#import "os.odin"; #import "mem.odin"; #import "utf8.odin"; #import "types.odin"; _BUFFER_SIZE :: 1<<12; Buffer :: struct { data: []byte, length: int, } buffer_write :: proc(buf: ^Buffer, b: []byte) { if buf.length < buf.data.count { n := min(buf.data.count-buf.length, b.count); if n > 0 { copy(buf.data[buf.length:], b[:n]); buf.length += n; } } } buffer_write_string :: proc(buf: ^Buffer, s: string) { buffer_write(buf, cast([]byte)s); } buffer_write_byte :: proc(buf: ^Buffer, b: byte) { if buf.length < buf.data.count { buf.data[buf.length] = b; buf.length += 1; } } buffer_write_rune :: proc(buf: ^Buffer, r: rune) { if r < utf8.RUNE_SELF { buffer_write_byte(buf, cast(byte)r); return; } b, n := utf8.encode_rune(r); buffer_write(buf, b[:n]); } Fmt_Info :: struct { minus: bool, plus: bool, space: bool, zero: bool, hash: bool, width_set: bool, prec_set: bool, width: int, prec: int, reordered: bool, good_arg_index: bool, buf: ^Buffer, arg: any, // Temporary } fprint :: proc(fd: os.Handle, args: ...any) -> int { data: [_BUFFER_SIZE]byte; buf := Buffer{data[:], 0}; bprint(^buf, ...args); os.write(fd, buf.data[:buf.length]); return buf.length; } fprintln :: proc(fd: os.Handle, args: ...any) -> int { data: [_BUFFER_SIZE]byte; buf := Buffer{data[:], 0}; bprintln(^buf, ...args); os.write(fd, buf.data[:buf.length]); return buf.length; } fprintf :: proc(fd: os.Handle, fmt: string, args: ...any) -> int { data: [_BUFFER_SIZE]byte; buf := Buffer{data[:], 0}; bprintf(^buf, fmt, ...args); os.write(fd, buf.data[:buf.length]); return buf.length; } print :: proc(args: ...any) -> int { return fprint(os.stdout, ...args); } println :: proc(args: ...any) -> int { return fprintln(os.stdout, ...args); } printf :: proc(fmt: string, args: ...any) -> int { return fprintf(os.stdout, fmt, ...args); } fprint_type :: proc(fd: os.Handle, info: ^Type_Info) { data: [_BUFFER_SIZE]byte; buf := Buffer{data[:], 0}; buffer_write_type(^buf, info); os.write(fd, buf.data[:buf.length]); } buffer_write_type :: proc(buf: ^Buffer, ti: ^Type_Info) { if ti == nil { return; } using Type_Info; match info in ti { case Named: buffer_write_string(buf, info.name); case Integer: match { case ti == type_info(int): buffer_write_string(buf, "int"); case ti == type_info(uint): buffer_write_string(buf, "uint"); default: buffer_write_string(buf, info.signed ? "i" : "u"); fi := Fmt_Info{buf = buf}; fmt_int(^fi, cast(u64)(8*info.size), false, 'd'); } case Float: match info.size { case 4: buffer_write_string(buf, "f32"); case 8: buffer_write_string(buf, "f64"); } case String: buffer_write_string(buf, "string"); case Boolean: buffer_write_string(buf, "bool"); case Pointer: if info.elem == nil { buffer_write_string(buf, "rawptr"); } else { buffer_write_string(buf, "^"); buffer_write_type(buf, info.elem); } case Procedure: buffer_write_string(buf, "proc"); if info.params == nil { buffer_write_string(buf, "()"); } else { t := union_cast(^Tuple)info.params; buffer_write_string(buf, "("); for type, i in t.types { if i > 0 { buffer_write_string(buf, ", "); } buffer_write_type(buf, type); } buffer_write_string(buf, ")"); } if info.results != nil { buffer_write_string(buf, " -> "); buffer_write_type(buf, info.results); } case Tuple: count := info.names.count; if count != 1 { buffer_write_string(buf, "("); } for name, i in info.names { if i > 0 { buffer_write_string(buf, ", "); } type := info.types[i]; if name.count > 0 { buffer_write_string(buf, name); buffer_write_string(buf, ": "); } buffer_write_type(buf, type); } if