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Author SHA1 Message Date
7812b1064b Make progress on compiler posts 2019-10-26 20:30:29 -07:00
65b9f385cf Start working on runtime chapter 2019-10-15 11:13:13 -07:00
27 changed files with 1471 additions and 0 deletions

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cmake_minimum_required(VERSION 3.1)
project(compiler)
find_package(BISON)
find_package(FLEX)
bison_target(parser
${CMAKE_CURRENT_SOURCE_DIR}/parser.y
${CMAKE_CURRENT_BINARY_DIR}/parser.cpp
COMPILE_FLAGS "-d")
flex_target(scanner
${CMAKE_CURRENT_SOURCE_DIR}/scanner.l
${CMAKE_CURRENT_BINARY_DIR}/scanner.cpp)
add_flex_bison_dependency(scanner parser)
add_executable(compiler
ast.cpp ast.hpp definition.cpp
type_env.cpp type_env.hpp
env.cpp env.hpp
type.cpp type.hpp
error.cpp error.hpp
binop.cpp binop.hpp
instruction.cpp instruction.hpp
${BISON_parser_OUTPUTS}
${FLEX_scanner_OUTPUTS}
main.cpp
)
target_include_directories(compiler PUBLIC ${CMAKE_CURRENT_SOURCE_DIR})
target_include_directories(compiler PUBLIC ${CMAKE_CURRENT_BINARY_DIR})

