core/fxge/dib/cfx_imagetransformer.cpp - pdfium - Git at Google

 // Copyright 2017 The PDFium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

 #include "core/fxge/dib/cfx_imagetransformer.h"

 #include <math.h>

 #include <iterator>
 #include <memory>
 #include <utility>

 #include "core/fxcrt/check.h"
 #include "core/fxcrt/compiler_specific.h"
 #include "core/fxcrt/fx_system.h"
 #include "core/fxcrt/notreached.h"
 #include "core/fxcrt/numerics/safe_conversions.h"
 #include "core/fxge/dib/cfx_dibitmap.h"
 #include "core/fxge/dib/cfx_imagestretcher.h"
 #include "core/fxge/dib/fx_dib.h"

 namespace {

 constexpr int kBase = 256;
 constexpr float kFix16 = 0.05f;
 constexpr uint8_t kOpaqueAlpha = 0xff;

 uint8_t BilinearInterpolate(const uint8_t* buf,
                             const CFX_ImageTransformer::BilinearData& data,
                             int bpp,
                             int c_offset) {
   int i_resx = 255 - data.res_x;
   int col_bpp_l = data.src_col_l * bpp;
   int col_bpp_r = data.src_col_r * bpp;
   const uint8_t* buf_u = buf + data.row_offset_l + c_offset;
   const uint8_t* buf_d = buf + data.row_offset_r + c_offset;
   const uint8_t* src_pos0 = buf_u + col_bpp_l;
   const uint8_t* src_pos1 = buf_u + col_bpp_r;
   const uint8_t* src_pos2 = buf_d + col_bpp_l;
   const uint8_t* src_pos3 = buf_d + col_bpp_r;
   uint8_t r_pos_0 = (*src_pos0 * i_resx + *src_pos1 * data.res_x) >> 8;
   uint8_t r_pos_1 = (*src_pos2 * i_resx + *src_pos3 * data.res_x) >> 8;
   return (r_pos_0 * (255 - data.res_y) + r_pos_1 * data.res_y) >> 8;
 }

 class CFX_BilinearMatrix {
  public:
   explicit CFX_BilinearMatrix(const CFX_Matrix& src)
       : a(FXSYS_roundf(src.a * kBase)),
         b(FXSYS_roundf(src.b * kBase)),
         c(FXSYS_roundf(src.c * kBase)),
         d(FXSYS_roundf(src.d * kBase)),
         e(FXSYS_roundf(src.e * kBase)),
         f(FXSYS_roundf(src.f * kBase)) {}

   void Transform(int x, int y, int* x1, int* y1, int* res_x, int* res_y) const {
     CFX_PointF val = TransformInternal(CFX_PointF(x, y));
     *x1 = pdfium::saturated_cast<int>(val.x / kBase);
     *y1 = pdfium::saturated_cast<int>(val.y / kBase);
     *res_x = static_cast<int>(val.x) % kBase;
     *res_y = static_cast<int>(val.y) % kBase;
     if (*res_x < 0 && *res_x > -kBase)
       *res_x = kBase + *res_x;
     if (*res_y < 0 && *res_y > -kBase)
       *res_y = kBase + *res_y;
   }

  private:
   CFX_PointF TransformInternal(CFX_PointF pt) const {
     return CFX_PointF(a * pt.x + c * pt.y + e + kBase / 2,
                       b * pt.x + d * pt.y + f + kBase / 2);
   }

   const int a;
   const int b;
   const int c;
   const int d;
   const int e;
   const int f;
 };

 bool InStretchBounds(const FX_RECT& clip_rect, int col, int row) {
   return col >= 0 && col <= clip_rect.Width() && row >= 0 &&
          row <= clip_rect.Height();
 }

 void AdjustCoords(const FX_RECT& clip_rect, int* col, int* row) {
   int& src_col = *col;
   int& src_row = *row;
   if (src_col == clip_rect.Width())
     src_col--;
   if (src_row == clip_rect.Height())
     src_row--;
 }

