/* * avrftdi - extension for avrdude, Wolfgang Moser, Ville Voipio * Copyright (C) 2011 Hannes Weisbach, Doug Springer * * 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 . */ /* $Id$ */ /* * Interface to the MPSSE Engine of FTDI Chips using libftdi. */ #include "ac_cfg.h" #include #include #include #include #include #include #include #include #include #include #include "avrdude.h" #include "avr.h" #include "pgm.h" #include "pindefs.h" #include "avrftdi.h" #include "avrpart.h" #include "avrftdi_tpi.h" #include "avrftdi_private.h" #ifdef DO_NOT_BUILD_AVRFTDI static int avrftdi_noftdi_open (struct programmer_t *pgm, char * name) { fprintf(stderr, "%s: Error: no libftdi or libusb support. Install libftdi1/libusb-1.0 or libftdi/libusb and run configure/make again.\n", progname); return -1; } void avrftdi_initpgm(PROGRAMMER * pgm) { strcpy(pgm->type, "avrftdi"); pgm->open = avrftdi_noftdi_open; } #else enum { FTDI_SCK = 0, FTDI_MOSI, FTDI_MISO, FTDI_RESET }; /* This is for running the code without having a FTDI-device. * The generated code is useless! For debugging purposes only. * This should never be defined, unless you know what you are * doing. * If you think you know what you are doing: YOU DONT! */ //#define DRYRUN static int write_flush(avrftdi_t *); /* * returns a human-readable name for a pin number. the name should match with * the pin names used in FTDI datasheets. */ static char* ftdi_pin_name(avrftdi_t* pdata, struct pindef_t pin) { static char str[128]; char interface = '@'; /* INTERFACE_ANY is zero, so @ is used * INTERFACE_A is one, so '@' + 1 = 'A' * and so forth ... * be aware, there is an 'interface' member in ftdi_context, * however, we really want the 'index' member here. */ interface += pdata->ftdic->index; int pinno; int n = 0; int mask = pin.mask[0]; const char * fmt; str[0] = 0; for(pinno = 0; mask; mask >>= 1, pinno++) { if(!(mask & 1)) continue; int chars = 0; char port; /* This is FTDI's naming scheme. * probably 'D' is for data and 'C' for control */ if(pinno < 8) port = 'D'; else port = 'C'; if(str[0] == 0) fmt = "%c%cBUS%d%n"; else fmt = ", %c%cBUS%d%n"; snprintf(&str[n], sizeof(str) - n, fmt, interface, port, pinno, &chars); n += chars; } return str; } /* * output function, to save if(vebose>level)-constructs. also prefixes output * with "avrftdi function-name(line-number):" to identify were messages came * from. * This function is the backend of the log_*-macros, but it can be used * directly. */ void avrftdi_log(int level, const char * func, int line, const char * fmt, ...) { static int skip_prefix = 0; const char *p = fmt; va_list ap; if(verbose >= level) { if(!skip_prefix) { switch(level) { case ERR: fprintf(stderr, "E "); break; case WARN: fprintf(stderr, "W "); break; case INFO: fprintf(stderr, "I "); break; case DEBUG: fprintf(stderr, "D "); break; case TRACE: fprintf(stderr, "T "); break; default: fprintf(stderr, " "); } fprintf(stderr, "%s(%d): ", func, line); } va_start(ap, fmt); vfprintf(stderr, fmt, ap); va_end(ap); } skip_prefix = 1; while(*p++) if(*p == '\n' && !(*(p+1))) skip_prefix = 0; } /* * helper function to print a binary buffer *buf of size len. begin and end of * the dump are enclosed in the string contained in *desc. offset denotes the * number of bytes which are printed on the first line (may be 0). after that * width bytes are printed on each line */ static void buf_dump(unsigned char *buf, int len, char *desc, int offset, int width) { int i; fprintf(stderr, "%s begin:\n", desc); for (i = 0; i < offset; i++) fprintf(stderr, "%02x ", buf[i]); fprintf(stderr, "\n"); for (i++; i <= len; i++) { fprintf(stderr, "%02x ", buf[i-1]); if((i-offset) != 0 && (i-offset)%width == 0) fprintf(stderr, "\n"); } fprintf(stderr, "%s end\n", desc); } /* * calculates the so-called 'divisor'-value from a given frequency. * the divisor is sent to the chip. */ static int set_frequency(avrftdi_t* ftdi, uint32_t freq) { uint32_t divisor; uint8_t buf[3]; /* divisor on 6000000 / freq - 1 */ divisor = (6000000 / freq) - 1; if (divisor < 0) { log_warn("Frequency too high (%u > 6 MHz)\n", freq); log_warn("Resetting Frequency to 6MHz\n"); divisor = 0; } if (divisor > 65535) { log_warn("Frequency too low (%u < 