test/avb_util_unittest.cc - platform/external/avb - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Permission is hereby granted, free of charge, to any person
  * obtaining a copy of this software and associated documentation
  * files (the "Software"), to deal in the Software without
  * restriction, including without limitation the rights to use, copy,
  * modify, merge, publish, distribute, sublicense, and/or sell copies
  * of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be
  * included in all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
  * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
  * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
  * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
  * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
  * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
  * SOFTWARE.
  */

 #include <endian.h>
 #include <string.h>

 #include <gtest/gtest.h>

 #include <libavb/avb_sha.h>
 #include <libavb/libavb.h>

 #include "avb_unittest_util.h"

 namespace avb {

 // Subclass BaseAvbToolTest to check for memory leaks.
 class UtilTest : public BaseAvbToolTest {
  public:
   UtilTest() {}
 };

 TEST_F(UtilTest, RSAPublicKeyHeaderByteswap) {
   AvbRSAPublicKeyHeader h;
   AvbRSAPublicKeyHeader s;
   uint32_t n32;
   uint64_t n64;

   n32 = 0x11223344;
   n64 = 0x1122334455667788;

   h.key_num_bits = htobe32(n32);
   n32++;
   h.n0inv = htobe32(n32);
   n32++;

   EXPECT_NE(0, avb_rsa_public_key_header_validate_and_byteswap(&h, &s));

   n32 = 0x11223344;
   n64 = 0x1122334455667788;

   EXPECT_EQ(n32, s.key_num_bits);
   n32++;
   EXPECT_EQ(n32, s.n0inv);
   n32++;
 }

 TEST_F(UtilTest, FooterByteswap) {
   AvbFooter h;
   AvbFooter s;
   AvbFooter other;
   AvbFooter bad;
   uint64_t n64;

   n64 = 0x1122334455667788;

   memcpy(h.magic, AVB_FOOTER_MAGIC, AVB_FOOTER_MAGIC_LEN);
   h.version_major = htobe32(AVB_FOOTER_VERSION_MAJOR);
   h.version_minor = htobe32(AVB_FOOTER_VERSION_MINOR);
   h.original_image_size = htobe64(n64);
   n64++;
   h.vbmeta_offset = htobe64(n64);
   n64++;
   h.vbmeta_size = htobe64(n64);
   n64++;

   EXPECT_NE(0, avb_footer_validate_and_byteswap(&h, &s));

   n64 = 0x1122334455667788;

   EXPECT_EQ((uint32_t)AVB_FOOTER_VERSION_MAJOR, s.version_major);
   EXPECT_EQ((uint32_t)AVB_FOOTER_VERSION_MINOR, s.version_minor);
   EXPECT_EQ(n64, s.original_image_size);
   n64++;
   EXPECT_EQ(n64, s.vbmeta_offset);
   n64++;
   EXPECT_EQ(n64, s.vbmeta_size);
   n64++;

   // Check that the struct still validates if minor is bigger than
   // what we expect.
   other = h;
   h.version_minor = htobe32(AVB_FOOTER_VERSION_MINOR + 1);
   EXPECT_NE(0, avb_footer_validate_and_byteswap(&other, &s));

   // Check for bad magic.
   bad = h;
   bad.magic[0] = 'x';
   EXPECT_EQ(0, avb_footer_validate_and_byteswap(&bad, &s));

   // Check for bad major version.
   bad = h;
   bad.version_major = htobe32(AVB_FOOTER_VERSION_MAJOR + 1);
   EXPECT_EQ(0, avb_footer_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, KernelCmdlineDescriptorByteswap) {
   AvbKernelCmdlineDescriptor h;
   AvbKernelCmdlineDescriptor s;
   AvbKernelCmdlineDescriptor bad;
   uint64_t nbf;
   uint32_t n32;

   // Specify 40 bytes of data past the end of the descriptor struct.
   nbf = 40 + sizeof(AvbKernelCmdlineDescriptor) - sizeof(AvbDescriptor);
   h.parent_descriptor.num_bytes_following = htobe64(nbf);
   h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_KERNEL_CMDLINE);
   h.kernel_cmdline_length = htobe32(40);

   n32 = 0x11223344;
   h.flags = htobe32(n32);
   n32++;

   EXPECT_NE(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&h, &s));

   n32 = 0x11223344;
   EXPECT_EQ(n32, s.flags);
   n32++;

   EXPECT_EQ(AVB_DESCRIPTOR_TAG_KERNEL_CMDLINE, s.parent_descriptor.tag);
   EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
   EXPECT_EQ(40UL, s.kernel_cmdline_length);

   // Check for bad tag.
   bad = h;
   bad.parent_descriptor.tag = htobe64(0xf00dd00d);
   EXPECT_EQ(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 41 bytes.
   bad = h;
   bad.kernel_cmdline_length = htobe32(41);
   EXPECT_EQ(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, HashtreeDescriptorByteswap) {
   AvbHashtreeDescriptor h;
   AvbHashtreeDescriptor s;
   AvbHashtreeDescriptor bad;
   uint64_t nbf;
   uint32_t n32;
   uint64_t n64;

   // Specify 44 bytes of data past the end of the descriptor struct.
   nbf = 44 + sizeof(AvbHashtreeDescriptor) - sizeof(AvbDescriptor);
   h.parent_descriptor.num_bytes_following = htobe64(nbf);
   h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_HASHTREE);
   h.partition_name_len = htobe32(10);
   h.salt_len = htobe32(10);
   h.root_digest_len = htobe32(10);

   n32 = 0x11223344;
   n64 = 0x1122334455667788;

   h.dm_verity_version = htobe32(n32);
   n32++;
   h.image_size = htobe64(n64);
   n64++;
   h.tree_offset = htobe64(n64);
   n64++;
   h.tree_size = htobe64(n64);
   n64++;
   h.data_block_size = htobe32(n32);
   n32++;
   h.hash_block_size = htobe32(n32);
   n32++;
   h.fec_num_roots = htobe32(n32);
   n32++;
   h.fec_offset = htobe64(n64);
   n64++;
   h.fec_size = htobe64(n64);
   n64++;