count != 1 { buffer_write_string(buf, ")"); } case Array: buffer_write_string(buf, "["); fi := Fmt_Info{buf = buf}; fmt_int(^fi, cast(u64)info.count, false, 'd'); buffer_write_string(buf, "]"); buffer_write_type(buf, info.elem); case Dynamic_Array: buffer_write_string(buf, "[...]"); buffer_write_type(buf, info.elem); case Slice: buffer_write_string(buf, "["); buffer_write_string(buf, "]"); buffer_write_type(buf, info.elem); case Vector: buffer_write_string(buf, "[vector "); fi := Fmt_Info{buf = buf}; fmt_int(^fi, cast(u64)info.count, false, 'd'); buffer_write_string(buf, "]"); buffer_write_type(buf, info.elem); case Map: buffer_write_string(buf, "map["); buffer_write_type(buf, info.key); buffer_write_byte(buf, ']'); buffer_write_type(buf, info.value); case Struct: buffer_write_string(buf, "struct "); if info.packed { buffer_write_string(buf, "#packed "); } if info.ordered { buffer_write_string(buf, "#ordered "); } if info.custom_align { buffer_write_string(buf, "#align "); fi := Fmt_Info{buf = buf}; fmt_int(^fi, cast(u64)info.align, false, 'd'); buffer_write_byte(buf, ' '); } buffer_write_byte(buf, '{'); for name, i in info.names { if i > 0 { buffer_write_string(buf, ", "); } buffer_write_string(buf, name); buffer_write_string(buf, ": "); buffer_write_type(buf, info.types[i]); } buffer_write_byte(buf, '}'); case Union: buffer_write_string(buf, "union {"); cf := info.common_fields; total_count := 0; for name, i in cf.names { if i > 0 { buffer_write_string(buf, ", "); } buffer_write_string(buf, name); buffer_write_string(buf, ": "); buffer_write_type(buf, cf.types[i]); total_count += 1; } for name, i in info.variant_names { if total_count > 0 || i > 0 { buffer_write_string(buf, ", "); } buffer_write_string(buf, name); buffer_write_byte(buf, '{'); defer buffer_write_byte(buf, '}'); variant_type := type_info_base(info.variant_types[i]); variant := union_cast(^Struct)variant_type; vc := variant.names.count-cf.names.count; for j in 0.. 0 { buffer_write_string(buf, ", "); } index := j + cf.names.count; buffer_write_string(buf, variant.names[index]); buffer_write_string(buf, ": "); buffer_write_type(buf, variant.types[index]); } } buffer_write_string(buf, "}"); case Raw_Union: buffer_write_string(buf, "raw_union {"); for name, i in info.names { if i > 0 { buffer_write_string(buf, ", "); } buffer_write_string(buf, name); buffer_write_string(buf, ": "); buffer_write_type(buf, info.types[i]); } buffer_write_string(buf, "}"); case Enum: buffer_write_string(buf, "enum "); buffer_write_type(buf, info.base); buffer_write_string(buf, " {"); buffer_write_string(buf, "}"); } } bprint :: proc(buf: ^Buffer, args: ...any) -> int { fi: Fmt_Info; fi.buf = buf; prev_string := false; for arg, i in args { is_string := arg.data != nil && types.is_string(arg.type_info); if i > 0 && !is_string && !prev_string { buffer_write_byte(buf, ' '); } fmt_value(^fi, args[i], 'v'); prev_string = is_string; } return buf.length; } bprintln :: proc(buf: ^Buffer, args: ...any) -> int { fi: Fmt_Info; fi.buf = buf; for arg, i in args { if i > 0 { buffer_write_byte(buf, ' '); } fmt_value(^fi, args[i], 'v'); } buffer_write_byte(buf, '\n'); return buf.length; } sprint :: proc(buf: []byte, args: ...any) -> string { b: Buffer; b.data = buf; count := bprint(^b, ...args); return cast(string)b.data[:b.length]; } sprintln :: proc(buf: []byte, args: ...any) -> string { b: Buffer; b.data = buf; count := bprintln(^b, ...args); return cast(string)b.data[:b.length]; } sprintf :: proc(buf: []byte, fmt: string, args: ...any) -> string { b: Buffer; b.data = buf; count := bprintf(^b, fmt, ...args); return cast(string)b.data[:b.length]; } parse_int :: proc(s: string, offset: int) -> (result: int, offset: int, ok: bool) { is_digit :: proc(r: rune) -> bool #inline { return '0' <= r && r <= '9'; } result := 0; ok := true; i := 0; for o in offset.. (index: int, offset: int, ok: bool) { parse_arg_number :: proc(format: string) -> (int, int, bool) { if format.count < 3 { return 0, 1, false; } for i in 1.. (int, int, bool) { num := 0; new_arg_index := arg_index; ok := true; if arg_index < args.count { arg := args[arg_index]; arg.type_info = type_info_base(arg.type_info); match i in arg { case int: num = i; case i8: num = cast(int)i; case i16: num = cast(int)i; case i32: num = cast(int)i; case i64: num = cast(int)i; case u8: num = cast(int)i; case u16: num = cast(int)i; case u32: num = cast(int)i; case u64: num = cast(int)i; default: ok = false; } } return num, new_arg_index, ok; } fmt_bad_verb :: proc(using fi: ^Fmt_Info, verb: rune) { assert(verb != 'v'); buffer_write_string(buf, "%!"); buffer_write_rune(buf, verb); buffer_write_byte(buf, '('); if arg.type_info != nil { buffer_write_type(buf, arg.type_info); buffer_write_byte(buf, '='); fmt_value(fi, arg, 'v'); } else { buffer_write_string(buf, ""); } buffer_write_byte(buf, ')'); } fmt_bool :: proc(using fi: ^Fmt_Info, b: bool, verb: rune) { match verb { case 't', 'v': buffer_write_string(buf, b ? "true" : "false"); default: fmt_bad_verb(fi, verb); } } fmt_write_padding :: proc(fi: ^Fmt_Info, width: int) { if width <= 0 { return; } pad_byte: byte = ' '; if fi.zero { pad_byte = '0'; } count := min(width, fi.buf.data.count-fi.buf.length); start := fi.buf.length; for i in start.. buf.count { // TODO(bill):???? panic("fmt_integer buffer overrun. Width and precision too big"); } } prec := 0; if fi.prec_set { prec = fi.prec; if prec == 0 && u == 0 { old_zero := fi.zero; fi.zero = false; fmt_write_padding(fi, fi.width); fi.zero = old_zero; return; } } else if fi.zero && fi.width_set { prec = fi.width; if negative || fi.plus || fi.space { // There needs to be space for the "sign" prec -= 1; } } i := buf.count; match base { case 2, 8, 10, 16: break; default: panic("fmt_integer: unknown base, whoops"); } for b := cast(u64)base; u >= b; { i -= 1; next := u / b; buf[i] = digits[u%b]; u = next; } i -= 1; buf[i] = digits[u]; for i > 0 && prec > buf.count-i { i -= 1; buf[i] = '0'; } if fi.hash { i -= 1; match base { case 2: buf[i] = 'b'; case 8: buf[i] = 'o'; case 10: buf[i] = 'd'; case 16: buf[i] = digits[16]; } i -= 1; buf[i] = '0'; } if negative { i -= 1; buf[i] = '-'; } else if fi.plus { i -= 1; buf[i] = '+'; } else if fi.space { i -= 1; buf[i] = ' '; } old_zero := fi.zero; defer fi.zero = old_zero; fi.zero = false; if !fi.width_set || fi.width == 0 { buffer_write(fi.buf, buf[i:]); } else { width := fi.width - utf8.rune_count(cast(string)buf[i:]); if width > 0 { if fi.minus { // Right pad buffer_write(fi.buf, buf[i:]); fmt_write_padding(fi, width); } else { // Left pad fmt_write_padding(fi, width); buffer_write(fi.buf, buf[i:]); } } } } __DIGITS_LOWER := "0123456789abcdefx"; __DIGITS_UPPER := "0123456789ABCDEFX"; fmt_rune :: proc(fi: ^Fmt_Info, r: rune) { buffer_write_rune(fi.buf, r); } fmt_int :: proc(fi: ^Fmt_Info, u: u64, signed: bool, verb: rune) { match verb { case 