rayoko/src/codegen.zig

const std = @import("std");
const ast = @import("ast.zig");
const llvm = @import("llvm.zig");
const comp = @import("comp_ctx.zig");
// const analysis = @import("analysis.zig");

fn sliceify(non_slice: ?[*]const u8) []const u8 {
    if (non_slice == null) return "";
    return non_slice.?[0..std.mem.len(u8, non_slice.?)];
}

pub const CompileError = error{
    LLVMError,
    EmitError,
    TypeError,
};

fn mkLLVMBool(val: bool) llvm.LLVMValueRef {
    if (val) {
        return llvm.LLVMConstInt(llvm.LLVMInt1Type(), 1, 1);
    } else {
        return llvm.LLVMConstInt(llvm.LLVMInt1Type(), 0, 1);
    }
}

pub const LLVMTable = std.StringHashMap(llvm.LLVMValueRef);
pub const LLVMValueList = std.ArrayList(llvm.LLVMValueRef);

pub const Codegen = struct {
    allocator: *std.mem.Allocator,
    ctx: *comp.CompilationContext,
    llvm_table: LLVMTable,

    current_function_name: ?[]const u8 = null,

    pub fn init(allocator: *std.mem.Allocator, ctx: *comp.CompilationContext) Codegen {
        return Codegen{
            .allocator = allocator,
            .ctx = ctx,
            .llvm_table = LLVMTable.init(allocator),
        };
    }

    fn typeToLLVM(self: *@This(), typ: comp.SymbolUnderlyingType) !llvm.LLVMTypeRef {
        return switch (typ) {
            .Integer32 => llvm.LLVMInt32Type(),
            .Integer64 => llvm.LLVMInt64Type(),
            .Bool => llvm.LLVMInt1Type(),

            .OpaqueType => |val| {
                std.debug.warn("Invalid return type: {}\n", val);
                return CompileError.TypeError;
            },

            .Struct, .Enum => |lex| blk: {
                var sym_data = self.ctx.symbol_table.get(lex).?.value;
                break :blk switch (sym_data) {
                    .Struct => unreachable,
                    .Enum => llvm.LLVMInt32Type(),
                    else => {
                        std.debug.warn("Function {} is not a type\n", lex);
                        return CompileError.TypeError;
                    },
                };
            },

            else => {
                std.debug.warn("TODO handle {}\n", typ);
                return CompileError.TypeError;
            },
        };
    }

    fn emitForVariableType(self: *@This(), vari: var, get: var, kv: var) !llvm.LLVMValueRef {
        var sym = kv.value;

        switch (sym) {
            .Enum => |map| {
                var val = map.get(get.name.lexeme);
                if (val == null) {
                    std.debug.warn(
                        "enum {} does not have field {}\n",
                        vari.lexeme,
                        get.name.lexeme,
                    );
                }
                return llvm.LLVMConstInt(llvm.LLVMInt32Type(), val.?.value, 1);
            },

            .Struct => @panic("TODO handle struct"),
            else => {
                std.debug.warn("Invalid get target: {}\n", comp.SymbolType(sym));
                return CompileError.EmitError;
            },
        }
    }

    fn emitExpr(
        self: *Codegen,
        builder: var,
        expr: *const ast.Expr,
    ) anyerror!llvm.LLVMValueRef {
        // TODO if expr is Variable, we should do a variable lookup
        // in a symbol table, going up in scope, etc.

        // TODO Assign modify symbol table
        return switch (expr.*) {

            // TODO handle all literals, construct llvm values for them
            .Literal => |literal| blk: {
                break :blk switch (literal) {
                    // TODO other literals
                    .Integer32 => |val| llvm.LLVMConstInt(
                        llvm.LLVMInt32Type(),
                        @intCast(c_ulonglong, val),
                        10,
                    ),
                    .Integer64 => |val| llvm.LLVMConstInt(
                        llvm.LLVMInt64Type(),
                        @intCast(c_ulonglong, val),
                        10,
                    ),