 // Let the compiler deduce the type for |func|, which cheaper than specifying it
 // with std::function.
 template <typename F>
 void DoBilinearLoop(const CFX_ImageTransformer::CalcData& calc_data,
                     const FX_RECT& result_rect,
                     const FX_RECT& clip_rect,
                     int increment,
                     const F& func) {
   CFX_BilinearMatrix matrix_fix(calc_data.matrix);
   for (int row = 0; row < result_rect.Height(); row++) {
     uint8_t* dest = calc_data.bitmap->GetWritableScanline(row).data();
     for (int col = 0; col < result_rect.Width(); col++) {
       CFX_ImageTransformer::BilinearData d;
       d.res_x = 0;
       d.res_y = 0;
       d.src_col_l = 0;
       d.src_row_l = 0;
       matrix_fix.Transform(col, row, &d.src_col_l, &d.src_row_l, &d.res_x,
                            &d.res_y);
       if (LIKELY(InStretchBounds(clip_rect, d.src_col_l, d.src_row_l))) {
         AdjustCoords(clip_rect, &d.src_col_l, &d.src_row_l);
         d.src_col_r = d.src_col_l + 1;
         d.src_row_r = d.src_row_l + 1;
         AdjustCoords(clip_rect, &d.src_col_r, &d.src_row_r);
         d.row_offset_l = d.src_row_l * calc_data.pitch;
         d.row_offset_r = d.src_row_r * calc_data.pitch;
         func(d, dest);
       }
       dest += increment;
     }
   }
 }

 }  // namespace

 CFX_ImageTransformer::CFX_ImageTransformer(RetainPtr<const CFX_DIBBase> source,
                                            const CFX_Matrix& matrix,
                                            const FXDIB_ResampleOptions& options,
                                            const FX_RECT* pClip)
     : m_pSrc(std::move(source)), m_matrix(matrix), m_ResampleOptions(options) {
   FX_RECT result_rect = m_matrix.GetUnitRect().GetClosestRect();
   FX_RECT result_clip = result_rect;
   if (pClip)
     result_clip.Intersect(*pClip);

   if (result_clip.IsEmpty())
     return;

   m_result = result_clip;
   if (fabs(m_matrix.a) < fabs(m_matrix.b) / 20 &&
       fabs(m_matrix.d) < fabs(m_matrix.c) / 20 && fabs(m_matrix.a) < 0.5f &&
       fabs(m_matrix.d) < 0.5f) {
     int dest_width = result_rect.Width();
     int dest_height = result_rect.Height();
     result_clip.Offset(-result_rect.left, -result_rect.top);
     result_clip = result_clip.SwappedClipBox(dest_width, dest_height,
                                              m_matrix.c > 0, m_matrix.b < 0);
     m_Stretcher = std::make_unique<CFX_ImageStretcher>(
         &m_Storer, m_pSrc, dest_height, dest_width, result_clip,
         m_ResampleOptions);
     m_Stretcher->Start();
     m_type = StretchType::kRotate;
     return;
   }
   if (fabs(m_matrix.b) < kFix16 && fabs(m_matrix.c) < kFix16) {
     int dest_width =
         static_cast<int>(m_matrix.a > 0 ? ceil(m_matrix.a) : floor(m_matrix.a));
     int dest_height = static_cast<int>(m_matrix.d > 0 ? -ceil(m_matrix.d)
                                                       : -floor(m_matrix.d));
     result_clip.Offset(-result_rect.left, -result_rect.top);
     m_Stretcher = std::make_unique<CFX_ImageStretcher>(
         &m_Storer, m_pSrc, dest_width, dest_height, result_clip,
         m_ResampleOptions);
     m_Stretcher->Start();
     m_type = StretchType::kNormal;
     return;
   }

   int stretch_width =
       static_cast<int>(ceil(FXSYS_sqrt2(m_matrix.a, m_matrix.b)));
   int stretch_height =
       static_cast<int>(ceil(FXSYS_sqrt2(m_matrix.c, m_matrix.d)));
   CFX_Matrix stretch_to_dest(1.0f, 0.0f, 0.0f, -1.0f, 0.0f, stretch_height);
   stretch_to_dest.Concat(
       CFX_Matrix(m_matrix.a / stretch_width, m_matrix.b / stretch_width,
                  m_matrix.c / stretch_height, m_matrix.d / stretch_height,
                  m_matrix.e, m_matrix.f));
   CFX_Matrix dest_to_strech = stretch_to_dest.GetInverse();

