// Copyright (c) the JPEG XL 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.

#include "lib/jxl/splines.h"

#include <jxl/cms.h>
#include <jxl/memory_manager.h>

#include <cstddef>
#include <cstdint>
#include <cstdio>
#include <ostream>
#include <utility>
#include <vector>

#include "lib/extras/codec.h"
#include "lib/jxl/base/common.h"
#include "lib/jxl/base/compiler_specific.h"
#include "lib/jxl/base/printf_macros.h"
#include "lib/jxl/base/rect.h"
#include "lib/jxl/base/span.h"
#include "lib/jxl/base/status.h"
#include "lib/jxl/chroma_from_luma.h"
#include "lib/jxl/common.h"
#include "lib/jxl/enc_aux_out.h"
#include "lib/jxl/enc_bit_writer.h"
#include "lib/jxl/enc_splines.h"
#include "lib/jxl/image.h"
#include "lib/jxl/image_ops.h"
#include "lib/jxl/image_test_utils.h"
#include "lib/jxl/test_memory_manager.h"
#include "lib/jxl/test_utils.h"
#include "lib/jxl/testing.h"

namespace jxl {

std::ostream& operator<<(std::ostream& os, const Spline::Point& p) {
  return os << "(" << p.x << ", " << p.y << ")";
}

std::ostream& operator<<(std::ostream& os, const Spline& spline) {
  return os << "(spline with " << spline.control_points.size()
            << " control points)";
}

namespace {

using ::jxl::test::ReadTestData;

constexpr int kQuantizationAdjustment = 0;
const ColorCorrelation color_correlation{};
const float kYToX = color_correlation.YtoXRatio(0);
const float kYToB = color_correlation.YtoBRatio(0);

constexpr float kTolerance = 0.003125;

Status DequantizeSplines(const Splines& splines,
                         std::vector<Spline>& dequantized) {
  const auto& quantized_splines = splines.QuantizedSplines();
  const auto& starting_points = splines.StartingPoints();
  JXL_ENSURE(quantized_splines.size() == starting_points.size());

  uint64_t total = 0;
  for (size_t i = 0; i < quantized_splines.size(); ++i) {
    dequantized.emplace_back();
    JXL_RETURN_IF_ERROR(quantized_splines[i].Dequantize(
        starting_points[i], kQuantizationAdjustment, kYToX, kYToB, 2u << 30u,
        &total, dequantized.back()));
  }
  return true;
}

