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pdfium / pdfium / f1ecbedf506e4bbe46ffb9131a1c592c6e3e1b2f / . / core / fpdfapi / page / cpdf_psengine.cpp
blob: 63560fccc02527dbe2e2952ebf225f1274381d28 [file] [log] [blame]
// 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_psengine.h"
#include <utility>
#include "core/fpdfapi/parser/cpdf_simple_parser.h"
#include "core/fxcrt/fx_safe_types.h"
#include "core/fxcrt/fx_string.h"
#include "third_party/base/logging.h"
#include "third_party/base/ptr_util.h"
namespace {
struct PDF_PSOpName {
const char* name;
PDF_PSOP op;
};
const PDF_PSOpName kPsOpNames[] = {
{"add", PSOP_ADD}, {"sub", PSOP_SUB},
{"mul", PSOP_MUL}, {"div", PSOP_DIV},
{"idiv", PSOP_IDIV}, {"mod", PSOP_MOD},
{"neg", PSOP_NEG}, {"abs", PSOP_ABS},
{"ceiling", PSOP_CEILING}, {"floor", PSOP_FLOOR},
{"round", PSOP_ROUND}, {"truncate", PSOP_TRUNCATE},
{"sqrt", PSOP_SQRT}, {"sin", PSOP_SIN},
{"cos", PSOP_COS}, {"atan", PSOP_ATAN},
{"exp", PSOP_EXP}, {"ln", PSOP_LN},
{"log", PSOP_LOG}, {"cvi", PSOP_CVI},
{"cvr", PSOP_CVR}, {"eq", PSOP_EQ},
{"ne", PSOP_NE}, {"gt", PSOP_GT},
{"ge", PSOP_GE}, {"lt", PSOP_LT},
{"le", PSOP_LE}, {"and", PSOP_AND},
{"or", PSOP_OR}, {"xor", PSOP_XOR},
{"not", PSOP_NOT}, {"bitshift", PSOP_BITSHIFT},
{"true", PSOP_TRUE}, {"false", PSOP_FALSE},
{"if", PSOP_IF}, {"ifelse", PSOP_IFELSE},
{"pop", PSOP_POP}, {"exch", PSOP_EXCH},
{"dup", PSOP_DUP}, {"copy", PSOP_COPY},
{"index", PSOP_INDEX}, {"roll", PSOP_ROLL}};
} // namespace
class CPDF_PSOP {
public:
explicit CPDF_PSOP(PDF_PSOP op) : m_op(op), m_value(0) {
ASSERT(m_op != PSOP_CONST);
ASSERT(m_op != PSOP_PROC);
}
explicit CPDF_PSOP(float value) : m_op(PSOP_CONST), m_value(value) {}
CPDF_PSOP()
: m_op(PSOP_PROC),
m_value(0),
m_proc(pdfium::MakeUnique<CPDF_PSProc>()) {}
float GetFloatValue() const {
if (m_op == PSOP_CONST)
return m_value;
NOTREACHED();
return 0;
}
CPDF_PSProc* GetProc() const {
if (m_op == PSOP_PROC)
return m_proc.get();
NOTREACHED();
return nullptr;
}
PDF_PSOP GetOp() const { return m_op; }
private:
const PDF_PSOP m_op;
const float m_value;
std::unique_ptr<CPDF_PSProc> m_proc;
};
bool CPDF_PSEngine::Execute() {
return m_MainProc.Execute(this);
}
CPDF_PSProc::CPDF_PSProc() {}
CPDF_PSProc::~CPDF_PSProc() {}
bool CPDF_PSProc::Execute(CPDF_PSEngine* pEngine) {
for (size_t i = 0; i < m_Operators.size(); ++i) {
const PDF_PSOP op = m_Operators[i]->GetOp();
if (op == PSOP_PROC)
continue;
if (op == PSOP_CONST) {
pEngine->Push(m_Operators[i]->GetFloatValue());
continue;
}
if (op == PSOP_IF) {
if (i == 0 || m_Operators[i - 1]->GetOp() != PSOP_PROC)
return false;
