OpenCores

Rev 78	Rev 90
Line 7...	Line 7...
`* binary file editer program`	`* binary file editer program`
`*/`	`*/`
`#include <stdio.h>`	`#include <stdio.h>`
`#include <string.h>`	`#include <string.h>`
`#include <ctype.h>`	`#include <ctype.h>`
	`#include <math.h>`

`/*`	`/*`
`* equates`	`* equates`
`*/`	`*/`
`#define EPROM_MAX (1<<16)`	`#define EPROM_MAX (1<<16)`
`#define CMD_LINE_MAX 80`	`#define CMD_LINE_MAX 80`
Line 46...	Line 48...
`* return FALSE if no match`	`* return FALSE if no match`
`* ignore case`	`* ignore case`
`*/`	`*/`
`int str_equal( char s1, char s2, int len )`	`int str_equal( char s1, char s2, int len )`
`{`	`{`
`int i;`	`int i = 0;`
	`while( i<len ) {`
`i = 0;`
`while( i<len )`
`{`
`if( toupper( s1[i] ) == toupper( s2[i] ) )`	`if( toupper( s1[i] ) == toupper( s2[i] ) )`
`i++;`	`i++;`
`else return FALSE;`	`else`
	`return FALSE;`
`}`	`}`
`return TRUE;`	`return TRUE;`
`}`	`}`


`int to_hexadecimal( char c )`	`int to_hexadecimal( char c )`
`{`	`{`
`int k;`	`for( int k=0; k<16; k++ ) {`
	`if( toupper(c) == hex_str[k] ) return k;`
`for( k=0; k<16; k++ )`
`{`
`if( toupper(c) == hex_str[k] )`
`return k;`
`}`	`}`
`return -1;`	`return -1;`
`}`	`}`

`/*`	`/*`
Line 79...	Line 74...
`*/`	`*/`
`int get_address( char cb, int addr )`	`int get_address( char cb, int addr )`
`{`	`{`
`int i, j, k;`	`int i, j, k;`

`j = 0;`	`j = i = 0;`
`i = 0;`

`while((k = to_hexadecimal(cb[i])) != -1)`	`while((k = to_hexadecimal(cb[i])) != -1) {`
`{`
`i++;`	`i++;`
`j = j *16 + k;`	`j = j *16 + k;`
`}`	`}`
`*addr = j;`	`*addr = j;`
`if( i == 0 )`	`if( i == 0 ) return i;`
`return i;`	`while( isspace( cb[i]) ) i++;`
`while( isspace( cb[i]) )`
`i++;`
`return i;`	`return i;`
`}`	`}`


`/*`	`/*`
`* Motorola S1 format to Intel hex format`	`* Motorola S1 format to Intel hex format`
`* Usage`	`* Usage`
`* mot2hex <file_name>`	`* mot2hex <file_name>`
`*/`	`*/`
Line 184...	Line 174...
`}`	`}`
`}`	`}`
`return -1;`	`return -1;`
`}`	`}`




`/*`	`/*`
`* load motorola formatted file`	`* load motorola formatted file`
`*/`	`*/`

`bool load_mot( char *fname_in )`	`bool load_mot( char *fname_in )`
`{`	`{`
`FILE *fp_in;`	`FILE *fp_in;`
`int byte, addr, i;`	`int byte, addr, i;`

`fp_in = fopen( fname_in, "r" );`	`fp_in = fopen( fname_in, "r" );`
`if( !fp_in )`	`if ( !fp_in ) {`
`{`
`printf( "\nCan't open %s", fname_in );`	`printf( "\nCan't open %s", fname_in );`
`return false;`	`return false;`
`}`	`}`

`byte = 0;`	`byte = 0;`
`addr = 0;`	`addr = 0;`

`while( byte != -1 )`	`while( byte != -1 ) {`
`{`
`do {`	`do {`
`byte = fgetc( fp_in);`	`byte = fgetc( fp_in);`
`} while( (byte != 'S') && (byte != -1) );`	`} while( (byte != 'S') && (byte != -1) );`

