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[/] [System09/] [trunk/] [Tools/] [s19tovhd/] [S19toVHD.cpp] - Rev 138
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// S19toVHD.cpp : Defines the entry point for the console application. // /* * epedit * * binary file editer program */ #include <stdio.h> #include <string.h> #include <ctype.h> #include <math.h> /* * equates */ #define EPROM_MAX (1<<16) #define CMD_LINE_MAX 80 #define FALSE 0 #define TRUE !FALSE #define BINARY 0 #define MOTOROLA 1 #define INTEL 2 #define SMAL32 3 #define VHDL_BIN 4 #define VHDL_BYTE 5 #define VHDL_WORD 6 /* * global variables */ FILE *cmdfp; /* command input pointer */ char cmdbuff[CMD_LINE_MAX]; unsigned char eprom_buff[EPROM_MAX]; /* eprom buffer */ int eprom_top; /* top of EPROM buffer */ int mod_flag; /* buffer has been modified */ int auxflag; /* Auxillary input file specified */ int count; int checksum; int offset; /* Eprom Buffer memory offset */ int format_type; /* load / save format type */ char *hex_str = "0123456789ABCDEF"; /* * compare a string of specified length * return TRUE if a match * return FALSE if no match * ignore case */ int str_equal( char *s1, char *s2, int len ) { int i = 0; while( i<len ) { if( toupper( s1[i] ) == toupper( s2[i] ) ) i++; else return FALSE; } return TRUE; } int to_hexadecimal( char c ) { for( int k=0; k<16; k++ ) { if( toupper(c) == hex_str[k] ) return k; } return -1; } /* * extract an address from the command line * returns an offset to the end of the argument. */ int get_address( char *cb, int *addr ) { int i, j, k; j = i = 0; while((k = to_hexadecimal(cb[i])) != -1) { i++; j = j *16 + k; } *addr = j; if( i == 0 ) return i; while( isspace( cb[i]) ) i++; return i; } /* * Motorola S1 format to Intel hex format * Usage * mot2hex <file_name> */ int gethex( FILE *fp_in ) { int hex; hex = fgetc( fp_in ); return( to_hexadecimal( hex ) ); } int get2hex( FILE *fp_in ) { int hexhi, hexlo, byte; hexhi = gethex( fp_in ); if( hexhi != -1 ) { hexlo = gethex( fp_in ); if( hexlo != -1 ) { byte = hexhi * 16 + hexlo; checksum = (checksum + byte) & 0xff; return byte; } } return -1; } int get4hex( FILE *fp_in ) { int bytehi, bytelo, addr; bytehi = get2hex( fp_in ); if( bytehi != -1 ) { bytelo = get2hex( fp_in ); if( bytelo != -1 ) { addr = (bytehi * 256) + bytelo; return addr; } } return -1; } int get6hex( FILE *fp_in ) { int bytehi, bytemid, bytelow, addr; bytehi = get2hex( fp_in ); if( bytehi != -1 ) { bytemid = get2hex( fp_in ); if( bytemid != -1 ) { bytelow = get2hex( fp_in ); if( bytelow != -1 ) { addr = (bytehi << 16) + (bytemid << 8) + bytelow; return addr; } } } return -1; } long get8hex( FILE *fp_in ) { int wordhi, wordlow; long addr; wordhi = get4hex( fp_in ); if( wordhi != -1 ) { wordlow = get4hex( fp_in ); if( wordlow != -1 ) { addr = ((long)wordhi << 16) + (long)wordlow; return addr; } } return -1; } /* * load motorola formatted file */ bool load_mot( char *fname_in ) { FILE *fp_in; int byte, addr, i; fp_in = fopen( fname_in, "r" ); if ( !fp_in ) { printf( "\nCan't open %s", fname_in ); return false; } byte = 0; addr = 0; while( byte != -1 ) { do { byte = fgetc( fp_in); } while( (byte != 'S') && (byte != -1) ); byte = fgetc( fp_in ); checksum = 0; if ( (byte == '1') || (byte == '2') ) { count = get2hex( fp_in ); if ( byte == '1' ) { addr = get4hex( fp_in ); count -= 3; } else { addr = get6hex( fp_in ); count -= 4; } for( i=0; i<count; i++ ) { byte = get2hex( fp_in ); eprom_buff[( addr - offset) % EPROM_MAX ] = (unsigned char)byte; addr++; } byte = get2hex( fp_in); checksum = (~checksum) & 0xff; if ( checksum != 0 ) printf( "\nchecksum error - read check = %02x", byte ); } } fclose( fp_in ); return true; } int put2hex( FILE *fp, int h ) { int hex = (h & 0xf0)>>4; int i = fputc( (int)hex_str[hex], fp ); hex = (h & 0xf); i = fputc( (int)hex_str[hex], fp ); checksum = (checksum + h) & 0xff; return i; } int put4hex( FILE * fp, int h ) { int i = put2hex( fp, (h & 0xff00 )>>8 ); i = put2hex( fp, (h & 0xff) ); return i; } char *bin_string( int num, int num_len ) { static char retbuf[33]; char *p; int i; p = &retbuf[sizeof(retbuf)-1]; *p = '\0'; for (i=0; i<num_len; i++ ) { *--p = "01"[num % 2]; num >>= 1; } return p; } /* * save VHDL hexadecimal file 4KBit Block RAM (Spartan 2) */ void save_vhdl_b4( FILE *fp_out, char *entity_name, int start_addr, int end_addr ) { int addr; int i,j; int byte; int rom_num, rom_max, rom_len; int addr_len; rom_max = (end_addr+1-start_addr)/512; rom_len = 8; addr_len = (int)(log((double)(end_addr-start_addr))/log(2.0)); fprintf(fp_out, "library IEEE;\n"); fprintf(fp_out, " use IEEE.std_logic_1164.all;\n"); fprintf(fp_out, " use IEEE.std_logic_arith.all;\n"); fprintf(fp_out, "library unisim;\n"); fprintf(fp_out, " use unisim.vcomponents.all;\n"); fprintf(fp_out, "\n"); fprintf(fp_out, "entity %s is\n", entity_name); fprintf(fp_out, " port(\n"); fprintf(fp_out, " clk : in std_logic;\n"); fprintf(fp_out, " rst : in std_logic;\n"); fprintf(fp_out, " cs : in std_logic;\n"); fprintf(fp_out, " rw : in std_logic;\n"); fprintf(fp_out, " addr : in std_logic_vector(%d downto 0);\n", addr_len); fprintf(fp_out, " data_out : out std_logic_vector(7 downto 0);\n"); fprintf(fp_out, " data_in : in std_logic_vector(7 downto 0)\n"); fprintf(fp_out, " );\n"); fprintf(fp_out, "end %s;\n", entity_name); fprintf(fp_out, "\n"); fprintf(fp_out, "architecture rtl of %s is\n", entity_name); fprintf(fp_out, "\n"); fprintf(fp_out, " type data_array is array(0 to %d) of std_logic_vector(7 downto 0);\n",rom_max-1); fprintf(fp_out, " signal xdata : data_array;\n"); fprintf(fp_out, " signal en : std_logic_vector(%d downto 0);\n", rom_max-1); fprintf(fp_out, " signal we : std_logic;\n"); fprintf(fp_out, "\n"); fprintf(fp_out," begin\n"); fprintf(fp_out, "\n"); addr=start_addr; for( rom_num=0; rom_num<rom_max; rom_num++) { fprintf(fp_out, " ROM%02x: RAMB4_S8\n", rom_num ); fprintf(fp_out, " generic map (\n"); for( j=0; j<16; j++ ) { fprintf( fp_out, " INIT_%02x => x\"", j ); for(i=31; i>=0; i-- ) { byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX]; putc( hex_str[(byte >>4) & 0xf], fp_out ); putc( hex_str[byte & 0xf], fp_out ); } if (j < 15) { fprintf( fp_out, "\",\n" ); } else { fprintf( fp_out, "\"\n" ); } addr+=32; } fprintf(fp_out, " )\n"); fprintf(fp_out, " port map (\n"); fprintf(fp_out, " clk => clk,\n"); fprintf(fp_out, " en => en(%d),\n", rom_num ); fprintf(fp_out, " we => we,\n"); fprintf(fp_out, " rst => rst,\n"); fprintf(fp_out, " addr => addr(8 downto 0),\n"); fprintf(fp_out, " di => data_in,\n"); fprintf(fp_out, " do => xdata(%d)\n", rom_num ); fprintf(fp_out, " );\n"); fprintf(fp_out, "\n"); } fprintf(fp_out, " rom_glue: process (cs, rw, addr, xdata)\n"); fprintf(fp_out, " begin\n"); if( addr_len > rom_len ) { fprintf(fp_out, " en <= (others=>'0');\n"); fprintf(fp_out, " case addr(%d downto %d) is\n", addr_len, rom_len+1 ); for( rom_num=0; rom_num<rom_max; rom_num++ ) { fprintf(fp_out, " when \"%s\" =>\n", bin_string(rom_num, addr_len-rom_len) ); fprintf(fp_out, " en(%d) <= cs;\n", rom_num ); fprintf(fp_out, " data_out <= xdata(%d);\n", rom_num); } fprintf(fp_out, " when others =>\n"); fprintf(fp_out, " null;\n"); fprintf(fp_out, " end case;\n"); } else { fprintf(fp_out, " en(0) <= cs;\n" ); fprintf(fp_out, " data_out <= xdata(0);\n" ); } fprintf(fp_out, " we <= not rw;\n"); fprintf(fp_out, " end process;\n"); fprintf(fp_out, "end architecture rtl;\n\n"); } /* * save VHDL hexadecimal file 16 KBit Block RAM (Spartan 3) */ void save_vhdl_b16( FILE *fp_out, char *entity_name, int start_addr, int end_addr ) { int addr; int i,j; int byte; int rom_num, rom_max, rom_len; int addr_len; rom_max = (end_addr+1-start_addr)/2048; rom_len = 10; addr_len = (int)(log((double)(end_addr-start_addr))/log(2.0)); fprintf(fp_out, "library IEEE;\n"); fprintf(fp_out, " use IEEE.std_logic_1164.all;\n"); fprintf(fp_out, " use IEEE.std_logic_arith.all;\n"); fprintf(fp_out, "library unisim;\n"); fprintf(fp_out, " use unisim.vcomponents.all;\n"); fprintf(fp_out, "\n"); fprintf(fp_out, "entity %s is\n", entity_name); fprintf(fp_out, " port(\n"); fprintf(fp_out, " clk : in std_logic;\n"); fprintf(fp_out, " rst : in std_logic;\n"); fprintf(fp_out, " cs : in std_logic;\n"); fprintf(fp_out, " rw : in std_logic;\n"); fprintf(fp_out, " addr : in std_logic_vector(%d downto 0);\n", addr_len); fprintf(fp_out, " data_out : out std_logic_vector(7 downto 0);\n"); fprintf(fp_out, " data_in : in std_logic_vector(7 downto 0)\n"); fprintf(fp_out, " );\n"); fprintf(fp_out, "end %s;\n", entity_name); fprintf(fp_out, "\n"); fprintf(fp_out, "architecture rtl of %s is\n", entity_name); fprintf(fp_out, "\n"); fprintf(fp_out, " type data_array is array(0 to %d) of std_logic_vector(7 downto 0);\n",rom_max-1); fprintf(fp_out, " signal xdata : data_array;\n"); fprintf(fp_out, " signal en : std_logic_vector(%d downto 0);\n", rom_max-1); fprintf(fp_out, " signal dp : std_logic_vector(%d downto 0);\n", rom_max-1); fprintf(fp_out, " signal we : std_logic;\n"); fprintf(fp_out, "\n"); fprintf(fp_out, " begin\n"); fprintf(fp_out, "\n"); addr=start_addr; for( rom_num=0; rom_num<rom_max; rom_num++) { fprintf(fp_out, " ROM%02x: RAMB16_S9\n", rom_num ); fprintf(fp_out, " generic map (\n"); for( j=0; j<64; j++ ) { fprintf( fp_out, " INIT_%02x => x\"", j ); for(i=31; i>=0; i-- ) { byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX]; putc( hex_str[(byte >>4) & 0xf], fp_out ); putc( hex_str[byte & 0xf], fp_out ); } if (j < 63) { fprintf( fp_out, "\",\n" ); } else { fprintf( fp_out, "\"\n" ); } addr+=32; } fprintf(fp_out, " )\n"); fprintf(fp_out, " port map (\n"); fprintf(fp_out, " CLK => clk,\n"); fprintf(fp_out, " SSR => rst,\n"); fprintf(fp_out, " EN => en(%d),\n", rom_num ); fprintf(fp_out, " WE => we,\n"); fprintf(fp_out, " ADDR => addr(10 downto 