if (static_cast<int>(pEngine->Pop()))
m_Operators[i - 1]->GetProc()->Execute(pEngine);
} else if (op == PSOP_IFELSE) {
if (i < 2 || m_Operators[i - 1]->GetOp() != PSOP_PROC ||
m_Operators[i - 2]->GetOp() != PSOP_PROC) {
return false;
}
size_t offset = static_cast<int>(pEngine->Pop()) ? 2 : 1;
m_Operators[i - offset]->GetProc()->Execute(pEngine);
} else {
pEngine->DoOperator(op);
}
}
return true;
}
CPDF_PSEngine::CPDF_PSEngine() : m_StackCount(0) {}
CPDF_PSEngine::~CPDF_PSEngine() {}
void CPDF_PSEngine::Push(float v) {
if (m_StackCount < PSENGINE_STACKSIZE)
m_Stack[m_StackCount++] = v;
}
float CPDF_PSEngine::Pop() {
return m_StackCount > 0 ? m_Stack[--m_StackCount] : 0;
}
bool CPDF_PSEngine::Parse(const char* str, int size) {
CPDF_SimpleParser parser(reinterpret_cast<const uint8_t*>(str), size);
ByteStringView word = parser.GetWord();
return word == "{" ? m_MainProc.Parse(&parser, 0) : false;
}
bool CPDF_PSProc::Parse(CPDF_SimpleParser* parser, int depth) {
if (depth > kMaxDepth)
return false;
while (1) {
ByteStringView word = parser->GetWord();
if (word.IsEmpty())
return false;
if (word == "}")
return true;
if (word == "{") {
m_Operators.push_back(pdfium::MakeUnique<CPDF_PSOP>());
if (!m_Operators.back()->GetProc()->Parse(parser, depth + 1))
return false;
continue;
}
std::unique_ptr<CPDF_PSOP> op;
for (const PDF_PSOpName& op_name : kPsOpNames) {
if (word == ByteStringView(op_name.name)) {
op = pdfium::MakeUnique<CPDF_PSOP>(op_name.op);
break;
}
}
if (!op)
op = pdfium::MakeUnique<CPDF_PSOP>(FX_atof(word));
m_Operators.push_back(std::move(op));
}
}
bool CPDF_PSEngine::DoOperator(PDF_PSOP op) {
int i1;
int i2;
float d1;
float d2;
FX_SAFE_INT32 result;
switch (op) {
case PSOP_ADD:
d1 = Pop();
d2 = Pop();
Push(d1 + d2);
break;
case PSOP_SUB:
d2 = Pop();
d1 = Pop();
Push(d1 - d2);
break;
case PSOP_MUL:
d1 = Pop();
d2 = Pop();
Push(d1 * d2);
break;
case PSOP_DIV:
d2 = Pop();
d1 = Pop();
Push(d1 / d2);
break;
case PSOP_IDIV:
i2 = static_cast<int>(Pop());
i1 = static_cast<int>(Pop());
if (i2) {
result = i1;
result /= i2;
Push(result.ValueOrDefault(0));
} else {
Push(0);
}
break;
case PSOP_MOD:
i2 = static_cast<int>(Pop());
i1 = static_cast<int>(Pop());
if (i2) {
result = i1;
result %= i2;
Push(result.ValueOrDefault(0));
} else {
Push(0);
}
break;
case PSOP_NEG:
d1 = Pop();
Push(-d1);
break;
case PSOP_ABS:
d1 = Pop();
Push((float)fabs(d1));
break;
case PSOP_CEILING:
d1 = Pop();
Push((float)ceil(d1));
break;
case PSOP_FLOOR:
d1 = Pop();
Push((float)floor(d1));
break;
case PSOP_ROUND:
d1 = Pop();
Push(FXSYS_round(d1));
break;
case PSOP_TRUNCATE:
i1 = (int)Pop();
Push(i1);
break;