   EXPECT_TRUE(avb_hashtree_descriptor_validate_and_byteswap(&h, &s));

   n32 = 0x11223344;
   n64 = 0x1122334455667788;

   EXPECT_EQ(n32, s.dm_verity_version);
   n32++;
   EXPECT_EQ(n64, s.image_size);
   n64++;
   EXPECT_EQ(n64, s.tree_offset);
   n64++;
   EXPECT_EQ(n64, s.tree_size);
   n64++;
   EXPECT_EQ(n32, s.data_block_size);
   n32++;
   EXPECT_EQ(n32, s.hash_block_size);
   n32++;
   EXPECT_EQ(n32, s.fec_num_roots);
   n32++;
   EXPECT_EQ(n64, s.fec_offset);
   n64++;
   EXPECT_EQ(n64, s.fec_size);
   n64++;

   EXPECT_EQ(AVB_DESCRIPTOR_TAG_HASHTREE, s.parent_descriptor.tag);
   EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
   EXPECT_EQ(10UL, s.partition_name_len);
   EXPECT_EQ(10UL, s.salt_len);
   EXPECT_EQ(10UL, s.root_digest_len);

   // Check for bad tag.
   bad = h;
   bad.parent_descriptor.tag = htobe64(0xf00dd00d);
   EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (30 + 10 + 10 = 50).
   bad = h;
   bad.partition_name_len = htobe32(30);
   EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (10 + 30 + 10 = 50).
   bad = h;
   bad.salt_len = htobe32(30);
   EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (10 + 10 + 30 = 50).
   bad = h;
   bad.root_digest_len = htobe32(30);
   EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, HashDescriptorByteswap) {
   AvbHashDescriptor h;
   AvbHashDescriptor s;
   AvbHashDescriptor bad;
   uint64_t nbf;

   // Specify 44 bytes of data past the end of the descriptor struct.
   nbf = 44 + sizeof(AvbHashDescriptor) - sizeof(AvbDescriptor);
   h.parent_descriptor.num_bytes_following = htobe64(nbf);
   h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_HASH);
   h.partition_name_len = htobe32(10);
   h.salt_len = htobe32(10);
   h.digest_len = htobe32(10);

   EXPECT_NE(0, avb_hash_descriptor_validate_and_byteswap(&h, &s));

   EXPECT_EQ(AVB_DESCRIPTOR_TAG_HASH, s.parent_descriptor.tag);
   EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
   EXPECT_EQ(10UL, s.partition_name_len);
   EXPECT_EQ(10UL, s.salt_len);
   EXPECT_EQ(10UL, s.digest_len);

   // Check for bad tag.
   bad = h;
   bad.parent_descriptor.tag = htobe64(0xf00dd00d);
   EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (30 + 10 + 10 = 50).
   bad = h;
   bad.partition_name_len = htobe32(30);
   EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (10 + 30 + 10 = 50).
   bad = h;
   bad.salt_len = htobe32(30);
   EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 44 bytes (10 + 10 + 30 = 50).
   bad = h;
   bad.digest_len = htobe32(30);
   EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, ChainPartitionDescriptorByteswap) {
   AvbChainPartitionDescriptor h;
   AvbChainPartitionDescriptor s;
   AvbChainPartitionDescriptor bad;
   uint64_t nbf;

   // Specify 36 bytes of data past the end of the descriptor struct.
   nbf = 36 + sizeof(AvbChainPartitionDescriptor) - sizeof(AvbDescriptor);
   h.parent_descriptor.num_bytes_following = htobe64(nbf);
   h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_CHAIN_PARTITION);
   h.rollback_index_location = htobe32(42);
   h.partition_name_len = htobe32(16);
   h.public_key_len = htobe32(17);

   EXPECT_NE(0, avb_chain_partition_descriptor_validate_and_byteswap(&h, &s));

   EXPECT_EQ(AVB_DESCRIPTOR_TAG_CHAIN_PARTITION, s.parent_descriptor.tag);
   EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
   EXPECT_EQ(42UL, s.rollback_index_location);
   EXPECT_EQ(16UL, s.partition_name_len);
   EXPECT_EQ(17UL, s.public_key_len);

   // Check for bad tag.
   bad = h;
   bad.parent_descriptor.tag = htobe64(0xf00dd00d);
   EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

   // Check for bad rollback index slot (must be at least 1).
   bad = h;
   bad.rollback_index_location = htobe32(0);
   EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 40 bytes (24 + 17 = 41).
   bad = h;
   bad.partition_name_len = htobe32(24);
   EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 40 bytes (16 + 25 = 41).
   bad = h;
   bad.public_key_len = htobe32(25);
   EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, PropertyDescriptorByteswap) {
   AvbPropertyDescriptor h;
   AvbPropertyDescriptor s;
   AvbPropertyDescriptor bad;
   uint64_t nbf;

   // Specify 40 bytes of data past the end of the descriptor struct.
   nbf = 40 + sizeof(AvbPropertyDescriptor) - sizeof(AvbDescriptor);
   h.parent_descriptor.num_bytes_following = htobe64(nbf);
   h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_PROPERTY);
   h.key_num_bytes = htobe64(16);
   h.value_num_bytes = htobe64(17);

   EXPECT_NE(0, avb_property_descriptor_validate_and_byteswap(&h, &s));

   EXPECT_EQ(AVB_DESCRIPTOR_TAG_PROPERTY, s.parent_descriptor.tag);
   EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
   EXPECT_EQ(16UL, s.key_num_bytes);
   EXPECT_EQ(17UL, s.value_num_bytes);

   // Check for bad tag.
   bad = h;
   bad.parent_descriptor.tag = htobe64(0xf00dd00d);
   EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 40 bytes (22 + 17 + 2 = 41).
   bad = h;
   bad.key_num_bytes = htobe64(22);
   EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));

   // Doesn't fit in 40 bytes (16 + 23 + 2 = 41).
   bad = h;
   bad.value_num_bytes = htobe64(23);
   EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));
 }