'v': fmt_integer(fi, u, 10, signed, __DIGITS_LOWER); case 'b': fmt_integer(fi, u, 2, signed, __DIGITS_LOWER); case 'o': fmt_integer(fi, u, 8, signed, __DIGITS_LOWER); case 'd': fmt_integer(fi, u, 10, signed, __DIGITS_LOWER); case 'x': fmt_integer(fi, u, 16, signed, __DIGITS_LOWER); case 'X': fmt_integer(fi, u, 16, signed, __DIGITS_UPPER); case 'c', 'r': fmt_rune(fi, cast(rune)u); case 'U': r := cast(rune)u; if r < 0 || r > utf8.MAX_RUNE { fmt_bad_verb(fi, verb); } else { buffer_write_string(fi.buf, "U+"); fmt_integer(fi, u, 16, false, __DIGITS_UPPER); } default: fmt_bad_verb(fi, verb); } } fmt_float :: proc(fi: ^Fmt_Info, v: f64, bit_size: int, verb: rune) { match verb { // case 'e', 'E', 'f', 'F', 'g', 'G', 'v': // case 'f', 'F', 'v': // TODO(bill): This is a shit copy from gb.h and I really need a decent implementation case 'f', 'F', 'v': width := 0; if fi.width_set { width = max(fi.width, 0); } prec := 3; if fi.prec_set { prec = max(fi.prec, 0); } if v == 0 { buffer_write_byte(fi.buf, '0'); if fi.hash && width > 0 { buffer_write_byte(fi.buf, '.'); } } else { signed := v < 0; v = abs(v); if signed { buffer_write_byte(fi.buf, '-'); } val := cast(u64)v; fi.minus = false; fi.width = 0; fi.prec = 0; // TODO(bill): Write integer to buffer than use this crap fmt_integer(fi, val, 10, false, __DIGITS_LOWER); if fi.hash || prec > 0 { arg := v - cast(f64)val; mult: f64 = 10; buffer_write_byte(fi.buf, '.'); for _ in 0.. 0 { fill: byte = ' '; match { case fi.zero: fill = '0'; case fi.space: fill = ' '; } for width > 0 { width -= 1; buffer_write_byte(fi.buf, fill); } } default: fmt_bad_verb(fi, verb); return; } } fmt_string :: proc(fi: ^Fmt_Info, s: string, verb: rune) { match verb { case 's', 'v': buffer_write_string(fi.buf, s); default: fmt_bad_verb(fi, verb); } } fmt_pointer :: proc(fi: ^Fmt_Info, p: rawptr, verb: rune) { match verb { case 'p', 'v': // Okay default: fmt_bad_verb(fi, verb); return; } u := cast(u64)cast(uint)p; if !fi.hash || verb == 'v' { buffer_write_string(fi.buf, "0x"); } fmt_integer(fi, u, 16, false, __DIGITS_UPPER); } fmt_enum :: proc(fi: ^Fmt_Info, v: any, verb: rune) { if v.type_info == nil || v.data == nil { buffer_write_string(fi.buf, ""); return; } using Type_Info; match e in v.type_info { default: fmt_bad_verb(fi, verb); return; case Enum: match verb { case 'd', 'f': fmt_arg(fi, any{type_info_base(e.base), v.data}, verb); case 's', 'v': i: i64; f: f64; ok := false; a := any{type_info_base(e.base), v.data}; match v in a { case i8: i = cast(i64)v; case i16: i = cast(i64)v; case i32: i = cast(i64)v; case i64: i = cast(i64)v; case int: i = cast(i64)v; case u8: i = cast(i64)v; case u16: i = cast(i64)v; case u32: i = cast(i64)v; case u64: i = cast(i64)v; case uint: i = cast(i64)v; case f32: f = cast(f64)v; case f64: f = cast(f64)v; } if types.is_string(e.base) { for it, idx in e.values { if it.i == i { buffer_write_string(fi.buf, e.names[idx]); ok = true; break; } } } else if e.values.count == 0 { buffer_write_string(fi.buf, ""); ok = true; } else { for it, idx in e.values { if it.f == f { buffer_write_string(fi.buf, e.names[idx]); ok = true; break; } } } if !ok { buffer_write_string(fi.buf, "!