void check_stmt_list(Checker *c, AstNodeArray stmts, u32 flags) { if (stmts.count == 0) { return; } check_scope_decls(c, stmts, 1.2*stmts.count); bool ft_ok = (flags & Stmt_FallthroughAllowed) != 0; flags &= ~Stmt_FallthroughAllowed; isize max = stmts.count; for (isize i = stmts.count-1; i >= 0; i--) { if (stmts.e[i]->kind != AstNode_EmptyStmt) { break; } max--; } for (isize i = 0; i < max; i++) { AstNode *n = stmts.e[i]; if (n->kind == AstNode_EmptyStmt) { continue; } u32 new_flags = flags; if (ft_ok && i+1 == max) { new_flags |= Stmt_FallthroughAllowed; } if (i+1 < max) { switch (n->kind) { case AstNode_ReturnStmt: error_node(n, "Statements after this `return` are never executed"); break; case AstNode_ExprStmt: if (n->ExprStmt.expr->kind == AstNode_GiveExpr) { error_node(n, "A `give` must be the last statement in a block"); } break; } } check_stmt(c, n, new_flags); } } bool check_is_terminating_list(AstNodeArray stmts) { // Iterate backwards for (isize n = stmts.count-1; n >= 0; n--) { AstNode *stmt = stmts.e[n]; if (stmt->kind != AstNode_EmptyStmt) { return check_is_terminating(stmt); } } return false; } bool check_has_break_list(AstNodeArray stmts, bool implicit) { for_array(i, stmts) { AstNode *stmt = stmts.e[i]; if (check_has_break(stmt, implicit)) { return true; } } return false; } bool check_has_break(AstNode *stmt, bool implicit) { switch (stmt->kind) { case AstNode_BranchStmt: if (stmt->BranchStmt.token.kind == Token_break) { return implicit; } break; case AstNode_BlockStmt: return check_has_break_list(stmt->BlockStmt.stmts, implicit); case AstNode_IfStmt: if (check_has_break(stmt->IfStmt.body, implicit) || (stmt->IfStmt.else_stmt != NULL && check_has_break(stmt->IfStmt.else_stmt, implicit))) { return true; } break; case AstNode_CaseClause: return check_has_break_list(stmt->CaseClause.stmts, implicit); } return false; } // NOTE(bill): The last expression has to be a `return` statement // TODO(bill): This is a mild hack and should be probably handled properly // TODO(bill): Warn/err against code after `return` that it won't be executed bool check_is_terminating(AstNode *node) { switch (node->kind) { case_ast_node(rs, ReturnStmt, node); return true; case_end; case_ast_node(bs, BlockStmt, node); return check_is_terminating_list(bs->stmts); case_end; case_ast_node(es, ExprStmt, node); return check_is_terminating(es->expr); case_end; case_ast_node(is, IfStmt, node); if (is->else_stmt != NULL) { if (check_is_terminating(is->body) && check_is_terminating(is->else_stmt)) { return true; } } case_end; case_ast_node(ws, WhenStmt, node); if (ws->else_stmt != NULL) { if (check_is_terminating(ws->body) && check_is_terminating(ws->else_stmt)) { return true; } } case_end; case_ast_node(fs, ForStmt, node); if (!check_has_break(fs->body, true)) { return check_is_terminating(fs->body); } case_end; case_ast_node(rs, RangeStmt, node); if (!check_has_break(rs->body, true)) { return check_is_terminating(rs->body); } case_end; case_ast_node(ms, MatchStmt, node); bool has_default = false; for_array(i, ms->body->BlockStmt.stmts) { AstNode *clause = ms->body->BlockStmt.stmts.e[i]; ast_node(cc, CaseClause, clause); if (cc->list.count == 0) { has_default = true; } if (!check_is_terminating_list(cc->stmts) || check_has_break_list(cc->stmts, true)) { return false; } } return has_default; case_end; case_ast_node(ms, TypeMatchStmt, node); bool has_default = false; for_array(i, ms->body->BlockStmt.stmts) { AstNode *clause = ms->body->BlockStmt.stmts.e[i]; ast_node(cc, CaseClause, clause); if (cc->list.count == 0) { has_default = true; } if (!check_is_terminating_list(cc->stmts) || check_has_break_list(cc->stmts, true)) { return false; } } return has_default; case_end; case_ast_node(pa, PushAllocator, node); return check_is_terminating(pa->body); case_end; case_ast_node(pc, PushContext, node); return check_is_terminating(pc->body); case_end; } return false; } Type *check_assignment_variable(Checker *c, Operand *op_a, AstNode *lhs) { if (op_a->mode == Addressing_Invalid || (op_a->type == t_invalid && op_a->mode != Addressing_Overload)) { return NULL; } AstNode *node = unparen_expr(lhs); // NOTE(bill): Ignore