`byte = fgetc( fp_in );`	`byte = fgetc( fp_in );`
`checksum = 0;`	`checksum = 0;`
`if( (byte == '1') \|\| (byte == '2') )`	`if ( (byte == '1') \|\| (byte == '2') ) {`
`{`
`count = get2hex( fp_in );`	`count = get2hex( fp_in );`
`if( byte == '1' )`	`if ( byte == '1' ) {`
`{`
`addr = get4hex( fp_in );`	`addr = get4hex( fp_in );`
`count -= 3;`	`count -= 3;`
`}`	`} else {`
`else`
`{`
`addr = get6hex( fp_in );`	`addr = get6hex( fp_in );`
`count -= 4;`	`count -= 4;`
`}`	`}`
`for( i=0; i<count; i++ )`	`for( i=0; i<count; i++ ) {`
`{`
`byte = get2hex( fp_in );`	`byte = get2hex( fp_in );`
`eprom_buff[( addr - offset) % EPROM_MAX ] = (unsigned char)byte;`	`eprom_buff[( addr - offset) % EPROM_MAX ] = (unsigned char)byte;`
`addr++;`	`addr++;`
`}`	`}`
`byte = get2hex( fp_in);`	`byte = get2hex( fp_in);`
Line 243...	Line 223...
`}`	`}`
`fclose( fp_in );`	`fclose( fp_in );`
`return true;`	`return true;`
`}`	`}`




`int put2hex( FILE *fp, int h )`	`int put2hex( FILE *fp, int h )`
`{`	`{`
`int i, hex;`	`int hex = (h & 0xf0)>>4;`
	`int i = fputc( (int)hex_str[hex], fp );`
`hex = (h & 0xf0)>>4;`
`i = fputc( (int)hex_str[hex], fp );`
`hex = (h & 0xf);`	`hex = (h & 0xf);`
`i = fputc( (int)hex_str[hex], fp );`	`i = fputc( (int)hex_str[hex], fp );`
`checksum = (checksum + h) & 0xff;`	`checksum = (checksum + h) & 0xff;`
`return i;`	`return i;`
`}`	`}`

`int put4hex( FILE * fp, int h )`	`int put4hex( FILE * fp, int h )`
`{`	`{`
`int i;`	`int i = put2hex( fp, (h & 0xff00 )>>8 );`

`i = put2hex( fp, (h & 0xff00 )>>8 );`
`i = put2hex( fp, (h & 0xff) );`	`i = put2hex( fp, (h & 0xff) );`
`return i;`	`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`	`* save VHDL hexadecimal file 4KBit Block RAM (Spartan 2)`
`*/`	`*/`

`void save_vhdl_byte( FILE fp_out, char entity_name, int start_addr, int end_addr )`	`void save_vhdl_b4( FILE fp_out, char entity_name, int start_addr, int end_addr )`
`{`	`{`
`int addr;`	`int addr;`
`int i,j;`	`int i,j;`
`int byte;`	`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));`