}  // namespace

TEST(SplinesTest, Serialization) {
  JxlMemoryManager* memory_manager = jxl::test::MemoryManager();
  Spline spline1{
      /*control_points=*/{
          {109, 54}, {218, 159}, {80, 3}, {110, 274}, {94, 185}, {17, 277}},
      /*color_dct=*/
      {Dct32{36.3, 39.7, 23.2, 67.5, 4.4,  71.5, 62.3, 32.3, 92.2, 10.1, 10.8,
             9.2,  6.1,  10.5, 79.1, 7,    24.6, 90.8, 5.5,  84,   43.8, 49,
             33.5, 78.9, 54.5, 77.9, 62.1, 51.4, 36.4, 14.3, 83.7, 35.4},
       Dct32{9.4,  53.4, 9.5,  74.9, 72.7, 26.7, 7.9,  0.9, 84.9, 23.2, 26.5,
             31.1, 91,   11.7, 74.1, 39.3, 23.7, 82.5, 4.8, 2.7,  61.2, 96.4,
             13.7, 66.7, 62.9, 82.4, 5.9,  98.7, 21.5, 7.9, 51.7, 63.1},
       Dct32{48,   39.3, 6.9,  26.3, 33.3, 6.2,  1.7,  98.9, 59.9, 59.6, 95,
             61.3, 82.7, 53,   6.1,  30.4, 34.7, 96.9, 93.4, 17,   38.8, 80.8,
             63,   18.6, 43.6, 32.3, 61,   20.2, 24.3, 28.3, 69.1, 62.4}},
      /*sigma_dct=*/{32.7, 21.5, 44.4, 1.8,  45.8, 90.6, 29.3, 59.2,
                     23.7, 85.2, 84.8, 27.2, 42.1, 84.1, 50.6, 17.6,
                     93.7, 4.9,  2.6,  69.8, 94.9, 52,   24.3, 18.8,
                     12.1, 95.7, 28.5, 81.4, 89.9, 31.4, 74.8, 52}};
  Spline spline2{
      /*control_points=*/{{172, 309},
                          {196, 277},
                          {42, 238},
                          {114, 350},
                          {307, 290},
                          {316, 269},
                          {124, 66},
                          {233, 267}},
      /*color_dct=*/
      {Dct32{15,   28.9, 22, 6.6,  41.8, 83,   8.6,  56.8, 68.9, 9.7,  5.4,
             19.8, 70.8, 90, 52.5, 65.2, 7.8,  23.5, 26.4, 72.2, 64.7, 87.1,
             1.3,  67.5, 46, 68.4, 65.4, 35.5, 29.1, 13,   41.6, 23.9},
       Dct32{47.7, 79.4, 62.7, 29.1, 96.8, 18.5, 17.6, 15.2, 80.5, 56,  96.2,
             59.9, 26.7, 96.1, 92.3, 42.1, 35.8, 54,   23.2, 55,   76,  35.8,
             58.4, 88.7, 2.4,  78.1, 95.6, 27.5, 6.6,  78.5, 24.1, 69.8},
       Dct32{43.8, 96.5, 0.9,  95.1, 49.1, 71.2, 25.1, 33.6, 75.2, 95,  82.1,
             19.7, 10.5, 44.9, 50,   93.3, 83.5, 99.5, 64.6, 54,   3.5, 99.7,
             45.3, 82.1, 22.4, 37.9, 60,   32.2, 12.6, 4.6,  65.5, 96.4}},
      /*sigma_dct=*/{72.5, 2.6,  41.7, 2.2,  39.7, 79.1, 69.6, 19.9,
                     92.3, 71.5, 41.9, 62.1, 30,   49.4, 70.3, 45.3,
                     62.5, 47.2, 46.7, 41.2, 90.8, 46.8, 91.2, 55,
                     8.1,  69.6, 25.4, 84.7, 61.7, 27.6, 3.7,  46.9}};
  Spline spline3{
      /*control_points=*/{{100, 186},
                          {257, 97},
                          {170, 49},
                          {25, 169},
                          {309, 104},
                          {232, 237},
                          {385, 101},
                          {122, 168},
                          {26, 300},
                          {390, 88}},
      /*color_dct=*/
      {Dct32{16.9, 64.8, 4.2,  10.6, 23.5, 17,   79.3, 5.7,  60.4, 16.6, 94.9,
             63.7, 87.6, 10.5, 3.8,  61.1, 22.9, 81.9, 80.4, 40.5, 45.9, 25.4,
             39.8, 30,   50.2, 90.4, 27.9, 93.7, 65.1, 48.2, 22.3, 43.9},
       Dct32{24.9, 66,   3.5,  90.2, 97.1, 15.8, 35.6, 0.6,  68,   39.6, 24.4,
             85.9, 57.7, 77.6, 47.5, 67.9, 4.3,  5.4,  91.2, 58.5, 0.1,  52.2,
             3.5,  47.8, 63.2, 43.5, 85.8, 35.8, 50.2, 35.9, 19.2, 48.2},
       Dct32{82.8, 44.9, 76.4, 39.5, 94.1, 14.3, 89.8, 10,   10.5, 74.5, 56.3,
             65.8, 7.8,  23.3, 52.8, 99.3, 56.8, 46,   76.7, 13.5, 67,   22.4,
             29.9, 43.3, 70.3, 26,   74.3, 53.9, 62,   19.1, 49.3, 46.7}},
      /*sigma_dct=*/{83.5, 1.7,  25.1, 18.7, 46.5, 75.3, 28,   62.3,
                     50.3, 23.3, 85.6, 96,   45.8, 33.1, 33.4, 52.9,
                     26.3, 58.5, 19.6, 70,   92.6, 22.5, 57,   21.6,
                     76.8, 87.5, 22.9, 66.3, 35.7, 35.6, 56.8, 67.2}};
  std::vector<Spline> spline_data{spline1, spline2, spline3};

