-05-03 dbrown$ */ /* Based on Id: stk500v2.c 836 2009-07-10 22:39:37Z joerg_wunsch */ /* * avrdude interface for PicKit2 programmer * * The PicKit2 programmer is a cheap device capable * of 2 (bidirectional data line), 3, 4 wire SPI comms * * The PICkit2 software license doesn't allow the source to be * modified to program other devices - nor can we distribute * their source code. This program is not derived from nor does it * contain any of the pickit2 source and should be exempt from any * licensing issues. * * ISP Pinout (AVR - PICKit2 (pin)): * RST - VPP/MCLR (1) * VDD - VDD Target (2) -- possibly optional if AVR self powered * GND - GND (3) * MISO - PGD (4) * SCLK - PDC (5) * MOSI - AUX (6) */ #include "ac_cfg.h" #include #include #include #include #include "avrdude.h" #include "avr.h" #include "pgm.h" #if defined(HAVE_LIBUSB) || (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) #include #if defined(HAVE_DDK_HIDSDI_H) # include #else # include "my_ddk_hidsdi.h" #endif #include #else #if defined(HAVE_USB_H) # include #elif defined(HAVE_LUSB0_USB_H) # include #else # error "libusb needs either or " #endif #endif #if 0 #define DEBUG(...) do { fprintf(stderr, __VA_ARGS__); } while(0) #else #define DEBUG(...) ((void)0) #endif #if 0 #define DEBUGRECV(...) do { fprintf(stderr, __VA_ARGS__); } while(0) #else #define DEBUGRECV(...) ((void)0) #endif #define PICKIT2_VID 0x04d8 #define PICKIT2_PID 0x0033 #define SPI_MAX_CHUNK (64 - 10) // max packet size less the command overhead // win32native only: #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) static HANDLE open_hid(unsigned short vid, unsigned short pid); const char *usb_strerror() { return ""; } #else static int usb_open_device(struct usb_dev_handle **dev, int vid, int pid); //#define INVALID_HANDLE_VALUE NULL #define USB_ERROR_NONE 0 #define USB_ERROR_ACCESS 1 #define USB_ERROR_NOTFOUND 2 #define USB_ERROR_BUSY 16 #define USB_ERROR_IO 5 #endif // WIN32NATIVE static int pickit2_write_report(PROGRAMMER *pgm, unsigned char report[65]); static int pickit2_read_report(PROGRAMMER *pgm, unsigned char report[65]); #ifndef MIN #define MIN(X,Y) ((X) < (Y) ? (X) : (Y)) #endif /* * Private data for this programmer. */ struct pdata { #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) HANDLE usb_handle, write_event, read_event; #else struct usb_dev_handle *usb_handle; // LIBUSB STUFF #endif uint8_t clock_period; // SPI clock period in us int transaction_timeout; // usb trans timeout in ms }; #define PDATA(pgm) ((struct pdata *)(pgm->cookie)) #define CMD_NOP 0x5A #define CMD_GET_VERSION 0x76 #define CMD_SET_VDD_4(v) 0xA0, (uint8_t)((v)*2048+672), (uint8_t)(((v)*2048+672)/256), (uint8_t)((v)*36) #define CMD_SET_VPP_4(v) 0xA1, 0x40, (uint8_t)((v)*18.61), (uint8_t)((v)*13) #define CMD_READ_VDD_VPP 0xA3 #define CMD_EXEC_SCRIPT_2(len) 0xA6, (len) #define CMD_CLR_DLOAD_BUFF 0xA7 #define CMD_DOWNLOAD_DATA_2(len) 0xA8, (len) #define CMD_CLR_ULOAD_BUFF 0xA9 #define CMD_UPLOAD_DATA 0xAA #define CMD_UPLOAD_DATA_NO_LEN 0xAC #define CMD_END_OF_BUFFER 0xAD #define SCR_VDD_ON 0xFF #define SCR_VDD_OFF 0xFE #define SCR_VPP_ON 0xFB #define SCR_VPP_OFF 0xFA #define SCR_VPP_PWM_ON 0xF9 #define SCR_VPP_PWM_OFF 0xF8 #define SCR_MCLR_GND_ON 0xF7 #define SCR_MCLR_GND_OFF 0xF6 #define SCR_BUSY_LED_ON 0xF5 #define SCR_BUSY_LED_OFF 0xF4 #define SCR_SET_ICSP_DELAY_2(us) 0xEA,(us) #define SCR_SET_PINS_2(dd, cd, dv, cv) 0xF3, (((cd)!=0) | (((dd)!=0)<<1) | (((cv)!=0)<<2) | (((dv)!=0)<<3)) #define SCR_GET_PINS 0xDC #define SCR_LOOP_3(rel, cnt) 0xE9, rel, cnt #define SCR_DELAY_2(sec) ((sec)>0.0054528?0xE8:0xE7), (uint8_t)((sec)>0.0054528?(.999+(sec)/.00546):(.999+(sec)/.0000213)) #define SCR_SET_AUX_2(ad, av) 0xCF, (((ad)!=0) | (((av)!