avrdude/src/term.c

1421 lines
37 KiB
C

/*
* avrdude - A Downloader/Uploader for AVR device programmers
* Copyright (C) 2000-2004 Brian S. Dean <bsd@bsdhome.com>
*
* 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 <http://www.gnu.org/licenses/>.
*/
/* $Id$ */
#include "ac_cfg.h"
#include <ctype.h>
#include <string.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <stdarg.h>
#include <limits.h>
#include <unistd.h>
#include <errno.h>
#if defined(HAVE_LIBREADLINE)
# include <readline/readline.h>
# include <readline/history.h>
#endif
#include "avrdude.h"
#include "term.h"
struct command {
char * name;
int (*func)(PROGRAMMER * pgm, struct avrpart * p, int argc, char *argv[]);
char * desc;
};
static int cmd_dump (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_write (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_erase (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_sig (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_part (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_help (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_quit (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_send (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_parms (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_vtarg (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_varef (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_fosc (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_sck (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_spi (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_pgm (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_verbose (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
static int cmd_quell (PROGRAMMER * pgm, struct avrpart * p,
int argc, char *argv[]);
struct command cmd[] = {
{ "dump", cmd_dump, "%s <memory> [<addr> <len> | <addr> ... | <addr> | ...]" },
{ "read", cmd_dump, "alias for dump" },
{ "write", cmd_write, "%s <memory> <addr> [<data>[,] {<data>[,]} | <len> <data>[,] {<data>[,]} ...]" },
{ "erase", cmd_erase, "perform a chip erase" },
{ "sig", cmd_sig, "display device signature bytes" },
{ "part", cmd_part, "display the current part information" },
{ "send", cmd_send, "send a raw command: %s <b1> <b2> <b3> <b4>" },
{ "parms", cmd_parms, "display adjustable parameters (STK500 and Curiosity Nano only)" },
{ "vtarg", cmd_vtarg, "set <V[target]> (STK500 and Curiosity Nano only)" },
{ "varef", cmd_varef, "set <V[aref]> (STK500 only)" },
{ "fosc", cmd_fosc, "set <oscillator frequency> (STK500 only)" },
{ "sck", cmd_sck, "set <SCK period> (STK500 only)" },
{ "spi", cmd_spi, "enter direct SPI mode" },
{ "pgm", cmd_pgm, "return to programming mode" },
{ "verbose", cmd_verbose, "change verbosity" },
{ "quell", cmd_quell, "set quell level for progress bars" },
{ "help", cmd_help, "help" },
{ "?", cmd_help, "help" },
{ "quit", cmd_quit, "quit" }
};
#define NCMDS ((int)(sizeof(cmd)/sizeof(struct command)))
static int spi_mode = 0;
static int nexttok(char * buf, char ** tok, char ** next)
{
unsigned char *q, *n;
q = (unsigned char *) buf;
while (isspace(*q))
q++;
/* isolate first token */
n = q;
uint8_t quotes = 0;
while (*n && (!isspace(*n) || quotes)) {
// poor man's quote and escape processing
if (*n == '"' || *n == '\'')
quotes++;
else if(*n == '\\' && n[1])
n++;
else if (isspace(*n) && (n > q+1) && (n[-1] == '"' || n[-1] == '\''))
break;
n++;
}
if (*n) {
*n = 0;
n++;
}
/* find start of next token */
while (isspace(*n))
n++;
*tok = (char *) q;
*next = (char *) n;
return 0;
}
static int hexdump_line(char * buffer, unsigned char * p, int n, int pad)
{
char * hexdata = "0123456789abcdef";
char * b = buffer;
int i = 0;
int j = 0;
for (i=0; i<n; i++) {
if (i && ((i % 8) == 0))
b[j++] = ' ';
b[j++] = hexdata[(p[i] & 0xf0) >> 4];
b[j++] = hexdata[(p[i] & 0x0f)];
if (i < 15)
b[j++] = ' ';
}
for (i=j; i<pad; i++)
b[i] = ' ';
b[i] = 0;
for (i=0; i<pad; i++) {
if (!((b[i] == '0') || (b[i] == ' ')))
return 0;
}
return 1;
}
static int chardump_line(char * buffer, unsigned char * p, int n, int pad)
{
int i;
unsigned char b[128];
// sanity check
n = n < 1? 1: n > sizeof b? sizeof b: n;
memcpy(b, p, n);
for (int i = 0; i < n; i++)
buffer[i] = isascii(b[i]) && isspace(b[i])? ' ':
isascii(b[i]) && isgraph(b[i])? b[i]: '.';
for (i = n; i < pad; i++)
buffer[i] = ' ';
buffer[i] = 0;
return 0;
}