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code/compiler/07/ast.cpp Normal file
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#include "ast.hpp"
#include <ostream>
#include "error.hpp"
static void print_indent(int n, std::ostream& to) {
while(n--) to << " ";
}
type_ptr ast::typecheck_common(type_mgr& mgr, const type_env& env) {
node_type = typecheck(mgr, env);
return node_type;
}
void ast::resolve_common(const type_mgr& mgr) {
type_var* var;
type_ptr resolved_type = mgr.resolve(node_type, var);
if(var) throw type_error("ambiguously typed program");
resolve(mgr);
node_type = std::move(resolved_type);
}
void ast_int::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "INT: " << value << std::endl;
}
type_ptr ast_int::typecheck(type_mgr& mgr, const type_env& env) const {
return type_ptr(new type_base("Int"));
}
void ast_int::resolve(const type_mgr& mgr) const {
}
void ast_int::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
into.push_back(instruction_ptr(new instruction_pushint(value)));
}
void ast_lid::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "LID: " << id << std::endl;
}
type_ptr ast_lid::typecheck(type_mgr& mgr, const type_env& env) const {
return env.lookup(id);
}
void ast_lid::resolve(const type_mgr& mgr) const {
}
void ast_lid::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
into.push_back(instruction_ptr(
env->has_variable(id) ?
(instruction*) new instruction_push(env->get_offset(id)) :
(instruction*) new instruction_pushglobal(id)));
}
void ast_uid::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "UID: " << id << std::endl;
}
type_ptr ast_uid::typecheck(type_mgr& mgr, const type_env& env) const {
return env.lookup(id);
}
void ast_uid::resolve(const type_mgr& mgr) const {
}
void ast_uid::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
into.push_back(instruction_ptr(new instruction_pushglobal(id)));
}
void ast_binop::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "BINOP: " << op_name(op) << std::endl;
left->print(indent + 1, to);
right->print(indent + 1, to);
}
type_ptr ast_binop::typecheck(type_mgr& mgr, const type_env& env) const {
type_ptr ltype = left->typecheck_common(mgr, env);
type_ptr rtype = right->typecheck_common(mgr, env);
type_ptr ftype = env.lookup(op_name(op));
if(!ftype) throw type_error(std::string("unknown binary operator ") + op_name(op));
type_ptr return_type = mgr.new_type();
type_ptr arrow_one = type_ptr(new type_arr(rtype, return_type));
type_ptr arrow_two = type_ptr(new type_arr(ltype, arrow_one));
mgr.unify(arrow_two, ftype);
return return_type;
}
void ast_binop::resolve(const type_mgr& mgr) const {
left->resolve_common(mgr);
right->resolve_common(mgr);
}
void ast_binop::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
right->compile(env, into);
left->compile(env_ptr(new env_offset(1, env)), into);
into.push_back(instruction_ptr(new instruction_pushglobal(op_name(op))));
into.push_back(instruction_ptr(new instruction_mkapp()));
into.push_back(instruction_ptr(new instruction_mkapp()));
}
void ast_app::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "APP:" << std::endl;
left->print(indent + 1, to);
right->print(indent + 1, to);
}
type_ptr ast_app::typecheck(type_mgr& mgr, const type_env& env) const {
type_ptr ltype = left->typecheck_common(mgr, env);
type_ptr rtype = right->typecheck_common(mgr, env);
type_ptr return_type = mgr.new_type();
type_ptr arrow = type_ptr(new type_arr(rtype, return_type));
mgr.unify(arrow, ltype);
return return_type;
}
void ast_app::resolve(const type_mgr& mgr) const {
left->resolve_common(mgr);
right->resolve_common(mgr);
}
void ast_app::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
right->compile(env, into);
left->compile(env_ptr(new env_offset(1, env)), into);
into.push_back(instruction_ptr(new instruction_mkapp()));
}
void ast_case::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "CASE: " << std::endl;
for(auto& branch : branches) {
print_indent(indent + 1, to);
branch->pat->print(to);
to << std::endl;
branch->expr->print(indent + 2, to);
}
}
type_ptr ast_case::typecheck(type_mgr& mgr, const type_env& env) const {
type_var* var;
type_ptr case_type = mgr.resolve(of->typecheck_common(mgr, env), var);
type_ptr branch_type = mgr.new_type();
for(auto& branch : branches) {
type_env new_env = env.scope();
branch->pat->match(case_type, mgr, new_env);
type_ptr curr_branch_type = branch->expr->typecheck_common(mgr, new_env);
mgr.unify(branch_type, curr_branch_type);
}
case_type = mgr.resolve(case_type, var);
if(!dynamic_cast<type_data*>(case_type.get())) {
throw type_error("attempting case analysis of non-data type");
}
return branch_type;
}
void ast_case::resolve(const type_mgr& mgr) const {
of->resolve_common(mgr);
for(auto& branch : branches) {
branch->expr->resolve_common(mgr);
}
}
void ast_case::compile(const env_ptr& env, std::vector<instruction_ptr>& into) const {
type_data* type = dynamic_cast<type_data*>(of->node_type.get());
of->compile(env, into);
into.push_back(instruction_ptr(new instruction_eval()));
instruction_jump* jump_instruction = new instruction_jump();
into.push_back(instruction_ptr(jump_instruction));
for(auto& branch : branches) {
std::vector<instruction_ptr> branch_instructions;
pattern_var* vpat;
pattern_constr* cpat;
if((vpat = dynamic_cast<pattern_var*>(branch->pat.get()))) {
branch->expr->compile(env_ptr(new env_offset(1, env)), branch_instructions);
for(auto& constr_pair : type->constructors) {
if(jump_instruction->tag_mappings.find(constr_pair.second.tag) !=
jump_instruction->tag_mappings.end())
break;
jump_instruction->tag_mappings[constr_pair.second.tag] =
jump_instruction->branches.size();
}
jump_instruction->branches.push_back(std::move(branch_instructions));
} else if((cpat = dynamic_cast<pattern_constr*>(branch->pat.get()))) {
env_ptr new_env = env;
for(auto it = cpat->params.rbegin(); it != cpat->params.rend(); it++) {
new_env = env_ptr(new env_var(*it, new_env));
}
branch_instructions.push_back(instruction_ptr(new instruction_split()));
branch->expr->compile(new_env, branch_instructions);
branch_instructions.push_back(instruction_ptr(new instruction_slide(
cpat->params.size())));
int new_tag = type->constructors[cpat->constr].tag;
if(jump_instruction->tag_mappings.find(new_tag) !=
jump_instruction->tag_mappings.end())
throw type_error("technically not a type error: duplicate pattern");
jump_instruction->tag_mappings[new_tag] =
jump_instruction->branches.size();
jump_instruction->branches.push_back(std::move(branch_instructions));
}
}
for(auto& constr_pair : type->constructors) {
if(jump_instruction->tag_mappings.find(constr_pair.second.tag) ==
jump_instruction->tag_mappings.end())
throw type_error("non-total pattern");
}
}
void pattern_var::print(std::ostream& to) const {
to << var;
}
void pattern_var::match(type_ptr t, type_mgr& mgr, type_env& env) const {
env.bind(var, t);
}
void pattern_constr::print(std::ostream& to) const {
to << constr;
for(auto& param : params) {
to << " " << param;
}
}
void pattern_constr::match(type_ptr t, type_mgr& mgr, type_env& env) const {
type_ptr constructor_type = env.lookup(constr);
if(!constructor_type) {
throw type_error(std::string("pattern using unknown constructor ") + constr);
}
for(int i = 0; i < params.size(); i++) {
type_arr* arr = dynamic_cast<type_arr*>(constructor_type.get());
if(!arr) throw type_error("too many parameters in constructor pattern");
env.bind(params[i], arr->left);
constructor_type = arr->right;
}
mgr.unify(t, constructor_type);
}

