/* * avrdude - A Downloader/Uploader for AVR device programmers * Copyright (C) 2019 Marius Greuel * Portions Copyright (C) 2014 T. Bo"scke * Portions Copyright (C) 2012 ihsan Kehribar * * 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 . */ // Notes: // This file adds support for the Micronucleus bootloader V1 and V2, // so you do no longer need the Micronucleus command-line utility. // // This bootloader is typically used on small ATtiny boards, // such as Digispark (ATtiny85), Digispark Pro (ATtiny167), // and the respective clones. // By default, it bootloader uses the VID/PID 16d0:0753 (MCS Digistump). // // As the micronucleus bootloader is optimized for size, it implements // writing to flash memory only. Since it does not support reading, // use the -V option to prevent avrdude from verifing the flash memory. // To have avrdude wait for the device to be connected, use the // extended option '-x wait'. // // Example: // avrdude -c micronucleus -p t85 -x wait -V -U flash:w:main.hex #include "ac_cfg.h" #include #include #include #include #include #include #include #include #include "avrdude.h" #include "micronucleus.h" #include "usbdevs.h" #if defined(HAVE_LIBUSB) #if defined(HAVE_USB_H) #include #elif defined(HAVE_LUSB0_USB_H) #include #else #error "libusb needs either or " #endif //----------------------------------------------------------------------------- #define MICRONUCLEUS_VID 0x16D0 #define MICRONUCLEUS_PID 0x0753 #define MICRONUCLEUS_CONNECT_WAIT 100 #define MICRONUCLEUS_CMD_INFO 0 #define MICRONUCLEUS_CMD_TRANSFER 1 #define MICRONUCLEUS_CMD_ERASE 2 #define MICRONUCLEUS_CMD_PROGRAM 3 #define MICRONUCLEUS_CMD_START 4 #define MICRONUCLEUS_DEFAULT_TIMEOUT 500 #define MICRONUCLEUS_MAX_MAJOR_VERSION 2 #define PDATA(pgm) ((pdata_t*)(pgm->cookie)) //----------------------------------------------------------------------------- typedef struct pdata { usb_dev_handle* usb_handle; // Extended parameters bool wait_until_device_present; int wait_timout; // in seconds // Bootloader version uint8_t major_version; uint8_t minor_version; // Bootloader info (via USB request) uint16_t flash_size; // programmable size (in bytes) of flash uint8_t page_size; // size (in bytes) of page uint8_t write_sleep; // milliseconds uint8_t signature1; // only used in protocol v2 uint8_t signature2; // only used in protocol v2 // Calculated bootloader info uint16_t pages; // total number of pages to program uint16_t bootloader_start; // start of the bootloader (at page boundary) uint16_t erase_sleep; // milliseconds // State uint16_t user_reset_vector; // reset vector of user program bool write_last_page; // last page already programmed bool start_program; // require start after flash } pdata_t; //----------------------------------------------------------------------------- static void delay_ms(uint32_t duration) { usleep(duration * 1000); } static int micronucleus_check_connection(pdata_t* pdata) { if (pdata->major_version >= 2) { uint8_t buffer[6] = { 0 }; int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_IN | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_INFO, 0, 0, (char*)buffer, sizeof(buffer), MICRONUCLEUS_DEFAULT_TIMEOUT); return result == sizeof(buffer) ? 0 : -1; } else { uint8_t buffer[4] = { 0 }; int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_IN | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_INFO, 0, 0, (char*)buffer, sizeof(buffer), MICRONUCLEUS_DEFAULT_TIMEOUT); return result == sizeof(buffer) ? 