static int hexdump_buf(FILE * f, int startaddr, unsigned char * buf, int len)
{
char dst1[80];
char dst2[80];
int addr = startaddr;
unsigned char * p = (unsigned char *)buf;
while (len) {
int n = 16;
if (n > len)
n = len;
hexdump_line(dst1, p, n, 48);
chardump_line(dst2, p, n, 16);
fprintf(stdout, "%04x %s |%s|\n", addr, dst1, dst2);
len -= n;
addr += n;
p += n;
}
return 0;
}
static int cmd_dump(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
if (argc < 2 || argc > 4) {
terminal_message(MSG_INFO,
"Usage: %s <memory> <addr> <len>\n"
" %s <memory> <addr> ...\n"
" %s <memory> <addr>\n"
" %s <memory> ...\n"
" %s <memory>\n",
argv[0], argv[0], argv[0], argv[0], argv[0]);
return -1;
}
enum { read_size = 256 };
static const char *prevmem = "";
char * memtype = argv[1];
AVRMEM * mem = avr_locate_mem(p, memtype);
if (mem == NULL) {
terminal_message(MSG_INFO, "%s (dump): %s memory type not defined for part %s\n",
progname, memtype, p->desc);
return -1;
}
int maxsize = mem->size;
// Get start address if present
char * end_ptr;
static int addr = 0;
if (argc >= 3 && strcmp(argv[2], "...") != 0) {
addr = strtoul(argv[2], &end_ptr, 0);
if (*end_ptr || (end_ptr == argv[2])) {
terminal_message(MSG_INFO, "%s (dump): can't parse address %s\n",
progname, argv[2]);
return -1;
} else if (addr >= maxsize) {
terminal_message(MSG_INFO, "%s (dump): address 0x%05lx is out of range for %s memory\n",
progname, (long) addr, mem->desc);
return -1;
}
}
// Get no. bytes to read if present
static int len = read_size;
if (argc >= 3) {
prevmem = cache_string("");
if (strcmp(argv[argc - 1], "...") == 0) {
if (argc == 3)
addr = 0;
len = maxsize - addr;
} else if (argc == 4) {
len = strtol(argv[3], &end_ptr, 0);
if (*end_ptr || (end_ptr == argv[3])) {
terminal_message(MSG_INFO, "%s (dump): can't parse length %s\n",
progname, argv[3]);
return -1;
}
} else {
len = read_size;
}
}
// No address or length specified
else if (argc == 2) {
if (strncmp(prevmem, memtype, strlen(memtype)) != 0) {
addr = 0;
len = read_size;
prevmem = cache_string(mem->desc);
}
if (addr >= maxsize)
addr = 0; // Wrap around
}
// Trim len if nessary to not read past the end of memory
if ((addr + len) > maxsize)
len = maxsize - addr;
uint8_t * buf = malloc(len);
if (buf == NULL) {
terminal_message(MSG_INFO, "%s (dump): out of memory\n", progname);
return -1;
}
report_progress(0, 1, "Reading");
for (int i = 0; i < len; i++) {
int rc = pgm->read_byte(pgm, p, mem, addr + i, &buf[i]);
if (rc != 0) {
terminal_message(MSG_INFO, "%s (dump): error reading %s address 0x%05lx of part %s\n",
progname, mem->desc, (long) addr + i, p->desc);
if (rc == -1)
terminal_message(MSG_INFO, "%*sread operation not supported on memory type %s\n",
(int) strlen(progname)+9, "", mem->desc);
return -1;
}
report_progress(i, len, NULL);
}
report_progress(1, 1, NULL);
hexdump_buf(stdout, addr, buf, len);
fprintf(stdout, "\n");
free(buf);
addr = addr + len;
return 0;
}
static size_t maxstrlen(int argc, char **argv) {
size_t max = 0;
for(int i=0; i<argc; i++)
if(strlen(argv[i]) > max)
max = strlen(argv[i]);
return max;
}
// Change data item p of size bytes from big endian to little endian and vice versa
static void change_endian(void *p, int size) {
uint8_t tmp, *w = p;
for(int i=0; i<size/2; i++)
tmp = w[i], w[i] = w[size-i-1], w[size-i-1] = tmp;
}
// Looks like a double mantissa in hex or dec notation
static int is_mantissa_only(char *p) {
char *digs;
if(*p == '+' || *p == '-')
p++;
if(*p == '0' && (p[1] == 'x' || p[1] == 'X')) {
p += 2;
digs = "0123456789abcdefABCDEF";
} else
digs = "0123456789";
if(!*p)
return 0;
while(*p)
if(!strchr(digs, *p++))
return 0;
return 1;
}
static int cmd_write(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
if (argc < 4) {
terminal_message(MSG_INFO,
"Usage: write <memory> <addr> <data>[,] {<data>[,]} \n"
" write <memory> <addr> <len> <data>[,] {<data>[,]} ...\n"
"\n"
"Ellipsis ... writes <len> bytes padded by repeating the last <data> item.\n"
"\n"
"<data> can be hexadecimal, octal or decimal integers, floating point numbers\n"
"or C-style strings and characters. For integers, an optional case-insensitive\n"
"suffix specifies the data size: HH 8 bit, H/S 16 bit, L 32 bit, LL 64 bit.\n"
"Suffix D indicates a 64-bit double, F a 32-bit float, whilst a floating point\n"
"number without suffix defaults to 32-bit float. Hexadecimal floating point\n"
"notation is supported. An ambiguous trailing suffix, eg, 0x1.8D, is read as\n"