assignments to `_` if (node->kind == AstNode_Ident && str_eq(node->Ident.string, str_lit("_"))) { add_entity_definition(&c->info, node, NULL); check_assignment(c, op_a, NULL, str_lit("assignment to `_` identifier")); if (op_a->mode == Addressing_Invalid) { return NULL; } return op_a->type; } Entity *e = NULL; bool used = false; Operand op_b = {Addressing_Invalid}; check_expr(c, &op_b, lhs); if (op_b.mode == Addressing_Invalid || op_b.type == t_invalid) { return NULL; } if (op_a->mode == Addressing_Overload) { isize overload_count = op_a->overload_count; Entity **procs = op_a->overload_entities; GB_ASSERT(procs != NULL && overload_count > 0); // NOTE(bill): These should be done for (isize i = 0; i < overload_count; i++) { Type *t = base_type(procs[i]->type); if (t == t_invalid) { continue; } Operand x = {0}; x.mode = Addressing_Value; x.type = t; if (check_is_assignable_to(c, &x, op_b.type)) { e = procs[i]; add_entity_use(c, op_a->expr, e); break; } } if (e != NULL) { // HACK TODO(bill): Should the entities be freed as it's technically a leak op_a->mode = Addressing_Value; op_a->type = e->type; op_a->overload_count = 0; op_a->overload_entities = NULL; } } else { if (node->kind == AstNode_Ident) { ast_node(i, Ident, node); e = scope_lookup_entity(c->context.scope, i->string); if (e != NULL && e->kind == Entity_Variable) { used = (e->flags & EntityFlag_Used) != 0; // TODO(bill): Make backup just in case } } } if (e != NULL && used) { e->flags |= EntityFlag_Used; } switch (op_b.mode) { case Addressing_Invalid: return NULL; case Addressing_Variable: break; default: { if (op_b.expr->kind == AstNode_SelectorExpr) { // NOTE(bill): Extra error checks Operand op_c = {Addressing_Invalid}; ast_node(se, SelectorExpr, op_b.expr); check_expr(c, &op_c, se->expr); } gbString str = expr_to_string(op_b.expr); if (e != NULL && e->kind == Entity_Variable && e->Variable.is_immutable) { error_node(op_b.expr, "Cannot assign to an immutable: `%s`", str); } else { error_node(op_b.expr, "Cannot assign to `%s`", str); } gb_string_free(str); } break; } check_assignment(c, op_a, op_b.type, str_lit("assignment")); if (op_a->mode == Addressing_Invalid) { return NULL; } return op_a->type; } bool check_valid_type_match_type(Type *type, bool *is_union_ptr, bool *is_any) { if (is_type_pointer(type)) { *is_union_ptr = is_type_union(type_deref(type)); return *is_union_ptr; } if (is_type_any(type)) { *is_any = true; return *is_any; } return false; } void check_stmt_internal(Checker *c, AstNode *node, u32 flags); void check_stmt(Checker *c, AstNode *node, u32 flags) { u32 prev_stmt_state_flags = c->context.stmt_state_flags; if (node->stmt_state_flags != 0) { u32 in = node->stmt_state_flags; u32 out = c->context.stmt_state_flags; if (in & StmtStateFlag_no_bounds_check) { out |= StmtStateFlag_no_bounds_check; out &= ~StmtStateFlag_bounds_check; } else { // if (in & StmtStateFlag_bounds_check) { out |= StmtStateFlag_bounds_check; out &= ~StmtStateFlag_no_bounds_check; } c->context.stmt_state_flags = out; } check_stmt_internal(c, node, flags); c->context.stmt_state_flags = prev_stmt_state_flags; } typedef struct TypeAndToken { Type *type; Token token; } TypeAndToken; #define MAP_TYPE TypeAndToken #define MAP_PROC map_type_and_token_ #define MAP_NAME MapTypeAndToken #include "map.c" void check_when_stmt(Checker *c, AstNodeWhenStmt *ws, u32 flags) { Operand operand = {Addressing_Invalid}; check_expr(c, &operand, ws->cond); if (operand.mode != Addressing_Constant || !is_type_boolean(operand.type)) { error_node(ws->cond, "Non-constant boolean `when` condition"); return; } if (ws->body == NULL || ws->body->kind != AstNode_BlockStmt) { error_node(ws->cond, "Invalid body for `when` statement"); return; } if (operand.value.kind == ExactValue_Bool && operand.value.value_bool) { check_stmt_list(c, ws->body->BlockStmt.stmts, flags); } else if (ws->else_stmt) { switch (ws->else_stmt->kind) { case AstNode_BlockStmt: check_stmt_list(c, ws->else_stmt->BlockStmt.stmts, flags); break; case AstNode_WhenStmt: check_when_stmt(c, &ws->else_stmt->WhenStmt, flags); break; default: error_node(ws->else_stmt, "Invalid `else` statement in `when` statement"); break; } } } void check_stmt_internal(Checker *c, AstNode *node, u32 flags) { u32 mod_flags = flags & (~Stmt_FallthroughAllowed); switch (node->kind) { case_ast_node(_, EmptyStmt, node); case_end; case_ast_node(_, BadStmt, node); case_end; case_ast_node(_, BadDecl, node); case_end; case_ast_node(es, ExprStmt, node) Operand operand = {Addressing_Invalid}; ExprKind kind = check_expr_base(c, &operand, es->expr, NULL); switch (operand.mode) { case Addressing_Type: error_node(node, "Is not an expression"); break; case Addressing_NoValue: return; default: { if (kind == Expr_Stmt) { return; } if (operand.expr->kind == AstNode_CallExpr) { return; } if (operand.expr->kind == AstNode_GiveExpr) { if ((flags&Stmt_GiveAllowed) != 0) { return; } error_node(node, "Illegal use of `give`"); } gbString expr_str = expr_to_string(operand.expr); error_node(node, "Expression is not used: `%s`", expr_str); gb_string_free(expr_str); } break; } case_end; case_ast_node(ts, TagStmt, node); // TODO(bill): Tag Statements error_node(node, "Tag statements are not supported yet"); check_stmt(c, ts->stmt, flags); case_end; case_ast_node(as, AssignStmt, node); switch (as->op.kind) { case Token_Eq: { // a, b, c = 1, 2, 3; // Multisided if (as->lhs.count == 0) { error(as->op, "Missing lhs in assignment statement"); return; } gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&c->tmp_arena); // NOTE(bill): If there is a bad syntax error, rhs > lhs which would mean there would need to be // an extra allocation Array(Operand) operands; array_init_reserve(&operands, c->tmp_allocator, 2 * as->lhs.count); for_array(i, as->rhs) { AstNode *rhs = as->rhs.e[i]; Operand o = {0}; check_multi_expr(c, &o, rhs); if (o.type->kind != Type_Tuple) { array_add(&operands, o); } else { TypeTuple *tuple = &o.type->Tuple; for (isize j = 0; j < tuple->variable_count; j++) { o.type = tuple->variables[j]->type; array_add(&operands, o); } } } isize lhs_count = as->lhs.count; isize rhs_count = operands.count; isize operand_count = gb_min(as->lhs.count, operands.count); for (isize i = 0; i < operand_count; i++) { AstNode *lhs = as->lhs.e[i]; check_assignment_variable(c, &operands.e[i], lhs); } if (lhs_count != rhs_count) { error_node(as->lhs.e[0], "Assignment count mismatch `%td` = `%td`", lhs_count, rhs_count); } gb_temp_arena_memory_end(tmp); } break; default: { // a += 1; // Single-sided Token op = as->op; if (as->lhs.count != 1 || as->rhs.count != 1) { error(op, "Assignment operation `%.*s` requires single-valued expressions", LIT(op.string)); return; } if (!gb_is_between(op.kind, Token__AssignOpBegin+1, Token__AssignOpEnd-1)) { error(op, "Unknown Assignment operation `%.*s`", LIT(op.string)); return; } // TODO(bill): Check if valid assignment operator Operand operand = {Addressing_Invalid}; AstNode binary_expr = {AstNode_BinaryExpr}; ast_node(be, BinaryExpr, &binary_expr); be->op = op; be->op.kind = cast(TokenKind)(cast(i32)be->op.kind - (Token_AddEq - Token_Add)); // NOTE(bill): Only use the first one will be used be->left = as->lhs.e[0]; be->right = as->rhs.e[0]; check_binary_expr(c, &operand, &binary_expr); if (operand.mode == Addressing_Invalid) { return; } // NOTE(bill): Only use the first one will be used check_assignment_variable(c, &operand, as->lhs.e[0]); } break; } case_end; case_ast_node(bs, BlockStmt, node); check_open_scope(c, node); check_stmt_list(c, bs->stmts, mod_flags); check_close_scope(c); case_end; case_ast_node(is, IfStmt, node); check_open_scope(c, node); if (is->init != NULL) { check_stmt(c, is->init, 0); } Operand operand = {Addressing_Invalid}; check_expr(c, &operand, is->cond); if (operand.mode != Addressing_Invalid && !is_type_boolean(operand.type)) { error_node(is->cond, "Non-boolean condition in `if` statement"); } check_stmt(c, is->body, mod_flags); if (is->else_stmt != NULL) { switch (is->else_stmt->kind) { case AstNode_IfStmt: case AstNode_BlockStmt: check_stmt(c, is->else_stmt, mod_flags); break; default: error_node(is->else_stmt, "Invalid `else` statement in `if` statement"); break; } } check_close_scope(c); case_end; case_ast_node(ws, WhenStmt, node); check_when_stmt(c, ws, flags); case_end; case_ast_node(rs, ReturnStmt, node); GB_ASSERT(c->proc_stack.count > 0); if (c->context.in_defer) { error(rs->token, "You cannot `return` within a defer statement"); // TODO(bill): Should I break here? break; } Type *proc_type = c->proc_stack.e[c->proc_stack.count-1]; isize result_count = 0; if (proc_type->Proc.results) { result_count = proc_type->Proc.results->Tuple.variable_count; } if (result_count > 0) { Entity **variables = NULL; if (proc_type->Proc.results != NULL) { TypeTuple *tuple = &proc_type->Proc.results->Tuple; variables = tuple->variables; } if (rs->results.count == 0) { error_node(node, "Expected %td return values, got 0", result_count); } else { // TokenPos pos = rs->token.pos; // if (pos.line == 10) { // gb_printf_err("%s\n", type_to_string(variables[0]->type)); // } check_init_variables(c, variables, result_count, rs->results, str_lit("return statement")); // if (pos.line == 10) { // AstNode *x = rs->results.e[0]; // gb_printf_err("%s\n", expr_to_string(x)); // gb_printf_err("%s\n", type_to_string(type_of_expr(&c->info, x))); // } } } else if (rs->results.count > 0) { error_node(rs->results.e[0], "No return values expected"); } case_end; case_ast_node(fs, ForStmt, node); u32 new_flags = mod_flags | Stmt_BreakAllowed | Stmt_ContinueAllowed; check_open_scope(c, node); if (fs->init != NULL) { check_stmt(c, fs->init, 0); } if (fs->cond != NULL) { Operand o = {Addressing_Invalid}; check_expr(c, &o, fs->cond); if (o.mode != Addressing_Invalid && !is_type_boolean(o.type)) { error_node(fs->cond, "Non-boolean condition in `for` statement"); } } if (fs->post != NULL) { check_stmt(c, fs->post, 0); if (fs->post->kind != AstNode_AssignStmt) { error_node(fs->post, "`for` statement post statement must be an assignment"); } } check_stmt(c, fs->body, new_flags); check_close_scope(c); case_end; case_ast_node(rs, RangeStmt, node); u32 new_flags = mod_flags | Stmt_BreakAllowed | Stmt_ContinueAllowed; check_open_scope(c, node); Type *val = NULL; Type *idx = NULL; Entity *entities[2] = {0}; isize entity_count = 0; if (rs->expr != NULL && rs->expr->kind == AstNode_IntervalExpr) { ast_node(ie, IntervalExpr, rs->expr); Operand x = {Addressing_Invalid}; Operand y = {Addressing_Invalid}; check_expr(c, &x, ie->left); if (x.mode == Addressing_Invalid) { goto skip_expr; } check_expr(c, &y, ie->right); if (y.mode == Addressing_Invalid) { goto skip_expr; } convert_to_typed(c, &x, y.type, 0); if (x.mode == Addressing_Invalid) { goto skip_expr; } convert_to_typed(c, &y, x.type, 0); if (y.mode == Addressing_Invalid) { goto skip_expr; } convert_to_typed(c, &x, default_type(y.type), 0); if (x.mode == Addressing_Invalid) { goto skip_expr; } convert_to_typed(c, &y, default_type(x.type), 0); if (y.mode == Addressing_Invalid) { goto skip_expr; } if (!are_types_identical(x.type, y.type)) { if (x.type != t_invalid && y.type != t_invalid) { gbString xt = type_to_string(x.type); gbString yt = type_to_string(y.type); gbString expr_str = expr_to_string(x.expr); error(ie->op, "Mismatched types in interval expression `%s` : `%s` vs `%s`", expr_str, xt, yt); gb_string_free(expr_str); gb_string_free(yt); gb_string_free(xt); } goto skip_expr; } Type *type = x.type; if (!is_type_integer(type) && !is_type_float(type) && !is_type_pointer(type)) { error(ie->op, "Only numerical and pointer types are allowed within interval expressions"); goto skip_expr; } if (x.mode == Addressing_Constant && y.mode == Addressing_Constant) { ExactValue a = x.value; ExactValue b = y.value; GB_ASSERT(are_types_identical(x.type, y.type)); TokenKind op = Token_Lt; switch (ie->op.kind) { case Token_HalfOpenRange: op = Token_Lt; break; case Token_Ellipsis: op = Token_LtEq; break; default: error(ie->op, "Invalid range operator"); break; } bool ok = compare_exact_values(Token_Lt, a, b); if (!ok) { // TODO(bill): Better error message error(ie->op, "Invalid interval range"); goto skip_expr; } } add_type_and_value(&c->info, ie->left, x.mode, x.type, x.value); add_type_and_value(&c->info, ie->right, y.mode, y.type, y.value); val = type; idx = t_int; } else { Operand operand = {Addressing_Invalid}; check_expr(c, &operand, rs->expr); if (operand.mode != Addressing_Invalid) { Type *t = base_type(type_deref(operand.type)); switch (t->kind) { case Type_Basic: if (is_type_string(t)) { val = t_rune; idx = t_int; } break; case Type_Array: // val = make_type_pointer(c->allocator, t->Array.elem); val = t->Array.elem; idx = t_int; break; case Type_Slice: // val = make_type_pointer(c->allocator, t->Slice.elem); val = t->Slice.elem; idx = t_int; break; } } if (val == NULL) { gbString s = expr_to_string(operand.expr); gbString t = type_to_string(operand.type); error_node(operand.expr, "Cannot iterate over `%s` of type `%s`", s, t); gb_string_free(t); gb_string_free(s); } } skip_expr: AstNode *lhs[2] = {rs->value, rs->index}; Type * rhs[2] = {val, idx}; for (isize i = 0; i < 2; i++) { if (lhs[i] == NULL) { continue; } AstNode *name = lhs[i]; Type * type = rhs[i]; Entity *entity = NULL; if (name->kind == AstNode_Ident) { Token token = name->Ident; String str = token.string; Entity *found = NULL; if (str_ne(str, str_lit("_"))) { found = current_scope_lookup_entity(c->context.scope, str); } if (found == NULL) { entity = make_entity_variable(c->allocator, c->context.scope, token, type, true); add_entity_definition(&c->info, name, entity); } else { TokenPos pos = found->token.pos; error(token, "Redeclaration of `%.*s` in this scope\n" "\tat %.*s(%td:%td)", LIT(str), LIT(pos.file), pos.line, pos.column); entity = found; } } else { error_node(name, "A variable declaration must be an identifier"); } if (entity == NULL) { entity = make_entity_dummy_variable(c->allocator, c->global_scope, ast_node_token(name)); } entities[entity_count++] = entity; if (type == NULL) { entity->type = t_invalid; entity->flags |= EntityFlag_Used; } } for (isize i = 0; i < entity_count; i++) { add_entity(c, c->context.scope, entities[i]->identifier, entities[i]); } check_stmt(c, rs->body, new_flags); check_close_scope(c); case_end; case_ast_node(ms, MatchStmt, node); Operand x = {0}; mod_flags |= Stmt_BreakAllowed; check_open_scope(c, node); if (ms->init != NULL) { check_stmt(c, ms->init, 0); } if (ms->tag != NULL) { check_expr(c, &x, ms->tag); check_assignment(c, &x, NULL, str_lit("match expression")); } else { x.mode = Addressing_Constant; x.type = t_bool; x.value = make_exact_value_bool(true); Token token = {0}; token.pos = ast_node_token(ms->body).pos; token.string = str_lit("true"); x.expr = make_ident(c->curr_ast_file, token); } // NOTE(bill): Check for multiple defaults AstNode *first_default = NULL; ast_node(bs, BlockStmt, ms->body); for_array(i, bs->stmts) { AstNode *stmt = bs->stmts.e[i]; AstNode *default_stmt = NULL; if (stmt->kind == AstNode_CaseClause) { ast_node(cc, CaseClause, stmt); if (cc->list.count == 0) { default_stmt = stmt; } } else { error_node(stmt, "Invalid AST - expected case clause"); } if (default_stmt != NULL) { if (first_default != NULL) { TokenPos pos = ast_node_token(first_default).pos; error_node(stmt, "multiple `default` clauses\n" "\tfirst at %.*s(%td:%td)", LIT(pos.file), pos.line, pos.column); } else { first_default = default_stmt; } } } MapTypeAndToken seen = {0}; // NOTE(bill): Multimap map_type_and_token_init(&seen, heap_allocator()); for_array(i, bs->stmts) { AstNode *stmt = bs->stmts.e[i]; if (stmt->kind != AstNode_CaseClause) { // NOTE(bill): error handled by above multiple default checker continue; } ast_node(cc, CaseClause, stmt); for_array(j, cc->list) { AstNode *expr = cc->list.e[j]; Operand y = {0}; check_expr(c, &y, expr); if (x.mode == Addressing_Invalid || y.mode == Addressing_Invalid) { continue; } convert_to_typed(c, &y, x.type, 0); if (y.mode == Addressing_Invalid) { continue; } // NOTE(bill): the ordering here matters Operand z = y; check_comparison(c, &z, &x, Token_CmpEq); if (z.mode == Addressing_Invalid) { continue; } if (y.mode != Addressing_Constant) { continue; } if (y.value.kind != ExactValue_Invalid) { HashKey key = hash_exact_value(y.value); TypeAndToken *found = map_type_and_token_get(&seen, key); if (found != NULL) { gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&c->tmp_arena); isize count = map_type_and_token_multi_count(&seen, key); TypeAndToken *taps = gb_alloc_array(c->tmp_allocator, TypeAndToken, count); map_type_and_token_multi_get_all(&seen, key, taps); bool continue_outer = false; for (isize i = 0; i < count; i++) { TypeAndToken tap = taps[i]; if (are_types_identical(y.type, tap.type)) { TokenPos pos = tap.token.pos; gbString expr_str = expr_to_string(y.expr); error_node(y.expr, "Duplicate case `%s`\n" "\tprevious case at %.