// Copyright 2016 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_meshstream.h" #include "core/fpdfapi/page/cpdf_colorspace.h" #include "core/fpdfapi/page/pageint.h" #include "core/fpdfapi/parser/cpdf_array.h" namespace { // See PDF Reference 1.7, page 315, table 4.32. (Also table 4.33 and 4.34) bool ShouldCheckBPC(ShadingType type) { switch (type) { case kFreeFormGouraudTriangleMeshShading: case kLatticeFormGouraudTriangleMeshShading: case kCoonsPatchMeshShading: case kTensorProductPatchMeshShading: return true; default: return false; } } // Same references as ShouldCheckBPC() above. bool IsValidBitsPerComponent(uint32_t x) { switch (x) { case 1: case 2: case 4: case 8: case 12: case 16: return true; default: return false; } } // Same references as ShouldCheckBPC() above. bool IsValidBitsPerCoordinate(uint32_t x) { switch (x) { case 1: case 2: case 4: case 8: case 12: case 16: case 24: case 32: return true; default: return false; } } // See PDF Reference 1.7, page 315, table 4.32. (Also table 4.34) bool ShouldCheckBitsPerFlag(ShadingType type) { switch (type) { case kFreeFormGouraudTriangleMeshShading: case kCoonsPatchMeshShading: case kTensorProductPatchMeshShading: return true; default: return false; } } // Same references as ShouldCheckBitsPerFlag() above. bool IsValidBitsPerFlag(uint32_t x) { switch (x) { case 2: case 4: case 8: return true; default: return false; } } } // namespace CPDF_MeshVertex::CPDF_MeshVertex() = default; CPDF_MeshVertex::CPDF_MeshVertex(const CPDF_MeshVertex&) = default; CPDF_MeshVertex::~CPDF_MeshVertex() = default; CPDF_MeshStream::CPDF_MeshStream( ShadingType type, const std::vector<std::unique_ptr<CPDF_Function>>& funcs, CPDF_Stream* pShadingStream, CPDF_ColorSpace* pCS) : m_type(type), m_funcs(funcs), m_pShadingStream(pShadingStream), m_pCS(pCS), m_nCoordBits(0), m_nComponentBits(0), m_nFlagBits(0), m_nComponents(0), m_CoordMax(0), m_ComponentMax(0), m_xmin(0), m_xmax(0), m_ymin(0), m_ymax(0) { memset(&m_ColorMin, 0, sizeof(m_ColorMin)); memset(&m_ColorMax, 0, sizeof(m_ColorMax)); } bool CPDF_MeshStream::Load() { m_Stream.LoadAllData(m_pShadingStream); m_BitStream.Init(m_Stream.GetData(), m_Stream.GetSize()); CPDF_Dictionary* pDict = m_pShadingStream->GetDict(); m_nCoordBits = pDict->GetIntegerFor("BitsPerCoordinate"); m_nComponentBits = pDict->GetIntegerFor("BitsPerComponent"); if (ShouldCheckBPC(m_type)) { if (!IsValidBitsPerCoordinate(m_nCoordBits)) return false; if (!IsValidBitsPerComponent(m_nComponentBits)) return false; } m_nFlagBits = pDict->GetIntegerFor("BitsPerFlag"); if (ShouldCheckBitsPerFlag(m_type) && !IsValidBitsPerFlag(m_nFlagBits)) return false; uint32_t nComponents = m_pCS->CountComponents(); if (nComponents > kMaxComponents) return false; m_nComponents = m_funcs.empty() ? nComponents : 1; CPDF_Array* pDecode = pDict->GetArrayFor("Decode"); if (!pDecode || pDecode->GetCount() != 4 + m_nComponents * 2) return false; m_xmin = pDecode->GetNumberAt(0); m_xmax = pDecode->GetNumberAt(1); m_ymin = pDecode->GetNumberAt(2); m_ymax = pDecode->GetNumberAt(3); for (uint32_t i = 0; i < m_nComponents; ++i) { m_ColorMin[i] = pDecode->GetNumberAt(i * 2 + 4); m_ColorMax[i] = pDecode->GetNumberAt(i * 2 + 5); } if (ShouldCheckBPC(m_type)) { m_CoordMax = m_nCoordBits == 32 ? -1 : (1 << m_nCoordBits) - 1; m_ComponentMax = (1 << m_nComponentBits) - 1; } return true; } bool CPDF_MeshStream::CanReadFlag() const { return m_BitStream.BitsRemaining() >= m_nFlagBits; } bool CPDF_MeshStream::CanReadCoords() const { return m_BitStream.BitsRemaining() / 2 >= m_nCoordBits; } bool CPDF_MeshStream::CanReadColor() const { return m_BitStream.BitsRemaining() / m_nComponentBits >= m_nComponents; } uint32_t CPDF_MeshStream::ReadFlag() { ASSERT(ShouldCheckBitsPerFlag(m_type)); return m_BitStream.GetBits(m_nFlagBits) & 0x03; } CFX_PointF CPDF_MeshStream::ReadCoords() { ASSERT(ShouldCheckBPC(m_type)); CFX_PointF pos; if (m_nCoordBits == 32) { pos.x = m_xmin + m_BitStream.GetBits(m_nCoordBits) * (m_xmax - m_xmin) / static_cast<double>(m_CoordMax); pos.y = m_ymin + m_BitStream.GetBits(m_nCoordBits) * (m_ymax - m_ymin) / static_cast<double>(m_CoordMax); } else { pos.x = m_xmin + m_BitStream.GetBits(m_nCoordBits) * (m_xmax - m_xmin) / m_CoordMax; pos.y = m_ymin + m_BitStream.GetBits(m_nCoordBits) * (m_ymax - m_ymin) / m_CoordMax; } return pos; } std::tuple<FX_FLOAT, FX_FLOAT, FX_FLOAT> CPDF_MeshStream::ReadColor() { ASSERT(ShouldCheckBPC(m_type)); FX_FLOAT color_value[kMaxComponents]; for (uint32_t i = 0; i < m_nComponents; ++i) { color_value[i] = m_ColorMin[i] + m_BitStream.GetBits(m_nComponentBits) * (m_ColorMax[i] - m_ColorMin[i]) / m_ComponentMax; } FX_FLOAT r; FX_FLOAT g; FX_FLOAT b; if (m_funcs.empty()) { m_pCS->GetRGB(color_value, r, g, b); return std::tuple<FX_FLOAT, FX_FLOAT, FX_FLOAT>(r, g, b); } FX_FLOAT result[kMaxComponents]; FXSYS_memset(result, 0, sizeof(result)); int nResults; for (const auto& func : m_funcs) { if (func && func->CountOutputs() <= kMaxComponents) func->Call(color_value, 1, result, nResults); } m_pCS->GetRGB(result, r, g, b); return std::tuple<FX_FLOAT, FX_FLOAT, FX_FLOAT>(r, g, b); } bool CPDF_MeshStream::ReadVertex(const CFX_Matrix& pObject2Bitmap, CPDF_MeshVertex* vertex, uint32_t* flag) { if (!CanReadFlag()) return false; *flag = ReadFlag(); if (!CanReadCoords()) return false; vertex->position = pObject2Bitmap.Transform(ReadCoords()); if (!CanReadColor()) return false; std::tie(vertex->r, vertex->g, vertex->b) = ReadColor(); m_BitStream.ByteAlign(); return true; } bool CPDF_MeshStream::ReadVertexRow(const CFX_Matrix& pObject2Bitmap, int count, CPDF_MeshVertex* vertex) { for (int i = 0; i < count; i++) { if (m_BitStream.IsEOF() || !CanReadCoords()) return false; vertex[i].position = pObject2Bitmap.Transform(ReadCoords()); if (!CanReadColor()) return false; std::tie(vertex[i].r, vertex[i].g, vertex[i].b) = ReadColor(); m_BitStream.ByteAlign(); } return true; }