"no-suffix float where D is part of the mantissa; use a zero exponent 0x1.8p0D\n"
"to clarify.\n"
"\n"
"An optional U suffix makes integers unsigned. Ordinary 0x hex integers are\n"
"always treated as unsigned. +0x or -0x hex numbers are treated as signed\n"
"unless they have a U suffix. Unsigned integers cannot be larger than 2^64-1.\n"
"If n is an unsigned integer then -n is also a valid unsigned integer as in C.\n"
"Signed integers must fall into the [-2^63, 2^63-1] range or a correspondingly\n"
"smaller range when a suffix specifies a smaller type. Out of range signed\n"
"numbers trigger a warning.\n"
"\n"
"Ordinary 0x hex integers with n hex digits (counting leading zeros) use the\n"
"smallest size of 1, 2, 4 and 8 bytes that can accommodate any n-digit hex\n"
"integer. If an integer suffix specifies a size explicitly the corresponding\n"
"number of least significant bytes are written. Otherwise, signed and unsigned\n"
"integers alike occupy the smallest of 1, 2, 4, or 8 bytes needed to\n"
"accommodate them in their respective representation.\n"
);
return -1;
}
int i;
uint8_t write_mode; // Operation mode, "standard" or "fill"
uint8_t start_offset; // Which argc argument
int len; // Number of bytes to write to memory
char * memtype = argv[1]; // Memory name string
AVRMEM * mem = avr_locate_mem(p, memtype);
if (mem == NULL) {
terminal_message(MSG_INFO, "%s (write): %s memory type not defined for part %s\n",
progname, memtype, p->desc);
return -1;
}
int maxsize = mem->size;
char * end_ptr;
int addr = strtoul(argv[2], &end_ptr, 0);
if (*end_ptr || (end_ptr == argv[2])) {
terminal_message(MSG_INFO, "%s (write): can't parse address %s\n",
progname, argv[2]);
return -1;
}
if (addr > maxsize) {
terminal_message(MSG_INFO, "%s (write): address 0x%05lx is out of range for %s memory\n",
progname, (long) addr, memtype);
return -1;
}
// Allocate a buffer guaranteed to be large enough
uint8_t * buf = calloc(mem->size + 8 + maxstrlen(argc-3, argv+3)+1, sizeof(uint8_t));
if (buf == NULL) {
terminal_message(MSG_INFO, "%s (write): out of memory\n", progname);
return -1;
}
// Find the first argument to write to flash and how many arguments to parse and write
if (strcmp(argv[argc - 1], "...") == 0) {
write_mode = WRITE_MODE_FILL;
start_offset = 4;
len = strtoul(argv[3], &end_ptr, 0);
if (*end_ptr || (end_ptr == argv[3])) {
terminal_message(MSG_INFO, "%s (write ...): can't parse length %s\n",
progname, argv[3]);
free(buf);
return -1;
}
} else {
write_mode = WRITE_MODE_STANDARD;
start_offset = 3;
len = argc - start_offset;
}
// Structure related to data that is being written to memory
struct Data {
// Data info
int bytes_grown;
uint8_t size;
char *str_ptr;
// Data union
union {
float f;
double d;
int64_t ll;
uint64_t ull;
uint8_t a[8];
};
} data = {
.bytes_grown = 0,
.size = 0,
.str_ptr = NULL,
.ull = 1
};
if(sizeof(long long) != sizeof(int64_t) || (data.a[0]^data.a[7]) != 1)
terminal_message(MSG_INFO, "%s (write): assumption on data types not met? "
"Check source and recompile\n", progname);
bool is_big_endian = data.a[7];
for (i = start_offset; i < len + start_offset; i++) {
// Handle the next argument
if (i < argc - start_offset + 3) {
char *argi = argv[i];
size_t arglen = strlen(argi);
data.size = 0;
// Free string pointer if already allocated
if(data.str_ptr) {
free(data.str_ptr);
data.str_ptr = NULL;
}
// Remove trailing comma to allow cut and paste of lists
if(arglen > 0 && argi[arglen-1] == ',')
argi[--arglen] = 0;
// Try integers and assign data size
errno = 0;
data.ull = strtoull(argi, &end_ptr, 0);
if (!(end_ptr == argi || errno)) {
unsigned int nu=0, nl=0, nh=0, ns=0, nx=0;
char *p;
// Parse suffixes: ULL, LL, UL, L ... UHH, HH
for(p=end_ptr; *p; p++)
switch(toupper(*p)) {
case 'U': nu++; break;
case 'L': nl++; break;
case 'H': nh++; break;
case 'S': ns++; break;
default: nx++;
}
if(nx==0 && nu<2 && nl<3 && nh<3 && ns<2) { // Could be valid integer suffix
if(nu==0 || toupper(*end_ptr) == 'U' || toupper(p[-1]) == 'U') { // If U, then must be at start or end
bool is_hex = strncasecmp(argi, "0x", 2) == 0; // Ordinary hex: 0x... without explicit +/- sign
bool is_signed = !(nu || is_hex); // Neither explicitly unsigned nor ordinary hex
bool is_outside_int64_t = 0;
bool is_out_of_range = 0;
int nhexdigs = p-argi-2;
if(is_signed) { // Is input in range for int64_t?