 TEST_F(UtilTest, DescriptorByteswap) {
   AvbDescriptor h;
   AvbDescriptor s;
   uint64_t n64;

   n64 = 0x1122334455667788;

   h.num_bytes_following = htobe64(n64);
   n64++;
   h.tag = htobe64(n64);
   n64++;

   EXPECT_NE(0, avb_descriptor_validate_and_byteswap(&h, &s));

   n64 = 0x1122334455667788;

   EXPECT_EQ(n64, s.num_bytes_following);
   n64++;
   EXPECT_EQ(n64, s.tag);
   n64++;

   // Check that we catch if |num_bytes_following| isn't divisble by 8.
   h.num_bytes_following = htobe64(7);
   EXPECT_EQ(0, avb_descriptor_validate_and_byteswap(&h, &s));
 }

 TEST_F(UtilTest, SafeAddition) {
   uint64_t value;
   uint64_t pow2_60 = 1ULL << 60;

   value = 2;
   EXPECT_NE(0, avb_safe_add_to(&value, 5));
   EXPECT_EQ(7UL, value);

   /* These should not overflow */
   value = 1 * pow2_60;
   EXPECT_NE(0, avb_safe_add_to(&value, 2 * pow2_60));
   EXPECT_EQ(3 * pow2_60, value);
   value = 7 * pow2_60;
   EXPECT_NE(0, avb_safe_add_to(&value, 8 * pow2_60));
   EXPECT_EQ(15 * pow2_60, value);
   value = 9 * pow2_60;
   EXPECT_NE(0, avb_safe_add_to(&value, 3 * pow2_60));
   EXPECT_EQ(12 * pow2_60, value);
   value = 0xfffffffffffffffcUL;
   EXPECT_NE(0, avb_safe_add_to(&value, 2));
   EXPECT_EQ(0xfffffffffffffffeUL, value);

   /* These should overflow. */
   value = 8 * pow2_60;
   EXPECT_EQ(0, avb_safe_add_to(&value, 8 * pow2_60));
   value = 0xfffffffffffffffcUL;
   EXPECT_EQ(0, avb_safe_add_to(&value, 4));
 }

 static int avb_validate_utf8z(const char* data) {
   return avb_validate_utf8(reinterpret_cast<const uint8_t*>(data),
                            strlen(data));
 }

 TEST_F(UtilTest, UTF8Validation) {
   // These should succeed.
   EXPECT_NE(0, avb_validate_utf8z("foo bar"));
   // Encoding of U+00E6 LATIN SMALL LETTER AE: æ
   EXPECT_NE(0, avb_validate_utf8z("foo \xC3\xA6 bar"));
   // Encoding of U+20AC EURO SIGN: €
   EXPECT_NE(0, avb_validate_utf8z("foo \xE2\x82\xAC bar"));
   // Encoding of U+1F466 BOY: 👦
   EXPECT_NE(0, avb_validate_utf8z("foo \xF0\x9F\x91\xA6 bar"));
   // All three runes following each other.
   EXPECT_NE(0, avb_validate_utf8z("\xC3\xA6\xE2\x82\xAC\xF0\x9F\x91\xA6"));

   // These should fail.
   EXPECT_EQ(0, avb_validate_utf8z("foo \xF8 bar"));
   EXPECT_EQ(0, avb_validate_utf8z("\xF8"));
   // Stops in the middle of Unicode rune.
   EXPECT_EQ(0, avb_validate_utf8z("foo \xC3"));
 }

 TEST_F(UtilTest, StrConcat) {
   char buf[8];

   // These should succeed.
   EXPECT_NE(0, avb_str_concat(buf, sizeof buf, "foo", 3, "bar1", 4));

   // This should fail: Insufficient space.
   EXPECT_EQ(0, avb_str_concat(buf, sizeof buf, "foo0", 4, "bar1", 4));
 }

 TEST_F(UtilTest, StrStr) {
   const char* haystack = "abc def abcabc";

   EXPECT_EQ(nullptr, avb_strstr(haystack, "needle"));
   EXPECT_EQ(haystack, avb_strstr(haystack, "abc"));
   EXPECT_EQ(haystack + 4, avb_strstr(haystack, "def"));
   EXPECT_EQ(haystack, avb_strstr(haystack, haystack));
 }

 TEST_F(UtilTest, StrvFindStr) {
   const char* strings[] = {"abcabc", "abc", "def", nullptr};

   EXPECT_EQ(nullptr, avb_strv_find_str(strings, "not there", 9));
   EXPECT_EQ(strings[1], avb_strv_find_str(strings, "abc", 3));
   EXPECT_EQ(strings[2], avb_strv_find_str(strings, "def", 3));
   EXPECT_EQ(strings[0], avb_strv_find_str(strings, "abcabc", 6));
 }

 TEST_F(UtilTest, StrReplace) {
   char* str;

   str = avb_replace("$(FOO) blah bah $(FOO $(FOO) blah", "$(FOO)", "OK");
   EXPECT_EQ("OK blah bah $(FOO OK blah", std::string(str));
   avb_free(str);

   str = avb_replace("$(FOO)", "$(FOO)", "OK");
   EXPECT_EQ("OK", std::string(str));
   avb_free(str);

   str = avb_replace(" $(FOO)", "$(FOO)", "OK");
   EXPECT_EQ(" OK", std::string(str));
   avb_free(str);

   str = avb_replace("$(FOO) ", "$(FOO)", "OK");
   EXPECT_EQ("OK ", std::string(str));
   avb_free(str);

   str = avb_replace("$(FOO)$(FOO)", "$(FOO)", "LONGSTRING");
   EXPECT_EQ("LONGSTRINGLONGSTRING", std::string(str));
   avb_free(str);
 }

 TEST_F(UtilTest, StrDupV) {
   char* str;

   str = avb_strdupv("x", "y", "z", NULL);
   EXPECT_EQ("xyz", std::string(str));
   avb_free(str);

   str = avb_strdupv("Hello", "World", " XYZ", NULL);
   EXPECT_EQ("HelloWorld XYZ", std::string(str));
   avb_free(str);
 }