=0)<<1)) #define SCR_SPI_SETUP_PINS_4 SCR_SET_PINS_2(1,0,0,0), SCR_SET_AUX_2(0,0) #define SCR_SPI 0xC3 #define SCR_SPI_LIT_2(v) 0xC7,(v) static void pickit2_setup(PROGRAMMER * pgm) { if ((pgm->cookie = malloc(sizeof(struct pdata))) == 0) { fprintf(stderr, "%s: pickit2_setup(): Out of memory allocating private data\n", progname); exit(1); } memset(pgm->cookie, 0, sizeof(struct pdata)); PDATA(pgm)->transaction_timeout = 1500; // default value, may be overridden with -x timeout=ms PDATA(pgm)->clock_period = 10; // default value, may be overridden with -x clockrate=us or -B or -i } static void pickit2_teardown(PROGRAMMER * pgm) { free(pgm->cookie); } static int pickit2_open(PROGRAMMER * pgm, char * port) { #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) PDATA(pgm)->usb_handle = open_hid(PICKIT2_VID, PICKIT2_PID); if (PDATA(pgm)->usb_handle == INVALID_HANDLE_VALUE) { /* no PICkit2 found */ fprintf(stderr, "%s: error: could not find PICkit2 with vid=0x%x pid=0x%x\n", progname, PICKIT2_VID, PICKIT2_PID); exit(1); } else { // get the device description while we're at it short buff[PGM_DESCLEN], i; HidD_GetProductString(PDATA(pgm)->usb_handle, buff, PGM_DESCLEN); // convert from wide chars memset(&(pgm->type), 0, PGM_DESCLEN); for (i = 0; i < PGM_DESCLEN && buff[i]; i++) { pgm->type[i] = (char)buff[i]; } } #else if (usb_open_device(&(PDATA(pgm)->usb_handle), PICKIT2_VID, PICKIT2_PID) < 0) { /* no PICkit2 found */ fprintf(stderr, "%s: error: could not find PICkit2 with vid=0x%x pid=0x%x\n", progname, PICKIT2_VID, PICKIT2_PID); exit(1); } #endif if (pgm->ispdelay > 0) { PDATA(pgm)->clock_period = MIN(pgm->ispdelay, 255); } else if (pgm->bitclock > 0.0) { PDATA(pgm)->clock_period = MIN(pgm->bitclock * 1e6, 255); } return 0; } static void pickit2_close(PROGRAMMER * pgm) { #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) CloseHandle(PDATA(pgm)->usb_handle); CloseHandle(PDATA(pgm)->read_event); CloseHandle(PDATA(pgm)->write_event); #else usb_close(PDATA(pgm)->usb_handle); #endif // WIN32NATIVE } static int pickit2_initialize(PROGRAMMER * pgm, AVRPART * p) { unsigned char temp[4]; memset(temp, 0, sizeof(temp)); int errorCode = 0; /* set sck period */ if (pgm->set_sck_period) pgm->set_sck_period(pgm, pgm->bitclock); /* connect to target device -- we'll just ask for the firmware version */ char report[65] = {0, CMD_GET_VERSION, CMD_END_OF_BUFFER}; if ((errorCode = pickit2_write_report(pgm, report)) > 0) { memset(report, 0, sizeof(report)); if ((errorCode = pickit2_read_report(pgm, report)) >= 4) { if (verbose) { fprintf(stderr, "%s: %s firmware version %d.%d.%d\n", progname, pgm->desc, (int)report[1], (int)report[2], (int)report[3]); } // set the pins, apply reset, // TO DO: apply vtarget (if requested though -x option) char report[65] = { 0, CMD_SET_VDD_4(5), CMD_SET_VPP_4(5), CMD_EXEC_SCRIPT_2(24), SCR_SPI_SETUP_PINS_4, // SDO, SDI, SCK SCR_SET_ICSP_DELAY_2(PDATA(pgm)->clock_period), // slow down the SPI SCR_VDD_ON, SCR_MCLR_GND_OFF, // let reset float high SCR_VPP_PWM_ON, SCR_DELAY_2(.1), SCR_VPP_ON, SCR_DELAY_2(.1), SCR_VPP_OFF, SCR_DELAY_2(.01), SCR_MCLR_GND_ON, // reset low - programming mode SCR_DELAY_2(.1), SCR_BUSY_LED_ON, SCR_DELAY_2(.3), SCR_BUSY_LED_OFF, CMD_CLR_DLOAD_BUFF, CMD_CLR_ULOAD_BUFF, CMD_END_OF_BUFFER }; if (pickit2_write_report(pgm, report) < 0) { fprintf(stderr, "pickit2_read_report failed (ec %d). %s\n", errorCode, usb_strerror()); return -1; } } else { fprintf(stderr, "pickit2_read_report failed (ec %d). %s\n", errorCode, usb_strerror()); return -1; } } else { fprintf(stderr, "pickit2_write_report failed (ec %d). %s\n", errorCode, usb_strerror()); return -1; } if (pgm->program_enable) return pgm->program_enable(pgm, p); else return -1; } static void pickit2_disable(PROGRAMMER * pgm) { /* make sure all pins are floating & all voltages are off */ uint8_t report[65] = { 0, CMD_EXEC_SCRIPT_2(8), SCR_SET_PINS_2(1,1,0,0), SCR_SET_AUX_2(1,0), SCR_MCLR_GND_OFF, SCR_VPP_OFF, SCR_VDD_OFF, SCR_BUSY_LED_OFF, CMD_END_OF_BUFFER }; pickit2_write_report(pgm, report); return; } static void pickit2_enable(PROGRAMMER * pgm) { /* Do nothing. */ return; } static void pickit2_display(PROGRAMMER * pgm, const char * p) { DEBUG( "%s: Found \"%s\" version %d.