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code/compiler/07/ast.hpp Normal file
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#pragma once
#include <memory>
#include <vector>
#include "type.hpp"
#include "type_env.hpp"
#include "binop.hpp"
#include "instruction.hpp"
#include "env.hpp"
struct ast {
type_ptr node_type;
virtual ~ast() = default;
virtual void print(int indent, std::ostream& to) const = 0;
virtual type_ptr typecheck(type_mgr& mgr, const type_env& env) const = 0;
virtual void resolve(const type_mgr& mgr) const = 0;
virtual void compile(const env_ptr& env,
std::vector<instruction_ptr>& into) const = 0;
type_ptr typecheck_common(type_mgr& mgr, const type_env& env);
void resolve_common(const type_mgr& mgr);
};
using ast_ptr = std::unique_ptr<ast>;
struct pattern {
virtual ~pattern() = default;
virtual void print(std::ostream& to) const = 0;
virtual void match(type_ptr t, type_mgr& mgr, type_env& env) const = 0;
};
using pattern_ptr = std::unique_ptr<pattern>;
struct branch {
pattern_ptr pat;
ast_ptr expr;
branch(pattern_ptr p, ast_ptr a)
: pat(std::move(p)), expr(std::move(a)) {}
};
using branch_ptr = std::unique_ptr<branch>;
struct constructor {
std::string name;
std::vector<std::string> types;
constructor(std::string n, std::vector<std::string> ts)
: name(std::move(n)), types(std::move(ts)) {}
};
using constructor_ptr = std::unique_ptr<constructor>;
struct definition {
virtual ~definition() = default;
virtual void typecheck_first(type_mgr& mgr, type_env& env) = 0;
virtual void typecheck_second(type_mgr& mgr, const type_env& env) const = 0;
virtual void resolve(const type_mgr& mgr) = 0;
virtual void compile() = 0;
};
using definition_ptr = std::unique_ptr<definition>;
struct ast_int : public ast {
int value;
explicit ast_int(int v)
: value(v) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct ast_lid : public ast {
std::string id;
explicit ast_lid(std::string i)
: id(std::move(i)) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct ast_uid : public ast {
std::string id;
explicit ast_uid(std::string i)
: id(std::move(i)) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct ast_binop : public ast {
binop op;
ast_ptr left;
ast_ptr right;
ast_binop(binop o, ast_ptr l, ast_ptr r)
: op(o), left(std::move(l)), right(std::move(r)) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct ast_app : public ast {
ast_ptr left;
ast_ptr right;
ast_app(ast_ptr l, ast_ptr r)
: left(std::move(l)), right(std::move(r)) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct ast_case : public ast {
ast_ptr of;
std::vector<branch_ptr> branches;
ast_case(ast_ptr o, std::vector<branch_ptr> b)
: of(std::move(o)), branches(std::move(b)) {}
void print(int indent, std::ostream& to) const;
type_ptr typecheck(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr) const;
void compile(const env_ptr& env, std::vector<instruction_ptr>& into) const;
};
struct pattern_var : public pattern {
std::string var;
pattern_var(std::string v)
: var(std::move(v)) {}
void print(std::ostream &to) const;
void match(type_ptr t, type_mgr& mgr, type_env& env) const;
};
struct pattern_constr : public pattern {
std::string constr;
std::vector<std::string> params;
pattern_constr(std::string c, std::vector<std::string> p)
: constr(std::move(c)), params(std::move(p)) {}
void print(std::ostream &to) const;
void match(type_ptr t, type_mgr&, type_env& env) const;
};
struct definition_defn : public definition {
std::string name;
std::vector<std::string> params;
ast_ptr body;
type_ptr return_type;
std::vector<type_ptr> param_types;
std::vector<instruction_ptr> instructions;
definition_defn(std::string n, std::vector<std::string> p, ast_ptr b)
: name(std::move(n)), params(std::move(p)), body(std::move(b)) {
}
void typecheck_first(type_mgr& mgr, type_env& env);
void typecheck_second(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr);
void compile();
};
struct definition_data : public definition {
std::string name;
std::vector<constructor_ptr> constructors;
definition_data(std::string n, std::vector<constructor_ptr> cs)
: name(std::move(n)), constructors(std::move(cs)) {}
void typecheck_first(type_mgr& mgr, type_env& env);
void typecheck_second(type_mgr& mgr, const type_env& env) const;
void resolve(const type_mgr& mgr);
void compile();
};

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#include "binop.hpp"
std::string op_name(binop op) {
switch(op) {
case PLUS: return "+";
case MINUS: return "-";
case TIMES: return "*";
case DIVIDE: return "/";
}
return "??";
}
std::string op_action(binop op) {
switch(op) {
case PLUS: return "plus";
case MINUS: return "minus";
case TIMES: return "times";
case DIVIDE: return "divide";
}
return "??";
}