 TEST_F(UtilTest, Crc32) {
   /* Compare with output of crc32(1):
    *
    *  $ (echo -n foobar > /tmp/crc32_input); crc32 /tmp/crc32_input
    *  9ef61f95
    */
   EXPECT_EQ(uint32_t(0x9ef61f95), avb_crc32((const uint8_t*)"foobar", 6));
 }

 TEST_F(UtilTest, htobe32) {
   EXPECT_EQ(avb_htobe32(0x12345678), htobe32(0x12345678));
 }

 TEST_F(UtilTest, be32toh) {
   EXPECT_EQ(avb_be32toh(0x12345678), be32toh(0x12345678));
 }

 TEST_F(UtilTest, htobe64) {
   EXPECT_EQ(avb_htobe64(0x123456789abcdef0), htobe64(0x123456789abcdef0));
 }

 TEST_F(UtilTest, be64toh) {
   EXPECT_EQ(avb_be64toh(0x123456789abcdef0), be64toh(0x123456789abcdef0));
 }

 TEST_F(UtilTest, Basename) {
   EXPECT_EQ("foobar.c", std::string(avb_basename("foobar.c")));
   EXPECT_EQ("foobar.c", std::string(avb_basename("/path/to/foobar.c")));
   EXPECT_EQ("foobar.c", std::string(avb_basename("a/foobar.c")));
   EXPECT_EQ("baz.c", std::string(avb_basename("/baz.c")));
   EXPECT_EQ("some_dir/", std::string(avb_basename("some_dir/")));
   EXPECT_EQ("some_dir/", std::string(avb_basename("/path/to/some_dir/")));
   EXPECT_EQ("some_dir/", std::string(avb_basename("a/some_dir/")));
   EXPECT_EQ("some_dir/", std::string(avb_basename("/some_dir/")));
   EXPECT_EQ("/", std::string(avb_basename("/")));
 }

 TEST_F(UtilTest, Sha256) {
   AvbSHA256Ctx ctx;

   /* Compare with
    *
    * $ echo -n foobar |sha256sum
    * c3ab8ff13720e8ad9047dd39466b3c8974e592c2fa383d4a3960714caef0c4f2 -
    */
   avb_sha256_init(&ctx);
   avb_sha256_update(&ctx, (const uint8_t*)"foobar", 6);
   EXPECT_EQ("c3ab8ff13720e8ad9047dd39466b3c8974e592c2fa383d4a3960714caef0c4f2",
             mem_to_hexstring(avb_sha256_final(&ctx), AVB_SHA256_DIGEST_SIZE));
 }

 // Disabled for now because it takes ~30 seconds to run.
 TEST_F(UtilTest, DISABLED_Sha256Large) {
   AvbSHA256Ctx ctx;

   /* Also check we this works with greater than 4GiB input. Compare with
    *
    * $ dd if=/dev/zero bs=1048576 count=4097 |sha256sum
    * 829816e339ff597ec3ada4c30fc840d3f2298444169d242952a54bcf3fcd7747 -
    */
   const size_t kMebibyte = 1048576;
   uint8_t* megabuf;
   megabuf = new uint8_t[kMebibyte];
   memset((char*)megabuf, '\0', kMebibyte);
   avb_sha256_init(&ctx);
   for (size_t n = 0; n < 4097; n++) {
     avb_sha256_update(&ctx, megabuf, kMebibyte);
   }
   EXPECT_EQ("829816e339ff597ec3ada4c30fc840d3f2298444169d242952a54bcf3fcd7747",
             mem_to_hexstring(avb_sha256_final(&ctx), AVB_SHA256_DIGEST_SIZE));
   delete[] megabuf;
 }

 TEST_F(UtilTest, Sha512) {
   AvbSHA512Ctx ctx;

   /* Compare with
    *
    * $ echo -n foobar |sha512sum
    * 0a50261ebd1a390fed2bf326f2673c145582a6342d523204973d0219337f81616a8069b012587cf5635f6925f1b56c360230c19b273500ee013e030601bf2425
    * -
    */
   avb_sha512_init(&ctx);
   avb_sha512_update(&ctx, (const uint8_t*)"foobar", 6);
   EXPECT_EQ(
       "0a50261ebd1a390fed2bf326f2673c145582a6342d523204973d0219337f81616a8069b0"
       "12587cf5635f6925f1b56c360230c19b273500ee013e030601bf2425",
       mem_to_hexstring(avb_sha512_final(&ctx), AVB_SHA512_DIGEST_SIZE));
 }

 // Disabled for now because it takes ~30 seconds to run.
 TEST_F(UtilTest, DISABLED_Sha512Large) {
   AvbSHA512Ctx ctx;

   /* Also check we this works with greater than 4GiB input. Compare with
    *
    * $ dd if=/dev/zero bs=1048576 count=4097 |sha512sum
    * eac1685671cc2060315888746de072398116c0c83b7ee9463f0576e11bfdea9cdd5ddbf291fb3ffc4ee8a1b459c798d9fb9b50b7845e2871c4b1402470aaf4c0
    * -
    */
   const size_t kMebibyte = 1048576;
   uint8_t* megabuf;
   megabuf = new uint8_t[kMebibyte];
   memset((char*)megabuf, '\0', kMebibyte);
   avb_sha512_init(&ctx);
   for (size_t n = 0; n < 4097; n++) {
     avb_sha512_update(&ctx, megabuf, kMebibyte);
   }
   EXPECT_EQ(
       "eac1685671cc2060315888746de072398116c0c83b7ee9463f0576e11bfdea9cdd5ddbf2"
       "91fb3ffc4ee8a1b459c798d9fb9b50b7845e2871c4b1402470aaf4c0",
       mem_to_hexstring(avb_sha512_final(&ctx), AVB_SHA512_DIGEST_SIZE));
   delete[] megabuf;
 }

 }  // namespace avb
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Permission is hereby granted, free of charge, to any person
	* obtaining a copy of this software and associated documentation
	* files (the "Software"), to deal in the Software without
	* restriction, including without limitation the rights to use, copy,
	* modify, merge, publish, distribute, sublicense, and/or sell copies
	* of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be
	* included in all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
	* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
	* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
	* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
	* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
	* SOFTWARE.
	*/