`j=0;`
`fprintf(fp_out, "library IEEE;\n");`	`fprintf(fp_out, "library IEEE;\n");`
`fprintf(fp_out, " use IEEE.std_logic_1164.all;\n");`	`fprintf(fp_out, " use IEEE.std_logic_1164.all;\n");`
`fprintf(fp_out, " use IEEE.std_logic_arith.all;\n");`	`fprintf(fp_out, " use IEEE.std_logic_arith.all;\n");`
`fprintf(fp_out, "library unisim;\n");`	`fprintf(fp_out, "library unisim;\n");`
`fprintf(fp_out, " use unisim.vcomponents.all;\n");`	`fprintf(fp_out, " use unisim.vcomponents.all;\n");`
Line 291...	Line 283...
`fprintf(fp_out, " port(\n");`	`fprintf(fp_out, " port(\n");`
`fprintf(fp_out, " clk : in std_logic;\n");`	`fprintf(fp_out, " clk : in std_logic;\n");`
`fprintf(fp_out, " rst : in std_logic;\n");`	`fprintf(fp_out, " rst : in std_logic;\n");`
`fprintf(fp_out, " cs : in std_logic;\n");`	`fprintf(fp_out, " cs : in std_logic;\n");`
`fprintf(fp_out, " rw : in std_logic;\n");`	`fprintf(fp_out, " rw : in std_logic;\n");`
`fprintf(fp_out, " addr : in std_logic_vector(10 downto 0);\n");`	`fprintf(fp_out, " addr : in std_logic_vector(%d downto 0);\n", addr_len);`
`fprintf(fp_out, " rdata : out std_logic_vector(7 downto 0);\n");`	`fprintf(fp_out, " rdata : out std_logic_vector(7 downto 0);\n");`
`fprintf(fp_out, " wdata : in std_logic_vector(7 downto 0)\n");`	`fprintf(fp_out, " wdata : in std_logic_vector(7 downto 0)\n");`
`fprintf(fp_out, " );\n");`	`fprintf(fp_out, " );\n");`
`fprintf(fp_out, "end %s;\n", entity_name);`	`fprintf(fp_out, "end %s;\n", entity_name);`
`fprintf(fp_out, "\n");`	`fprintf(fp_out, "\n");`
`fprintf(fp_out, "architecture rtl of %s is\n", entity_name);`	`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, " signal we : std_logic;\n");`
`fprintf(fp_out, " signal dp : std_logic;\n");`	`fprintf(fp_out, "\n");`
`fprintf(fp_out, "begin\n");`	`fprintf(fp_out, "begin\n");`
`fprintf(fp_out, " ROM: RAMB16_S9\n");`	`fprintf(fp_out, "\n");`
`fprintf(fp_out, " generic map (\n");`

`for( addr=start_addr; addr<=end_addr; addr+=32 )`	`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 );`	`fprintf( fp_out, " INIT_%02x => x\"", j );`
`for(i=31; i>=0; i-- )`	`for(i=31; i>=0; i-- ) {`
`{`
`byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX];`	`byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX];`
`putc( hex_str[(byte >>4) & 0xf], fp_out );`	`putc( hex_str[(byte >>4) & 0xf], fp_out );`
`putc( hex_str[byte & 0xf], fp_out );`	`putc( hex_str[byte & 0xf], fp_out );`
`}`	`}`
`if (addr+32 < end_addr) {`	`if (j < 15) {`
`fprintf( fp_out, "\",\n" );`	`fprintf( fp_out, "\",\n" );`
`} else {`	`} else {`
`fprintf( fp_out, "\"\n" );`	`fprintf( fp_out, "\"\n" );`
`}`	`}`
`j++;`	`addr+=32;`
`}`	`}`
`fprintf(fp_out, " )\n");`	`fprintf(fp_out, " )\n");`
`fprintf(fp_out, " port map (\n");`	`fprintf(fp_out, " port map (\n");`
`fprintf(fp_out, " do => rdata,\n");`
`fprintf(fp_out, " dop(0) => dp,\n");`
`fprintf(fp_out, " addr => addr,\n");`
`fprintf(fp_out, " clk => clk,\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 => wdata,\n");`	`fprintf(fp_out, " di => wdata,\n");`
`fprintf(fp_out, " dip(0) => dp,\n");`	`fprintf(fp_out, " do => xdata(%d)\n", rom_num );`
`fprintf(fp_out, " en => cs,\n");`
`fprintf(fp_out, " ssr => rst,\n");`
`fprintf(fp_out, " we => we\n");`
`fprintf(fp_out, " );\n");`	`fprintf(fp_out, " );\n");`
`fprintf(fp_out, " drive_we: process (rw)\n");`	`fprintf(fp_out, "\n");`
	`}`

	`fprintf(fp_out, " rom_glue: process (cs, rw, addr, xdata)\n");`
`fprintf(fp_out, " begin\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, " rdata <= 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, " rdata <= xdata(0);\n" );`
	`}`
`fprintf(fp_out, " we <= not rw;\n");`	`fprintf(fp_out, " we <= not rw;\n");`
`fprintf(fp_out, " end process;\n");`	`fprintf(fp_out, " end process;\n");`
`fprintf(fp_out, "end architecture rtl;\n\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, " rdata : out std_logic_vector(7 downto 0);\n");`
	`fprintf(fp_out, " wdata : 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 => wdata,\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, " rdata <= 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, " rdata <= 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`	`* epedit main program`
`*/`	`*/`
`int main(int argc, char* argv[])`	`int main(int argc, char* argv[])`
Line 357...	Line 470...
`char hdl_file_buf[1024];`	`char hdl_file_buf[1024];`
`char buf[1024];`	`char buf[1024];`
`char *curpos;`	`char *curpos;`
`FILE *fp_out;`	`FILE *fp_out;`

