/* * avrdude - A Downloader/Uploader for AVR device programmers * Copyright (C) 2012 Kirill Levchenko * * 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 . */ /* $Id$ */ #include "ac_cfg.h" #include #include #include #include #include #include #include #include "avrdude.h" #include "libavrdude.h" #include "flip2.h" #include "dfu.h" #include "usbdevs.h" /* for USB_VENDOR_ATMEL */ /* There are three versions of the FLIP protocol: * * Version 0: C51 parts * Version 1: megaAVR parts ("USB DFU Bootloader Datasheet" [doc7618]) * Version 2: XMEGA parts (AVR4023 [doc8457]) * * We currently only support Version 2, as documented in AVR4023. * * Additional references: * flip_protocol.h from the Atmel Software Framework. * udi_dfu_atmel.c from XMEGA bootloaders archive. */ /* EXPORTED CONSTANT STRINGS */ const char flip2_desc[] = "FLIP USB DFU protocol version 2 (AVR4023)"; /* PRIVATE DATA STRUCTURES */ struct flip2 { struct dfu_dev *dfu; unsigned char part_sig[3]; unsigned char part_rev; unsigned char boot_ver; }; #define FLIP2(pgm) ((struct flip2 *)(pgm->cookie)) /* The FLIP2 protocol assigns specific meaning to certain combinations of * status and state bytes in the DFU_GETSTATUS response. These constants en- * code these combinations as a 16-bit value: the high order byte is the * status and the low order byte is the state of the status-state pairing. */ #define FLIP2_STATUS_OK 0x0000 #define FLIP2_STATUS_STALL 0x0F0A #define FLIP2_STATUS_MEM_UKNOWN 0x030A #define FLIP2_STATUS_MEM_PROTECTED 0x0300 #define FLIP2_STATUS_OUTOFRANGE 0x080A #define FLIP2_STATUS_BLANK_FAIL 0x0500 #define FLIP2_STATUS_ERASE_ONGOING 0x0904 /* FLIP2 data structures and constants. */ struct flip2_cmd { unsigned char group_id; unsigned char cmd_id; unsigned char args[4]; }; #define FLIP2_CMD_GROUP_DOWNLOAD 0x01 #define FLIP2_CMD_GROUP_UPLOAD 0x03 #define FLIP2_CMD_GROUP_EXEC 0x04 #define FLIP2_CMD_GROUP_SELECT 0x06 #define FLIP2_CMD_PROG_START 0x00 #define FLIP2_CMD_READ_MEMORY 0x00 #define FLIP2_CMD_SELECT_MEMORY 0x03 #define FLIP2_CMD_CHIP_ERASE 0x00 #define FLIP2_CMD_START_APP 0x03 #define FLIP2_SELECT_MEMORY_UNIT 0x00 #define FLIP2_SELECT_MEMORY_PAGE 0x01 enum flip2_mem_unit { FLIP2_MEM_UNIT_UNKNOWN = -1, FLIP2_MEM_UNIT_FLASH = 0x00, FLIP2_MEM_UNIT_EEPROM = 0x01, FLIP2_MEM_UNIT_SECURITY = 0x02, FLIP2_MEM_UNIT_CONFIGURATION = 0x03, FLIP2_MEM_UNIT_BOOTLOADER = 0x04, FLIP2_MEM_UNIT_SIGNATURE = 0x05, FLIP2_MEM_UNIT_USER = 0x06, FLIP2_MEM_UNIT_INT_RAM = 0x07, FLIP2_MEM_UNIT_EXT_MEM_CS0 = 0x08, FLIP2_MEM_UNIT_EXT_MEM_CS1 = 0x09, FLIP2_MEM_UNIT_EXT_MEM_CS2 = 0x0A, FLIP2_MEM_UNIT_EXT_MEM_CS3 = 0x0B, FLIP2_MEM_UNIT_EXT_MEM_CS4 = 0x0C, FLIP2_MEM_UNIT_EXT_MEM_CS5 = 0x0D, FLIP2_MEM_UNIT_EXT_MEM_CS6 = 0x0E, FLIP2_MEM_UNIT_EXT_MEM_CS7 = 0x0F, FLIP2_MEM_UNIT_EXT_MEM_DF = 0x10 }; /* EXPORTED PROGRAMMER FUNCTION PROTOTYPES */ static int flip2_open(PROGRAMMER *pgm, const char *port_spec); static int flip2_initialize(const PROGRAMMER *pgm, const AVRPART *part); static void flip2_close(PROGRAMMER* pgm); static void flip2_enable(PROGRAMMER *pgm, const AVRPART *p); static void flip2_disable(const PROGRAMMER *pgm); static void flip2_display(const PROGRAMMER *pgm, const char *prefix); static int flip2_program_enable(const PROGRAMMER *pgm, const AVRPART *part); static int flip2_chip_erase(const