/* * Copyright (c) 2011, Google Inc. All rights reserved. * * SPDX-License-Identifier: GPL-2.0+ */ /* * This module records the progress of boot and arbitrary commands, and * permits accurate timestamping of each. */ #include #include #include #include DECLARE_GLOBAL_DATA_PTR; enum { RECORD_COUNT = CONFIG_BOOTSTAGE_RECORD_COUNT, }; struct bootstage_record { ulong time_us; uint32_t start_us; const char *name; int flags; /* see enum bootstage_flags */ enum bootstage_id id; }; struct bootstage_data { uint rec_count; uint next_id; struct bootstage_record record[RECORD_COUNT]; }; enum { BOOTSTAGE_VERSION = 0, BOOTSTAGE_MAGIC = 0xb00757a3, BOOTSTAGE_DIGITS = 9, }; struct bootstage_hdr { uint32_t version; /* BOOTSTAGE_VERSION */ uint32_t count; /* Number of records */ uint32_t size; /* Total data size (non-zero if valid) */ uint32_t magic; /* Unused */ }; int bootstage_relocate(void) { struct bootstage_data *data = gd->bootstage; int i; /* * Duplicate all strings. They may point to an old location in the * program .text section that can eventually get trashed. */ debug("Relocating %d records\n", data->rec_count); for (i = 0; i < data->rec_count; i++) data->record[i].name = strdup(data->record[i].name); return 0; } struct bootstage_record *find_id(struct bootstage_data *data, enum bootstage_id id) { struct bootstage_record *rec; struct bootstage_record *end; for (rec = data->record, end = rec + data->rec_count; rec < end; rec++) { if (rec->id == id) return rec; } return NULL; } struct bootstage_record *ensure_id(struct bootstage_data *data, enum bootstage_id id) { struct bootstage_record *rec; rec = find_id(data, id); if (!rec && data->rec_count < RECORD_COUNT) { rec = &data->record[data->rec_count++]; rec->id = id; return rec; } return rec; } ulong bootstage_add_record(enum bootstage_id id, const char *name, int flags, ulong mark) { struct bootstage_data *data = gd->bootstage; struct bootstage_record *rec; if (flags & BOOTSTAGEF_ALLOC) id = data->next_id++; /* Only record the first event for each */ rec = find_id(data, id); if (!rec && data->rec_count < RECORD_COUNT) { rec = &data->record[data->rec_count++]; rec->time_us = mark; rec->name = name; rec->flags = flags; rec->id = id; } /* Tell the board about this progress */ show_boot_progress(flags & BOOTSTAGEF_ERROR ? -id : id); return mark; } ulong bootstage_mark(enum bootstage_id id) { return bootstage_add_record(id, NULL, 0, timer_get_boot_us()); } ulong bootstage_error(enum bootstage_id id) { return bootstage_add_record(id, NULL, BOOTSTAGEF_ERROR, timer_get_boot_us()); } ulong bootstage_mark_name(enum bootstage_id id, const char *name) { int flags = 0; if (id == BOOTSTAGE_ID_ALLOC) flags = BOOTSTAGEF_ALLOC; return bootstage_add_record(id, name, flags, timer_get_boot_us()); } ulong bootstage_mark_code(const char *file, const char *func, int linenum) { char *str, *p; __maybe_unused char *end; int len = 0; /* First work out the length we need to allocate */ if (linenum != -1) len = 11; if (func) len += strlen(func); if (file) len += strlen(file); str = malloc(len + 1); p = str; end = p + len; if (file) p += snprintf(p, end - p, "%s,", file); if (linenum != -1) p += snprintf(p, end - p, "%d", linenum); if (func) p += snprintf(p, end - p, ": %s", func); return bootstage_mark_name(BOOTSTAGE_ID_ALLOC, str); } uint32_t bootstage_start(enum bootstage_id id, const char *name) { struct bootstage_data *data = gd->bootstage; struct bootstage_record *rec = ensure_id(data, id); ulong start_us = timer_get_boot_us(); if (rec) { rec->start_us = start_us; rec->name = name; } return start_us; } uint32_t bootstage_accum(enum bootstage_id id) { struct bootstage_data *data = gd->bootstage; struct bootstage_record *rec = ensure_id(data, id); uint32_t duration; if (!rec) return 0; duration = (uint32_t)timer_get_boot_us() - rec->start_us; rec->time_us += duration; return duration; } /** * Get a record name as a printable string * * @param buf Buffer to put name if needed * @param len Length of buffer * @param rec Boot stage record to get the name from * @return pointer to name, either from the record or pointing to buf. */ static const char *get_record_name(char *buf, int len, struct bootstage_record *rec) { if (rec->name) return rec->name; else if (rec->id >= BOOTSTAGE_ID_USER) snprintf(buf, len, "user_%d", rec->id - BOOTSTAGE_ID_USER); else snprintf(buf, len, "id=%d", rec->id); return buf; } static uint32_t print_time_record(struct bootstage_record *rec, uint32_t prev) { char buf[20]; if (prev == -1U) { printf("%11s", ""); print_grouped_ull(rec->time_us, BOOTSTAGE_DIGITS); } else { print_grouped_ull(rec->time_us, BOOTSTAGE_DIGITS); print_grouped_ull(rec->time_us - prev, BOOTSTAGE_DIGITS); } printf(" %s\n", get_record_name(buf, sizeof(buf), rec)); return rec->time_us; } static int h_compare_record(const void *r1, const void *r2) { const struct bootstage_record *rec1 = r1, *rec2 = r2; return rec1->time_us > rec2->time_us ? 1 : -1; } #ifdef CONFIG_OF_LIBFDT /** * Add all bootstage timings to a device tree. * * @param blob Device tree blob * @return 0 on success, != 0 on failure. */ static int add_bootstages_devicetree(struct fdt_header *blob) { struct bootstage_data *data = gd->bootstage; int bootstage; char buf[20]; int recnum; int i; if (!blob) return 0; /* * Create the node for bootstage. * The address of flat device tree is set up by the command bootm. */ bootstage = fdt_add_subnode(blob, 0, "bootstage"); if (bootstage < 0) return -1; /* * Insert the timings to the device tree in the reverse order so * that they can be printed in the Linux kernel in the right order. */ for (recnum = data->rec_count - 1, i = 0; recnum >= 0; recnum--, i++) { struct bootstage_record *rec = &data->record[recnum]; int node; if (rec->id != BOOTSTAGE_ID_AWAKE && rec->time_us == 0) continue; node = fdt_add_subnode(blob, bootstage, simple_itoa(i)); if (node < 0) break; /* add properties to the node. */ if (fdt_setprop_string(blob, node, "name", get_record_name(buf, sizeof(buf), rec))) return -1; /* Check if this is a 'mark' or 'accum' record */ if (fdt_setprop_cell(blob, node, rec->start_us ? "accum" : "mark", rec->time_us)) return -1; } return 0; } int bootstage_fdt_add_report(void) { if (add_bootstages_devicetree(working_fdt)) puts("bootstage: Failed to add to device tree\n"); return 0; } #endif void bootstage_report(void) { struct bootstage_data *data = gd->bootstage; struct bootstage_record *rec = data->record; uint32_t prev; int i; printf("Timer summary in microseconds (%d records):\n", data->rec_count); printf("%11s%11s %s\n", "Mark", "Elapsed", "Stage"); prev = print_time_record(rec, 0); /* Sort records by increasing time */ qsort(data->record, data->rec_count, sizeof(*rec), h_compare_record); for (i = 1, rec++; i < data->rec_count; i++, rec++) { if (rec->id && !rec->start_us) prev = print_time_record(rec, prev); } if (data->rec_count > RECORD_COUNT) printf("Overflowed internal boot id table by %d entries\n" "- please increase CONFIG_BOOTSTAGE_RECORD_COUNT\n", data->rec_count - RECORD_COUNT); puts("\nAccumulated time:\n"); for (i = 0, rec = data->record; i < data->rec_count; i++, rec++) { if (rec->start_us) prev = print_time_record(rec, -1); } } /** * Append data to a memory buffer * * Write data to the buffer if there is space. Whether there is space or not, * the buffer pointer is incremented. * * @param ptrp Pointer to buffer, updated by this