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ImHex/plugins/libimhex/include/hex/pattern_language/ast_node.hpp

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#pragma once
#include <hex/pattern_language/token.hpp>
#include <hex/pattern_language/evaluator.hpp>
#include <hex/pattern_language/pattern_data.hpp>
#include <algorithm>
#include <bit>
#include <optional>
#include <map>
#include <variant>
#include <vector>
#include <hex/pattern_language/ast_node_base.hpp>
namespace hex::pl {
class PatternData;
class ASTNodeAttribute : public ASTNode {
public:
explicit ASTNodeAttribute(std::string attribute, std::optional<std::string> value = std::nullopt)
: ASTNode(), m_attribute(std::move(attribute)), m_value(std::move(value)) { }
~ASTNodeAttribute() override = default;
ASTNodeAttribute(const ASTNodeAttribute &other) : ASTNode(other) {
this->m_attribute = other.m_attribute;
this->m_value = other.m_value;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeAttribute(*this);
}
[[nodiscard]] const std::string& getAttribute() const {
return this->m_attribute;
}
[[nodiscard]] const std::optional<std::string>& getValue() const {
return this->m_value;
}
private:
std::string m_attribute;
std::optional<std::string> m_value;
};
class ASTNodeLiteral : public ASTNode {
public:
explicit ASTNodeLiteral(Token::Literal literal) : ASTNode(), m_literal(literal) { }
ASTNodeLiteral(const ASTNodeLiteral&) = default;
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeLiteral(*this);
}
[[nodiscard]] const auto& getValue() const {
return this->m_literal;
}
private:
Token::Literal m_literal;
};
class ASTNodeMathematicalExpression : public ASTNode {
#define FLOAT_BIT_OPERATION(name) \
auto name(hex::floating_point auto left, auto right) const { LogConsole::abortEvaluation("invalid floating point operation", this); return 0; } \
auto name(auto left, hex::floating_point auto right) const { LogConsole::abortEvaluation("invalid floating point operation", this); return 0; } \
auto name(hex::floating_point auto left, hex::floating_point auto right) const { LogConsole::abortEvaluation("invalid floating point operation", this); return 0; } \
auto name(hex::integral auto left, hex::integral auto right) const
FLOAT_BIT_OPERATION(shiftLeft) {
return left << right;
}
FLOAT_BIT_OPERATION(shiftRight) {
return left >> right;
}
FLOAT_BIT_OPERATION(bitAnd) {
return left & right;
}
FLOAT_BIT_OPERATION(bitOr) {
return left | right;
}
FLOAT_BIT_OPERATION(bitXor) {
return left ^ right;
}
FLOAT_BIT_OPERATION(bitNot) {
return ~right;
}
FLOAT_BIT_OPERATION(modulus) {
return left % right;
}
#undef FLOAT_BIT_OPERATION
public:
ASTNodeMathematicalExpression(ASTNode *left, ASTNode *right, Token::Operator op)
: ASTNode(), m_left(left), m_right(right), m_operator(op) { }
~ASTNodeMathematicalExpression() override {
delete this->m_left;
delete this->m_right;
}
ASTNodeMathematicalExpression(const ASTNodeMathematicalExpression &other) : ASTNode(other) {
this->m_operator = other.m_operator;
this->m_left = other.m_left->clone();
this->m_right = other.m_right->clone();
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeMathematicalExpression(*this);
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
if (this->getLeftOperand() == nullptr || this->getRightOperand() == nullptr)
LogConsole::abortEvaluation("attempted to use void expression in mathematical expression", this);
auto *left = dynamic_cast<ASTNodeLiteral*>(this->getLeftOperand()->evaluate(evaluator));
auto *right = dynamic_cast<ASTNodeLiteral*>(this->getRightOperand()->evaluate(evaluator));
ON_SCOPE_EXIT { delete left; delete right; };
return std::visit(overloaded {
// TODO: :notlikethis:
[this](u128 left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](s128 left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](double left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](char left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](bool left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](std::string left, PatternData * const &right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, u128 right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, s128 right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, double right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, char right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, bool right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, std::string right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](PatternData * const &left, PatternData *right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](auto&& left, std::string right) -> ASTNode* { LogConsole::abortEvaluation("invalid operand used in mathematical expression", this); },
[this](std::string left, auto&& right) -> ASTNode* {
switch (this->getOperator()) {
case Token::Operator::Star: {
std::string result;
for (auto i = 0; i < right; i++)
result += left;
return new ASTNodeLiteral(result);
}
default:
LogConsole::abortEvaluation("invalid operand used in mathematical expression", this);
}
},
[this](std::string left, std::string right) -> ASTNode* {
switch (this->getOperator()) {
case Token::Operator::Plus:
return new ASTNodeLiteral(left + right);
case Token::Operator::BoolEquals:
return new ASTNodeLiteral(left == right);
case Token::Operator::BoolNotEquals:
return new ASTNodeLiteral(left != right);
case Token::Operator::BoolGreaterThan:
return new ASTNodeLiteral(left > right);
case Token::Operator::BoolLessThan:
return new ASTNodeLiteral(left < right);
case Token::Operator::BoolGreaterThanOrEquals:
return new ASTNodeLiteral(left >= right);
case Token::Operator::BoolLessThanOrEquals:
return new ASTNodeLiteral(left <= right);
default:
LogConsole::abortEvaluation("invalid operand used in mathematical expression", this);
}
},
[this](std::string left, char right) -> ASTNode* {
switch (this->getOperator()) {
case Token::Operator::Plus:
return new ASTNodeLiteral(left + right);
default:
LogConsole::abortEvaluation("invalid operand used in mathematical expression", this);
}
},
[this](char left, std::string right) -> ASTNode* {
switch (this->getOperator()) {
case Token::Operator::Plus:
return new ASTNodeLiteral(left + right);
default:
LogConsole::abortEvaluation("invalid operand used in mathematical expression", this);
}
},
[this](auto &&left, auto &&right) -> ASTNode* {
switch (this->getOperator()) {
case Token::Operator::Plus:
return new ASTNodeLiteral(left + right);
case Token::Operator::Minus:
return new ASTNodeLiteral(left - right);
case Token::Operator::Star:
return new ASTNodeLiteral(left * right);
case Token::Operator::Slash:
if (right == 0) LogConsole::abortEvaluation("division by zero!", this);
return new ASTNodeLiteral(left / right);
case Token::Operator::Percent:
if (right == 0) LogConsole::abortEvaluation("division by zero!", this);
return new ASTNodeLiteral(modulus(left, right));
case Token::Operator::ShiftLeft:
return new ASTNodeLiteral(shiftLeft(left, right));
case Token::Operator::ShiftRight:
return new ASTNodeLiteral(shiftRight(left, right));
case Token::Operator::BitAnd:
return new ASTNodeLiteral(bitAnd(left, right));
case Token::Operator::BitXor:
return new ASTNodeLiteral(bitXor(left, right));
case Token::Operator::BitOr:
return new ASTNodeLiteral(bitOr(left, right));
case Token::Operator::BitNot:
return new ASTNodeLiteral(bitNot(left, right));
case Token::Operator::BoolEquals:
return new ASTNodeLiteral(bool(left == right));
case Token::Operator::BoolNotEquals:
return new ASTNodeLiteral(bool(left != right));
case Token::Operator::BoolGreaterThan:
return new ASTNodeLiteral(bool(left > right));
case Token::Operator::BoolLessThan:
return new ASTNodeLiteral(bool(left < right));
case Token::Operator::BoolGreaterThanOrEquals:
return new ASTNodeLiteral(bool(left >= right));
case Token::Operator::BoolLessThanOrEquals:
return new ASTNodeLiteral(bool(left <= right));
case Token::Operator::BoolAnd:
return new ASTNodeLiteral(bool(left && right));
case Token::Operator::BoolXor:
return new ASTNodeLiteral(bool(left && !right || !left && right));
case Token::Operator::BoolOr:
return new ASTNodeLiteral(bool(left || right));
case Token::Operator::BoolNot:
return new ASTNodeLiteral(bool(!right));
default:
LogConsole::abortEvaluation("invalid operand used in mathematical expression", this);
}
}
}, left->getValue(), right->getValue());
}
