uboot/lib/libavb/avb_util.c
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   1// SPDX-License-Identifier: MIT
   2/*
   3 * Copyright (C) 2016 The Android Open Source Project
   4 */
   5
   6#include "avb_util.h"
   7#include <log.h>
   8#include <malloc.h>
   9
  10#include <stdarg.h>
  11
  12uint32_t avb_be32toh(uint32_t in) {
  13  uint8_t* d = (uint8_t*)&in;
  14  uint32_t ret;
  15  ret = ((uint32_t)d[0]) << 24;
  16  ret |= ((uint32_t)d[1]) << 16;
  17  ret |= ((uint32_t)d[2]) << 8;
  18  ret |= ((uint32_t)d[3]);
  19  return ret;
  20}
  21
  22uint64_t avb_be64toh(uint64_t in) {
  23  uint8_t* d = (uint8_t*)&in;
  24  uint64_t ret;
  25  ret = ((uint64_t)d[0]) << 56;
  26  ret |= ((uint64_t)d[1]) << 48;
  27  ret |= ((uint64_t)d[2]) << 40;
  28  ret |= ((uint64_t)d[3]) << 32;
  29  ret |= ((uint64_t)d[4]) << 24;
  30  ret |= ((uint64_t)d[5]) << 16;
  31  ret |= ((uint64_t)d[6]) << 8;
  32  ret |= ((uint64_t)d[7]);
  33  return ret;
  34}
  35
  36/* Converts a 32-bit unsigned integer from host to big-endian byte order. */
  37uint32_t avb_htobe32(uint32_t in) {
  38  union {
  39    uint32_t word;
  40    uint8_t bytes[4];
  41  } ret;
  42  ret.bytes[0] = (in >> 24) & 0xff;
  43  ret.bytes[1] = (in >> 16) & 0xff;
  44  ret.bytes[2] = (in >> 8) & 0xff;
  45  ret.bytes[3] = in & 0xff;
  46  return ret.word;
  47}
  48
  49/* Converts a 64-bit unsigned integer from host to big-endian byte order. */
  50uint64_t avb_htobe64(uint64_t in) {
  51  union {
  52    uint64_t word;
  53    uint8_t bytes[8];
  54  } ret;
  55  ret.bytes[0] = (in >> 56) & 0xff;
  56  ret.bytes[1] = (in >> 48) & 0xff;
  57  ret.bytes[2] = (in >> 40) & 0xff;
  58  ret.bytes[3] = (in >> 32) & 0xff;
  59  ret.bytes[4] = (in >> 24) & 0xff;
  60  ret.bytes[5] = (in >> 16) & 0xff;
  61  ret.bytes[6] = (in >> 8) & 0xff;
  62  ret.bytes[7] = in & 0xff;
  63  return ret.word;
  64}
  65
  66int avb_safe_memcmp(const void* s1, const void* s2, size_t n) {
  67  const unsigned char* us1 = s1;
  68  const unsigned char* us2 = s2;
  69  int result = 0;
  70
  71  if (0 == n) {
  72    return 0;
  73  }
  74
  75  /*
  76   * Code snippet without data-dependent branch due to Nate Lawson
  77   * (nate@root.org) of Root Labs.
  78   */
  79  while (n--) {
  80    result |= *us1++ ^ *us2++;
  81  }
  82
  83  return result != 0;
  84}
  85
  86bool avb_safe_add_to(uint64_t* value, uint64_t value_to_add) {
  87  uint64_t original_value;
  88
  89  avb_assert(value != NULL);
  90
  91  original_value = *value;
  92
  93  *value += value_to_add;
  94  if (*value < original_value) {
  95    avb_error("Overflow when adding values.\n");
  96    return false;
  97  }
  98
  99  return true;
 100}
 101
 102bool avb_safe_add(uint64_t* out_result, uint64_t a, uint64_t b) {
 103  uint64_t dummy;
 104  if (out_result == NULL) {
 105    out_result = &dummy;
 106  }
 107  *out_result = a;
 108  return avb_safe_add_to(out_result, b);
 109}
 110
 111bool avb_validate_utf8(const uint8_t* data, size_t num_bytes) {
 112  size_t n;
 113  unsigned int num_cc;
 114
 115  for (n = 0, num_cc = 0; n < num_bytes; n++) {
 116    uint8_t c = data[n];
 117
 118    if (num_cc > 0) {
 119      if ((c & (0x80 | 0x40)) == 0x80) {
 120        /* 10xx xxxx */
 121      } else {
 122        goto fail;
 123      }
 124      num_cc--;
 125    } else {
 126      if (c < 0x80) {
 127        num_cc = 0;
 128      } else if ((c & (0x80 | 0x40 | 0x20)) == (0x80 | 0x40)) {
 129        /* 110x xxxx */
 130        num_cc = 1;
 131      } else if ((c & (0x80 | 0x40 | 0x20 | 0x10)) == (0x80 | 0x40 | 0x20)) {
 132        /* 1110 xxxx */
 133        num_cc = 2;
