// Copyright (c) 2019-2021 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. module c import strings import v.ast import v.util fn (mut g Gen) is_used_by_main(node ast.FnDecl) bool { mut is_used_by_main := true if g.pref.skip_unused { fkey := node.fkey() is_used_by_main = g.table.used_fns[fkey] $if trace_skip_unused_fns ? { println('> is_used_by_main: $is_used_by_main | node.name: $node.name | fkey: $fkey | node.is_method: $node.is_method') } if !is_used_by_main { $if trace_skip_unused_fns_in_c_code ? { g.writeln('// trace_skip_unused_fns_in_c_code, $node.name, fkey: $fkey') } } } else { $if trace_skip_unused_fns_in_c_code ? { g.writeln('// trace_skip_unused_fns_in_c_code, $node.name, fkey: $node.fkey()') } } return is_used_by_main } fn (mut g Gen) process_fn_decl(node ast.FnDecl) { if !g.is_used_by_main(node) { return } if node.should_be_skipped { return } if g.is_builtin_mod && g.pref.gc_mode == .boehm_leak && node.name == 'malloc' { g.definitions.write_string('#define _v_malloc GC_MALLOC\n') return } g.gen_attrs(node.attrs) mut skip := false pos := g.out.len should_bundle_module := util.should_bundle_module(node.mod) if g.pref.build_mode == .build_module { // if node.name.contains('parse_text') { // println('!!! $node.name mod=$node.mod, built=$g.module_built') // } // TODO true for not just "builtin" // TODO: clean this up mod := if g.is_builtin_mod { 'builtin' } else { node.name.all_before_last('.') } if (mod != g.module_built && node.mod != g.module_built.after('/')) || should_bundle_module { // Skip functions that don't have to be generated for this module. // println('skip bm $node.name mod=$node.mod module_built=$g.module_built') skip = true } if g.is_builtin_mod && g.module_built == 'builtin' && node.mod == 'builtin' { skip = false } if !skip && g.pref.is_verbose { println('build module `$g.module_built` fn `$node.name`') } } if g.pref.use_cache { // We are using prebuilt modules, we do not need to generate // their functions in main.c. if node.mod != 'main' && node.mod != 'help' && !should_bundle_module && !g.pref.is_test && node.generic_names.len == 0 { skip = true } } keep_fn_decl := g.fn_decl unsafe { g.fn_decl = &node } if node.is_main { g.has_main = true } if node.name == 'backtrace' || node.name == 'backtrace_symbols' || node.name == 'backtrace_symbols_fd' { g.write('\n#ifndef __cplusplus\n') } g.gen_fn_decl(node, skip) if node.name == 'backtrace' || node.name == 'backtrace_symbols' || node.name == 'backtrace_symbols_fd' { g.write('\n#endif\n') } g.fn_decl = keep_fn_decl if skip { g.out.go_back_to(pos) } if !g.pref.skip_unused { if node.language != .c { g.writeln('') } } } fn (mut g Gen) gen_fn_decl(node &ast.FnDecl, skip bool) { // TODO For some reason, build fails with autofree with this line // as it's only informative, comment it for now // g.gen_attrs(it.attrs) if node.language == .c { // || node.no_body { return } tmp_defer_vars := g.defer_vars // must be here because of workflow if !g.anon_fn { g.defer_vars = []string{} } else { if node.defer_stmts.len > 0 { g.defer_vars = []string{} defer { g.defer_vars = tmp_defer_vars } } } // Skip [if xxx] if xxx is not defined /* for attr in node.attrs { if !attr.is_comptime_define { continue } if attr.name !in g.pref.compile_defines_all { // println('skipping [if]') return } } */ g.returned_var_name = '' // old_g_autofree := g.is_autofree if node.is_manualfree { g.is_autofree = false } defer { g.is_autofree = old_g_autofree } // // if g.fileis('vweb.v') { // println('\ngen_fn_decl() $node.name $node.is_generic $g.cur_generic_type') // } if node.generic_names.len > 0 && g.table.cur_concrete_types.len == 0 { // need the cur_concrete_type check to avoid inf. recursion // loop thru each generic type and generate a function for concrete_types in g.table.fn_generic_types[node.name] { if g.pref.is_verbose { syms := concrete_types.map(g.table.get_type_symbol(it)) the_type := syms.map(it.name).join(', ') println('gen fn `$node.name` for type `$the_type`') } g.table.cur_concrete_types = concrete_types g.gen_fn_decl(node, skip) } g.table.cur_concrete_types = [] return } cur_fn_save := g.table.cur_fn defer { g.table.cur_fn = cur_fn_save } unsafe { // TODO remove unsafe g.table.cur_fn = node } fn_start_pos := g.out.len is_closure := node.scope.has_inherited_vars() mut cur_closure_ctx := '' if is_closure { cur_closure_ctx = closure_ctx_struct(node) // declare the struct before its implementation g.definitions.write_string(cur_closure_ctx) g.definitions.writeln(';') } g.write_v_source_line_info(node.pos) msvc_attrs := g.write_fn_attrs(node.attrs) // Live is_livefn := node.attrs.contains('live') is_livemain := g.pref.is_livemain && is_livefn is_liveshared := g.pref.is_liveshared && is_livefn is_livemode := g.pref.is_livemain || g.pref.is_liveshared is_live_wrap := is_livefn && is_livemode if is_livefn && !is_livemode { eprintln('INFO: compile with `v -live $g.pref.path `, if you want to use the [live] function $node.name .') } // mut name := node.name if name in ['+', '-', '*', '/', '%', '<', '=='] { name = util.replace_op(name) } if node.is_method { unwrapped_rec_sym := g.table.get_type_symbol(g.unwrap_generic(node.receiver.typ)) if unwrapped_rec_sym.kind == .placeholder { return } name = g.cc_type(node.receiver.typ, false) + '_' + name // name = g.table.get_type_symbol(node.receiver.typ).name + '_' + name } if node.language == .c { name = util.no_dots(name) } else { name = c_name(name) } mut type_name := g.typ(node.return_type) name = g.generic_fn_name(g.table.cur_concrete_types, name, true) if