%d.%d\n", progname, p, 1, 1, 1); return; } #define sendReport(x) #define readReport(x) 0 #if 0 static int pickit2_rdy_led (struct programmer_t * pgm, int value) { // no rdy led return 0; } static int pickit2_err_led(struct programmer_t * pgm, int value) { // there is no error led, so just flash the busy led a few times uint8_t report[65] = { 0, CMD_EXEC_SCRIPT_2(9), SCR_BUSY_LED_ON, SCR_DELAY_2(.2), SCR_BUSY_LED_OFF, SCR_DELAY_2(.2), SCR_LOOP_3(6, 9), CMD_END_OF_BUFFER }; // busy stops flashing by itself, so just return if (!value) { return 0; } return pickit2_write_report(pgm, report) != -1; } #endif static int pickit2_pgm_led (struct programmer_t * pgm, int value) { // script to set busy led appropriately uint8_t report[65] = {0, CMD_EXEC_SCRIPT_2(1), value ? SCR_BUSY_LED_ON : SCR_BUSY_LED_OFF, CMD_END_OF_BUFFER }; return pickit2_write_report(pgm, report) != -1; } static int pickit2_vfy_led (struct programmer_t * pgm, int value) { // no such thing - maybe just call pgm_led return pgm->pgm_led(pgm, value); } static void pickit2_powerup(struct programmer_t * pgm) { // turn vdd on? } static void pickit2_powerdown(struct programmer_t * pgm) { // do what? pgm->disable(pgm); } static int pickit2_program_enable(struct programmer_t * pgm, AVRPART * p) { unsigned char cmd[4]; unsigned char res[4]; if (p->op[AVR_OP_PGM_ENABLE] == NULL) { fprintf(stderr, "program enable instruction not defined for part \"%s\"\n", p->desc); return -1; } memset(cmd, 0, sizeof(cmd)); avr_set_bits(p->op[AVR_OP_PGM_ENABLE], cmd); pgm->cmd(pgm, cmd, res); if (verbose) { int i; fprintf(stderr, "program_enable(): sending command. Resp = "); for (i = 0; i < 4; i++) { fprintf(stderr, "%x ", (int)res[i]); } fprintf(stderr, "\n"); } // check for sync character if (res[2] != cmd[1]) return -2; return 0; } static int pickit2_chip_erase(struct programmer_t * pgm, AVRPART * p) { unsigned char cmd[4]; unsigned char res[4]; if (p->op[AVR_OP_CHIP_ERASE] == NULL) { fprintf(stderr, "chip erase instruction not defined for part \"%s\"\n", p->desc); return -1; } pgm->pgm_led(pgm, ON); memset(cmd, 0, sizeof(cmd)); avr_set_bits(p->op[AVR_OP_CHIP_ERASE], cmd); pgm->cmd(pgm, cmd, res); usleep(p->chip_erase_delay); pgm->initialize(pgm, p); pgm->pgm_led(pgm, OFF); return 0; } static int pickit2_paged_load(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { // only supporting flash & eeprom page reads if ((!mem->paged || page_size <= 1) || (strcmp(mem->desc, "flash") != 0 && strcmp(mem->desc, "eeprom") != 0)) { return -1; } DEBUG( "paged read ps %d, mem %s\n", page_size, mem->desc); OPCODE *readop = 0, *lext = mem->op[AVR_OP_LOAD_EXT_ADDR]; uint8_t data = 0, cmd[SPI_MAX_CHUNK], res[SPI_MAX_CHUNK]; unsigned int addr_base; unsigned int max_addr = addr + n_bytes; pgm->pgm_led(pgm, ON); for (addr_base = addr; addr_base < max_addr; ) { if ((addr_base == 0 || (addr_base % /*ext_address_boundary*/ 65536) == 0) && lext != NULL) { memset(cmd, 0, sizeof(cmd)); avr_set_bits(lext, cmd); avr_set_addr(lext, cmd, addr_base); pgm->cmd(pgm, cmd, res); } // bytes to send in the next packet -- not necessary as pickit2_spi() handles breaking up // the data into packets -- but we need to keep transfers frequent so that we can update the // status indicator bar uint32_t blockSize = MIN(65536 - (addr_base % 65536), MIN(max_addr - addr_base, SPI_MAX_CHUNK / 4)); memset(cmd, 0, sizeof(cmd)); memset(res, 0, sizeof(res)); uint8_t addr_off; for (addr_off = 0; addr_off < blockSize; addr_off++) { int addr = addr_base + addr_off, caddr = addr; if (mem->op[AVR_OP_READ_LO] != NULL && mem->op[AVR_OP_READ_HI] != NULL) { if (addr & 0x00000001) readop = mem->op[AVR_OP_READ_HI]; else readop = mem->op[AVR_OP_READ_LO]; caddr /= 2; } else if (mem->op[AVR_OP_READ] != NULL) { readop = mem->op[AVR_OP_READ]; } else { fprintf(stderr, "no read command specified\n"); return -1; } avr_set_bits(readop, &cmd[addr_off*4]); avr_set_addr(readop, &cmd[addr_off*4], caddr); } int bytes_read = pgm->spi(pgm, cmd, res, blockSize*4); if (bytes_read < 0) { fprintf(stderr, "Failed @ pgm->spi()\n"); pgm->err_led(pgm, ON); return -1; } DEBUG( "\npaged_load @ %X, wrote: %d, read: %d bytes\n", addr_base, blockSize*4, bytes_read); for (addr_off = 0; addr_off < bytes_read / 4; addr_off++) { data = 0; avr_get_output(readop, &res[addr_off*4], &data); mem->buf[addr_base + addr_off] = data; DEBUG( "%2X(%c)", (int)data, data<0x20?'.':data); } DEBUG( "\n"); addr_base += blockSize; } pgm->pgm_led(pgm, OFF); return n_bytes; } static int pickit2_commit_page(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem, unsigned long addr) { OPCODE * wp, * lext; wp = mem->op[AVR_OP_WRITEPAGE]; if (wp == NULL) { fprintf(stderr, "pickit2_commit_page(): memory \"%s\" not configured for page writes\n", mem->desc); return -1; } // adjust the address if this memory is word-addressable if ((mem->op[AVR_OP_LOADPAGE_LO]) || (mem->op[AVR_OP_READ_LO])) addr /= 2; unsigned char cmd[8]; memset(cmd, 0, sizeof(cmd)); // use the "load extended address" command, if available lext = mem->op[AVR_OP_LOAD_EXT_ADDR]; if (lext != NULL) { avr_set_bits(lext, cmd); avr_set_addr(lext, cmd, addr); } // make up the write page command in the 2nd cmd position avr_set_bits(wp, &cmd[4]); avr_set_addr(wp, &cmd[4], addr); if (lext != NULL) { // write the load extended address cmd && the write_page cmd pgm->spi(pgm, cmd, NULL, 8); } else { // write just the write_page cmd pgm->spi(pgm, &cmd[4], NULL, 4); } // just delay the max (we could do the delay in the PICkit2 if we wanted) usleep(mem->max_write_delay); return 0; } // not actually a paged write, but a bulk/batch write static int pickit2_paged_write(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { // only paged write for flash implemented if (strcmp(mem->desc, "flash") != 0 && strcmp(mem->desc, "eeprom") != 0) { fprintf(stderr, "Part does not support %d paged write of %s\n", page_size, mem->desc); return -1; } DEBUG( "page size %d mem %s supported: %d\n", page_size, mem->desc, mem->paged); DEBUG( "loadpagehi %x, loadpagelow %x, writepage %x\n", (int)mem->op[AVR_OP_LOADPAGE_HI], (int)mem->op[AVR_OP_LOADPAGE_LO], (int)mem->op[AVR_OP_WRITEPAGE]); OPCODE *writeop; uint8_t cmd[SPI_MAX_CHUNK], res[SPI_MAX_CHUNK]; unsigned int addr_base; unsigned int max_addr = addr + n_bytes; pgm->pgm_led(pgm, ON); for (addr_base = addr; addr_base < max_addr; ) { uint32_t blockSize; if (mem->paged) { blockSize = MIN(page_size - (addr_base % page_size), MIN(max_addr - addr_base, SPI_MAX_CHUNK/4) ); // bytes remaining in page } else { blockSize = 1; } memset(cmd, 0, sizeof(cmd)); memset(res, 0, sizeof(res)); uint8_t addr_off; for (addr_off = 0; addr_off < blockSize; addr_off++) { int addr = addr_base + addr_off; int caddr = 0; /* * determine which memory opcode to use */ if (mem->paged && mem->op[AVR_OP_LOADPAGE_HI] && mem->op[AVR_OP_LOADPAGE_LO]) { if (addr & 0x01) writeop = mem->op[AVR_OP_LOADPAGE_HI]; else writeop = mem->op[AVR_OP_LOADPAGE_LO]; caddr = addr / 2; } else if (mem->paged && mem->op[AVR_OP_LOADPAGE_LO]) { writeop = mem->op[AVR_OP_LOADPAGE_LO]; caddr = addr; } else if (mem->op[AVR_OP_WRITE_LO]) { writeop = mem->op[AVR_OP_WRITE_LO]; caddr = addr; // maybe this should divide by 2 & use the write_high opcode also fprintf(stderr, "Error AVR_OP_WRITE_LO defined only (where's the HIGH command?)