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#pragma once
#include <string>
enum binop {
PLUS,
MINUS,
TIMES,
DIVIDE
};
std::string op_name(binop op);
std::string op_action(binop op);

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#include "ast.hpp"
#include "error.hpp"
void definition_defn::typecheck_first(type_mgr& mgr, type_env& env) {
return_type = mgr.new_type();
type_ptr full_type = return_type;
for(auto it = params.rbegin(); it != params.rend(); it++) {
type_ptr param_type = mgr.new_type();
full_type = type_ptr(new type_arr(param_type, full_type));
param_types.push_back(param_type);
}
env.bind(name, full_type);
}
void definition_defn::typecheck_second(type_mgr& mgr, const type_env& env) const {
type_env new_env = env.scope();
auto param_it = params.begin();
auto type_it = param_types.rbegin();
while(param_it != params.end() && type_it != param_types.rend()) {
new_env.bind(*param_it, *type_it);
param_it++;
type_it++;
}
type_ptr body_type = body->typecheck_common(mgr, new_env);
mgr.unify(return_type, body_type);
}
void definition_defn::resolve(const type_mgr& mgr) {
type_var* var;
body->resolve_common(mgr);
return_type = mgr.resolve(return_type, var);
if(var) throw type_error("ambiguously typed program");
for(auto& param_type : param_types) {
param_type = mgr.resolve(param_type, var);
if(var) throw type_error("ambiguously typed program");
}
}
void definition_defn::compile() {
env_ptr new_env = env_ptr(new env_offset(0, nullptr));
for(auto it = params.rbegin(); it != params.rend(); it++) {
new_env = env_ptr(new env_var(*it, new_env));
}
body->compile(new_env, instructions);
instructions.push_back(instruction_ptr(new instruction_update(params.size())));
}
void definition_data::typecheck_first(type_mgr& mgr, type_env& env) {
type_data* this_type = new type_data(name);
type_ptr return_type = type_ptr(this_type);
int next_tag = 0;
for(auto& constructor : constructors) {
this_type->constructors[constructor->name] = { next_tag++ };
type_ptr full_type = return_type;
for(auto it = constructor->types.rbegin(); it != constructor->types.rend(); it++) {
type_ptr type = type_ptr(new type_base(*it));
full_type = type_ptr(new type_arr(type, full_type));
}
env.bind(constructor->name, full_type);
}
}
void definition_data::typecheck_second(type_mgr& mgr, const type_env& env) const {
// Nothing
}
void definition_data::resolve(const type_mgr& mgr) {
// Nothing
}
void definition_data::compile() {
}

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#include "env.hpp"
int env_var::get_offset(const std::string& name) const {
if(name == this->name) return 0;
if(parent) return parent->get_offset(name) + 1;
throw 0;
}
bool env_var::has_variable(const std::string& name) const {
if(name == this->name) return true;
if(parent) return parent->has_variable(name);
return false;
}
int env_offset::get_offset(const std::string& name) const {
if(parent) return parent->get_offset(name) + offset;
throw 0;
}
bool env_offset::has_variable(const std::string& name) const {
if(parent) return parent->has_variable(name);
return false;
}

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code/compiler/07/env.hpp Normal file
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#pragma once
#include <memory>
#include <string>
struct env {
virtual ~env() = default;
virtual int get_offset(const std::string& name) const = 0;
virtual bool has_variable(const std::string& name) const = 0;
};
using env_ptr = std::shared_ptr<env>;
struct env_var : public env {
std::string name;
env_ptr parent;
env_var(std::string& n, env_ptr p)
: name(std::move(n)), parent(std::move(p)) {}
int get_offset(const std::string& name) const;
bool has_variable(const std::string& name) const;
};
struct env_offset : public env {
int offset;
env_ptr parent;
env_offset(int o, env_ptr p)
: offset(o), parent(std::move(p)) {}
int get_offset(const std::string& name) const;
bool has_variable(const std::string& name) const;
};

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#include "error.hpp"
const char* type_error::what() const noexcept {
return "an error occured while checking the types of the program";
}

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#pragma once
#include <exception>
#include "type.hpp"
struct type_error : std::exception {
std::string description;
type_error(std::string d)
: description(std::move(d)) {}
const char* what() const noexcept override;
};
struct unification_error : public type_error {
type_ptr left;
type_ptr right;
unification_error(type_ptr l, type_ptr r)
: left(std::move(l)), right(std::move(r)),
type_error("failed to unify types") {}
};

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data Bool = { True, False }
defn main = { 3 + True }

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defn main = { 1 2 3 4 5 }

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data List = { Nil, Cons Int List }
defn head l = {
case l of {
Nil -> { 0 }
Cons x y z -> { x }
}
}

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defn main = { plus 320 6 }
defn plus x y = { x + y }

