/////////////////////////////////////////////////////////////////////////////// // /// \file test_index.c /// \brief Tests functions handling the lzma_index structure /// /// \todo Implement tests for lzma_file_info_decoder // // Authors: Jia Tan // Lasse Collin // // // This file has been put into the public domain. // You can do whatever you want with this file. // /////////////////////////////////////////////////////////////////////////////// #include "tests.h" // liblzma internal header file needed for: // UNPADDED_SIZE_MIN // UNPADDED_SIZE_MAX // vli_ceil4 #include "common/index.h" #define MEMLIMIT (UINT64_C(1) << 20) static uint8_t *decode_buffer; static size_t decode_buffer_size = 0; static lzma_index *decode_test_index; static void test_lzma_index_memusage(void) { // The return value from lzma_index_memusage is an approximation // of the amount of memory needed for lzma_index for a given // amount of Streams and Blocks. It will be an upperbound, // so this test will mostly sanity check and error check the // function. // The maximum number of Streams should be UINT32_MAX in the // current implementation even though the parameter is lzma_vli. assert_uint_eq(lzma_index_memusage((lzma_vli)UINT32_MAX + 1, 1), UINT64_MAX); // While the number of blocks is lzma_vli, the real maximum value is // much smaller than LZMA_VLI_MAX. Just check that it fails with a // huge but valid VLI and that it succeeds with a smaller one. assert_uint_eq(lzma_index_memusage(1, LZMA_VLI_MAX / 5), UINT64_MAX); assert_uint(lzma_index_memusage(1, LZMA_VLI_MAX / 11), <, UINT64_MAX); // Number of Streams must be non-zero assert_uint_eq(lzma_index_memusage(0, 1), UINT64_MAX); // Number of Blocks CAN be zero assert_uint(lzma_index_memusage(1, 0), !=, UINT64_MAX); // Arbitrary values for Stream and Block should work without error // and should always increase uint64_t previous = 1; lzma_vli streams = 1; lzma_vli blocks = 1; // Test 100 different increasing values for Streams and Block for (int i = 0; i < 100; i++) { uint64_t current = lzma_index_memusage(streams, blocks); assert_uint(current, >, previous); previous = current; streams += 29; blocks += 107; } // Force integer overflow in calculation (should result in an error) assert_uint_eq(lzma_index_memusage(UINT32_MAX, LZMA_VLI_MAX), UINT64_MAX); } static void test_lzma_index_memused(void) { // Very similar to test_lzma_index_memusage above since // lzma_index_memused is essentially a wrapper for // lzma_index_memusage lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Test with empty Index assert_uint(lzma_index_memused(idx), <, UINT64_MAX); // Append small Blocks and then test again (should pass). for (lzma_vli i = 0; i < 10; i++) assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_uint(lzma_index_memused(idx), <, UINT64_MAX); lzma_index_end(idx, NULL); } static void test_lzma_index_append(void) { // Basic input-output test done here. // Less trivial tests for this function are done throughout // other tests. // First test with NULL lzma_index assert_lzma_ret(lzma_index_append(NULL, NULL, UNPADDED_SIZE_MIN, 1), LZMA_PROG_ERROR); lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Test with invalid Unpadded Size assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN - 1, 1), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MAX + 1, 1), LZMA_PROG_ERROR); // Test with invalid Uncompressed Size assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MAX, LZMA_VLI_MAX + 1), LZMA_PROG_ERROR); // Test expected successful Block appends assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 2, 2), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 3, 3), LZMA_OK); lzma_index_end(idx, NULL); // Test compressed .xz file size growing too large. This also tests // a failing assert fixed in 68bda971bb8b666a009331455fcedb4e18d837a4. // Should result in LZMA_DATA_ERROR. idx = lzma_index_init(NULL); // The calculation for maximum unpadded size is to make room for the // second stream when lzma_index_cat() is called. The // 4 * LZMA_STREAM_HEADER_SIZE is for the header and footer of // both streams. The extra 24 bytes are for the size of the indexes // for both streams. This allows us to maximize the unpadded sum // during the lzma_index_append() call after the indexes have been // concatenated. assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MAX - ((4 * LZMA_STREAM_HEADER_SIZE) + 24), 1), LZMA_OK); lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_lzma_ret(lzma_index_cat(second, idx, NULL), LZMA_OK); assert_lzma_ret(lzma_index_append(second, NULL, UNPADDED_SIZE_MAX, 1), LZMA_DATA_ERROR); lzma_index_end(second, NULL); // Test uncompressed size growing too large. // Should result in LZMA_DATA_ERROR. idx = lzma_index_init(NULL); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, LZMA_VLI_MAX), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_DATA_ERROR); lzma_index_end(idx, NULL); // Currently not testing for error case when the size of the Index // grows too large to be stored. This was not practical to test for // since too many Blocks needed to be created to cause this. } static void test_lzma_index_stream_flags(void) { // Only trivial tests done here testing for basic functionality. // More in-depth testing for this function will be done in // test_lzma_index_checks. // Testing for NULL inputs assert_lzma_ret(lzma_index_stream_flags(NULL, NULL), LZMA_PROG_ERROR); lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); assert_lzma_ret(lzma_index_stream_flags(idx, NULL), LZMA_PROG_ERROR); lzma_stream_flags stream_flags = { .version = 0, .backward_size = LZMA_BACKWARD_SIZE_MIN, .check = LZMA_CHECK_CRC32 }; assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); lzma_index_end(idx, NULL); } static void test_lzma_index_checks(void) { // Tests should still pass, even if some of the check types // are disabled. lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); lzma_stream_flags stream_flags = { .version = 0, .backward_size = LZMA_BACKWARD_SIZE_MIN, .check = LZMA_CHECK_NONE }; // First set the check type to None assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(idx), UINT32_C(1) << LZMA_CHECK_NONE); // Set the check type to CRC32 