[[nodiscard]] ASTNode *getLeftOperand() const { return this->m_left; }
[[nodiscard]] ASTNode *getRightOperand() const { return this->m_right; }
[[nodiscard]] Token::Operator getOperator() const { return this->m_operator; }
private:
ASTNode *m_left, *m_right;
Token::Operator m_operator;
};
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class ASTNodeTernaryExpression : public ASTNode {
public:
ASTNodeTernaryExpression(ASTNode *first, ASTNode *second, ASTNode *third, Token::Operator op)
: ASTNode(), m_first(first), m_second(second), m_third(third), m_operator(op) { }
~ASTNodeTernaryExpression() override {
delete this->m_first;
delete this->m_second;
delete this->m_third;
}
ASTNodeTernaryExpression(const ASTNodeTernaryExpression &other) : ASTNode(other) {
this->m_operator = other.m_operator;
this->m_first = other.m_first->clone();
this->m_second = other.m_second->clone();
this->m_third = other.m_third->clone();
}
[[nodiscard]] ASTNode* clone() const override {
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return new ASTNodeTernaryExpression(*this);
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
if (this->getFirstOperand() == nullptr || this->getSecondOperand() == nullptr || this->getThirdOperand() == nullptr)
LogConsole::abortEvaluation("attempted to use void expression in mathematical expression", this);
auto *first = dynamic_cast<ASTNodeLiteral*>(this->getFirstOperand()->evaluate(evaluator));
auto *second = dynamic_cast<ASTNodeLiteral*>(this->getSecondOperand()->evaluate(evaluator));
auto *third = dynamic_cast<ASTNodeLiteral*>(this->getThirdOperand()->evaluate(evaluator));
ON_SCOPE_EXIT { delete first; delete second; delete third; };
auto condition = std::visit(overloaded {
[this](std::string value) -> bool { return !value.empty(); },
[this](PatternData * const &) -> bool { LogConsole::abortEvaluation("cannot cast custom type to bool", this); },
[](auto &&value) -> bool { return bool(value); }
}, first->getValue());
return std::visit(overloaded {
[condition]<typename T>(const T &second, const T &third) -> ASTNode* { return new ASTNodeLiteral(condition ? second : third); },
[this](auto &&second, auto &&third) -> ASTNode* { LogConsole::abortEvaluation("operands to ternary expression have different types", this); }
}, second->getValue(), third->getValue());
}
[[nodiscard]] ASTNode *getFirstOperand() const { return this->m_first; }
[[nodiscard]] ASTNode *getSecondOperand() const { return this->m_second; }
[[nodiscard]] ASTNode *getThirdOperand() const { return this->m_third; }
[[nodiscard]] Token::Operator getOperator() const { return this->m_operator; }
2021-01-07 01:19:54 +01:00
private:
ASTNode *m_first, *m_second, *m_third;
Token::Operator m_operator;
};
class ASTNodeBuiltinType : public ASTNode {
public:
constexpr explicit ASTNodeBuiltinType(Token::ValueType type)
: ASTNode(), m_type(type) { }
[[nodiscard]] constexpr const auto& getType() const { return this->m_type; }
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeBuiltinType(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto offset = evaluator->dataOffset();
auto size = Token::getTypeSize(this->m_type);
evaluator->dataOffset() += size;
PatternData *pattern;
if (Token::isUnsigned(this->m_type))
pattern = new PatternDataUnsigned(offset, size, evaluator);
else if (Token::isSigned(this->m_type))
pattern = new PatternDataSigned(offset, size, evaluator);
else if (Token::isFloatingPoint(this->m_type))
pattern = new PatternDataFloat(offset, size, evaluator);
else if (this->m_type == Token::ValueType::Boolean)
pattern = new PatternDataBoolean(offset, evaluator);
else if (this->m_type == Token::ValueType::Character)
pattern = new PatternDataCharacter(offset, evaluator);
else if (this->m_type == Token::ValueType::Character16)
pattern = new PatternDataCharacter16(offset, evaluator);
else if (this->m_type == Token::ValueType::Padding)
pattern = new PatternDataPadding(offset, 1, evaluator);
else if (this->m_type == Token::ValueType::String)
pattern = new PatternDataString(offset, 1, evaluator);
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else if (this->m_type == Token::ValueType::Auto)
return { nullptr };
else
LogConsole::abortEvaluation("invalid built-in type", this);
pattern->setTypeName(Token::getTypeName(this->m_type));
return { pattern };
}
private:
const Token::ValueType m_type;
};
class ASTNodeTypeDecl : public ASTNode, public Attributable {
public:
ASTNodeTypeDecl(std::string name, ASTNode *type, std::optional<std::endian> endian = std::nullopt)
: ASTNode(), m_name(std::move(name)), m_type(type), m_endian(endian) { }
ASTNodeTypeDecl(const ASTNodeTypeDecl& other) : ASTNode(other), Attributable(other) {
this->m_name = other.m_name;
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this->m_type = other.m_type;
this->m_endian = other.m_endian;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeTypeDecl(*this);
}
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void setName(const std::string &name) { this->m_name = name; }
[[nodiscard]] const std::string& getName() const { return this->m_name; }
[[nodiscard]] ASTNode* getType() { return this->m_type; }
[[nodiscard]] std::optional<std::endian> getEndian() const { return this->m_endian; }
[[nodiscard]] ASTNode *evaluate(Evaluator *evaluator) const override {
return this->m_type->evaluate(evaluator);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto patterns = this->m_type->createPatterns(evaluator);
for (auto &pattern : patterns) {
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if (pattern == nullptr)
continue;
if (!this->m_name.empty())
pattern->setTypeName(this->m_name);
pattern->setEndian(this->m_endian.value_or(evaluator->getDefaultEndian()));
}
return patterns;
}
private:
std::string m_name;
ASTNode *m_type;
std::optional<std::endian> m_endian;
};
class ASTNodeCast : public ASTNode {
public:
ASTNodeCast(ASTNode *value, ASTNode *type) : m_value(value), m_type(type) { }
ASTNodeCast(const ASTNodeCast &other) {
this->m_value = other.m_value->clone();
this->m_type = other.m_type->clone();
}
~ASTNodeCast() override {
delete this->m_value;
delete this->m_type;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeCast(*this);
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
auto literal = dynamic_cast<ASTNodeLiteral*>(this->m_value->evaluate(evaluator));
auto type = dynamic_cast<ASTNodeBuiltinType*>(this->m_type->evaluate(evaluator))->getType();
auto typePattern = this->m_type->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete typePattern; };
return std::visit(overloaded {
[&, this](PatternData * value) -> ASTNode* { LogConsole::abortEvaluation(hex::format("cannot cast custom type '{}' to '{}'", value->getTypeName(), Token::getTypeName(type)), this); },
[&, this](const std::string&) -> ASTNode* { LogConsole::abortEvaluation(hex::format("cannot cast string to '{}'", Token::getTypeName(type)), this); },
[&, this](auto &&value) -> ASTNode* {
auto endianAdjustedValue = hex::changeEndianess(value, typePattern->getSize(), typePattern->getEndian());
switch (type) {
case Token::ValueType::Unsigned8Bit:
return new ASTNodeLiteral(u128(u8(endianAdjustedValue)));
case Token::ValueType::Unsigned16Bit:
return new ASTNodeLiteral(u128(u16(endianAdjustedValue)));
case Token::ValueType::Unsigned32Bit:
return new ASTNodeLiteral(u128(u32(endianAdjustedValue)));
case Token::ValueType::Unsigned64Bit:
return new ASTNodeLiteral(u128(u64(endianAdjustedValue)));
case Token::ValueType::Unsigned128Bit:
return new ASTNodeLiteral(u128(endianAdjustedValue));
case Token::ValueType::Signed8Bit:
return new ASTNodeLiteral(s128(s8(endianAdjustedValue)));
case Token::ValueType::Signed16Bit:
return new ASTNodeLiteral(s128(s16(endianAdjustedValue)));
case Token::ValueType::Signed32Bit:
return new ASTNodeLiteral(s128(s32(endianAdjustedValue)));
case Token::ValueType::Signed64Bit:
return new ASTNodeLiteral(s128(s64(endianAdjustedValue)));
case Token::ValueType::Signed128Bit:
return new ASTNodeLiteral(s128(endianAdjustedValue));
case Token::ValueType::Float:
return new ASTNodeLiteral(double(float(endianAdjustedValue)));
case Token::ValueType::Double:
return new ASTNodeLiteral(double(endianAdjustedValue));
case Token::ValueType::Character:
return new ASTNodeLiteral(char(endianAdjustedValue));
case Token::ValueType::Character16:
return new ASTNodeLiteral(u128(char16_t(endianAdjustedValue)));
