#include #include #include #include #include #include #include #include #include #include #include #include "sdram.h" #include "dataflow.h" #include "boot.h" enum { CSR_IE = 1, CSR_IM, CSR_IP, CSR_ICC, CSR_DCC, CSR_CC, CSR_CFG, CSR_EBA, CSR_DC, CSR_DEBA, CSR_JTX, CSR_JRX, CSR_BP0, CSR_BP1, CSR_BP2, CSR_BP3, CSR_WP0, CSR_WP1, CSR_WP2, CSR_WP3, }; /* General address space functions */ #define NUMBER_OF_BYTES_ON_A_LINE 16 static void dump_bytes(unsigned int *ptr, int count, unsigned addr) { char *data = (char *)ptr; int line_bytes = 0, i = 0; putsnonl("Memory dump:"); while(count > 0){ line_bytes = (count > NUMBER_OF_BYTES_ON_A_LINE)? NUMBER_OF_BYTES_ON_A_LINE : count; printf("\n0x%08x ", addr); for(i=0;i 0x7e)) printf("."); else printf("%c", *(data+i)); } for(;i [length]\n"); return; } addr = (unsigned *)strtoul(startaddr, &c, 0); if(*c != 0) { printf("incorrect address\n"); return; } if(*len == 0) { length = 4; } else { length = strtoul(len, &c, 0); if(*c != 0) { printf("incorrect length\n"); return; } } dump_bytes(addr, length, (unsigned)addr); } static void mw(char *addr, char *value, char *count) { char *c; unsigned int *addr2; unsigned int value2; unsigned int count2; unsigned int i; if((*addr == 0) || (*value == 0)) { printf("mw
[count]\n"); return; } addr2 = (unsigned int *)strtoul(addr, &c, 0); if(*c != 0) { printf("incorrect address\n"); return; } value2 = strtoul(value, &c, 0); if(*c != 0) { printf("incorrect value\n"); return; } if(*count == 0) { count2 = 1; } else { count2 = strtoul(count, &c, 0); if(*c != 0) { printf("incorrect count\n"); return; } } for (i=0;i [count]\n"); return; } dstaddr2 = (unsigned int *)strtoul(dstaddr, &c, 0); if(*c != 0) { printf("incorrect destination address\n"); return; } srcaddr2 = (unsigned int *)strtoul(srcaddr, &c, 0); if(*c != 0) { printf("incorrect source address\n"); return; } if(*count == 0) { count2 = 1; } else { count2 = strtoul(count, &c, 0); if(*c != 0) { printf("incorrect count\n"); return; } } for (i=0;i \n"); return; } addr = (char *)strtoul(startaddr, &c, 0); if(*c != 0) { printf("incorrect address\n"); return; } length = strtoul(len, &c, 0); if(*c != 0) { printf("incorrect length\n"); return; } printf("CRC32: %08x\n", crc32((unsigned char *)addr, length)); } /* processor registers */ static int parse_csr(const char *csr) { if(!strcmp(csr, "ie")) return CSR_IE; if(!strcmp(csr, "im")) return CSR_IM; if(!strcmp(csr, "ip")) return CSR_IP; if(!strcmp(csr, "icc")) return CSR_ICC; if(!strcmp(csr, "dcc")) return CSR_DCC; if(!strcmp(csr, "cc")) return CSR_CC; if(!strcmp(csr, "cfg")) return CSR_CFG; if(!strcmp(csr, "eba")) return CSR_EBA; if(!strcmp(csr, "dc")) return CSR_DC; if(!strcmp(csr, "deba")) return CSR_DEBA; if(!strcmp(csr, "jtx")) return CSR_JTX; if(!strcmp(csr, "jrx")) return CSR_JRX; if(!strcmp(csr, "bp0")) return CSR_BP0; if(!strcmp(csr, "bp1")) return CSR_BP1; if(!strcmp(csr, "bp2")) return CSR_BP2; if(!strcmp(csr, "bp3")) return CSR_BP3; if(!strcmp(csr, "wp0")) return CSR_WP0; if(!strcmp(csr, "wp1")) return CSR_WP1; if(!strcmp(csr, "wp2")) return CSR_WP2; if(!strcmp(csr, "wp3")) return CSR_WP3; return 0; } static void rcsr(char *csr) { unsigned int csr2; register unsigned int value; if(*csr == 0) { printf("rcsr \n"); return; } csr2 = parse_csr(csr); if(csr2 == 0) { printf("incorrect csr\n"); return; } switch(csr2) { case CSR_IE: asm volatile ("rcsr %0,ie":"=r"(value)); break; case CSR_IM: asm volatile ("rcsr %0,im":"=r"(value)); break; case CSR_IP: asm volatile ("rcsr %0,ip":"=r"(value)); break; case CSR_CC: asm volatile ("rcsr %0,cc":"=r"(value)); break; case CSR_CFG: asm volatile ("rcsr %0,cfg":"=r"(value)); break; case CSR_EBA: asm volatile ("rcsr %0,eba":"=r"(value)); break; case CSR_DEBA: asm volatile ("rcsr %0,deba":"=r"(value)); break; case CSR_JTX: asm volatile ("rcsr %0,jtx":"=r"(value)); break; case CSR_JRX: asm volatile ("rcsr %0,jrx":"=r"(value)); break; default: printf("csr write only\n"); return; } printf("%08x\n", value); } static void wcsr(char *csr, char *value) { char *c; unsigned int csr2; register unsigned int value2; if((*csr == 0) || (*value == 0)) { printf("wcsr
\n"); return; } csr2 = parse_csr(csr); if(csr2 == 0) { printf("incorrect csr\n"); return; } value2 = strtoul(value, &c, 0); if(*c != 0) { printf("incorrect value\n"); return; } switch(csr2) { case CSR_IE: asm volatile ("wcsr ie,%0"::"r"(value2)); break; case CSR_IM: asm volatile ("wcsr im,%0"::"r"(value2)); break; case CSR_ICC: asm volatile ("wcsr icc,%0"::"r"(value2)); break; case CSR_DCC: asm volatile ("wcsr dcc,%0"::"r"(value2)); break; case CSR_EBA: asm volatile ("wcsr eba,%0"::"r"(value2)); break; case CSR_DC: asm volatile ("wcsr dcc,%0"::"r"(value2)); break; case CSR_DEBA: asm volatile ("wcsr deba,%0"::"r"(value2)); break; case CSR_JTX: asm volatile ("wcsr jtx,%0"::"r"(value2)); break; case CSR_JRX: asm volatile ("wcsr jrx,%0"::"r"(value2)); break; case CSR_BP0: asm volatile ("wcsr bp0,%0"::"r"(value2)); break; case CSR_BP1: asm volatile ("wcsr bp1,%0"::"r"(value2)); break; case CSR_BP2: asm volatile ("wcsr bp2,%0"::"r"(value2)); break; case CSR_BP3: asm volatile ("wcsr bp3,%0"::"r"(value2)); break; case CSR_WP0: asm volatile ("wcsr wp0,%0"::"r"(value2)); break; case CSR_WP1: asm volatile ("wcsr wp1,%0"::"r"(value2)); break; case CSR_WP2: asm volatile ("wcsr wp2,%0"::"r"(value2)); break; case CSR_WP3: asm volatile ("wcsr wp3,%0"::"r"(value2)); break; default: printf("csr read only\n"); return; } } static void dfs(char *baseaddr) { char *c; unsigned int addr; if(*baseaddr == 0) { printf("dfs
\n"); return; } addr = strtoul(baseaddr, &c, 0); if(*c != 0) { printf("incorrect address\n"); return; } print_isd_info(addr); } /* Init + command line */ static void help(void) { puts("MiSoC BIOS"); puts("Available commands:"); puts("mr - read address space"); puts("mw - write address space"); puts("mc - copy address space"); puts("crc - compute CRC32 of a part of the address space"); puts("rcsr - read processor CSR"); puts("wcsr - write processor CSR"); #ifdef MINIMAC_BASE puts("netboot - boot via TFTP"); #endif puts("serialboot - boot via SFL"); puts("flashboot - boot from flash"); puts("revision - display revision"); } static char *get_token(char **str) { char *c, *d; c = (char *)strchr(*str, ' '); if(c == NULL) { d = *str; *str = *str+strlen(*str); return d; } *c = 0; d = *str; *str = c+1; return d; } static void do_command(char *c) { char *token; token = get_token(&c); if(strcmp(token, "mr") == 0) mr(get_token(&c), get_token(&c)); else if(strcmp(token, "mw") == 0) mw(get_token(&c), get_token(&c), get_token(&c)); else if(strcmp(token, "mc") == 0) mc(get_token(&c), get_token(&c), get_token(&c)); else if(strcmp(token, "crc") == 0) crc(get_token(&c), get_token(&c)); else if(strcmp(token, "flushl2") == 