errno = 0; (void) strtoll(argi, NULL, 0);
is_outside_int64_t = errno == ERANGE;
}
if(nl==0 && ns==0 && nh==0) { // No explicit data size
// Ordinary hex numbers have implicit size given by number of hex digits, including leading zeros
if(is_hex) {
data.size = nhexdigs > 8? 8: nhexdigs > 4? 4: nhexdigs > 2? 2: 1;
} else if(is_signed) {
// Smallest size that fits signed representation
data.size =
is_outside_int64_t? 8:
data.ll < INT32_MIN || data.ll > INT32_MAX? 8:
data.ll < INT16_MIN || data.ll > INT16_MAX? 4:
data.ll < INT8_MIN || data.ll > INT8_MAX? 2: 1;
} else {
// Smallest size that fits unsigned representation
data.size =
data.ull > UINT32_MAX? 8:
data.ull > UINT16_MAX? 4:
data.ull > UINT8_MAX? 2: 1;
}
} else if(nl==0 && nh==2 && ns==0) { // HH
data.size = 1;
if(is_outside_int64_t || (is_signed && (data.ll < INT8_MIN || data.ll > INT8_MAX))) {
is_out_of_range = 1;
data.ll = (int8_t) data.ll;
}
} else if(nl==0 && ((nh==1 && ns==0) || (nh==0 && ns==1))) { // H or S
data.size = 2;
if(is_outside_int64_t || (is_signed && (data.ll < INT16_MIN || data.ll > INT16_MAX))) {
is_out_of_range = 1;
data.ll = (int16_t) data.ll;
}
} else if(nl==1 && nh==0 && ns==0) { // L
data.size = 4;
if(is_outside_int64_t || (is_signed && (data.ll < INT32_MIN || data.ll > INT32_MAX))) {
is_out_of_range = 1;
data.ll = (int32_t) data.ll;
}
} else if(nl==2 && nh==0 && ns==0) { // LL
data.size = 8;
}
if(is_outside_int64_t || is_out_of_range)
terminal_message(MSG_INFO, "%s (write): %s out of int%d_t range, "
"interpreted as %d-byte %lld; consider 'U' suffix\n",
progname, argi, data.size*8, data.size, data.ll);
}
}
}
if(!data.size) { // Try double now that input was rejected as integer
data.d = strtod(argi, &end_ptr);
if (end_ptr != argi && toupper(*end_ptr) == 'D' && end_ptr[1] == 0)
data.size = 8;
}
if(!data.size) { // Try float
data.f = strtof(argi, &end_ptr);
if (end_ptr != argi && toupper(*end_ptr) == 'F' && end_ptr[1] == 0)
data.size = 4;
if (end_ptr != argi && *end_ptr == 0) // no suffix defaults to float but ...