0 : -1; } } static bool micronucleus_is_device_responsive(pdata_t* pdata, struct usb_device* device) { pdata->usb_handle = usb_open(device); if (pdata->usb_handle == NULL) { return false; } int result = micronucleus_check_connection(pdata); usb_close(pdata->usb_handle); pdata->usb_handle = NULL; return result >= 0; } static int micronucleus_reconnect(pdata_t* pdata) { struct usb_device* device = usb_device(pdata->usb_handle); usb_close(pdata->usb_handle); pdata->usb_handle = NULL; for (int i = 0; i < 25; i++) { pmsg_notice("trying to reconnect ...\n"); pdata->usb_handle = usb_open(device); if (pdata->usb_handle != NULL) return 0; delay_ms(MICRONUCLEUS_CONNECT_WAIT); } return -1; } static int micronucleus_get_bootloader_info_v1(pdata_t* pdata) { uint8_t buffer[4] = { 0 }; int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_IN | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_INFO, 0, 0, (char*)buffer, sizeof(buffer), MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_warning("unable to get bootloader info block: %s\n", usb_strerror()); return result; } else if (result < sizeof(buffer)) { pmsg_warning("received invalid bootloader info block size: %d\n", result); return -1; } pdata->flash_size = (buffer[0] << 8) | buffer[1]; pdata->page_size = buffer[2]; pdata->write_sleep = buffer[3] & 127; // Take a wild guess on the part ID, so that we can supply it for device verification if (pdata->page_size == 128) { // ATtiny167 pdata->signature1 = 0x94; pdata->signature2 = 0x87; } else if (pdata->page_size == 64) { if (pdata->flash_size > 4096) { // ATtiny85 pdata->signature1 = 0x93; pdata->signature2 = 0x0B; } else { // ATtiny45 pdata->signature1 = 0x92; pdata->signature2 = 0x06; } } else if (pdata->page_size == 16) { // ATtiny841 pdata->signature1 = 0x93; pdata->signature2 = 0x15; } else { // Unknown device pdata->signature1 = 0; pdata->signature2 = 0; } pdata->pages = (pdata->flash_size + pdata->page_size - 1) / pdata->page_size; pdata->bootloader_start = pdata->pages * pdata->page_size; pdata->erase_sleep = pdata->write_sleep * pdata->pages; return 0; } static int micronucleus_get_bootloader_info_v2(pdata_t* pdata) { uint8_t buffer[6] = { 0 }; int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_IN | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_INFO, 0, 0, (char*)buffer, sizeof(buffer), MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_warning("unable to get bootloader info block: %s\n", usb_strerror()); return result; } else if (result < sizeof(buffer)) { pmsg_warning("received invalid bootloader info block size: %d\n", result); return -1; } pdata->flash_size = (buffer[0] << 8) + buffer[1]; pdata->page_size = buffer[2]; pdata->write_sleep = (buffer[3] & 127) + 2; pdata->signature1 = buffer[4]; pdata->signature2 = buffer[5]; pdata->pages = (pdata->flash_size + pdata->page_size - 1) / pdata->page_size; pdata->bootloader_start = pdata->pages * pdata->page_size; pdata->erase_sleep = pdata->write_sleep * pdata->pages; // if bit 7 of write sleep time is set, divide the erase time by four to // accomodate to the 4*page erase of the ATtiny841/441 if ((buffer[3] & 128) != 0) { pdata->erase_sleep /= 4; } return 0; } static int micronucleus_get_bootloader_info(pdata_t* pdata) { if (pdata->major_version >= 2) { return micronucleus_get_bootloader_info_v2(pdata); } else { return micronucleus_get_bootloader_info_v1(pdata); } } static void micronucleus_dump_device_info(pdata_t* pdata) { pmsg_notice("Bootloader version: %d.