g.pref.obfuscate && g.cur_mod.name == 'main' && name.starts_with('main__') && !node.is_main && node.name != 'str' { mut key := node.name if node.is_method { sym := g.table.get_type_symbol(node.receiver.typ) key = sym.name + '.' + node.name } g.writeln('/* obf: $key */') name = g.obf_table[key] or { panic('cgen: fn_decl: obf name "$key" not found, this should never happen') } } // if g.pref.show_cc && it.is_builtin { // println(name) // } // type_name := g.ast.Type_to_str(it.return_type) // Live functions are protected by a mutex, because otherwise they // can be changed by the live reload thread, *while* they are // running, with unpredictable results (usually just crashing). // For this purpose, the actual body of the live function, // is put under a non publicly accessible function, that is prefixed // with 'impl_live_' . if is_livemain { g.hotcode_fn_names << name } mut impl_fn_name := name if is_live_wrap { impl_fn_name = 'impl_live_$name' } last_fn_c_name_save := g.last_fn_c_name defer { g.last_fn_c_name = last_fn_c_name_save } g.last_fn_c_name = impl_fn_name // if is_live_wrap { if is_livemain { g.definitions.write_string('$type_name (* $impl_fn_name)(') g.write('$type_name no_impl_${name}(') } if is_liveshared { g.definitions.write_string('$type_name ${impl_fn_name}(') g.write('$type_name ${impl_fn_name}(') } } else { if !(node.is_pub || g.pref.is_debug) { // Private functions need to marked as static so that they are not exportable in the // binaries if g.pref.build_mode != .build_module && !g.pref.use_cache { // if !(g.pref.build_mode == .build_module && g.is_builtin_mod) { // If we are building vlib/builtin, we need all private functions like array_get // to be public, so that all V programs can access them. g.write('VV_LOCAL_SYMBOL ') g.definitions.write_string('VV_LOCAL_SYMBOL ') } } fn_header := if msvc_attrs.len > 0 { '$type_name $msvc_attrs ${name}(' } else { '$type_name ${name}(' } g.definitions.write_string(fn_header) g.write(fn_header) } arg_start_pos := g.out.len fargs, fargtypes, heap_promoted := g.fn_args(node.params, node.scope) if is_closure { mut s := '$cur_closure_ctx *$c.closure_ctx' if node.params.len > 0 { s = ', ' + s } else { // remove generated `void` g.out.cut_to(arg_start_pos) } g.definitions.write_string(s) g.write(s) g.nr_closures++ } arg_str := g.out.after(arg_start_pos) if node.no_body || ((g.pref.use_cache && g.pref.build_mode != .build_module) && node.is_builtin && !g.is_test) || skip { // Just a function header. Builtin function bodies are defined in builtin.o g.definitions.writeln(');') // // NO BODY') g.writeln(');') return } g.definitions.writeln(');') g.writeln(') {') for i, is_promoted in heap_promoted { if is_promoted { g.writeln('${fargtypes[i]}* ${fargs[i]} = HEAP(${fargtypes[i]}, _v_toheap_${fargs[i]});') } } for defer_stmt in node.defer_stmts { g.writeln('bool ${g.defer_flag_var(defer_stmt)} = false;') for var in defer_stmt.defer_vars { if var.name in fargs || var.kind == .constant { continue } if var.kind == .variable { if var.name !in g.defer_vars { g.defer_vars << var.name mut deref := '' if v := var.scope.find_var(var.name) { if v.is_auto_heap { deref = '*' } } info := var.obj as ast.Var g.writeln('${g.typ(info.typ)}$deref $var.name;') } } } } if is_live_wrap { // The live function just calls its implementation dual, while ensuring // that the call is wrapped by the mutex lock & unlock calls. // Adding the mutex lock/unlock inside the body of the implementation // function is not reliable, because the implementation function can do // an early exit, which will leave the mutex locked. mut fn_args_list := []string{} for ia, fa in fargs { fn_args_list << '${fargtypes[ia]} $fa' } mut live_fncall := '${impl_fn_name}(' + fargs.join(', ') + ');' mut live_fnreturn := '' if type_name != 'void' { live_fncall = '$type_name res = $live_fncall' live_fnreturn = 'return res;' } g.definitions.writeln('$type_name ${name}(' + fn_args_list.join(', ') + ');') g.hotcode_definitions.writeln('$type_name ${name}(' + fn_args_list.join(', ') + '){') g.hotcode_definitions.writeln(' pthread_mutex_lock(&live_fn_mutex);') g.hotcode_definitions.writeln(' $live_fncall') g.hotcode_definitions.writeln(' pthread_mutex_unlock(&live_fn_mutex);') g.hotcode_definitions.writeln(' $live_fnreturn') g.hotcode_definitions.writeln('}') } // Profiling mode? Start counting at the beginning of the function (save current time). if g.pref.is_prof && g.pref.build_mode != .build_module { g.profile_fn(node) } // we could be in an anon fn so save outer fn defer stmts prev_defer_stmts := g.defer_stmts g.defer_stmts = [] ctmp := g.tmp_count g.tmp_count = 0 defer { g.tmp_count = ctmp } g.stmts(node.stmts) if node.is_noreturn { g.writeln('\twhile(1);') } // clear g.fn_mut_arg_names if !node.has_return { g.write_defer_stmts_when_needed() } if node.is_anon { g.defer_stmts = prev_defer_stmts } else { g.defer_stmts = [] } if node.return_type != ast.void_type && node.stmts.len > 0 && node.stmts.last() !is ast.Return && !node.attrs.contains('_naked') { default_expr := g.type_default(node.return_type) // TODO: perf? if default_expr == '{0}' { // if node.return_type.idx() == 1 && node.return_type.has_flag(.optional) { // // The default return for anonymous functions that return `?, // // should have .ok = true set, otherwise calling them with // // optfn() or { panic(err) } will cause a panic: // g.writeln('\treturn (Option_void){0};') // } else { g.writeln('\treturn ($type_name)$default_expr;') // } } else { g.writeln('\treturn $default_expr;') } } g.writeln('}') if g.pref.printfn_list.len > 0 && g.last_fn_c_name in g.pref.printfn_list { println(g.out.after(fn_start_pos)) } for attr in node.attrs { if attr.name == 'export' { g.writeln('// export alias: $attr.arg -> $name') export_alias := '$type_name ${attr.arg}($arg_str)' g.definitions.writeln('VV_EXPORTED_SYMBOL $export_alias; // exported fn $node.name') g.writeln('$export_alias {') g.write('\treturn ${name}(') g.write(fargs.join(', ')) g.writeln(');') g.writeln('}') } } } const closure_ctx = '_V_closure_ctx' fn closure_ctx_struct(node ast.FnDecl) string { return 'struct _V_${node.name}_Ctx' } fn (mut g Gen) gen_anon_fn(mut node ast.AnonFn) { g.gen_anon_fn_decl(mut node) if !node.decl.scope.has_inherited_vars() { g.write(node.decl.name) return } // it may be possible to optimize `memdup` out if the closure never leaves current scope ctx_var := g.new_tmp_var() cur_line := g.go_before_stmt(0) ctx_struct := closure_ctx_struct(node.decl) g.writeln('$ctx_struct* $ctx_var = ($ctx_struct*) memdup(&($ctx_struct){') g.indent++ for var in node.inherited_vars { g.writeln('.$var.name = $var.name,') } g.indent-- g.writeln('}, sizeof($ctx_struct));') g.empty_line = false g.write(cur_line) // TODO in case of an assignment, this should only call "__closure_set_data" and "__closure_set_function" (and free the former data) g.write('__closure_create($node.decl.name, ${node.decl.params.len + 1}, $ctx_var)') } fn (mut g Gen) gen_anon_fn_decl(mut node ast.AnonFn) { if node.has_gen { return } node.has_gen = true mut builder := strings.new_builder(256) if node.inherited_vars.len > 0 { ctx_struct := closure_ctx_struct(node.decl) builder.writeln('$ctx_struct {') for var in node.inherited_vars { styp := g.typ(var.typ) builder.writeln('\t$styp $var.name;') } builder.writeln('};\n') } pos := g.out.len was_anon_fn := g.anon_fn g.anon_fn = true g.process_fn_decl(node.decl) g.anon_fn = was_anon_fn builder.write_string(g.out.cut_to(pos)) g.anon_fn_definitions << builder.str() } fn (g &Gen) defer_flag_var(stmt &ast.DeferStmt) string { return '${g.last_fn_c_name}_defer_$stmt.idx_in_fn' } fn (mut g Gen) write_defer_stmts_when_needed() { // unlock all mutexes, in case we are in a lock statement. defers are not allowed in lock statements g.unlock_locks() if g.defer_stmts.len > 0 { g.write_defer_stmts() } if g.defer_profile_code.len > 0 { g.writeln('') g.writeln('\t// defer_profile_code') g.writeln(g.defer_profile_code) g.writeln('') } } // fn decl args fn (mut g Gen) fn_args(args []ast.Param, scope &ast.Scope) ([]string, []string, []bool) { mut fargs := []string{} mut fargtypes := []string{} mut heap_promoted := []bool{} if args.len == 0 { // in C, `()` is untyped, unlike `(void)` g.write('void') } for i, arg in args { mut caname := if arg.name == '_' { g.new_tmp_declaration_name() } else { c_name(arg.name) } typ := g.unwrap_generic(arg.typ) arg_type_sym := g.table.get_type_symbol(typ) mut arg_type_name := g.typ(typ) // util.no_dots(arg_type_sym.name) if arg_type_sym.kind == .function { info := arg_type_sym.info as ast.FnType func := info.func g.write('${g.typ(func.return_type)} (*$caname)(') g.definitions.write_string('${g.typ(func.return_type)} (*$caname)(') g.fn_args(func.params, voidptr(0)) g.write(')') g.definitions.write_string(')') fargs << caname fargtypes << arg_type_name } else { mut heap_prom := false if scope != voidptr(0) { if arg.name != '_' { if v := scope.find_var(arg.name) { if !v.is_stack_obj && v.is_auto_heap { heap_prom = true } } } } var_name_prefix := if heap_prom { '_v_toheap_' } else { '' } const_prefix := if arg.typ.is_any_kind_of_pointer() && !arg.is_mut && arg.name.starts_with('const_') { 'const ' } else { '' } s := '$const_prefix$arg_type_name $var_name_prefix$caname' g.write(s) g.definitions.write_string(s) fargs << caname fargtypes << arg_type_name heap_promoted << heap_prom } if i < args.len - 1 { g.write(', ') g.definitions.write_string(', ') } } return fargs, fargtypes, heap_promoted } fn (mut g Gen) call_expr(node ast.CallExpr) { // g.write('/*call expr*/') // NOTE: everything could be done this way // see my comment in parser near anon_fn if node.left is ast.AnonFn { g.expr(node.left) } if node.left is ast.IndexExpr && node.name == '' { g.is_fn_index_call = true g.expr(node.left) g.is_fn_index_call = false } if node.should_be_skipped { return } g.inside_call = true defer { g.inside_call = false } gen_keep_alive := node.is_keep_alive && node.return_type != ast.void_type && g.pref.gc_mode in [.boehm_full, .boehm_incr, .boehm_full_opt, .boehm_incr_opt] gen_or := node.or_block.kind != .absent // && !g.is_autofree is_gen_or_and_assign_rhs := gen_or && !g.discard_or_result cur_line := if is_gen_or_and_assign_rhs || gen_keep_alive { // && !g.is_autofree { // `x := foo() or { ...