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/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*-
 * This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

#include "gfxPattern.h"

#include "gfxUtils.h"
#include "gfxTypes.h"
#include "gfxASurface.h"
#include "gfxPlatform.h"
#include "gfx2DGlue.h"
#include "gfxGradientCache.h"
#include "mozilla/gfx/2D.h"

#include "cairo.h"

#include <vector>

using namespace mozilla::gfx;

gfxPattern::gfxPattern(const Color& aColor)
  : mExtend(ExtendMode::CLAMP)
{
  mGfxPattern.InitColorPattern(ToDeviceColor(aColor));
}

// linear
gfxPattern::gfxPattern(gfxFloat x0, gfxFloat y0, gfxFloat x1, gfxFloat y1)
  : mExtend(ExtendMode::CLAMP)
{
  mGfxPattern.InitLinearGradientPattern(Point(x0, y0), Point(x1, y1), nullptr);
}

// radial
gfxPattern::gfxPattern(gfxFloat cx0, gfxFloat cy0, gfxFloat radius0,
                       gfxFloat cx1, gfxFloat cy1, gfxFloat radius1)
  : mExtend(ExtendMode::CLAMP)
{
  mGfxPattern.InitRadialGradientPattern(Point(cx0, cy0), Point(cx1, cy1),
                                        radius0, radius1, nullptr);
}

// Azure
gfxPattern::gfxPattern(SourceSurface *aSurface, const Matrix &aPatternToUserSpace)
  : mPatternToUserSpace(aPatternToUserSpace)
  , mExtend(ExtendMode::CLAMP)
{
  mGfxPattern.InitSurfacePattern(aSurface, mExtend, Matrix(), // matrix is overridden in GetPattern()
                                 mozilla::gfx::Filter::GOOD);
}

void
gfxPattern::AddColorStop(gfxFloat offset, const Color& c)
{
  if (mGfxPattern.GetPattern()->GetType() != PatternType::LINEAR_GRADIENT &&
      mGfxPattern.GetPattern()->GetType() != PatternType::RADIAL_GRADIENT) {
    return;
  }

  mStops = nullptr;

  GradientStop stop;
  stop.offset = offset;
  stop.color = ToDeviceColor(c);
  mStopsList.AppendElement(stop);
}

void
gfxPattern::SetColorStops(GradientStops* aStops)
{
  mStops = aStops;
}

void
gfxPattern::CacheColorStops(const DrawTarget *aDT)
{
  mStops = gfxGradientCache::GetOrCreateGradientStops(aDT, mStopsList, mExtend);
}

void
gfxPattern::SetMatrix(const gfxMatrix& aPatternToUserSpace)
{
  mPatternToUserSpace = ToMatrix(aPatternToUserSpace);
  // Cairo-pattern matrices specify the conversion from DrawTarget to pattern
  // space. Azure pattern matrices specify the conversion from pattern to
  // DrawTarget space.
  mPatternToUserSpace.Invert();
}

gfxMatrix
gfxPattern::GetMatrix() const
{
  // invert at the higher precision of gfxMatrix
  // cause we need to convert at some point anyways
  gfxMatrix mat = ThebesMatrix(mPatternToUserSpace);
  mat.Invert();
  return mat;
}

gfxMatrix
gfxPattern::GetInverseMatrix() const
{
  return ThebesMatrix(mPatternToUserSpace);
}

Pattern*
gfxPattern::GetPattern(const DrawTarget *aTarget,
                       Matrix *aOriginalUserToDevice)
{
  Matrix patternToUser = mPatternToUserSpace;

  if (aOriginalUserToDevice &&
      *aOriginalUserToDevice != aTarget->GetTransform()) {
    // mPatternToUserSpace maps from pattern space to the original user space,
    // but aTarget now has a transform to a different user space.  In order for
    // the Pattern* that we return to be usable in aTarget's new user space we
    // need the Pattern's mMatrix to be the transform from pattern space to
    // aTarget's -new- user space.  That transform is equivalent to the
    // transform from pattern space to original user space (patternToUser),
    // multiplied by the transform from original user space to device space,
    // multiplied by the transform from device space to current user space.

    Matrix deviceToCurrentUser = aTarget->GetTransform();
    deviceToCurrentUser.Invert();

    patternToUser = patternToUser * *aOriginalUserToDevice * deviceToCurrentUser;
  }
  patternToUser.NudgeToIntegers();

  if (!mStops &&
      !mStopsList.IsEmpty()) {
    mStops = aTarget->CreateGradientStops(mStopsList.Elements(),
                                          mStopsList.Length(), mExtend);
  }

  switch (mGfxPattern.GetPattern()->GetType()) {
  case PatternType::SURFACE: {
    SurfacePattern* surfacePattern = static_cast<SurfacePattern*>(mGfxPattern.GetPattern());
    surfacePattern->mMatrix = patternToUser;
    surfacePattern->mExtendMode = mExtend;
    break;
  }
  case PatternType::LINEAR_GRADIENT: {
    LinearGradientPattern* linearGradientPattern = static_cast<LinearGradientPattern*>(mGfxPattern.GetPattern());
    linearGradientPattern->mMatrix = patternToUser;
    linearGradientPattern->mStops = mStops;
    break;
  }
  case PatternType::RADIAL_GRADIENT: {
    RadialGradientPattern* radialGradientPattern = static_cast<RadialGradientPattern*>(mGfxPattern.GetPattern());
    radialGradientPattern->mMatrix = patternToUser;
    radialGradientPattern->mStops = mStops;
    break;
  }
  default:
    /* Reassure the compiler we are handling all the enum values.  */
    break;
  }

  return mGfxPattern.GetPattern();
}

void
gfxPattern::SetExtend(ExtendMode aExtend)
{
  mExtend = aExtend;
  mStops = nullptr;
}

bool
gfxPattern::IsOpaque()
{
  if (mGfxPattern.GetPattern()->GetType() != PatternType::SURFACE) {
    return false;
  }

  if (static_cast<SurfacePattern*>(mGfxPattern.GetPattern())->mSurface->GetFormat() == SurfaceFormat::B8G8R8X8) {
    return true;
  }
  return false;
}

void
gfxPattern::SetFilter(gfx::Filter filter)
{
  if (mGfxPattern.GetPattern()->GetType() != PatternType::SURFACE) {
    return;
  }

  static_cast<SurfacePattern*>(mGfxPattern.GetPattern())->mFilter = filter;
}

Filter
gfxPattern::Filter() const
{
  if (mGfxPattern.GetPattern()->GetType() != PatternType::SURFACE) {
    return gfx::Filter::GOOD;
  }
  return static_cast<const SurfacePattern*>(mGfxPattern.GetPattern())->mFilter;
}

bool
gfxPattern::GetSolidColor(Color& aColorOut)
{
  if (mGfxPattern.GetPattern()->GetType() == PatternType::COLOR) {
    aColorOut = static_cast<ColorPattern*>(mGfxPattern.GetPattern())->mColor;
    return true;
  }

 return false;
}

int
gfxPattern::CairoStatus()
{
  return CAIRO_STATUS_SUCCESS;
}