	#include <endian.h>
	#include <string.h>

	#include <gtest/gtest.h>

	#include <libavb/avb_sha.h>
	#include <libavb/libavb.h>

	#include "avb_unittest_util.h"

	namespace avb {

	// Subclass BaseAvbToolTest to check for memory leaks.
	class UtilTest : public BaseAvbToolTest {
	public:
	UtilTest() {}
	};

	TEST_F(UtilTest, RSAPublicKeyHeaderByteswap) {
	AvbRSAPublicKeyHeader h;
	AvbRSAPublicKeyHeader s;
	uint32_t n32;
	uint64_t n64;

	n32 = 0x11223344;
	n64 = 0x1122334455667788;

	h.key_num_bits = htobe32(n32);
	n32++;
	h.n0inv = htobe32(n32);
	n32++;

	EXPECT_NE(0, avb_rsa_public_key_header_validate_and_byteswap(&h, &s));

	n32 = 0x11223344;
	n64 = 0x1122334455667788;

	EXPECT_EQ(n32, s.key_num_bits);
	n32++;
	EXPECT_EQ(n32, s.n0inv);
	n32++;
	}

	TEST_F(UtilTest, FooterByteswap) {
	AvbFooter h;
	AvbFooter s;
	AvbFooter other;
	AvbFooter bad;
	uint64_t n64;

	n64 = 0x1122334455667788;

	memcpy(h.magic, AVB_FOOTER_MAGIC, AVB_FOOTER_MAGIC_LEN);
	h.version_major = htobe32(AVB_FOOTER_VERSION_MAJOR);
	h.version_minor = htobe32(AVB_FOOTER_VERSION_MINOR);
	h.original_image_size = htobe64(n64);
	n64++;
	h.vbmeta_offset = htobe64(n64);
	n64++;
	h.vbmeta_size = htobe64(n64);
	n64++;

	EXPECT_NE(0, avb_footer_validate_and_byteswap(&h, &s));

	n64 = 0x1122334455667788;

	EXPECT_EQ((uint32_t)AVB_FOOTER_VERSION_MAJOR, s.version_major);
	EXPECT_EQ((uint32_t)AVB_FOOTER_VERSION_MINOR, s.version_minor);
	EXPECT_EQ(n64, s.original_image_size);
	n64++;
	EXPECT_EQ(n64, s.vbmeta_offset);
	n64++;
	EXPECT_EQ(n64, s.vbmeta_size);
	n64++;

	// Check that the struct still validates if minor is bigger than
	// what we expect.
	other = h;
	h.version_minor = htobe32(AVB_FOOTER_VERSION_MINOR + 1);
	EXPECT_NE(0, avb_footer_validate_and_byteswap(&other, &s));

	// Check for bad magic.
	bad = h;
	bad.magic[0] = 'x';
	EXPECT_EQ(0, avb_footer_validate_and_byteswap(&bad, &s));

	// Check for bad major version.
	bad = h;
	bad.version_major = htobe32(AVB_FOOTER_VERSION_MAJOR + 1);
	EXPECT_EQ(0, avb_footer_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, KernelCmdlineDescriptorByteswap) {
	AvbKernelCmdlineDescriptor h;
	AvbKernelCmdlineDescriptor s;
	AvbKernelCmdlineDescriptor bad;
	uint64_t nbf;
	uint32_t n32;

	// Specify 40 bytes of data past the end of the descriptor struct.
	nbf = 40 + sizeof(AvbKernelCmdlineDescriptor) - sizeof(AvbDescriptor);
	h.parent_descriptor.num_bytes_following = htobe64(nbf);
	h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_KERNEL_CMDLINE);
	h.kernel_cmdline_length = htobe32(40);

	n32 = 0x11223344;
	h.flags = htobe32(n32);
	n32++;

	EXPECT_NE(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&h, &s));

	n32 = 0x11223344;
	EXPECT_EQ(n32, s.flags);
	n32++;

	EXPECT_EQ(AVB_DESCRIPTOR_TAG_KERNEL_CMDLINE, s.parent_descriptor.tag);
	EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
	EXPECT_EQ(40UL, s.kernel_cmdline_length);

	// Check for bad tag.
	bad = h;
	bad.parent_descriptor.tag = htobe64(0xf00dd00d);
	EXPECT_EQ(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 41 bytes.
	bad = h;
	bad.kernel_cmdline_length = htobe32(41);
	EXPECT_EQ(0, avb_kernel_cmdline_descriptor_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, HashtreeDescriptorByteswap) {
	AvbHashtreeDescriptor h;
	AvbHashtreeDescriptor s;
	AvbHashtreeDescriptor bad;
	uint64_t nbf;
	uint32_t n32;
	uint64_t n64;

	// Specify 44 bytes of data past the end of the descriptor struct.
	nbf = 44 + sizeof(AvbHashtreeDescriptor) - sizeof(AvbDescriptor);
	h.parent_descriptor.num_bytes_following = htobe64(nbf);
	h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_HASHTREE);
	h.partition_name_len = htobe32(10);
	h.salt_len = htobe32(10);
	h.root_digest_len = htobe32(10);

	n32 = 0x11223344;
	n64 = 0x1122334455667788;

	h.dm_verity_version = htobe32(n32);
	n32++;
	h.image_size = htobe64(n64);
	n64++;
	h.tree_offset = htobe64(n64);
	n64++;
	h.tree_size = htobe64(n64);
	n64++;
	h.data_block_size = htobe32(n32);
	n32++;
	h.hash_block_size = htobe32(n32);
	n32++;
	h.fec_num_roots = htobe32(n32);
	n32++;
	h.fec_offset = htobe64(n64);
	n64++;
	h.fec_size = htobe64(n64);
	n64++;

	EXPECT_TRUE(avb_hashtree_descriptor_validate_and_byteswap(&h, &s));

	n32 = 0x11223344;
	n64 = 0x1122334455667788;