`if (argc < 5) {`	`if (argc < 5)`
`printf("Usage: s19tovhd <s19 file> <base vhd file> <vhdl base entity name> <addr> [<addr> ...]\n");`	`{`
	`printf("Usage: s19tovhd <bram_type> <s19 file> <base vhd file> <vhdl base entity name> <addr> [<addr> ...]\n");`
`return(-1);`	`return(-1);`
`}`	`}`
`printf("Reading Motorola S19 from file '%s'\n", argv[1]);`	`int bram_type_arg_pos = 1;`
`printf("VHDL file name '%s'\n", argv[2]);`	`int s19_file_arg_pos = 2;`
`printf("Base RAM/ROM entity name is '%s'\n", argv[3]);`	`int base_vhdl_file_arg_pos = 3;`
`if (!load_mot( argv[1] )) {`	`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);`	`return(-1);`
`}`	`}`
`if( (fp_out = fopen( argv[2], "w" )) == NULL ) {`
`printf( "\nCan't open '%s' for write ", argv[2] );`	`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);`	`return(-1);`
`}`	`}`

`for (int cnt=4; cnt<argc; cnt++) {`	`for (int cnt=first_addr_arg_pos; cnt<argc; cnt++) {`
`if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) {`	`if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) {`
`printf("Expected hex start address, got %s\n", argv[cnt]);`	`printf("Expected hex start address, got %s\n", argv[cnt]);`
`continue;`	`continue;`
`}`	`}`
`end_addr = start_addr + 2047;`	`end_addr = start_addr + 2047;`
`sprintf(entity_name_buf, "%s_%4X", argv[3], start_addr);`	`sprintf(entity_name_buf, "%s_%4X", entity_name, start_addr);`

`printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n",`	`printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n",`
`entity_name_buf, start_addr, end_addr, argv[2]);`	`entity_name_buf, start_addr, end_addr, base_vhd_file);`
`save_vhdl_byte( fp_out, entity_name_buf, start_addr, end_addr );`	`save_vhdl_b4( fp_out, entity_name_buf, start_addr, end_addr );`
`}`	`}`
`if (fp_out) fclose(fp_out);`	`if (fp_out) fclose(fp_out);`
	`}`
`return(0);`	`return(0);`
`}`	`}`


`No newline at end of file`	`No newline at end of file`

Line 7...

* binary file editer program

* binary file editer program

*/

*/

#include <stdio.h>

#include <stdio.h>

#include <string.h>

#include <string.h>

#include <ctype.h>

#include <ctype.h>

#include <math.h>

/*

/*

* equates

* equates

*/

*/

#define EPROM_MAX (1<<16)

#define EPROM_MAX (1<<16)

#define CMD_LINE_MAX 80

#define CMD_LINE_MAX 80

Line 46...

Line 48...

* return FALSE if no match

* return FALSE if no match

* ignore case

* ignore case

*/

*/

int str_equal( char *s1, char *s2, int len )

int str_equal( char *s1, char *s2, int len )

        int i;

        int i = 0;

        while( i<len ) {

        i = 0;

        while( i<len )

                if( toupper( s1[i] ) == toupper( s2[i] ) )

                if( toupper( s1[i] ) == toupper( s2[i] ) )

                        i++;

                        i++;

                else return FALSE;

                else

                        return FALSE;

        return TRUE;

        return TRUE;

int to_hexadecimal( char c )

int to_hexadecimal( char c )

        int k;

        for( int k=0; k<16; k++ ) {

                if( toupper(c) == hex_str[k] ) return k;

        for( k=0; k<16; k++ )

                if( toupper(c) == hex_str[k] )

                        return k;

        return -1;

        return -1;

/*

/*

Line 79...

Line 74...