and repeat stream_flags.check = LZMA_CHECK_CRC32; assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(idx), UINT32_C(1) << LZMA_CHECK_CRC32); // Set the check type to CRC64 and repeat stream_flags.check = LZMA_CHECK_CRC64; assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(idx), UINT32_C(1) << LZMA_CHECK_CRC64); // Set the check type to SHA256 and repeat stream_flags.check = LZMA_CHECK_SHA256; assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(idx), UINT32_C(1) << LZMA_CHECK_SHA256); // Create second lzma_index and cat to first lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); // Set the check type to CRC32 for the second lzma_index stream_flags.check = LZMA_CHECK_CRC32; assert_lzma_ret(lzma_index_stream_flags(second, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(second), UINT32_C(1) << LZMA_CHECK_CRC32); assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); // Index should now have both CRC32 and SHA256 assert_uint_eq(lzma_index_checks(idx), (UINT32_C(1) << LZMA_CHECK_CRC32) | (UINT32_C(1) << LZMA_CHECK_SHA256)); // Change the check type of the second Stream to SHA256 stream_flags.check = LZMA_CHECK_SHA256; assert_lzma_ret(lzma_index_stream_flags(idx, &stream_flags), LZMA_OK); // Index should now have only SHA256 assert_uint_eq(lzma_index_checks(idx), UINT32_C(1) << LZMA_CHECK_SHA256); // Test with a third Stream lzma_index *third = lzma_index_init(NULL); assert_true(third != NULL); stream_flags.check = LZMA_CHECK_CRC64; assert_lzma_ret(lzma_index_stream_flags(third, &stream_flags), LZMA_OK); assert_uint_eq(lzma_index_checks(third), UINT32_C(1) << LZMA_CHECK_CRC64); assert_lzma_ret(lzma_index_cat(idx, third, NULL), LZMA_OK); // Index should now have CRC64 and SHA256 assert_uint_eq(lzma_index_checks(idx), (UINT32_C(1) << LZMA_CHECK_CRC64) | (UINT32_C(1) << LZMA_CHECK_SHA256)); lzma_index_end(idx, NULL); } static void test_lzma_index_stream_padding(void) { // Test NULL lzma_index assert_lzma_ret(lzma_index_stream_padding(NULL, 0), LZMA_PROG_ERROR); lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Test Stream Padding not a multiple of 4 assert_lzma_ret(lzma_index_stream_padding(idx, 3), LZMA_PROG_ERROR); // Test Stream Padding too large assert_lzma_ret(lzma_index_stream_padding(idx, LZMA_VLI_MAX - 3), LZMA_DATA_ERROR); // Test Stream Padding valid assert_lzma_ret(lzma_index_stream_padding(idx, 0x1000), LZMA_OK); assert_lzma_ret(lzma_index_stream_padding(idx, 4), LZMA_OK); assert_lzma_ret(lzma_index_stream_padding(idx, 0), LZMA_OK); // Test Stream Padding causing the file size to grow too large assert_lzma_ret(lzma_index_append(idx, NULL, LZMA_VLI_MAX - 0x1000, 1), LZMA_OK); assert_lzma_ret(lzma_index_stream_padding(idx, 0x1000), LZMA_DATA_ERROR); lzma_index_end(idx, NULL); } static void test_lzma_index_stream_count(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); assert_uint_eq(lzma_index_stream_count(idx), 1); // Appending Blocks should not change the Stream count value assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_uint_eq(lzma_index_stream_count(idx), 1); // Test with multiple Streams for (uint32_t i = 0; i < 100; i++) { lzma_index *idx_cat = lzma_index_init(NULL); assert_true(idx != NULL); assert_lzma_ret(lzma_index_cat(idx, idx_cat, NULL), LZMA_OK); assert_uint_eq(lzma_index_stream_count(idx), i + 2); } lzma_index_end(idx, NULL); } static void test_lzma_index_block_count(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); assert_uint_eq(lzma_index_block_count(idx), 0); const uint32_t iterations = 0x1000; for (uint32_t i = 0; i < iterations; i++) { assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_uint_eq(lzma_index_block_count(idx), i + 1); } // Create new lzma_index with a few Blocks lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_lzma_ret(lzma_index_append(second, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(second, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(second, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_uint_eq(lzma_index_block_count(second), 3); // Concatenate the lzma_indexes together and the result should have // the sum of the two individual counts. assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); assert_uint_eq(lzma_index_block_count(idx), iterations + 3); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_uint_eq(lzma_index_block_count(idx), iterations + 4); lzma_index_end(idx, NULL); } static void test_lzma_index_size(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Base size should be: // 1 byte Index Indicator // 1 byte Number of Records // 0 bytes Records // 2 bytes Index Padding // 4 bytes CRC32 // Total: 8 bytes assert_uint_eq(lzma_index_size(idx), 8); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); // New size should be: // 1 byte Index Indicator // 1 byte Number of Records // 2 bytes Records // 0 bytes Index Padding // 4 bytes CRC32 // Total: 8 bytes assert_uint_eq(lzma_index_size(idx), 8); assert_lzma_ret(lzma_index_append(idx, NULL, LZMA_VLI_MAX / 4, LZMA_VLI_MAX / 4), LZMA_OK); // New size should be: // 1 byte Index Indicator // 1 byte Number of Records // 20 bytes Records // 2 bytes Index Padding // 4 bytes CRC32 // Total: 28 bytes assert_uint_eq(lzma_index_size(idx), 28); lzma_index_end(idx, NULL); } static void test_lzma_index_stream_size(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Stream size calculated by: // Size of Stream Header (12 bytes) // Size of all Blocks // Size of the Index // Size of the Stream Footer (12 bytes) // First test with empty Index // Stream size should be: // Size of Stream Header - 12 bytes // Size of all Blocks - 0 bytes // Size of Index - 8 bytes // Size of Stream Footer - 12 bytes // Total: 32 bytes assert_uint_eq(lzma_index_stream_size(idx), 32); // Next, append a few Blocks and retest assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 999, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 997, 1), LZMA_OK); // Stream size should be: // Size of Stream Header - 12 bytes // Size of all Blocks - 3000 bytes [*] // Size of Index - 16 bytes // Size of Stream Footer - 12 bytes // Total: 3040 bytes // // [*] Block size is a multiple of 4 bytes so 999 and 997 get // rounded up to 1000 