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defn add x y = { x + y }
defn double x = { add x x }
defn main = { double 163 }

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data List = { Nil, Cons Int List }
defn length l = {
case l of {
Nil -> { 0 }
Cons x xs -> { 1 + length xs }
}
}

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#include "instruction.hpp"
static void print_indent(int n, std::ostream& to) {
while(n--) to << " ";
}
void instruction_pushint::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "PushInt(" << value << ")" << std::endl;
}
void instruction_pushglobal::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "PushGlobal(" << name << ")" << std::endl;
}
void instruction_push::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Push(" << offset << ")" << std::endl;
}
void instruction_mkapp::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "MkApp()" << std::endl;
}
void instruction_update::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Update(" << offset << ")" << std::endl;
}
void instruction_pack::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Pack(" << tag << ", " << size << ")" << std::endl;
}
void instruction_split::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Split()" << std::endl;
}
void instruction_jump::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Jump(" << std::endl;
for(auto& instruction_set : branches) {
for(auto& instruction : instruction_set) {
instruction->print(indent + 2, to);
}
to << std::endl;
}
print_indent(indent, to);
to << ")" << std::endl;
}
void instruction_slide::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Slide(" << offset << ")" << std::endl;
}
void instruction_binop::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "BinOp(" << op_action(op) << ")" << std::endl;
}
void instruction_eval::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Eval()" << std::endl;
}
void instruction_alloc::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Alloc(" << amount << ")" << std::endl;
}
void instruction_unwind::print(int indent, std::ostream& to) const {
print_indent(indent, to);
to << "Unwind()" << std::endl;
}

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#pragma once
#include <string>
#include <memory>
#include <vector>
#include <map>
#include <ostream>
#include "binop.hpp"
struct instruction {
virtual ~instruction() = default;
virtual void print(int indent, std::ostream& to) const = 0;
};
using instruction_ptr = std::unique_ptr<instruction>;
struct instruction_pushint : public instruction {
int value;
instruction_pushint(int v)
: value(v) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_pushglobal : public instruction {
std::string name;
instruction_pushglobal(std::string n)
: name(std::move(n)) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_push : public instruction {
int offset;
instruction_push(int o)
: offset(o) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_mkapp : public instruction {
void print(int indent, std::ostream& to) const;
};
struct instruction_update : public instruction {
int offset;
instruction_update(int o)
: offset(o) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_pack : public instruction {
int tag;
int size;
instruction_pack(int t, int s)
: tag(t), size(s) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_split : public instruction {
void print(int indent, std::ostream& to) const;
};
struct instruction_jump : public instruction {
std::vector<std::vector<instruction_ptr>> branches;
std::map<int, int> tag_mappings;
void print(int indent, std::ostream& to) const;
};
struct instruction_slide : public instruction {
int offset;
instruction_slide(int o)
: offset(o) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_binop : public instruction {
binop op;
instruction_binop(binop o)
: op(o) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_eval : public instruction {
void print(int indent, std::ostream& to) const;
};
struct instruction_alloc : public instruction {
int amount;
instruction_alloc(int a)
: amount(a) {}
void print(int indent, std::ostream& to) const;
};
struct instruction_unwind : public instruction {
void print(int indent, std::ostream& to) const;
};

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#include "ast.hpp"
#include <iostream>
#include "parser.hpp"
#include "error.hpp"
#include "type.hpp"
void yy::parser::error(const std::string& msg) {
std::cout << "An error occured: " << msg << std::endl;
}
extern std::vector<definition_ptr> program;
void typecheck_program(
const std::vector<definition_ptr>& prog,
type_mgr& mgr, type_env& env) {
type_ptr int_type = type_ptr(new type_base("Int"));
type_ptr binop_type = type_ptr(new type_arr(
int_type,
type_ptr(new type_arr(int_type, int_type))));
env.bind("+", binop_type);
env.bind("-", binop_type);
env.bind("*", binop_type);
env.bind("/", binop_type);
for(auto& def : prog) {
def->typecheck_first(mgr, env);
}
for(auto& def : prog) {
def->typecheck_second(mgr, env);
}
for(auto& pair : env.names) {
std::cout << pair.first << ": ";
pair.second->print(mgr, std::cout);
std::cout << std::endl;
}
for(auto& def : prog) {
def->resolve(mgr);
}
}
void compile_program(const std::vector<definition_ptr>& prog) {
for(auto& def : prog) {
def->compile();
definition_defn* defn = dynamic_cast<definition_defn*>(def.get());
if(!defn) continue;
for(auto& instruction : defn->instructions) {
instruction->print(0, std::cout);
}
std::cout << std::endl;
}
}
int main() {
yy::parser parser;
type_mgr mgr;
type_env env;
parser.parse();
for(auto& definition : program) {
definition_defn* def = dynamic_cast<definition_defn*>(definition.get());
if(!def) continue;
std::cout << def->name;
for(auto& param : def->params) std::cout << " " << param;
std::cout << ":" << std::endl;
def->body->print(1, std::cout);
}
try {
typecheck_program(program, mgr, env);
compile_program(program);
} catch(unification_error& err) {
std::cout << "failed to unify types: " << std::endl;
std::cout << " (1) \033[34m";
err.left->print(mgr, std::cout);
std::cout << "\033[0m" << std::endl;
std::cout << " (2) \033[32m";
err.right->print(mgr, std::cout);
std::cout << "\033[0m" << std::endl;
} catch(type_error& err) {
std::cout << "failed to type check program: " << err.description << std::endl;
}
}