function * @param end Pointer to end of buffer * @param data Data to write to buffer * @param size Size of data */ static void append_data(char **ptrp, char *end, const void *data, int size) { char *ptr = *ptrp; *ptrp += size; if (*ptrp > end) return; memcpy(ptr, data, size); } int bootstage_stash(void *base, int size) { struct bootstage_data *data = gd->bootstage; struct bootstage_hdr *hdr = (struct bootstage_hdr *)base; struct bootstage_record *rec; char buf[20]; char *ptr = base, *end = ptr + size; uint32_t count; int i; if (hdr + 1 > (struct bootstage_hdr *)end) { debug("%s: Not enough space for bootstage hdr\n", __func__); return -1; } /* Write an arbitrary version number */ hdr->version = BOOTSTAGE_VERSION; /* Count the number of records, and write that value first */ for (rec = data->record, i = count = 0; i < data->rec_count; i++, rec++) { if (rec->id != 0) count++; } hdr->count = count; hdr->size = 0; hdr->magic = BOOTSTAGE_MAGIC; ptr += sizeof(*hdr); /* Write the records, silently stopping when we run out of space */ for (rec = data->record, i = 0; i < data->rec_count; i++, rec++) { append_data(&ptr, end, rec, sizeof(*rec)); } /* Write the name strings */ for (rec = data->record, i = 0; i < data->rec_count; i++, rec++) { const char *name; name = get_record_name(buf, sizeof(buf), rec); append_data(&ptr, end, name, strlen(name) + 1); } /* Check for buffer overflow */ if (ptr > end) { debug("%s: Not enough space for bootstage stash\n", __func__); return -1; } /* Update total data size */ hdr->size = ptr - (char *)base; debug("Stashed %d records\n", hdr->count); return 0; } int bootstage_unstash(void *base, int size) { struct bootstage_data *data = gd->bootstage; struct bootstage_hdr *hdr = (struct bootstage_hdr *)base; struct bootstage_record *rec; char *ptr = base, *end = ptr + size; uint rec_size; int i; if (size == -1) end = (char *)(~(uintptr_t)0); if (hdr + 1 > (struct bootstage_hdr *)end) { debug("%s: Not enough space for bootstage hdr\n", __func__); return -1; } if (hdr->magic != BOOTSTAGE_MAGIC) { debug("%s: Invalid bootstage magic\n", __func__); return -1; } if (ptr + hdr->size > end) { debug("%s: Bootstage data runs past buffer end\n", __func__); return -1; } if (hdr->count * sizeof(*rec) > hdr->size) { debug("%s: Bootstage has %d records needing %lu bytes, but " "only %d bytes is available\n", __func__, hdr->count, (ulong)hdr->count * sizeof(*rec), hdr->size); return -1; } if (hdr->version != BOOTSTAGE_VERSION) { debug("%s: Bootstage data version %#0x unrecognised\n", __func__, hdr->version); return -1; } if (data->rec_count + hdr->count > RECORD_COUNT) { debug("%s: Bootstage has %d records, we have space for %d\n" "- please increase CONFIG_BOOTSTAGE_USER_COUNT\n", __func__, hdr->count, RECORD_COUNT - data->rec_count); return -1; } ptr += sizeof(*hdr); /* Read the records */ rec_size = hdr->count * sizeof(*data->record); memcpy(data->record + data->rec_count, ptr, rec_size); /* Read the name strings */ ptr += rec_size; for (rec = data->record + data->next_id, i = 0; i < hdr->count; i++, rec++) { rec->name = ptr; /* Assume no data corruption here */ ptr += strlen(ptr) + 1; } /* Mark the records as read */ data->rec_count += hdr->count; debug("Unstashed %d records\n", hdr->count); return 0; } int bootstage_get_size(void) { return sizeof(struct bootstage_data); } int bootstage_init(bool first) { struct bootstage_data *data; int size = sizeof(struct bootstage_data); gd->bootstage = (struct bootstage_data *)malloc(size); if (!gd->bootstage) return -ENOMEM; data = gd->bootstage; memset(data, '\0', size); if (first) { data->next_id = BOOTSTAGE_ID_USER; bootstage_add_record(BOOTSTAGE_ID_AWAKE, "reset", 0, 0); } return 0; }