                    .Float => |val| blk2: {
                        var val_cstr = try std.cstr.addNullByte(self.allocator, val);
                        break :blk2 llvm.LLVMConstRealOfString(llvm.LLVMDoubleType(), val_cstr.ptr);
                    },
                    .Bool => |val| blk2: {
                        break :blk2 mkLLVMBool(val);
                    },
                    else => unreachable,
                };
            },

            .Binary => |binary| {
                var left = try self.emitExpr(builder, binary.left);
                var right = try self.emitExpr(builder, binary.right);

                return switch (binary.op) {
                    .Add => llvm.LLVMBuildAdd(builder, left, right, c"addtmp"),
                    .Sub => llvm.LLVMBuildSub(builder, left, right, c"subtmp"),
                    .Mul => llvm.LLVMBuildMul(builder, left, right, c"multmp"),

                    //.Div => llvm.LLVMBuildDiv(builder, left, right, c"divtmp"),
                    .And => llvm.LLVMBuildAnd(builder, left, right, c"andtmp"),
                    .Or => llvm.LLVMBuildOr(builder, left, right, c"ortmp"),

                    else => {
                        std.debug.warn("Unexpected binary operator: '{}'\n", binary.op);
                        return CompileError.EmitError;
                    },
                };
            },

            .Get => |get| {
                var target = get.target.*;

                switch (target) {
                    .Variable => |vari| {
                        // first, we must check if the target is a type
                        // and emit accordingly
                        var kv_sym_opt = self.ctx.symbol_table.get(vari.lexeme);
                        if (kv_sym_opt) |kv| {
                            return try self.emitForVariableType(vari, get, kv);
                        }

                        // if not, its likely a variable, we should handle it accordingly
                        // as well
                        @panic("TODO handle variables");
                    },

                    else => {
                        std.debug.warn("Invalid get target: {}\n", ast.ExprType(target));
                        return CompileError.EmitError;
                    },
                }
            },

            .Call => |call| {
                const name = call.callee.*.Variable.lexeme;

                var llvm_func = self.llvm_table.get(name);
                if (llvm_func == null) {
                    std.debug.warn("Function '{}' not found\n", name);
                    return CompileError.EmitError;
                }

                var args = LLVMValueList.init(self.allocator);
                errdefer args.deinit();

                for (call.arguments.toSlice()) |arg_expr| {
                    var arg_val = try self.emitExpr(builder, &arg_expr);
                    try args.append(arg_val);
                }

                var args_slice = args.toSlice();

                return llvm.LLVMBuildCall(
                    builder,
                    llvm_func.?.value,
                    args_slice.ptr,
                    @intCast(c_uint, args_slice.len),
                    c"call",
                );
            },

            // TODO finish this
            .Assign => |assign| {
                // TODO find assign.name on the "parent context", we should have
                // a way to do name resolution that is completely relative to
                // where we currently are, and go up in scope. so that we find
                // the LLVMValueRef.

                // we will also need to repeat the step for the type resolver

                //var typ = self.findCurrent(assign.name);
                var assign_expr = try self.emitExpr(builder, assign.value);

                // TODO rm null
                return llvm.LLVMBuildStore(builder, null, assign_expr);
            },

            .Variable => |vari| {
                var kv_opt = self.ctx.metadata_map.get(expr);

                if (kv_opt == null) {
                    std.debug.warn("variable {} not fully analyzed\n", vari);
                    return CompileError.EmitError;
                }

                // we have metadata, which means we can check if the variable
                // is coming from the scope or from the function

                var metadata = kv_opt.?.value;

                return switch (metadata.using) {
                    .Function => blk: {
                        var param = metadata.from_function.?.parameters.get(vari.lexeme).?.value;
                        // var llvm_func = self.llvm_table.get(self.current_function_name.?).?.value;
                        // break :blk llvm.LLVMGetParam(llvm_func, @intCast(c_uint, param.idx));