   FX_RECT stretch_clip =
       dest_to_strech.TransformRect(CFX_FloatRect(result_clip)).GetOuterRect();
   if (!stretch_clip.Valid())
     return;

   stretch_clip.Intersect(0, 0, stretch_width, stretch_height);
   if (!stretch_clip.Valid())
     return;

   m_dest2stretch = dest_to_strech;
   m_StretchClip = stretch_clip;
   m_Stretcher = std::make_unique<CFX_ImageStretcher>(
       &m_Storer, m_pSrc, stretch_width, stretch_height, m_StretchClip,
       m_ResampleOptions);
   m_Stretcher->Start();
   m_type = StretchType::kOther;
 }

 CFX_ImageTransformer::~CFX_ImageTransformer() = default;

 bool CFX_ImageTransformer::Continue(PauseIndicatorIface* pPause) {
   if (m_type == StretchType::kNone) {
     return false;
   }

   if (m_Stretcher->Continue(pPause))
     return true;

   switch (m_type) {
     case StretchType::kNone:
       // Already handled separately at the beginning of this method.
       NOTREACHED_NORETURN();
     case StretchType::kNormal:
       return false;
     case StretchType::kRotate:
       ContinueRotate(pPause);
       return false;
     case StretchType::kOther:
       ContinueOther(pPause);
       return false;
   }
 }

 void CFX_ImageTransformer::ContinueRotate(PauseIndicatorIface* pPause) {
   if (m_Storer.GetBitmap()) {
     m_Storer.Replace(
         m_Storer.GetBitmap()->SwapXY(m_matrix.c > 0, m_matrix.b < 0));
   }
 }

 void CFX_ImageTransformer::ContinueOther(PauseIndicatorIface* pPause) {
   if (!m_Storer.GetBitmap())
     return;

   auto pTransformed = pdfium::MakeRetain<CFX_DIBitmap>();
   FXDIB_Format format = m_Stretcher->source()->IsMaskFormat()
                             ? FXDIB_Format::k8bppMask
                             : FXDIB_Format::kArgb;
   if (!pTransformed->Create(m_result.Width(), m_result.Height(), format))
     return;

   CFX_Matrix result2stretch(1.0f, 0.0f, 0.0f, 1.0f, m_result.left,
                             m_result.top);
   result2stretch.Concat(m_dest2stretch);
   result2stretch.Translate(-m_StretchClip.left, -m_StretchClip.top);

   CalcData calc_data = {pTransformed.Get(), result2stretch,
                         m_Storer.GetBitmap()->GetBuffer().data(),
                         m_Storer.GetBitmap()->GetPitch()};
   if (m_Storer.GetBitmap()->IsMaskFormat()) {
     CalcAlpha(calc_data);
   } else {
     int Bpp = m_Storer.GetBitmap()->GetBPP() / 8;
     if (Bpp == 1)
       CalcMono(calc_data);
     else
       CalcColor(calc_data, format, Bpp);
   }
   m_Storer.Replace(std::move(pTransformed));
 }

 RetainPtr<CFX_DIBitmap> CFX_ImageTransformer::DetachBitmap() {
   return m_Storer.Detach();
 }

 void CFX_ImageTransformer::CalcAlpha(const CalcData& calc_data) {
   auto func = [&calc_data](const BilinearData& data, uint8_t* dest) {
     *dest = BilinearInterpolate(calc_data.buf, data, 1, 0);
   };
   DoBilinearLoop(calc_data, m_result, m_StretchClip, 1, func);
 }

