metaforce/hecl/include/HECL/Frontend.hpp

196 lines
4.9 KiB
C++

#ifndef HECLFRONTEND_HPP
#define HECLFRONTEND_HPP
#include <string>
#include <vector>
#include <forward_list>
#include <Athena/Types.hpp>
namespace HECL
{
namespace Frontend
{
struct SourceLocation
{
int line = -1;
int col = -1;
SourceLocation() = default;
SourceLocation(int l, int c) : line(l), col(c) {}
};
class Diagnostics
{
std::string m_name;
public:
void setName(const std::string& name) {m_name = name;}
void reportParserErr(const SourceLocation& l, const char* format, ...);
void reportLexerErr(const SourceLocation& l, const char* format, ...);
};
class Parser
{
public:
enum TokenType
{
TokenNone,
TokenSourceBegin,
TokenSourceEnd,
TokenNumLiteral,
TokenVectorSwizzle,
TokenEvalGroupStart,
TokenEvalGroupEnd,
TokenFunctionStart,
TokenFunctionEnd,
TokenFunctionArgDelim,
TokenArithmeticOp,
};
private:
Diagnostics& m_diag;
const std::string* m_source = nullptr;
std::string::const_iterator m_sourceIt;
std::vector<TokenType> m_parenStack;
bool m_reset = false;
void skipWhitespace(std::string::const_iterator& it);
public:
struct Token
{
TokenType m_type;
SourceLocation m_location;
std::string m_tokenString;
int m_tokenInt = 0;
float m_tokenFloat = 0.0;
Token() : m_type(TokenNone) {}
Token(TokenType type, SourceLocation loc) : m_type(type), m_location(loc) {}
};
void reset(const std::string& source);
Token consumeToken();
SourceLocation getLocation() const;
Parser(Diagnostics& diag) : m_diag(diag) {}
};
struct IR
{
enum OpType
{
OpNone, /**< NOP */
OpCall, /**< Deferred function insertion for HECL backend using specified I/O regs */
OpLoadImm, /**< Load a constant (numeric literal) into register */
OpArithmetic, /**< Perform binary arithmetic between registers */
OpSwizzle /**< Vector insertion/extraction/swizzling operation */
};
using RegID = int;
struct Instruction
{
OpType m_op = OpNone;
struct
{
std::string m_name;
RegID m_target;
} m_call;
struct
{
atVec4f m_immVec;
RegID m_target;
} m_loadImm;
enum ArithmeticOpType
{
ArithmeticOpNone,
ArithmeticOpAdd,
ArithmeticOpSubtract,
ArithmeticOpMultiply,
ArithmeticOpDivide
};
struct
{
ArithmeticOpType m_op = ArithmeticOpNone;
RegID m_a;
RegID m_b;
RegID m_target;
} m_arithmetic;
struct
{
RegID m_reg;
int m_idxs[4] = {-1};
RegID m_target;
} m_swizzle;
Instruction(OpType type) : m_op(type) {}
};
int m_regCount = 0;
std::vector<Instruction> m_instructions;
};
class Lexer
{
friend class OperationNode;
Diagnostics& m_diag;
/* Intermediate tree-node for organizing tokens into operations */
struct OperationNode
{
Parser::Token m_tok;
OperationNode* m_prev = nullptr;
OperationNode* m_next = nullptr;
OperationNode* m_sub = nullptr;
OperationNode() {}
OperationNode(Parser::Token&& tok) : m_tok(std::move(tok)) {}
};
/* Pool of nodes to keep ownership (forward_list so pointers aren't invalidated) */
std::forward_list<OperationNode> m_pool;
/* Final lexed root function (IR comes from this) */
OperationNode* m_root = nullptr;
/* Helper for relinking operator precedence */
static void ReconnectArithmetic(OperationNode* sn, OperationNode** lastSub, OperationNode** newSub);
/* Recursive IR compile funcs */
static void RecursiveFuncCompile(IR& ir, const Lexer::OperationNode* funcNode, IR::RegID target);
static void RecursiveGroupCompile(IR& ir, const Lexer::OperationNode* groupNode, IR::RegID target);
static void EmitVec3(IR& ir, const Lexer::OperationNode* funcNode, IR::RegID target);
static void EmitVec4(IR& ir, const Lexer::OperationNode* funcNode, IR::RegID target);
static void EmitArithmetic(IR& ir, const Lexer::OperationNode* arithNode, IR::RegID target);
static void EmitVectorSwizzle(IR& ir, const Lexer::OperationNode* swizNode, IR::RegID target);
public:
void reset();
void consumeAllTokens(Parser& parser);
IR compileIR() const;
Lexer(Diagnostics& diag) : m_diag(diag) {}
};
class Frontend
{
Diagnostics m_diag;
Parser m_parser;
Lexer m_lexer;
public:
IR compileSource(const std::string& source, const std::string& diagName)
{
m_diag.setName(diagName);
m_parser.reset(source);
m_lexer.consumeAllTokens(m_parser);
return m_lexer.compileIR();
}
Frontend() : m_parser(m_diag), m_lexer(m_diag) {}
};
}
}
#endif // HECLFRONTEND_HPP