                        break :blk param.llvm_alloca;
                    },

                    .Scope => @panic("TODO local variables"),
                };
            },

            else => {
                std.debug.warn("Got unexpected expr {}\n", ast.ExprType(expr.*));
                return CompileError.EmitError;
            },
        };
    }

    fn emitStmt(self: *Codegen, builder: var, stmt: *ast.Stmt) anyerror!void {
        switch (stmt.*) {
            .Expr => |expr| _ = try self.emitExpr(builder, expr),

            .Return => |ret| {
                var ret_expr = try self.emitExpr(builder, ret.value);
                _ = llvm.LLVMBuildRet(builder, ret_expr);
            },

            .If => |ifstmt| {
                var cond = try self.emitExpr(builder, ifstmt.condition);
                var zero = mkLLVMBool(false);
                var icmp = llvm.LLVMBuildICmp(builder, llvm.LLVMIntPredicate.LLVMIntNE, cond, zero, c"ifcond");

                var insert = llvm.LLVMGetInsertBlock(builder);
                var function = llvm.LLVMGetBasicBlockParent(insert);

                var then_bb = llvm.LLVMAppendBasicBlock(function, c"then");
                var else_bb = llvm.LLVMAppendBasicBlock(function, c"else");
                var merge_bb = llvm.LLVMAppendBasicBlock(function, c"ifcont");

                var condbr = llvm.LLVMBuildCondBr(builder, icmp, then_bb, else_bb);

                llvm.LLVMPositionBuilderAtEnd(builder, then_bb);

                // roughly translating to kaleidoscope's
                // 'Value *ThenV = Then->codegen();'
                var then_rets = false;
                var else_rets = false;

                self.ctx.setScope(self.ctx.current_scope.?.nextChild());

                var then_branch = ifstmt.then_branch.toSlice();
                for (then_branch) |_, idx| {

                    // keep emitting until branch has ret
                    if (!then_rets)
                        try self.emitStmt(builder, &then_branch[idx]);

                    switch (then_stmt) {
                        .Return => then_rets = true,
                        else => {},
                    }
                }

                self.ctx.dumpScope();

                // only build the br instruction if we didn't ret, because
                // there can't be any instruction after a terminator
                // same applies for the else branch
                if (!then_rets)
                    _ = llvm.LLVMBuildBr(builder, merge_bb);

                then_bb = llvm.LLVMGetInsertBlock(builder);

                llvm.LLVMPositionBuilderAtEnd(builder, else_bb);

                // roughly translating to kaleidoscope's
                // 'Else *ElseV = Else->codegen();'
                if (ifstmt.else_branch) |else_block| {
                    self.ctx.setScope(self.ctx.current_scope.?.nextChild());

                    var else_slice = else_block.toSlice();
                    for (else_slice) |_, idx| {
                        // keep emitting until branch has ret
                        if (!else_rets)
                            try self.emitStmt(builder, &else_slice[idx]);

                        switch (else_stmt) {
                            .Return => else_rets = true,
                            else => {},
                        }
                    }

                    self.ctx.dumpScope();
                }

                if (!else_rets)
                    _ = llvm.LLVMBuildBr(builder, merge_bb);

                else_bb = llvm.LLVMGetInsertBlock(builder);

                llvm.LLVMPositionBuilderAtEnd(builder, merge_bb);

                // if both of the branches return, we should put
                // the merge branch as unreachable.
                if (then_rets and else_rets)
                    _ = llvm.LLVMBuildUnreachable(builder);
            },

            .VarDecl => |vardecl| {
                // we alaready inferred the type of the variable in the
                // analyze pass and the current scope contains the variable's
                // type(hopefully), so we resolve it
                const name = vardecl.name.lexeme;
                var var_metadata = try self.ctx.resolveVarType(name);

                var name_cstr = try std.cstr.addNullByte(self.allocator, name);
                errdefer self.allocator.free(name_cstr);

                var fn_symbol = self.getFnSymbol(self.current_function_name.?);

                var variable = llvm.LLVMBuildAlloca(
                    builder,
                    try self.typeToLLVM(var_metadata.typ),
                    name_cstr.ptr,
                );

                vardecl.llvm_alloca = variable;

