kc3-lang/angle/src/common/mathutil_unittest.cpp

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• Author : Yuly Novikov
  Date : 2017-10-25 17:02:29
  Hash : c4f1dd83
  Message : Use angle::BitSetIterator optimizations on arm64 as well Previously were enabled only on x86_64. Also change from using target_cpu to current_cpu, as the doc recommends. BUG=angleproject:1814 Change-Id: Ia7e8e930c76aab5cfb47b75e0ec78902ab313237 Reviewed-on: https://chromium-review.googlesource.com/737438 Reviewed-by: Jamie Madill <jmadill@chromium.org> Reviewed-by: Corentin Wallez <cwallez@chromium.org> Commit-Queue: Yuly Novikov <ynovikov@chromium.org>

• src/common/mathutil_unittest.cpp

• //
  // Copyright 2015 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // mathutil_unittest:
  //   Unit tests for the utils defined in mathutil.h
  //
  
  #include "mathutil.h"
  
  #include <gtest/gtest.h>
  
  using namespace gl;
  
  namespace
  {
  
  // Test the correctness of packSnorm2x16 and unpackSnorm2x16 functions.
  // For floats f1 and f2, unpackSnorm2x16(packSnorm2x16(f1, f2)) should be same as f1 and f2.
  TEST(MathUtilTest, packAndUnpackSnorm2x16)
  {
      const float input[8][2] =
      {
          { 0.0f, 0.0f },
          { 1.0f, 1.0f },
          { -1.0f, 1.0f },
          { -1.0f, -1.0f },
          { 0.875f, 0.75f },
          { 0.00392f, -0.99215f },
          { -0.000675f, 0.004954f },
          { -0.6937f, -0.02146f }
      };
      const float floatFaultTolerance = 0.0001f;
      float outputVal1, outputVal2;
  
      for (size_t i = 0; i < 8; i++)
      {
          unpackSnorm2x16(packSnorm2x16(input[i][0], input[i][1]), &outputVal1, &outputVal2);
          EXPECT_NEAR(input[i][0], outputVal1, floatFaultTolerance);
          EXPECT_NEAR(input[i][1], outputVal2, floatFaultTolerance);
      }
  }
  
  // Test the correctness of packSnorm2x16 and unpackSnorm2x16 functions with infinity values,
  // result should be clamped to [-1, 1].
  TEST(MathUtilTest, packAndUnpackSnorm2x16Infinity)
  {
      const float floatFaultTolerance = 0.0001f;
      float outputVal1, outputVal2;
  
      unpackSnorm2x16(packSnorm2x16(std::numeric_limits<float>::infinity(),
                                    std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(1.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(1.0f, outputVal2, floatFaultTolerance);
  
      unpackSnorm2x16(packSnorm2x16(std::numeric_limits<float>::infinity(),
                                    -std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(1.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(-1.0f, outputVal2, floatFaultTolerance);
  
      unpackSnorm2x16(packSnorm2x16(-std::numeric_limits<float>::infinity(),
                                    -std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(-1.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(-1.0f, outputVal2, floatFaultTolerance);
  }
  
  // Test the correctness of packUnorm2x16 and unpackUnorm2x16 functions.
  // For floats f1 and f2, unpackUnorm2x16(packUnorm2x16(f1, f2)) should be same as f1 and f2.
  TEST(MathUtilTest, packAndUnpackUnorm2x16)
  {
      const float input[8][2] =
      {
          { 0.0f, 0.0f },
          { 1.0f, 1.0f },
          { -1.0f, 1.0f },
          { -1.0f, -1.0f },
          { 0.875f, 0.75f },
          { 0.00392f, -0.99215f },
          { -0.000675f, 0.004954f },
          { -0.6937f, -0.02146f }
      };
      const float floatFaultTolerance = 0.0001f;
      float outputVal1, outputVal2;
  
      for (size_t i = 0; i < 8; i++)
      {
          unpackUnorm2x16(packUnorm2x16(input[i][0], input[i][1]), &outputVal1, &outputVal2);
          float expected = input[i][0] < 0.0f ? 0.0f : input[i][0];
          EXPECT_NEAR(expected, outputVal1, floatFaultTolerance);
          expected = input[i][1] < 0.0f ? 0.0f : input[i][1];
          EXPECT_NEAR(expected, outputVal2, floatFaultTolerance);
      }
  }
  