bytes. assert_uint_eq(lzma_index_stream_size(idx), 3040); lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_uint_eq(lzma_index_stream_size(second), 32); assert_lzma_ret(lzma_index_append(second, NULL, 1000, 1), LZMA_OK); // Stream size should be: // Size of Stream Header - 12 bytes // Size of all Blocks - 1000 bytes // Size of Index - 12 bytes // Size of Stream Footer - 12 bytes // Total: 1036 bytes assert_uint_eq(lzma_index_stream_size(second), 1036); assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); // Stream size should be: // Size of Stream Header - 12 bytes // Size of all Blocks - 4000 bytes // Size of Index - 20 bytes // Size of Stream Footer - 12 bytes // Total: 4044 bytes assert_uint_eq(lzma_index_stream_size(idx), 4044); lzma_index_end(idx, NULL); } static void test_lzma_index_total_size(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // First test empty lzma_index. // Result should be 0 since no Blocks have been added. assert_uint_eq(lzma_index_total_size(idx), 0); // Add a few Blocks and retest after each append assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 1000); assert_lzma_ret(lzma_index_append(idx, NULL, 999, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 2000); assert_lzma_ret(lzma_index_append(idx, NULL, 997, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 3000); // Create second lzma_index and append Blocks to it. lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_uint_eq(lzma_index_total_size(second), 0); assert_lzma_ret(lzma_index_append(second, NULL, 100, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(second), 100); assert_lzma_ret(lzma_index_append(second, NULL, 100, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(second), 200); // Concatenate the Streams together assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); // The resulting total size should be the size of all Blocks // from both Streams assert_uint_eq(lzma_index_total_size(idx), 3200); // Test sizes that aren't multiples of four bytes assert_lzma_ret(lzma_index_append(idx, NULL, 11, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 3212); assert_lzma_ret(lzma_index_append(idx, NULL, 11, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 3224); assert_lzma_ret(lzma_index_append(idx, NULL, 9, 1), LZMA_OK); assert_uint_eq(lzma_index_total_size(idx), 3236); lzma_index_end(idx, NULL); } static void test_lzma_index_file_size(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Should be the same as test_lzma_index_stream_size with // only one Stream and no Stream Padding. assert_uint_eq(lzma_index_file_size(idx), 32); assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 999, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 997, 1), LZMA_OK); assert_uint_eq(lzma_index_file_size(idx), 3040); // Next add Stream Padding assert_lzma_ret(lzma_index_stream_padding(idx, 1000), LZMA_OK); assert_uint_eq(lzma_index_file_size(idx), 4040); // Create second lzma_index. // Very similar to test_lzma_index_stream_size, but // the values should include the headers of the second Stream. lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_lzma_ret(lzma_index_append(second, NULL, 1000, 1), LZMA_OK); assert_uint_eq(lzma_index_stream_size(second), 1036); assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); // .xz file size should be: // Size of 2 Stream Headers - 12 * 2 bytes // Size of all Blocks - 3000 + 1000 bytes // Size of 2 Indexes - 16 + 12 bytes // Size of Stream Padding - 1000 bytes // Size of 2 Stream Footers - 12 * 2 bytes // Total: 5076 bytes assert_uint_eq(lzma_index_file_size(idx), 5076); lzma_index_end(idx, NULL); } static void test_lzma_index_uncompressed_size(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Empty lzma_index should have 0 uncompressed .xz file size. assert_uint_eq(lzma_index_uncompressed_size(idx), 0); // Append a few small Blocks assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 10), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 100), LZMA_OK); assert_uint_eq(lzma_index_uncompressed_size(idx), 111); // Create another lzma_index lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); // Append a few small Blocks assert_lzma_ret(lzma_index_append(second, NULL, 1000, 2), LZMA_OK); assert_lzma_ret(lzma_index_append(second, NULL, 1000, 20), LZMA_OK); assert_lzma_ret(lzma_index_append(second, NULL, 1000, 200), LZMA_OK); assert_uint_eq(lzma_index_uncompressed_size(second), 222); // Concatenate second lzma_index to first assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); // New uncompressed .xz file size should be the sum of the two Streams assert_uint_eq(lzma_index_uncompressed_size(idx), 333); // Append one more Block to the lzma_index and ensure that // it is properly updated assert_lzma_ret(lzma_index_append(idx, NULL, 1000, 111), LZMA_OK); assert_uint_eq(lzma_index_uncompressed_size(idx), 444); lzma_index_end(idx, NULL); } static void test_lzma_index_iter_init(void) { // Testing basic init functionality. // The init function should call rewind on the iterator. lzma_index *first = lzma_index_init(NULL); assert_true(first != NULL); lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); lzma_index *third = lzma_index_init(NULL); assert_true(third != NULL); assert_lzma_ret(lzma_index_cat(first, second, NULL), LZMA_OK); assert_lzma_ret(lzma_index_cat(first, third, NULL), LZMA_OK); lzma_index_iter iter; lzma_index_iter_init(&iter, first); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_uint_eq(iter.stream.number, 1); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_uint_eq(iter.stream.number, 2); lzma_index_iter_init(&iter, first); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_uint_eq(iter.stream.number, 3); lzma_index_end(first, NULL); } static void test_lzma_index_iter_rewind(void) { lzma_index *first = lzma_index_init(NULL); assert_true(first != NULL); lzma_index_iter iter; lzma_index_iter_init(&iter, first); // Append 3 Blocks and iterate over each. This is to test // the LZMA_INDEX_ITER_BLOCK mode. for (uint32_t i = 0; i < 3; i++) { assert_lzma_ret(lzma_index_append(first, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); assert_uint_eq(iter.block.number_in_file, i + 1); assert_uint_eq(iter.block.number_in_stream, i + 1); } // Rewind back to the beginning and iterate over the Blocks again lzma_index_iter_rewind(&iter); // Should be able to re-iterate over the Blocks again. for (uint32_t i = 0; i < 3; i++) { assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); assert_uint_eq(iter.block.number_in_file, i + 1); assert_uint_eq(iter.block.number_in_stream, i + 1); } // Next concatenate two more lzma_indexes, iterate over them, // rewind, and iterate over them again. This is to test // the LZMA_INDEX_ITER_STREAM mode. lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); lzma_index *third = lzma_index_init(NULL); assert_true(third != NULL); assert_lzma_ret(lzma_index_cat(first, second, NULL), LZMA_OK); assert_lzma_ret(lzma_index_cat(first, third, NULL), LZMA_OK); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_uint_eq(iter.stream.number, 3); lzma_index_iter_rewind(&iter); for (uint32_t i = 0; i < 3; i++) { assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); assert_uint_eq(iter.stream.number, i + 1); } lzma_index_end(first, NULL); } static void test_lzma_index_iter_next(void) { lzma_index *first = lzma_index_init(NULL); assert_true(first != NULL); lzma_index_iter iter; lzma_index_iter_init(&iter, first); // First test bad mode values for (uint32_t i = LZMA_INDEX_ITER_NONEMPTY_BLOCK + 1; i < 100; i++) assert_true(lzma_index_iter_next(&iter, i)); // Test iterating over Blocks assert_lzma_ret(lzma_index_append(first, NULL, UNPADDED_SIZE_MIN, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(first, NULL, UNPADDED_SIZE_MIN * 2, 10), LZMA_OK); assert_lzma_ret(lzma_index_append(first, NULL, UNPADDED_SIZE_MIN * 3, 100), LZMA_OK); // For Blocks, need to verify: // - number_in_file (overall Block number) // - compressed_file_offset // - uncompressed_file_offset // - number_in_stream (Block number relative to current Stream) // - compressed_stream_offset // - uncompressed_stream_offset // - uncompressed_size // - unpadded_size // - total_size assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); // Verify Block data stored correctly assert_uint_eq(iter.block.number_in_file, 1); // Should start right after the Stream Header assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_file_offset, 0); assert_uint_eq(iter.block.number_in_stream, 1); assert_uint_eq(iter.block.compressed_stream_offset, LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_stream_offset, 0); assert_uint_eq(iter.block.unpadded_size, UNPADDED_SIZE_MIN); assert_uint_eq(iter.block.total_size, vli_ceil4(UNPADDED_SIZE_MIN)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); // Verify Block data stored correctly assert_uint_eq(iter.block.number_in_file, 2); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + vli_ceil4(UNPADDED_SIZE_MIN)); assert_uint_eq(iter.block.uncompressed_file_offset, 1); assert_uint_eq(iter.block.number_in_stream, 2); assert_uint_eq(iter.block.compressed_stream_offset, LZMA_STREAM_HEADER_SIZE + vli_ceil4(UNPADDED_SIZE_MIN)); assert_uint_eq(iter.block.uncompressed_stream_offset, 1); assert_uint_eq(iter.block.unpadded_size, UNPADDED_SIZE_MIN * 2); assert_uint_eq(iter.block.total_size, vli_ceil4(UNPADDED_SIZE_MIN * 2)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); // Verify Block data stored correctly assert_uint_eq(iter.block.number_in_file, 3); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + vli_ceil4(UNPADDED_SIZE_MIN) + vli_ceil4(UNPADDED_SIZE_MIN * 2)); assert_uint_eq(iter.block.uncompressed_file_offset, 11); assert_uint_eq(iter.block.number_in_stream, 3); assert_uint_eq(iter.block.compressed_stream_offset, LZMA_STREAM_HEADER_SIZE + vli_ceil4(UNPADDED_SIZE_MIN) + vli_ceil4(UNPADDED_SIZE_MIN * 2)); assert_uint_eq(iter.block.uncompressed_stream_offset, 11); assert_uint_eq(iter.block.unpadded_size, UNPADDED_SIZE_MIN * 3); assert_uint_eq(iter.block.total_size, vli_ceil4(UNPADDED_SIZE_MIN * 3)); // Only three Blocks were added, so this should return true assert_true(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); const lzma_vli second_stream_compressed_start = LZMA_STREAM_HEADER_SIZE * 2 + vli_ceil4(UNPADDED_SIZE_MIN) + vli_ceil4(UNPADDED_SIZE_MIN * 2) + vli_ceil4(UNPADDED_SIZE_MIN * 3) + lzma_index_size(first); const lzma_vli second_stream_uncompressed_start = 1 + 10 + 100; // Test iterating over Streams. // The second Stream will have 0 Blocks lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); // Set Stream Flags for Stream 2 lzma_stream_flags flags = { .version = 0, .backward_size = LZMA_BACKWARD_SIZE_MIN, .check = LZMA_CHECK_CRC32 }; assert_lzma_ret(lzma_index_stream_flags(second, &flags), LZMA_OK); // The Second stream will have 8 bytes of Stream Padding assert_lzma_ret(lzma_index_stream_padding(second, 8), LZMA_OK); const lzma_vli second_stream_index_size = lzma_index_size(second); // The third Stream will have 2 Blocks lzma_index *third = lzma_index_init(NULL); assert_true(third != NULL); assert_lzma_ret(lzma_index_append(third, NULL, 32, 20), LZMA_OK); assert_lzma_ret(lzma_index_append(third, NULL, 64, 40), LZMA_OK); const lzma_vli third_stream_index_size = lzma_index_size(third); assert_lzma_ret(lzma_index_cat(first, second, NULL), LZMA_OK); assert_lzma_ret(lzma_index_cat(first, third, NULL), LZMA_OK); // For Streams, need to verify: // - flags (Stream Flags) // - number (Stream count) // - block_count // - compressed_offset // - uncompressed_offset // - compressed_size // - uncompressed_size // - padding (Stream Padding) assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); // Verify Stream assert_uint_eq(iter.stream.flags->backward_size, LZMA_BACKWARD_SIZE_MIN); assert_uint_eq(iter.stream.flags->check, LZMA_CHECK_CRC32); assert_uint_eq(iter.stream.number, 2); assert_uint_eq(iter.stream.block_count, 0); assert_uint_eq(iter.stream.compressed_offset, second_stream_compressed_start); assert_uint_eq(iter.stream.uncompressed_offset, second_stream_uncompressed_start); assert_uint_eq(iter.stream.compressed_size, LZMA_STREAM_HEADER_SIZE * 2 + second_stream_index_size); assert_uint_eq(iter.stream.uncompressed_size, 0); assert_uint_eq(iter.stream.padding, 8); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); // Verify Stream const lzma_vli