*s(%td:%td)", expr_str, LIT(pos.file), pos.line, pos.column); gb_string_free(expr_str); continue_outer = true; break; } } gb_temp_arena_memory_end(tmp); if (continue_outer) { continue; } } TypeAndToken tap = {y.type, ast_node_token(y.expr)}; map_type_and_token_multi_insert(&seen, key, tap); } } check_open_scope(c, stmt); u32 ft_flags = mod_flags; if (i+1 < bs->stmts.count) { ft_flags |= Stmt_FallthroughAllowed; } check_stmt_list(c, cc->stmts, ft_flags); check_close_scope(c); } map_type_and_token_destroy(&seen); check_close_scope(c); case_end; case_ast_node(ms, TypeMatchStmt, node); Operand x = {0}; mod_flags |= Stmt_BreakAllowed; check_open_scope(c, node); bool is_union_ptr = false; bool is_any = false; check_expr(c, &x, ms->tag); check_assignment(c, &x, NULL, str_lit("type match expression")); if (!check_valid_type_match_type(x.type, &is_union_ptr, &is_any)) { gbString str = type_to_string(x.type); error_node(x.expr, "Invalid type for this type match expression, got `%s`", str); gb_string_free(str); break; } // NOTE(bill): Check for multiple defaults AstNode *first_default = NULL; ast_node(bs, BlockStmt, ms->body); for_array(i, bs->stmts) { AstNode *stmt = bs->stmts.e[i]; AstNode *default_stmt = NULL; if (stmt->kind == AstNode_CaseClause) { ast_node(cc, CaseClause, stmt); if (cc->list.count == 0) { default_stmt = stmt; } } else { error_node(stmt, "Invalid AST - expected case clause"); } if (default_stmt != NULL) { if (first_default != NULL) { TokenPos pos = ast_node_token(first_default).pos; error_node(stmt, "Multiple `default` clauses\n" "\tfirst at %.*s(%td:%td)", LIT(pos.file), pos.line, pos.column); } else { first_default = default_stmt; } } } if (ms->var->kind != AstNode_Ident) { break; } MapBool seen = {0}; map_bool_init(&seen, heap_allocator()); for_array(i, bs->stmts) { AstNode *stmt = bs->stmts.e[i]; if (stmt->kind != AstNode_CaseClause) { // NOTE(bill): error handled by above multiple default checker continue; } ast_node(cc, CaseClause, stmt); // TODO(bill): Make robust Type *bt = base_type(type_deref(x.type)); AstNode *type_expr = cc->list.count > 0 ? cc->list.e[0] : NULL; Type *case_type = NULL; if (type_expr != NULL) { // Otherwise it's a default expression Operand y = {0}; check_expr_or_type(c, &y, type_expr); if (is_union_ptr) { GB_ASSERT(is_type_union(bt)); bool tag_type_found = false; for (isize i = 0; i < bt->Record.field_count; i++) { Entity *f = bt->Record.fields[i]; if (are_types_identical(f->type, y.type)) { tag_type_found = true; break; } } if (!tag_type_found) { gbString type_str = type_to_string(y.type); error_node(y.expr, "Unknown tag type, got `%s`", type_str); gb_string_free(type_str); continue; } case_type = y.type; } else if (is_any) { case_type = y.type; } else { GB_PANIC("Unknown type to type match statement"); } HashKey key = hash_pointer(y.type); bool *found = map_bool_get(&seen, key); if (found) { TokenPos pos = cc->token.pos; gbString expr_str = expr_to_string(y.expr); error_node(y.expr, "Duplicate type case `%s`\n" "\tprevious type case at %.*s(%td:%td)", expr_str, LIT(pos.file), pos.line, pos.column); gb_string_free(expr_str); break; } map_bool_set(&seen, key, cast(bool)true); } check_open_scope(c, stmt); if (case_type != NULL) { add_type_info_type(c, case_type); // NOTE(bill): Dummy type Type *tt = case_type; if (is_union_ptr) { tt = make_type_pointer(c->allocator, case_type); add_type_info_type(c, tt); } Entity *tag_var = make_entity_variable(c->allocator, c->context.scope, ms->var->Ident, tt, true); tag_var->flags |= EntityFlag_Used; add_entity(c, c->context.scope, ms->var, tag_var); add_entity_use(c, ms->var, tag_var); } check_stmt_list(c, cc->stmts, mod_flags); check_close_scope(c); } map_bool_destroy(&seen); check_close_scope(c); case_end; case_ast_node(ds, DeferStmt, node); if (is_ast_node_decl(ds->stmt)) { error(ds->token, "You cannot defer a declaration"); } else { bool out_in_defer = c->context.in_defer; c->context.in_defer = true; check_stmt(c, ds->stmt, 0); c->context.in_defer = out_in_defer; } case_end; case_ast_node(bs, BranchStmt, node); Token token = bs->token; switch (token.kind) { case Token_break: if ((flags & Stmt_BreakAllowed) == 0) { error(token, "`break` only allowed in loops or `match` statements"); } break; case Token_continue: if ((flags & Stmt_ContinueAllowed) == 0) { error(token, "`continue` only allowed in loops"); } break; case Token_fallthrough: if ((flags & Stmt_FallthroughAllowed) == 0) { error(token, "`fallthrough` statement in illegal position"); } break; default: error(token, "Invalid AST: Branch Statement `%.*s`", LIT(token.string)); break; } case_end; case_ast_node(us, UsingStmt, node); switch (us->node->kind) { default: // TODO(bill): Better error message for invalid using statement error(us->token, "Invalid `using` statement"); break; case_ast_node(es, ExprStmt, us->node); // TODO(bill): Allow for just a LHS expression list rather than this silly code Entity *e = NULL; bool is_selector = false; AstNode *expr = unparen_expr(es->expr); if (expr->kind == AstNode_Ident) { String name = expr->Ident.string; e = scope_lookup_entity(c->context.scope, name); } else if (expr->kind == AstNode_SelectorExpr) { Operand o = {0}; e = check_selector(c, &o, expr, NULL); is_selector = true; } if (e == NULL) { error(us->token, "`using` applied to an unknown entity"); return; } switch (e->kind) { case Entity_TypeName: { Type *t = base_type(e->type); if (is_type_union(t)) { for (isize i = 0; i < t->Record.field_count; i++) { Entity *f = t->Record.fields[i]; Entity *found = scope_insert_entity(c->context.scope, f); if (found != NULL) { gbString expr_str = expr_to_string(expr); error(us->token, "Namespace collision while `using` `%s` of: %.*s", expr_str, LIT(found->token.string)); gb_string_free(expr_str); return; } f->using_parent = e; } } else if (is_type_enum(t)) { for (isize i = 0; i < t->Record.field_count; i++) { Entity *f = t->Record.fields[i]; Entity *found = scope_insert_entity(c->context.scope, f); if (found != NULL) { gbString expr_str = expr_to_string(expr); error(us->token, "Namespace collision while `using` `%s` of: %.*s", expr_str, LIT(found->token.string)); gb_string_free(expr_str); return; } f->using_parent = e; } } else { error(us->token, "`using` can be only applied to `union` or `enum` type entities"); } } break; case Entity_ImportName: { Scope *scope = e->ImportName.scope; for_array(i, scope->elements.entries) { Entity *decl = scope->elements.entries.e[i].value; Entity *found = scope_insert_entity(c->context.scope, decl); if (found != NULL) { gbString expr_str = expr_to_string(expr); error(us->token, "Namespace collision while `using` `%s` of: %.*s\n" "\tat %.*s(%td:%td)\n" "\tat %.*s(%td:%td)", expr_str, LIT(found->token.string), LIT(found->token.pos.file), found->token.pos.line, found->token.pos.column, LIT(decl->token.pos.file), decl->token.pos.line, decl->token.pos.column ); gb_string_free(expr_str); return; } } } break; case Entity_Variable: { Type *t = base_type(type_deref(e->type)); if (is_type_struct(t) || is_type_raw_union(t)) { Scope **found = map_scope_get(&c->info.scopes, hash_pointer(t->Record.node)); GB_ASSERT(found != NULL); for_array(i, (*found)->elements.entries) { Entity *f = (*found)->elements.entries.e[i].value; if (f->kind == Entity_Variable) { Entity *uvar = make_entity_using_variable(c->allocator, e, f->token, f->type); if (is_selector) { uvar->using_expr = expr; } Entity *prev = scope_insert_entity(c->context.scope, uvar); if (prev != NULL) { gbString expr_str = expr_to_string(expr); error(us->token, "Namespace collision while `using` `%s` of: %.