// ... do not accept valid mantissa-only floats that are integer rejects (eg, 078 or ULL overflows)
if (!is_mantissa_only(argi))
data.size = 4;
}
if(!data.size && arglen > 1) { // Try C-style string or single character
if ((*argi == '\'' && argi[arglen-1] == '\'') || (*argi == '\"' && argi[arglen-1] == '\"')) {
char *s = calloc(arglen-1, 1);
if (s == NULL) {
terminal_message(MSG_INFO, "%s (write str): out of memory\n", progname);
free(buf);
return -1;
}
// Strip start and end quotes, and unescape C string
strncpy(s, argi+1, arglen-2);
cfg_unescape(s, s);
if (*argi == '\'') { // Single C-style character
if(*s && s[1])
terminal_message(MSG_INFO, "%s (write): only using first character of %s\n",
progname, argi);
data.ll = *s;
data.size = 1;
free(s);
} else { // C-style string
data.str_ptr = s;
}
}
}
if(!data.size && !data.str_ptr) {
terminal_message(MSG_INFO, "%s (write): can't parse data %s\n",
progname, argi);
free(buf);
return -1;
}
// Assume endianness is the same for double and int, and ensure little endian representation
if(is_big_endian && data.size > 1)
change_endian(data.a, data.size);
}
if(data.str_ptr) {
for(size_t j = 0; j < strlen(data.str_ptr); j++)
buf[i - start_offset + data.bytes_grown++] = (uint8_t)data.str_ptr[j];
} else if(data.size > 0) {
for(int k=0; k<data.size; k++)
buf[i - start_offset + data.bytes_grown + k] = data.a[k];
data.bytes_grown += data.size-1;
}
// Make sure buf does not overflow
if (i - start_offset + data.bytes_grown > maxsize)
break;
}
// When in "fill" mode, the maximum size is already predefined
if (write_mode == WRITE_MODE_FILL)
data.bytes_grown = 0;
if ((addr + len + data.bytes_grown) > maxsize) {
terminal_message(MSG_INFO, "%s (write): selected address and # bytes exceed "
"range for %s memory\n", progname, memtype);
free(buf);
return -1;
}
if(data.str_ptr)
free(data.str_ptr);
terminal_message(MSG_NOTICE, "Info: writing %d bytes starting from address 0x%02lx",
len + data.bytes_grown, (long) addr);
if (write_mode == WRITE_MODE_FILL)
terminal_message(MSG_NOTICE, "; remaining space filled with %s", argv[argc - 2]);
terminal_message(MSG_NOTICE, "\n");
pgm->err_led(pgm, OFF);
bool werror = false;
report_progress(0, 1, "Writing");
for (i = 0; i < (len + data.bytes_grown); i++) {
int rc = avr_write_byte(pgm, p, mem, addr+i, buf[i]);
if (rc) {
terminal_message(MSG_INFO, "%s (write): error writing 0x%02x at 0x%05lx, rc=%d\n",
progname, buf[i], (long) addr+i, (int) rc);
if (rc == -1)
terminal_message(MSG_INFO, "%*swrite operation not supported on memory type %s\n",
(int) strlen(progname)+10, "", mem->desc);
werror = true;
}
uint8_t b;
rc = pgm->read_byte(pgm, p, mem, addr+i, &b);
if (b != buf[i]) {
terminal_message(MSG_INFO, "%s (write): error writing 0x%02x at 0x%05lx cell=0x%02x\n",
progname, buf[i], (long) addr+i, b);
werror = true;
}
if (werror) {
pgm->err_led(pgm, ON);
}
report_progress(i, (len + data.bytes_grown), NULL);
}
report_progress(1, 1, NULL);
free(buf);
return 0;
}
static int cmd_send(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
unsigned char cmd[4], res[4];
char * e;
int i;
int len;
if (pgm->cmd == NULL) {
terminal_message(MSG_INFO, "%s (send): the %s programmer does not support direct ISP commands\n",
progname, pgm->type);
return -1;
}
if (spi_mode && (pgm->spi == NULL)) {
terminal_message(MSG_INFO, "%s (send): the %s programmer does not support direct SPI transfers\n",
progname, pgm->type);
return -1;
}
if ((argc > 5) || ((argc < 5) && (!spi_mode))) {
terminal_message(MSG_INFO, spi_mode?
"Usage: send <byte1> [<byte2> [<byte3> [<byte4>]]]\n":
"Usage: send <byte1> <byte2> <byte3> <byte4>\n");
return -1;
}
/* number of bytes to write at the specified address */
len = argc - 1;
/* load command bytes */
for (i=1; i<argc; i++) {
cmd[i-1] = strtoul(argv[i], &e, 0);
if (*e || (e == argv[i])) {
terminal_message(MSG_INFO, "%s (send): can't parse byte %s\n",
progname, argv[i]);
return -1;
}
}
pgm->err_led(pgm, OFF);
if (spi_mode)
pgm->spi(pgm, cmd, res, argc-1);
else
pgm->cmd(pgm, cmd, res);
/*
* display results
*/
terminal_message(MSG_INFO, "results:");
for (i=0; i<len; i++)
terminal_message(MSG_INFO, " %02x", res[i]);
terminal_message(MSG_INFO, "\n");
fprintf(stdout, "\n");
return 0;
}