third_stream_compressed_start = second_stream_compressed_start + LZMA_STREAM_HEADER_SIZE * 2 + 8 + // Stream padding second_stream_index_size; const lzma_vli third_stream_uncompressed_start = second_stream_uncompressed_start; assert_uint_eq(iter.stream.number, 3); assert_uint_eq(iter.stream.block_count, 2); assert_uint_eq(iter.stream.compressed_offset, third_stream_compressed_start); assert_uint_eq(iter.stream.uncompressed_offset, third_stream_uncompressed_start); assert_uint_eq(iter.stream.compressed_size, LZMA_STREAM_HEADER_SIZE * 2 + 96 + // Total compressed size third_stream_index_size); assert_uint_eq(iter.stream.uncompressed_size, 60); assert_uint_eq(iter.stream.padding, 0); assert_true(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)); // Even after a failing call to next with ITER_STREAM mode, // should still be able to iterate over the 2 Blocks in // Stream 3. assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); // Verify both Blocks // Next call to iterate Block should return true because the // first Block can already be read from the LZMA_INDEX_ITER_STREAM // call. assert_true(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); // Rewind to test LZMA_INDEX_ITER_ANY lzma_index_iter_rewind(&iter); // Iterate past the first three Blocks assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); // Iterate past the next Stream assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); // Iterate past the next Stream assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); // Last call should fail assert_true(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); // Rewind to test LZMA_INDEX_ITER_NONEMPTY_BLOCK lzma_index_iter_rewind(&iter); // Iterate past the first three Blocks assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_NONEMPTY_BLOCK)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_NONEMPTY_BLOCK)); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_NONEMPTY_BLOCK)); // Skip past the next Stream which has no Blocks. // We will get to the first Block of the third Stream. assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_NONEMPTY_BLOCK)); // Iterate past the second (the last) Block in the third Stream assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_NONEMPTY_BLOCK)); // Last call should fail since there is nothing left to iterate over. assert_true(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)); lzma_index_end(first, NULL); } static void test_lzma_index_iter_locate(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); lzma_index_iter iter; lzma_index_iter_init(&iter, idx); // Cannot locate anything from an empty Index. assert_true(lzma_index_iter_locate(&iter, 0)); assert_true(lzma_index_iter_locate(&iter, 555)); // One empty Record: nothing is found since there's no uncompressed // data. assert_lzma_ret(lzma_index_append(idx, NULL, 16, 0), LZMA_OK); assert_true(lzma_index_iter_locate(&iter, 0)); // Non-empty Record and we can find something. assert_lzma_ret(lzma_index_append(idx, NULL, 32, 5), LZMA_OK); assert_false(lzma_index_iter_locate(&iter, 0)); assert_uint_eq(iter.block.total_size, 32); assert_uint_eq(iter.block.uncompressed_size, 5); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16); assert_uint_eq(iter.block.uncompressed_file_offset, 0); // Still cannot find anything past the end. assert_true(lzma_index_iter_locate(&iter, 5)); // Add the third Record. assert_lzma_ret(lzma_index_append(idx, NULL, 40, 11), LZMA_OK); assert_false(lzma_index_iter_locate(&iter, 0)); assert_uint_eq(iter.block.total_size, 32); assert_uint_eq(iter.block.uncompressed_size, 5); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16); assert_uint_eq(iter.block.uncompressed_file_offset, 0); assert_false(lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)); assert_uint_eq(iter.block.total_size, 40); assert_uint_eq(iter.block.uncompressed_size, 11); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16 + 32); assert_uint_eq(iter.block.uncompressed_file_offset, 5); assert_false(lzma_index_iter_locate(&iter, 2)); assert_uint_eq(iter.block.total_size, 32); assert_uint_eq(iter.block.uncompressed_size, 5); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16); assert_uint_eq(iter.block.uncompressed_file_offset, 0); assert_false(lzma_index_iter_locate(&iter, 5)); assert_uint_eq(iter.block.total_size, 40); assert_uint_eq(iter.block.uncompressed_size, 11); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16 + 32); assert_uint_eq(iter.block.uncompressed_file_offset, 5); assert_false(lzma_index_iter_locate(&iter, 5 + 11 - 1)); assert_uint_eq(iter.block.total_size, 40); assert_uint_eq(iter.block.uncompressed_size, 11); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 16 + 32); assert_uint_eq(iter.block.uncompressed_file_offset, 5); assert_true(lzma_index_iter_locate(&iter, 5 + 11)); assert_true(lzma_index_iter_locate(&iter, 5 + 15)); // Large Index lzma_index_end(idx, NULL); idx = lzma_index_init(NULL); assert_true(idx != NULL); lzma_index_iter_init(&iter, idx); for (uint32_t n = 4; n <= 4 * 5555; n += 4) assert_lzma_ret(lzma_index_append(idx, NULL, n + 7, n), LZMA_OK); assert_uint_eq(lzma_index_block_count(idx), 5555); // First Record assert_false(lzma_index_iter_locate(&iter, 0)); assert_uint_eq(iter.block.unpadded_size, 4 + 7); assert_uint_eq(iter.block.total_size, 4 + 8); assert_uint_eq(iter.block.uncompressed_size, 4); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_file_offset, 0); assert_false(lzma_index_iter_locate(&iter, 3)); assert_uint_eq(iter.block.unpadded_size, 4 + 7); assert_uint_eq(iter.block.total_size, 4 + 8); assert_uint_eq(iter.block.uncompressed_size, 4); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_file_offset, 0); // Second Record assert_false(lzma_index_iter_locate(&iter, 4)); assert_uint_eq(iter.block.unpadded_size, 2 * 4 + 7); assert_uint_eq(iter.block.total_size, 2 * 4 + 8); assert_uint_eq(iter.block.uncompressed_size, 2 * 4); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + 4 + 8); assert_uint_eq(iter.block.uncompressed_file_offset, 4); // Last Record assert_false(lzma_index_iter_locate( &iter, lzma_index_uncompressed_size(idx) - 1)); assert_uint_eq(iter.block.unpadded_size, 4 * 5555 + 