PROGRAMMER *pgm, const AVRPART *part); static int flip2_read_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char *value); static int flip2_write_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char value); static int flip2_paged_load(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes); static int flip2_paged_write(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes); static int flip2_read_sig_bytes(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem); static void flip2_setup(PROGRAMMER * pgm); static void flip2_teardown(PROGRAMMER * pgm); /* INTERNAL PROGRAMMER FUNCTION PROTOTYPES */ #ifdef HAVE_LIBUSB // The internal ones are made conditional, as they're not defined further down #ifndef HAVE_LIBUSB static void flip2_show_info(struct flip2 *flip2); static int flip2_read_memory(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit, uint32_t addr, void *ptr, int size); static int flip2_write_memory(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit, uint32_t addr, const void *ptr, int size); static int flip2_set_mem_unit(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit); static int flip2_set_mem_page(struct dfu_dev *dfu, unsigned short page_addr); static int flip2_read_max1k(struct dfu_dev *dfu, unsigned short offset, void *ptr, unsigned short size); static int flip2_write_max1k(struct dfu_dev *dfu, unsigned short offset, const void *ptr, unsigned short size); static const char * flip2_status_str(const struct dfu_status *status); static const char * flip2_mem_unit_str(enum flip2_mem_unit mem_unit); static enum flip2_mem_unit flip2_mem_unit(const char *name); #endif /* HAVE_LIBUSB */ /* THE INITPGM FUNCTION DEFINITIONS */ void flip2_initpgm(PROGRAMMER *pgm) { strcpy(pgm->type, "flip2"); /* Mandatory Functions */ pgm->initialize = flip2_initialize; pgm->enable = flip2_enable; pgm->disable = flip2_disable; pgm->display = flip2_display; pgm->program_enable = flip2_program_enable; pgm->chip_erase = flip2_chip_erase; pgm->open = flip2_open; pgm->close = flip2_close; pgm->paged_load = flip2_paged_load; pgm->paged_write = flip2_paged_write; pgm->read_byte = flip2_read_byte; pgm->write_byte = flip2_write_byte; pgm->read_sig_bytes = flip2_read_sig_bytes; pgm->setup = flip2_setup; pgm->teardown = flip2_teardown; } #ifdef HAVE_LIBUSB /* EXPORTED PROGRAMMER FUNCTION DEFINITIONS */ int flip2_open(PROGRAMMER *pgm, const char *port_spec) { FLIP2(pgm)->dfu = dfu_open(port_spec); return (FLIP2(pgm)->dfu != NULL) ? 0 : -1; } int flip2_initialize(const PROGRAMMER *pgm, const AVRPART *part) { unsigned short vid, pid; int result; struct dfu_dev *dfu = FLIP2(pgm)->dfu; /* A note about return values. Negative return values from this function are * interpreted as failure by main(), from where this function is called. * However such failures are interpreted as a device signature check failure * and the user is advised to use the -F option to override this check. In * our case, this is misleading, so we defer reporting an error until another * function is called. Thus, we always return 0 (success) from initialize(). * I don't like this, but I don't want to mess with main(). */ /* The dfu_init() function will try to find the target part either based on * a USB address provided by the user with the -P option or by matching the * VID and