case Token::ValueType::Boolean:
return new ASTNodeLiteral(bool(endianAdjustedValue));
case Token::ValueType::String:
{
std::string string(sizeof(value), '\x00');
std::memcpy(string.data(), &value, string.size());
hex::trim(string);
if (typePattern->getEndian() != std::endian::native)
std::reverse(string.begin(), string.end());
return new ASTNodeLiteral(string);
}
default:
LogConsole::abortEvaluation(hex::format("cannot cast value to '{}'", Token::getTypeName(type)), this);
}
},
}, literal->getValue());
}
private:
ASTNode *m_value;
ASTNode *m_type;
};
class ASTNodeWhileStatement : public ASTNode {
public:
explicit ASTNodeWhileStatement(ASTNode *condition, std::vector<ASTNode*> body)
: ASTNode(), m_condition(condition), m_body(std::move(body)) { }
~ASTNodeWhileStatement() override {
delete this->m_condition;
for (auto &statement : this->m_body)
delete statement;
}
ASTNodeWhileStatement(const ASTNodeWhileStatement &other) : ASTNode(other) {
this->m_condition = other.m_condition->clone();
for (auto &statement : other.m_body)
this->m_body.push_back(statement->clone());
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeWhileStatement(*this);
}
[[nodiscard]] ASTNode* getCondition() {
return this->m_condition;
}
[[nodiscard]] const std::vector<ASTNode*>& getBody() {
return this->m_body;
}
FunctionResult execute(Evaluator *evaluator) override {
u64 loopIterations = 0;
while (evaluateCondition(evaluator)) {
evaluator->handleAbort();
auto variables = *evaluator->getScope(0).scope;
u32 startVariableCount = variables.size();
ON_SCOPE_EXIT {
s64 stackSize = evaluator->getStack().size();
for (u32 i = startVariableCount; i < variables.size(); i++) {
stackSize--;
delete variables[i];
}
if (stackSize < 0) LogConsole::abortEvaluation("stack pointer underflow!", this);
evaluator->getStack().resize(stackSize);
};
evaluator->pushScope(nullptr, variables);
ON_SCOPE_EXIT { evaluator->popScope(); };
for (auto &statement : this->m_body) {
auto [executionStopped, result] = statement->execute(evaluator);
if (executionStopped) {
return { true, result };
}
}
loopIterations++;
if (loopIterations >= evaluator->getLoopLimit())
LogConsole::abortEvaluation(hex::format("loop iterations exceeded limit of {}", evaluator->getLoopLimit()), this);
evaluator->handleAbort();
}
return { false, { } };
}
[[nodiscard]]
bool evaluateCondition(Evaluator *evaluator) const {
auto literal = dynamic_cast<ASTNodeLiteral*>(this->m_condition->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
return std::visit(overloaded {
[](std::string value) -> bool { return !value.empty(); },
[this](PatternData * const &) -> bool { LogConsole::abortEvaluation("cannot cast custom type to bool", this); },
[](auto &&value) -> bool { return value != 0; }
}, literal->getValue());
}
private:
ASTNode *m_condition;
std::vector<ASTNode*> m_body;
};
inline void applyVariableAttributes(Evaluator *evaluator, const Attributable *attributable, PatternData *pattern) {
auto endOffset = evaluator->dataOffset();
evaluator->dataOffset() = pattern->getOffset();
ON_SCOPE_EXIT { evaluator->dataOffset() = endOffset; };
for (ASTNodeAttribute *attribute : attributable->getAttributes()) {
auto &name = attribute->getAttribute();
auto value = attribute->getValue();
auto node = reinterpret_cast<const ASTNode*>(attributable);
auto requiresValue = [&]() {
if (!value.has_value())
LogConsole::abortEvaluation(hex::format("used attribute '{}' without providing a value", name), node);
return true;
};
auto noValue = [&]() {
if (value.has_value())
LogConsole::abortEvaluation(hex::format("provided a value to attribute '{}' which doesn't take one", name), node);
return true;
};
if (name == "color" && requiresValue()) {
u32 color = strtoul(value->c_str(), nullptr, 16);
pattern->setColor(hex::changeEndianess(color, std::endian::big) >> 8);
} else if (name == "name" && requiresValue()) {
pattern->setVariableName(*value);
} else if (name == "comment" && requiresValue()) {
pattern->setComment(*value);
} else if (name == "hidden" && noValue()) {
pattern->setHidden(true);
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} else if (name == "inline" && noValue()) {
auto inlinable = dynamic_cast<Inlinable*>(pattern);
if (inlinable == nullptr)
LogConsole::abortEvaluation("inline attribute can only be applied to nested types", node);
else
inlinable->setInlined(true);
} else if (name == "format" && requiresValue()) {
auto functions = evaluator->getCustomFunctions();
if (!functions.contains(*value))
LogConsole::abortEvaluation(hex::format("cannot find formatter function '{}'", *value), node);
const auto &function = functions[*value];
if (function.parameterCount != 1)
LogConsole::abortEvaluation("formatter function needs exactly one parameter", node);
pattern->setFormatterFunction(function);
} else if (name == "transform" && requiresValue()) {
auto functions = evaluator->getCustomFunctions();
if (!functions.contains(*value))
LogConsole::abortEvaluation(hex::format("cannot find transform function '{}'", *value), node);
const auto &function = functions[*value];
if (function.parameterCount != 1)
LogConsole::abortEvaluation("transform function needs exactly one parameter", node);
pattern->setTransformFunction(function);
} else if (name == "pointer_base" && requiresValue()) {
auto functions = evaluator->getCustomFunctions();
if (!functions.contains(*value))
LogConsole::abortEvaluation(hex::format("cannot find pointer base function '{}'", *value), node);
const auto &function = functions[*value];
if (function.parameterCount != 1)
LogConsole::abortEvaluation("pointer base function needs exactly one parameter", node);
if (auto pointerPattern = dynamic_cast<PatternDataPointer*>(pattern)) {
u128 value = 0;
evaluator->getProvider()->read(pattern->getOffset(), &value, pattern->getSize());
auto result = function.func(evaluator, { value });
if (!result.has_value())
LogConsole::abortEvaluation("pointer base function did not return a value", node);
pointerPattern->rebase(Token::literalToUnsigned(result.value()));
} else {
LogConsole::abortEvaluation("pointer_base attribute may only be applied to a pointer");
}
}
}
}
class ASTNodeVariableDecl : public ASTNode, public Attributable {
public:
ASTNodeVariableDecl(std::string name, ASTNode *type, ASTNode *placementOffset = nullptr)
: ASTNode(), m_name(std::move(name)), m_type(type), m_placementOffset(placementOffset) { }
ASTNodeVariableDecl(const ASTNodeVariableDecl &other) : ASTNode(other), Attributable(other) {
this->m_name = other.m_name;
this->m_type = other.m_type->clone();
if (other.m_placementOffset != nullptr)
this->m_placementOffset = other.m_placementOffset->clone();
else
this->m_placementOffset = nullptr;
}
~ASTNodeVariableDecl() override {
delete this->m_type;
delete this->m_placementOffset;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeVariableDecl(*this);
}
[[nodiscard]] const std::string& getName() const { return this->m_name; }
[[nodiscard]] constexpr ASTNode* getType() const { return this->m_type; }
[[nodiscard]] constexpr auto getPlacementOffset() const { return this->m_placementOffset; }
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
if (this->m_placementOffset != nullptr) {
auto offset = dynamic_cast<ASTNodeLiteral *>(this->m_placementOffset->evaluate(evaluator));
ON_SCOPE_EXIT { delete offset; };
evaluator->dataOffset() = std::visit(overloaded {
[this](std::string) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a string", this); },
[this](PatternData * const &) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a custom type", this); },
[](auto &&offset) -> u64 { return offset; }
}, offset->getValue());
}
auto pattern = this->m_type->createPatterns(evaluator).front();
pattern->setVariableName(this->m_name);
applyVariableAttributes(evaluator, this, pattern);
return { pattern };
}
FunctionResult execute(Evaluator *evaluator) override {
evaluator->createVariable(this->getName(), this->getType());
return { false, { } };
}
private:
std::string m_name;
ASTNode *m_type;
ASTNode *m_placementOffset;
};
class ASTNodeArrayVariableDecl : public ASTNode, public Attributable {
public:
ASTNodeArrayVariableDecl(std::string name, ASTNode *type, ASTNode *size, ASTNode *placementOffset = nullptr)
: ASTNode(), m_name(std::move(name)), m_type(type), m_size(size), m_placementOffset(placementOffset) { }
