/* * This file is part of the coreboot project. * * Copyright (C) 2012 The ChromiumOS Authors. All rights reserved. * * 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; version 2 of the License. * * 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, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #include #include #include #include #include #include #include #include #include #define ARRAY_SIZE(a) (sizeof(a) / sizeof((a)[0])) #define MAP_BYTES (1024*1024) #include "boot/coreboot_tables.h" typedef uint16_t u16; typedef uint32_t u32; typedef uint64_t u64; #include "cbmem.h" #include "timestamp.h" #define CBMEM_VERSION "1.0" /* verbose output? */ static int verbose = 0; #define debug(x...) if(verbose) printf(x) /* File handle used to access /dev/mem */ static int fd; /* * calculate ip checksum (16 bit quantities) on a passed in buffer. In case * the buffer length is odd last byte is excluded from the calculation */ static u16 ipchcksum(const void *addr, unsigned size) { const u16 *p = addr; unsigned i, n = size / 2; /* don't expect odd sized blocks */ u32 sum = 0; for (i = 0; i < n; i++) sum += p[i]; sum = (sum >> 16) + (sum & 0xffff); sum += (sum >> 16); sum = ~sum & 0xffff; return (u16) sum; } /* * Functions to map / unmap physical memory into virtual address space. These * functions always maps 1MB at a time and can only map one area at once. */ static void *mapped_virtual; static void *map_memory(u64 physical) { void *v; off_t p; int page = getpagesize(); /* Mapped memory must be aligned to page size */ p = physical & ~(page - 1); debug("Mapping 1MB of physical memory at %zx.\n", p); v = mmap(NULL, MAP_BYTES, PROT_READ, MAP_SHARED, fd, p); if (v == MAP_FAILED) { fprintf(stderr, "Failed to mmap /dev/mem: %s\n", strerror(errno)); exit(1); } /* Remember what we actually mapped ... */ mapped_virtual = v; /* ... but return address to the physical memory that was requested */ v += physical & (page-1); return v; } static void unmap_memory(void) { debug("Unmapping 1MB of virtual memory at %p.\n", mapped_virtual); munmap(mapped_virtual, MAP_BYTES); } /* * Try finding the timestamp table and coreboot cbmem console starting from the * passed in memory offset. Could be called recursively in case a forwarding * entry is found. * * Returns pointer to a memory buffer containg the timestamp table or zero if * none found. */ static struct lb_cbmem_ref timestamps; static struct lb_cbmem_ref console; static struct lb_memory_range cbmem; static int parse_cbtable(u64 address) { int i, found = 0; void *buf; debug("Looking for coreboot table at %lx\n", address); buf = map_memory(address); /* look at every 16 bytes within 4K of the base */ for (i = 0; i < 0x1000; i += 0x10) { struct lb_header *lbh; struct lb_record* lbr_p; void *lbtable; int j; lbh = (struct lb_header *)(buf + i); if (memcmp(lbh->signature, "LBIO", sizeof(lbh->signature)) || !lbh->header_bytes || ipchcksum(lbh, sizeof(*lbh))) { continue; } lbtable = buf + i + lbh->header_bytes; if (ipchcksum(lbtable, lbh->table_bytes) != lbh->table_checksum) { debug("Signature found, but wrong checksum.\n"); continue; } found = 1; debug("Found!\n"); for (j = 0; j < lbh->table_bytes; j += lbr_p->size) { /* look for the timestamp table */ lbr_p = (struct lb_record*) ((char *)lbtable + j); debug(" coreboot table entry 0x%02x\n", lbr_p->tag); switch (lbr_p->tag) { case LB_TAG_MEMORY: { int i = 0; debug(" Found memory map.\n"); struct lb_memory *memory = (struct lb_memory *)lbr_p; while ((char *)&memory->map[i] < ((char *)lbtable + lbr_p->size)) { if (memory->map[i].type == LB_MEM_TABLE) { debug(" LB_MEM_TABLE found.\n"); /* The last one found is CBMEM */ cbmem = memory->map[i]; } i++; } continue; } case LB_TAG_TIMESTAMPS: { debug(" Found timestamp table.\n"); timestamps = *(struct lb_cbmem_ref *) lbr_p; continue; } case LB_TAG_CBMEM_CONSOLE: { debug(" Found cbmem console.\n"); console = *(struct lb_cbmem_ref *) lbr_p; continue; } case LB_TAG_FORWARD: { /* * This is a forwarding entry - repeat the * search at the new address. */ struct lb_forward lbf_p = *(struct lb_forward *) lbr_p; debug(" Found forwarding entry.