PID of the device. The VID may be specified in the programmer * definition; if not specified, it defaults to USB_VENDOR_ATMEL (defined * in usbdevs.h). The PID may be specified either in the programmer * definition or the part definition; the programmer definition takes * priority. The default PID value is 0, which causes dfu_init() to ignore * the PID when matching a target device. */ vid = (pgm->usbvid != 0) ? pgm->usbvid : USB_VENDOR_ATMEL; LNODEID usbpid = lfirst(pgm->usbpid); if (usbpid) { pid = *(int *)(ldata(usbpid)); if (lnext(usbpid)) avrdude_message(MSG_INFO, "%s: Warning: using PID 0x%04x, ignoring remaining PIDs in list\n", progname, pid); } else { pid = part->usbpid; } if (!ovsigck && !(part->flags & AVRPART_HAS_PDI)) { avrdude_message(MSG_INFO, "%s: \"flip2\" (FLIP protocol version 2) is for Xmega devices.\n" "%s For AT90USB* or ATmega*U* devices, use \"flip1\".\n" "%s (Use -F to bypass this check.)\n", progname, progbuf, progbuf); return -1; } result = dfu_init(dfu, vid, pid); if (result != 0) goto flip2_initialize_fail; /* Check if descriptor values are what we expect. */ if (dfu->dev_desc.idVendor != vid) avrdude_message(MSG_INFO, "%s: Warning: USB idVendor = 0x%04X (expected 0x%04X)\n", progname, dfu->dev_desc.idVendor, vid); if (pid != 0 && dfu->dev_desc.idProduct != pid) avrdude_message(MSG_INFO, "%s: Warning: USB idProduct = 0x%04X (expected 0x%04X)\n", progname, dfu->dev_desc.idProduct, pid); if (dfu->dev_desc.bNumConfigurations != 1) avrdude_message(MSG_INFO, "%s: Warning: USB bNumConfigurations = %d (expected 1)\n", progname, (int) dfu->dev_desc.bNumConfigurations); if (dfu->conf_desc.bNumInterfaces != 1) avrdude_message(MSG_INFO, "%s: Warning: USB bNumInterfaces = %d (expected 1)\n", progname, (int) dfu->conf_desc.bNumInterfaces); if (dfu->dev_desc.bDeviceClass != 0) avrdude_message(MSG_INFO, "%s: Warning: USB bDeviceClass = %d (expected 0)\n", progname, (int) dfu->dev_desc.bDeviceClass); if (dfu->dev_desc.bDeviceSubClass != 0) avrdude_message(MSG_INFO, "%s: Warning: USB bDeviceSubClass = %d (expected 0)\n", progname, (int) dfu->dev_desc.bDeviceSubClass); if (dfu->dev_desc.bDeviceProtocol != 0) avrdude_message(MSG_INFO, "%s: Warning: USB bDeviceProtocol = %d (expected 0)\n", progname, (int) dfu->dev_desc.bDeviceProtocol); if (dfu->intf_desc.bInterfaceClass != 0xFF) avrdude_message(MSG_INFO, "%s: Warning: USB bInterfaceClass = %d (expected 255)\n", progname, (int) dfu->intf_desc.bInterfaceClass); if (dfu->intf_desc.bInterfaceSubClass != 0) avrdude_message(MSG_INFO, "%s: Warning: USB bInterfaceSubClass = %d (expected 0)\n", progname, (int) dfu->intf_desc.bInterfaceSubClass); if (dfu->intf_desc.bInterfaceProtocol != 0) avrdude_message(MSG_INFO, "%s: Warning: USB bInterfaceSubClass = %d (expected 0)\n", progname, (int) dfu->intf_desc.bInterfaceProtocol); result = flip2_read_memory(FLIP2(pgm)->dfu, FLIP2_MEM_UNIT_SIGNATURE, 0, FLIP2(pgm)->part_sig, 4); if (result != 0) goto flip2_initialize_fail; result = flip2_read_memory(FLIP2(pgm)->dfu, FLIP2_MEM_UNIT_BOOTLOADER, 0, &FLIP2(pgm)->boot_ver, 1); if (result != 0) goto flip2_initialize_fail; if (verbose) flip2_show_info(FLIP2(pgm)); return 0; flip2_initialize_fail: dfu_close(FLIP2(pgm)->dfu); FLIP2(pgm)->dfu = NULL; return 0; } void flip2_close(PROGRAMMER* pgm) { if (FLIP2(pgm)->dfu != NULL) { dfu_close(FLIP2(pgm)->dfu); FLIP2(pgm)->dfu = NULL; } } void flip2_enable(PROGRAMMER *pgm, const AVRPART *p) { /* Nothing to do. */ } void flip2_disable(const PROGRAMMER *pgm) { /* Nothing to do. */ } void flip2_display(const PROGRAMMER *pgm, const char *prefix) { /* Nothing to do. */ } int flip2_program_enable(const PROGRAMMER *pgm, const AVRPART *part) { /* I couldn't find anything that uses this function, although it is marked * as "mandatory" in pgm.c. In case anyone does use it, we'll report an * error if we failed to initialize. */ return (FLIP2(pgm)->dfu != NULL) ? 0 : -1; } int flip2_chip_erase(const PROGRAMMER *pgm, const AVRPART *part) { struct dfu_status status; int cmd_result = 0; int aux_result; avrdude_message(MSG_NOTICE2, "%s: flip_chip_erase()\n", progname); struct flip2_cmd cmd = { FLIP2_CMD_GROUP_EXEC, FLIP2_CMD_CHIP_ERASE, { 0xFF, 0, 0, 0 } }; for (;;) { cmd_result = dfu_dnload(FLIP2(pgm)->dfu, &cmd, sizeof(cmd)); aux_result = dfu_getstatus(FLIP2(pgm)->dfu, &status); if (aux_result != 0) return aux_result; if (status.bStatus != DFU_STATUS_OK) { if (status.bStatus == ((FLIP2_STATUS_ERASE_ONGOING >> 8) & 0xFF) && status.bState == ((FLIP2_STATUS_ERASE_ONGOING >> 0) & 0xFF)) { continue; } else avrdude_message(MSG_INFO, "%s: Error: DFU status %s\n", progname, flip2_status_str(&status)); dfu_clrstatus(FLIP2(pgm)->dfu); } else break; } return cmd_result; } int flip2_read_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char *value) { enum flip2_mem_unit mem_unit; if (FLIP2(pgm)->dfu == NULL) return -1; mem_unit = flip2_mem_unit(mem->desc); if (mem_unit == FLIP2_MEM_UNIT_UNKNOWN) { avrdude_message(MSG_INFO, "%s: Error: " "\"%s\" memory not accessible using FLIP", progname, mem->desc); if (strcmp(mem->desc, "flash") == 0) avrdude_message(MSG_INFO, " (did you mean \"application\"?)"); avrdude_message(MSG_INFO, "\n"); return -1; } return flip2_read_memory(FLIP2(pgm)->dfu, mem_unit, addr, value, 1); } int flip2_write_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char value) { enum flip2_mem_unit mem_unit; if (FLIP2(pgm)->dfu == NULL) return -1; mem_unit = flip2_mem_unit(mem->desc); if (mem_unit == FLIP2_MEM_UNIT_UNKNOWN) { avrdude_message(MSG_INFO, "%s: Error: " "\"%s\" memory not accessible using FLIP", progname, mem->desc); if (strcmp(mem->desc, "flash") == 0) avrdude_message(MSG_INFO, " (did you mean \"application\"?)"); avrdude_message(MSG_INFO, "\n"); return -1; } return flip2_write_memory(FLIP2(pgm)->dfu, mem_unit, addr, &value, 1); } int flip2_paged_load(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { enum flip2_mem_unit mem_unit; int result; if (FLIP2(pgm)->dfu == NULL) return -1; mem_unit = flip2_mem_unit(mem->desc); if (mem_unit == FLIP2_MEM_UNIT_UNKNOWN) { avrdude_message(MSG_INFO, "%s: Error: " "\"%s\" memory not accessible using FLIP", progname, mem->desc); if (strcmp(mem->desc, "flash") == 0) avrdude_message(MSG_INFO, " (did you mean \"application\"?)"); avrdude_message(MSG_INFO, "\n"); return -1; } if (n_bytes > INT_MAX) { /* This should never happen, unless the int type is only 16 bits. */ avrdude_message(MSG_INFO, "%s: Error: Attempting to read more than %d bytes\n", progname, INT_MAX); exit(1); } result = flip2_read_memory(FLIP2(pgm)->dfu, mem_unit, addr, mem->buf + addr, n_bytes); return (result == 0) ? n_bytes : -1; } int flip2_paged_write(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { enum flip2_mem_unit mem_unit; int result; if (FLIP2(pgm)->dfu == NULL) return -1; mem_unit = flip2_mem_unit(mem->desc); if (mem_unit == FLIP2_MEM_UNIT_UNKNOWN) { avrdude_message(MSG_INFO, "%s: Error: " "\"%s\" memory not accessible using FLIP", progname, mem->desc); if (strcmp(mem->desc, "flash") == 0) avrdude_message(MSG_INFO, " (did you mean \"application\"?)"); avrdude_message(MSG_INFO, "\n"); return -1; } if (n_bytes > INT_MAX) { /* This should never happen, unless the int type is only 16 bits. */ avrdude_message(MSG_INFO, "%s: Error: Attempting to read more than %d bytes\n", progname, INT_MAX); exit(1); } result = flip2_write_memory(FLIP2(pgm)->dfu, mem_unit, addr, mem->buf + addr, n_bytes); return (result == 0) ? n_bytes : -1; } int flip2_read_sig_bytes(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem) { if (FLIP2(pgm)->dfu == NULL) return -1; if (mem->size < sizeof(FLIP2(pgm)->part_sig)) { avrdude_message(MSG_INFO, "%s: Error: Signature read must be at least %u bytes\n", progname, (unsigned int) sizeof(FLIP2(pgm)->part_sig)); return -1; } memcpy(mem->buf, FLIP2(pgm)->part_sig, sizeof(FLIP2(pgm)->part_sig)); return 0; } void flip2_setup(PROGRAMMER * pgm) { pgm->cookie = calloc(1, sizeof(struct flip2)); if (pgm->cookie == NULL) { avrdude_message(MSG_INFO, "%s: Out of memory allocating private data structure\n", progname); exit(1); } } void flip2_teardown(PROGRAMMER * pgm) { free(pgm->cookie); pgm->cookie = NULL; } /* INTERNAL FUNCTION DEFINITIONS */ void flip2_show_info(struct flip2 *flip2) { dfu_show_info(flip2->dfu); avrdude_message(MSG_INFO, " Part signature : 0x%02X%02X%02X\n", (int) flip2->part_sig[0], (int) flip2->part_sig[1], (int) flip2->part_sig[2]); if (flip2->part_rev < 26) avrdude_message(MSG_INFO, " Part revision : %c\n", (char) (flip2->part_rev + 'A')); else avrdude_message(MSG_INFO, " Part revision : %c%c\n", (char) (flip2->part_rev / 26 - 1 + 'A'), (char) (flip2->part_rev % 26 + 'A')); avrdude_message(MSG_INFO, " Bootloader version : 2.%hu.%hu\n", ((unsigned short) flip2->boot_ver >> 4) & 0xF, ((unsigned short) flip2->boot_ver >> 0) & 0xF); avrdude_message(MSG_INFO, " USB max packet size : %hu\n", (unsigned short) flip2->dfu->dev_desc.bMaxPacketSize0); } int flip2_read_memory(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit, uint32_t addr, void *ptr, int size) { unsigned short prev_page_addr; unsigned short page_addr; const char * mem_name; int read_size; int result; avrdude_message(MSG_NOTICE2, "%s: flip_read_memory(%s, 0x%04x, %d)\n", progname, flip2_mem_unit_str(mem_unit), addr, size); result = flip2_set_mem_unit(dfu, mem_unit); if (result != 0) { if ((mem_name = flip2_mem_unit_str(mem_unit)) != NULL) avrdude_message(MSG_INFO, "%s: Error: Failed to set memory unit 0x%02X (%s)\n", progname, (int) mem_unit, mem_name); else avrdude_message(MSG_INFO, "%s: Error: Failed to set memory unit 0x%02X\n", progname, (int) mem_unit); return -1; } page_addr = addr >> 16; result = flip2_set_mem_page(dfu, page_addr); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to set memory page 0x%04hX\n", progname, page_addr); return -1; } while (size > 0) { prev_page_addr = page_addr; page_addr = addr >> 16; if (page_addr != prev_page_addr) { result = flip2_set_mem_page(dfu, page_addr); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to set memory page 0x%04hX\n", progname, page_addr); return -1; } } read_size = (size > 0x400) ? 