\n"); return -1; } else { writeop = mem->op[AVR_OP_WRITE]; caddr = addr; } if (writeop == NULL) { pgm->err_led(pgm, ON); // not supported! return -1; } avr_set_bits(writeop, &cmd[addr_off*4]); avr_set_addr(writeop, &cmd[addr_off*4], caddr); avr_set_input(writeop, &cmd[addr_off*4], mem->buf[addr]); } int bytes_read = pgm->spi(pgm, cmd, res, blockSize*4); if (bytes_read < 0) { fprintf(stderr, "Failed @ pgm->spi()\n"); pgm->err_led(pgm, ON); return -1; } addr_base += blockSize; // write the page - this function looks after extended address also if (mem->paged && (((addr_base % page_size) == 0) || (addr_base == max_addr))) { DEBUG( "Calling pickit2_commit_page()\n"); pickit2_commit_page(pgm, p, mem, addr_base-1); } else if (!mem->paged) { usleep(mem->max_write_delay); } } pgm->pgm_led(pgm, OFF); return n_bytes; } static int pickit2_cmd(struct programmer_t * pgm, const unsigned char *cmd, unsigned char *res) { return pgm->spi(pgm, cmd, res, 4); } // breaks up the cmd[] data into packets & sends to the pickit2. Data shifted in is stored in res[]. static int pickit2_spi(struct programmer_t * pgm, const unsigned char *cmd, unsigned char *res, int n_bytes) { int retval = 0, temp1 = 0, temp2 = 0, count = n_bytes; while (count > 0) { uint8_t i, blockSize = MIN(count, SPI_MAX_CHUNK); uint8_t report[65] = {0, CMD_DOWNLOAD_DATA_2(blockSize)}; uint8_t *repptr = report + 3; memset(report + 3, CMD_END_OF_BUFFER, sizeof(report) - 3); // append some data to write to SPI for (i = 0; i < blockSize; i++) { *repptr++ = *cmd++; count--; // 1 less byte to pack } if (blockSize == 1) { *repptr++ = 0xa6; //CMD_EXECUTE_SCRIPT; *repptr++ = 1; *repptr++ = SCR_SPI; } else { *repptr++ = 0xa6; //CMD_EXECUTE_SCRIPT_2; *repptr++ = 4; *repptr++ = SCR_SPI; *repptr++ = 0xe9; //SCR_LOOP_3; *repptr++ = 1; *repptr++ = blockSize - 1; } // request the data read to be sent to us *repptr++ = CMD_UPLOAD_DATA; // check return values if ((temp1=pickit2_write_report(pgm, report)) < 0 || (temp2=pickit2_read_report(pgm, report)) < 0) { return -1; }/* else { int i; DEBUG( "in spi. wrote %d, read %d\n", temp1, temp2); for (i = 0; i < temp2; i++) { DEBUG( "%2.2x ", report[i]); } DEBUG( "\n"); }*/ retval = report[1]; // upload-length field repptr = &report[2]; // actual data starts here if (res) // copy data if user has specified a storage location { memcpy(res, repptr, retval); res += retval; } } return n_bytes; } #if (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) /* Func: open_hid() Desc: finds & opens device having specified VID & PID. Retn: Handle of open device or INVALID_HANDLE_VALUE on fail Note this routine is a modified function from: usbhidiocDlg.cpp : implementation file Project: usbhidioc.cpp Version: 3.0 Date: 7/18/05 by Jan Axelson (jan@Lvr.com) */ static HANDLE open_hid(unsigned short vid, unsigned short pid) { //Use a series of API calls to find a HID with a specified Vendor IF and Product ID. HANDLE returnHandle = INVALID_HANDLE_VALUE; HIDD_ATTRIBUTES Attributes; // DWORD DeviceUsage; SP_DEVICE_INTERFACE_DATA devInfoData; BOOL LastDevice = FALSE; int MemberIndex = 0; LONG Result; // were global, now just local scrap int Length = 0; PSP_DEVICE_INTERFACE_DETAIL_DATA detailData = NULL; HANDLE DeviceHandle=NULL; GUID HidGuid; HANDLE hDevInfo; ULONG Required; BOOL MyDeviceDetected = 0; /* API function: HidD_GetHidGuid Get the GUID for all system HIDs. Returns: the GUID in HidGuid. */ HidD_GetHidGuid(&HidGuid); DEBUG("\nHidD_GetHidGuid returned.\n"); /* API function: SetupDiGetClassDevs Returns: a handle to a device information set for all installed devices. Requires: the GUID returned by GetHidGuid. */ hDevInfo=SetupDiGetClassDevs (&HidGuid, NULL, NULL, DIGCF_PRESENT|DIGCF_INTERFACEDEVICE); DEBUG("\nSetupDiGetClassDevs returned 0x%x\n", hDevInfo); devInfoData.cbSize = sizeof(devInfoData); //Step through the available devices looking for the one we want. //Quit on detecting the desired device or checking all available devices without success. MemberIndex = 0; LastDevice = FALSE; do { /* API function: SetupDiEnumDeviceInterfaces