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%{
#include <string>
#include <iostream>
#include "ast.hpp"
#include "parser.hpp"
std::vector<definition_ptr> program;
extern yy::parser::symbol_type yylex();
%}
%token PLUS
%token TIMES
%token MINUS
%token DIVIDE
%token <int> INT
%token DEFN
%token DATA
%token CASE
%token OF
%token OCURLY
%token CCURLY
%token OPAREN
%token CPAREN
%token COMMA
%token ARROW
%token EQUAL
%token <std::string> LID
%token <std::string> UID
%language "c++"
%define api.value.type variant
%define api.token.constructor
%type <std::vector<std::string>> lowercaseParams uppercaseParams
%type <std::vector<definition_ptr>> program definitions
%type <std::vector<branch_ptr>> branches
%type <std::vector<constructor_ptr>> constructors
%type <ast_ptr> aAdd aMul case app appBase
%type <definition_ptr> definition defn data
%type <branch_ptr> branch
%type <pattern_ptr> pattern
%type <constructor_ptr> constructor
%start program
%%
program
: definitions { program = std::move($1); }
;
definitions
: definitions definition { $$ = std::move($1); $$.push_back(std::move($2)); }
| definition { $$ = std::vector<definition_ptr>(); $$.push_back(std::move($1)); }
;
definition
: defn { $$ = std::move($1); }
| data { $$ = std::move($1); }
;
defn
: DEFN LID lowercaseParams EQUAL OCURLY aAdd CCURLY
{ $$ = definition_ptr(
new definition_defn(std::move($2), std::move($3), std::move($6))); }
;
lowercaseParams
: %empty { $$ = std::vector<std::string>(); }
| lowercaseParams LID { $$ = std::move($1); $$.push_back(std::move($2)); }
;
uppercaseParams
: %empty { $$ = std::vector<std::string>(); }
| uppercaseParams UID { $$ = std::move($1); $$.push_back(std::move($2)); }
;
aAdd
: aAdd PLUS aMul { $$ = ast_ptr(new ast_binop(PLUS, std::move($1), std::move($3))); }
| aAdd MINUS aMul { $$ = ast_ptr(new ast_binop(MINUS, std::move($1), std::move($3))); }
| aMul { $$ = std::move($1); }
;
aMul
: aMul TIMES app { $$ = ast_ptr(new ast_binop(TIMES, std::move($1), std::move($3))); }
| aMul DIVIDE app { $$ = ast_ptr(new ast_binop(DIVIDE, std::move($1), std::move($3))); }
| app { $$ = std::move($1); }
;
app
: app appBase { $$ = ast_ptr(new ast_app(std::move($1), std::move($2))); }
| appBase { $$ = std::move($1); }
;
appBase
: INT { $$ = ast_ptr(new ast_int($1)); }
| LID { $$ = ast_ptr(new ast_lid(std::move($1))); }
| UID { $$ = ast_ptr(new ast_uid(std::move($1))); }
| OPAREN aAdd CPAREN { $$ = std::move($2); }
| case { $$ = std::move($1); }
;
case
: CASE aAdd OF OCURLY branches CCURLY
{ $$ = ast_ptr(new ast_case(std::move($2), std::move($5))); }
;
branches
: branches branch { $$ = std::move($1); $$.push_back(std::move($2)); }
| branch { $$ = std::vector<branch_ptr>(); $$.push_back(std::move($1));}
;
branch
: pattern ARROW OCURLY aAdd CCURLY
{ $$ = branch_ptr(new branch(std::move($1), std::move($4))); }
;
pattern
: LID { $$ = pattern_ptr(new pattern_var(std::move($1))); }
| UID lowercaseParams
{ $$ = pattern_ptr(new pattern_constr(std::move($1), std::move($2))); }
;
data
: DATA UID EQUAL OCURLY constructors CCURLY
{ $$ = definition_ptr(new definition_data(std::move($2), std::move($5))); }
;
constructors
: constructors COMMA constructor { $$ = std::move($1); $$.push_back(std::move($3)); }
| constructor
{ $$ = std::vector<constructor_ptr>(); $$.push_back(std::move($1)); }
;
constructor
: UID uppercaseParams
{ $$ = constructor_ptr(new constructor(std::move($1), std::move($2))); }
;