0x400 : size; result = flip2_read_max1k(dfu, addr & 0xFFFF, ptr, read_size); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to read 0x%04X bytes at 0x%04lX\n", progname, read_size, (unsigned long) addr); return -1; } ptr = (char*)ptr + read_size; addr += read_size; size -= read_size; } return 0; } int flip2_write_memory(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit, uint32_t addr, const void *ptr, int size) { unsigned short prev_page_addr; unsigned short page_addr; const char * mem_name; int write_size; int result; avrdude_message(MSG_NOTICE2, "%s: flip_write_memory(%s, 0x%04x, %d)\n", progname, flip2_mem_unit_str(mem_unit), addr, size); result = flip2_set_mem_unit(dfu, mem_unit); if (result != 0) { if ((mem_name = flip2_mem_unit_str(mem_unit)) != NULL) avrdude_message(MSG_INFO, "%s: Error: Failed to set memory unit 0x%02X (%s)\n", progname, (int) mem_unit, mem_name); else avrdude_message(MSG_INFO, "%s: Error: Failed to set memory unit 0x%02X\n", progname, (int) mem_unit); return -1; } page_addr = addr >> 16; result = flip2_set_mem_page(dfu, page_addr); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to set memory page 0x%04hX\n", progname, page_addr); return -1; } while (size > 0) { prev_page_addr = page_addr; page_addr = addr >> 16; if (page_addr != prev_page_addr) { result = flip2_set_mem_page(dfu, page_addr); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to set memory page 0x%04hX\n", progname, page_addr); return -1; } } write_size = (size > 0x800) ? 0x800 : size; result = flip2_write_max1k(dfu, addr & 0xFFFF, ptr, write_size); if (result != 0) { avrdude_message(MSG_INFO, "%s: Error: Failed to write 0x%04X bytes at 0x%04lX\n", progname, write_size, (unsigned long) addr); return -1; } ptr = (const char*)ptr + write_size; addr += write_size; size -= write_size; } return 0; } int flip2_set_mem_unit(struct dfu_dev *dfu, enum flip2_mem_unit mem_unit) { struct dfu_status status; int cmd_result = 0; int aux_result; struct flip2_cmd cmd = { FLIP2_CMD_GROUP_SELECT, FLIP2_CMD_SELECT_MEMORY, { 0, 0, 0, 0 } }; cmd.args[0] = FLIP2_SELECT_MEMORY_UNIT; cmd.args[1] = mem_unit; cmd_result = dfu_dnload(dfu, &cmd, sizeof(cmd)); aux_result = dfu_getstatus(dfu, &status); if (aux_result != 0) return aux_result; if (status.bStatus != DFU_STATUS_OK) { if (status.bStatus == ((FLIP2_STATUS_OUTOFRANGE >> 8) & 0xFF) && status.bState == ((FLIP2_STATUS_OUTOFRANGE >> 0) & 0xFF)) { avrdude_message(MSG_INFO, "%s: Error: Unknown memory unit (0x%02x)\n", progname, (unsigned int) mem_unit); } else avrdude_message(MSG_INFO, "%s: Error: DFU status %s\n", progname, flip2_status_str(&status)); dfu_clrstatus(dfu); } return cmd_result; } int flip2_set_mem_page(struct dfu_dev *dfu, unsigned short page_addr) { struct dfu_status status; int cmd_result = 0; int aux_result; struct flip2_cmd cmd = { FLIP2_CMD_GROUP_SELECT, FLIP2_CMD_SELECT_MEMORY, { 0, 0, 0, 0 } }; cmd.args[0] = FLIP2_SELECT_MEMORY_PAGE; cmd.args[1] = (page_addr >> 8) & 0xFF; cmd.args[2] = (page_addr >> 0) & 0xFF; cmd_result = dfu_dnload(dfu, &cmd, sizeof(cmd)); aux_result = dfu_getstatus(dfu, &status); if (aux_result != 0) return aux_result; if (status.bStatus != DFU_STATUS_OK) { if (status.bStatus == ((FLIP2_STATUS_OUTOFRANGE >> 8) & 0xFF) && status.bState == ((FLIP2_STATUS_OUTOFRANGE >> 0) & 0xFF)) { avrdude_message(MSG_INFO, "%s: Error: Page address out of range (0x%04hx)\n", progname, page_addr); } else avrdude_message(MSG_INFO, "%s: Error: DFU status %s\n", progname, flip2_status_str(&status)); dfu_clrstatus(dfu); } return cmd_result; } int flip2_read_max1k(struct dfu_dev *dfu, unsigned short offset, void *ptr, unsigned short size) { struct dfu_status status; int cmd_result = 0; int aux_result; struct flip2_cmd cmd = { FLIP2_CMD_GROUP_UPLOAD, FLIP2_CMD_READ_MEMORY, { 0, 0, 0, 0 } }; cmd.args[0] = (offset >> 8) & 0xFF; cmd.args[1] = (offset >> 0) & 0xFF; cmd.args[2] = ((offset+size-1) >> 8) & 0xFF; cmd.args[3] = ((offset+size-1) >> 0) & 0xFF; cmd_result = dfu_dnload(dfu, &cmd, sizeof(cmd)); if (cmd_result != 0) goto flip2_read_max1k_status; cmd_result = dfu_upload(dfu, (char*) ptr, size); flip2_read_max1k_status: aux_result = dfu_getstatus(dfu, &status); if (aux_result != 0) return aux_result; if (status.bStatus != DFU_STATUS_OK) { if (status.bStatus == ((FLIP2_STATUS_OUTOFRANGE >> 8) & 0xFF) && status.bState == ((FLIP2_STATUS_OUTOFRANGE >> 0) & 0xFF)) { avrdude_message(MSG_INFO, "%s: Error: Address out of range [0x%04hX,0x%04hX]\n", progname, offset, offset+size-1); } else avrdude_message(MSG_INFO, "%s: Error: DFU status %s\n", progname, flip2_status_str(&status)); dfu_clrstatus(dfu); } return cmd_result; } int flip2_write_max1k(struct dfu_dev *dfu, unsigned short offset, const void *ptr, unsigned short size) { char buffer[64+64+0x400]; unsigned short data_offset; struct dfu_status status; int cmd_result = 0; int aux_result; struct flip2_cmd cmd = { FLIP2_CMD_GROUP_DOWNLOAD, FLIP2_CMD_PROG_START, { 0, 0, 0, 0 } }; cmd.args[0] = (offset >> 8) & 0xFF; cmd.args[1] = (offset >> 0) & 0xFF; cmd.args[2] = ((offset+size-1) >> 8) & 0xFF; cmd.args[3] = ((offset+size-1) >> 0) & 0xFF; if (size > 0x400) { avrdude_message(MSG_INFO, "%s: Error: Write block too large (%hu > 1024)\n", progname, size); return -1; } /* There are some special padding requirements for writes. The first packet * must consist only of the FLIP2 command data, which must be padded to * fill out the USB packet (the packet size is given by bMaxPacketSize0 in * the device descriptor). In addition, the data must be padded so that the * first byte of data to be written is at located at position (offset mod * bMaxPacketSize0) within the packet. */ data_offset = dfu->dev_desc.bMaxPacketSize0; data_offset += offset % dfu->dev_desc.bMaxPacketSize0; memcpy(buffer, &cmd, sizeof(cmd)); memset(buffer + sizeof(cmd), 0, data_offset - sizeof(cmd)); memcpy(buffer + data_offset, ptr, size); cmd_result = dfu_dnload(dfu, buffer, data_offset + size); aux_result = dfu_getstatus(dfu, &status); if (aux_result != 0) return aux_result; if (status.bStatus != DFU_STATUS_OK) { if (status.bStatus == ((FLIP2_STATUS_OUTOFRANGE >> 8) & 0xFF) && status.bState == ((FLIP2_STATUS_OUTOFRANGE >> 0) & 0xFF)) { avrdude_message(MSG_INFO, "%s: Error: Address out of range [0x%04hX,0x%04hX]\n", progname, offset, offset+size-1); } else avrdude_message(MSG_INFO, "%s: Error: DFU status %s\n", progname, flip2_status_str(&status)); dfu_clrstatus(dfu); } return cmd_result; } const char * flip2_status_str(const struct dfu_status *status) { unsigned short selector; selector = (unsigned short) status->bStatus << 8; selector |= status->bState; switch (selector) { case FLIP2_STATUS_OK: return "OK"; case FLIP2_STATUS_STALL: return "STALL"; case FLIP2_STATUS_MEM_UKNOWN: return "MEM_UKNOWN"; case FLIP2_STATUS_MEM_PROTECTED: return "MEM_PROTECTED"; case FLIP2_STATUS_OUTOFRANGE: return "OUTOFRANGE"; case FLIP2_STATUS_BLANK_FAIL: return "BLANK_FAIL"; case FLIP2_STATUS_ERASE_ONGOING: return "ERASE_ONGOING"; default: return dfu_status_str(status->bStatus); } } const char * flip2_mem_unit_str(enum flip2_mem_unit mem_unit) { switch (mem_unit) { case FLIP2_MEM_UNIT_FLASH: return "Flash"; case FLIP2_MEM_UNIT_EEPROM: return "EEPROM"; case FLIP2_MEM_UNIT_SECURITY: return "security"; case FLIP2_MEM_UNIT_CONFIGURATION: return "configuration"; case FLIP2_MEM_UNIT_BOOTLOADER: return "bootloader version"; case FLIP2_MEM_UNIT_SIGNATURE: return "signature"; case FLIP2_MEM_UNIT_USER: return "user"; case FLIP2_MEM_UNIT_INT_RAM: return "internal RAM"; case FLIP2_MEM_UNIT_EXT_MEM_CS0: return "EXT_MEM_CS0"; case FLIP2_MEM_UNIT_EXT_MEM_CS1: return "EXT_MEM_CS1"; case FLIP2_MEM_UNIT_EXT_MEM_CS2: return "EXT_MEM_CS2"; case FLIP2_MEM_UNIT_EXT_MEM_CS3: return "EXT_MEM_CS3"; case FLIP2_MEM_UNIT_EXT_MEM_CS4: return "EXT_MEM_CS4"; case FLIP2_MEM_UNIT_EXT_MEM_CS5: return "EXT_MEM_CS5"; case FLIP2_MEM_UNIT_EXT_MEM_CS6: return "EXT_MEM_CS6"; case FLIP2_MEM_UNIT_EXT_MEM_CS7: return "EXT_MEM_CS7"; case FLIP2_MEM_UNIT_EXT_MEM_DF: return "EXT_MEM_DF"; default: return "unknown"; } } enum flip2_mem_unit flip2_mem_unit(const char *name) { if (strcmp(name, "application") == 0) return FLIP2_MEM_UNIT_FLASH; if (strcmp(name, "eeprom") == 0) return FLIP2_MEM_UNIT_EEPROM; if (strcmp(name, "signature") == 0) return FLIP2_MEM_UNIT_SIGNATURE; return FLIP2_MEM_UNIT_UNKNOWN; } #else /* HAVE_LIBUSB */ /* EXPORTED PROGRAMMER FUNCTION DEFINITIONS */ int flip2_open(PROGRAMMER *pgm, const char *port_spec) { fprintf(stderr, "%s: Error: No USB support in this compile of avrdude\n", progname); return -1; } int flip2_initialize(const PROGRAMMER *pgm, const AVRPART *part) { return -1; } void flip2_close(PROGRAMMER* pgm) { } void flip2_enable(PROGRAMMER *pgm, const AVRPART *p) { } void flip2_disable(const PROGRAMMER *pgm) { } void flip2_display(const PROGRAMMER *pgm, const char *prefix) { } int flip2_program_enable(const PROGRAMMER *pgm, const AVRPART *part) { return -1; } int flip2_chip_erase(const PROGRAMMER *pgm, const AVRPART *part) { return -1; } int flip2_read_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char *value) { return -1; } int flip2_write_byte(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned long addr, unsigned char value) { return -1; } int flip2_paged_load(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { return -1; } int flip2_paged_write(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem, unsigned int page_size, unsigned int addr, unsigned int n_bytes) { return -1; } int flip2_read_sig_bytes(const PROGRAMMER *pgm, const AVRPART *part, const AVRMEM *mem) { return -1; } void flip2_setup(PROGRAMMER * pgm) { } void flip2_teardown(PROGRAMMER * pgm) { } #endif /* HAVE_LIBUSB */