On return, MyDeviceInterfaceData contains the handle to a SP_DEVICE_INTERFACE_DATA structure for a detected device. Requires: The DeviceInfoSet returned in SetupDiGetClassDevs. The HidGuid returned in GetHidGuid. An index to specify a device. */ Result=SetupDiEnumDeviceInterfaces (hDevInfo, 0, &HidGuid, MemberIndex, &devInfoData); DEBUG("\nSetupDiEnumDeviceInterfaces returned 0x%x\n", Result); if (Result != 0) { //A device has been detected, so get more information about it. /* API function: SetupDiGetDeviceInterfaceDetail Returns: an SP_DEVICE_INTERFACE_DETAIL_DATA structure containing information about a device. To retrieve the information, call this function twice. The first time returns the size of the structure in Length. The second time returns a pointer to the data in DeviceInfoSet. Requires: A DeviceInfoSet returned by SetupDiGetClassDevs The SP_DEVICE_INTERFACE_DATA structure returned by SetupDiEnumDeviceInterfaces. The final parameter is an optional pointer to an SP_DEV_INFO_DATA structure. This application doesn't retrieve or use the structure. If retrieving the structure, set MyDeviceInfoData.cbSize = length of MyDeviceInfoData. and pass the structure's address. */ //Get the Length value. //The call will return with a "buffer too small" error which can be ignored. Result = SetupDiGetDeviceInterfaceDetail (hDevInfo, &devInfoData, NULL, 0, &Length, NULL); DEBUG("\nSetupDiGetDeviceInterfaceDetail returned 0x%x\n", Result); //Allocate memory for the hDevInfo structure, using the returned Length. detailData = (PSP_DEVICE_INTERFACE_DETAIL_DATA)malloc(Length); //Set cbSize in the detailData structure. detailData -> cbSize = sizeof(SP_DEVICE_INTERFACE_DETAIL_DATA); //Call the function again, this time passing it the returned buffer size. Result = SetupDiGetDeviceInterfaceDetail (hDevInfo, &devInfoData, detailData, Length, &Required, NULL); // Open a handle to the device. // To enable retrieving information about a system mouse or keyboard, // don't request Read or Write access for this handle. /* API function: CreateFile Returns: a handle that enables reading and writing to the device. Requires: The DevicePath in the detailData structure returned by SetupDiGetDeviceInterfaceDetail. */ DeviceHandle=CreateFile (detailData->DevicePath, 0, FILE_SHARE_READ|FILE_SHARE_WRITE, (LPSECURITY_ATTRIBUTES)NULL, OPEN_EXISTING, 0, NULL); DEBUG("CreateFile(): %s\n", detailData->DevicePath); /* API function: HidD_GetAttributes Requests information from the device. Requires: the handle returned by CreateFile. Returns: a HIDD_ATTRIBUTES structure containing the Vendor ID, Product ID, and Product Version Number. Use this information to decide if the detected device is the one we're looking for. */ //Set the Size to the number of bytes in the structure. Attributes.Size = sizeof(Attributes); Result = HidD_GetAttributes (DeviceHandle, &Attributes); DEBUG("HidD_GetAttributes returned 0x%x\n", Result); DEBUG("VID: %.4X PID: %.4X\n", Attributes.VendorID, Attributes.ProductID); //Is it the desired device? MyDeviceDetected = FALSE; if (Attributes.VendorID == vid) { if (Attributes.ProductID == pid) { //Both the Vendor ID and Product ID match. MyDeviceDetected = TRUE; // Get a handle for us to use. returnHandle = CreateFile (detailData->DevicePath, GENERIC_WRITE | GENERIC_READ, FILE_SHARE_READ|FILE_SHARE_WRITE, (LPSECURITY_ATTRIBUTES)NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL); } //if (Attributes.ProductID == ProductID) else //The Product ID doesn't match. CloseHandle(DeviceHandle); } //if (Attributes.VendorID == VendorID) else //The Vendor ID doesn't match. CloseHandle(DeviceHandle); //Free the memory used by the detailData structure (no longer needed). free(detailData); } //if (Result != 0) else //SetupDiEnumDeviceInterfaces returned 0, so there are no more devices to check. LastDevice=TRUE; //If