  // Test the correctness of packUnorm2x16 and unpackUnorm2x16 functions with infinity values,
  // result should be clamped to [0, 1].
  TEST(MathUtilTest, packAndUnpackUnorm2x16Infinity)
  {
      const float floatFaultTolerance = 0.0001f;
      float outputVal1, outputVal2;
  
      unpackUnorm2x16(packUnorm2x16(std::numeric_limits<float>::infinity(),
                                    std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(1.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(1.0f, outputVal2, floatFaultTolerance);
  
      unpackUnorm2x16(packUnorm2x16(std::numeric_limits<float>::infinity(),
                                    -std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(1.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(0.0f, outputVal2, floatFaultTolerance);
  
      unpackUnorm2x16(packUnorm2x16(-std::numeric_limits<float>::infinity(),
                                    -std::numeric_limits<float>::infinity()), &outputVal1, &outputVal2);
      EXPECT_NEAR(0.0f, outputVal1, floatFaultTolerance);
      EXPECT_NEAR(0.0f, outputVal2, floatFaultTolerance);
  }
  
  // Test the correctness of packHalf2x16 and unpackHalf2x16 functions.
  // For floats f1 and f2, unpackHalf2x16(packHalf2x16(f1, f2)) should be same as f1 and f2.
  TEST(MathUtilTest, packAndUnpackHalf2x16)
  {
      const float input[8][2] =
      {
          { 0.0f, 0.0f },
          { 1.0f, 1.0f },
          { -1.0f, 1.0f },
          { -1.0f, -1.0f },
          { 0.875f, 0.75f },
          { 0.00392f, -0.99215f },
          { -0.000675f, 0.004954f },
          { -0.6937f, -0.02146f },
      };
      const float floatFaultTolerance = 0.0005f;
      float outputVal1, outputVal2;
  
      for (size_t i = 0; i < 8; i++)
      {
          unpackHalf2x16(packHalf2x16(input[i][0], input[i][1]), &outputVal1, &outputVal2);
          EXPECT_NEAR(input[i][0], outputVal1, floatFaultTolerance);
          EXPECT_NEAR(input[i][1], outputVal2, floatFaultTolerance);
      }
  }
  
  // Test the correctness of packUnorm4x8 and unpackUnorm4x8 functions.
  // For floats f1 to f4, unpackUnorm4x8(packUnorm4x8(f1, f2, f3, f4)) should be same as f1 to f4.
  TEST(MathUtilTest, packAndUnpackUnorm4x8)
  {
      const float input[5][4] = {{0.0f, 0.0f, 0.0f, 0.0f},
                                 {1.0f, 1.0f, 1.0f, 1.0f},
                                 {-1.0f, 1.0f, -1.0f, 1.0f},
                                 {-1.0f, -1.0f, -1.0f, -1.0f},
                                 {64.0f / 255.0f, 128.0f / 255.0f, 32.0f / 255.0f, 16.0f / 255.0f}};
  
      const float floatFaultTolerance = 0.005f;
      float outputVals[4];
  
      for (size_t i = 0; i < 5; i++)
      {
          UnpackUnorm4x8(PackUnorm4x8(input[i][0], input[i][1], input[i][2], input[i][3]),
                         outputVals);
          for (size_t j = 0; j < 4; j++)
          {
              float expected = input[i][j] < 0.0f ? 0.0f : input[i][j];
              EXPECT_NEAR(expected, outputVals[j], floatFaultTolerance);
          }
      }
  }
  
  // Test the correctness of packSnorm4x8 and unpackSnorm4x8 functions.
  // For floats f1 to f4, unpackSnorm4x8(packSnorm4x8(f1, f2, f3, f4)) should be same as f1 to f4.
  TEST(MathUtilTest, packAndUnpackSnorm4x8)
  {
      const float input[5][4] = {{0.0f, 0.0f, 0.0f, 0.0f},
                                 {1.0f, 1.0f, 1.0f, 1.0f},
                                 {-1.0f, 1.0f, -1.0f, 1.0f},
                                 {-1.0f, -1.0f, -1.0f, -1.0f},
                                 {64.0f / 127.0f, -8.0f / 127.0f, 32.0f / 127.0f, 16.0f / 127.0f}};
  
      const float floatFaultTolerance = 0.01f;
      float outputVals[4];
  
      for (size_t i = 0; i < 5; i++)
      {
          UnpackSnorm4x8(PackSnorm4x8(input[i][0], input[i][1], input[i][2], input[i][3]),
                         outputVals);
          for (size_t j = 0; j < 4; j++)
          {
              float expected = input[i][j];
              EXPECT_NEAR(expected, outputVals[j], floatFaultTolerance);
          }
      }
  }
  