                var llvm_expr = try self.emitExpr(builder, vardecl.value);
                _ = llvm.LLVMBuildStore(builder, llvm_expr, variable);
            },

            else => {
                std.debug.warn("Got unexpected stmt {}\n", stmt.*);
                return CompileError.EmitError;
            },
        }
    }

    fn getFnSymbol(self: *@This(), name: []const u8) comp.FunctionSymbol {
        var fn_sym_search = self.ctx.symbol_table.get(name).?.value;
        std.debug.assert(comp.SymbolType(fn_sym_search) == .Function);
        return fn_sym_search.Function;
    }

    /// Emit LLVM ir for the given node.
    fn genNode(
        self: *Codegen,
        mod: llvm.LLVMModuleRef,
        node: *ast.Node,
    ) !void {
        switch (node.*) {
            .Root => @panic("Should not have gotten Root"),
            .FnDecl => |decl| {
                const name = decl.func_name.lexeme;
                self.current_function_name = name;
                std.debug.warn("cgen: genning function '{}'\n", name);

                var fn_sym = self.getFnSymbol(name);

                const name_cstr = try std.cstr.addNullByte(self.allocator, name);
                errdefer self.allocator.free(name_cstr);

                var param_types = llvm.LLVMTypeList.init(self.allocator);
                errdefer param_types.deinit();

                for (decl.params.toSlice()) |param| {
                    try param_types.append(try self.typeToLLVM(fn_sym.parameters.get(
                        param.name.lexeme,
                    ).?.value.typ));
                }

                var llvm_ret_type = llvm.LLVMFunctionType(
                    try self.typeToLLVM(fn_sym.return_type),
                    param_types.toSlice().ptr,
                    @intCast(c_uint, param_types.len),
                    0,
                );

                var func = llvm.LLVMAddFunction(mod, name_cstr.ptr, llvm_ret_type);
                _ = try self.llvm_table.put(name, func);

                var buf = try self.allocator.alloc(u8, 512);
                var entry_lbl = try std.fmt.bufPrint(buf, "fn_{}_entry", name);
                var entry_lbl_cstr = try std.cstr.addNullByte(self.allocator, entry_lbl);
                var entry = llvm.LLVMAppendBasicBlock(func, entry_lbl_cstr.ptr);

                var builder = llvm.LLVMCreateBuilder();
                llvm.LLVMPositionBuilderAtEnd(builder, entry);

                // to have the ability to mutate parameters, we must allocate them on
                // the stack
                for (params_slice) |param_node, idx| {
                    var param = fn_sym.parameters.get(param_node.name.lexeme).?.value;

                    const name_cstr = try std.cstr.addNullByte(self.allocator, param_node.name.lexeme);
                    errdefer self.allocator.free(name_cstr);

                    var alloca = llvm.LLVMBuildAlloca(builder, try self.typeToLLVM(param.typ), name_cstr.ptr);
                    param.llvm_alloca = alloca;

                    // TODO store register into stack param
                    // llvm.LLVMBuildStore(builder, null, assign_expr);
                }

                self.ctx.setScope(fn_sym.scope);
                defer self.ctx.dumpScope();

                var body_slice = decl.body.toSlice();
                for (body_slice) |_, idx| {
                    try self.emitStmt(builder, &body_slice[idx]);
                }

                std.debug.warn("cgen: generated function '{}'\n", name);
            },

            // NOTE: enums don't have specific llvm ir code generated for them
            .Enum => {},

            .ConstDecl => |constdecls| {
                for (constdecls.toSlice()) |constdecl| {
                    const name = constdecl.name.lexeme;

                    var const_type = self.ctx.symbol_table.get(name).?.value;
                    var const_llvm_type = try self.typeToLLVM(const_type.Const);

                    const const_name = try std.cstr.addNullByte(self.allocator, name);
                    errdefer self.allocator.free(const_name);

                    var global = llvm.LLVMAddGlobal(mod, const_llvm_type, const_name.ptr);

                    // TODO maybe put builder at main function so we can still
                    // call other functions inside consts?