91.553 Hz)\n", freq); log_warn("Resetting Frequency to 91.553Hz\n"); divisor = 65535; } log_info("Using frequency: %d\n", 6000000/(divisor+1)); log_info("Clock divisor: 0x%04x\n", divisor); buf[0] = TCK_DIVISOR; buf[1] = (uint8_t)(divisor & 0xff); buf[2] = (uint8_t)((divisor >> 8) & 0xff); #ifndef DRYRUN E(ftdi_write_data(ftdi->ftdic, buf, 3) < 0, ftdi->ftdic); #endif return 0; } /* * This function sets or clears any pin, except SCK, MISO and MOSI. Depending * on the pin configuration, a non-zero value sets the pin in the 'active' * state (high active, low active) and a zero value sets the pin in the * inactive state. * Because we configured the pin direction mask earlier, nothing bad can happen * here. */ static int set_pin(PROGRAMMER * pgm, int pinfunc, int value) { avrftdi_t* pdata = to_pdata(pgm); struct pindef_t pin = pgm->pin[pinfunc]; if (pin.mask[0] == 0) { // ignore not defined pins (might be the led or vcc or buff if not needed) return 0; } log_debug("Setting pin %s (%s) as %s: %s (%s active)\n", pinmask_to_str(pin.mask), ftdi_pin_name(pdata, pin), avr_pin_name(pinfunc), (value) ? "high" : "low", (pin.inverse[0]) ? "low" : "high"); pdata->pin_value = SET_BITS_0(pdata->pin_value, pgm, pinfunc, value); return write_flush(pdata); } /* * Mandatory callbacks which boil down to GPIO. */ static int set_led_pgm(struct programmer_t * pgm, int value) { return set_pin(pgm, PIN_LED_PGM, value); } static int set_led_rdy(struct programmer_t * pgm, int value) { return set_pin(pgm, PIN_LED_RDY, value); } static int set_led_err(struct programmer_t * pgm, int value) { return set_pin(pgm, PIN_LED_ERR, value); } static int set_led_vfy(struct programmer_t * pgm, int value) { return set_pin(pgm, PIN_LED_VFY, value); } static void avrftdi_enable(PROGRAMMER * pgm) { set_pin(pgm, PPI_AVR_BUFF, ON); } static void avrftdi_disable(PROGRAMMER * pgm) { set_pin(pgm, PPI_AVR_BUFF, OFF); } static void avrftdi_powerup(PROGRAMMER * pgm) { set_pin(pgm, PPI_AVR_VCC, ON); } static void avrftdi_powerdown(PROGRAMMER * pgm) { set_pin(pgm, PPI_AVR_VCC, OFF); } static inline int set_data(PROGRAMMER * pgm, unsigned char *buf, unsigned char data, bool read_data) { int j; int buf_pos = 0; unsigned char bit = 0x80; avrftdi_t* pdata = to_pdata(pgm); for (j=0; j<8; j++) { pdata->pin_value = SET_BITS_0(pdata->pin_value,pgm,PIN_AVR_MOSI,data & bit); pdata->pin_value = SET_BITS_0(pdata->pin_value,pgm,PIN_AVR_SCK,0); buf[buf_pos++] = SET_BITS_LOW; buf[buf_pos++] = (pdata->pin_value) & 0xff; buf[buf_pos++] = (pdata->pin_direction) & 0xff; buf[buf_pos++] = SET_BITS_HIGH; buf[buf_pos++] = ((pdata->pin_value) >> 8) & 0xff; buf[buf_pos++] = ((pdata->pin_direction) >> 8) & 0xff; pdata->pin_value = SET_BITS_0(pdata->pin_value,pgm,PIN_AVR_SCK,1); buf[buf_pos++] = SET_BITS_LOW; buf[buf_pos++] = (pdata->pin_value) & 0xff; buf[buf_pos++] = (pdata->pin_direction) & 0xff; buf[buf_pos++] = SET_BITS_HIGH; buf[buf_pos++] = ((pdata->pin_value) >> 8) & 0xff; buf[buf_pos++] = ((pdata->pin_direction) >> 8) & 0xff; if (read_data) { buf[buf_pos++] = GET_BITS_LOW; buf[buf_pos++] = GET_BITS_HIGH; } bit >>= 1; } return buf_pos; } static inline unsigned char extract_data(PROGRAMMER * pgm, unsigned char *buf, int offset) { int j; unsigned char bit = 0x80; unsigned char r = 0; buf += offset * 16; // 2 bytes per bit, 8 bits for (j=0; j<8; j++) { uint16_t in = buf[0] | (buf[1] << 8); if (GET_BITS_0(in,pgm,PIN_AVR_MISO)) { r |= bit; } buf += 2; // 2 bytes per input bit >>= 1; } return r; } static int avrftdi_transmit_bb(PROGRAMMER * pgm, unsigned char mode, unsigned char *buf, unsigned char *data, int buf_size) { size_t blocksize; size_t remaining = buf_size; size_t written = 0; avrftdi_t* pdata = to_pdata(pgm); // more than this does not work with FT2232D blocksize = 12;//pdata->rx_buffer_size/2; // we are reading 2 bytes per data byte while(remaining) { size_t transfer_size = (remaining > blocksize) ? blocksize : remaining; // (8*2) outputs per data byte, 6 transmit bytes per output (SET_BITS_LOW/HIGH), // (8*1) inputs per data byte, 2 transmit bytes per input (GET_BITS_LOW/HIGH), // 1x SEND_IMMEDIATE unsigned char send_buffer[(8*2*6)*transfer_size+(8*1*2)*transfer_size+7]; int len = 0; int i; for(i = 0 ; i< transfer_size; i++) { len += set_data(pgm, send_buffer + len, buf[written+i], (mode & MPSSE_DO_READ) != 0); } pdata->pin_value = SET_BITS_0(pdata->pin_value,pgm,PIN_AVR_SCK,0); send_buffer[len++] = SET_BITS_LOW; send_buffer[len++] = (pdata->pin_value) & 0xff; send_buffer[len++] = (pdata->pin_direction) & 0xff; send_buffer[len++] = SET_BITS_HIGH; send_buffer[len++] = ((pdata->pin_value) >> 8) & 0xff; send_buffer[len++] = ((pdata->pin_direction) >> 8) & 0xff; send_buffer[len++] = SEND_IMMEDIATE; E(ftdi_write_data(pdata->ftdic, send_buffer, len) != len, pdata->ftdic); if (mode & MPSSE_DO_READ) { unsigned char recv_buffer[2*16*transfer_size]; int n; int k = 0; do { n = ftdi_read_data(pdata->ftdic, &recv_buffer[k], 2*16*transfer_size - k); E(n < 0, pdata->ftdic); k += n; } while (k < transfer_size); for(i = 0 ; i< transfer_size; i++) { data[written + i] = extract_data(pgm, recv_buffer, i); } } written += transfer_size; remaining -= transfer_size; } return written; } /* Send 'buf_size' bytes from 'cmd' to device and return data from device in * buffer 'data'. * Write is only performed when mode contains MPSSE_DO_WRITE. * Read is only performed when mode contains MPSSE_DO_WRITE and MPSSE_DO_READ. */ static int avrftdi_transmit_mpsse(avrftdi_t* pdata, unsigned char mode, unsigned char *buf, unsigned char *data, int buf_size) { size_t blocksize; size_t remaining = buf_size; size_t written = 0; unsigned char cmd[3]; // unsigned char si = SEND_IMMEDIATE; cmd[0] = mode | MPSSE_WRITE_NEG; cmd[1] = ((buf_size - 1) & 0xff); cmd[2] = (((buf_size - 1) >> 8) & 0xff); //if we are not reading back, we can just write the data out if(!(mode & MPSSE_DO_READ)) blocksize = buf_size; else blocksize = pdata->rx_buffer_size; #ifndef DRYRUN E(ftdi_write_data(pdata->ftdic, cmd, sizeof(cmd)) != sizeof(cmd), pdata->ftdic); #endif while(remaining) { size_t transfer_size = (remaining > blocksize) ? blocksize : remaining; #ifndef DRYRUN E(ftdi_write_data(pdata->ftdic, &buf[written], transfer_size) != transfer_size, pdata->ftdic); #endif #if 0 if(remaining < blocksize) E(ftdi_write_data(pdata->ftdic, &si, sizeof(si)) != sizeof(si), pdata->ftdic); #endif if (mode & MPSSE_DO_READ) { int n; int k = 0; do { #ifndef DRYRUN n = ftdi_read_data(pdata->ftdic, &data[written + k], transfer_size - k); E(n < 0, pdata->ftdic); #else n = transfer_size - k; #endif k += n; } while (k < transfer_size); } written += transfer_size; remaining -= transfer_size; } return written; } static inline int avrftdi_transmit(PROGRAMMER * pgm, unsigned char mode, unsigned char *buf, unsigned char *data, int buf_size) { avrftdi_t* pdata = to_pdata(pgm); if (pdata->use_bitbanging) return avrftdi_transmit_bb(pgm, mode, buf, data, buf_size); else return avrftdi_transmit_mpsse(pdata, mode, buf, data, buf_size); } /* this function tries to sync up with the FTDI. See FTDI application note AN_129. * AN_135 uses 0xab as bad command and enables/disables loopback around synchronisation. * This may fail if data is left in the buffer (i.e. avrdude aborted with ctrl-c) * or the device is in an illegal state (i.e. a previous program). * If the FTDI is out of sync, the buffers are cleared ("purged") and the * sync is re-tried. * if it still fails, we return an error code. higher level code may than abort. * the device may be reset by unplugging the device and plugging it back in. * resetting the device did not always help for me. */ static int ftdi_sync(avrftdi_t* pdata) { unsigned char illegal_cmd[] = {0xaa}; unsigned char reply[2]; unsigned int i, n; unsigned int retry = 0; unsigned char latency; ftdi_get_latency_timer(pdata->ftdic, &latency); fprintf(stderr, "Latency: %d\n", latency); do{ n = ftdi_read_data(pdata->ftdic, reply, 1); } while(n > 0); retry: /* send command "0xaa", which is an illegal command. */ E(ftdi_write_data(pdata->ftdic, illegal_cmd, sizeof(illegal_cmd)) != sizeof(illegal_cmd), pdata->ftdic); i = 0; do { #ifndef DRYRUN n = ftdi_read_data(pdata->ftdic, &reply[i], sizeof(reply) - i); E(n < 0, pdata->ftdic); //fprintf(stderr, "%s\n", ftdi_get_error_string(pdata->ftdic)); #else n = sizeof(reply) - i; #endif i += n; } while (i < sizeof(reply)); /* 0xfa is return code for illegal command - we expect that, since we issued an * illegal command (0xaa) * the next byte will be the illegal command, the FTDI is complaining about. */ if(reply[0] == 0xfa && reply[1] == illegal_cmd[0]) { /* if the FTDI is complaining about the right thing, everything is fine */ fprintf(stderr, "FTDI is in sync.