core/fpdfapi/page/cpdf_function.cpp - pdfium - Git at Google

 // Copyright 2017 PDFium Authors. All rights reserved.
 // 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/fpdfapi/page/cpdf_function.h"

 #include <vector>

 #include "core/fpdfapi/page/cpdf_expintfunc.h"
 #include "core/fpdfapi/page/cpdf_psfunc.h"
 #include "core/fpdfapi/page/cpdf_sampledfunc.h"
 #include "core/fpdfapi/page/cpdf_stitchfunc.h"
 #include "core/fpdfapi/parser/cpdf_array.h"
 #include "core/fpdfapi/parser/cpdf_dictionary.h"
 #include "core/fpdfapi/parser/cpdf_stream.h"
 #include "core/fpdfapi/parser/fpdf_parser_utility.h"
 #include "core/fxcrt/fx_safe_types.h"
 #include "core/fxcrt/scoped_set_insertion.h"
 #include "core/fxcrt/stl_util.h"
 #include "third_party/base/containers/contains.h"
 #include "third_party/base/cxx17_backports.h"

 namespace {

 CPDF_Function::Type IntegerToFunctionType(int iType) {
   switch (iType) {
     case 0:
     case 2:
     case 3:
     case 4:
       return static_cast<CPDF_Function::Type>(iType);
     default:
       return CPDF_Function::Type::kTypeInvalid;
   }
 }

 }  // namespace

 // static
 std::unique_ptr<CPDF_Function> CPDF_Function::Load(
     const CPDF_Object* pFuncObj) {
   std::set<const CPDF_Object*> visited;
   return Load(pFuncObj, &visited);
 }

 // static
 std::unique_ptr<CPDF_Function> CPDF_Function::Load(
     const CPDF_Object* pFuncObj,
     std::set<const CPDF_Object*>* pVisited) {
   if (!pFuncObj)
     return nullptr;

   if (pdfium::Contains(*pVisited, pFuncObj))
     return nullptr;
   ScopedSetInsertion<const CPDF_Object*> insertion(pVisited, pFuncObj);

   int iType = -1;
   if (const CPDF_Stream* pStream = pFuncObj->AsStream())
     iType = pStream->GetDict()->GetIntegerFor("FunctionType");
   else if (const CPDF_Dictionary* pDict = pFuncObj->AsDictionary())
     iType = pDict->GetIntegerFor("FunctionType");

   std::unique_ptr<CPDF_Function> pFunc;
   Type type = IntegerToFunctionType(iType);
   if (type == Type::kType0Sampled)
     pFunc = std::make_unique<CPDF_SampledFunc>();
   else if (type == Type::kType2ExponentialInterpolation)
     pFunc = std::make_unique<CPDF_ExpIntFunc>();
   else if (type == Type::kType3Stitching)
     pFunc = std::make_unique<CPDF_StitchFunc>();
   else if (type == Type::kType4PostScript)
     pFunc = std::make_unique<CPDF_PSFunc>();

   if (!pFunc || !pFunc->Init(pFuncObj, pVisited))
     return nullptr;

   return pFunc;
 }

 CPDF_Function::CPDF_Function(Type type) : m_Type(type) {}

 CPDF_Function::~CPDF_Function() = default;

 bool CPDF_Function::Init(const CPDF_Object* pObj,
                          std::set<const CPDF_Object*>* pVisited) {
   const CPDF_Stream* pStream = pObj->AsStream();
   const CPDF_Dictionary* pDict =
       pStream ? pStream->GetDict() : pObj->AsDictionary();

   const CPDF_Array* pDomains = pDict->GetArrayFor("Domain");
   if (!pDomains)
     return false;

   m_nInputs = fxcrt::CollectionSize<uint32_t>(*pDomains) / 2;
   if (m_nInputs == 0)
     return false;

   size_t nInputs = m_nInputs * 2;
   m_Domains = ReadArrayElementsToVector(pDomains, nInputs);

   const CPDF_Array* pRanges = pDict->GetArrayFor("Range");
   m_nOutputs = pRanges ? fxcrt::CollectionSize<uint32_t>(*pRanges) / 2 : 0;

   // Ranges are required for type 0 and type 4 functions. A non-zero
   // |m_nOutputs| here implied Ranges meets the requirements.
   bool bRangeRequired =
       m_Type == Type::kType0Sampled || m_Type == Type::kType4PostScript;
   if (bRangeRequired && m_nOutputs == 0)
     return false;

   if (m_nOutputs > 0) {
     size_t nOutputs = m_nOutputs * 2;
     m_Ranges = ReadArrayElementsToVector(pRanges, nOutputs);
   }

   uint32_t old_outputs = m_nOutputs;
   if (!v_Init(pObj, pVisited))
     return false;