*/

*/

int get_address( char *cb, int *addr )

int get_address( char *cb, int *addr )

        int i, j, k;

        int i, j, k;

        j = 0;

        j = i = 0;

        i = 0;

        while((k = to_hexadecimal(cb[i])) != -1)

        while((k = to_hexadecimal(cb[i])) != -1) {

                i++;

                i++;

                j = j *16 + k;

                j = j *16 + k;

        *addr = j;

        *addr = j;

        if( i == 0 )

        if( i == 0 ) return i;

                return i;

        while( isspace( cb[i]) ) i++;

        while( isspace( cb[i]) )

                i++;

        return i;

        return i;

/*

/*

* Motorola S1 format to Intel hex format

* Motorola S1 format to Intel hex format

* Usage

* Usage

* mot2hex <file_name>

* mot2hex <file_name>

*/

*/

Line 184...

Line 174...

        return -1;

        return -1;

/*

/*

* load motorola formatted file

* load motorola formatted file

*/

*/

bool load_mot( char *fname_in )

bool load_mot( char *fname_in )

        FILE *fp_in;

        FILE *fp_in;

        int byte, addr, i;

        int byte, addr, i;

        fp_in = fopen( fname_in, "r" );

        fp_in = fopen( fname_in, "r" );

        if( !fp_in )

        if ( !fp_in ) {

                printf( "\nCan't open %s", fname_in );

                printf( "\nCan't open %s", fname_in );

                return false;

                return false;

        byte = 0;

        byte = 0;

        addr = 0;

        addr = 0;

        while( byte != -1 )

        while( byte != -1 ) {

                do {

                do {

                        byte = fgetc( fp_in);

                        byte = fgetc( fp_in);

                } while( (byte != 'S') && (byte != -1) );

                } while( (byte != 'S') && (byte != -1) );

                byte = fgetc( fp_in );

                byte = fgetc( fp_in );

                checksum = 0;

                checksum = 0;

                if( (byte == '1') || (byte == '2') )

                if ( (byte == '1') || (byte == '2') ) {

                        count = get2hex( fp_in );

                        count = get2hex( fp_in );

                        if( byte == '1' )

                        if ( byte == '1' ) {

                                addr = get4hex( fp_in );

                                addr = get4hex( fp_in );

                                count -= 3;

                                count -= 3;

                        } else {

                        else

                                addr = get6hex( fp_in );

                                addr = get6hex( fp_in );

                                count -= 4;

                                count -= 4;

                        for( i=0; i<count; i++ )

                        for( i=0; i<count; i++ ) {

                                byte = get2hex( fp_in );

                                byte = get2hex( fp_in );

                                eprom_buff[( addr - offset) % EPROM_MAX ] = (unsigned char)byte;

                                eprom_buff[( addr - offset) % EPROM_MAX ] = (unsigned char)byte;

                                addr++;

                                addr++;

                        byte = get2hex( fp_in);

                        byte = get2hex( fp_in);

Line 243...

Line 223...

        fclose( fp_in );

        fclose( fp_in );

        return true;

        return true;

int put2hex( FILE *fp, int h )

int put2hex( FILE *fp, int h )

        int i, hex;

        int hex = (h & 0xf0)>>4;

        int i = fputc( (int)hex_str[hex], fp );

        hex = (h & 0xf0)>>4;

        i = fputc( (int)hex_str[hex], fp );

        hex = (h & 0xf);

        hex = (h & 0xf);

        i = fputc( (int)hex_str[hex], fp );

        i = fputc( (int)hex_str[hex], fp );

        checksum = (checksum + h) & 0xff;

        checksum = (checksum + h) & 0xff;

        return i;

        return i;

int put4hex( FILE * fp, int h )

int put4hex( FILE * fp, int h )

        int i;

        int i = put2hex( fp, (h & 0xff00 )>>8 );

        i = put2hex( fp, (h & 0xff00 )>>8 );

        i = put2hex( fp, (h & 0xff) );

        i = put2hex( fp, (h & 0xff) );

        return i;

        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

* save VHDL hexadecimal file 4KBit Block RAM (Spartan 2)