\n"); return 0; } else { fprintf(stderr, "FTDI out of sync. Received 0x%02x 0x%02x\n", reply[0], reply[1]); if(retry < 4) { fprintf(stderr, "Trying to re-sync by purging buffers. Attempt\n"); E(ftdi_usb_purge_buffers(pdata->ftdic), pdata->ftdic); retry++; goto retry; } else fprintf(stderr, "Aborting. Try resetting or unplugging the device.\n"); } return -1; } static int write_flush(avrftdi_t* pdata) { unsigned char buf[6]; log_debug("Setting pin direction (0x%04x) and value (0x%04x)\n", pdata->pin_direction, pdata->pin_value); buf[0] = SET_BITS_LOW; buf[1] = (pdata->pin_value) & 0xff; buf[2] = (pdata->pin_direction) & 0xff; buf[3] = SET_BITS_HIGH; buf[4] = ((pdata->pin_value) >> 8) & 0xff; buf[5] = ((pdata->pin_direction) >> 8) & 0xff; #ifndef DRYRUN E(ftdi_write_data(pdata->ftdic, buf, 6) != 6, pdata->ftdic); #endif log_trace("Set pins command: %02x %02x %02x %02x %02x %02x\n", buf[0], buf[1], buf[2], buf[3], buf[4], buf[5]); /* we need to flush here, because set_pin is used as reset. * if we want to sleep reset periods, we must be certain the * avr has got the reset signal when we start sleeping. * (it may be stuck in the USB stack or some USB hub) * * Add.: purge does NOT flush. It clears. Also, it is unkown, when the purge * command actually arrives at the chip. * Use read pin status command as sync. */ #ifndef DRYRUN //E(ftdi_usb_purge_buffers(pdata->ftdic), pdata->ftdic); unsigned char cmd[] = { GET_BITS_LOW, SEND_IMMEDIATE }; E(ftdi_write_data(pdata->ftdic, cmd, sizeof(cmd)) != sizeof(cmd), pdata->ftdic); int num = 0; do { int n = ftdi_read_data(pdata->ftdic, buf, sizeof(buf)); if(n > 0) num += n; E(n < 0, pdata->ftdic); } while(num < 1); if(num > 1) log_warn("Read %d extra bytes\n", num-1); #endif return 0; } static int avrftdi_check_pins_bb(PROGRAMMER * pgm, bool output) { int pin; /* pin checklist. */ struct pin_checklist_t pin_checklist[N_PINS]; avrftdi_t* pdata = to_pdata(pgm); /* value for 8/12/16 bit wide interface */ int valid_mask = ((1 << pdata->pin_limit) - 1); log_debug("Using valid mask bibanging: 0x%08x\n", valid_mask); static struct pindef_t valid_pins; valid_pins.mask[0] = valid_mask; valid_pins.inverse[0] = valid_mask ; /* build pin checklist */ for(pin = 0; pin < N_PINS; ++pin) { pin_checklist[pin].pinname = pin; pin_checklist[pin].mandatory = 0; pin_checklist[pin].valid_pins = &valid_pins; } /* assumes all checklists above have same number of entries */ return pins_check(pgm, pin_checklist, N_PINS, output); } static int avrftdi_check_pins_mpsse(PROGRAMMER * pgm, bool output) { int pin; /* pin checklist. */ struct pin_checklist_t pin_checklist[N_PINS]; avrftdi_t* pdata = to_pdata(pgm); /* SCK/MOSI/MISO are fixed and not invertable?*/ /* TODO: inverted SCK/MISO/MOSI */ static const struct pindef_t valid_pins_SCK = {{0x01},{0x00}} ; static const struct pindef_t valid_pins_MOSI = {{0x02},{0x00}} ; static const struct pindef_t valid_pins_MISO = {{0x04},{0x00}} ; /* value for 8/12/16 bit wide interface for other pins */ int valid_mask = ((1 << pdata->pin_limit) - 1); /* mask out SCK/MISO/MOSI */ valid_mask &= ~((1 << FTDI_SCK) | (1 << FTDI_MOSI) | (1 << FTDI_MISO)); log_debug("Using valid mask mpsse: 0x%08x\n", valid_mask); static struct pindef_t valid_pins_others; valid_pins_others.mask[0] = valid_mask; valid_pins_others.inverse[0] = valid_mask ; /* build pin checklist */ for(pin = 0; pin < N_PINS; ++pin) { pin_checklist[pin].pinname = pin; pin_checklist[pin].mandatory = 0; pin_checklist[pin].valid_pins = &valid_pins_others; } /* now set mpsse specific pins */ pin_checklist[PIN_AVR_SCK].mandatory = 1; pin_checklist[PIN_AVR_SCK].valid_pins = &valid_pins_SCK; pin_checklist[PIN_AVR_MOSI].mandatory = 1; pin_checklist[PIN_AVR_MOSI].valid_pins = &valid_pins_MOSI; pin_checklist[PIN_AVR_MISO].mandatory = 1; pin_checklist[PIN_AVR_MISO].valid_pins = &valid_pins_MISO; pin_checklist[PIN_AVR_RESET].mandatory = 1; /* assumes all checklists above have same number of entries */ return pins_check(pgm, pin_checklist, N_PINS, output); } static int avrftdi_pin_setup(PROGRAMMER * pgm) { int pin; /************* * pin setup * *************/ avrftdi_t* pdata = to_pdata(pgm); bool pin_check_mpsse = (0 == avrftdi_check_pins_mpsse(pgm, verbose>3)); bool pin_check_bitbanging = (0 == avrftdi_check_pins_bb(pgm, verbose>3)); if (!pin_check_mpsse && !pin_check_bitbanging) { log_err("No valid pin configuration found.