we haven't found the device yet, and haven't tried every available device, //try the next one. MemberIndex = MemberIndex + 1; } //do while ((LastDevice == FALSE) && (MyDeviceDetected == FALSE)); if (MyDeviceDetected == FALSE) DEBUG("Device not detected\n"); else DEBUG("Device detected\n"); //Free the memory reserved for hDevInfo by SetupDiClassDevs. DEBUG("Calling SetupDiDestroyDeviceInfoList\n"); SetupDiDestroyDeviceInfoList(hDevInfo); return returnHandle; } // simple read with timeout static int usb_read_interrupt(PROGRAMMER *pgm, void *buff, int size, int timeout) { OVERLAPPED ovr; DWORD bytesRead = 0; if (PDATA(pgm)->read_event == NULL) { PDATA(pgm)->read_event = CreateEvent(0, 0, 0, 0); } memset(&ovr, 0, sizeof(ovr)); ovr.hEvent = PDATA(pgm)->read_event; ReadFile(PDATA(pgm)->usb_handle, buff, size, &bytesRead, &ovr); if (WaitForSingleObject(PDATA(pgm)->read_event, timeout) == WAIT_TIMEOUT) { CancelIo(PDATA(pgm)->usb_handle); return -1; } GetOverlappedResult(PDATA(pgm)->usb_handle, &ovr, &bytesRead, 0); return bytesRead > 0 ? bytesRead : -1; } // simple write with timeout static int usb_write_interrupt(PROGRAMMER *pgm, void *buff, int size, int timeout) { OVERLAPPED ovr; DWORD bytesWritten = 0; if (PDATA(pgm)->write_event == NULL) { PDATA(pgm)->write_event = CreateEvent(0, 0, 0, 0); } memset(&ovr, 0, sizeof(ovr)); ovr.hEvent = PDATA(pgm)->write_event; WriteFile(PDATA(pgm)->usb_handle, buff, size, &bytesWritten, &ovr); if (WaitForSingleObject(PDATA(pgm)->write_event, timeout) == WAIT_TIMEOUT) { CancelIo(PDATA(pgm)->usb_handle); return -1; } GetOverlappedResult(PDATA(pgm)->usb_handle, &ovr, &bytesWritten, 0); return bytesWritten > 0 ? bytesWritten : -1; } static int pickit2_write_report(PROGRAMMER * pgm, unsigned char report[65]) { return usb_write_interrupt(pgm, report, 65, PDATA(pgm)->transaction_timeout); } static int pickit2_read_report(PROGRAMMER * pgm, unsigned char report[65]) { return usb_read_interrupt(pgm, report, 65, PDATA(pgm)->transaction_timeout); } #else // WIN32NATIVE /* taken (modified) from avrdude usbasp.c */ static int usb_open_device(struct usb_dev_handle **device, int vendor, int product) { struct usb_bus *bus; struct usb_device *dev; usb_dev_handle *handle = NULL; int errorCode = USB_ERROR_NOTFOUND; static int didUsbInit = 0; if (!didUsbInit) { didUsbInit = 1; usb_init(); } usb_find_busses(); usb_find_devices(); for (bus=usb_get_busses(); bus; bus=bus->next) { for (dev=bus->devices; dev; dev=dev->next) { DEBUG( "Enumerating device list.. VID: 0x%4.4x, PID: 0x%4.4x\n", dev->descriptor.idVendor, dev->descriptor.idProduct); if (dev->descriptor.idVendor == vendor && dev->descriptor.idProduct == product) { /* we need to open the device in order to query strings */ handle = usb_open(dev); if (handle == NULL) { errorCode = USB_ERROR_ACCESS; fprintf(stderr, "%s: Warning: cannot open USB device: %s\n", progname, usb_strerror()); continue; } // return with opened device handle else { if (verbose) { fprintf(stderr, "Device 0x%4.4X seemed to open OK.\n", (int)handle); } if ((errorCode = usb_set_configuration(handle, 1)) < 0) { fprintf(stderr, "Could not set configuration. Error code %d, %s.\n" "You may need to run avrdude as root or set up correct usb port permissions.", errorCode, usb_strerror()); } if ((errorCode = usb_claim_interface(handle, 0)) < 0) { fprintf(stderr, "Could not claim interface. Error code %d, %s\n" "You may need to run avrdude as root or set up correct usb port permissions.", errorCode, usb_strerror()); } errorCode = 0; *device = handle; return 0; } } } } return -1; } static int pickit2_write_report(PROGRAMMER * pgm, unsigned char report[65]) { // endpoint 1 OUT?? return usb_interrupt_write(PDATA(pgm)->usb_handle, USB_ENDPOINT_OUT | 1, report+1, 64, PDATA(pgm)->transaction_timeout); } static int pickit2_read_report(PROGRAMMER * pgm, unsigned char