%d\n", pdata->major_version, pdata->minor_version); imsg_notice("Available flash size: %u\n", pdata->flash_size); imsg_notice("Page size: %u\n", pdata->page_size); imsg_notice("Bootloader start: 0x%04X\n", pdata->bootloader_start); imsg_notice("Write sleep: %ums\n", pdata->write_sleep); imsg_notice("Erase sleep: %ums\n", pdata->erase_sleep); imsg_notice("Signature1: 0x%02X\n", pdata->signature1); imsg_notice("Signature2: 0x%02X\n", pdata->signature2); } static int micronucleus_erase_device(pdata_t* pdata) { pmsg_debug("micronucleus_erase_device()\n"); int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_ERASE, 0, 0, NULL, 0, MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { switch (result) { case -EIO: case -EPIPE: pmsg_notice("ignoring last error of erase command: %s\n", usb_strerror()); break; default: pmsg_warning("erase command failed, code %d: %s\n", result, usb_strerror()); return result; } } delay_ms(pdata->erase_sleep); result = micronucleus_check_connection(pdata); if (result < 0) { pmsg_notice("connection dropped, trying to reconnect ...\n"); result = micronucleus_reconnect(pdata); if (result < 0) { pmsg_warning("unable to reconnect USB device: %s\n", usb_strerror()); return result; } } return 0; } static int micronucleus_patch_reset_vector(pdata_t* pdata, uint8_t* buffer) { // Save user reset vector. uint16_t word0 = (buffer[1] << 8) | buffer[0]; uint16_t word1 = (buffer[3] << 8) | buffer[2]; if (word0 == 0x940C) { // long jump pdata->user_reset_vector = word1; } else if ((word0 & 0xF000) == 0xC000) { // rjmp pdata->user_reset_vector = (word0 & 0x0FFF) + 1; } else { pmsg_error("the reset vector of the user program does not contain a branch instruction\n"); return -1; } // Patch in jmp to bootloader. if (pdata->bootloader_start > 0x2000) { // jmp uint16_t data = 0x940C; buffer[0] = (uint8_t)(data >> 0); buffer[1] = (uint8_t)(data >> 8); buffer[2] = (uint8_t)(pdata->bootloader_start >> 0); buffer[3] = (uint8_t)(pdata->bootloader_start >> 8); } else { // rjmp uint16_t data = 0xC000 | ((pdata->bootloader_start / 2 - 1) & 0x0FFF); buffer[0] = (uint8_t)(data >> 0); buffer[1] = (uint8_t)(data >> 8); } return 0; } static void micronucleus_patch_user_vector(pdata_t* pdata, uint8_t* buffer) { uint16_t user_reset_addr = pdata->bootloader_start - 4; uint16_t address = pdata->bootloader_start - pdata->page_size; if (user_reset_addr > 0x2000) { // jmp uint16_t data = 0x940C; buffer[user_reset_addr - address + 0] = (uint8_t)(data >> 0); buffer[user_reset_addr - address + 1] = (uint8_t)(data >> 8); buffer[user_reset_addr - address + 2] = (uint8_t)(pdata->user_reset_vector >> 0); buffer[user_reset_addr - address + 3] = (uint8_t)(pdata->user_reset_vector >> 8); } else { // rjmp uint16_t data = 0xC000 | ((pdata->user_reset_vector - user_reset_addr / 2 - 1) & 0x0FFF); buffer[user_reset_addr - address + 0] = (uint8_t)(data >> 0); buffer[user_reset_addr - address + 1] = (uint8_t)(data >> 8); } } static int micronucleus_write_page_v1(pdata_t* pdata, uint32_t address, uint8_t* buffer, uint32_t size) { int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_TRANSFER, size, address, (char*)buffer, size, MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_error("unable to transfer page: %s\n", usb_strerror()); return result; } return 0; } static int micronucleus_write_page_v2(pdata_t* pdata, uint32_t address, uint8_t* buffer, uint32_t size) { int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_TRANSFER, size, address, NULL, 0, MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_error("unable to transfer page: %s\n", usb_strerror()); return result; } for (int i = 0; i < size; i += 4) { int w1 = (buffer[i + 1] << 8) | (buffer[i + 0] << 0); int w2 = (buffer[i + 3] << 8) | (buffer[i + 2] << 0); result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_PROGRAM, w1, w2, NULL, 0, MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_error("unable to transfer page: %s\n", usb_strerror()); return result; } } return 0; } static int micronucleus_write_page(pdata_t* pdata, uint32_t address, uint8_t* buffer, uint32_t