  std::vector<QuantizedSpline> quantized_splines;
  std::vector<Spline::Point> starting_points;
  for (const Spline& spline : spline_data) {
    JXL_ASSIGN_OR_QUIT(
        QuantizedSpline qspline,
        QuantizedSpline::Create(spline, kQuantizationAdjustment, kYToX, kYToB),
        "Failed to create QuantizedSpline.");
    quantized_splines.emplace_back(std::move(qspline));
    starting_points.push_back(spline.control_points.front());
  }

  Splines splines(kQuantizationAdjustment, std::move(quantized_splines),
                  std::move(starting_points));
  std::vector<Spline> quantized_spline_data;
  ASSERT_TRUE(DequantizeSplines(splines, quantized_spline_data));
  EXPECT_EQ(quantized_spline_data.size(), spline_data.size());
  for (size_t i = 0; i < quantized_spline_data.size(); ++i) {
    const Spline& actual = quantized_spline_data[i];
    const Spline& expected = spline_data[i];
    const auto& actual_points = actual.control_points;
    const auto& expected_points = expected.control_points;
    EXPECT_EQ(actual_points.size(), expected_points.size());
    for (size_t j = 0; j < actual_points.size(); ++j) {
      EXPECT_NEAR(actual_points[j].x, expected_points[j].x, kTolerance)
          << "spline " << i << " point " << j;
      EXPECT_NEAR(actual_points[j].y, expected_points[j].y, kTolerance)
          << "spline " << i << " point " << j;
    }
  }

  BitWriter writer{memory_manager};
  ASSERT_TRUE(EncodeSplines(splines, &writer, LayerType::Splines,
                            HistogramParams(), nullptr));
  writer.ZeroPadToByte();
  const size_t bits_written = writer.BitsWritten();

  printf("Wrote %" PRIuS " bits of splines.\n", bits_written);

  BitReader reader(writer.GetSpan());
  Splines decoded_splines;
  ASSERT_TRUE(
      decoded_splines.Decode(memory_manager, &reader, /*num_pixels=*/1000));
  ASSERT_TRUE(reader.JumpToByteBoundary());
  EXPECT_EQ(reader.TotalBitsConsumed(), bits_written);
  ASSERT_TRUE(reader.Close());

  std::vector<Spline> decoded_spline_data;
  ASSERT_TRUE(DequantizeSplines(decoded_splines, decoded_spline_data));

  EXPECT_EQ(decoded_spline_data.size(), quantized_spline_data.size());
  for (size_t i = 0; i < decoded_spline_data.size(); ++i) {
    const Spline& actual = decoded_spline_data[i];
    const Spline& expected = quantized_spline_data[i];
    const auto& actual_points = actual.control_points;
    const auto& expected_points = expected.control_points;
    EXPECT_EQ(actual_points.size(), expected_points.size());
    for (size_t j = 0; j < actual_points.size(); ++j) {
      EXPECT_NEAR(actual_points[j].x, expected_points[j].x, kTolerance)
          << "spline " << i << " point " << j;
      EXPECT_NEAR(actual_points[j].y, expected_points[j].y, kTolerance)
          << "spline " << i << " point " << j;
    }

    const auto& actual_color_dct = actual.color_dct;
    const auto& expected_color_dct = expected.color_dct;
    for (size_t j = 0; j < actual_color_dct.size(); ++j) {
      EXPECT_ARRAY_NEAR(actual_color_dct[j], expected_color_dct[j], kTolerance);
    }
    EXPECT_ARRAY_NEAR(actual.sigma_dct, expected.sigma_dct, kTolerance);
  }
}