 void CFX_ImageTransformer::CalcMono(const CalcData& calc_data) {
   uint32_t argb[256];
   if (m_Storer.GetBitmap()->HasPalette()) {
     pdfium::span<const uint32_t> palette =
         m_Storer.GetBitmap()->GetPaletteSpan();
     for (size_t i = 0; i < std::size(argb); i++)
       argb[i] = palette[i];
   } else {
     for (size_t i = 0; i < std::size(argb); i++) {
       uint32_t v = static_cast<uint32_t>(i);
       argb[i] = ArgbEncode(0xff, v, v, v);
     }
   }
   int destBpp = calc_data.bitmap->GetBPP() / 8;
   auto func = [&calc_data, &argb](const BilinearData& data, uint8_t* dest) {
     uint8_t idx = BilinearInterpolate(calc_data.buf, data, 1, 0);
     *reinterpret_cast<uint32_t*>(dest) = argb[idx];
   };
   DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
 }

 void CFX_ImageTransformer::CalcColor(const CalcData& calc_data,
                                      FXDIB_Format format,
                                      int Bpp) {
   DCHECK(format == FXDIB_Format::k8bppMask || format == FXDIB_Format::kArgb);
   const int destBpp = calc_data.bitmap->GetBPP() / 8;
   if (!m_Storer.GetBitmap()->IsAlphaFormat()) {
     auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
       uint8_t b = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
       uint8_t g = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
       uint8_t r = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
       *reinterpret_cast<uint32_t*>(dest) = ArgbEncode(kOpaqueAlpha, r, g, b);
     };
     DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
     return;
   }

   if (format == FXDIB_Format::kArgb) {
     auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
       uint8_t b = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
       uint8_t g = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
       uint8_t r = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
       uint8_t alpha = BilinearInterpolate(calc_data.buf, data, Bpp, 3);
       *reinterpret_cast<uint32_t*>(dest) = ArgbEncode(alpha, r, g, b);
     };
     DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
     return;
   }

   auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
     uint8_t c = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
     uint8_t m = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
     uint8_t y = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
     uint8_t k = BilinearInterpolate(calc_data.buf, data, Bpp, 3);
     *reinterpret_cast<uint32_t*>(dest) = FXCMYK_TODIB(CmykEncode(c, m, y, k));
   };
   DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
 }
	// Copyright 2017 The PDFium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com

	#include "core/fxge/dib/cfx_imagetransformer.h"

	#include <math.h>

	#include <iterator>
	#include <memory>
	#include <utility>

	#include "core/fxcrt/check.h"
	#include "core/fxcrt/compiler_specific.h"
	#include "core/fxcrt/fx_system.h"
	#include "core/fxcrt/notreached.h"
	#include "core/fxcrt/numerics/safe_conversions.h"
	#include "core/fxge/dib/cfx_dibitmap.h"
	#include "core/fxge/dib/cfx_imagestretcher.h"
	#include "core/fxge/dib/fx_dib.h"

	namespace {

	constexpr int kBase = 256;
	constexpr float kFix16 = 0.05f;
	constexpr uint8_t kOpaqueAlpha = 0xff;

	uint8_t BilinearInterpolate(const uint8_t* buf,
	const CFX_ImageTransformer::BilinearData& data,
	int bpp,
	int c_offset) {
	int i_resx = 255 - data.res_x;
	int col_bpp_l = data.src_col_l * bpp;
	int col_bpp_r = data.src_col_r * bpp;
	const uint8_t* buf_u = buf + data.row_offset_l + c_offset;
	const uint8_t* buf_d = buf + data.row_offset_r + c_offset;
	const uint8_t* src_pos0 = buf_u + col_bpp_l;
	const uint8_t* src_pos1 = buf_u + col_bpp_r;
	const uint8_t* src_pos2 = buf_d + col_bpp_l;
	const uint8_t* src_pos3 = buf_d + col_bpp_r;
	uint8_t r_pos_0 = (src_pos0 i_resx + src_pos1 data.res_x) >> 8;
	uint8_t r_pos_1 = (src_pos2 i_resx + src_pos3 data.res_x) >> 8;
	return (r_pos_0 * (255 - data.res_y) + r_pos_1 * data.res_y) >> 8;
	}