                    var builder = llvm.LLVMCreateBuilder();
                    var expr_llvm_val = try self.emitExpr(builder, constdecl.expr);

                    llvm.LLVMSetInitializer(global, expr_llvm_val);
                }
            },

            else => {
                std.debug.warn("TODO handle node type {}\n", @tagName(node.*));
                return;
            },
        }
    }

    pub fn gen(self: *Codegen, root: *ast.Node) !void {
        std.debug.warn("cgen: start gen\n");
        _ = llvm.LLVMInitializeNativeTarget();

        var mod = llvm.LLVMModuleCreateWithName(c"awoo").?;
        defer llvm.LLVMDisposeModule(mod);

        var root_slice = root.Root.toSlice();
        for (root_slice) |_, idx| {
            try self.genNode(mod, &root_slice[idx]);
        }

        var err: ?[*]u8 = null;
        defer llvm.LLVMDisposeMessage(err);

        if (llvm.LLVMPrintModuleToFile(mod, c"output.ll", &err) != 0) {
            std.debug.warn("error printing module to file: {}\n", sliceify(err));
            return CompileError.LLVMError;
        }

        //if (llvm.LLVMWriteBitcodeToFile(mod, c"awoo.bc") != 0) {
        //    std.debug.warn("error writing bitcode to file: {}\n", sliceify(err));
        //    return CompileError.LLVMError;
        //}

        std.debug.warn("cgen: verify llvm module\n");
        _ = llvm.LLVMVerifyModule(
            mod,
            llvm.LLVMVerifierFailureAction.LLVMAbortProcessAction,
            &err,
        );

        llvm.LLVMInitializeAllTargetInfos();
        llvm.LLVMInitializeAllTargets();
        llvm.LLVMInitializeAllTargetMCs();
        llvm.LLVMInitializeAllAsmParsers();
        llvm.LLVMInitializeAllAsmPrinters();

        var engine: llvm.LLVMExecutionEngineRef = undefined;
        if (llvm.LLVMCreateExecutionEngineForModule(&engine, mod, &err) != 0) {
            std.debug.warn("failed to create execution engine: {}\n", sliceify(err));
            return CompileError.LLVMError;
        }

        var machine = llvm.LLVMGetExecutionEngineTargetMachine(engine);
        defer llvm.LLVMDisposeTargetMachine(machine);

        var target = llvm.LLVMGetTargetMachineTarget(machine);
        var target_data = llvm.LLVMCreateTargetDataLayout(machine);
        var data_layout = llvm.LLVMCopyStringRepOfTargetData(target_data);
        llvm.LLVMSetDataLayout(mod, data_layout);

        var outpath_cstr = try std.cstr.addNullByte(self.allocator, "outpath.o");

        //var asmpath_cstr = try std.cstr.addNullByte(self.allocator, "output.S");

        var desc = llvm.LLVMGetTargetDescription(target);
        var features = llvm.LLVMGetTargetMachineFeatureString(machine);
        var triple = llvm.LLVMGetTargetMachineTriple(machine);

        std.debug.warn("target: {}\n", sliceify(desc));
        std.debug.warn("triple: {}\n", sliceify(triple));
        std.debug.warn("features: {}\n", sliceify(features));

        //if (llvm.LLVMTargetMachineEmitToFile(
        //    machine,
        //    mod,
        //    asmpath_cstr.ptr,
        //    llvm.LLVMCodeGenFileType.LLVMAssemblyFile,
        //    &err,
        //) != 0) {
        //    std.debug.warn("failed to emit to assembly file: {}\n", sliceify(err));
        //    return CompileError.LLVMError;
        //}

        if (llvm.LLVMTargetMachineEmitToFile(
            machine,
            mod,
            outpath_cstr.ptr,
            llvm.LLVMCodeGenFileType.LLVMObjectFile,
            &err,
        ) != 0) {
            std.debug.warn("failed to emit to file: {}\n", sliceify(err));
            return CompileError.LLVMError;
        }
    }
};