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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [arm/] [pid/] [v2_0/] [src/] [flash.c] - Rev 174
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//========================================================================== // // flash.c // // ARM PID7 eval board FLASH program tool // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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 or (at your option) any later version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: gthomas // Date: 1998-11-18 // Description: Tool used to program onboard FLASH image //####DESCRIPTIONEND#### // // This program will program the FLASH on the PID board // #include <pkgconf/libc.h> // Configuration header #include <cyg/kernel/kapi.h> #include <stdlib.h> #include <ctype.h> #include <cyg/infra/testcase.h> #include <sys/cstartup.h> #ifndef FALSE #define FALSE 0 #define TRUE 1 #endif #define SYNC_COUNT 63 extern void diag_printf(const char *, ...); int identify_FLASH(void); void write_sector(int, char *); bool load_srecords(char (*readc)(), CYG_ADDRESS *start, int *size); char dbuf[256]; char *raw = (char *)0x10000; char *flash_buffer = (char *)0x30000; int pos, len; // FUNCTIONS externC void cyg_package_start( void ) { #ifdef CYGPKG_LIBC cyg_iso_c_start(); #else (void)main(0, NULL); #endif } // cyg_package_start() char nextch(void) { return (raw[pos++]); } int main( int argc, char *argv[] ) { int i, j, size; CYG_ADDRESS entry; char c; diag_printf("FLASH here!\n"); while (identify_FLASH() == 0) { diag_printf("... Please change FLASH jumper - hit C/R to continue:"); do { hal_diag_read_char(&c); } while ((c != '\r') && (c != '\n')); diag_printf("\n"); } restart: diag_printf("Ready file - hit C/R to continue:"); while (TRUE) { hal_diag_read_char(&c); if (c == '>') break; } i = 0; j = 0; while (1) { hal_diag_read_char(&c); if (c == '!') { diag_printf("... Reset\n"); goto restart; } raw[i++] = c; if (++j == SYNC_COUNT) { hal_diag_write_char(c); j = 0; } if (c == ':') break; } diag_printf("\n"); pos = 0; len = i; if (load_srecords(nextch, &entry, &size)) { diag_printf("Read %x bytes, entry: %x\n", size, entry); dump_buf(flash_buffer, 128); diag_printf("\nData loaded - hit '!' to continue:"); while (TRUE) { hal_diag_read_char(&c); if (c == '!') break; } diag_printf("\n"); diag_printf("...Programming FLASH\n"); pos = 0; i = 0; while (pos < size) { write_sector(i++, flash_buffer+pos); pos += 256; } } else { // Display buffer around failure dump_buf(&raw[pos-32], 64); } diag_printf("All done!\n"); while (1) ; } // Adapted from ARM sample code #define SEQ_ADD1 0x5555 #define SEQ_ADD2 0xAAAA #define START_CMD1 0xAA #define START_CMD2 0x55 #define ID_CMD 0x90 #define PROG_CMD 0xA0 #define STOP_CMD 0xF0 #define MAN_ATMEL 0x1F #define ATMEL_AT29C040_ID 0X5B #define ATMEL_AT29C040A_ID 0XA4 #define ATMEL_AT29C1024_ID 0X25 #define ATMEL_SECTOR_SIZE 256 #define ATMEL_MAX_SECTORS 2048 int manuf_code, device_code, sector_size, max_no_of_sectors, word_mode; volatile char *FLASH = (volatile char *)0x04000000; int identify_FLASH(void ) { // Enter Software Product Identification Mode FLASH[SEQ_ADD1] = START_CMD1; FLASH[SEQ_ADD2] = START_CMD2; FLASH[SEQ_ADD1] = ID_CMD; // Wait at least 10ms cyg_thread_delay(2); // Read Manufacturer and device code from the device manuf_code = FLASH[0]; device_code = FLASH[1]; diag_printf("manuf: %x, device: %x\n", manuf_code, device_code); // Exit Software Product Identification Mode FLASH[SEQ_ADD1] = START_CMD1; FLASH[SEQ_ADD2] = START_CMD2; FLASH[SEQ_ADD1] = STOP_CMD; // Wait at least 10ms cyg_thread_delay(5); if (manuf_code != MAN_ATMEL) { diag_printf ( "Error: Wrong Manufaturer: %02x\n",manuf_code ); return (0); } switch (device_code) { case ATMEL_AT29C040A_ID: diag_printf ("AT29C040A recognised\n"); sector_size = ATMEL_SECTOR_SIZE; max_no_of_sectors = ATMEL_MAX_SECTORS; word_mode = FALSE; break; case ATMEL_AT29C1024_ID: diag_printf ("AT29C1024 recognised\n"); sector_size = ATMEL_SECTOR_SIZE; max_no_of_sectors = ATMEL_MAX_SECTORS; word_mode = TRUE; break; default : diag_printf ( "Error: Unsupported device: %02x\n", device_code); return (0); } return (1); } void write_sector(int num, char *buf) { int i, cnt; volatile char *wrt = (volatile int *)&FLASH[num*sector_size]; // diag_printf("Writing to %08x\n", wrt); // Enter Program Mode FLASH[SEQ_ADD1] = START_CMD1; FLASH[SEQ_ADD2] = START_CMD2; FLASH[SEQ_ADD1] = PROG_CMD; // Note: write bytes as longs regardless of bus width for (i = 0; i < sector_size; i++) { wrt[i] = buf[i]; } // Wait for sector to program cnt = 0; i = sector_size - 1; while (wrt[i] != buf[i]) { if (cnt++ > 0x01000000) break; } // diag_printf("Out - i: %d, wrt[i] = %08X.