  // Test the correctness of gl::isNaN function.
  TEST(MathUtilTest, isNaN)
  {
      EXPECT_TRUE(isNaN(bitCast<float>(0xffu << 23 | 1u)));
      EXPECT_TRUE(isNaN(bitCast<float>(1u << 31 | 0xffu << 23 | 1u)));
      EXPECT_TRUE(isNaN(bitCast<float>(1u << 31 | 0xffu << 23 | 0x400000u)));
      EXPECT_TRUE(isNaN(bitCast<float>(1u << 31 | 0xffu << 23 | 0x7fffffu)));
      EXPECT_FALSE(isNaN(0.0f));
      EXPECT_FALSE(isNaN(bitCast<float>(1u << 31 | 0xffu << 23)));
      EXPECT_FALSE(isNaN(bitCast<float>(0xffu << 23)));
  }
  
  // Test the correctness of gl::isInf function.
  TEST(MathUtilTest, isInf)
  {
      EXPECT_TRUE(isInf(bitCast<float>(0xffu << 23)));
      EXPECT_TRUE(isInf(bitCast<float>(1u << 31 | 0xffu << 23)));
      EXPECT_FALSE(isInf(0.0f));
      EXPECT_FALSE(isInf(bitCast<float>(0xffu << 23 | 1u)));
      EXPECT_FALSE(isInf(bitCast<float>(1u << 31 | 0xffu << 23 | 1u)));
      EXPECT_FALSE(isInf(bitCast<float>(1u << 31 | 0xffu << 23 | 0x400000u)));
      EXPECT_FALSE(isInf(bitCast<float>(1u << 31 | 0xffu << 23 | 0x7fffffu)));
      EXPECT_FALSE(isInf(bitCast<float>(0xfeu << 23 | 0x7fffffu)));
      EXPECT_FALSE(isInf(bitCast<float>(1u << 31 | 0xfeu << 23 | 0x7fffffu)));
  }
  
  TEST(MathUtilTest, CountLeadingZeros)
  {
      for (unsigned int i = 0; i < 32u; ++i)
      {
          uint32_t iLeadingZeros = 1u << (31u - i);
          EXPECT_EQ(i, CountLeadingZeros(iLeadingZeros));
      }
      EXPECT_EQ(32u, CountLeadingZeros(0));
  }
  
  // Some basic tests. Tests that rounding up zero produces zero.
  TEST(MathUtilTest, BasicRoundUp)
  {
      EXPECT_EQ(0u, rx::roundUp(0u, 4u));
      EXPECT_EQ(4u, rx::roundUp(1u, 4u));
      EXPECT_EQ(4u, rx::roundUp(4u, 4u));
  }
  
  // Test that rounding up zero produces zero for checked ints.
  TEST(MathUtilTest, CheckedRoundUpZero)
  {
      auto checkedValue = rx::CheckedRoundUp(0u, 4u);
      ASSERT_TRUE(checkedValue.IsValid());
      ASSERT_EQ(0u, checkedValue.ValueOrDie());
  }
  
  // Test out-of-bounds with CheckedRoundUp
  TEST(MathUtilTest, CheckedRoundUpInvalid)
  {
      // The answer to this query is out of bounds.
      auto limit        = std::numeric_limits<unsigned int>::max();
      auto checkedValue = rx::CheckedRoundUp(limit, limit - 1);
      ASSERT_FALSE(checkedValue.IsValid());
  
      // Our implementation can't handle this query, despite the parameters being in range.
      auto checkedLimit = rx::CheckedRoundUp(limit - 1, limit);
      ASSERT_FALSE(checkedLimit.IsValid());
  }
  
  // Test BitfieldReverse which reverses the order of the bits in an integer.
  TEST(MathUtilTest, BitfieldReverse)
  {
      EXPECT_EQ(0u, gl::BitfieldReverse(0u));
      EXPECT_EQ(0x80000000u, gl::BitfieldReverse(1u));
      EXPECT_EQ(0x1u, gl::BitfieldReverse(0x80000000u));
      uint32_t bits     = (1u << 4u) | (1u << 7u);
      uint32_t reversed = (1u << (31u - 4u)) | (1u << (31u - 7u));
      EXPECT_EQ(reversed, gl::BitfieldReverse(bits));
  }
  