\n"); unmap_memory(); return parse_cbtable(lbf_p.forward); } default: break; } } } unmap_memory(); return found; } /* * read CPU frequency from a sysfs file, return an frequency in Kilohertz as * an int or exit on any error. */ static u64 get_cpu_freq_KHz(void) { FILE *cpuf; char freqs[100]; int size; char *endp; u64 rv; const char* freq_file = "/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq"; cpuf = fopen(freq_file, "r"); if (!cpuf) { fprintf(stderr, "Could not open %s: %s\n", freq_file, strerror(errno)); exit(1); } memset(freqs, 0, sizeof(freqs)); size = fread(freqs, 1, sizeof(freqs), cpuf); if (!size || (size == sizeof(freqs))) { fprintf(stderr, "Wrong number of bytes(%d) read from %s\n", size, freq_file); exit(1); } fclose(cpuf); rv = strtoull(freqs, &endp, 10); if (*endp == '\0' || *endp == '\n') return rv; fprintf(stderr, "Wrong formatted value ^%s^ read from %s\n", freqs, freq_file); exit(1); } /* * Print an integer in 'normalized' form - with commas separating every three * decimal orders. The 'comma' parameter indicates if a comma is needed after * the value is printed. */ static void print_norm(u64 v, int comma) { int first_triple = 1; if (v > 1000) { /* print the higher order sections first */ print_norm(v / 1000, 1); first_triple = 0; } if (first_triple) printf("%d", (u32)(v % 1000)); else printf("%3.3d", (u32)(v % 1000)); if (comma) printf(","); } /* dump the timestamp table */ static void dump_timestamps(void) { int i; u64 cpu_freq_MHz = get_cpu_freq_KHz() / 1000; struct timestamp_table *tst_p; if (timestamps.tag != LB_TAG_TIMESTAMPS) { fprintf(stderr, "No timestamps found in coreboot table.\n"); return; } tst_p = (struct timestamp_table *) map_memory((unsigned long)timestamps.cbmem_addr); printf("%d entries total:\n\n", tst_p->num_entries); for (i = 0; i < tst_p->num_entries; i++) { const struct timestamp_entry *tse_p = tst_p->entries + i; printf("%4d:", tse_p->entry_id); print_norm(tse_p->entry_stamp / cpu_freq_MHz, 0); if (i) { printf(" ("); print_norm((tse_p->entry_stamp - tse_p[-1].entry_stamp) / cpu_freq_MHz, 0); printf(")"); } printf("\n"); } unmap_memory(); } /* dump the cbmem console */ static void dump_console(void) { void *console_p; char *console_c; uint32_t size; if (console.tag != LB_TAG_CBMEM_CONSOLE) { fprintf(stderr, "No console found in coreboot table.\n"); return; } console_p = map_memory((unsigned long)console.cbmem_addr); /* The in-memory format of the console area is: * u32 size * u32 cursor * char console[size] * Hence we have to add 8 to get to the actual console string. */ size = *(uint32_t *)console_p; console_c = malloc(size + 1); if (!console_c) { fprintf(stderr, "Not enough memory for console.\n"); exit(1); } memcpy(console_c, console_p + 8, size); console_c[size] = 0; printf("%s", console_c); free(console_c); unmap_memory(); } #define CBMEM_MAGIC 0x434f5245 #define MAX_CBMEM_ENTRIES 16 struct cbmem_entry { uint32_t magic; uint32_t id; uint64_t base; uint64_t size; }; void dump_cbmem_toc(void) { int i; uint64_t start; struct cbmem_entry *entries; if (cbmem.type != LB_MEM_TABLE) { fprintf(stderr, "No coreboot table area found!\n"); return; } start = unpack_lb64(cbmem.start); entries = (struct cbmem_entry *)map_memory(start); printf("CBMEM table of contents:\n"); printf(" ID START LENGTH\n"); for (i=0; i.\n\n"); } void print_usage(const char *name) { printf("usage: %s [-vh?]\n", name); printf("\n" " -c | --console: print cbmem console\n" " -l | --list: print cbmem table of contents\n" " -t | --timestamps: print timestamp information\n" " -V | --verbose: verbose (debugging) output\n" " -v | --version: print the version\n" " -h | --help: print this help\n" "\n"); exit(1); } int main(int argc, char** argv) { int j; static const int possible_base_addresses[] = { 0, 0xf0000 }; int print_defaults = 1; int print_console = 0; int print_list = 0; int print_timestamps = 0; int opt, option_index = 0; static struct option long_options[] = { {"console", 0, 0, 'c'}, {"list", 0, 0, 'l'}, {"timestamps", 0, 0, 't'}, {"verbose", 0, 0, 'V'}, {"version", 0, 0, 'v'}, {"help", 0, 0, 'h'}, {0, 0, 0, 0} }; while ((opt = getopt_long(argc, argv, "cltVvh?", long_options, &option_index)) != EOF) { switch (opt) { case 'c': print_console = 1; print_defaults = 0; break; case 'l': print_list = 1; print_defaults = 0; break; case 't': print_timestamps = 1; print_defaults = 0; break; case 'V': verbose = 1; break; case 'v': print_version(); exit(0); break; case 'h': case '?': default: print_usage(argv[0]); exit(0); break; } } fd = open("/dev/mem", O_RDONLY, 0); if (fd < 0) { fprintf(stderr, "Failed to gain memory access: %s\n", strerror(errno)); return 1; } /* Find and parse coreboot table */ for (j = 0; j < ARRAY_SIZE(possible_base_addresses); j++) { if (parse_cbtable(possible_base_addresses[j])) break; } if (print_console) dump_console(); if (print_list) dump_cbmem_toc(); if (print_defaults || print_timestamps) dump_timestamps(); close(fd); return 0; }