}` // cut everything that has been generated to prepend optional variable creation line := g.go_before_stmt(0) g.out.write_string(util.tabs(g.indent)) // g.write('/*is_gen_or_and_assign_rhs*/') line } else { '' } tmp_opt := if gen_or || gen_keep_alive { g.new_tmp_var() } else { '' } if gen_or || gen_keep_alive { mut ret_typ := node.return_type if gen_or { ret_typ = ret_typ.set_flag(.optional) } styp := g.typ(ret_typ) g.write('$styp $tmp_opt = ') } if node.is_method && !node.is_field { if node.name == 'writeln' && g.pref.experimental && node.args.len > 0 && node.args[0].expr is ast.StringInterLiteral && g.table.get_type_symbol(node.receiver_type).name == 'strings.Builder' { g.string_inter_literal_sb_optimized(node) } else { g.method_call(node) } } else { g.fn_call(node) } if gen_or { // && !g.autofree { // if !g.is_autofree { g.or_block(tmp_opt, node.or_block, node.return_type) //} if is_gen_or_and_assign_rhs { unwrapped_typ := node.return_type.clear_flag(.optional) unwrapped_styp := g.typ(unwrapped_typ) if unwrapped_typ == ast.void_type { g.write('\n $cur_line') } else if g.table.get_type_symbol(node.return_type).kind == .multi_return { g.write('\n $cur_line $tmp_opt /*U*/') } else { if !g.inside_const { g.write('\n $cur_line (*($unwrapped_styp*)${tmp_opt}.data)') } else { g.write('\n $cur_line $tmp_opt') } } } } else if gen_keep_alive { if node.return_type == ast.void_type { g.write('\n $cur_line') } else { g.write('\n $cur_line $tmp_opt') } } if node.is_noreturn { if g.inside_ternary == 0 { g.writeln(';') g.write('VUNREACHABLE()') } else { $if msvc { // MSVC has no support for the statement expressions used below } $else { g.write(', ({VUNREACHABLE();})') } } } } fn (mut g Gen) conversion_function_call(prefix string, postfix string, node ast.CallExpr) { g.write('${prefix}( (') g.expr(node.left) dot := if node.left_type.is_ptr() { '->' } else { '.' } g.write(')${dot}_typ )$postfix') } fn (mut g Gen) method_call(node ast.CallExpr) { // TODO: there are still due to unchecked exprs (opt/some fn arg) if node.left_type == 0 { g.checker_bug('CallExpr.left_type is 0 in method_call', node.pos) } if node.receiver_type == 0 { g.checker_bug('CallExpr.receiver_type is 0 in method_call', node.pos) } mut unwrapped_rec_type := node.receiver_type if g.table.cur_fn.generic_names.len > 0 { // in generic fn unwrapped_rec_type = g.unwrap_generic(node.receiver_type) } else { // in non-generic fn sym := g.table.get_type_symbol(node.receiver_type) match sym.info { ast.Struct, ast.Interface, ast.SumType { generic_names := sym.info.generic_types.map(g.table.get_type_symbol(it).name) if utyp := g.table.resolve_generic_to_concrete(node.receiver_type, generic_names, sym.info.concrete_types) { unwrapped_rec_type = utyp } } else {} } } mut typ_sym := g.table.get_type_symbol(unwrapped_rec_type) // alias type that undefined this method (not include `str`) need to use parent type if typ_sym.kind == .alias && node.name != 'str' && !typ_sym.has_method(node.name) { unwrapped_rec_type = (typ_sym.info as ast.Alias).parent_type typ_sym = g.table.get_type_symbol(unwrapped_rec_type) } rec_cc_type := g.cc_type(unwrapped_rec_type, false) mut receiver_type_name := util.no_dots(rec_cc_type) if typ_sym.kind == .interface_ && (typ_sym.info as ast.Interface).defines_method(node.name) { // Speaker_name_table[s._interface_idx].speak(s._object) $if debug_interface_method_call ? { eprintln('>>> interface typ_sym.name: $typ_sym.name | receiver_type_name: $receiver_type_name') } g.write('${c_name(receiver_type_name)}_name_table[') g.expr(node.left) dot := if node.left_type.is_ptr() { '->' } else { '.' } mname := c_name(node.name) g.write('${dot}_typ]._method_${mname}(') g.expr(node.left) g.write('${dot}_object') if node.args.len > 0 { g.write(', ') g.call_args(node) } g.write(')') return } left_sym := g.table.get_type_symbol(node.left_type) final_left_sym := g.table.get_final_type_symbol(node.left_type) if left_sym.kind == .array { match node.name { 'filter' { g.gen_array_filter(node) return } 'sort' { g.gen_array_sort(node) return } 'insert' { g.gen_array_insert(node) return } 'map' { g.gen_array_map(node) return } 'prepend' { g.gen_array_prepend(node) return } 'contains' { g.gen_array_contains(node) return } 'index' { g.gen_array_index(node) return } 'wait' { g.gen_array_wait(node) return } 'any' { g.gen_array_any(node) return } 'all' { g.gen_array_all(node) return } else {} } } if left_sym.kind == .map && node.name == 'delete' { left_info := left_sym.info as ast.Map elem_type_str := g.typ(left_info.key_type) g.write('map_delete(') if node.left_type.is_ptr() { g.expr(node.left) } else { g.write('&') g.expr(node.left) } g.write(', &($elem_type_str[]){') g.expr(node.args[0].expr) g.write('})') return } else if left_sym.kind == .array && node.name == 'delete' { g.write('array_delete(') if node.left_type.is_ptr() { g.expr(node.left) } else { g.write('&') g.expr(node.left) } g.write(', ') g.expr(node.args[0].expr) g.write(')') return } if left_sym.kind in [.sum_type, .interface_] { if node.name == 'type_name' { if left_sym.kind == .sum_type { g.conversion_function_call('charptr_vstring_literal( /* $left_sym.name */ v_typeof_sumtype_$typ_sym.cname', ')', node) return } if left_sym.kind == .interface_ { g.conversion_function_call('charptr_vstring_literal( /* $left_sym.name */ v_typeof_interface_$typ_sym.cname', ')', node) return } } if node.name == 'type_idx' { if left_sym.kind == .sum_type { g.conversion_function_call('/* $left_sym.name */ v_typeof_sumtype_idx_$typ_sym.cname', '', node) return } if left_sym.kind == .interface_ { g.conversion_function_call('/* $left_sym.name */ v_typeof_interface_idx_$typ_sym.cname', '', node) return } } } if node.name == 'str' { mut rec_type := node.receiver_type if rec_type.has_flag(.shared_f) { rec_type = rec_type.clear_flag(.shared_f).set_nr_muls(0) } g.gen_str_method_for_type(rec_type) } else if node.name == 'free' { mut rec_type := node.receiver_type if rec_type.has_flag(.shared_f) { rec_type = rec_type.clear_flag(.shared_f).set_nr_muls(0) } g.gen_free_method_for_type(rec_type) } mut has_cast := false if left_sym.kind == .map && node.name in ['clone', 'move'] { receiver_type_name = 'map' } if final_left_sym.kind == .array && node.name in ['repeat', 'sort_with_compare', 'free', 'push_many', 'trim', 'first', 'last', 'pop', 'clone', 'reverse', 'slice', 'pointers'] { if !