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d52ffcd830
Rename unsigned_int generator to number_u32. Add generators: - number_u64 - number_f64 - percentage
287 lines
9.8 KiB
C++
287 lines
9.8 KiB
C++
/*
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* Copyright (c) 2023, Tim Schumacher <timschumi@gmx.de>
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#include <AK/BitStream.h>
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#include <AK/MemoryStream.h>
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#include <LibTest/TestCase.h>
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using namespace Test::Randomized;
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// Note: This does not do any checks on the internal representation, it just ensures that the behavior of the input and output streams match.
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TEST_CASE(little_endian_bit_stream_input_output_match)
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{
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auto memory_stream = make<AllocatingMemoryStream>();
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// Note: The bit stream only ever reads from/writes to the underlying stream in one byte chunks,
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// so testing with sizes that will not trigger a write will yield unexpected results.
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LittleEndianOutputBitStream bit_write_stream { MaybeOwned<Stream>(*memory_stream) };
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LittleEndianInputBitStream bit_read_stream { MaybeOwned<Stream>(*memory_stream) };
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// Test two mirrored chunks of a fully mirrored pattern to check that we are not dropping bits.
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{
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MUST(bit_write_stream.write_bits(0b1111u, 4));
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MUST(bit_write_stream.write_bits(0b1111u, 4));
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MUST(bit_write_stream.flush_buffer_to_stream());
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1111u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1111u, result);
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}
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{
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MUST(bit_write_stream.write_bits(0b0000u, 4));
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MUST(bit_write_stream.write_bits(0b0000u, 4));
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MUST(bit_write_stream.flush_buffer_to_stream());
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0000u, result);
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}
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// Test two mirrored chunks of a non-mirrored pattern to check that we are writing bits within a pattern in the correct order.
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{
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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MUST(bit_write_stream.flush_buffer_to_stream());
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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}
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// Test two different chunks to check that we are not confusing their order.
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{
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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MUST(bit_write_stream.write_bits(0b0100u, 4));
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MUST(bit_write_stream.flush_buffer_to_stream());
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0100u, result);
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}
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// Test a pattern that spans multiple bytes.
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{
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MUST(bit_write_stream.write_bits(0b1101001000100001u, 16));
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MUST(bit_write_stream.flush_buffer_to_stream());
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auto result = MUST(bit_read_stream.read_bits(16));
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EXPECT_EQ(0b1101001000100001u, result);
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}
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}
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// Note: This does not do any checks on the internal representation, it just ensures that the behavior of the input and output streams match.
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TEST_CASE(big_endian_bit_stream_input_output_match)
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{
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auto memory_stream = make<AllocatingMemoryStream>();
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// Note: The bit stream only ever reads from/writes to the underlying stream in one byte chunks,
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// so testing with sizes that will not trigger a write will yield unexpected results.
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BigEndianOutputBitStream bit_write_stream { MaybeOwned<Stream>(*memory_stream) };
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BigEndianInputBitStream bit_read_stream { MaybeOwned<Stream>(*memory_stream) };
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// Test two mirrored chunks of a fully mirrored pattern to check that we are not dropping bits.
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{
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MUST(bit_write_stream.write_bits(0b1111u, 4));
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MUST(bit_write_stream.write_bits(0b1111u, 4));
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1111u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1111u, result);
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}
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{
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MUST(bit_write_stream.write_bits(0b0000u, 4));
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MUST(bit_write_stream.write_bits(0b0000u, 4));
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0000u, result);
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}
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// Test two mirrored chunks of a non-mirrored pattern to check that we are writing bits within a pattern in the correct order.
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{
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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}
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// Test two different chunks to check that we are not confusing their order.
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{
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MUST(bit_write_stream.write_bits(0b1000u, 4));
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MUST(bit_write_stream.write_bits(0b0100u, 4));
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auto result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b1000u, result);
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result = MUST(bit_read_stream.read_bits(4));
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EXPECT_EQ(0b0100u, result);
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}
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// Test a pattern that spans multiple bytes.