\n"); avrftdi_check_pins_bb(pgm, true); log_err("Pin configuration for FTDI MPSSE must be:\n"); log_err("%s: 0, %s: 1, %s: 2 (is: %s, %s, %s)\n", avr_pin_name(PIN_AVR_SCK), avr_pin_name(PIN_AVR_MOSI), avr_pin_name(PIN_AVR_MISO), pins_to_str(&pgm->pin[PIN_AVR_SCK]), pins_to_str(&pgm->pin[PIN_AVR_MOSI]), pins_to_str(&pgm->pin[PIN_AVR_MISO])); log_err("If other pin configuration is used, fallback to slower bitbanging mode is used.\n"); return -1; } pdata->use_bitbanging = !pin_check_mpsse || 1; if (pdata->use_bitbanging) log_info("Because of pin configuration fallback to bitbanging mode.\n"); /* * TODO: No need to fail for a wrongly configured led or something. * Maybe we should only fail for SCK; MISO, MOSI, RST (and probably * VCC and BUFF). */ /* everything is an output, except MISO */ for(pin = 0; pin < N_PINS; ++pin) { pdata->pin_direction |= pgm->pin[pin].mask[0]; pdata->pin_value = SET_BITS_0(pdata->pin_value, pgm, pin, OFF); } pdata->pin_direction &= ~pgm->pin[PIN_AVR_MISO].mask[0]; for(pin = PIN_LED_ERR; pin < N_PINS; ++pin) { pdata->led_mask |= pgm->pin[pin].mask[0]; } log_info("Pin direction mask: %04x\n", pdata->pin_direction); log_info("Pin value mask: %04x\n", pdata->pin_value); return 0; } static int avrftdi_open(PROGRAMMER * pgm, char *port) { int vid, pid, interface, index, err; char * serial, *desc; avrftdi_t* pdata = to_pdata(pgm); /************************ * parameter validation * ************************/ /* use vid/pid in following priority: config, * defaults. cmd-line is currently not supported */ if (pgm->usbvid) vid = pgm->usbvid; else vid = 0x0403; if (pgm->usbpid) pid = pgm->usbpid; else pid = 0x6010; if (0 == pgm->usbsn[0]) /* we don't care about SN. Use first avail. */ serial = NULL; else serial = pgm->usbsn; /* not used yet, but i put them here, just in case someone does needs or * wants to implement this. */ desc = NULL; index = 0; if (pgm->usbdev[0] == 'a' || pgm->usbdev[0] == 'A') interface = INTERFACE_A; else if (pgm->usbdev[0] == 'b' || pgm->usbdev[0] == 'B') interface = INTERFACE_B; else { log_warn("Invalid interface '%s'. Setting to Interface A\n", pgm->usbdev); interface = INTERFACE_A; } /**************** * Device setup * ****************/ E(ftdi_set_interface(pdata->ftdic, interface) < 0, pdata->ftdic); err = ftdi_usb_open_desc_index(pdata->ftdic, vid, pid, desc, serial, index); if(err) { log_err("Error %d occured: %s\n", err, ftdi_get_error_string(pdata->ftdic)); //stupid hack, because avrdude calls pgm->close() even when pgm->open() fails //and usb_dev is intialized to the last usb device from probing pdata->ftdic->usb_dev = NULL; return err; } else { log_info("Using device VID:PID %04x:%04x and SN '%s' on interface %c.\n", vid, pid, serial, INTERFACE_A == interface? 'A': 'B'); } ftdi_set_latency_timer(pdata->ftdic, 1); //ftdi_write_data_set_chunksize(pdata->ftdic, 16); //ftdi_read_data_set_chunksize(pdata->ftdic, 16); /* set SPI mode */ E(ftdi_set_bitmode(pdata->ftdic, 0, BITMODE_RESET) < 0, pdata->ftdic); E(ftdi_set_bitmode(pdata->ftdic, pdata->pin_direction & 0xff, BITMODE_MPSSE) < 0, pdata->ftdic); E(ftdi_usb_purge_buffers(pdata->ftdic), pdata->ftdic); /* ret = ftdi_sync(pdata); if(ret < 0) return ret; */ write_flush(pdata); if (pgm->baudrate) { set_frequency(pdata, pgm->baudrate); } else if(pgm->bitclock) { set_frequency(pdata, (uint32_t)(1.0f/pgm->bitclock)); } else { set_frequency(pdata, pgm->baudrate ? pgm->baudrate : 150000); } /* set pin limit depending on chip type */ switch(pdata->ftdic->type) { case TYPE_AM: case TYPE_BM: case TYPE_R: log_err("Found unsupported device type AM, BM or R. avrftdi "); log_err("cannot work with your chip. Try the 'synbb' programmer.