ASTNodeArrayVariableDecl(const ASTNodeArrayVariableDecl &other) : ASTNode(other), Attributable(other) {
this->m_name = other.m_name;
this->m_type = other.m_type->clone();
if (other.m_size != nullptr)
this->m_size = other.m_size->clone();
else
this->m_size = nullptr;
if (other.m_placementOffset != nullptr)
this->m_placementOffset = other.m_placementOffset->clone();
else
this->m_placementOffset = nullptr;
}
~ASTNodeArrayVariableDecl() override {
delete this->m_type;
delete this->m_size;
delete this->m_placementOffset;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeArrayVariableDecl(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
if (this->m_placementOffset != nullptr) {
auto offset = dynamic_cast<ASTNodeLiteral*>(this->m_placementOffset->evaluate(evaluator));
ON_SCOPE_EXIT { delete offset; };
evaluator->dataOffset() = std::visit(overloaded {
[this](std::string) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a string", this); },
[this](PatternData * const &) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a custom type", this); },
[](auto &&offset) -> u64 { return offset; }
}, offset->getValue());
}
auto type = this->m_type->evaluate(evaluator);
ON_SCOPE_EXIT { delete type; };
PatternData *pattern;
if (dynamic_cast<ASTNodeBuiltinType*>(type))
pattern = createStaticArray(evaluator);
else if (auto attributable = dynamic_cast<Attributable*>(type)) {
auto &attributes = attributable->getAttributes();
bool isStaticType = std::any_of(attributes.begin(), attributes.end(), [](ASTNodeAttribute *attribute) {
return attribute->getAttribute() == "static" && !attribute->getValue().has_value();
});
if (isStaticType)
pattern = createStaticArray(evaluator);
else
pattern = createDynamicArray(evaluator);
} else {
LogConsole::abortEvaluation("invalid type used in array", this);
}
applyVariableAttributes(evaluator, this, pattern);
return { pattern };
}
[[nodiscard]] const std::string& getName() const { return this->m_name; }
[[nodiscard]] constexpr ASTNode* getType() const { return this->m_type; }
[[nodiscard]] constexpr ASTNode* getSize() const { return this->m_size; }
[[nodiscard]] constexpr auto getPlacementOffset() const { return this->m_placementOffset; }
private:
std::string m_name;
ASTNode *m_type;
ASTNode *m_size;
ASTNode *m_placementOffset;
PatternData* createStaticArray(Evaluator *evaluator) const {
u64 startOffset = evaluator->dataOffset();
PatternData *templatePattern = this->m_type->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete templatePattern; };
evaluator->dataOffset() = startOffset;
u128 entryCount = 0;
if (this->m_size != nullptr) {
auto sizeNode = this->m_size->evaluate(evaluator);
ON_SCOPE_EXIT { delete sizeNode; };
if (auto literal = dynamic_cast<ASTNodeLiteral*>(sizeNode)) {
entryCount = std::visit(overloaded {
[this](std::string) -> u128 { LogConsole::abortEvaluation("cannot use string to index array", this); },
[this](PatternData*) -> u128 { LogConsole::abortEvaluation("cannot use custom type to index array", this); },
[](auto &&size) -> u128 { return size; }
}, literal->getValue());
} else if (auto whileStatement = dynamic_cast<ASTNodeWhileStatement*>(sizeNode)) {
while (whileStatement->evaluateCondition(evaluator)) {
entryCount++;
evaluator->dataOffset() += templatePattern->getSize();
evaluator->handleAbort();
}
}
} else {
std::vector<u8> buffer(templatePattern->getSize());
while (true) {
if (evaluator->dataOffset() >= evaluator->getProvider()->getActualSize() - buffer.size())
LogConsole::abortEvaluation("reached end of file before finding end of unsized array", this);
evaluator->getProvider()->read(evaluator->dataOffset(), buffer.data(), buffer.size());
evaluator->dataOffset() += buffer.size();
entryCount++;
bool reachedEnd = true;
for (u8 &byte : buffer) {
if (byte != 0x00) {
reachedEnd = false;
break;
}
}
if (reachedEnd) break;
evaluator->handleAbort();
}
}
PatternData *outputPattern;
if (dynamic_cast<PatternDataPadding*>(templatePattern)) {
outputPattern = new PatternDataPadding(startOffset, 0, evaluator);
} else if (dynamic_cast<PatternDataCharacter*>(templatePattern)) {
outputPattern = new PatternDataString(startOffset, 0, evaluator);
} else if (dynamic_cast<PatternDataCharacter16*>(templatePattern)) {
outputPattern = new PatternDataString16(startOffset, 0, evaluator);
} else {
auto arrayPattern = new PatternDataStaticArray(startOffset, 0, evaluator);
arrayPattern->setEntries(templatePattern->clone(), entryCount);
outputPattern = arrayPattern;
}
outputPattern->setVariableName(this->m_name);
outputPattern->setEndian(templatePattern->getEndian());
outputPattern->setColor(templatePattern->getColor());
outputPattern->setTypeName(templatePattern->getTypeName());
outputPattern->setSize(templatePattern->getSize() * entryCount);
evaluator->dataOffset() = startOffset + outputPattern->getSize();
return outputPattern;
}
PatternData* createDynamicArray(Evaluator *evaluator) const {
auto arrayPattern = new PatternDataDynamicArray(evaluator->dataOffset(), 0, evaluator);
arrayPattern->setVariableName(this->m_name);
std::vector<PatternData *> entries;
auto arrayCleanup = SCOPE_GUARD {
for (auto entry : entries)
delete entry;
};
size_t size = 0;
u64 entryCount = 0;
if (this->m_size != nullptr) {
auto sizeNode = this->m_size->evaluate(evaluator);
ON_SCOPE_EXIT { delete sizeNode; };
{
auto templatePattern = this->m_type->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete templatePattern; };
arrayPattern->setTypeName(templatePattern->getTypeName());
evaluator->dataOffset() -= templatePattern->getSize();
}
if (auto literal = dynamic_cast<ASTNodeLiteral*>(sizeNode)) {
entryCount = std::visit(overloaded{
[this](std::string) -> u128 { LogConsole::abortEvaluation("cannot use string to index array", this); },
[this](PatternData*) -> u128 { LogConsole::abortEvaluation("cannot use custom type to index array", this); },
[](auto &&size) -> u128 { return size; }
}, literal->getValue());
auto limit = evaluator->getArrayLimit();
if (entryCount > limit)
LogConsole::abortEvaluation(hex::format("array grew past set limit of {}", limit), this);
for (u64 i = 0; i < entryCount; i++) {
auto pattern = this->m_type->createPatterns(evaluator).front();
pattern->setVariableName(hex::format("[{}]", i));
pattern->setEndian(arrayPattern->getEndian());
pattern->setColor(arrayPattern->getColor());
entries.push_back(pattern);
size += pattern->getSize();
evaluator->handleAbort();
}
} else if (auto whileStatement = dynamic_cast<ASTNodeWhileStatement*>(sizeNode)) {
while (whileStatement->evaluateCondition(evaluator)) {
auto limit = evaluator->getArrayLimit();
if (entryCount > limit)
LogConsole::abortEvaluation(hex::format("array grew past set limit of {}", limit), this);
auto pattern = this->m_type->createPatterns(evaluator).front();
pattern->setVariableName(hex::format("[{}]", entryCount));
pattern->setEndian(arrayPattern->getEndian());
pattern->setColor(arrayPattern->getColor());
entries.push_back(pattern);
entryCount++;
size += pattern->getSize();
evaluator->handleAbort();
}
}
} else {
while (true) {
auto limit = evaluator->getArrayLimit();
if (entryCount > limit)
LogConsole::abortEvaluation(hex::format("array grew past set limit of {}", limit), this);
auto pattern = this->m_type->createPatterns(evaluator).front();
std::vector<u8> buffer(pattern->getSize());
if (evaluator->dataOffset() >= evaluator->getProvider()->getActualSize() - buffer.size()) {
delete pattern;
LogConsole::abortEvaluation("reached end of file before finding end of unsized array", this);
}
pattern->setVariableName(hex::format("[{}]", entryCount));
pattern->setEndian(arrayPattern->getEndian());
pattern->setColor(arrayPattern->getColor());
entries.push_back(pattern);
size += pattern->getSize();
entryCount++;
evaluator->getProvider()->read(evaluator->dataOffset() - pattern->getSize(), buffer.data(), buffer.size());
bool reachedEnd = true;
for (u8 &byte : buffer) {
if (byte != 0x00) {
reachedEnd = false;
break;
}
}
if (reachedEnd) break;
evaluator->handleAbort();
}
}
arrayPattern->setEntries(entries);
arrayPattern->setSize(size);
arrayCleanup.release();
return arrayPattern;
}
};
class ASTNodePointerVariableDecl : public ASTNode, public Attributable {
public:
ASTNodePointerVariableDecl(std::string name, ASTNode *type, ASTNode *sizeType, ASTNode *placementOffset = nullptr)
: ASTNode(), m_name(std::move(name)), m_type(type), m_sizeType(sizeType), m_placementOffset(placementOffset) { }