	class CFX_BilinearMatrix {
	public:
	explicit CFX_BilinearMatrix(const CFX_Matrix& src)
	: a(FXSYS_roundf(src.a * kBase)),
	b(FXSYS_roundf(src.b * kBase)),
	c(FXSYS_roundf(src.c * kBase)),
	d(FXSYS_roundf(src.d * kBase)),
	e(FXSYS_roundf(src.e * kBase)),
	f(FXSYS_roundf(src.f * kBase)) {}

	void Transform(int x, int y, int* x1, int* y1, int* res_x, int* res_y) const {
	CFX_PointF val = TransformInternal(CFX_PointF(x, y));
	*x1 = pdfium::saturated_cast<int>(val.x / kBase);
	*y1 = pdfium::saturated_cast<int>(val.y / kBase);
	*res_x = static_cast<int>(val.x) % kBase;
	*res_y = static_cast<int>(val.y) % kBase;
	if (res_x < 0 && res_x > -kBase)
	res_x = kBase + res_x;
	if (res_y < 0 && res_y > -kBase)
	res_y = kBase + res_y;
	}

	private:
	CFX_PointF TransformInternal(CFX_PointF pt) const {
	return CFX_PointF(a * pt.x + c * pt.y + e + kBase / 2,
	b * pt.x + d * pt.y + f + kBase / 2);
	}

	const int a;
	const int b;
	const int c;
	const int d;
	const int e;
	const int f;
	};

	bool InStretchBounds(const FX_RECT& clip_rect, int col, int row) {
	return col >= 0 && col <= clip_rect.Width() && row >= 0 &&
	row <= clip_rect.Height();
	}

	void AdjustCoords(const FX_RECT& clip_rect, int* col, int* row) {
	int& src_col = *col;
	int& src_row = *row;
	if (src_col == clip_rect.Width())
	src_col--;
	if (src_row == clip_rect.Height())
	src_row--;
	}

	// Let the compiler deduce the type for \|func\|, which cheaper than specifying it
	// with std::function.
	template <typename F>
	void DoBilinearLoop(const CFX_ImageTransformer::CalcData& calc_data,
	const FX_RECT& result_rect,
	const FX_RECT& clip_rect,
	int increment,
	const F& func) {
	CFX_BilinearMatrix matrix_fix(calc_data.matrix);
	for (int row = 0; row < result_rect.Height(); row++) {
	uint8_t* dest = calc_data.bitmap->GetWritableScanline(row).data();
	for (int col = 0; col < result_rect.Width(); col++) {
	CFX_ImageTransformer::BilinearData d;
	d.res_x = 0;
	d.res_y = 0;
	d.src_col_l = 0;
	d.src_row_l = 0;
	matrix_fix.Transform(col, row, &d.src_col_l, &d.src_row_l, &d.res_x,
	&d.res_y);
	if (LIKELY(InStretchBounds(clip_rect, d.src_col_l, d.src_row_l))) {
	AdjustCoords(clip_rect, &d.src_col_l, &d.src_row_l);
	d.src_col_r = d.src_col_l + 1;
	d.src_row_r = d.src_row_l + 1;
	AdjustCoords(clip_rect, &d.src_col_r, &d.src_row_r);
	d.row_offset_l = d.src_row_l * calc_data.pitch;
	d.row_offset_r = d.src_row_r * calc_data.pitch;
	func(d, dest);
	}
	dest += increment;
	}
	}
	}

	} // namespace

	CFX_ImageTransformer::CFX_ImageTransformer(RetainPtr<const CFX_DIBBase> source,
	const CFX_Matrix& matrix,
	const FXDIB_ResampleOptions& options,
	const FX_RECT* pClip)
	: m_pSrc(std::move(source)), m_matrix(matrix), m_ResampleOptions(options) {
	FX_RECT result_rect = m_matrix.GetUnitRect().GetClosestRect();
	FX_RECT result_clip = result_rect;
	if (pClip)
	result_clip.Intersect(*pClip);

	if (result_clip.IsEmpty())
	return;