	EXPECT_EQ(n32, s.dm_verity_version);
	n32++;
	EXPECT_EQ(n64, s.image_size);
	n64++;
	EXPECT_EQ(n64, s.tree_offset);
	n64++;
	EXPECT_EQ(n64, s.tree_size);
	n64++;
	EXPECT_EQ(n32, s.data_block_size);
	n32++;
	EXPECT_EQ(n32, s.hash_block_size);
	n32++;
	EXPECT_EQ(n32, s.fec_num_roots);
	n32++;
	EXPECT_EQ(n64, s.fec_offset);
	n64++;
	EXPECT_EQ(n64, s.fec_size);
	n64++;

	EXPECT_EQ(AVB_DESCRIPTOR_TAG_HASHTREE, s.parent_descriptor.tag);
	EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
	EXPECT_EQ(10UL, s.partition_name_len);
	EXPECT_EQ(10UL, s.salt_len);
	EXPECT_EQ(10UL, s.root_digest_len);

	// Check for bad tag.
	bad = h;
	bad.parent_descriptor.tag = htobe64(0xf00dd00d);
	EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (30 + 10 + 10 = 50).
	bad = h;
	bad.partition_name_len = htobe32(30);
	EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (10 + 30 + 10 = 50).
	bad = h;
	bad.salt_len = htobe32(30);
	EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (10 + 10 + 30 = 50).
	bad = h;
	bad.root_digest_len = htobe32(30);
	EXPECT_FALSE(avb_hashtree_descriptor_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, HashDescriptorByteswap) {
	AvbHashDescriptor h;
	AvbHashDescriptor s;
	AvbHashDescriptor bad;
	uint64_t nbf;

	// Specify 44 bytes of data past the end of the descriptor struct.
	nbf = 44 + sizeof(AvbHashDescriptor) - sizeof(AvbDescriptor);
	h.parent_descriptor.num_bytes_following = htobe64(nbf);
	h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_HASH);
	h.partition_name_len = htobe32(10);
	h.salt_len = htobe32(10);
	h.digest_len = htobe32(10);

	EXPECT_NE(0, avb_hash_descriptor_validate_and_byteswap(&h, &s));

	EXPECT_EQ(AVB_DESCRIPTOR_TAG_HASH, s.parent_descriptor.tag);
	EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
	EXPECT_EQ(10UL, s.partition_name_len);
	EXPECT_EQ(10UL, s.salt_len);
	EXPECT_EQ(10UL, s.digest_len);

	// Check for bad tag.
	bad = h;
	bad.parent_descriptor.tag = htobe64(0xf00dd00d);
	EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (30 + 10 + 10 = 50).
	bad = h;
	bad.partition_name_len = htobe32(30);
	EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (10 + 30 + 10 = 50).
	bad = h;
	bad.salt_len = htobe32(30);
	EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 44 bytes (10 + 10 + 30 = 50).
	bad = h;
	bad.digest_len = htobe32(30);
	EXPECT_EQ(0, avb_hash_descriptor_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, ChainPartitionDescriptorByteswap) {
	AvbChainPartitionDescriptor h;
	AvbChainPartitionDescriptor s;
	AvbChainPartitionDescriptor bad;
	uint64_t nbf;

	// Specify 36 bytes of data past the end of the descriptor struct.
	nbf = 36 + sizeof(AvbChainPartitionDescriptor) - sizeof(AvbDescriptor);
	h.parent_descriptor.num_bytes_following = htobe64(nbf);
	h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_CHAIN_PARTITION);
	h.rollback_index_location = htobe32(42);
	h.partition_name_len = htobe32(16);
	h.public_key_len = htobe32(17);

	EXPECT_NE(0, avb_chain_partition_descriptor_validate_and_byteswap(&h, &s));

	EXPECT_EQ(AVB_DESCRIPTOR_TAG_CHAIN_PARTITION, s.parent_descriptor.tag);
	EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
	EXPECT_EQ(42UL, s.rollback_index_location);
	EXPECT_EQ(16UL, s.partition_name_len);
	EXPECT_EQ(17UL, s.public_key_len);

	// Check for bad tag.
	bad = h;
	bad.parent_descriptor.tag = htobe64(0xf00dd00d);
	EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

	// Check for bad rollback index slot (must be at least 1).
	bad = h;
	bad.rollback_index_location = htobe32(0);
	EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 40 bytes (24 + 17 = 41).
	bad = h;
	bad.partition_name_len = htobe32(24);
	EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 40 bytes (16 + 25 = 41).
	bad = h;
	bad.public_key_len = htobe32(25);
	EXPECT_EQ(0, avb_chain_partition_descriptor_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, PropertyDescriptorByteswap) {
	AvbPropertyDescriptor h;
	AvbPropertyDescriptor s;
	AvbPropertyDescriptor bad;
	uint64_t nbf;

	// Specify 40 bytes of data past the end of the descriptor struct.
	nbf = 40 + sizeof(AvbPropertyDescriptor) - sizeof(AvbDescriptor);
	h.parent_descriptor.num_bytes_following = htobe64(nbf);
	h.parent_descriptor.tag = htobe64(AVB_DESCRIPTOR_TAG_PROPERTY);
	h.key_num_bytes = htobe64(16);
	h.value_num_bytes = htobe64(17);

	EXPECT_NE(0, avb_property_descriptor_validate_and_byteswap(&h, &s));

	EXPECT_EQ(AVB_DESCRIPTOR_TAG_PROPERTY, s.parent_descriptor.tag);
	EXPECT_EQ(nbf, s.parent_descriptor.num_bytes_following);
	EXPECT_EQ(16UL, s.key_num_bytes);
	EXPECT_EQ(17UL, s.value_num_bytes);

	// Check for bad tag.
	bad = h;
	bad.parent_descriptor.tag = htobe64(0xf00dd00d);
	EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 40 bytes (22 + 17 + 2 = 41).
	bad = h;
	bad.key_num_bytes = htobe64(22);
	EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));