 134      } else if ((c & (0x80 | 0x40 | 0x20 | 0x10 | 0x08)) ==
 135                 (0x80 | 0x40 | 0x20 | 0x10)) {
 136        /* 1111 0xxx */
 137        num_cc = 3;
 138      } else {
 139        goto fail;
 140      }
 141    }
 142  }
 143
 144  if (num_cc != 0) {
 145    goto fail;
 146  }
 147
 148  return true;
 149
 150fail:
 151  return false;
 152}
 153
 154bool avb_str_concat(char* buf,
 155                    size_t buf_size,
 156                    const char* str1,
 157                    size_t str1_len,
 158                    const char* str2,
 159                    size_t str2_len) {
 160  uint64_t combined_len;
 161
 162  if (!avb_safe_add(&combined_len, str1_len, str2_len)) {
 163    avb_error("Overflow when adding string sizes.\n");
 164    return false;
 165  }
 166
 167  if (combined_len > buf_size - 1) {
 168    avb_error("Insufficient buffer space.\n");
 169    return false;
 170  }
 171
 172  avb_memcpy(buf, str1, str1_len);
 173  avb_memcpy(buf + str1_len, str2, str2_len);
 174  buf[combined_len] = '\0';
 175
 176  return true;
 177}
 178
 179void* avb_malloc(size_t size) {
 180  void* ret = avb_malloc_(size);
 181  if (ret == NULL) {
 182    avb_error("Failed to allocate memory.\n");
 183    return NULL;
 184  }
 185  return ret;
 186}
 187
 188void* avb_calloc(size_t size) {
 189  void* ret = avb_malloc(size);
 190  if (ret == NULL) {
 191    return NULL;
 192  }
 193
 194  avb_memset(ret, '\0', size);
 195  return ret;
 196}
 197
 198char* avb_strdup(const char* str) {
 199  size_t len = avb_strlen(str);
 200  char* ret = avb_malloc(len + 1);
 201  if (ret == NULL) {
 202    return NULL;
 203  }
 204
 205  avb_memcpy(ret, str, len);
 206  ret[len] = '\0';
 207
 208  return ret;
 209}
 210
 211const char* avb_strstr(const char* haystack, const char* needle) {
 212  size_t n, m;
 213
 214  /* Look through |haystack| and check if the first character of
 215   * |needle| matches. If so, check the rest of |needle|.
 216   */
 217  for (n = 0; haystack[n] != '\0'; n++) {
 218    if (haystack[n] != needle[0]) {
 219      continue;
 220    }
 221
 222    for (m = 1;; m++) {
 223      if (needle[m] == '\0') {
 224        return haystack + n;
 225      }
 226
 227      if (haystack[n + m] != needle[m]) {
 228        break;
 229      }
 230    }
 231  }
 232
 233  return NULL;
 234}
 235
 236const char* avb_strv_find_str(const char* const* strings,
 237                              const char* str,
 238                              size_t str_size) {
 239  size_t n;
 240  for (n = 0; strings[n] != NULL; n++) {
 241    if (avb_strlen(strings[n]) == str_size &&
 242        avb_memcmp(strings[n], str, str_size) == 0) {
 243      return strings[n];
 244    }
 245  }
 246  return NULL;
 247}
 248
 249char* avb_replace(const char* str, const char* search, const char* replace) {
 250  char* ret = NULL;
 251  size_t ret_len = 0;
 252  size_t search_len, replace_len;
 253  const char* str_after_last_replace;
 254
 255  search_len = avb_strlen(search);
 256  replace_len = avb_strlen(replace);
 257
 258  str_after_last_replace = str;
 259  while (*str != '\0') {
 260    const char* s;
 261    size_t num_before;
 262    size_t num_new;
 263
 264    s = avb_strstr(str, search);
 265    if (s == NULL) {
 266      break;
 267    }
 268
 269    num_before = s - str;
 270
 271    if (ret == NULL) {
 272      num_new = num_before + replace_len + 1;
 273      ret = avb_malloc(num_new);
 274      if (ret == NULL) {
 275        goto out;
 276      }
 277      avb_memcpy(ret, str, num_before);
 278      avb_memcpy(ret + num_before, replace, replace_len);
 279      ret[num_new - 1] = '\0';