static int cmd_erase(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
terminal_message(MSG_INFO, "%s: erasing chip\n", progname);
pgm->chip_erase(pgm, p);
return 0;
}
static int cmd_part(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
fprintf(stdout, "\n");
avr_display(stdout, p, "", 0);
fprintf(stdout, "\n");
return 0;
}
static int cmd_sig(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int i;
int rc;
AVRMEM * m;
rc = avr_signature(pgm, p);
if (rc != 0) {
terminal_message(MSG_INFO, "%s (sig): error reading signature data, rc=%d\n",
progname, rc);
}
m = avr_locate_mem(p, "signature");
if (m == NULL) {
terminal_message(MSG_INFO, "%s (sig): signature data not defined for device %s\n",
progname, p->desc);
}
else {
fprintf(stdout, "Device signature = 0x");
for (i=0; i<m->size; i++)
fprintf(stdout, "%02x", m->buf[i]);
fprintf(stdout, "\n\n");
}
return 0;
}
static int cmd_quit(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
/* FUSE bit verify will fail if left in SPI mode */
if (spi_mode) {
cmd_pgm(pgm, p, 0, NULL);
}
return 1;
}
static int cmd_parms(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
if (pgm->print_parms == NULL) {
terminal_message(MSG_INFO, "%s (parms): the %s programmer does not support "
"adjustable parameters\n", progname, pgm->type);
return -1;
}
pgm->print_parms(pgm);
terminal_message(MSG_INFO, "\n");
return 0;
}
static int cmd_vtarg(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int rc;
double v;
char *endp;
if (argc != 2) {
terminal_message(MSG_INFO, "Usage: vtarg <value>\n");
return -1;
}
v = strtod(argv[1], &endp);
if (endp == argv[1]) {
terminal_message(MSG_INFO, "%s (vtarg): can't parse voltage %s\n",
progname, argv[1]);
return -1;
}
if (pgm->set_vtarget == NULL) {
terminal_message(MSG_INFO, "%s (vtarg): the %s programmer cannot set V[target]\n",
progname, pgm->type);
return -2;
}
if ((rc = pgm->set_vtarget(pgm, v)) != 0) {
terminal_message(MSG_INFO, "%s (vtarg): failed to set V[target] (rc = %d)\n",
progname, rc);
return -3;
}
return 0;
}
static int cmd_fosc(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int rc;
double v;
char *endp;
if (argc != 2) {
terminal_message(MSG_INFO, "Usage: fosc <value>[M|k] | off\n");
return -1;
}
v = strtod(argv[1], &endp);
if (endp == argv[1]) {
if (strcmp(argv[1], "off") == 0)
v = 0.0;
else {
terminal_message(MSG_INFO, "%s (fosc): can't parse frequency %s\n",
progname, argv[1]);
return -1;
}
}
if (*endp == 'm' || *endp == 'M')
v *= 1e6;
else if (*endp == 'k' || *endp == 'K')
v *= 1e3;
if (pgm->set_fosc == NULL) {
terminal_message(MSG_INFO, "%s (fosc): the %s programmer cannot set oscillator frequency\n",
progname, pgm->type);
return -2;
}
if ((rc = pgm->set_fosc(pgm, v)) != 0) {
terminal_message(MSG_INFO, "%s (fosc): failed to set oscillator frequency (rc = %d)\n",
progname, rc);
return -3;
}
return 0;
}
static int cmd_sck(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int rc;
double v;
char *endp;
if (argc != 2) {
terminal_message(MSG_INFO, "Usage: sck <value>\n");
return -1;
}
v = strtod(argv[1], &endp);
if (endp == argv[1]) {
terminal_message(MSG_INFO, "%s (sck): can't parse period %s\n",
progname, argv[1]);
return -1;
}
v *= 1e-6; /* Convert from microseconds to seconds. */
if (pgm->set_sck_period == NULL) {
terminal_message(MSG_INFO, "%s (sck): the %s programmer cannot set SCK period\n",
progname, pgm->type);
return -2;
}
if ((rc = pgm->set_sck_period(pgm, v)) != 0) {
terminal_message(MSG_INFO, "%s (sck): failed to set SCK period (rc = %d)\n",
progname, rc);
return -3;
}
return 0;
}
static int cmd_varef(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int rc;
unsigned int chan;
double v;
char *endp;
if (argc != 2 && argc != 3) {
terminal_message(MSG_INFO, "Usage: varef [channel] <value>\n");
return -1;
}
if (argc == 2) {
chan = 0;
v = strtod(argv[1], &endp);
if (endp == argv[1]) {
terminal_message(MSG_INFO, "%s (varef): can't parse voltage %s\n",
progname, argv[1]);
return -1;
}
} else {
chan = strtoul(argv[1], &endp, 10);
if (endp == argv[1]) {
terminal_message(MSG_INFO, "%s (varef): can't parse channel %s\n",
progname, argv[1]);
return -1;
}
v = strtod(argv[2], &endp);
if (endp == argv[2]) {
terminal_message(MSG_INFO, "%s (varef): can't parse voltage %s\n",