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{
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MUST(bit_write_stream.write_bits(0b1101001000100001u, 16));
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auto result = MUST(bit_read_stream.read_bits(16));
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EXPECT_EQ(0b1101001000100001u, result);
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}
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}
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TEST_CASE(bit_reads_beyond_stream_limits)
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{
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Array<u8, 1> const test_data { 0xFF };
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{
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auto memory_stream = make<FixedMemoryStream>(test_data);
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auto bit_stream = make<LittleEndianInputBitStream>(move(memory_stream), LittleEndianInputBitStream::UnsatisfiableReadBehavior::Reject);
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{
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auto result = TRY_OR_FAIL(bit_stream->read_bits<u8>(6));
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EXPECT_EQ(result, 0b111111);
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}
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{
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auto result = bit_stream->read_bits<u8>(6);
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EXPECT(result.is_error());
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}
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{
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auto result = bit_stream->read_bits<u8>(6);
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EXPECT(result.is_error());
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}
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}
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{
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// LittleEndianInputBitStream allows reading null bits beyond the original data
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// for compatibility purposes if enabled.
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auto memory_stream = make<FixedMemoryStream>(test_data);
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auto bit_stream = make<LittleEndianInputBitStream>(move(memory_stream), LittleEndianInputBitStream::UnsatisfiableReadBehavior::FillWithZero);
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{
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auto result = TRY_OR_FAIL(bit_stream->read_bits<u8>(6));
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EXPECT_EQ(result, 0b111111);
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}
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{
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auto result = TRY_OR_FAIL(bit_stream->read_bits<u8>(6));
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EXPECT_EQ(result, 0b000011);
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}
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{
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auto result = TRY_OR_FAIL(bit_stream->read_bits<u8>(6));
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EXPECT_EQ(result, 0b000000);
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}
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}
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{
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auto memory_stream = make<FixedMemoryStream>(test_data);
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auto bit_stream = make<BigEndianInputBitStream>(move(memory_stream));
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{
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auto result = TRY_OR_FAIL(bit_stream->read_bits<u8>(6));
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EXPECT_EQ(result, 0b111111);
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}
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{
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auto result = bit_stream->read_bits<u8>(6);
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EXPECT(result.is_error());
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}
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{
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auto result = bit_stream->read_bits<u8>(6);
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EXPECT(result.is_error());
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}
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}
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}
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RANDOMIZED_TEST_CASE(roundtrip_u8_little_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u8>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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LittleEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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LittleEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 8));
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MUST(sut_write.flush_buffer_to_stream());
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auto result = MUST(sut_read.read_bits<u64>(8));
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EXPECT_EQ(result, n);
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}
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RANDOMIZED_TEST_CASE(roundtrip_u16_little_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u16>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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LittleEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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LittleEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 16));
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MUST(sut_write.flush_buffer_to_stream());
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auto result = MUST(sut_read.read_bits<u64>(16));
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EXPECT_EQ(result, n);
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}
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RANDOMIZED_TEST_CASE(roundtrip_u32_little_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u32>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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LittleEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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LittleEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 32));
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MUST(sut_write.flush_buffer_to_stream());
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auto result = MUST(sut_read.read_bits<u64>(32));
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EXPECT_EQ(result, n);
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}
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RANDOMIZED_TEST_CASE(roundtrip_u8_big_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u8>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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BigEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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BigEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 8));
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auto result = MUST(sut_read.read_bits<u64>(8));
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EXPECT_EQ(result, n);
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}
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RANDOMIZED_TEST_CASE(roundtrip_u16_big_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u16>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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BigEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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BigEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 16));
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auto result = MUST(sut_read.read_bits<u64>(16));
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EXPECT_EQ(result, n);
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}
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RANDOMIZED_TEST_CASE(roundtrip_u32_big_endian)
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{
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GEN(n, Gen::number_u64(NumericLimits<u32>::max()));
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auto memory_stream = make<AllocatingMemoryStream>();
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BigEndianOutputBitStream sut_write { MaybeOwned<Stream>(*memory_stream) };
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BigEndianInputBitStream sut_read { MaybeOwned<Stream>(*memory_stream) };
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MUST(sut_write.write_bits(n, 32));
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auto result = MUST(sut_read.read_bits<u64>(32));
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EXPECT_EQ(result, n);
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}
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