0) flush_l2_cache(); else if(strcmp(token, "flashboot") == 0) flashboot(); else if(strcmp(token, "serialboot") == 0) serialboot(); #ifdef MINIMAC_BASE else if(strcmp(token, "netboot") == 0) netboot(); #endif else if(strcmp(token, "revision") == 0) printf("%08x\n", GIT_ID); else if(strcmp(token, "help") == 0) help(); else if(strcmp(token, "rcsr") == 0) rcsr(get_token(&c)); else if(strcmp(token, "wcsr") == 0) wcsr(get_token(&c), get_token(&c)); #ifdef DFII_BASE else if(strcmp(token, "ddrrow") == 0) ddrrow(get_token(&c)); else if(strcmp(token, "ddrsw") == 0) ddrsw(); else if(strcmp(token, "ddrhw") == 0) ddrhw(); else if(strcmp(token, "ddrrd") == 0) ddrrd(get_token(&c)); else if(strcmp(token, "ddrwr") == 0) ddrwr(get_token(&c)); else if(strcmp(token, "memtest") == 0) memtest(); else if(strcmp(token, "ddrinit") == 0) ddrinit(); #endif else if(strcmp(token, "dfs") == 0) dfs(get_token(&c)); else if(strcmp(token, "") != 0) printf("Command not found\n"); } extern unsigned int _ftext, _edata; static void crcbios(void) { unsigned int offset_bios; unsigned int length; unsigned int expected_crc; unsigned int actual_crc; /* * _edata is located right after the end of the flat * binary image. The CRC tool writes the 32-bit CRC here. * We also use the address of _edata to know the length * of our code. */ offset_bios = (unsigned int)&_ftext; expected_crc = _edata; length = (unsigned int)&_edata - offset_bios; actual_crc = crc32((unsigned char *)offset_bios, length); if(expected_crc == actual_crc) printf("BIOS CRC passed (%08x)\n", actual_crc); else { printf("BIOS CRC failed (expected %08x, got %08x)\n", expected_crc, actual_crc); printf("The system will continue, but expect problems.\n"); } } static void readstr(char *s, int size) { char c[2]; int ptr; c[1] = 0; ptr = 0; while(1) { c[0] = readchar(); switch(c[0]) { case 0x7f: case 0x08: if(ptr > 0) { ptr--; putsnonl("\x08 \x08"); } break; case 0x07: break; case '\r': case '\n': s[ptr] = 0x00; putsnonl("\n"); return; default: putsnonl(c); s[ptr] = c[0]; ptr++; break; } } } static int test_user_abort(void) { char c; printf("Automatic boot in 2 seconds...\n"); printf("Q/ESC: abort boot\n"); printf("F7: boot from serial\n"); #ifdef MINIMAC_BASE printf("F8: boot from network\n"); #endif timer0_en_write(0); timer0_reload_write(0); timer0_load_write(identifier_frequency_read()*2); timer0_en_write(1); timer0_update_value_write(1); while(timer0_value_read()) { if(readchar_nonblock()) { c = readchar(); if((c == 'Q')||(c == '\e')) { puts("Aborted"); return 0; } if(c == 0x06) { serialboot(); return 0; } #ifdef MINIMAC_BASE if(c == 0x07) { netboot(); return 0; } #endif } timer0_update_value_write(1); } return 1; } static void boot_sequence(void) { if(test_user_abort()) { flashboot(); serialboot(); #ifdef MINIMAC_BASE netboot(); #endif printf("No boot medium found\n"); } } int main(int i, char **c) { char buffer[64]; int ddr_ok; irq_setmask(0); irq_setie(1); uart_init(); puts("\nMiSoC BIOS http://m-labs.hk\n" "(c) Copyright 2007-2014 Sebastien Bourdeauducq"); printf("Revision %08x built "__DATE__" "__TIME__"\n\n", GIT_ID); crcbios(); id_print(); #ifdef MINIMAC_BASE ethreset(); #endif #ifdef DFII_BASE ddr_ok = ddrinit(); #else ddr_ok = 1; #endif if(ddr_ok) boot_sequence(); else printf("Memory initialization failed\n"); while(1) { putsnonl("\e[1mBIOS>\e[0m "); readstr(buffer, 64); do_command(buffer); } return 0; }