	m_result = result_clip;
	if (fabs(m_matrix.a) < fabs(m_matrix.b) / 20 &&
	fabs(m_matrix.d) < fabs(m_matrix.c) / 20 && fabs(m_matrix.a) < 0.5f &&
	fabs(m_matrix.d) < 0.5f) {
	int dest_width = result_rect.Width();
	int dest_height = result_rect.Height();
	result_clip.Offset(-result_rect.left, -result_rect.top);
	result_clip = result_clip.SwappedClipBox(dest_width, dest_height,
	m_matrix.c > 0, m_matrix.b < 0);
	m_Stretcher = std::make_unique<CFX_ImageStretcher>(
	&m_Storer, m_pSrc, dest_height, dest_width, result_clip,
	m_ResampleOptions);
	m_Stretcher->Start();
	m_type = StretchType::kRotate;
	return;
	}
	if (fabs(m_matrix.b) < kFix16 && fabs(m_matrix.c) < kFix16) {
	int dest_width =
	static_cast<int>(m_matrix.a > 0 ? ceil(m_matrix.a) : floor(m_matrix.a));
	int dest_height = static_cast<int>(m_matrix.d > 0 ? -ceil(m_matrix.d)
	: -floor(m_matrix.d));
	result_clip.Offset(-result_rect.left, -result_rect.top);
	m_Stretcher = std::make_unique<CFX_ImageStretcher>(
	&m_Storer, m_pSrc, dest_width, dest_height, result_clip,
	m_ResampleOptions);
	m_Stretcher->Start();
	m_type = StretchType::kNormal;
	return;
	}

	int stretch_width =
	static_cast<int>(ceil(FXSYS_sqrt2(m_matrix.a, m_matrix.b)));
	int stretch_height =
	static_cast<int>(ceil(FXSYS_sqrt2(m_matrix.c, m_matrix.d)));
	CFX_Matrix stretch_to_dest(1.0f, 0.0f, 0.0f, -1.0f, 0.0f, stretch_height);
	stretch_to_dest.Concat(
	CFX_Matrix(m_matrix.a / stretch_width, m_matrix.b / stretch_width,
	m_matrix.c / stretch_height, m_matrix.d / stretch_height,
	m_matrix.e, m_matrix.f));
	CFX_Matrix dest_to_strech = stretch_to_dest.GetInverse();

	FX_RECT stretch_clip =
	dest_to_strech.TransformRect(CFX_FloatRect(result_clip)).GetOuterRect();
	if (!stretch_clip.Valid())
	return;

	stretch_clip.Intersect(0, 0, stretch_width, stretch_height);
	if (!stretch_clip.Valid())
	return;

	m_dest2stretch = dest_to_strech;
	m_StretchClip = stretch_clip;
	m_Stretcher = std::make_unique<CFX_ImageStretcher>(
	&m_Storer, m_pSrc, stretch_width, stretch_height, m_StretchClip,
	m_ResampleOptions);
	m_Stretcher->Start();
	m_type = StretchType::kOther;
	}

	CFX_ImageTransformer::~CFX_ImageTransformer() = default;

	bool CFX_ImageTransformer::Continue(PauseIndicatorIface* pPause) {
	if (m_type == StretchType::kNone) {
	return false;
	}

	if (m_Stretcher->Continue(pPause))
	return true;

	switch (m_type) {
	case StretchType::kNone:
	// Already handled separately at the beginning of this method.
	NOTREACHED_NORETURN();
	case StretchType::kNormal:
	return false;
	case StretchType::kRotate:
	ContinueRotate(pPause);
	return false;
	case StretchType::kOther:
	ContinueOther(pPause);
	return false;
	}
	}

	void CFX_ImageTransformer::ContinueRotate(PauseIndicatorIface* pPause) {
	if (m_Storer.GetBitmap()) {
	m_Storer.Replace(
	m_Storer.GetBitmap()->SwapXY(m_matrix.c > 0, m_matrix.b < 0));
	}
	}

	void CFX_ImageTransformer::ContinueOther(PauseIndicatorIface* pPause) {
	if (!m_Storer.GetBitmap())
	return;

	auto pTransformed = pdfium::MakeRetain<CFX_DIBitmap>();
	FXDIB_Format format = m_Stretcher->source()->IsMaskFormat()
	? FXDIB_Format::k8bppMask
	: FXDIB_Format::kArgb;
	if (!pTransformed->Create(m_result.Width(), m_result.Height(), format))
	return;