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#include <stdint.h>
#include <stdlib.h>
#include <assert.h>
struct stack;
enum node_tag {
NODE_APP,
NODE_NUM,
NODE_GLOBAL,
NODE_IND,
NODE_PACK
};
struct node_base {
enum node_tag tag;
};
struct node_app {
struct node_base base;
struct node_base* left;
struct node_base* right;
};
struct node_num {
struct node_base base;
int32_t value;
};
struct node_global {
struct node_base base;
void (*function)(struct stack*);
};
struct node_ind {
struct node_base base;
struct node_base* next;
};
struct node_data {
struct node_base base;
int8_t tag;
struct node_base** array;
};
struct node_base* alloc_node() {
node_base* new_node = malloc(sizeof(struct node_app));
assert(new_node != NULL);
return new_node;
}

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%option noyywrap
%{
#include <iostream>
#include "ast.hpp"
#include "parser.hpp"
#define YY_DECL yy::parser::symbol_type yylex()
%}
%%
[ \n]+ {}
\+ { return yy::parser::make_PLUS(); }
\* { return yy::parser::make_TIMES(); }
- { return yy::parser::make_MINUS(); }
\/ { return yy::parser::make_DIVIDE(); }
[0-9]+ { return yy::parser::make_INT(atoi(yytext)); }
defn { return yy::parser::make_DEFN(); }
data { return yy::parser::make_DATA(); }
case { return yy::parser::make_CASE(); }
of { return yy::parser::make_OF(); }
\{ { return yy::parser::make_OCURLY(); }
\} { return yy::parser::make_CCURLY(); }
\( { return yy::parser::make_OPAREN(); }
\) { return yy::parser::make_CPAREN(); }
, { return yy::parser::make_COMMA(); }
-> { return yy::parser::make_ARROW(); }
= { return yy::parser::make_EQUAL(); }
[a-z][a-zA-Z]* { return yy::parser::make_LID(std::string(yytext)); }
[A-Z][a-zA-Z]* { return yy::parser::make_UID(std::string(yytext)); }
%%

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#include "type.hpp"
#include <sstream>
#include <algorithm>
#include "error.hpp"
void type_var::print(const type_mgr& mgr, std::ostream& to) const {
auto it = mgr.types.find(name);
if(it != mgr.types.end()) {
it->second->print(mgr, to);
} else {
to << name;
}
}
void type_base::print(const type_mgr& mgr, std::ostream& to) const {
to << name;
}
void type_arr::print(const type_mgr& mgr, std::ostream& to) const {
left->print(mgr, to);
to << " -> (";
right->print(mgr, to);
to << ")";
}
std::string type_mgr::new_type_name() {
int temp = last_id++;
std::string str = "";
while(temp != -1) {
str += (char) ('a' + (temp % 26));
temp = temp / 26 - 1;
}
std::reverse(str.begin(), str.end());
return str;
}
type_ptr type_mgr::new_type() {
return type_ptr(new type_var(new_type_name()));
}
type_ptr type_mgr::new_arrow_type() {
return type_ptr(new type_arr(new_type(), new_type()));
}
type_ptr type_mgr::resolve(type_ptr t, type_var*& var) const {
type_var* cast;
var = nullptr;
while((cast = dynamic_cast<type_var*>(t.get()))) {
auto it = types.find(cast->name);
if(it == types.end()) {
var = cast;
break;
}
t = it->second;
}
return t;
}
void type_mgr::unify(type_ptr l, type_ptr r) {
type_var* lvar;
type_var* rvar;
type_arr* larr;
type_arr* rarr;
type_base* lid;
type_base* rid;
l = resolve(l, lvar);
r = resolve(r, rvar);
if(lvar) {
bind(lvar->name, r);
return;
} else if(rvar) {
bind(rvar->name, l);
return;
} else if((larr = dynamic_cast<type_arr*>(l.get())) &&
(rarr = dynamic_cast<type_arr*>(r.get()))) {
unify(larr->left, rarr->left);
unify(larr->right, rarr->right);
return;
} else if((lid = dynamic_cast<type_base*>(l.get())) &&
(rid = dynamic_cast<type_base*>(r.get()))) {
if(lid->name == rid->name) return;
}
throw unification_error(l, r);
}
void type_mgr::bind(const std::string& s, type_ptr t) {
type_var* other = dynamic_cast<type_var*>(t.get());
if(other && other->name == s) return;
types[s] = t;
}