 280      ret_len = num_new - 1;
 281    } else {
 282      char* new_str;
 283      num_new = ret_len + num_before + replace_len + 1;
 284      new_str = avb_malloc(num_new);
 285      if (new_str == NULL) {
 286        goto out;
 287      }
 288      avb_memcpy(new_str, ret, ret_len);
 289      avb_memcpy(new_str + ret_len, str, num_before);
 290      avb_memcpy(new_str + ret_len + num_before, replace, replace_len);
 291      new_str[num_new - 1] = '\0';
 292      avb_free(ret);
 293      ret = new_str;
 294      ret_len = num_new - 1;
 295    }
 296
 297    str = s + search_len;
 298    str_after_last_replace = str;
 299  }
 300
 301  if (ret == NULL) {
 302    ret = avb_strdup(str_after_last_replace);
 303    if (ret == NULL) {
 304      goto out;
 305    }
 306  } else {
 307    size_t num_remaining = avb_strlen(str_after_last_replace);
 308    size_t num_new = ret_len + num_remaining + 1;
 309    char* new_str = avb_malloc(num_new);
 310    if (new_str == NULL) {
 311      goto out;
 312    }
 313    avb_memcpy(new_str, ret, ret_len);
 314    avb_memcpy(new_str + ret_len, str_after_last_replace, num_remaining);
 315    new_str[num_new - 1] = '\0';
 316    avb_free(ret);
 317    ret = new_str;
 318    ret_len = num_new - 1;
 319  }
 320
 321out:
 322  return ret;
 323}
 324
 325/* We only support a limited amount of strings in avb_strdupv(). */
 326#define AVB_STRDUPV_MAX_NUM_STRINGS 32
 327
 328char* avb_strdupv(const char* str, ...) {
 329  va_list ap;
 330  const char* strings[AVB_STRDUPV_MAX_NUM_STRINGS];
 331  size_t lengths[AVB_STRDUPV_MAX_NUM_STRINGS];
 332  size_t num_strings, n;
 333  uint64_t total_length;
 334  char *ret = NULL, *dest;
 335
 336  num_strings = 0;
 337  total_length = 0;
 338  va_start(ap, str);
 339  do {
 340    size_t str_len = avb_strlen(str);
 341    strings[num_strings] = str;
 342    lengths[num_strings] = str_len;
 343    if (!avb_safe_add_to(&total_length, str_len)) {
 344      avb_fatal("Overflow while determining total length.\n");
 345      break;
 346    }
 347    num_strings++;
 348    if (num_strings == AVB_STRDUPV_MAX_NUM_STRINGS) {
 349      avb_fatal("Too many strings passed.\n");
 350      break;
 351    }
 352    str = va_arg(ap, const char*);
 353  } while (str != NULL);
 354  va_end(ap);
 355
 356  ret = avb_malloc(total_length + 1);
 357  if (ret == NULL) {
 358    goto out;
 359  }
 360
 361  dest = ret;
 362  for (n = 0; n < num_strings; n++) {
 363    avb_memcpy(dest, strings[n], lengths[n]);
 364    dest += lengths[n];
 365  }
 366  *dest = '\0';
 367  avb_assert(dest == ret + total_length);
 368
 369out:
 370  return ret;
 371}
 372
 373const char* avb_basename(const char* str) {
 374  int64_t n;
 375  size_t len;
 376
 377  len = avb_strlen(str);
 378  if (len >= 2) {
 379    for (n = len - 2; n >= 0; n--) {
 380      if (str[n] == '/') {
 381        return str + n + 1;
 382      }
 383    }
 384  }
 385  return str;
 386}
 387
 388void avb_uppercase(char* str) {
 389  size_t i;
 390  for (i = 0; str[i] != '\0'; ++i) {
 391    if (str[i] <= 0x7A && str[i] >= 0x61) {
 392      str[i] -= 0x20;
 393    }
 394  }
 395}
 396
 397char* avb_bin2hex(const uint8_t* data, size_t data_len) {
 398  const char hex_digits[17] = "0123456789abcdef";
 399  char* hex_data;
 400  size_t n;
 401
 402  hex_data = avb_malloc(data_len * 2 + 1);
 403  if (hex_data == NULL) {
 404    return NULL;
 405  }
 406
 407  for (n = 0; n < data_len; n++) {
 408    hex_data[n * 2] = hex_digits[data[n] >> 4];
 409    hex_data[n * 2 + 1] = hex_digits[data[n] & 0x0f];
 410  }
 411  hex_data[n * 2] = '\0';
 412  return hex_data;
 413}
 414