size) { pmsg_debug("micronucleus_write_page(address=0x%04X, size=%d)\n", address, size); if (address == 0) { if (pdata->major_version >= 2) { int result = micronucleus_patch_reset_vector(pdata, buffer); if (result < 0) { return result; } } // Require last page (with application reset vector) to be written. pdata->write_last_page = true; // Require software start. pdata->start_program = true; } else if (address >= pdata->bootloader_start - pdata->page_size) { if (pdata->major_version >= 2) { micronucleus_patch_user_vector(pdata, buffer); } // Mark last page as written. pdata->write_last_page = false; } int result; if (pdata->major_version >= 2) { result = micronucleus_write_page_v2(pdata, address, buffer, size); } else { result = micronucleus_write_page_v1(pdata, address, buffer, size); } if (result < 0) { return result; } delay_ms(pdata->write_sleep); return 0; } static int micronucleus_start(pdata_t* pdata) { pmsg_debug("micronucleus_start()\n"); int result = usb_control_msg( pdata->usb_handle, USB_ENDPOINT_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE, MICRONUCLEUS_CMD_START, 0, 0, NULL, 0, MICRONUCLEUS_DEFAULT_TIMEOUT); if (result < 0) { pmsg_warning("start command failed: %s\n", usb_strerror()); return result; } return 0; } //----------------------------------------------------------------------------- static void micronucleus_setup(PROGRAMMER* pgm) { pmsg_debug("micronucleus_setup()\n"); if ((pgm->cookie = malloc(sizeof(pdata_t))) == 0) { pmsg_error("out of memory allocating private data\n"); exit(1); } memset(pgm->cookie, 0, sizeof(pdata_t)); } static void micronucleus_teardown(PROGRAMMER* pgm) { pmsg_debug("micronucleus_teardown()\n"); free(pgm->cookie); } static int micronucleus_initialize(const PROGRAMMER *pgm, const AVRPART *p) { pmsg_debug("micronucleus_initialize()\n"); pdata_t* pdata = PDATA(pgm); int result = micronucleus_get_bootloader_info(pdata); if (result < 0) return result; micronucleus_dump_device_info(pdata); return 0; } static void micronucleus_display(const PROGRAMMER *pgm, const char *prefix) { pmsg_debug("micronucleus_display()\n"); } static void micronucleus_powerup(const PROGRAMMER *pgm) { pmsg_debug("micronucleus_powerup()\n"); } static void micronucleus_powerdown(const PROGRAMMER *pgm) { pmsg_debug("micronucleus_powerdown()\n"); pdata_t* pdata = PDATA(pgm); if (pdata->write_last_page) { pdata->write_last_page = false; uint8_t* buffer = (unsigned char*)malloc(pdata->page_size); if (buffer != NULL) { memset(buffer, 0xFF, pdata->page_size); micronucleus_write_page(pdata, pdata->bootloader_start - pdata->page_size, buffer, pdata->page_size); free(buffer); } } if (pdata->start_program) { pdata->start_program = false; micronucleus_start(pdata); } } static void micronucleus_enable(PROGRAMMER *pgm, const AVRPART *p) { pmsg_debug("micronucleus_enable()\n"); } static void micronucleus_disable(const PROGRAMMER *pgm) { pmsg_debug("micronucleus_disable()\n"); } static int micronucleus_program_enable(const PROGRAMMER *pgm, const AVRPART *p) { pmsg_debug("micronucleus_program_enable()\n"); return 0; } static int micronucleus_read_sig_bytes(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem) { pmsg_debug("micronucleus_read_sig_bytes()\n"); if (mem->size < 3) { pmsg_error("memory size %d < 3 too small for read_sig_bytes", mem->size); return -1; } pdata_t* pdata = PDATA(pgm); mem->buf[0] = 0x1E; mem->buf[1] = pdata->signature1; mem->buf[2] = pdata->signature2; return 0; } static int micronucleus_chip_erase(const PROGRAMMER *pgm, const AVRPART *p) { pmsg_debug("micronucleus_chip_erase()\n"); pdata_t* pdata = PDATA(pgm); return micronucleus_erase_device(pdata); } static int micronucleus_open(PROGRAMMER* pgm, const char *port) { pmsg_debug("micronucleus_open(\"%s\")\n", port); pdata_t* pdata = PDATA(pgm); const char *bus_name = NULL; char* dev_name = NULL; // if no -P was given or '-P usb' was given if (strcmp(port, "usb") == 0) { port = NULL; } else { // calculate bus and device names from -P option if (strncmp(port, "usb", 3) == 0 && ':' == port[3]) { bus_name = port + 4; dev_name = strchr(bus_name, ':'); if (dev_name != NULL) { *dev_name = '\0'; dev_name++; } } } if (port != NULL && dev_name == NULL) { pmsg_error("invalid -P value %s\n", port); imsg_error("use -P usb:bus:device\n"); return -1; } // Determine VID/PID int vid = pgm->usbvid ? pgm->usbvid : MICRONUCLEUS_VID; int pid = MICRONUCLEUS_PID; LNODEID usbpid = lfirst(pgm->usbpid); if (usbpid != NULL) { pid = *(int*)(ldata(usbpid)); if (lnext(usbpid)) { pmsg_warning("using PID 0x%04x, ignoring remaining PIDs in list\n", pid); } } usb_init(); bool show_retry_message = true; bool show_unresponsive_device_message = true; time_t start_time = time(NULL); for (;;) { usb_find_busses(); usb_find_devices(); pdata->usb_handle = NULL; // Search for device struct usb_bus* bus = NULL; for (bus = usb_busses; bus != NULL && pdata->usb_handle == NULL; bus = bus->next) { struct usb_device* device = NULL; for (device = bus->devices; device != NULL && pdata->usb_handle == NULL; device = device->next) { if (device->descriptor.idVendor == vid && device->descriptor.idProduct == pid) { pdata->major_version = (uint8_t)(device->descriptor.bcdDevice >> 8); pdata->minor_version = (uint8_t)(device->descriptor.bcdDevice >> 0); if (!micronucleus_is_device_responsive(pdata, device)) { if (show_unresponsive_device_message) { pmsg_warning("unresponsive Micronucleus device detected, please reconnect ...\n"); show_unresponsive_device_message = false; } continue; } pmsg_notice("found device with Micronucleus V%d.%d, bus:device: %s:%s\n", pdata->major_version, pdata->minor_version, bus->dirname, device->filename); // if -P was given, match device by device name and bus name if (port != NULL) { if (dev_name == NULL || strcmp(bus->dirname, bus_name) || strcmp(device->filename, dev_name)) { continue; } } if (pdata->major_version > MICRONUCLEUS_MAX_MAJOR_VERSION) { pmsg_warning("device with unsupported Micronucleus version V%d.%d\n", pdata->major_version, pdata->minor_version); continue; } pdata->usb_handle = usb_open(device); if (pdata->usb_handle == NULL) { pmsg_error("unable to open USB device: %s\n", usb_strerror()); } } } } if (pdata->usb_handle == NULL && pdata->wait_until_device_present) { if (show_retry_message) { if (pdata->wait_timout < 0) { pmsg_error("no device found, waiting for device to be plugged in ...\n"); } else { pmsg_error("no device found, waiting %d seconds for device to be plugged in ...\n", pdata->wait_timout); } pmsg_error("press CTRL-C to terminate\n"); show_retry_message = false; } if (pdata->wait_timout < 0 || (time(NULL) - start_time) < pdata->wait_timout) { delay_ms(MICRONUCLEUS_CONNECT_WAIT); continue; } } break; } if (!pdata->usb_handle) { pmsg_error("cannot find device with Micronucleus bootloader (%04X:%04X)\n", vid, pid); return -1; } return 0; } static void micronucleus_close(PROGRAMMER* pgm) { pmsg_debug("micronucleus_close()\n"); pdata_t* pdata = PDATA(pgm); if (pdata->usb_handle != NULL) { usb_close(pdata->usb_handle); pdata->usb_handle = NULL; } } static int micronucleus_read_byte(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned long addr, unsigned char* value) { pmsg_debug("micronucleus_read_byte(desc=%s, addr=0x%04lX)\n", mem->desc, addr); if (strcmp(mem->desc, "lfuse") == 0 || strcmp(mem->desc, "hfuse") == 0 || strcmp(mem->desc, "efuse") == 0 || strcmp(mem->desc, "lock") == 0) { *value = 0xFF; return 0; } else { pmsg_notice("reading not supported for %s memory\n", mem->desc); return -1; } } static int micronucleus_write_byte(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned long addr, unsigned char value) { pmsg_debug("micronucleus_write_byte(desc=%s, addr=0x%04lX)\n", mem->desc, addr); return -1; } static int micronucleus_paged_load(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { pmsg_debug("micronucleus_paged_load(page_size=0x%X, addr=0x%X, n_bytes=0x%X)\n", page_size, addr, n_bytes); return -1; } static int micronucleus_paged_write(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { pmsg_debug("micronucleus_paged_write(page_size=0x%X, addr=0x%X, n_bytes=0x%X)\n", page_size, addr, n_bytes); if (strcmp(mem->desc, "flash") == 0) { pdata_t* pdata = PDATA(pgm); if (n_bytes > page_size) { pmsg_error("buffer size %u exceeds page size %u\n", n_bytes, page_size); return -1; } if (addr + n_bytes > pdata->flash_size) { pmsg_error("program size %u exceeds flash size %u\n", addr + n_bytes, pdata->flash_size); return -1; } uint8_t* page_buffer = (uint8_t*)malloc(pdata->page_size); if (page_buffer == NULL) { pmsg_error("unable to allocate memory\n"); return -1; } // Note: Page size reported by the bootloader may be smaller than device page size as configured in avrdude.conf. int result = 0; while (n_bytes > 0) { size_t chunk_size = n_bytes < pdata->page_size ? n_bytes : pdata->page_size; memcpy(page_buffer, mem->buf + addr, chunk_size); memset(page_buffer + chunk_size, 0xFF, pdata->page_size - chunk_size); result = micronucleus_write_page(pdata, addr, page_buffer, pdata->page_size); if (result < 0) { break; } addr += chunk_size; n_bytes -= chunk_size; } free(page_buffer); return result; } else { pmsg_error("unsupported memory type: %s\n", mem->desc); return -1; } } static int micronucleus_parseextparams(const PROGRAMMER *pgm, const LISTID xparams) { pmsg_debug("micronucleus_parseextparams()\n"); pdata_t* pdata = PDATA(pgm); for (LNODEID node = lfirst(xparams); node != NULL; node = lnext(node)) { const char* param = ldata(node); if (strcmp(param, "wait") == 0) { pdata->wait_until_device_present = true; pdata->wait_timout = -1; } else if (strncmp(param, "wait=", 5) == 0) { pdata->wait_until_device_present = true; pdata->wait_timout = atoi(param + 5); } else { pmsg_error("invalid extended parameter '%s'\n", param); return -1; } } return 0; } void micronucleus_initpgm(PROGRAMMER *pgm) { strcpy(pgm->type, "Micronucleus V2.0"); pgm->setup = micronucleus_setup; pgm->teardown = micronucleus_teardown; pgm->initialize = micronucleus_initialize; pgm->display = micronucleus_display; pgm->powerup = micronucleus_powerup; pgm->powerdown = micronucleus_powerdown; pgm->enable = micronucleus_enable; pgm->disable = micronucleus_disable; pgm->program_enable = micronucleus_program_enable; pgm->read_sig_bytes = micronucleus_read_sig_bytes; pgm->chip_erase = micronucleus_chip_erase; pgm->cmd = NULL; pgm->open = micronucleus_open; pgm->close = micronucleus_close; pgm->read_byte = micronucleus_read_byte; pgm->write_byte = micronucleus_write_byte; pgm->paged_load = micronucleus_paged_load; pgm->paged_write = micronucleus_paged_write; pgm->parseextparams = micronucleus_parseextparams; } #else /* !HAVE_LIBUSB */ // Give a proper error if we were not compiled with libusb static int micronucleus_nousb_open(PROGRAMMER* pgm, const char* name) { pmsg_error("no usb support; please compile again with libusb installed\n"); return -1; } void micronucleus_initpgm(PROGRAMMER *pgm) { strcpy(pgm->type, "micronucleus"); pgm->open = micronucleus_nousb_open; } #endif /* HAVE_LIBUSB */ const char micronucleus_desc[] = "Micronucleus Bootloader";