7); assert_uint_eq(iter.block.total_size, 4 * 5555 + 8); assert_uint_eq(iter.block.uncompressed_size, 4 * 5555); assert_uint_eq(iter.block.compressed_file_offset, lzma_index_total_size(idx) + LZMA_STREAM_HEADER_SIZE - 4 * 5555 - 8); assert_uint_eq(iter.block.uncompressed_file_offset, lzma_index_uncompressed_size(idx) - 4 * 5555); // Allocation chunk boundaries. See INDEX_GROUP_SIZE in // liblzma/common/index.c. const uint32_t group_multiple = 256 * 4; const uint32_t radius = 8; const uint32_t start = group_multiple - radius; lzma_vli ubase = 0; lzma_vli tbase = 0; uint32_t n; for (n = 1; n < start; ++n) { ubase += n * 4; tbase += n * 4 + 8; } while (n < start + 2 * radius) { assert_false(lzma_index_iter_locate(&iter, ubase + n * 4)); assert_uint_eq(iter.block.compressed_file_offset, tbase + n * 4 + 8 + LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_file_offset, ubase + n * 4); tbase += n * 4 + 8; ubase += n * 4; ++n; assert_uint_eq(iter.block.total_size, n * 4 + 8); assert_uint_eq(iter.block.uncompressed_size, n * 4); } // Do it also backwards. while (n > start) { assert_false(lzma_index_iter_locate( &iter, ubase + (n - 1) * 4)); assert_uint_eq(iter.block.total_size, n * 4 + 8); assert_uint_eq(iter.block.uncompressed_size, n * 4); --n; tbase -= n * 4 + 8; ubase -= n * 4; assert_uint_eq(iter.block.compressed_file_offset, tbase + n * 4 + 8 + LZMA_STREAM_HEADER_SIZE); assert_uint_eq(iter.block.uncompressed_file_offset, ubase + n * 4); } // Test locating in concatenated Index. lzma_index_end(idx, NULL); idx = lzma_index_init(NULL); assert_true(idx != NULL); lzma_index_iter_init(&iter, idx); for (n = 0; n < group_multiple; ++n) assert_lzma_ret(lzma_index_append(idx, NULL, 8, 0), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, 16, 1), LZMA_OK); assert_false(lzma_index_iter_locate(&iter, 0)); assert_uint_eq(iter.block.total_size, 16); assert_uint_eq(iter.block.uncompressed_size, 1); assert_uint_eq(iter.block.compressed_file_offset, LZMA_STREAM_HEADER_SIZE + group_multiple * 8); assert_uint_eq(iter.block.uncompressed_file_offset, 0); lzma_index_end(idx, NULL); } static void test_lzma_index_cat(void) { // Most complex tests for this function are done in other tests. // This will mostly test basic functionality. lzma_index *dest = lzma_index_init(NULL); assert_true(dest != NULL); lzma_index *src = lzma_index_init(NULL); assert_true(src != NULL); // First test NULL dest or src assert_lzma_ret(lzma_index_cat(NULL, NULL, NULL), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_cat(dest, NULL, NULL), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_cat(NULL, src, NULL), LZMA_PROG_ERROR); // Check for uncompressed size overflow assert_lzma_ret(lzma_index_append(dest, NULL, (UNPADDED_SIZE_MAX / 2) + 1, 1), LZMA_OK); assert_lzma_ret(lzma_index_append(src, NULL, (UNPADDED_SIZE_MAX / 2) + 1, 1), LZMA_OK); assert_lzma_ret(lzma_index_cat(dest, src, NULL), LZMA_DATA_ERROR); // Check for compressed size overflow lzma_index_end(src, NULL); lzma_index_end(dest, NULL); dest = lzma_index_init(NULL); assert_true(dest != NULL); src = lzma_index_init(NULL); assert_true(src != NULL); assert_lzma_ret(lzma_index_append(dest, NULL, UNPADDED_SIZE_MIN, (LZMA_VLI_MAX / 2) + 1), LZMA_OK); assert_lzma_ret(lzma_index_append(src, NULL, UNPADDED_SIZE_MIN, (LZMA_VLI_MAX / 2) + 1), LZMA_OK); assert_lzma_ret(lzma_index_cat(dest, src, NULL), LZMA_DATA_ERROR); lzma_index_end(dest, NULL); lzma_index_end(src, NULL); } // Helper function for test_lzma_index_dup(). static bool index_is_equal(const lzma_index *a, const lzma_index *b) { // Compare only the Stream and Block sizes and offsets. lzma_index_iter ra, rb; lzma_index_iter_init(&ra, a); lzma_index_iter_init(&rb, b); while (true) { bool reta = lzma_index_iter_next(&ra, LZMA_INDEX_ITER_ANY); bool retb = lzma_index_iter_next(&rb, LZMA_INDEX_ITER_ANY); // If both iterators finish at the same time, then the Indexes // are identical. if (reta) return retb; if (ra.stream.number != rb.stream.number || ra.stream.block_count != rb.stream.block_count || ra.stream.compressed_offset != rb.stream.compressed_offset || ra.stream.uncompressed_offset != rb.stream.uncompressed_offset || ra.stream.compressed_size != rb.stream.compressed_size || ra.stream.uncompressed_size != rb.stream.uncompressed_size || ra.stream.padding != rb.stream.padding) return false; if (ra.stream.block_count == 0) continue; if (ra.block.number_in_file != rb.block.number_in_file || ra.block.compressed_file_offset != rb.block.compressed_file_offset || ra.block.uncompressed_file_offset != rb.block.uncompressed_file_offset || ra.block.number_in_stream != rb.block.number_in_stream || ra.block.compressed_stream_offset != rb.block.compressed_stream_offset || ra.block.uncompressed_stream_offset != rb.block.uncompressed_stream_offset || ra.block.uncompressed_size != rb.block.uncompressed_size || ra.block.unpadded_size != rb.block.unpadded_size || ra.block.total_size != rb.block.total_size) return false; } } // Allocator that succeeds for the first two allocation but fails the rest. static void * my_alloc(void *opaque, size_t a, size_t b) { (void)opaque; assert_true(SIZE_MAX / a >= b); static unsigned count = 0; if (count >= 2) return NULL; ++count; return malloc(a * b); } static const lzma_allocator test_index_dup_alloc = { &my_alloc, NULL, NULL }; static void test_lzma_index_dup(void) { lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); // Test for the bug fix 21515d79d778b8730a434f151b07202d52a04611: // liblzma: Fix lzma_index_dup() for empty Streams. assert_lzma_ret(lzma_index_stream_padding(idx, 4), LZMA_OK); lzma_index *copy = lzma_index_dup(idx, NULL); assert_true(copy != NULL); assert_true(index_is_equal(idx, copy)); lzma_index_end(copy, NULL); // Test for the bug fix 3bf857edfef51374f6f3fffae3d817f57d3264a0: // liblzma: Fix a memory leak in error path of lzma_index_dup(). // Use Valgrind to see that there are no leaks. assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 10), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 2, 100), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 3, 1000), LZMA_OK); assert_true(lzma_index_dup(idx, &test_index_dup_alloc) == NULL); // Test a few streams and