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#pragma once
#include <memory>
#include <map>
struct type_mgr;
struct type {
virtual ~type() = default;
virtual void print(const type_mgr& mgr, std::ostream& to) const = 0;
};
using type_ptr = std::shared_ptr<type>;
struct type_var : public type {
std::string name;
type_var(std::string n)
: name(std::move(n)) {}
void print(const type_mgr& mgr, std::ostream& to) const;
};
struct type_base : public type {
std::string name;
type_base(std::string n)
: name(std::move(n)) {}
void print(const type_mgr& mgr, std::ostream& to) const;
};
struct type_data : public type_base {
struct constructor {
int tag;
};
std::map<std::string, constructor> constructors;
type_data(std::string n)
: type_base(std::move(n)) {}
};
struct type_arr : public type {
type_ptr left;
type_ptr right;
type_arr(type_ptr l, type_ptr r)
: left(std::move(l)), right(std::move(r)) {}
void print(const type_mgr& mgr, std::ostream& to) const;
};
struct type_mgr {
int last_id = 0;
std::map<std::string, type_ptr> types;
std::string new_type_name();
type_ptr new_type();
type_ptr new_arrow_type();
void unify(type_ptr l, type_ptr r);
type_ptr resolve(type_ptr t, type_var*& var) const;
void bind(const std::string& s, type_ptr t);
};

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#include "type_env.hpp"
type_ptr type_env::lookup(const std::string& name) const {
auto it = names.find(name);
if(it != names.end()) return it->second;
if(parent) return parent->lookup(name);
return nullptr;
}
void type_env::bind(const std::string& name, type_ptr t) {
names[name] = t;
}
type_env type_env::scope() const {
return type_env(this);
}

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#pragma once
#include <map>
#include "type.hpp"
struct type_env {
std::map<std::string, type_ptr> names;
type_env const* parent = nullptr;
type_env(type_env const* p)
: parent(p) {}
type_env() : type_env(nullptr) {}
type_ptr lookup(const std::string& name) const;
void bind(const std::string& name, type_ptr t);
type_env scope() const;
};

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---
title: Compiling a Functional Language Using C++, Part 7 - Runtime
date: 2019-08-06T14:26:38-07:00
draft: true
tags: ["C and C++", "Functional Languages", "Compilers"]
---
Wikipedia has the following definition for a __runtime__:
> A [runtime] primarily implements portions of an execution model.
We know what our execution model is! We talked about it in Part 5 - it's the
lazy graph reduction we've been talking about. Creating and manipulating
graph nodes is slightly above hardware level, and all programs in our
functional language will rely on such manipulation (it's how they run!). Furthermore,
most G-machine instructions are also above hardware level (especially unwind!).
Push and Slide and other instructions are pretty complex instructions.
Most computers aren't stack machines. We'll have to implement
our own stack, and whenever a graph-building function will want to modify
the stack, it will have to call library routines for our stack implementation:
```C
void stack_push(struct stack* s, struct node_s* n);
struct node_s* stack_slide(struct stack* s, size_t c);
/* other stack operations */
```
Furthermore, we observe that Unwind does a lot of the heavy lifting in our
G-machine definition. After we build the graph,
Unwind is what picks it apart and performs function calls. Furthermore,
Unwind pushes Unwind back on the stack: once you've hit it,
you're continuing to Unwind until you reach a function call. This
effectively means we can implement Unwind as a loop:
```C
while(1) {
// Check for Unwind's first rule
// Check for Unwind's second rule
// ...
}
```
In this implementation, Unwind is in charge. We won't need to insert
the Unwind operations at the end of our generated functions, and you
may have noticed we've already been following this strategy in our
implementation of the G-machine compilation.
We can start working on an implementation of the runtime right now,
beginning with the nodes:
{{< codelines "C++" "compiler/07/runtime.c" 5 46 >}}
We have a variety of different nodes that can be on the stack, but without
the magic of C++'s `vtable` and RTTI, we have to take care of the bookkeeping
ourselves. We add an enum, `node_tag`, which we will use to indicate what
type of node we're looking at. We also add a "base class" `node_base`, which
contains the fields that all nodes must contain (only `tag` at the moment).
We then add to the beginning of each node struct a member of type
`node_base`. With this, a pointer to a node struct can be interpreted as a pointer
to `node_base`, which is our lowest common denominator. To go back, we
check the `tag` of `node_base`, and cast the pointer appropriately. This way,
we mimic inheritance, in a very basic manner.
We also add an `alloc_node`, which allocates a region of memory big enough
to be any node. We do this because we sometimes mutate nodes (replacing
expressions with the results of their evaluation), changing their type.
We then want to be able to change a node without reallocating memory.
Since the biggest node we have is `node_app`, that's the one we choose.