(left_sym.info is ast.Alias && typ_sym.has_method(node.name)) { // `array_Xyz_clone` => `array_clone` receiver_type_name = 'array' } if node.name in ['last', 'first', 'pop'] { return_type_str := g.typ(node.return_type) has_cast = true g.write('(*($return_type_str*)') } } mut name := util.no_dots('${receiver_type_name}_$node.name') mut array_depth := -1 mut noscan := '' if left_sym.kind == .array { needs_depth := node.name in ['clone', 'repeat'] if needs_depth { elem_type := (left_sym.info as ast.Array).elem_type array_depth = g.get_array_depth(elem_type) } maybe_noscan := needs_depth || node.name in ['pop', 'push', 'push_many', 'reverse', 'grow_cap', 'grow_len'] if maybe_noscan { info := left_sym.info as ast.Array noscan = g.check_noscan(info.elem_type) } } else if left_sym.kind == .chan { if node.name in ['close', 'try_pop', 'try_push'] { name = 'sync__Channel_$node.name' } } else if left_sym.kind == .map { if node.name == 'keys' { name = 'map_keys' } } if g.pref.obfuscate && g.cur_mod.name == 'main' && name.starts_with('main__') && node.name != 'str' { sym := g.table.get_type_symbol(node.receiver_type) key := sym.name + '.' + node.name g.write('/* obf method call: $key */') name = g.obf_table[key] or { panic('cgen: obf name "$key" not found, this should never happen') } } // Check if expression is: arr[a..b].clone(), arr[a..].clone() // if so, then instead of calling array_clone(&array_slice(...)) // call array_clone_static(array_slice(...)) mut is_range_slice := false if node.receiver_type.is_ptr() && !node.left_type.is_ptr() { if node.left is ast.IndexExpr { idx := node.left.index if idx is ast.RangeExpr { // expr is arr[range].clone() // use array_clone_static instead of array_clone name = util.no_dots('${receiver_type_name}_${node.name}_static') is_range_slice = true } } } name = g.generic_fn_name(node.concrete_types, name, false) // TODO2 // g.generate_tmp_autofree_arg_vars(node, name) // // if node.receiver_type != 0 { // g.write('/*${g.typ(node.receiver_type)}*/') // g.write('/*expr_type=${g.typ(node.left_type)} rec type=${g.typ(node.receiver_type)}*/') // } if !node.receiver_type.is_ptr() && node.left_type.is_ptr() && node.name == 'str' { g.write('ptr_str(') } else { if left_sym.kind == .array { if array_depth >= 0 { name = name + '_to_depth' } g.write('$name${noscan}(') } else { g.write('${name}(') } } if node.receiver_type.is_ptr() && (!node.left_type.is_ptr() || node.left_type.has_flag(.variadic) || node.from_embed_type != 0 || (node.left_type.has_flag(.shared_f) && node.name != 'str')) { // The receiver is a reference, but the caller provided a value // Add `&` automatically. // TODO same logic in call_args() if !is_range_slice { if !node.left.is_lvalue() { g.write('ADDR($rec_cc_type, ') has_cast = true } else { g.write('&') } } } else if !node.receiver_type.is_ptr() && node.left_type.is_ptr() && node.name != 'str' && node.from_embed_type == 0 { if !node.left_type.has_flag(.shared_f) { g.write('/*rec*/*') } } else if !is_range_slice && node.from_embed_type == 0 && node.name != 'str' { diff := node.left_type.nr_muls() - node.receiver_type.nr_muls() if diff < 0 { // TODO // g.write('&') } else if diff > 0 { g.write('/*diff=$diff*/') g.write([]byte{len: diff, init: `*`}.bytestr()) } } // if node.left_type.idx() != node.receiver_type.idx() { // println('${g.typ(node.left_type)} ${g.typ(node.receiver_type)}') // } if g.is_autofree && node.free_receiver && !g.inside_lambda && !g.is_builtin_mod { // The receiver expression needs to be freed, use the temp var. fn_name := node.name.replace('.', '_') arg_name := '_arg_expr_${fn_name}_0_$node.pos.pos' g.write('/*af receiver arg*/' + arg_name) } else { if left_sym.kind == .array && node.left.is_auto_deref_var() && node.name in ['first', 'last', 'repeat'] { g.write('*') } if node.left is ast.MapInit { g.write('(map[]){') g.expr(node.left) g.write('}[0]') } else { g.expr(node.left) } if node.from_embed_type != 0 { embed_name := typ_sym.embed_name() if node.left_type.is_ptr() { g.write('->') } else { g.write('.') } g.write(embed_name) } if node.left_type.has_flag(.shared_f) { g.write('->val') } } if has_cast { g.write(')') } is_variadic := node.expected_arg_types.len > 0 && node.expected_arg_types[node.expected_arg_types.len - 1].has_flag(.variadic) if node.args.len > 0 || is_variadic { g.write(', ') } // ///////// /* if name.contains('subkeys') { println('call_args $name $node.arg_types.len') for t in node.arg_types { sym := g.table.get_type_symbol(t) print('$sym.name ') } println('') } */ // /////// g.call_args(node) if array_depth >= 0 { g.write(', $array_depth') } g.write(')') } fn (mut g Gen) fn_call(node ast.CallExpr) { // call struct field with fn type // TODO: test node.left instead // left & left_type will be `x` and `x type` in `x.fieldfn()` // will be `0` for `foo()` mut is_interface_call := false mut is_selector_call := false if node.left_type != 0 { left_sym := g.table.get_type_symbol(node.left_type) if left_sym.kind == .interface_ { is_interface_call = true g.write('(*') } g.expr(node.left) if node.left_type.is_ptr() { g.write('->') } else { g.write('.') } is_selector_call = true } mut name := node.name is_print := name in ['print', 'println', 'eprint', 'eprintln', 'panic'] print_method := name is_json_encode := name == 'json.encode' is_json_encode_pretty := name == 'json.encode_pretty' is_json_decode := name == 