blocks lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); assert_lzma_ret(lzma_index_stream_padding(second, 16), LZMA_OK); lzma_index *third = lzma_index_init(NULL); assert_true(third != NULL); assert_lzma_ret(lzma_index_append(third, NULL, UNPADDED_SIZE_MIN * 10, 40), LZMA_OK); assert_lzma_ret(lzma_index_append(third, NULL, UNPADDED_SIZE_MIN * 20, 400), LZMA_OK); assert_lzma_ret(lzma_index_append(third, NULL, UNPADDED_SIZE_MIN * 30, 4000), LZMA_OK); assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); assert_lzma_ret(lzma_index_cat(idx, third, NULL), LZMA_OK); copy = lzma_index_dup(idx, NULL); assert_true(copy != NULL); assert_true(index_is_equal(idx, copy)); lzma_index_end(copy, NULL); lzma_index_end(idx, NULL); } #if defined(HAVE_ENCODERS) && defined(HAVE_DECODERS) static void verify_index_buffer(const lzma_index *idx, const uint8_t *buffer, const size_t buffer_size) { lzma_index_iter iter; lzma_index_iter_init(&iter, idx); size_t buffer_pos = 0; // Verify Index Indicator assert_uint_eq(buffer[buffer_pos++], 0); // Get Number of Records lzma_vli number_of_records = 0; lzma_vli block_count = 0; assert_lzma_ret(lzma_vli_decode(&number_of_records, NULL, buffer, &buffer_pos, buffer_size), LZMA_OK); while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_ANY)) { // Verify each Record (Unpadded Size, then Uncompressed Size). // Verify Unpadded Size. lzma_vli unpadded_size, uncompressed_size; assert_lzma_ret(lzma_vli_decode(&unpadded_size, NULL, buffer, &buffer_pos, buffer_size), LZMA_OK); assert_uint_eq(unpadded_size, iter.block.unpadded_size); // Verify Uncompressed Size assert_lzma_ret(lzma_vli_decode(&uncompressed_size, NULL, buffer, &buffer_pos, buffer_size), LZMA_OK); assert_uint_eq(uncompressed_size, iter.block.uncompressed_size); block_count++; } // Verify Number of Records assert_uint_eq(number_of_records, block_count); // Verify Index Padding for (; buffer_pos % 4 != 0; buffer_pos++) assert_uint_eq(buffer[buffer_pos], 0); // Verify CRC32 uint32_t crc32 = lzma_crc32(buffer, buffer_pos, 0); assert_uint_eq(read32le(buffer + buffer_pos), crc32); } // In a few places the Index size is needed as a size_t but lzma_index_size() // returns lzma_vli. static size_t get_index_size(const lzma_index *idx) { const lzma_vli size = lzma_index_size(idx); assert_uint(size, <, SIZE_MAX); return (size_t)size; } #endif static void test_lzma_index_encoder(void) { #if !defined(HAVE_ENCODERS) || !defined(HAVE_DECODERS) assert_skip("Encoder or decoder support disabled"); #else lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); lzma_stream strm = LZMA_STREAM_INIT; // First do basic NULL checks assert_lzma_ret(lzma_index_encoder(NULL, NULL), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_encoder(&strm, NULL), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_encoder(NULL, idx), LZMA_PROG_ERROR); // Append three small Blocks assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 10), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 2, 100), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 3, 1000), LZMA_OK); // Encode this lzma_index into a buffer size_t buffer_size = get_index_size(idx); uint8_t *buffer = tuktest_malloc(buffer_size); assert_lzma_ret(lzma_index_encoder(&strm, idx), LZMA_OK); strm.avail_out = buffer_size; strm.next_out = buffer; assert_lzma_ret(lzma_code(&strm, LZMA_FINISH), LZMA_STREAM_END); assert_uint_eq(strm.avail_out, 0); lzma_end(&strm); verify_index_buffer(idx, buffer, buffer_size); // Test with multiple Streams concatenated into 1 Index lzma_index *second = lzma_index_init(NULL); assert_true(second != NULL); // Include 1 Block assert_lzma_ret(lzma_index_append(second, NULL, UNPADDED_SIZE_MIN * 4, 20), LZMA_OK); // Include Stream Padding assert_lzma_ret(lzma_index_stream_padding(second, 16), LZMA_OK); assert_lzma_ret(lzma_index_cat(idx, second, NULL), LZMA_OK); buffer_size = get_index_size(idx); buffer = tuktest_malloc(buffer_size); assert_lzma_ret(lzma_index_encoder(&strm, idx), LZMA_OK); strm.avail_out = buffer_size; strm.next_out = buffer; assert_lzma_ret(lzma_code(&strm, LZMA_FINISH), LZMA_STREAM_END); assert_uint_eq(strm.avail_out, 0); verify_index_buffer(idx, buffer, buffer_size); lzma_index_end(idx, NULL); lzma_end(&strm); #endif } static void generate_index_decode_buffer(void) { #ifdef HAVE_ENCODERS decode_test_index = lzma_index_init(NULL); assert_true(decode_test_index != NULL); // Add 4 Blocks for (uint32_t i = 1; i < 5; i++) assert_lzma_ret(lzma_index_append(decode_test_index, NULL, 0x1000 * i, 0x100 * i), LZMA_OK); const size_t size = (size_t)lzma_index_size(decode_test_index); decode_buffer = tuktest_malloc(size); assert_lzma_ret(lzma_index_buffer_encode(decode_test_index, decode_buffer, &decode_buffer_size, size), LZMA_OK); assert_true(decode_buffer_size != 0); #endif } #ifdef HAVE_DECODERS static void decode_index(const uint8_t *buffer, const size_t size, lzma_stream *strm, lzma_ret expected_error) { strm->avail_in = size; strm->next_in = buffer; assert_lzma_ret(lzma_code(strm, LZMA_FINISH), expected_error); } #endif static void test_lzma_index_decoder(void) { #ifndef HAVE_DECODERS assert_skip("Decoder support disabled"); #else assert_true(decode_buffer_size != 0); lzma_stream strm = LZMA_STREAM_INIT; assert_lzma_ret(lzma_index_decoder(NULL, NULL, MEMLIMIT), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_decoder(&strm, NULL, MEMLIMIT), LZMA_PROG_ERROR); // If the first argument (lzma_stream *strm) is NULL then // *idx must still become NULL since the API docs say that // it's done if an error occurs. This was fixed in // 71eed2520e2eecae89bade9dceea16e56cfa2ea0. lzma_index *idx_allocated = lzma_index_init(NULL); lzma_index *idx = idx_allocated; assert_lzma_ret(lzma_index_decoder(NULL, &idx, MEMLIMIT), LZMA_PROG_ERROR); assert_true(idx == NULL); lzma_index_end(idx_allocated, NULL); idx_allocated = NULL; // Do actual decode assert_lzma_ret(lzma_index_decoder(&strm, &idx, MEMLIMIT), LZMA_OK); decode_index(decode_buffer, decode_buffer_size, &strm, LZMA_STREAM_END); // Compare results with expected assert_true(index_is_equal(decode_test_index, idx)); lzma_index_end(idx, NULL); // Test again with too low memory limit