	// Doesn't fit in 40 bytes (16 + 23 + 2 = 41).
	bad = h;
	bad.value_num_bytes = htobe64(23);
	EXPECT_EQ(0, avb_property_descriptor_validate_and_byteswap(&bad, &s));
	}

	TEST_F(UtilTest, DescriptorByteswap) {
	AvbDescriptor h;
	AvbDescriptor s;
	uint64_t n64;

	n64 = 0x1122334455667788;

	h.num_bytes_following = htobe64(n64);
	n64++;
	h.tag = htobe64(n64);
	n64++;

	EXPECT_NE(0, avb_descriptor_validate_and_byteswap(&h, &s));

	n64 = 0x1122334455667788;

	EXPECT_EQ(n64, s.num_bytes_following);
	n64++;
	EXPECT_EQ(n64, s.tag);
	n64++;

	// Check that we catch if \|num_bytes_following\| isn't divisble by 8.
	h.num_bytes_following = htobe64(7);
	EXPECT_EQ(0, avb_descriptor_validate_and_byteswap(&h, &s));
	}

	TEST_F(UtilTest, SafeAddition) {
	uint64_t value;
	uint64_t pow2_60 = 1ULL << 60;

	value = 2;
	EXPECT_NE(0, avb_safe_add_to(&value, 5));
	EXPECT_EQ(7UL, value);

	/* These should not overflow */
	value = 1 * pow2_60;
	EXPECT_NE(0, avb_safe_add_to(&value, 2 * pow2_60));
	EXPECT_EQ(3 * pow2_60, value);
	value = 7 * pow2_60;
	EXPECT_NE(0, avb_safe_add_to(&value, 8 * pow2_60));
	EXPECT_EQ(15 * pow2_60, value);
	value = 9 * pow2_60;
	EXPECT_NE(0, avb_safe_add_to(&value, 3 * pow2_60));
	EXPECT_EQ(12 * pow2_60, value);
	value = 0xfffffffffffffffcUL;
	EXPECT_NE(0, avb_safe_add_to(&value, 2));
	EXPECT_EQ(0xfffffffffffffffeUL, value);

	/* These should overflow. */
	value = 8 * pow2_60;
	EXPECT_EQ(0, avb_safe_add_to(&value, 8 * pow2_60));
	value = 0xfffffffffffffffcUL;
	EXPECT_EQ(0, avb_safe_add_to(&value, 4));
	}

	static int avb_validate_utf8z(const char* data) {
	return avb_validate_utf8(reinterpret_cast<const uint8_t*>(data),
	strlen(data));
	}

	TEST_F(UtilTest, UTF8Validation) {
	// These should succeed.
	EXPECT_NE(0, avb_validate_utf8z("foo bar"));
	// Encoding of U+00E6 LATIN SMALL LETTER AE: æ
	EXPECT_NE(0, avb_validate_utf8z("foo \xC3\xA6 bar"));
	// Encoding of U+20AC EURO SIGN: €
	EXPECT_NE(0, avb_validate_utf8z("foo \xE2\x82\xAC bar"));
	// Encoding of U+1F466 BOY: 👦
	EXPECT_NE(0, avb_validate_utf8z("foo \xF0\x9F\x91\xA6 bar"));
	// All three runes following each other.
	EXPECT_NE(0, avb_validate_utf8z("\xC3\xA6\xE2\x82\xAC\xF0\x9F\x91\xA6"));

	// These should fail.
	EXPECT_EQ(0, avb_validate_utf8z("foo \xF8 bar"));
	EXPECT_EQ(0, avb_validate_utf8z("\xF8"));
	// Stops in the middle of Unicode rune.
	EXPECT_EQ(0, avb_validate_utf8z("foo \xC3"));
	}

	TEST_F(UtilTest, StrConcat) {
	char buf[8];

	// These should succeed.
	EXPECT_NE(0, avb_str_concat(buf, sizeof buf, "foo", 3, "bar1", 4));

	// This should fail: Insufficient space.
	EXPECT_EQ(0, avb_str_concat(buf, sizeof buf, "foo0", 4, "bar1", 4));
	}

	TEST_F(UtilTest, StrStr) {
	const char* haystack = "abc def abcabc";

	EXPECT_EQ(nullptr, avb_strstr(haystack, "needle"));
	EXPECT_EQ(haystack, avb_strstr(haystack, "abc"));
	EXPECT_EQ(haystack + 4, avb_strstr(haystack, "def"));
	EXPECT_EQ(haystack, avb_strstr(haystack, haystack));
	}

	TEST_F(UtilTest, StrvFindStr) {
	const char* strings[] = {"abcabc", "abc", "def", nullptr};

	EXPECT_EQ(nullptr, avb_strv_find_str(strings, "not there", 9));
	EXPECT_EQ(strings[1], avb_strv_find_str(strings, "abc", 3));
	EXPECT_EQ(strings[2], avb_strv_find_str(strings, "def", 3));
	EXPECT_EQ(strings[0], avb_strv_find_str(strings, "abcabc", 6));
	}

	TEST_F(UtilTest, StrReplace) {
	char* str;

	str = avb_replace("$(FOO) blah bah $(FOO $(FOO) blah", "$(FOO)", "OK");
	EXPECT_EQ("OK blah bah $(FOO OK blah", std::string(str));
	avb_free(str);

	str = avb_replace("$(FOO)", "$(FOO)", "OK");
	EXPECT_EQ("OK", std::string(str));
	avb_free(str);

	str = avb_replace(" $(FOO)", "$(FOO)", "OK");
	EXPECT_EQ(" OK", std::string(str));
	avb_free(str);

	str = avb_replace("$(FOO) ", "$(FOO)", "OK");
	EXPECT_EQ("OK ", std::string(str));
	avb_free(str);

	str = avb_replace("$(FOO)$(FOO)", "$(FOO)", "LONGSTRING");
	EXPECT_EQ("LONGSTRINGLONGSTRING", std::string(str));
	avb_free(str);
	}