ASTNodePointerVariableDecl(const ASTNodePointerVariableDecl &other) : ASTNode(other), Attributable(other) {
this->m_name = other.m_name;
this->m_type = other.m_type->clone();
this->m_sizeType = other.m_sizeType->clone();
if (other.m_placementOffset != nullptr)
this->m_placementOffset = other.m_placementOffset->clone();
else
this->m_placementOffset = nullptr;
}
~ASTNodePointerVariableDecl() override {
delete this->m_type;
delete this->m_sizeType;
delete this->m_placementOffset;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodePointerVariableDecl(*this);
}
[[nodiscard]] const std::string& getName() const { return this->m_name; }
[[nodiscard]] constexpr ASTNode* getType() const { return this->m_type; }
[[nodiscard]] constexpr ASTNode* getSizeType() const { return this->m_sizeType; }
[[nodiscard]] constexpr auto getPlacementOffset() const { return this->m_placementOffset; }
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
if (this->m_placementOffset != nullptr) {
auto offset = dynamic_cast<ASTNodeLiteral *>(this->m_placementOffset->evaluate(evaluator));
ON_SCOPE_EXIT { delete offset; };
evaluator->dataOffset() = std::visit(overloaded {
[this](std::string) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a string", this); },
[this](PatternData*) -> u64 { LogConsole::abortEvaluation("placement offset cannot be a custom type", this); },
[](auto &&offset) -> u64 { return u64(offset); }
}, offset->getValue());
}
auto offset = evaluator->dataOffset();
auto sizePattern = this->m_sizeType->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete sizePattern; };
auto pattern = new PatternDataPointer(offset, sizePattern->getSize(), evaluator);
pattern->setVariableName(this->m_name);
offset = evaluator->dataOffset();
{
auto pointedAtPattern = this->m_type->createPatterns(evaluator).front();
u128 pointerAddress = 0;
evaluator->getProvider()->read(pattern->getOffset(), &pointerAddress, pattern->getSize());
pointedAtPattern->setOffset(pointerAddress);
pattern->setPointedAtPattern(pointedAtPattern);
}
evaluator->dataOffset() = offset;
applyVariableAttributes(evaluator, this, pattern);
return { pattern };
}
private:
std::string m_name;
ASTNode *m_type;
ASTNode *m_sizeType;
ASTNode *m_placementOffset;
};
class ASTNodeMultiVariableDecl : public ASTNode {
public:
explicit ASTNodeMultiVariableDecl(std::vector<ASTNode*> variables) : m_variables(std::move(variables)) { }
ASTNodeMultiVariableDecl(const ASTNodeMultiVariableDecl &other) : ASTNode(other) {
for (auto &variable : other.m_variables)
this->m_variables.push_back(variable->clone());
}
~ASTNodeMultiVariableDecl() override {
for (auto &variable : this->m_variables)
delete variable;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeMultiVariableDecl(*this);
}
[[nodiscard]] std::vector<ASTNode*> getVariables() {
return this->m_variables;
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
std::vector<PatternData*> patterns;
for (auto &node : this->m_variables) {
auto newPatterns = node->createPatterns(evaluator);
patterns.insert(patterns.end(), newPatterns.begin(), newPatterns.end());
}
return patterns;
}
FunctionResult execute(Evaluator *evaluator) override {
for (auto &variable : this->m_variables) {
auto variableDecl = dynamic_cast<ASTNodeVariableDecl*>(variable);
evaluator->createVariable(variableDecl->getName(), variableDecl->getType()->evaluate(evaluator));
}
return { false, { } };
}
private:
std::vector<ASTNode*> m_variables;
};
class ASTNodeStruct : public ASTNode, public Attributable {
public:
ASTNodeStruct() : ASTNode() { }
ASTNodeStruct(const ASTNodeStruct &other) : ASTNode(other), Attributable(other) {
for (const auto &otherMember : other.getMembers())
this->m_members.push_back(otherMember->clone());
for (const auto &otherInheritance : other.getInheritance())
this->m_inheritance.push_back(otherInheritance->clone());
}
~ASTNodeStruct() override {
for (auto &member : this->m_members)
delete member;
for (auto &inheritance : this->m_inheritance)
delete inheritance;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeStruct(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto pattern = new PatternDataStruct(evaluator->dataOffset(), 0, evaluator);
u64 startOffset = evaluator->dataOffset();
std::vector<PatternData*> memberPatterns;
auto structCleanup = SCOPE_GUARD {
delete pattern;
for (auto member : memberPatterns)
delete member;
};
evaluator->pushScope(pattern, memberPatterns);
for (auto inheritance : this->m_inheritance) {
auto inheritancePatterns = inheritance->createPatterns(evaluator).front();
ON_SCOPE_EXIT {
delete inheritancePatterns;
};
if (auto structPattern = dynamic_cast<PatternDataStruct*>(inheritancePatterns)) {
for (auto member : structPattern->getMembers()) {
memberPatterns.push_back(member->clone());
}
}
}
for (auto member : this->m_members) {
for (auto &memberPattern : member->createPatterns(evaluator)) {
memberPatterns.push_back(memberPattern);
}
}
evaluator->popScope();
pattern->setMembers(memberPatterns);
pattern->setSize(evaluator->dataOffset() - startOffset);
structCleanup.release();
return { pattern };
}
[[nodiscard]] const std::vector<ASTNode*>& getMembers() const { return this->m_members; }
void addMember(ASTNode *node) { this->m_members.push_back(node); }
[[nodiscard]] const std::vector<ASTNode*>& getInheritance() const { return this->m_inheritance; }
void addInheritance(ASTNode *node) { this->m_inheritance.push_back(node); }
private:
std::vector<ASTNode*> m_members;
std::vector<ASTNode*> m_inheritance;
};
class ASTNodeUnion : public ASTNode, public Attributable {
public:
ASTNodeUnion() : ASTNode() { }
ASTNodeUnion(const ASTNodeUnion &other) : ASTNode(other), Attributable(other) {
for (const auto &otherMember : other.getMembers())
this->m_members.push_back(otherMember->clone());
}
~ASTNodeUnion() override {
for (auto &member : this->m_members)
delete member;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeUnion(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto pattern = new PatternDataUnion(evaluator->dataOffset(), 0, evaluator);
size_t size = 0;
std::vector<PatternData*> memberPatterns;
u64 startOffset = evaluator->dataOffset();
auto unionCleanup = SCOPE_GUARD {
delete pattern;
for (auto member : memberPatterns)
delete member;
};
evaluator->pushScope(pattern, memberPatterns);
for (auto member : this->m_members) {
for (auto &memberPattern : member->createPatterns(evaluator)) {
memberPattern->setOffset(startOffset);
memberPatterns.push_back(memberPattern);
size = std::max(memberPattern->getSize(), size);
}
}
evaluator->popScope();
evaluator->dataOffset() = startOffset + size;
pattern->setMembers(memberPatterns);
pattern->setSize(size);
unionCleanup.release();
return { pattern };
}
[[nodiscard]] const std::vector<ASTNode*>& getMembers() const { return this->m_members; }
void addMember(ASTNode *node) { this->m_members.push_back(node); }
private:
std::vector<ASTNode*> m_members;
};
class ASTNodeEnum : public ASTNode, public Attributable {
2020-11-14 14:40:21 +01:00
public:
explicit ASTNodeEnum(ASTNode *underlyingType) : ASTNode(), m_underlyingType(underlyingType) { }
ASTNodeEnum(const ASTNodeEnum &other) : ASTNode(other), Attributable(other) {
for (const auto &[name, entry] : other.getEntries())
this->m_entries.emplace(name, entry->clone());
this->m_underlyingType = other.m_underlyingType->clone();
}
~ASTNodeEnum() override {
for (auto &[name, expr] : this->m_entries)
delete expr;
delete this->m_underlyingType;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeEnum(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto pattern = new PatternDataEnum(evaluator->dataOffset(), 0, evaluator);
auto enumCleanup = SCOPE_GUARD { delete pattern; };
std::vector<std::pair<Token::Literal, std::string>> enumEntries;
for (const auto &[name, value] : this->m_entries) {
auto literal = dynamic_cast<ASTNodeLiteral*>(value->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
enumEntries.emplace_back(literal->getValue(), name);
}
pattern->setEnumValues(enumEntries);
auto underlying = this->m_underlyingType->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete underlying; };
pattern->setSize(underlying->getSize());
pattern->setEndian(underlying->getEndian());
enumCleanup.release();
return { pattern };
}
[[nodiscard]] const std::map<std::string, ASTNode*>& getEntries() const { return this->m_entries; }