'json.decode' g.is_json_fn = is_json_encode || is_json_encode_pretty || is_json_decode mut json_type_str := '' mut json_obj := '' if g.is_json_fn { json_obj = g.new_tmp_var() mut tmp2 := '' cur_line := g.go_before_stmt(0) if is_json_encode || is_json_encode_pretty { g.gen_json_for_type(node.args[0].typ) json_type_str = g.typ(node.args[0].typ) // `json__encode` => `json__encode_User` // encode_name := c_name(name) + '_' + util.no_dots(json_type_str) encode_name := js_enc_name(json_type_str) g.writeln('// json.encode') g.write('cJSON* $json_obj = ${encode_name}(') if node.args[0].typ.is_ptr() { g.write('*') } g.call_args(node) g.writeln(');') tmp2 = g.new_tmp_var() if is_json_encode { g.writeln('string $tmp2 = json__json_print($json_obj);') } else { g.writeln('string $tmp2 = json__json_print_pretty($json_obj);') } } else { ast_type := node.args[0].expr as ast.TypeNode // `json.decode(User, s)` => json.decode_User(s) typ := c_name(g.typ(ast_type.typ)) fn_name := c_name(name) + '_' + typ g.gen_json_for_type(ast_type.typ) g.writeln('// json.decode') g.write('cJSON* $json_obj = json__json_parse(') // Skip the first argument in json.decode which is a type // its name was already used to generate the function call g.is_js_call = true g.call_args(node) g.is_js_call = false g.writeln(');') tmp2 = g.new_tmp_var() g.writeln('Option_$typ $tmp2 = $fn_name ($json_obj);') } if !g.is_autofree { g.write('cJSON_Delete($json_obj); //del') } g.write('\n$cur_line') name = '' json_obj = tmp2 } if node.language == .c { // Skip "C." name = util.no_dots(name[2..]) } else { name = c_name(name) } // Obfuscate only functions in the main module for now if g.pref.obfuscate && g.cur_mod.name == 'main' && name.starts_with('main__') { key := node.name g.write('/* obf call: $key */') name = g.obf_table[key] or { panic('cgen: obf name "$key" not found, this should never happen') } } if !is_selector_call { name = g.generic_fn_name(node.concrete_types, name, false) } // TODO2 // cgen shouldn't modify ast nodes, this should be moved // g.generate_tmp_autofree_arg_vars(node, name) // Handle `print(x)` mut print_auto_str := false if is_print && node.args[0].typ != ast.string_type { // && !free_tmp_arg_vars { mut typ := node.args[0].typ if typ == 0 { g.checker_bug('print arg.typ is 0', node.pos) } if typ != ast.string_type { expr := node.args[0].expr if g.is_autofree && !typ.has_flag(.optional) { // Create a temporary variable so that the value can be freed tmp := g.new_tmp_var() // tmps << tmp g.write('string $tmp = ') g.gen_expr_to_string(expr, typ) g.writeln('; ${c_name(print_method)}($tmp); string_free(&$tmp);') } else { g.write('${c_name(print_method)}(') g.gen_expr_to_string(expr, typ) g.write(')') } print_auto_str = true } } if !print_auto_str { if g.pref.is_debug && node.name == 'panic' { paline, pafile, pamod, pafn := g.panic_debug_info(node.pos) g.write('panic_debug($paline, tos3("$pafile"), tos3("$pamod"), tos3("$pafn"), ') g.call_args(node) g.write(')') } else { // Simple function call // if free_tmp_arg_vars { // g.writeln(';') // g.write(cur_line + ' /* <== af cur line*/') // } g.write(g.get_ternary_name(name)) if is_interface_call { g.write(')') } mut tmp_cnt_save := -1 g.write('(') if g.is_json_fn { g.write(json_obj) } else { if node.is_keep_alive && g.pref.gc_mode in [.boehm_full, .boehm_incr, .boehm_full_opt, .boehm_incr_opt] { cur_line := g.go_before_stmt(0) tmp_cnt_save = g.keep_alive_call_pregen(node) g.write(cur_line) for i in 0 .. node.args.len { if i > 0 { g.write(', ') } g.write('__tmp_arg_${tmp_cnt_save + i}') } } else { g.call_args(node) } } g.write(')') if tmp_cnt_save >= 0 { g.writeln(';') g.keep_alive_call_postgen(node, tmp_cnt_save) } } } g.is_json_fn = false } fn (mut g Gen) autofree_call_pregen(node ast.CallExpr) { // g.writeln('// autofree_call_pregen()') // Create a temporary var before fn call for each argument in order to free it (only if it's a complex expression, // like `foo(get_string())` or `foo(a + b)` mut free_tmp_arg_vars := g.is_autofree && !g.is_builtin_mod && node.args.len > 0 && !node.args[0].typ.has_flag(.optional) // TODO copy pasta checker.v if !free_tmp_arg_vars { return } if g.is_js_call { return } if g.inside_const { return } free_tmp_arg_vars = false // set the flag to true only if we have at least one arg to free g.tmp_count2++ mut scope := g.file.scope.innermost(node.pos.pos) // prepend the receiver for now (TODO turn the receiver into a CallArg everywhere?) mut args := [ ast.CallArg{ typ: node.receiver_type expr: node.left is_tmp_autofree: node.free_receiver }, ] args << node.args // for i, arg in node.args { for i, arg in args { if !arg.is_tmp_autofree { continue } if arg.expr is ast.CallExpr { // Any argument can be an expression that has to be freed. Generate a tmp expression // for each of those recursively. g.autofree_call_pregen(arg.expr) } free_tmp_arg_vars = true // t := g.new_tmp_var() + '_arg_expr_${name}_$i' fn_name := node.name.replace('.', '_') // can't use name... // t := '_tt${g.tmp_count2}_arg_expr_${fn_name}_$i' t := '_arg_expr_${fn_name}_${i}_$node.pos.pos' // g.called_fn_name = name used := false // scope.known_var(t) mut s := '$t = ' if used { // This means this tmp var name was already used (the same function was called and // `_arg_fnname_1` was already generated). // We do not need to declare this variable again, so just generate `t = ...` // instead of `string t = ...