\n"); return -1; case TYPE_2232C: pdata->pin_limit = 12; pdata->rx_buffer_size = 384; break; case TYPE_2232H: pdata->pin_limit = 16; pdata->rx_buffer_size = 4096; break; #ifdef HAVE_LIBFTDI_TYPE_232H case TYPE_232H: pdata->pin_limit = 16; pdata->rx_buffer_size = 1024; break; #else #warning No support for 232H, use a newer libftdi, version >= 0.20 #endif case TYPE_4232H: pdata->pin_limit = 8; pdata->rx_buffer_size = 2048; break; default: log_warn("Found unkown device %x. I will do my ", pdata->ftdic->type); log_warn("best to work with it, but no guarantees ...\n"); pdata->pin_limit = 8; pdata->rx_buffer_size = pdata->ftdic->max_packet_size; break; } if(avrftdi_pin_setup(pgm)) return -1; /********************************************** * set the ready LED and set our direction up * **********************************************/ set_led_rdy(pgm,0); set_led_pgm(pgm,1); return 0; } static void avrftdi_close(PROGRAMMER * pgm) { avrftdi_t* pdata = to_pdata(pgm); if(pdata->ftdic->usb_dev) { set_pin(pgm, PIN_AVR_RESET, ON); /* Stop driving the pins - except for the LEDs */ log_info("LED Mask=0x%04x value =0x%04x &=0x%04x\n", pdata->led_mask, pdata->pin_value, pdata->led_mask & pdata->pin_value); pdata->pin_direction = pdata->led_mask; pdata->pin_value &= pdata->led_mask; write_flush(pdata); #ifndef DRYRUN /* reset state recommended by FTDI */ ftdi_set_bitmode(pdata->ftdic, 0, BITMODE_RESET); E_VOID(ftdi_usb_close(pdata->ftdic), pdata->ftdic); #endif } return; } static int avrftdi_initialize(PROGRAMMER * pgm, AVRPART * p) { avrftdi_powerup(pgm); if(p->flags & AVRPART_HAS_TPI) { /* see avrftdi_tpi.c */ avrftdi_tpi_initialize(pgm, p); } else { set_pin(pgm, PIN_AVR_RESET, OFF); set_pin(pgm, PIN_AVR_SCK, OFF); /*use speed optimization with CAUTION*/ usleep(20 * 1000); /* giving rst-pulse of at least 2 avr-clock-cycles, for * security (2us @ 1MHz) */ set_pin(pgm, PIN_AVR_RESET, ON); usleep(20 * 1000); /*setting rst back to 0 */ set_pin(pgm, PIN_AVR_RESET, OFF); /*wait at least 20ms bevor issuing spi commands to avr */ usleep(20 * 1000); } return pgm->program_enable(pgm, p); } static void avrftdi_display(PROGRAMMER * pgm, const char *p) { // print the full pin definitiions as in ft245r ? return; } static int avrftdi_cmd(PROGRAMMER * pgm, unsigned char cmd[4], unsigned char res[4]) { /* Do not use 'sizeof(cmd)'. => message from cppcheck: Using sizeof for array given as function argument returns the size of pointer. */ return avrftdi_transmit(pgm, MPSSE_DO_READ | MPSSE_DO_WRITE, cmd, res, 4); } static int avrftdi_program_enable(PROGRAMMER * pgm, AVRPART * p) { int i; unsigned char buf[4]; memset(buf, 0, sizeof(buf)); if (p->op[AVR_OP_PGM_ENABLE] == NULL) { log_err("AVR_OP_PGM_ENABLE command not defined for %s\n", p->desc); return -1; } avr_set_bits(p->op[AVR_OP_PGM_ENABLE], buf); for(i = 0; i < 4; i++) { pgm->cmd(pgm, buf, buf); if (buf[p->pollindex-1] != p->pollvalue) { log_warn("Program enable command not successful. Retrying.\n"); set_pin(pgm, PIN_AVR_RESET, ON); usleep(20); set_pin(pgm, PIN_AVR_RESET, OFF); avr_set_bits(p->op[AVR_OP_PGM_ENABLE], buf); } else return 0; } log_err("Device is not responding to program enable. Check connection.\n"); #ifndef DRYRUN return -1; #else return 0; #endif } static int avrftdi_chip_erase(PROGRAMMER * pgm, AVRPART * p) { unsigned char cmd[4]; unsigned char res[4]; if (p->op[AVR_OP_CHIP_ERASE] == NULL) { log_err("AVR_OP_CHIP_ERASE command not defined for %s\n", p->desc); return -1; } 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); return 0; } /* Load extended address byte command */ static int avrftdi_lext(PROGRAMMER *pgm, AVRPART *p, AVRMEM *m, unsigned int address) { unsigned char buf[] = { 0x00, 0x00, 0x00, 0x00 }; avr_set_bits(m->op[AVR_OP_LOAD_EXT_ADDR], buf); avr_set_addr(m->op[AVR_OP_LOAD_EXT_ADDR], buf, address); if(verbose > TRACE) buf_dump(buf, sizeof(buf), "load extended address command", 0, 16 * 3); #ifndef DRYRUN if (0 > avrftdi_transmit(pgm, MPSSE_DO_WRITE, buf, buf, 4)) return -1; #endif return 0; } static int avrftdi_eeprom_write(PROGRAMMER *pgm, AVRPART *p, AVRMEM *m, unsigned int page_size, unsigned int addr, unsigned int len) { unsigned char cmd[] = { 0x00, 0x00, 0x00, 0x00 }; unsigned char *data = &m->buf[addr]; unsigned int add; avr_set_bits(m->op[AVR_OP_WRITE], cmd); for (add = addr; add < addr + len; add++) { avr_set_addr(m->op[AVR_OP_WRITE], cmd, add); avr_set_input(m->op[AVR_OP_WRITE], cmd, *data++); if (0 > avrftdi_transmit(pgm, MPSSE_DO_WRITE, cmd, cmd, 4)) return -1; usleep((m->max_write_delay)); } return len; } static int avrftdi_eeprom_read(PROGRAMMER *pgm, AVRPART *p, AVRMEM *m, unsigned int page_size, unsigned int addr, unsigned int len) { unsigned char cmd[4]; unsigned char buffer[len], *bufptr = buffer; unsigned int add; memset(buffer, 0, sizeof(buffer)); for (add = addr; add < addr + len; add++) { memset(cmd, 0, sizeof(cmd)); avr_set_bits(m->op[AVR_OP_READ], cmd); avr_set_addr(m->op[AVR_OP_READ], cmd, add); if (0 > avrftdi_transmit(pgm, MPSSE_DO_READ | MPSSE_DO_WRITE, cmd, cmd, 4)) return -1; avr_get_output(m->op[AVR_OP_READ], cmd, bufptr++); } memcpy(m->buf + addr, buffer, len); return len; } static int avrftdi_flash_write(PROGRAMMER * pgm, AVRPART * p, AVRMEM * m, unsigned int page_size, unsigned int addr, unsigned int len) { int use_lext_address = m->op[AVR_OP_LOAD_EXT_ADDR] != NULL; unsigned int word; unsigned int poll_index; unsigned int buf_size; unsigned char poll_byte; unsigned char *buffer = &m->buf[addr]; unsigned char buf[4*len+4], *bufptr = buf; memset(buf, 0, sizeof(buf)); /* pre-check opcodes */ if (m->op[AVR_OP_LOADPAGE_LO] == NULL) { log_err("AVR_OP_LOADPAGE_LO command not defined for %s\n", p->desc); return -1; } if (m->op[AVR_OP_LOADPAGE_HI] == NULL) { log_err("AVR_OP_LOADPAGE_HI command not defined for %s\n", p->desc); return -1; } if(page_size != m->page_size) { log_warn("Parameter page_size is %d, ", page_size); log_warn("but m->page_size is %d. Using the latter.\n", m->page_size); } page_size = m->page_size; /* if we do cross a 64k word boundary (or write the * first page), we need to issue a 'load extended * address byte' command, which is defined as 0x4d * 0x00
0x00. As far as i know, this * is only available on 256k parts. 64k word is 128k * bytes. * write the command only once. */ if(use_lext_address && (((addr/2) & 0xffff0000))) { if (0 > avrftdi_lext(pgm, p, m, addr/2)) return -1; } /* prepare the command stream for the whole page */ /* addr is in bytes, but we program in words. addr/2 should be something * like addr >> WORD_SHIFT, though */ for(word = addr/2; word < (len + addr)/2; word++) { log_debug("-< bytes = %d of %d\n", word * 2, len + addr); /*setting word*/ avr_set_bits(m->op[AVR_OP_LOADPAGE_LO], bufptr); /* here is the second byte increment, just if you're wondering */ avr_set_addr(m->op[AVR_OP_LOADPAGE_LO], bufptr, word); avr_set_input(m->op[AVR_OP_LOADPAGE_LO], bufptr, *buffer++); bufptr += 4; avr_set_bits(m->op[AVR_OP_LOADPAGE_HI], bufptr); avr_set_addr(m->op[AVR_OP_LOADPAGE_HI], bufptr, word); avr_set_input(m->op[AVR_OP_LOADPAGE_HI], bufptr, *buffer++); bufptr += 4; } /* issue write page command, if available */ if (m->op[AVR_OP_WRITEPAGE] == NULL) { log_err("AVR_OP_WRITEPAGE command not defined for %s\n", p->desc); return -1; } else { avr_set_bits(m->op[AVR_OP_WRITEPAGE], bufptr); /* setting page address highbyte */ avr_set_addr(m->op[AVR_OP_WRITEPAGE], bufptr, addr/2); bufptr += 4; } buf_size = bufptr - buf; if(verbose > TRACE) buf_dump(buf, buf_size, "command buffer", 0, 16*2); log_info("Transmitting buffer of size: %d\n", buf_size); if (0 > avrftdi_transmit(pgm, MPSSE_DO_WRITE, buf, buf, buf_size)) return -1; bufptr = buf; /* find a poll byte. we cannot poll a value of 0xff, so look * for a value != 0xff */ for(poll_index = addr+len-1; poll_index > addr-1; poll_index--) if(m->buf[poll_index] != 0xff) break; if((poll_index < addr + len) && m->buf[poll_index] != 0xff) { log_info("Using m->buf[%d] = 0x%02x as polling value ", poll_index, m->buf[poll_index]); /* poll page write ready */ do { log_info("."); pgm->read_byte(pgm, p, m, poll_index, &poll_byte); } while (m->buf[poll_index] != poll_byte); log_info("\n"); } else { log_warn("No suitable byte (!=0xff) for polling found.\n"); log_warn("Trying to sleep instead, but programming errors may occur.