*/

*/

void save_vhdl_byte( FILE *fp_out, char *entity_name, int start_addr, int end_addr )

void save_vhdl_b4( FILE *fp_out, char *entity_name, int start_addr, int end_addr )

        int addr;

        int addr;

        int i,j;

        int i,j;

        int byte;

        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));

        j=0;

        fprintf(fp_out, "library IEEE;\n");

        fprintf(fp_out, "library IEEE;\n");

        fprintf(fp_out, "   use IEEE.std_logic_1164.all;\n");

        fprintf(fp_out, "   use IEEE.std_logic_1164.all;\n");

        fprintf(fp_out, "   use IEEE.std_logic_arith.all;\n");

        fprintf(fp_out, "   use IEEE.std_logic_arith.all;\n");

        fprintf(fp_out, "library unisim;\n");

        fprintf(fp_out, "library unisim;\n");

        fprintf(fp_out, "   use unisim.vcomponents.all;\n");

        fprintf(fp_out, "   use unisim.vcomponents.all;\n");

Line 291...

Line 283...

        fprintf(fp_out, "   port(\n");

        fprintf(fp_out, "   port(\n");

        fprintf(fp_out, "      clk    : in  std_logic;\n");

        fprintf(fp_out, "      clk    : in  std_logic;\n");

        fprintf(fp_out, "      rst    : in  std_logic;\n");

        fprintf(fp_out, "      rst    : in  std_logic;\n");

        fprintf(fp_out, "      cs     : in  std_logic;\n");

        fprintf(fp_out, "      cs     : in  std_logic;\n");

        fprintf(fp_out, "      rw     : in  std_logic;\n");

        fprintf(fp_out, "      rw     : in  std_logic;\n");

        fprintf(fp_out, "      addr   : in  std_logic_vector(10 downto 0);\n");

        fprintf(fp_out, "      addr   : in  std_logic_vector(%d downto 0);\n", addr_len);

        fprintf(fp_out, "      rdata  : out std_logic_vector(7 downto 0);\n");

        fprintf(fp_out, "      rdata  : out std_logic_vector(7 downto 0);\n");

        fprintf(fp_out, "      wdata  : in  std_logic_vector(7 downto 0)\n");

        fprintf(fp_out, "      wdata  : in  std_logic_vector(7 downto 0)\n");

        fprintf(fp_out, "   );\n");

        fprintf(fp_out, "   );\n");

        fprintf(fp_out, "end %s;\n", entity_name);

        fprintf(fp_out, "end %s;\n", entity_name);

        fprintf(fp_out, "\n");

        fprintf(fp_out, "\n");

        fprintf(fp_out, "architecture rtl of %s is\n", entity_name);

        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, "   signal we : std_logic;\n");

        fprintf(fp_out, "   signal dp : std_logic;\n");

        fprintf(fp_out, "\n");

        fprintf(fp_out, "begin\n");

        fprintf(fp_out, "begin\n");

        fprintf(fp_out, "   ROM: RAMB16_S9\n");

        fprintf(fp_out, "\n");

        fprintf(fp_out, "      generic map (\n");

        for( addr=start_addr; addr<=end_addr; addr+=32 )

        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 );

                fprintf( fp_out, "         INIT_%02x => x\"", j );

                for(i=31; i>=0; i-- )

                        for(i=31; i>=0; i-- ) {

                        byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX];

                        byte = (int)eprom_buff[(addr - offset + i) % EPROM_MAX];

                        putc( hex_str[(byte >>4) & 0xf], fp_out );

                        putc( hex_str[(byte >>4) & 0xf], fp_out );

                        putc( hex_str[byte & 0xf], fp_out );

                        putc( hex_str[byte & 0xf], fp_out );

                if (addr+32 < end_addr) {

                        if (j < 15) {

                        fprintf( fp_out, "\",\n" );

                        fprintf( fp_out, "\",\n" );

                } else {

                } else {

                        fprintf( fp_out, "\"\n" );

                        fprintf( fp_out, "\"\n" );

                j++;