void addEntry(const std::string &name, ASTNode* expression) { this->m_entries.insert({ name, expression }); }
[[nodiscard]] ASTNode *getUnderlyingType() { return this->m_underlyingType; }
private:
std::map<std::string, ASTNode*> m_entries;
ASTNode *m_underlyingType;
};
class ASTNodeBitfield : public ASTNode, public Attributable {
public:
ASTNodeBitfield() : ASTNode() { }
ASTNodeBitfield(const ASTNodeBitfield &other) : ASTNode(other), Attributable(other) {
for (const auto &[name, entry] : other.getEntries())
this->m_entries.emplace_back(name, entry->clone());
}
~ASTNodeBitfield() override {
for (auto &[name, expr] : this->m_entries)
delete expr;
}
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[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeBitfield(*this);
}
[[nodiscard]] const std::vector<std::pair<std::string, ASTNode*>>& getEntries() const { return this->m_entries; }
void addEntry(const std::string &name, ASTNode* size) { this->m_entries.emplace_back(name, size); }
2020-11-14 14:40:21 +01:00
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto pattern = new PatternDataBitfield(evaluator->dataOffset(), 0, evaluator);
size_t bitOffset = 0;
std::vector<PatternData*> fields;
auto bitfieldCleanup = SCOPE_GUARD {
delete pattern;
for (auto field : fields)
delete field;
};
evaluator->pushScope(pattern, fields);
for (auto [name, bitSizeNode] : this->m_entries) {
auto literal = bitSizeNode->evaluate(evaluator);
ON_SCOPE_EXIT { delete literal; };
u8 bitSize = std::visit(overloaded {
[this](std::string) -> u8 { LogConsole::abortEvaluation("bitfield field size cannot be a string", this); },
[this](PatternData*) -> u8 { LogConsole::abortEvaluation("bitfield field size cannot be a custom type", this); },
[](auto &&offset) -> u8 { return static_cast<u8>(offset); }
}, dynamic_cast<ASTNodeLiteral*>(literal)->getValue());
// If a field is named padding, it was created through a padding expression and only advances the bit position
if (name != "padding") {
auto field = new PatternDataBitfieldField(evaluator->dataOffset(), bitOffset, bitSize, evaluator);
field->setVariableName(name);
fields.push_back(field);
}
bitOffset += bitSize;
}
evaluator->popScope();
pattern->setSize((bitOffset + 7) / 8);
pattern->setFields(fields);
evaluator->dataOffset() += pattern->getSize();
bitfieldCleanup.release();
return { pattern };
}
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private:
std::vector<std::pair<std::string, ASTNode*>> m_entries;
};
class ASTNodeRValue : public ASTNode {
public:
using Path = std::vector<std::variant<std::string, ASTNode*>>;
explicit ASTNodeRValue(Path path) : ASTNode(), m_path(std::move(path)) { }
ASTNodeRValue(const ASTNodeRValue&) = default;
~ASTNodeRValue() override {
for (auto &part : this->m_path) {
if (auto node = std::get_if<ASTNode*>(&part); node != nullptr)
delete *node;
}
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeRValue(*this);
}
[[nodiscard]]
const Path& getPath() const {
return this->m_path;
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
if (this->getPath().size() == 1) {
if (auto name = std::get_if<std::string>(&this->getPath().front()); name != nullptr) {
if (*name == "$") return new ASTNodeLiteral(u128(evaluator->dataOffset()));
}
}
auto pattern = this->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete pattern; };
auto readValue = [&evaluator](auto &value, PatternData *pattern) {
if (pattern->isLocal()) {
auto &literal = evaluator->getStack()[pattern->getOffset()];
std::visit(overloaded {
[&](std::string &assignmentValue) { },
[&](s128 assignmentValue) {
std::memcpy(&value, &assignmentValue, pattern->getSize());
value = hex::signExtend(pattern->getSize() * 8, value);
},
[&](auto &&assignmentValue) { std::memcpy(&value, &assignmentValue, pattern->getSize()); }
}, literal);
}
else
evaluator->getProvider()->read(pattern->getOffset(), &value, pattern->getSize());
value = hex::changeEndianess(value, pattern->getSize(), pattern->getEndian());
};
auto readString = [&evaluator](std::string &value, PatternData *pattern) {
if (pattern->isLocal()) {
auto &literal = evaluator->getStack()[pattern->getOffset()];
std::visit(overloaded {
[&](std::string &assignmentValue) { value = assignmentValue; },
[&](auto &&assignmentValue) { }
}, literal);
}
else {
value.resize(pattern->getSize());
evaluator->getProvider()->read(pattern->getOffset(), value.data(), value.size());
value.erase(std::find(value.begin(), value.end(), '\0'), value.end());
}
};
Token::Literal literal;
if (dynamic_cast<PatternDataUnsigned*>(pattern) || dynamic_cast<PatternDataEnum*>(pattern)) {
u128 value = 0;
readValue(value, pattern);
literal = value;
} else if (dynamic_cast<PatternDataSigned*>(pattern)) {
s128 value = 0;
readValue(value, pattern);
literal = value;
} else if (dynamic_cast<PatternDataFloat*>(pattern)) {
if (pattern->getSize() == sizeof(u16)) {
u16 value = 0;
readValue(value, pattern);
literal = double(float16ToFloat32(value));
} else if (pattern->getSize() == sizeof(float)) {
float value = 0;
readValue(value, pattern);
literal = double(value);
} else if (pattern->getSize() == sizeof(double)) {
double value = 0;
readValue(value, pattern);
literal = value;
} else LogConsole::abortEvaluation("invalid floating point type access", this);
} else if (dynamic_cast<PatternDataCharacter*>(pattern)) {
char value = 0;
readValue(value, pattern);
literal = value;
} else if (dynamic_cast<PatternDataBoolean*>(pattern)) {
bool value = false;
readValue(value, pattern);
literal = value;
} else if (dynamic_cast<PatternDataString*>(pattern)) {
std::string value;
if (pattern->isLocal()) {
auto &literal = evaluator->getStack()[pattern->getOffset()];
std::visit(overloaded {
[&](char assignmentValue) { if (assignmentValue != 0x00) value = std::string({ assignmentValue }); },
[&](std::string assignmentValue) { value = assignmentValue; },
[&, this](PatternData * const &assignmentValue) {
if (!dynamic_cast<PatternDataString*>(assignmentValue) && !dynamic_cast<PatternDataCharacter*>(assignmentValue))
LogConsole::abortEvaluation(hex::format("cannot assign '{}' to string", pattern->getTypeName()), this);
readString(value, assignmentValue);
},
[&, this](auto &&assignmentValue) { LogConsole::abortEvaluation(hex::format("cannot assign '{}' to string", pattern->getTypeName()), this); }
}, literal);
}
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else {
value.resize(pattern->getSize());
evaluator->getProvider()->read(pattern->getOffset(), value.data(), value.size());
value.erase(std::find(value.begin(), value.end(), '\0'), value.end());
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}
literal = value;
} else if (auto bitfieldFieldPattern = dynamic_cast<PatternDataBitfieldField*>(pattern)) {
u64 value = 0;
readValue(value, pattern);
literal = u128(hex::extract(bitfieldFieldPattern->getBitOffset() + (bitfieldFieldPattern->getBitSize() - 1), bitfieldFieldPattern->getBitOffset(), value));
} else {
literal = pattern->clone();
}
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if (auto transformFunc = pattern->getTransformFunction(); transformFunc.has_value() && pattern->getEvaluator() != nullptr) {
auto result = transformFunc->func(evaluator, { literal });
if (!result.has_value())
LogConsole::abortEvaluation("transform function did not return a value", this);
literal = result.value();
}
return new ASTNodeLiteral(literal);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
std::vector<PatternData*> searchScope;
PatternData *currPattern = nullptr;
s32 scopeIndex = 0;
if (!evaluator->isGlobalScope()){
auto globalScope = evaluator->getGlobalScope().scope;
std::copy(globalScope->begin(), globalScope->end(), std::back_inserter(searchScope));
}
{
auto currScope = evaluator->getScope(scopeIndex).scope;
std::copy(currScope->begin(), currScope->end(), std::back_inserter(searchScope));
}
for (const auto &part : this->getPath()) {
if (part.index() == 0) {
// Variable access
auto name = std::get<std::string>(part);
if (name == "parent") {
scopeIndex--;
searchScope = *evaluator->getScope(scopeIndex).scope;
auto currParent = evaluator->getScope(scopeIndex).parent;
if (currParent == nullptr)
LogConsole::abortEvaluation("no parent available", this);
currPattern = currParent->clone();
continue;
} else if (name == "this") {
searchScope = *evaluator->getScope(scopeIndex).scope;
auto currParent = evaluator->getScope(0).parent;