0),\n"); fprintf(fp_out, " DI => data_in,\n"); fprintf(fp_out, " DIP(0) => dp(%d),\n", rom_num ); fprintf(fp_out, " DO => xdata(%d),\n", rom_num ); fprintf(fp_out, " DOP(0) => dp(%d)\n", rom_num ); fprintf(fp_out, " );\n"); } fprintf(fp_out, " rom_glue: process (cs, rw, addr, xdata)\n"); fprintf(fp_out, " begin\n"); if( addr_len > rom_len ) { fprintf(fp_out, " en <= (others=>'0');\n"); fprintf(fp_out, " case addr(%d downto %d) is\n", addr_len, rom_len+1 ); for( rom_num=0; rom_num<rom_max; rom_num++ ) { fprintf(fp_out, " when \"%s\" =>\n", bin_string(rom_num, addr_len-rom_len) ); fprintf(fp_out, " en(%d) <= cs;\n", rom_num ); fprintf(fp_out, " data_out <= xdata(%d);\n", rom_num); } fprintf(fp_out, " when others =>\n"); fprintf(fp_out, " null;\n"); fprintf(fp_out, " end case;\n"); } else { fprintf(fp_out, " en(0) <= cs;\n"); fprintf(fp_out, " data_out <= xdata(0);\n"); } fprintf(fp_out, " we <= not rw;\n"); fprintf(fp_out, " end process;\n"); fprintf(fp_out, "end architecture rtl;\n\n"); } /* * epedit main program */ int main(int argc, char* argv[]) { int start_addr; int end_addr; int arglen; char entity_name_buf[512]; char hdl_file_buf[1024]; char buf[1024]; char *curpos; FILE *fp_out; if (argc < 5) { printf("Usage: s19tovhd <bram_type> <s19 file> <base vhd file> <vhdl base entity name> <addr> [<addr> ...]\n"); return(-1); } int bram_type_arg_pos = 1; int s19_file_arg_pos = 2; int base_vhdl_file_arg_pos = 3; int entity_name_arg_pos = 4; int first_addr_arg_pos = 5; char *bram_type = argv[bram_type_arg_pos]; char *s19_file = argv[s19_file_arg_pos]; char *base_vhd_file = argv[base_vhdl_file_arg_pos]; char *entity_name = argv[entity_name_arg_pos]; printf("Block-RAM type '%s'\n", bram_type); printf("Reading Motorola S19 from file '%s'\n", s19_file); printf("VHDL file name '%s'\n", base_vhd_file); printf("Base RAM/ROM entity name is '%s'\n", entity_name); if (! load_mot( s19_file )) return (-1); if (strcmp(bram_type,"b16") == 0) { if( (fp_out = fopen( base_vhd_file, "w" )) == NULL ) { printf( "\nCan't open '%s' for write ", base_vhd_file ); return(-1); } for (int cnt=first_addr_arg_pos; cnt<argc; cnt++) { if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) { printf("Expected hex start address, got %s\n", argv[cnt]); continue; } end_addr = start_addr + 2047; sprintf(entity_name_buf, "%s_%4X", entity_name, start_addr); printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n", entity_name_buf, start_addr, end_addr, base_vhd_file); save_vhdl_b16( fp_out, entity_name_buf, start_addr, end_addr ); } if (fp_out) fclose(fp_out); } if (strcmp(bram_type,"b4") == 0) { if( (fp_out = fopen( base_vhd_file, "w" )) == NULL ) { printf( "\nCan't open '%s' for write ", base_vhd_file ); return(-1); } for (int cnt=first_addr_arg_pos; cnt<argc; cnt++) { if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) { printf("Expected hex start address, got %s\n", argv[cnt]); continue; } end_addr = start_addr + 2047; sprintf(entity_name_buf, "%s_%4X", entity_name, start_addr); printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n", entity_name_buf, start_addr, end_addr, base_vhd_file); save_vhdl_b4( fp_out, entity_name_buf, start_addr, end_addr ); } if (fp_out) fclose(fp_out); } return(0); }
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