assert_lzma_ret(lzma_index_decoder(&strm, &idx, 0), LZMA_OK); decode_index(decode_buffer, decode_buffer_size, &strm, LZMA_MEMLIMIT_ERROR); uint8_t *corrupt_buffer = tuktest_malloc(decode_buffer_size); memcpy(corrupt_buffer, decode_buffer, decode_buffer_size); assert_lzma_ret(lzma_index_decoder(&strm, &idx, MEMLIMIT), LZMA_OK); // First corrupt the Index Indicator corrupt_buffer[0] ^= 1; decode_index(corrupt_buffer, decode_buffer_size, &strm, LZMA_DATA_ERROR); corrupt_buffer[0] ^= 1; // Corrupt something in the middle of Index corrupt_buffer[decode_buffer_size / 2] ^= 1; assert_lzma_ret(lzma_index_decoder(&strm, &idx, MEMLIMIT), LZMA_OK); decode_index(corrupt_buffer, decode_buffer_size, &strm, LZMA_DATA_ERROR); corrupt_buffer[decode_buffer_size / 2] ^= 1; // Corrupt CRC32 corrupt_buffer[decode_buffer_size - 1] ^= 1; assert_lzma_ret(lzma_index_decoder(&strm, &idx, MEMLIMIT), LZMA_OK); decode_index(corrupt_buffer, decode_buffer_size, &strm, LZMA_DATA_ERROR); corrupt_buffer[decode_buffer_size - 1] ^= 1; // Corrupt Index Padding by setting it to non-zero corrupt_buffer[decode_buffer_size - 5] ^= 1; assert_lzma_ret(lzma_index_decoder(&strm, &idx, MEMLIMIT), LZMA_OK); decode_index(corrupt_buffer, decode_buffer_size, &strm, LZMA_DATA_ERROR); corrupt_buffer[decode_buffer_size - 1] ^= 1; lzma_end(&strm); #endif } static void test_lzma_index_buffer_encode(void) { #if !defined(HAVE_ENCODERS) || !defined(HAVE_DECODERS) assert_skip("Encoder or decoder support disabled"); #else // More simple test than test_lzma_index_encoder() because // currently lzma_index_buffer_encode() is mostly a wrapper // around lzma_index_encoder() anyway. lzma_index *idx = lzma_index_init(NULL); assert_true(idx != NULL); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN, 10), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 2, 100), LZMA_OK); assert_lzma_ret(lzma_index_append(idx, NULL, UNPADDED_SIZE_MIN * 3, 1000), LZMA_OK); size_t buffer_size = get_index_size(idx); uint8_t *buffer = tuktest_malloc(buffer_size); size_t out_pos = 1; // First test bad arguments assert_lzma_ret(lzma_index_buffer_encode(NULL, NULL, NULL, 0), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_buffer_encode(idx, NULL, NULL, 0), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_buffer_encode(idx, buffer, NULL, 0), LZMA_PROG_ERROR); assert_lzma_ret(lzma_index_buffer_encode(idx, buffer, &out_pos, 0), LZMA_PROG_ERROR); out_pos = 0; assert_lzma_ret(lzma_index_buffer_encode(idx, buffer, &out_pos, 0), LZMA_BUF_ERROR); assert_uint_eq(out_pos, 0); assert_lzma_ret(lzma_index_buffer_encode(idx, buffer, &out_pos, 1), LZMA_BUF_ERROR); // Do encoding assert_lzma_ret(lzma_index_buffer_encode(idx, buffer, &out_pos, buffer_size), LZMA_OK); assert_uint_eq(out_pos, buffer_size); // Validate results verify_index_buffer(idx, buffer, buffer_size); lzma_index_end(idx, NULL); #endif } static void test_lzma_index_buffer_decode(void) { #ifndef HAVE_DECODERS assert_skip("Decoder support disabled"); #else assert_true(decode_buffer_size != 0); // Simple test since test_lzma_index_decoder() covers most of the // lzma_index_buffer_decode() code anyway. // First test NULL checks assert_lzma_ret(lzma_index_buffer_decode(NULL, NULL, NULL, NULL, NULL, 0), LZMA_PROG_ERROR); uint64_t memlimit = MEMLIMIT; size_t in_pos = 0; lzma_index *idx_allocated = lzma_index_init(NULL); lzma_index *idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, NULL, NULL, NULL, NULL, 0), LZMA_PROG_ERROR); assert_true(idx == NULL); idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, NULL, NULL, 0), LZMA_PROG_ERROR); assert_true(idx == NULL); idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, NULL, 0), LZMA_PROG_ERROR); assert_true(idx == NULL); idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, NULL, 0), LZMA_PROG_ERROR); assert_true(idx == NULL); idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, 0), LZMA_DATA_ERROR); assert_true(idx == NULL); in_pos = 1; idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, 0), LZMA_PROG_ERROR); assert_true(idx == NULL); // Test too short input in_pos = 0; idx = idx_allocated; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, decode_buffer_size - 1), LZMA_DATA_ERROR); assert_true(idx == NULL); lzma_index_end(idx_allocated, NULL); idx_allocated = NULL; // Test expected successful decode in_pos = 0; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, decode_buffer_size), LZMA_OK); assert_uint_eq(in_pos, decode_buffer_size); assert_true(index_is_equal(decode_test_index, idx)); lzma_index_end(idx, NULL); // Test too much input. This won't read past // the end of the allocated array (decode_buffer_size bytes). in_pos = 0; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, decode_buffer_size + 16), LZMA_OK); assert_uint_eq(in_pos, decode_buffer_size); assert_true(index_is_equal(decode_test_index, idx)); lzma_index_end(idx, NULL); // Test too small memlimit in_pos = 0; memlimit = 1; assert_lzma_ret(lzma_index_buffer_decode(&idx, &memlimit, NULL, decode_buffer, &in_pos, decode_buffer_size), LZMA_MEMLIMIT_ERROR); assert_uint(memlimit, >, 1); assert_uint(memlimit, <, MEMLIMIT); #endif } extern int main(int argc, char **argv) { tuktest_start(argc, argv); generate_index_decode_buffer(); tuktest_run(test_lzma_index_memusage); tuktest_run(test_lzma_index_memused); tuktest_run(test_lzma_index_append); tuktest_run(test_lzma_index_stream_flags); tuktest_run(test_lzma_index_checks); tuktest_run(test_lzma_index_stream_padding); tuktest_run(test_lzma_index_stream_count); tuktest_run(test_lzma_index_block_count); tuktest_run(test_lzma_index_size); tuktest_run(test_lzma_index_stream_size); tuktest_run(test_lzma_index_total_size); tuktest_run(test_lzma_index_file_size); tuktest_run(test_lzma_index_uncompressed_size); tuktest_run(test_lzma_index_iter_init); tuktest_run(test_lzma_index_iter_rewind); tuktest_run(test_lzma_index_iter_next); tuktest_run(test_lzma_index_iter_locate); tuktest_run(test_lzma_index_cat); tuktest_run(test_lzma_index_dup); tuktest_run(test_lzma_index_encoder); tuktest_run(test_lzma_index_decoder); tuktest_run(test_lzma_index_buffer_encode); tuktest_run(test_lzma_index_buffer_decode); lzma_index_end(decode_test_index, NULL); return tuktest_end(); }