case PSOP_SQRT:
d1 = Pop();
Push((float)sqrt(d1));
break;
case PSOP_SIN:
d1 = Pop();
Push((float)sin(d1 * FX_PI / 180.0f));
break;
case PSOP_COS:
d1 = Pop();
Push((float)cos(d1 * FX_PI / 180.0f));
break;
case PSOP_ATAN:
d2 = Pop();
d1 = Pop();
d1 = (float)(atan2(d1, d2) * 180.0 / FX_PI);
if (d1 < 0) {
d1 += 360;
}
Push(d1);
break;
case PSOP_EXP:
d2 = Pop();
d1 = Pop();
Push((float)FXSYS_pow(d1, d2));
break;
case PSOP_LN:
d1 = Pop();
Push((float)log(d1));
break;
case PSOP_LOG:
d1 = Pop();
Push((float)log10(d1));
break;
case PSOP_CVI:
i1 = (int)Pop();
Push(i1);
break;
case PSOP_CVR:
break;
case PSOP_EQ:
d2 = Pop();
d1 = Pop();
Push((int)(d1 == d2));
break;
case PSOP_NE:
d2 = Pop();
d1 = Pop();
Push((int)(d1 != d2));
break;
case PSOP_GT:
d2 = Pop();
d1 = Pop();
Push((int)(d1 > d2));
break;
case PSOP_GE:
d2 = Pop();
d1 = Pop();
Push((int)(d1 >= d2));
break;
case PSOP_LT:
d2 = Pop();
d1 = Pop();
Push((int)(d1 < d2));
break;
case PSOP_LE:
d2 = Pop();
d1 = Pop();
Push((int)(d1 <= d2));
break;
case PSOP_AND:
i1 = (int)Pop();
i2 = (int)Pop();
Push(i1 & i2);
break;
case PSOP_OR:
i1 = (int)Pop();
i2 = (int)Pop();
Push(i1 | i2);
break;
case PSOP_XOR:
i1 = (int)Pop();
i2 = (int)Pop();
Push(i1 ^ i2);
break;
case PSOP_NOT:
i1 = (int)Pop();
Push((int)!i1);
break;
case PSOP_BITSHIFT: {
int shift = (int)Pop();
result = (int)Pop();
if (shift > 0) {
result <<= shift;
} else {
// Avoids unsafe negation of INT_MIN.
FX_SAFE_INT32 safe_shift = shift;
result >>= (-safe_shift).ValueOrDefault(0);
}
Push(result.ValueOrDefault(0));
break;
}
case PSOP_TRUE:
Push(1);
break;
case PSOP_FALSE:
Push(0);
break;
case PSOP_POP:
Pop();
break;
case PSOP_EXCH:
d2 = Pop();
d1 = Pop();
Push(d2);
Push(d1);
break;
case PSOP_DUP:
d1 = Pop();
Push(d1);
Push(d1);
break;
case PSOP_COPY: {
int n = static_cast<int>(Pop());
if (n < 0 || m_StackCount + n > PSENGINE_STACKSIZE ||
n > static_cast<int>(m_StackCount))
break;
for (int i = 0; i < n; i++)
m_Stack[m_StackCount + i] = m_Stack[m_StackCount + i - n];
m_StackCount += n;
break;
}
case PSOP_INDEX: {
int n = static_cast<int>(Pop());
if (n < 0 || n >= static_cast<int>(m_StackCount))
break;
Push(m_Stack[m_StackCount - n - 1]);
break;
}
case PSOP_ROLL: {
int j = static_cast<int>(Pop());
int n = static_cast<int>(Pop());
if (j == 0 || n == 0 || m_StackCount == 0)
break;
if (n < 0 || n > static_cast<int>(m_StackCount))
break;
j %= n;
if (j > 0)
j -= n;
auto* begin_it = std::begin(m_Stack) + m_StackCount - n;
auto* middle_it = begin_it - j;
auto* end_it = std::begin(m_Stack) + m_StackCount;
std::rotate(begin_it, middle_it, end_it);
break;
}
default:
break;
}
return true;
}