  // Test BitCount, which counts 1 bits in an integer.
  TEST(MathUtilTest, BitCount)
  {
      EXPECT_EQ(0, gl::BitCount(0u));
      EXPECT_EQ(32, gl::BitCount(0xFFFFFFFFu));
      EXPECT_EQ(10, gl::BitCount(0x17103121u));
  
  #if defined(ANGLE_IS_64_BIT_CPU)
      EXPECT_EQ(0, gl::BitCount(0ull));
      EXPECT_EQ(32, gl::BitCount(0xFFFFFFFFull));
      EXPECT_EQ(10, gl::BitCount(0x17103121ull));
  #endif  // defined(ANGLE_IS_64_BIT_CPU)
  }
  
  // Test ScanForward, which scans for the least significant 1 bit from a non-zero integer.
  TEST(MathUtilTest, ScanForward)
  {
      EXPECT_EQ(0ul, gl::ScanForward(1u));
      EXPECT_EQ(16ul, gl::ScanForward(0x80010000u));
      EXPECT_EQ(31ul, gl::ScanForward(0x80000000u));
  
  #if defined(ANGLE_IS_64_BIT_CPU)
      EXPECT_EQ(0ul, gl::ScanForward(1ull));
      EXPECT_EQ(16ul, gl::ScanForward(0x80010000ull));
      EXPECT_EQ(31ul, gl::ScanForward(0x80000000ull));
  #endif  // defined(ANGLE_IS_64_BIT_CPU)
  }
  
  // Test ScanReverse, which scans for the most significant 1 bit from a non-zero integer.
  TEST(MathUtilTest, ScanReverse)
  {
      EXPECT_EQ(0ul, gl::ScanReverse(1ul));
      EXPECT_EQ(16ul, gl::ScanReverse(0x00010030ul));
      EXPECT_EQ(31ul, gl::ScanReverse(0x80000000ul));
  }
  
  // Test FindLSB, which finds the least significant 1 bit.
  TEST(MathUtilTest, FindLSB)
  {
      EXPECT_EQ(-1, gl::FindLSB(0u));
      EXPECT_EQ(0, gl::FindLSB(1u));
      EXPECT_EQ(16, gl::FindLSB(0x80010000u));
      EXPECT_EQ(31, gl::FindLSB(0x80000000u));
  }
  
  // Test FindMSB, which finds the most significant 1 bit.
  TEST(MathUtilTest, FindMSB)
  {
      EXPECT_EQ(-1, gl::FindMSB(0u));
      EXPECT_EQ(0, gl::FindMSB(1u));
      EXPECT_EQ(16, gl::FindMSB(0x00010030u));
      EXPECT_EQ(31, gl::FindMSB(0x80000000u));
  }
  
  // Test Ldexp, which combines mantissa and exponent into a floating-point number.
  TEST(MathUtilTest, Ldexp)
  {
      EXPECT_EQ(2.5f, Ldexp(0.625f, 2));
      EXPECT_EQ(-5.0f, Ldexp(-0.625f, 3));
      EXPECT_EQ(std::numeric_limits<float>::infinity(), Ldexp(0.625f, 129));
      EXPECT_EQ(0.0f, Ldexp(1.0f, -129));
  }
  
  // Test that Range::extend works as expected.
  TEST(MathUtilTest, RangeExtend)
  {
      RangeI range(0, 0);
  
      range.extend(5);
      EXPECT_EQ(0, range.low());
      EXPECT_EQ(6, range.high());
      EXPECT_EQ(6, range.length());
  
      range.extend(-1);
      EXPECT_EQ(-1, range.low());
      EXPECT_EQ(6, range.high());
      EXPECT_EQ(7, range.length());
  
      range.extend(10);
      EXPECT_EQ(-1, range.low());
      EXPECT_EQ(11, range.high());
      EXPECT_EQ(12, range.length());
  }
  
  // Test that Range iteration works as expected.
  TEST(MathUtilTest, RangeIteration)
  {
      RangeI range(0, 10);
      int expected = 0;
      for (int value : range)
      {
          EXPECT_EQ(expected, value);
          expected++;
      }
      EXPECT_EQ(range.length(), expected);
  }
  
  }  // anonymous namespace