	CFX_Matrix result2stretch(1.0f, 0.0f, 0.0f, 1.0f, m_result.left,
	m_result.top);
	result2stretch.Concat(m_dest2stretch);
	result2stretch.Translate(-m_StretchClip.left, -m_StretchClip.top);

	CalcData calc_data = {pTransformed.Get(), result2stretch,
	m_Storer.GetBitmap()->GetBuffer().data(),
	m_Storer.GetBitmap()->GetPitch()};
	if (m_Storer.GetBitmap()->IsMaskFormat()) {
	CalcAlpha(calc_data);
	} else {
	int Bpp = m_Storer.GetBitmap()->GetBPP() / 8;
	if (Bpp == 1)
	CalcMono(calc_data);
	else
	CalcColor(calc_data, format, Bpp);
	}
	m_Storer.Replace(std::move(pTransformed));
	}

	RetainPtr<CFX_DIBitmap> CFX_ImageTransformer::DetachBitmap() {
	return m_Storer.Detach();
	}

	void CFX_ImageTransformer::CalcAlpha(const CalcData& calc_data) {
	auto func = [&calc_data](const BilinearData& data, uint8_t* dest) {
	*dest = BilinearInterpolate(calc_data.buf, data, 1, 0);
	};
	DoBilinearLoop(calc_data, m_result, m_StretchClip, 1, func);
	}

	void CFX_ImageTransformer::CalcMono(const CalcData& calc_data) {
	uint32_t argb[256];
	if (m_Storer.GetBitmap()->HasPalette()) {
	pdfium::span<const uint32_t> palette =
	m_Storer.GetBitmap()->GetPaletteSpan();
	for (size_t i = 0; i < std::size(argb); i++)
	argb[i] = palette[i];
	} else {
	for (size_t i = 0; i < std::size(argb); i++) {
	uint32_t v = static_cast<uint32_t>(i);
	argb[i] = ArgbEncode(0xff, v, v, v);
	}
	}
	int destBpp = calc_data.bitmap->GetBPP() / 8;
	auto func = [&calc_data, &argb](const BilinearData& data, uint8_t* dest) {
	uint8_t idx = BilinearInterpolate(calc_data.buf, data, 1, 0);
	reinterpret_cast<uint32_t>(dest) = argb[idx];
	};
	DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
	}

	void CFX_ImageTransformer::CalcColor(const CalcData& calc_data,
	FXDIB_Format format,
	int Bpp) {
	DCHECK(format == FXDIB_Format::k8bppMask \|\| format == FXDIB_Format::kArgb);
	const int destBpp = calc_data.bitmap->GetBPP() / 8;
	if (!m_Storer.GetBitmap()->IsAlphaFormat()) {
	auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
	uint8_t b = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
	uint8_t g = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
	uint8_t r = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
	reinterpret_cast<uint32_t>(dest) = ArgbEncode(kOpaqueAlpha, r, g, b);
	};
	DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
	return;
	}

	if (format == FXDIB_Format::kArgb) {
	auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
	uint8_t b = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
	uint8_t g = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
	uint8_t r = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
	uint8_t alpha = BilinearInterpolate(calc_data.buf, data, Bpp, 3);
	reinterpret_cast<uint32_t>(dest) = ArgbEncode(alpha, r, g, b);
	};
	DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
	return;
	}

	auto func = [&calc_data, Bpp](const BilinearData& data, uint8_t* dest) {
	uint8_t c = BilinearInterpolate(calc_data.buf, data, Bpp, 0);
	uint8_t m = BilinearInterpolate(calc_data.buf, data, Bpp, 1);
	uint8_t y = BilinearInterpolate(calc_data.buf, data, Bpp, 2);
	uint8_t k = BilinearInterpolate(calc_data.buf, data, Bpp, 3);
	reinterpret_cast<uint32_t>(dest) = FXCMYK_TODIB(CmykEncode(c, m, y, k));
	};
	DoBilinearLoop(calc_data, m_result, m_StretchClip, destBpp, func);
	}