if (currParent == nullptr)
LogConsole::abortEvaluation("invalid use of 'this' outside of struct-like type", this);
currPattern = currParent->clone();
continue;
} else {
bool found = false;
for (auto iter = searchScope.crbegin(); iter != searchScope.crend(); ++iter) {
if ((*iter)->getVariableName() == name) {
auto newPattern = (*iter)->clone();
delete currPattern;
currPattern = newPattern;
found = true;
break;
}
}
if (name == "$")
LogConsole::abortEvaluation("invalid use of placeholder operator in rvalue");
if (!found)
LogConsole::abortEvaluation(hex::format("no variable named '{}' found", name), this);
}
} else {
// Array indexing
auto index = dynamic_cast<ASTNodeLiteral*>(std::get<ASTNode*>(part)->evaluate(evaluator));
ON_SCOPE_EXIT { delete index; };
std::visit(overloaded {
[](std::string) { throw std::string("cannot use string to index array"); },
[](PatternData * const &) { throw std::string("cannot use custom type to index array"); },
[&, this](auto &&index) {
if (auto dynamicArrayPattern = dynamic_cast<PatternDataDynamicArray*>(currPattern)) {
if (index >= searchScope.size() || index < 0)
LogConsole::abortEvaluation("array index out of bounds", this);
auto newPattern = searchScope[index]->clone();
delete currPattern;
currPattern = newPattern;
}
else if (auto staticArrayPattern = dynamic_cast<PatternDataStaticArray*>(currPattern)) {
if (index >= staticArrayPattern->getEntryCount() || index < 0)
LogConsole::abortEvaluation("array index out of bounds", this);
auto newPattern = searchScope.front()->clone();
delete currPattern;
currPattern = newPattern;
currPattern->setOffset(staticArrayPattern->getOffset() + index * staticArrayPattern->getSize());
}
}
}, index->getValue());
}
if (auto pointerPattern = dynamic_cast<PatternDataPointer*>(currPattern)) {
auto newPattern = pointerPattern->getPointedAtPattern()->clone();
delete currPattern;
currPattern = newPattern;
}
if (auto structPattern = dynamic_cast<PatternDataStruct*>(currPattern))
searchScope = structPattern->getMembers();
else if (auto unionPattern = dynamic_cast<PatternDataUnion*>(currPattern))
searchScope = unionPattern->getMembers();
else if (auto bitfieldPattern = dynamic_cast<PatternDataBitfield*>(currPattern))
searchScope = bitfieldPattern->getFields();
else if (auto dynamicArrayPattern = dynamic_cast<PatternDataDynamicArray*>(currPattern))
searchScope = dynamicArrayPattern->getEntries();
else if (auto staticArrayPattern = dynamic_cast<PatternDataStaticArray*>(currPattern))
searchScope = { staticArrayPattern->getTemplate() };
}
return { currPattern };
}
private:
Path m_path;
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};
class ASTNodeScopeResolution : public ASTNode {
public:
explicit ASTNodeScopeResolution(ASTNode *type, std::string name) : ASTNode(), m_type(type), m_name(std::move(name)) { }
ASTNodeScopeResolution(const ASTNodeScopeResolution &other) {
this->m_type = other.m_type->clone();
this->m_name = other.m_name;
}
~ASTNodeScopeResolution() override {
delete this->m_type;
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeScopeResolution(*this);
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
auto type = this->m_type->evaluate(evaluator);
ON_SCOPE_EXIT { delete type; };
if (auto enumType = dynamic_cast<ASTNodeEnum*>(type)) {
for (auto &[name, value] : enumType->getEntries()) {
if (name == this->m_name)
return value->evaluate(evaluator);
}
} else {
LogConsole::abortEvaluation("invalid scope resolution. Cannot access this type");
}
LogConsole::abortEvaluation(hex::format("could not find constant '{}'", this->m_name), this);
}
private:
ASTNode *m_type;
std::string m_name;
};
class ASTNodeConditionalStatement : public ASTNode {
public:
explicit ASTNodeConditionalStatement(ASTNode *condition, std::vector<ASTNode*> trueBody, std::vector<ASTNode*> falseBody)
: ASTNode(), m_condition(condition), m_trueBody(std::move(trueBody)), m_falseBody(std::move(falseBody)) { }
~ASTNodeConditionalStatement() override {
delete this->m_condition;
for (auto &statement : this->m_trueBody)
delete statement;
for (auto &statement : this->m_falseBody)
delete statement;
}
ASTNodeConditionalStatement(const ASTNodeConditionalStatement &other) : ASTNode(other) {
this->m_condition = other.m_condition->clone();
for (auto &statement : other.m_trueBody)
this->m_trueBody.push_back(statement->clone());
for (auto &statement : other.m_falseBody)
this->m_falseBody.push_back(statement->clone());
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeConditionalStatement(*this);
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
auto &scope = *evaluator->getScope(0).scope;
auto &body = evaluateCondition(evaluator) ? this->m_trueBody : this->m_falseBody;
for (auto &node : body) {
auto newPatterns = node->createPatterns(evaluator);
for (auto &pattern : newPatterns)
scope.push_back(pattern->clone());
}
return { };
}
[[nodiscard]] ASTNode* getCondition() {
return this->m_condition;
}
[[nodiscard]] const std::vector<ASTNode*>& getTrueBody() const {
return this->m_trueBody;
}
[[nodiscard]] const std::vector<ASTNode*>& getFalseBody() const {
return this->m_falseBody;
}
FunctionResult execute(Evaluator *evaluator) override {
auto &body = evaluateCondition(evaluator) ? this->m_trueBody : this->m_falseBody;
auto variables = *evaluator->getScope(0).scope;
u32 startVariableCount = variables.size();
ON_SCOPE_EXIT {
s64 stackSize = evaluator->getStack().size();
for (u32 i = startVariableCount; i < variables.size(); i++) {
stackSize--;
delete variables[i];
}
if (stackSize < 0) LogConsole::abortEvaluation("stack pointer underflow!", this);
evaluator->getStack().resize(stackSize);
};
evaluator->pushScope(nullptr, variables);
ON_SCOPE_EXIT { evaluator->popScope(); };
for (auto &statement : body) {
auto [executionStopped, result] = statement->execute(evaluator);
if (executionStopped) {
return { true, result };
}
}
return { false, { } };
}
private:
[[nodiscard]]
bool evaluateCondition(Evaluator *evaluator) const {
auto literal = dynamic_cast<ASTNodeLiteral*>(this->m_condition->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
return std::visit(overloaded {
[](std::string value) -> bool { return !value.empty(); },
[this](PatternData * const &) -> bool { LogConsole::abortEvaluation("cannot cast custom type to bool", this); },
[](auto &&value) -> bool { return value != 0; }
}, literal->getValue());
}
ASTNode *m_condition;
std::vector<ASTNode*> m_trueBody, m_falseBody;
};
class ASTNodeFunctionCall : public ASTNode {
public:
explicit ASTNodeFunctionCall(std::string functionName, std::vector<ASTNode*> params)
: ASTNode(), m_functionName(std::move(functionName)), m_params(std::move(params)) { }
~ASTNodeFunctionCall() override {
for (auto &param : this->m_params)
delete param;
}
ASTNodeFunctionCall(const ASTNodeFunctionCall &other) : ASTNode(other) {
this->m_functionName = other.m_functionName;
for (auto &param : other.m_params)
this->m_params.push_back(param->clone());
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeFunctionCall(*this);
}
[[nodiscard]] const std::string& getFunctionName() {
return this->m_functionName;
}
[[nodiscard]] const std::vector<ASTNode*>& getParams() const {
return this->m_params;
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
std::vector<Token::Literal> evaluatedParams;
for (auto param : this->m_params) {
auto expression = param->evaluate(evaluator);
ON_SCOPE_EXIT { delete expression; };
auto literal = dynamic_cast<ASTNodeLiteral*>(expression->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
evaluatedParams.push_back(literal->getValue());
}
auto &customFunctions = evaluator->getCustomFunctions();
auto functions = ContentRegistry::PatternLanguageFunctions::getEntries();
for (auto &func : customFunctions)
functions.insert(func);
if (!functions.contains(this->m_functionName))
LogConsole::abortEvaluation(hex::format("call to unknown function '{}'", this->m_functionName), this);
auto function = functions[this->m_functionName];
if (function.parameterCount == ContentRegistry::PatternLanguageFunctions::UnlimitedParameters) {
; // Don't check parameter count
}
else if (function.parameterCount & ContentRegistry::PatternLanguageFunctions::LessParametersThan) {
if (evaluatedParams.size() >= (function.parameterCount & ~ContentRegistry::PatternLanguageFunctions::LessParametersThan))