   if (!m_Ranges.empty() && m_nOutputs > old_outputs) {
     FX_SAFE_SIZE_T nOutputs = m_nOutputs;
     nOutputs *= 2;
     m_Ranges.resize(nOutputs.ValueOrDie());
   }
   return true;
 }

 absl::optional<uint32_t> CPDF_Function::Call(
     pdfium::span<const float> inputs,
     pdfium::span<float> results) const {
   if (m_nInputs != inputs.size())
     return absl::nullopt;

   std::vector<float> clamped_inputs(m_nInputs);
   for (uint32_t i = 0; i < m_nInputs; i++) {
     float domain1 = m_Domains[i * 2];
     float domain2 = m_Domains[i * 2 + 1];
     if (domain1 > domain2)
       return absl::nullopt;

     clamped_inputs[i] = pdfium::clamp(inputs[i], domain1, domain2);
   }
   if (!v_Call(clamped_inputs, results))
     return absl::nullopt;

   if (m_Ranges.empty())
     return m_nOutputs;

   for (uint32_t i = 0; i < m_nOutputs; i++) {
     float range1 = m_Ranges[i * 2];
     float range2 = m_Ranges[i * 2 + 1];
     if (range1 > range2)
       return absl::nullopt;

     results[i] = pdfium::clamp(results[i], range1, range2);
   }
   return m_nOutputs;
 }

 // See PDF Reference 1.7, page 170.
 float CPDF_Function::Interpolate(float x,
                                  float xmin,
                                  float xmax,
                                  float ymin,
                                  float ymax) const {
   float divisor = xmax - xmin;
   return ymin + (divisor ? (x - xmin) * (ymax - ymin) / divisor : 0);
 }

 #if defined(_SKIA_SUPPORT_) || defined(_SKIA_SUPPORT_PATHS_)
 const CPDF_SampledFunc* CPDF_Function::ToSampledFunc() const {
   return m_Type == Type::kType0Sampled
              ? static_cast<const CPDF_SampledFunc*>(this)
              : nullptr;
 }

 const CPDF_ExpIntFunc* CPDF_Function::ToExpIntFunc() const {
   return m_Type == Type::kType2ExponentialInterpolation
              ? static_cast<const CPDF_ExpIntFunc*>(this)
              : nullptr;
 }

 const CPDF_StitchFunc* CPDF_Function::ToStitchFunc() const {
   return m_Type == Type::kType3Stitching
              ? static_cast<const CPDF_StitchFunc*>(this)
              : nullptr;
 }
 #endif  // defined(_SKIA_SUPPORT_) || defined(_SKIA_SUPPORT_PATHS_)
	// Copyright 2017 PDFium Authors. All rights reserved.
	// 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/fpdfapi/page/cpdf_function.h"

	#include <vector>

	#include "core/fpdfapi/page/cpdf_expintfunc.h"
	#include "core/fpdfapi/page/cpdf_psfunc.h"
	#include "core/fpdfapi/page/cpdf_sampledfunc.h"
	#include "core/fpdfapi/page/cpdf_stitchfunc.h"
	#include "core/fpdfapi/parser/cpdf_array.h"
	#include "core/fpdfapi/parser/cpdf_dictionary.h"
	#include "core/fpdfapi/parser/cpdf_stream.h"
	#include "core/fpdfapi/parser/fpdf_parser_utility.h"
	#include "core/fxcrt/fx_safe_types.h"
	#include "core/fxcrt/scoped_set_insertion.h"
	#include "core/fxcrt/stl_util.h"
	#include "third_party/base/containers/contains.h"
	#include "third_party/base/cxx17_backports.h"

	namespace {

	CPDF_Function::Type IntegerToFunctionType(int iType) {
	switch (iType) {
	case 0:
	case 2:
	case 3:
	case 4:
	return static_cast<CPDF_Function::Type>(iType);
	default:
	return CPDF_Function::Type::kTypeInvalid;
	}
	}

	} // namespace

	// static
	std::unique_ptr<CPDF_Function> CPDF_Function::Load(
	const CPDF_Object* pFuncObj) {
	std::set<const CPDF_Object*> visited;
	return Load(pFuncObj, &visited);
	}

	// static
	std::unique_ptr<CPDF_Function> CPDF_Function::Load(
	const CPDF_Object* pFuncObj,
	std::set<const CPDF_Object> pVisited) {
	if (!pFuncObj)
	return nullptr;

	if (pdfium::Contains(*pVisited, pFuncObj))
	return nullptr;
	ScopedSetInsertion<const CPDF_Object*> insertion(pVisited, pFuncObj);

	int iType = -1;
	if (const CPDF_Stream* pStream = pFuncObj->AsStream())
	iType = pStream->GetDict()->GetIntegerFor("FunctionType");
	else if (const CPDF_Dictionary* pDict = pFuncObj->AsDictionary())
	iType = pDict->GetIntegerFor("FunctionType");