`, and we need to mark this variable as unused, // so that it's freed after the call. (Used tmp arg vars are not freed to avoid double frees). if x := scope.find(t) { match mut x { ast.Var { x.is_used = false } else {} } } s = '$t = ' } else { scope.register(ast.Var{ name: t typ: ast.string_type is_autofree_tmp: true pos: node.pos }) s = 'string $t = ' } // g.expr(arg.expr) s += g.expr_string(arg.expr) // g.writeln(';// new af pre') s += ';// new af2 pre' g.strs_to_free0 << s // This tmp arg var will be freed with the rest of the vars at the end of the scope. } } fn (mut g Gen) autofree_call_postgen(node_pos int) { // if g.strs_to_free.len == 0 { // return // } // g.writeln('\n/* strs_to_free3: $g.nr_vars_to_free */') // if g.nr_vars_to_free <= 0 { // return // } /* for s in g.strs_to_free { g.writeln('string_free(&$s);') } if !g.inside_or_block { // we need to free the vars both inside the or block (in case of an error) and after it // if we reset the array here, then the vars will not be freed after the block. g.strs_to_free = [] } */ if g.inside_vweb_tmpl { return } // g.doing_autofree_tmp = true // g.write('/* postgen */') scope := g.file.scope.innermost(node_pos) for _, obj in scope.objects { match mut obj { ast.Var { // if var.typ == 0 { // // TODO why 0? // continue // } is_optional := obj.typ.has_flag(.optional) if is_optional { // TODO: free optionals continue } if !obj.is_autofree_tmp { continue } if obj.is_used { // this means this tmp expr var has already been freed continue } obj.is_used = true // TODO bug? sets all vars is_used to true g.autofree_variable(obj) // g.nr_vars_to_free-- } else {} } } // g.write('/* postgen end */') // g.doing_autofree_tmp = false } fn (mut g Gen) call_args(node ast.CallExpr) { args := if g.is_js_call { node.args[1..] } else { node.args } expected_types := node.expected_arg_types // only v variadic, C variadic args will be appeneded like normal args is_variadic := expected_types.len > 0 && expected_types.last().has_flag(.variadic) && node.language == .v for i, arg in args { if is_variadic && i == expected_types.len - 1 { break } use_tmp_var_autofree := g.is_autofree && arg.typ == ast.string_type && arg.is_tmp_autofree && !g.inside_const && !g.is_builtin_mod // g.write('/* af=$arg.is_tmp_autofree */') // some c fn definitions dont have args (cfns.v) or are not updated in checker // when these are fixed we wont need this check if i < expected_types.len { if use_tmp_var_autofree { if arg.is_tmp_autofree { // && !g.is_js_call { // We saved expressions in temp variables so that they can be freed later. // `foo(str + str2) => x := str + str2; foo(x); x.free()` // g.write('_arg_expr_${g.called_fn_name}_$i') // Use these variables here. fn_name := node.name.replace('.', '_') // name := '_tt${g.tmp_count2}_arg_expr_${fn_name}_$i' name := '_arg_expr_${fn_name}_${i + 1}_$node.pos.pos' g.write('/*af arg*/' + name) } } else { if node.concrete_types.len > 0 && arg.expr.is_auto_deref_var() && !arg.is_mut && !expected_types[i].is_ptr() { g.write('*') } g.ref_or_deref_arg(arg, expected_types[i], node.language) } } else { if use_tmp_var_autofree { // TODO copypasta, move to an inline fn fn_name := node.name.replace('.', '_') // name := '_tt${g.tmp_count2}_arg_expr_${fn_name}_$i' name := '_arg_expr_${fn_name}_${i + 1}_$node.pos.pos' g.write('/*af arg2*/' + name) } else { g.expr(arg.expr) } } if i < args.len - 1 || is_variadic { g.write(', ') } } arg_nr := expected_types.len - 1 if is_variadic { varg_type := expected_types.last() variadic_count := args.len - arg_nr arr_sym := g.table.get_type_symbol(varg_type) mut arr_info := arr_sym.info as ast.Array if varg_type.has_flag(.generic) { if fn_def := g.table.find_fn(node.name) { if utyp := g.table.resolve_generic_to_concrete(arr_info.elem_type, fn_def.generic_names, node.concrete_types) { arr_info.elem_type = utyp } } else { g.error('unable to find function $node.name', node.pos) } } elem_type := g.typ(arr_info.elem_type) if g.pref.translated && args.len == 1 { // Handle `foo(c'str')` for `fn foo(args ...&u8)` // TODOC2V handle this in a better place // println(g.table.type_to_str(args[0].typ)) g.expr(args[0].expr) } else if args.len > 0 && args[args.len - 1].expr is ast.ArrayDecompose { g.expr(args[args.len - 1].expr) } else { if variadic_count > 0 { noscan := g.check_noscan(arr_info.elem_type) g.write('new_array_from_c_array${noscan}($variadic_count, $variadic_count, sizeof($elem_type), _MOV(($elem_type[$variadic_count]){') for j in arg_nr .. args.len { g.ref_or_deref_arg(args[j], arr_info.elem_type, node.language) if j < args.len - 1 { g.write(', ') } } g.write('}))') } else { g.write('__new_array(0, 0, sizeof($elem_type))') } } } } // similar to `autofree_call_pregen()` but only to to handle [keep_args_alive] for C functions fn (mut g Gen) keep_alive_call_pregen(node ast.CallExpr) int { g.empty_line = true g.writeln('// keep_alive_call_pregen()') // reserve the next tmp_vars for arguments tmp_cnt_save := g.tmp_count + 1 g.tmp_count += node.args.len for i, arg in node.args { // save all arguments in temp vars (not only pointers) to make sure the // evaluation order is preserved expected_type := node.expected_arg_types[i] typ := g.table.get_type_symbol(expected_type).cname g.write('$typ __tmp_arg_${tmp_cnt_save + i} = ') // g.expr(arg.expr) g.ref_or_deref_arg(arg, expected_type, node.language) g.writeln(';') } g.empty_line = false return tmp_cnt_save } fn (mut g Gen) keep_alive_call_postgen(node ast.CallExpr, tmp_cnt_save int) { g.writeln('// keep_alive_call_postgen()') for i, expected_type in node.expected_arg_types { if