	TEST_F(UtilTest, StrDupV) {
	char* str;

	str = avb_strdupv("x", "y", "z", NULL);
	EXPECT_EQ("xyz", std::string(str));
	avb_free(str);

	str = avb_strdupv("Hello", "World", " XYZ", NULL);
	EXPECT_EQ("HelloWorld XYZ", std::string(str));
	avb_free(str);
	}

	TEST_F(UtilTest, Crc32) {
	/* Compare with output of crc32(1):
	*
	* $ (echo -n foobar > /tmp/crc32_input); crc32 /tmp/crc32_input
	* 9ef61f95
	*/
	EXPECT_EQ(uint32_t(0x9ef61f95), avb_crc32((const uint8_t*)"foobar", 6));
	}

	TEST_F(UtilTest, htobe32) {
	EXPECT_EQ(avb_htobe32(0x12345678), htobe32(0x12345678));
	}

	TEST_F(UtilTest, be32toh) {
	EXPECT_EQ(avb_be32toh(0x12345678), be32toh(0x12345678));
	}

	TEST_F(UtilTest, htobe64) {
	EXPECT_EQ(avb_htobe64(0x123456789abcdef0), htobe64(0x123456789abcdef0));
	}

	TEST_F(UtilTest, be64toh) {
	EXPECT_EQ(avb_be64toh(0x123456789abcdef0), be64toh(0x123456789abcdef0));
	}

	TEST_F(UtilTest, Basename) {
	EXPECT_EQ("foobar.c", std::string(avb_basename("foobar.c")));
	EXPECT_EQ("foobar.c", std::string(avb_basename("/path/to/foobar.c")));
	EXPECT_EQ("foobar.c", std::string(avb_basename("a/foobar.c")));
	EXPECT_EQ("baz.c", std::string(avb_basename("/baz.c")));
	EXPECT_EQ("some_dir/", std::string(avb_basename("some_dir/")));
	EXPECT_EQ("some_dir/", std::string(avb_basename("/path/to/some_dir/")));
	EXPECT_EQ("some_dir/", std::string(avb_basename("a/some_dir/")));
	EXPECT_EQ("some_dir/", std::string(avb_basename("/some_dir/")));
	EXPECT_EQ("/", std::string(avb_basename("/")));
	}

	TEST_F(UtilTest, Sha256) {
	AvbSHA256Ctx ctx;

	/* Compare with
	*
	* $ echo -n foobar \|sha256sum
	* c3ab8ff13720e8ad9047dd39466b3c8974e592c2fa383d4a3960714caef0c4f2 -
	*/
	avb_sha256_init(&ctx);
	avb_sha256_update(&ctx, (const uint8_t*)"foobar", 6);
	EXPECT_EQ("c3ab8ff13720e8ad9047dd39466b3c8974e592c2fa383d4a3960714caef0c4f2",
	mem_to_hexstring(avb_sha256_final(&ctx), AVB_SHA256_DIGEST_SIZE));
	}

	// Disabled for now because it takes ~30 seconds to run.
	TEST_F(UtilTest, DISABLED_Sha256Large) {
	AvbSHA256Ctx ctx;

	/* Also check we this works with greater than 4GiB input. Compare with
	*
	* $ dd if=/dev/zero bs=1048576 count=4097 \|sha256sum
	* 829816e339ff597ec3ada4c30fc840d3f2298444169d242952a54bcf3fcd7747 -
	*/
	const size_t kMebibyte = 1048576;
	uint8_t* megabuf;
	megabuf = new uint8_t[kMebibyte];
	memset((char*)megabuf, '\0', kMebibyte);
	avb_sha256_init(&ctx);
	for (size_t n = 0; n < 4097; n++) {
	avb_sha256_update(&ctx, megabuf, kMebibyte);
	}
	EXPECT_EQ("829816e339ff597ec3ada4c30fc840d3f2298444169d242952a54bcf3fcd7747",
	mem_to_hexstring(avb_sha256_final(&ctx), AVB_SHA256_DIGEST_SIZE));
	delete[] megabuf;
	}

	TEST_F(UtilTest, Sha512) {
	AvbSHA512Ctx ctx;

	/* Compare with
	*
	* $ echo -n foobar \|sha512sum
	* 0a50261ebd1a390fed2bf326f2673c145582a6342d523204973d0219337f81616a8069b012587cf5635f6925f1b56c360230c19b273500ee013e030601bf2425
	* -
	*/
	avb_sha512_init(&ctx);
	avb_sha512_update(&ctx, (const uint8_t*)"foobar", 6);
	EXPECT_EQ(
	"0a50261ebd1a390fed2bf326f2673c145582a6342d523204973d0219337f81616a8069b0"
	"12587cf5635f6925f1b56c360230c19b273500ee013e030601bf2425",
	mem_to_hexstring(avb_sha512_final(&ctx), AVB_SHA512_DIGEST_SIZE));
	}

	// Disabled for now because it takes ~30 seconds to run.
	TEST_F(UtilTest, DISABLED_Sha512Large) {
	AvbSHA512Ctx ctx;

	/* Also check we this works with greater than 4GiB input. Compare with
	*
	* $ dd if=/dev/zero bs=1048576 count=4097 \|sha512sum
	* eac1685671cc2060315888746de072398116c0c83b7ee9463f0576e11bfdea9cdd5ddbf291fb3ffc4ee8a1b459c798d9fb9b50b7845e2871c4b1402470aaf4c0
	* -
	*/
	const size_t kMebibyte = 1048576;
	uint8_t* megabuf;
	megabuf = new uint8_t[kMebibyte];
	memset((char*)megabuf, '\0', kMebibyte);
	avb_sha512_init(&ctx);
	for (size_t n = 0; n < 4097; n++) {
	avb_sha512_update(&ctx, megabuf, kMebibyte);
	}
	EXPECT_EQ(
	"eac1685671cc2060315888746de072398116c0c83b7ee9463f0576e11bfdea9cdd5ddbf2"
	"91fb3ffc4ee8a1b459c798d9fb9b50b7845e2871c4b1402470aaf4c0",
	mem_to_hexstring(avb_sha512_final(&ctx), AVB_SHA512_DIGEST_SIZE));
	delete[] megabuf;
	}

	} // namespace avb