TEST(SplinesTest, TooManySplinesTest) {
  if (JXL_CRASH_ON_ERROR) {
    GTEST_SKIP() << "Skipping due to JXL_CRASH_ON_ERROR";
  }
  JxlMemoryManager* memory_manager = jxl::test::MemoryManager();
  // This is more than the limit for 1000 pixels.
  const size_t kNumSplines = 300;

  std::vector<QuantizedSpline> quantized_splines;
  std::vector<Spline::Point> starting_points;
  for (size_t i = 0; i < kNumSplines; i++) {
    Spline spline{
        /*control_points=*/{{1.f + i, 2}, {10.f + i, 25}, {30.f + i, 300}},
        /*color_dct=*/
        {Dct32{1.f, 0.2f, 0.1f}, Dct32{35.7f, 10.3f}, Dct32{35.7f, 7.8f}},
        /*sigma_dct=*/{10.f, 0.f, 0.f, 2.f}};
    JXL_ASSIGN_OR_QUIT(
        QuantizedSpline qspline,
        QuantizedSpline::Create(spline, kQuantizationAdjustment, kYToX, kYToB),
        "Failed to create QuantizedSpline.");
    quantized_splines.emplace_back(std::move(qspline));
    starting_points.push_back(spline.control_points.front());
  }

  Splines splines(kQuantizationAdjustment, std::move(quantized_splines),
                  std::move(starting_points));
  BitWriter writer{memory_manager};
  ASSERT_TRUE(EncodeSplines(splines, &writer, LayerType::Splines,
                            HistogramParams(SpeedTier::kFalcon, 1), nullptr));
  writer.ZeroPadToByte();
  // Re-read splines.
  BitReader reader(writer.GetSpan());
  Splines decoded_splines;
  EXPECT_FALSE(
      decoded_splines.Decode(memory_manager, &reader, /*num_pixels=*/1000));
  EXPECT_TRUE(reader.Close());
}

TEST(SplinesTest, DuplicatePoints) {
  if (JXL_CRASH_ON_ERROR) {
    GTEST_SKIP() << "Skipping due to JXL_CRASH_ON_ERROR";
  }
  JxlMemoryManager* memory_manager = jxl::test::MemoryManager();
  std::vector<Spline::Point> control_points{
      {9, 54}, {118, 159}, {97, 3},  // Repeated.
      {97, 3}, {10, 40},   {150, 25}, {120, 300}};
  Spline spline{
      control_points,
      /*color_dct=*/
      {Dct32{1.f, 0.2f, 0.1f}, Dct32{35.7f, 10.3f}, Dct32{35.7f, 7.8f}},
      /*sigma_dct=*/{10.f, 0.f, 0.f, 2.f}};
  std::vector<Spline> spline_data{spline};
  std::vector<QuantizedSpline> quantized_splines;
  std::vector<Spline::Point> starting_points;
  for (const Spline& spline : spline_data) {
    JXL_ASSIGN_OR_QUIT(
        QuantizedSpline qspline,
        QuantizedSpline::Create(spline, kQuantizationAdjustment, kYToX, kYToB),
        "Failed to create QuantizedSpline.");
    quantized_splines.emplace_back(std::move(qspline));
    starting_points.push_back(spline.control_points.front());
  }
  Splines splines(kQuantizationAdjustment, std::move(quantized_splines),
                  std::move(starting_points));

  JXL_TEST_ASSIGN_OR_DIE(Image3F image,
                         Image3F::Create(memory_manager, 320, 320));
  ZeroFillImage(&image);
  EXPECT_FALSE(splines.InitializeDrawCache(image.xsize(), image.ysize(),
                                           color_correlation));
}