LogConsole::abortEvaluation(hex::format("too many parameters for function '{0}'. Expected {1}", this->m_functionName, function.parameterCount & ~ContentRegistry::PatternLanguageFunctions::LessParametersThan), this);
} else if (function.parameterCount & ContentRegistry::PatternLanguageFunctions::MoreParametersThan) {
if (evaluatedParams.size() <= (function.parameterCount & ~ContentRegistry::PatternLanguageFunctions::MoreParametersThan))
LogConsole::abortEvaluation(hex::format("too few parameters for function '{0}'. Expected {1}", this->m_functionName, function.parameterCount & ~ContentRegistry::PatternLanguageFunctions::MoreParametersThan), this);
} else if (function.parameterCount != evaluatedParams.size()) {
LogConsole::abortEvaluation(hex::format("invalid number of parameters for function '{0}'. Expected {1}", this->m_functionName, function.parameterCount), this);
}
try {
auto result = functions[this->m_functionName].func(evaluator, evaluatedParams);
if (result.has_value())
return new ASTNodeLiteral(result.value());
else
return new ASTNodeMathematicalExpression(nullptr, nullptr, Token::Operator::Plus);
} catch (std::string &error) {
LogConsole::abortEvaluation(error, this);
}
return nullptr;
}
FunctionResult execute(Evaluator *evaluator) override {
delete this->evaluate(evaluator);
return { false, { } };
}
private:
std::string m_functionName;
std::vector<ASTNode*> m_params;
};
class ASTNodeTypeOperator : public ASTNode {
public:
ASTNodeTypeOperator(Token::Operator op, ASTNode *expression) : m_op(op), m_expression(expression) {
}
ASTNodeTypeOperator(const ASTNodeTypeOperator &other) : ASTNode(other) {
this->m_op = other.m_op;
this->m_expression = other.m_expression->clone();
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeTypeOperator(*this);
}
~ASTNodeTypeOperator() override {
delete this->m_expression;
}
[[nodiscard]]
Token::Operator getOperator() const {
return this->m_op;
}
[[nodiscard]]
ASTNode* getExpression() const {
return this->m_expression;
}
[[nodiscard]]
ASTNode* evaluate(Evaluator *evaluator) const override {
auto pattern = this->m_expression->createPatterns(evaluator).front();
ON_SCOPE_EXIT { delete pattern; };
switch (this->getOperator()) {
case Token::Operator::AddressOf:
return new ASTNodeLiteral(u128(pattern->getOffset()));
case Token::Operator::SizeOf:
return new ASTNodeLiteral(u128(pattern->getSize()));
default:
LogConsole::abortEvaluation("invalid type operator", this);
}
}
private:
Token::Operator m_op;
ASTNode *m_expression;
};
class ASTNodeAssignment : public ASTNode {
public:
// TODO: Implement this
ASTNodeAssignment(std::string lvalueName, ASTNode *rvalue) : m_lvalueName(std::move(lvalueName)), m_rvalue(rvalue) {
}
ASTNodeAssignment(const ASTNodeAssignment &other) : ASTNode(other) {
this->m_lvalueName = other.m_lvalueName;
this->m_rvalue = other.m_rvalue->clone();
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeAssignment(*this);
}
~ASTNodeAssignment() override {
delete this->m_rvalue;
}
[[nodiscard]] const std::string& getLValueName() const {
return this->m_lvalueName;
}
[[nodiscard]] ASTNode* getRValue() const {
return this->m_rvalue;
}
FunctionResult execute(Evaluator *evaluator) override {
auto literal = dynamic_cast<ASTNodeLiteral*>(this->getRValue()->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
evaluator->setVariable(this->getLValueName(), literal->getValue());
return { false, { } };
}
private:
std::string m_lvalueName;
ASTNode *m_rvalue;
};
class ASTNodeReturnStatement : public ASTNode {
public:
// TODO: Implement this
explicit ASTNodeReturnStatement(ASTNode *rvalue) : m_rvalue(rvalue) {
}
ASTNodeReturnStatement(const ASTNodeReturnStatement &other) : ASTNode(other) {
this->m_rvalue = other.m_rvalue->clone();
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeReturnStatement(*this);
}
~ASTNodeReturnStatement() override {
delete this->m_rvalue;
}
[[nodiscard]] ASTNode* getReturnValue() const {
return this->m_rvalue;
}
FunctionResult execute(Evaluator *evaluator) override {
auto returnValue = this->getReturnValue();
if (returnValue == nullptr)
return { true, std::nullopt };
else {
auto literal = dynamic_cast<ASTNodeLiteral*>(returnValue->evaluate(evaluator));
ON_SCOPE_EXIT { delete literal; };
return { true, literal->getValue() };
}
}
private:
ASTNode *m_rvalue;
};
class ASTNodeFunctionDefinition : public ASTNode {
public:
// TODO: Implement this
ASTNodeFunctionDefinition(std::string name, std::vector<std::pair<std::string, ASTNode*>> params, std::vector<ASTNode*> body)
: m_name(std::move(name)), m_params(std::move(params)), m_body(std::move(body)) {
}
ASTNodeFunctionDefinition(const ASTNodeFunctionDefinition &other) : ASTNode(other) {
this->m_name = other.m_name;
this->m_params = other.m_params;
for (const auto &[name, type] : other.m_params) {
this->m_params.emplace_back(name, type->clone());
}
for (auto statement : other.m_body) {
this->m_body.push_back(statement->clone());
}
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeFunctionDefinition(*this);
}
~ASTNodeFunctionDefinition() override {
for (auto &[name, type] : this->m_params)
delete type;
for (auto statement : this->m_body)
delete statement;
}
[[nodiscard]] const std::string& getName() const {
return this->m_name;
}
[[nodiscard]] const auto& getParams() const {
return this->m_params;
}
[[nodiscard]] const auto& getBody() const {
return this->m_body;
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
evaluator->addCustomFunction(this->m_name, this->m_params.size(), [this](Evaluator *ctx, const std::vector<Token::Literal>& params) -> std::optional<Token::Literal> {
std::vector<PatternData*> variables;
ctx->pushScope(nullptr, variables);
ON_SCOPE_EXIT {
for (auto variable : variables)
delete variable;
ctx->popScope();
};
u32 paramIndex = 0;
for (const auto &[name, type] : this->m_params) {
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ctx->createVariable(name, type, params[paramIndex]);
ctx->setVariable(name, params[paramIndex]);
paramIndex++;
}
for (auto statement : this->m_body) {
auto [executionStopped, result] = statement->execute(ctx);
if (executionStopped) {
return result;
}
}
return { };
});
return nullptr;
}
private:
std::string m_name;
std::vector<std::pair<std::string, ASTNode*>> m_params;
std::vector<ASTNode*> m_body;
};
class ASTNodeCompoundStatement : public ASTNode {
public:
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ASTNodeCompoundStatement(std::vector<ASTNode*> statements, bool newScope = false) : m_statements(std::move(statements)), m_newScope(newScope) {
}
ASTNodeCompoundStatement(const ASTNodeCompoundStatement &other) : ASTNode(other) {
for (const auto &statement : other.m_statements) {
this->m_statements.push_back(statement->clone());
}
}
[[nodiscard]] ASTNode* clone() const override {
return new ASTNodeCompoundStatement(*this);
}
~ASTNodeCompoundStatement() override {
for (const auto &statement : this->m_statements) {
delete statement;
}
}
[[nodiscard]] ASTNode* evaluate(Evaluator *evaluator) const override {
ASTNode *result = nullptr;
for (const auto &statement : this->m_statements) {
delete result;
result = statement->evaluate(evaluator);
}
return result;
}
[[nodiscard]] std::vector<PatternData*> createPatterns(Evaluator *evaluator) const override {
std::vector<PatternData*> result;
for (const auto &statement : this->m_statements) {
auto patterns = statement->createPatterns(evaluator);
std::copy(patterns.begin(), patterns.end(), std::back_inserter(result));
}
return result;
}
FunctionResult execute(Evaluator *evaluator) override {
FunctionResult result;
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auto variables = *evaluator->getScope(0).scope;
u32 startVariableCount = variables.size();
if (this->m_newScope) {
evaluator->pushScope(nullptr, variables);
}
for (const auto &statement : this->m_statements) {
result = statement->execute(evaluator);
if (result.first)
return result;
}
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if (this->m_newScope) {
s64 stackSize = evaluator->getStack().size();
for (u32 i = startVariableCount; i < variables.size(); i++) {
stackSize--;
delete variables[i];
}
if (stackSize < 0) LogConsole::abortEvaluation("stack pointer underflow!", this);
evaluator->getStack().resize(stackSize);
evaluator->popScope();
}
return result;
}
public:
std::vector<ASTNode*> m_statements;
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bool m_newScope;
};
};