\n"); log_warn("Be sure to verify programmed memory (no -V option)\n"); /* TODO sync write */ /* sleep */ usleep((m->max_write_delay)); } return len; } /* *Reading from flash */ static int avrftdi_flash_read(PROGRAMMER * pgm, AVRPART * p, AVRMEM * m, unsigned int page_size, unsigned int addr, unsigned int len) { OPCODE * readop; int byte, word; int use_lext_address = m->op[AVR_OP_LOAD_EXT_ADDR] != NULL; unsigned int address = addr/2; unsigned char o_buf[4*len+4]; unsigned char i_buf[4*len+4]; unsigned int index; memset(o_buf, 0, sizeof(o_buf)); memset(i_buf, 0, sizeof(i_buf)); /* pre-check opcodes */ if (m->op[AVR_OP_READ_LO] == NULL) { log_err("AVR_OP_READ_LO command not defined for %s\n", p->desc); return -1; } if (m->op[AVR_OP_READ_HI] == NULL) { log_err("AVR_OP_READ_HI command not defined for %s\n", p->desc); return -1; } if(use_lext_address && ((address & 0xffff0000))) { if (0 > avrftdi_lext(pgm, p, m, address)) return -1; } /* word addressing! */ for(word = addr/2, index = 0; word < (addr + len)/2; word++) { /* one byte is transferred via a 4-byte opcode. * TODO: reduce magic numbers */ avr_set_bits(m->op[AVR_OP_READ_LO], &o_buf[index*4]); avr_set_addr(m->op[AVR_OP_READ_LO], &o_buf[index*4], word); index++; avr_set_bits(m->op[AVR_OP_READ_HI], &o_buf[index*4]); avr_set_addr(m->op[AVR_OP_READ_HI], &o_buf[index*4], word); index++; } /* transmit, * if there was an error, we did not see, memory validation will * subsequently fail. */ if(verbose > TRACE) { buf_dump(o_buf, sizeof(o_buf), "o_buf", 0, 32); } if (0 > avrftdi_transmit(pgm, MPSSE_DO_READ | MPSSE_DO_WRITE, o_buf, i_buf, len * 4)) return -1; if(verbose > TRACE) { buf_dump(i_buf, sizeof(i_buf), "i_buf", 0, 32); } memset(&m->buf[addr], 0, page_size); /* every (read) op is 4 bytes in size and yields one byte of memory data */ for(byte = 0; byte < page_size; byte++) { if(byte & 1) readop = m->op[AVR_OP_READ_HI]; else readop = m->op[AVR_OP_READ_LO]; /* take 4 bytes and put the memory byte in the buffer at * offset addr + offset of the current byte */ avr_get_output(readop, &i_buf[byte*4], &m->buf[addr+byte]); } if(verbose > TRACE) buf_dump(&m->buf[addr], page_size, "page:", 0, 32); return len; } static int avrftdi_paged_write(PROGRAMMER * pgm, AVRPART * p, AVRMEM * m, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { if (strcmp(m->desc, "flash") == 0) return avrftdi_flash_write(pgm, p, m, page_size, addr, n_bytes); else if (strcmp(m->desc, "eeprom") == 0) return avrftdi_eeprom_write(pgm, p, m, page_size, addr, n_bytes); else return -2; } static int avrftdi_paged_load(PROGRAMMER * pgm, AVRPART * p, AVRMEM * m, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { if (strcmp(m->desc, "flash") == 0) return avrftdi_flash_read(pgm, p, m, page_size, addr, n_bytes); else if(strcmp(m->desc, "eeprom") == 0) return avrftdi_eeprom_read(pgm, p, m, page_size, addr, n_bytes); else return -2; } static void avrftdi_setup(PROGRAMMER * pgm) { avrftdi_t* pdata; pgm->cookie = malloc(sizeof(avrftdi_t)); pdata = to_pdata(pgm); #ifndef DRYRUN pdata->ftdic = ftdi_new(); if(!pdata->ftdic) { log_err("Error allocating memory.\n"); exit(-ENOMEM); } E_VOID(ftdi_init(pdata->ftdic), pdata->ftdic); #endif pdata->pin_value = 0; pdata->pin_direction = 0; pdata->led_mask = 0; } static void avrftdi_teardown(PROGRAMMER * pgm) { avrftdi_t* pdata = to_pdata(pgm); if(pdata) { #ifndef DRYRUN ftdi_deinit(pdata->ftdic); ftdi_free(pdata->ftdic); #endif free(pdata); } } void avrftdi_initpgm(PROGRAMMER * pgm) { strcpy(pgm->type, "avrftdi"); /* * mandatory functions */ pgm->initialize = avrftdi_initialize; pgm->display = avrftdi_display; pgm->enable = avrftdi_enable; pgm->disable = avrftdi_disable; pgm->powerup = avrftdi_powerup; pgm->powerdown = avrftdi_powerdown; pgm->program_enable = avrftdi_program_enable; pgm->chip_erase = avrftdi_chip_erase; pgm->cmd = avrftdi_cmd; pgm->open = avrftdi_open; pgm->close = avrftdi_close; pgm->read_byte = avr_read_byte_default; pgm->write_byte = avr_write_byte_default; /* * optional functions */ pgm->paged_write = avrftdi_paged_write; pgm->paged_load = avrftdi_paged_load; pgm->setpin = set_pin; pgm->setup = avrftdi_setup; pgm->teardown = avrftdi_teardown; pgm->rdy_led = set_led_rdy; pgm->err_led = set_led_err; pgm->pgm_led = set_led_pgm; pgm->vfy_led = set_led_vfy; } #endif /* DO_NOT_BUILD_AVRFTDI */ const char avrftdi_desc[] = "Interface to the MPSSE Engine of FTDI Chips using libftdi.";