TEST(SplinesTest, Drawing) {
  JxlMemoryManager* memory_manager = jxl::test::MemoryManager();
  CodecInOut io_expected{memory_manager};
  const std::vector<uint8_t> orig = ReadTestData("jxl/splines.pfm");
  ASSERT_TRUE(SetFromBytes(Bytes(orig), &io_expected,
                           /*pool=*/nullptr));

  std::vector<Spline::Point> control_points{{9, 54},  {118, 159}, {97, 3},
                                            {10, 40}, {150, 25},  {120, 300}};
  // Use values that survive quant/decorellation roundtrip.
  const Spline spline{
      control_points,
      /*color_dct=*/
      {Dct32{0.4989345073699951171875000f, 0.4997999966144561767578125f},
       Dct32{0.4772970676422119140625000f, 0.f, 0.5250000357627868652343750f},
       Dct32{-0.0176776945590972900390625f, 0.4900000095367431640625000f,
             0.5250000357627868652343750f}},
      /*sigma_dct=*/
      {0.9427147507667541503906250f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f,
       0.6665999889373779296875000f}};
  std::vector<Spline> spline_data = {spline};
  std::vector<QuantizedSpline> quantized_splines;
  std::vector<Spline::Point> starting_points;
  for (const Spline& spline : spline_data) {
    JXL_ASSIGN_OR_QUIT(
        QuantizedSpline qspline,
        QuantizedSpline::Create(spline, kQuantizationAdjustment, kYToX, kYToB),
        "Failed to create QuantizedSpline.");
    quantized_splines.emplace_back(std::move(qspline));
    starting_points.push_back(spline.control_points.front());
  }
  Splines splines(kQuantizationAdjustment, std::move(quantized_splines),
                  std::move(starting_points));

  JXL_TEST_ASSIGN_OR_DIE(Image3F image,
                         Image3F::Create(memory_manager, 320, 320));
  ZeroFillImage(&image);
  ASSERT_TRUE(splines.InitializeDrawCache(image.xsize(), image.ysize(),
                                          color_correlation));
  splines.AddTo(&image, Rect(image));

  CodecInOut io_actual{memory_manager};
  JXL_TEST_ASSIGN_OR_DIE(Image3F image2,
                         Image3F::Create(memory_manager, 320, 320));
  ASSERT_TRUE(CopyImageTo(image, &image2));
  ASSERT_TRUE(io_actual.SetFromImage(std::move(image2), ColorEncoding::SRGB()));
  ASSERT_TRUE(io_actual.frames[0].TransformTo(io_expected.Main().c_current(),
                                              *JxlGetDefaultCms()));

  JXL_TEST_ASSERT_OK(VerifyRelativeError(
      *io_expected.Main().color(), *io_actual.Main().color(), 1e-2f, 1e-1f, _));
}

TEST(SplinesTest, ClearedEveryFrame) {
  JxlMemoryManager* memory_manager = jxl::test::MemoryManager();
  CodecInOut io_expected{memory_manager};
  const std::vector<uint8_t> bytes_expected =
      ReadTestData("jxl/spline_on_first_frame.png");
  ASSERT_TRUE(SetFromBytes(Bytes(bytes_expected), &io_expected,
                           /*pool=*/nullptr));
  CodecInOut io_actual{memory_manager};
  const std::vector<uint8_t> bytes_actual =
      ReadTestData("jxl/spline_on_first_frame.jxl");
  ASSERT_TRUE(test::DecodeFile({}, Bytes(bytes_actual), &io_actual));

  ASSERT_TRUE(io_actual.frames[0].TransformTo(ColorEncoding::SRGB(),
                                              *JxlGetDefaultCms()));
  for (size_t c = 0; c < 3; ++c) {
    for (size_t y = 0; y < io_actual.ysize(); ++y) {
      float* const JXL_RESTRICT row = io_actual.Main().color()->PlaneRow(c, y);
      for (size_t x = 0; x < io_actual.xsize(); ++x) {
        row[x] = Clamp1(row[x], 0.f, 1.f);
      }
    }
  }
  JXL_TEST_ASSERT_OK(VerifyRelativeError(
      *io_expected.Main().color(), *io_actual.Main().color(), 1e-2f, 1e-1f, _));
}

}  // namespace jxl