                        addr+=32;

        fprintf(fp_out, "      )\n");

        fprintf(fp_out, "      )\n");

        fprintf(fp_out, "      port map (\n");

        fprintf(fp_out, "      port map (\n");

        fprintf(fp_out, "         do    => rdata,\n");

        fprintf(fp_out, "         dop(0)  => dp,\n");

        fprintf(fp_out, "         addr    => addr,\n");

        fprintf(fp_out, "         clk     => clk,\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      => wdata,\n");

        fprintf(fp_out, "         di      => wdata,\n");

        fprintf(fp_out, "         dip(0)  => dp,\n");

                fprintf(fp_out, "         do      => xdata(%d)\n", rom_num );

        fprintf(fp_out, "         en      => cs,\n");

        fprintf(fp_out, "         ssr     => rst,\n");

        fprintf(fp_out, "         we      => we\n");

        fprintf(fp_out, "      );\n");

        fprintf(fp_out, "      );\n");

        fprintf(fp_out, "   drive_we: process (rw)\n");

                fprintf(fp_out, "\n");

        fprintf(fp_out, "   rom_glue: process (cs, rw, addr, xdata)\n");

        fprintf(fp_out, "   begin\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, "         rdata  <= 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, "      rdata  <= xdata(0);\n" );

        fprintf(fp_out, "      we <= not rw;\n");

        fprintf(fp_out, "      we <= not rw;\n");

        fprintf(fp_out, "   end process;\n");

        fprintf(fp_out, "   end process;\n");

        fprintf(fp_out, "end architecture rtl;\n\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, "      rdata  : out std_logic_vector(7 downto 0);\n");

        fprintf(fp_out, "      wdata  : 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      => wdata,\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, "         rdata  <= 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, "      rdata  <= 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

* epedit main program

*/

*/

int main(int argc, char* argv[])

int main(int argc, char* argv[])

Line 357...

Line 470...

        char hdl_file_buf[1024];

        char hdl_file_buf[1024];

        char buf[1024];

        char buf[1024];

        char *curpos;

        char *curpos;

        FILE *fp_out;

        FILE *fp_out;

        if (argc < 5) {

        if (argc < 5)

                printf("Usage: s19tovhd <s19 file> <base vhd file> <vhdl base entity name> <addr> [<addr> ...]\n");

                printf("Usage: s19tovhd <bram_type> <s19 file> <base vhd file> <vhdl base entity name> <addr> [<addr> ...]\n");

                return(-1);

                return(-1);

        printf("Reading Motorola S19 from file '%s'\n", argv[1]);

        int bram_type_arg_pos = 1;

        printf("VHDL file name '%s'\n", argv[2]);

        int s19_file_arg_pos = 2;

        printf("Base RAM/ROM entity name is '%s'\n", argv[3]);

        int base_vhdl_file_arg_pos = 3;

        if (!load_mot( argv[1] )) {

        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);

                return(-1);

        if( (fp_out = fopen( argv[2], "w" )) == NULL ) {

                printf( "\nCan't open '%s' for write ", argv[2] );

                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);

                return(-1);

        for (int cnt=4; cnt<argc; cnt++) {

                for (int cnt=first_addr_arg_pos; cnt<argc; cnt++) {

                if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) {

                if( (arglen = get_address( argv[cnt], &start_addr )) == 0 ) {

                        printf("Expected hex start address, got %s\n", argv[cnt]);

                        printf("Expected hex start address, got %s\n", argv[cnt]);

                        continue;

                        continue;

                end_addr = start_addr + 2047;

                end_addr = start_addr + 2047;

                sprintf(entity_name_buf, "%s_%4X", argv[3], start_addr);

                        sprintf(entity_name_buf, "%s_%4X", entity_name, start_addr);

                printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n",

                printf("Entity '%s' (address range '0x%4X'-'0x%4X') written to file '%s'\n",

                        entity_name_buf, start_addr, end_addr, argv[2]);

                                entity_name_buf, start_addr, end_addr, base_vhd_file);

                save_vhdl_byte( fp_out, entity_name_buf, start_addr, end_addr );

                        save_vhdl_b4( fp_out, entity_name_buf, start_addr, end_addr );

        if (fp_out) fclose(fp_out);

        if (fp_out) fclose(fp_out);

        return(0);

        return(0);

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[/] [System09/] [trunk/] [Tools/] [s19tovhd/] [S19toVHD.cpp] - Diff between revs 78 and 90