report[65]) { // endpoint 1 IN?? return usb_interrupt_read(PDATA(pgm)->usb_handle, USB_ENDPOINT_IN | 1, report+1, 64, PDATA(pgm)->transaction_timeout); } #endif // WIN323NATIVE static int pickit2_parseextparams(struct programmer_t * pgm, LISTID extparms) { LNODEID ln; const char *extended_param; int rv = 0; for (ln = lfirst(extparms); ln; ln = lnext(ln)) { extended_param = ldata(ln); if (strncmp(extended_param, "clockrate=", strlen("clockrate=")) == 0) { int clock_rate; if (sscanf(extended_param, "clockrate=%i", &clock_rate) != 1 || clock_rate <= 0) { fprintf(stderr, "%s: pickit2_parseextparms(): invalid clockrate '%s'\n", progname, extended_param); rv = -1; continue; } int clock_period = MIN(1000000 / clock_rate, 255); // max period is 255 clock_rate = (int)(1000000 / (clock_period + 5e-7)); // assume highest speed is 2MHz - should probably check this if (verbose >= 2) { fprintf(stderr, "%s: pickit2_parseextparms(): clockrate set to 0x%02x\n", progname, clock_rate); } PDATA(pgm)->clock_period = clock_period; continue; } if (strncmp(extended_param, "timeout=", strlen("timeout=")) == 0) { int timeout; if (sscanf(extended_param, "timeout=%i", &timeout) != 1 || timeout <= 0) { fprintf(stderr, "%s: pickit2_parseextparms(): invalid timeout '%s'\n", progname, extended_param); rv = -1; continue; } if (verbose >= 2) { fprintf(stderr, "%s: pickit2_parseextparms(): usb timeout set to 0x%02x\n", progname, timeout); } PDATA(pgm)->transaction_timeout = timeout; continue; } fprintf(stderr, "%s: pickit2_parseextparms(): invalid extended parameter '%s'\n", progname, extended_param); rv = -1; } return rv; } void pickit2_initpgm (PROGRAMMER * pgm) { /* * mandatory functions - these are called without checking to see * whether they are assigned or not */ pgm->initialize = pickit2_initialize; pgm->display = pickit2_display; pgm->enable = pickit2_enable; pgm->disable = pickit2_disable; pgm->powerup = pickit2_powerup; pgm->powerdown = pickit2_powerdown; pgm->program_enable = pickit2_program_enable; pgm->chip_erase = pickit2_chip_erase; pgm->open = pickit2_open; pgm->close = pickit2_close; pgm->read_byte = avr_read_byte_default; pgm->write_byte = avr_write_byte_default; /* * predefined functions - these functions have a valid default * implementation. Hence, they don't need to be defined in * the programmer. */ //pgm->rdy_led = pickit2_rdy_led; //pgm->err_led = pickit2_err_led; pgm->pgm_led = pickit2_pgm_led; pgm->vfy_led = pickit2_vfy_led; /* * optional functions - these are checked to make sure they are * assigned before they are called */ pgm->cmd = pickit2_cmd; pgm->spi = pickit2_spi; pgm->paged_write = pickit2_paged_write; pgm->paged_load = pickit2_paged_load; //pgm->write_setup = NULL; //pgm->read_sig_bytes = NULL; //pgm->set_vtarget = NULL;//pickit2_vtarget; //pgm->set_varef = NULL; //pgm->set_fosc = NULL; //pgm->perform_osccal = NULL; pgm->parseextparams = pickit2_parseextparams; pgm->setup = pickit2_setup; pgm->teardown = pickit2_teardown; // pgm->page_size = 256; // not sure what this does... maybe the max page size that the page read/write function can handle strncpy(pgm->type, "pickit2", sizeof(pgm->type)); } #else static int pickit2_nousb_open (struct programmer_t *pgm, char * name) { fprintf(stderr, #ifdef WIN32NATIVE "%s: error: no usb or hid support. Please compile again with libusb or HID support from Win32 DDK installed.\n", #else "%s: error: no usb support. Please compile again with libusb installed.\n", #endif progname); exit(1); } void pickit2_initpgm (PROGRAMMER * pgm) { /* * mandatory functions - these are called without checking to see * whether they are assigned or not */ pgm->open = pickit2_nousb_open; strncpy(pgm->type, "pickit2", sizeof(pgm->type)); } #endif /* defined(HAVE_LIBUSB) || (defined(WIN32NATIVE) && defined(HAVE_LIBHID)) */ const char pickit2_desc[] = "Microchip's PICkit2 Programmer";