progname, argv[2]);
return -1;
}
}
if (pgm->set_varef == NULL) {
terminal_message(MSG_INFO, "%s (varef): the %s programmer cannot set V[aref]\n",
progname, pgm->type);
return -2;
}
if ((rc = pgm->set_varef(pgm, chan, v)) != 0) {
terminal_message(MSG_INFO, "%s (varef): failed to set V[aref] (rc = %d)\n",
progname, rc);
return -3;
}
return 0;
}
static int cmd_help(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int i;
fprintf(stdout, "Valid commands:\n");
for (i=0; i<NCMDS; i++) {
fprintf(stdout, " %-7s : ", cmd[i].name);
fprintf(stdout, cmd[i].desc, cmd[i].name);
fprintf(stdout, "\n");
}
fprintf(stdout,
"\nUse the 'part' command to display valid memory types for use with the\n"
"'dump' and 'write' commands.\n\n");
return 0;
}
static int cmd_spi(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
if (pgm->setpin != NULL) {
pgm->setpin(pgm, PIN_AVR_RESET, 1);
spi_mode = 1;
return 0;
}
terminal_message(MSG_INFO, "%s: spi command unavailable for this programmer type\n",
progname);
return -1;
}
static int cmd_pgm(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
if (pgm->setpin != NULL) {
pgm->setpin(pgm, PIN_AVR_RESET, 0);
spi_mode = 0;
pgm->initialize(pgm, p);
return 0;
}
terminal_message(MSG_INFO, "%s: pgm command unavailable for this programmer type\n",
progname);
return -1;
}
static int cmd_verbose(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int nverb;
char *endp;
if (argc != 1 && argc != 2) {
terminal_message(MSG_INFO, "Usage: verbose [<value>]\n");
return -1;
}
if (argc == 1) {
terminal_message(MSG_INFO, "Verbosity level: %d\n", verbose);
return 0;
}
nverb = strtol(argv[1], &endp, 0);
if (endp == argv[1] || *endp) {
terminal_message(MSG_INFO, "%s (verbose): can't parse verbosity level %s\n",
progname, argv[1]);
return -1;
}
if (nverb < 0) {
terminal_message(MSG_INFO, "%s: verbosity level must not be negative: %d\n",
progname, nverb);
return -1;
}
verbose = nverb;
terminal_message(MSG_INFO, "New verbosity level: %d\n", verbose);
return 0;
}
static int cmd_quell(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int nquell;
char *endp;
if (argc != 1 && argc != 2) {
terminal_message(MSG_INFO, "Usage: quell [<value>]\n");
return -1;
}
if (argc == 1) {
terminal_message(MSG_INFO, "Quell level: %d\n", quell_progress);
return 0;
}
nquell = strtol(argv[1], &endp, 0);
if (endp == argv[1] || *endp) {
terminal_message(MSG_INFO, "%s (quell): can't parse quell level %s\n",
progname, argv[1]);
return -1;
}
if (nquell < 0) {
terminal_message(MSG_INFO, "%s: quell level must not be negative: %d\n",
progname, nquell);
return -1;
}
quell_progress = nquell;
terminal_message(MSG_INFO, "New quell level: %d\n", quell_progress);
if(quell_progress > 0)
update_progress = NULL;
else
terminal_setup_update_progress();
return 0;
}
static int tokenize(char * s, char *** argv)
{
int i, n, l, k, nargs, offset;
int len, slen;
char * buf;
int bufsize;
char ** bufv;
char * bufp;
char * q, * r;
char * nbuf;
char ** av;
slen = strlen(s);
/*
* initialize allow for 20 arguments, use realloc to grow this if
* necessary
*/
nargs = 20;
bufsize = slen + 20;
buf = malloc(bufsize);
bufv = (char **) malloc(nargs*sizeof(char *));
for (i=0; i<nargs; i++) {
bufv[i] = NULL;
}
buf[0] = 0;
n = 0;
l = 0;
nbuf = buf;
r = s;
while (*r) {
nexttok(r, &q, &r);
strcpy(nbuf, q);
bufv[n] = nbuf;
len = strlen(q);
l += len + 1;
nbuf += len + 1;
nbuf[0] = 0;
n++;
if ((n % 20) == 0) {
char *buf_tmp;
char **bufv_tmp;
/* realloc space for another 20 args */
bufsize += 20;
nargs += 20;
bufp = buf;
buf_tmp = realloc(buf, bufsize);
if (buf_tmp == NULL) {
free(buf);
free(bufv);
return -1;
}
buf = buf_tmp;
bufv_tmp = realloc(bufv, nargs*sizeof(char *));
if (bufv_tmp == NULL) {
free(buf);
free(bufv);
return -1;
}
bufv = bufv_tmp;
nbuf = &buf[l];
/* correct bufv pointers */
k = buf - bufp;
for (i=0; i<n; i++) {
bufv[i] = bufv[i] + k;
}
for (i=n; i<nargs; i++)
bufv[i] = NULL;
}
}
/*
* We have parsed all the args, n == argc, bufv contains an array of
* pointers to each arg, and buf points to one memory block that
* contains all the args, back to back, seperated by a nul
* terminator. Consilidate bufv and buf into one big memory block
* so that the code that calls us, will have an easy job of freeing
* this memory.