expected_type.is_ptr() || expected_type.is_pointer() { g.writeln('GC_reachable_here(__tmp_arg_${tmp_cnt_save + i});') } } } [inline] fn (mut g Gen) ref_or_deref_arg(arg ast.CallArg, expected_type ast.Type, lang ast.Language) { arg_is_ptr := expected_type.is_ptr() || expected_type.idx() in ast.pointer_type_idxs expr_is_ptr := arg.typ.is_ptr() || arg.typ.idx() in ast.pointer_type_idxs if expected_type == 0 { g.checker_bug('ref_or_deref_arg expected_type is 0', arg.pos) } exp_sym := g.table.get_type_symbol(expected_type) mut needs_closing := false if arg.is_mut && !arg_is_ptr { g.write('&/*mut*/') } else if arg_is_ptr && !expr_is_ptr { if arg.is_mut { if exp_sym.kind == .array { if (arg.expr is ast.Ident && (arg.expr as ast.Ident).kind == .variable) || arg.expr is ast.SelectorExpr { g.write('&/*arr*/') g.expr(arg.expr) } else { // Special case for mutable arrays. We can't `&` function // results, have to use `(array[]){ expr }[0]` hack. g.write('&/*111*/(array[]){') g.expr(arg.expr) g.write('}[0]') } return } } if !g.is_json_fn { if arg.typ == 0 { g.checker_bug('ref_or_deref_arg arg.typ is 0', arg.pos) } arg_typ_sym := g.table.get_type_symbol(arg.typ) expected_deref_type := if expected_type.is_ptr() { expected_type.deref() } else { expected_type } deref_sym := g.table.get_type_symbol(expected_deref_type) if !((arg_typ_sym.kind == .function) || deref_sym.kind in [.sum_type, .interface_]) && lang != .c { if arg.expr.is_lvalue() { g.write('(voidptr)&/*qq*/') } else { mut atype := expected_deref_type if atype.has_flag(.generic) { atype = g.unwrap_generic(atype) } if atype.has_flag(.generic) { g.write('(voidptr)&/*qq*/') } else { needs_closing = true g.write('ADDR(${g.typ(atype)}/*qq*/, ') } } } } } else if arg.typ.has_flag(.shared_f) && !expected_type.has_flag(.shared_f) { if expected_type.is_ptr() { g.write('&') } g.expr(arg.expr) g.write('->val') return } g.expr_with_cast(arg.expr, arg.typ, expected_type) if needs_closing { g.write(')') } } fn (mut g Gen) is_gui_app() bool { $if windows { if g.force_main_console { return false } for cf in g.table.cflags { if cf.value == 'gdi32' { return true } } } return false } fn (g &Gen) fileis(s string) bool { return g.file.path.contains(s) } fn (mut g Gen) write_fn_attrs(attrs []ast.Attr) string { mut msvc_attrs := '' for attr in attrs { match attr.name { 'inline' { g.write('inline ') } 'noinline' { // since these are supported by GCC, clang and MSVC, we can consider them officially supported. g.write('__NOINLINE ') } 'noreturn' { // a `[noreturn]` tag tells the compiler, that a function // *DOES NOT RETURN* to its callsites. // See: https://en.cppreference.com/w/c/language/_Noreturn // Such functions should have no return type. They can be used // in places where `panic(err)` or `exit(0)` can be used. // panic/1 and exit/0 themselves will also be marked as // `[noreturn]` soon. // These functions should have busy `for{}` loops injected // at their end, when they do not end by calling other fns // marked by `[noreturn]`. g.write('VNORETURN ') } 'irq_handler' { g.write('__IRQHANDLER ') } '_cold' { // GCC/clang attributes // prefixed by _ to indicate they're for advanced users only and not really supported by V. // source for descriptions: https://gcc.gnu.org/onlinedocs/gcc/Common-Function-Attributes.html#Common-Function-Attributes // The cold attribute on functions is used to inform the compiler that the function is unlikely // to be executed. The function is optimized for size rather than speed and on many targets it // is placed into a special subsection of the text section so all cold functions appear close // together, improving code locality of non-cold parts of program. g.write('__attribute__((cold)) ') } '_constructor' { // The constructor attribute causes the function to be called automatically before execution // enters main (). g.write('__attribute__((constructor)) ') } '_destructor' { // The destructor attribute causes the function to be called automatically after main () // completes or exit () is called. g.write('__attribute__((destructor)) ') } '_flatten' { // Generally, inlining into a function is limited. For a function marked with this attribute, // every call inside this function is inlined, if possible. g.write('__attribute__((flatten)) ') } '_hot' { // The hot attribute on a function is used to inform the compiler that the function is a hot // spot of the compiled program. g.write('__attribute__((hot)) ') } '_malloc' { // This tells the compiler that a function is malloc-like, i.e., that the pointer P returned by // the function cannot alias any other pointer valid when the function returns, and moreover no // pointers to valid objects occur in any storage addressed by P. g.write('__attribute__((malloc)) ') } '_pure' { // Calls to functions whose return value is not affected by changes to the observable state // of the program and that have no observable effects on such state other than to return a // value may lend themselves to optimizations such as common subexpression elimination. // Declaring such functions with the const attribute allows GCC to avoid emitting some calls in // repeated invocations of the function with the same argument values. g.write('__attribute__((const)) ') } '_naked' { g.write('__attribute__((naked)) ') } 'windows_stdcall' { // windows attributes (msvc/mingw) // prefixed by windows to indicate they're for advanced users only and not really supported by V. msvc_attrs += '__stdcall ' } 'console' { g.force_main_console = true } else { // nothing but keep V happy } } } return msvc_attrs }