*s", expr_str, LIT(prev->token.string)); gb_string_free(expr_str); return; } } } } else { error(us->token, "`using` can only be applied to variables of type struct or raw_union"); return; } } break; case Entity_Constant: error(us->token, "`using` cannot be applied to a constant"); break; case Entity_Procedure: case Entity_Builtin: error(us->token, "`using` cannot be applied to a procedure"); break; case Entity_ImplicitValue: error(us->token, "`using` cannot be applied to an implicit value"); break; case Entity_Nil: error(us->token, "`using` cannot be applied to `nil`"); break; case Entity_Invalid: error(us->token, "`using` cannot be applied to an invalid entity"); break; default: GB_PANIC("TODO(bill): `using` other expressions?"); } case_end; } case_end; case_ast_node(pa, PushAllocator, node); Operand op = {0}; check_expr(c, &op, pa->expr); check_assignment(c, &op, t_allocator, str_lit("argument to push_allocator")); check_stmt(c, pa->body, mod_flags); case_end; case_ast_node(pa, PushContext, node); Operand op = {0}; check_expr(c, &op, pa->expr); check_assignment(c, &op, t_context, str_lit("argument to push_context")); check_stmt(c, pa->body, mod_flags); case_end; case_ast_node(vd, ValueDecl, node); GB_ASSERT(!c->context.scope->is_file); if (vd->is_var) { Entity **entities = gb_alloc_array(c->allocator, Entity *, vd->names.count); isize entity_count = 0; if (vd->flags & VarDeclFlag_thread_local) { vd->flags &= ~VarDeclFlag_thread_local; error_node(node, "`thread_local` may only be applied to a variable declaration"); } for_array(i, vd->names) { AstNode *name = vd->names.e[i]; Entity *entity = NULL; if (name->kind != AstNode_Ident) { error_node(name, "A variable declaration must be an identifier"); } else { Token token = name->Ident; String str = token.string; Entity *found = NULL; // NOTE(bill): Ignore assignments to `_` if (str_ne(str, str_lit("_"))) { found = current_scope_lookup_entity(c->context.scope, str); } if (found == NULL) { entity = make_entity_variable(c->allocator, c->context.scope, token, NULL, vd->flags&VarDeclFlag_immutable); entity->identifier = name; } else { TokenPos pos = found->token.pos; error(token, "Redeclaration of `%.*s` in this scope\n" "\tat %.*s(%td:%td)", LIT(str), LIT(pos.file), pos.line, pos.column); entity = found; } } if (entity == NULL) { entity = make_entity_dummy_variable(c->allocator, c->global_scope, ast_node_token(name)); } entities[entity_count++] = entity; } Type *init_type = NULL; if (vd->type) { init_type = check_type_extra(c, vd->type, NULL); if (init_type == NULL) { init_type = t_invalid; } } for (isize i = 0; i < entity_count; i++) { Entity *e = entities[i]; GB_ASSERT(e != NULL); if (e->flags & EntityFlag_Visited) { e->type = t_invalid; continue; } e->flags |= EntityFlag_Visited; if (e->type == NULL) { e->type = init_type; } } check_arity_match(c, vd); check_init_variables(c, entities, entity_count, vd->values, str_lit("variable declaration")); for (isize i = 0; i < entity_count; i++) { add_entity(c, c->context.scope, entities[i]->identifier, entities[i]); } if ((vd->flags & VarDeclFlag_using) != 0) { Token token = ast_node_token(node); if (vd->type != NULL && entity_count > 1) { error(token, "`using` can only be applied to one variable of the same type"); // TODO(bill): Should a `continue` happen here? } for (isize entity_index = 0; entity_index < entity_count; entity_index++) { Entity *e = entities[entity_index]; if (e == NULL) { continue; } if (e->kind != Entity_Variable) { continue; } bool is_immutable = e->Variable.is_immutable; String name = e->token.string; Type *t = base_type(type_deref(e->type)); if (is_type_struct(t) || is_type_raw_union(t)) { Scope **found = map_scope_get(&c->info.scopes, hash_pointer(t->Record.node)); GB_ASSERT(found != NULL); for_array(i, (*found)->elements.entries) { Entity *f = (*found)->elements.entries.e[i].value; if (f->kind == Entity_Variable) { Entity *uvar = make_entity_using_variable(c->allocator, e, f->token, f->type); uvar->Variable.is_immutable = is_immutable; Entity *prev = scope_insert_entity(c->context.scope, uvar); if (prev != NULL) { error(token, "Namespace collision while `using` `%.*s` of: %.*s", LIT(name), LIT(prev->token.string)); return; } } } } else { // NOTE(bill): skip the rest to remove extra errors error(token, "`using` can only be applied to variables of type struct or raw_union"); return; } } } } else { // NOTE(bill): Handled elsewhere } case_end; } }