*/
av = (char **) malloc(slen + n + (n+1)*sizeof(char *));
q = (char *)&av[n+1];
memcpy(q, buf, l);
for (i=0; i<n; i++) {
offset = bufv[i] - buf;
av[i] = q + offset;
}
av[i] = NULL;
free(buf);
free(bufv);
*argv = av;
return n;
}
static int do_cmd(PROGRAMMER * pgm, struct avrpart * p,
int argc, char * argv[])
{
int i;
int hold;
int len;
len = strlen(argv[0]);
hold = -1;
for (i=0; i<NCMDS; i++) {
if (strcasecmp(argv[0], cmd[i].name) == 0) {
return cmd[i].func(pgm, p, argc, argv);
}
else if (strncasecmp(argv[0], cmd[i].name, len)==0) {
if (hold != -1) {
terminal_message(MSG_INFO, "%s (cmd): command %s is ambiguous\n",
progname, argv[0]);
return -1;
}
hold = i;
}
}
if (hold != -1)
return cmd[hold].func(pgm, p, argc, argv);
terminal_message(MSG_INFO, "%s (cmd): invalid command %s\n",
progname, argv[0]);
return -1;
}
char * terminal_get_input(const char *prompt)
{
#if defined(HAVE_LIBREADLINE) && !defined(WIN32)
char *input;
input = readline(prompt);
if ((input != NULL) && (strlen(input) >= 1))
add_history(input);
return input;
#else
char input[256];
printf("%s", prompt);
if (fgets(input, sizeof(input), stdin))
{
/* FIXME: readline strips the '\n', should this too? */
return strdup(input);
}
else
return NULL;
#endif
}
int terminal_mode(PROGRAMMER * pgm, struct avrpart * p)
{
char * cmdbuf;
char * q;
int rc;
int argc;
char ** argv;
rc = 0;
while ((cmdbuf = terminal_get_input("avrdude> ")) != NULL) {
/*
* find the start of the command, skipping any white space
*/
q = cmdbuf;
while (*q && isspace((unsigned char) *q))
q++;
/* skip blank lines and comments */
if (!*q || (*q == '#'))
continue;
/* tokenize command line */
argc = tokenize(q, &argv);
if (argc < 0) {
free(cmdbuf);
return argc;
}
#if !defined(HAVE_LIBREADLINE) || defined(WIN32) || defined(__APPLE__)
fprintf(stdout, ">>> ");
for (int i=0; i<argc; i++)
fprintf(stdout, "%s ", argv[i]);
fprintf(stdout, "\n");
#endif
/* run the command */
rc = do_cmd(pgm, p, argc, argv);
free(argv);
if (rc > 0) {
rc = 0;
break;
}
free(cmdbuf);
}
return rc;
}
int terminal_message(const int msglvl, const char *format, ...) {
int rc = 0;
va_list ap;
fflush(stdout); fflush(stderr);
if (verbose >= msglvl) {
va_start(ap, format);
rc = vfprintf(stderr, format, ap);
va_end(ap);
}
fflush(stderr);
return rc;
}
static void update_progress_tty (int percent, double etime, char *hdr)
{
static char hashes[51];
static char *header;
static int last = 0;
int i;
setvbuf(stderr, (char*)NULL, _IONBF, 0);
hashes[50] = 0;
memset (hashes, ' ', 50);
for (i=0; i<percent; i+=2) {
hashes[i/2] = '#';
}
if (hdr) {
avrdude_message(MSG_INFO, "\n");
last = 0;
header = hdr;
}
if (last == 0) {
avrdude_message(MSG_INFO, "\r%s | %s | %d%% %0.2fs",
header, hashes, percent, etime);
}
if (percent == 100) {
if (!last) avrdude_message(MSG_INFO, "\n\n");
last = 1;
}
setvbuf(stderr, (char*)NULL, _IOLBF, 0);
}
static void update_progress_no_tty (int percent, double etime, char *hdr)
{
static int done = 0;
static int last = 0;
int cnt = (percent>>1)*2;
setvbuf(stderr, (char*)NULL, _IONBF, 0);
if (hdr) {
avrdude_message(MSG_INFO, "\n%s | ", hdr);
last = 0;
done = 0;
}
else {
while ((cnt > last) && (done == 0)) {
avrdude_message(MSG_INFO, "#");
cnt -= 2;
}
}
if ((percent == 100) && (done == 0)) {
avrdude_message(MSG_INFO, " | 100%% %0.2fs\n\n", etime);
last = 0;
done = 1;
}
else
last = (percent>>1)*2; /* Make last a multiple of 2. */
setvbuf(stderr, (char*)NULL, _IOLBF, 0);
}
void terminal_setup_update_progress() {
if (isatty (STDERR_FILENO))
update_progress = update_progress_tty;
else {
update_progress = update_progress_no_tty;
/* disable all buffering of stderr for compatibility with
software that captures and redirects output to a GUI
i.e. Programmers Notepad */
setvbuf( stderr, NULL, _IONBF, 0 );
setvbuf( stdout, NULL, _IONBF, 0 );
}
}