	std::unique_ptr<CPDF_Function> pFunc;
	Type type = IntegerToFunctionType(iType);
	if (type == Type::kType0Sampled)
	pFunc = std::make_unique<CPDF_SampledFunc>();
	else if (type == Type::kType2ExponentialInterpolation)
	pFunc = std::make_unique<CPDF_ExpIntFunc>();
	else if (type == Type::kType3Stitching)
	pFunc = std::make_unique<CPDF_StitchFunc>();
	else if (type == Type::kType4PostScript)
	pFunc = std::make_unique<CPDF_PSFunc>();

	if (!pFunc \|\| !pFunc->Init(pFuncObj, pVisited))
	return nullptr;

	return pFunc;
	}

	CPDF_Function::CPDF_Function(Type type) : m_Type(type) {}

	CPDF_Function::~CPDF_Function() = default;

	bool CPDF_Function::Init(const CPDF_Object* pObj,
	std::set<const CPDF_Object> pVisited) {
	const CPDF_Stream* pStream = pObj->AsStream();
	const CPDF_Dictionary* pDict =
	pStream ? pStream->GetDict() : pObj->AsDictionary();

	const CPDF_Array* pDomains = pDict->GetArrayFor("Domain");
	if (!pDomains)
	return false;

	m_nInputs = fxcrt::CollectionSize<uint32_t>(*pDomains) / 2;
	if (m_nInputs == 0)
	return false;

	size_t nInputs = m_nInputs * 2;
	m_Domains = ReadArrayElementsToVector(pDomains, nInputs);

	const CPDF_Array* pRanges = pDict->GetArrayFor("Range");
	m_nOutputs = pRanges ? fxcrt::CollectionSize<uint32_t>(*pRanges) / 2 : 0;

	// Ranges are required for type 0 and type 4 functions. A non-zero
	// \|m_nOutputs\| here implied Ranges meets the requirements.
	bool bRangeRequired =
	m_Type == Type::kType0Sampled \|\| m_Type == Type::kType4PostScript;
	if (bRangeRequired && m_nOutputs == 0)
	return false;

	if (m_nOutputs > 0) {
	size_t nOutputs = m_nOutputs * 2;
	m_Ranges = ReadArrayElementsToVector(pRanges, nOutputs);
	}

	uint32_t old_outputs = m_nOutputs;
	if (!v_Init(pObj, pVisited))
	return false;

	if (!m_Ranges.empty() && m_nOutputs > old_outputs) {
	FX_SAFE_SIZE_T nOutputs = m_nOutputs;
	nOutputs *= 2;
	m_Ranges.resize(nOutputs.ValueOrDie());
	}
	return true;
	}

	absl::optional<uint32_t> CPDF_Function::Call(
	pdfium::span<const float> inputs,
	pdfium::span<float> results) const {
	if (m_nInputs != inputs.size())
	return absl::nullopt;

	std::vector<float> clamped_inputs(m_nInputs);
	for (uint32_t i = 0; i < m_nInputs; i++) {
	float domain1 = m_Domains[i * 2];
	float domain2 = m_Domains[i * 2 + 1];
	if (domain1 > domain2)
	return absl::nullopt;

	clamped_inputs[i] = pdfium::clamp(inputs[i], domain1, domain2);
	}
	if (!v_Call(clamped_inputs, results))
	return absl::nullopt;

	if (m_Ranges.empty())
	return m_nOutputs;

	for (uint32_t i = 0; i < m_nOutputs; i++) {
	float range1 = m_Ranges[i * 2];
	float range2 = m_Ranges[i * 2 + 1];
	if (range1 > range2)
	return absl::nullopt;

	results[i] = pdfium::clamp(results[i], range1, range2);
	}
	return m_nOutputs;
	}

	// See PDF Reference 1.7, page 170.
	float CPDF_Function::Interpolate(float x,
	float xmin,
	float xmax,
	float ymin,
	float ymax) const {
	float divisor = xmax - xmin;
	return ymin + (divisor ? (x - xmin) * (ymax - ymin) / divisor : 0);
	}

	#if defined(_SKIA_SUPPORT_) \|\| defined(_SKIA_SUPPORT_PATHS_)
	const CPDF_SampledFunc* CPDF_Function::ToSampledFunc() const {
	return m_Type == Type::kType0Sampled
	? static_cast<const CPDF_SampledFunc*>(this)
	: nullptr;
	}

	const CPDF_ExpIntFunc* CPDF_Function::ToExpIntFunc() const {
	return m_Type == Type::kType2ExponentialInterpolation
	? static_cast<const CPDF_ExpIntFunc*>(this)
	: nullptr;
	}

	const CPDF_StitchFunc* CPDF_Function::ToStitchFunc() const {
	return m_Type == Type::kType3Stitching
	? static_cast<const CPDF_StitchFunc*>(this)
	: nullptr;
	}
	#endif // defined(_SKIA_SUPPORT_) \|\| defined(_SKIA_SUPPORT_PATHS_)