%08X, buf[i] = %08X, count = %x\n", i, &wrt[i], wrt[i], buf[i], cnt); // Verify for (i = 0; i < sector_size; i++) { for (cnt = 0; cnt < 10; cnt++) { if (*wrt == *buf) break; cyg_thread_delay(1); } if (cnt == 10) { diag_printf("Can't program at 0x%08X: %02X not %02X\n", wrt, *wrt, *buf); } wrt++; buf++; } } // S-record download code - viciously 'adapted' from "kernel/src/sload/sload.c" /*---------------------------------------------------------------------------*/ /* // // An srecord looks like this: // // byte count-+ address // start ---+ | | data +- checksum // | | | | // S01000006F6B692D746573742E73726563E4 // S315000448600000000000000000FC00005900000000E9 // S31A0004000023C1400037DE00F023604000377B009020825000348D // S30B0004485A0000000000004E // S70500040000F6 // // S<type><length><address><data><checksum> // // Where // - length (2 characters) // is the number of bytes following upto the checksum. Note that // this is not the number of chars following, since it takes two // chars to represent a byte. // - type (2 characters) // is one of: // 0) header record // 1) two byte address data record // 2) three byte address data record // 3) four byte address data record // 5) record containing the number of S1, S2, or S3 records // 7) four byte address termination record // 8) three byte address termination record // 9) two byte address termination record // // - address (4, 6, or 8 characters) // is the start address of the data following, or in the case of // a termination record, the start address of the image // - data (0-2n characters) // is the data. // - checksum (2 characters) // is the sum of all the raw byte data in the record, from the length // upwards, modulo 256 and subtracted from 255. // // Useful S-records for testing purposes: // Start record: // S00B0000737461303030447563 // This sets the default address to be 0x02005000: // S31A020050002700801481C4E0B0A15000000100000091D02000018F // S31A0200501500000001000000010000002700801881C4E2E4A150C1 // S311020080A42407070A090B0A0781050000E1 // Termination record: // S70502005000A8 // */ #define S0 0 #define S1 1 #define S2 2 #define S3 3 #define S5 5 #define S7 7 #define S8 8 #define S9 9 /*---------------------------------------------------------------------------*/ int hex2digit(char c) { if( c & 0x40 ) c += 9;; return c &0x0f; // return ( c <= '9' ? c - '0' : // c <= 'Z' ? c - 'A' + 10 : // c - 'a' + 10); } /*---------------------------------------------------------------------------*/ bool load_srecords(char (*readc)(), CYG_ADDRESS *start, int *size) { CYG_ADDRESS addr, load_addr; int addrsize; int length; int i; cyg_uint8 chksum, ochksum; cyg_uint8 val; cyg_uint8 *tdata; char s; char type; char len0; char len1; bool first = true; do { // Skip whitespace characters until we find something that // might be an 'S'. do { s = readc(); } while( s == '\r' || s == '\n' || s == ' '); // Check that this is an S record if( s != 'S' ) { diag_printf("Invalid 'S' record\n"); return false; } // First 4 bytes are standard S + type + len type = readc(); len0 = readc(); len1 = readc(); // decode the type type = hex2digit(type); // determine address size switch (type) { case S0: // start records have no address addrsize = 0; break; case S1: // two byte address case S9: addrsize = 4; break; case S2: // 3 byte address case S8: addrsize = 6; break; case S3: // 4 byte address case S7: addrsize = 8; break; } length = hex2digit (len0) << 4; length |= hex2digit (len1); chksum = length; // read the address addr = 0; for (i = 0; i < addrsize; i++) { val = hex2digit(readc()); addr = (addr << 4) | val; } // calculate the checksum, which is done by the byte, not the digit for (i = 0; i < addrsize*4; i += 8) { chksum += ((addr >> i) & 0xff); } // decide where to load this data if (first && (type != S0)) { load_addr = addr; first = false; } // read the data and put it directly into memory where it belongs tdata = (cyg_uint8 *)((addr - load_addr) + flash_buffer); if (type < S7) { *size = (addr - load_addr); } val = 0; for (i = 0; i < ((length - 1) * 2) - addrsize; i += 2 ) { val = hex2digit (readc()) << 4; val |= hex2digit (readc()); chksum += val; if( type != S0 ) *tdata++ = val; if (type < S7) *size = *size + 1; } // now get the old checksum ochksum = hex2digit(readc()) << 4; ochksum |= hex2digit(readc()); chksum = ~chksum; if (chksum != ochksum) { diag_printf("Bad checksum - addr: %x\n", addr); return false; } } while( type < S7 ); *start = addr; return true; }