%(BAD ENUM VALUE)"); } default: fmt_bad_verb(fi, verb); return; } } } fmt_value :: proc(fi: ^Fmt_Info, v: any, verb: rune) { if v.data == nil || v.type_info == nil { buffer_write_string(fi.buf, ""); return; } using Type_Info; match info in v.type_info { case Named: match b in info.base { case Struct: if verb != 'v' { fmt_bad_verb(fi, verb); return; } buffer_write_string(fi.buf, info.name); buffer_write_byte(fi.buf, '{'); for _, i in b.names { if i > 0 { buffer_write_string(fi.buf, ", "); } buffer_write_string(fi.buf, b.names[i]); buffer_write_string(fi.buf, " = "); data := cast(^byte)v.data + b.offsets[i]; fmt_arg(fi, any{b.types[i], cast(rawptr)data}, 'v'); } buffer_write_byte(fi.buf, '}'); default: fmt_value(fi, any{info.base, v.data}, verb); } case Boolean: fmt_arg(fi, v, verb); case Float: fmt_arg(fi, v, verb); case Integer: fmt_arg(fi, v, verb); case String: fmt_arg(fi, v, verb); case Pointer: if v.type_info == type_info(^Type_Info) { buffer_write_type(fi.buf, (cast(^^Type_Info)v.data)^); } else { fmt_pointer(fi, (cast(^rawptr)v.data)^, verb); } case Array: if verb != 'v' { fmt_bad_verb(fi, verb); return; } buffer_write_byte(fi.buf, '['); defer buffer_write_byte(fi.buf, ']'); for i in 0.. 0 { buffer_write_string(fi.buf, ", "); } data := cast(^byte)v.data + i*info.elem_size; fmt_arg(fi, any{info.elem, cast(rawptr)data}, 'v'); } case Dynamic_Array: if verb != 'v' { fmt_bad_verb(fi, verb); return; } buffer_write_byte(fi.buf, '['); defer buffer_write_byte(fi.buf, ']'); array := cast(^Raw_Dynamic_Array)v.data; for i in 0.. 0 { buffer_write_string(fi.buf, ", "); } data := cast(^byte)array.data + i*info.elem_size; fmt_arg(fi, any{info.elem, cast(rawptr)data}, 'v'); } case Map: if verb != 'v' { fmt_bad_verb(fi, verb); return; } buffer_write_string(fi.buf, "map["); defer buffer_write_byte(fi.buf, ']'); entries := ^(cast(^Raw_Dynamic_Map)v.data).entries; gs := union_cast(^Struct)type_info_base(info.generated_struct); ed := union_cast(^Dynamic_Array)type_info_base(gs.types[1]); entry_type := union_cast(^Struct)ed.elem; entry_size := ed.elem_size; for i in 0.. 0 { buffer_write_string(fi.buf, ", "); } data := cast(^byte)entries.data + i*entry_size; header := cast(^__Map_Entry_Header)data; if types.is_string(info.key) { buffer_write_string(fi.buf, header.key.str); } else { fi := Fmt_Info{buf = fi.buf}; fmt_arg(^fi, any{info.key, cast(rawptr)^header.key.hash}, 'v'); } buffer_write_string(fi.buf, "="); value := data + entry_type.offsets[2]; fmt_arg(fi, any{info.value, cast(rawptr)value}, 'v'); } case Slice: if verb != 'v' { fmt_bad_verb(fi, verb); return; } buffer_write_byte(fi.buf, '['); defer buffer_write_byte(fi.buf, ']'); slice := cast(^[]byte)v.data; for i in 0.. 0 { buffer_write_string(fi.buf, ", "); } data := slice.data + i*info.elem_size; fmt_arg(fi, any{info.elem, cast(rawptr)data}, 'v'); } case Vector: buffer_write_byte(fi.buf, '<'); defer buffer_write_byte(fi.buf, '>'); for i in 0.. 0 { buffer_write_string(fi.buf, ", "); } data := cast(^byte)v.data + i*info.elem_size; fmt_value(fi, any{info.elem, cast(rawptr)data}, 'v'); } case Struct: buffer_write_byte(fi.buf, '{'); defer buffer_write_byte(fi.buf, '}'); for _, i in info.names { if i > 0 { buffer_write_string(fi.buf, ", "); } buffer_write_string(fi.buf, info.names[i]); buffer_write_string(fi.buf, " = "); data := cast(^byte)v.data + info.offsets[i]; fmt_value(fi, any{info.types[i], cast(rawptr)data}, 'v'); } case Union: buffer_write_byte(fi.buf, '{'); defer buffer_write_byte(fi.buf, '}'); cf := info.common_fields; for _, i in cf.names { if i > 0 { buffer_write_string(fi.buf, ", "); } buffer_write_string(fi.buf, cf.names[i]); buffer_write_string(fi.buf, " = "); data := cast(^byte)v.data + cf.offsets[i]; fmt_value(fi, any{cf.types[i], cast(rawptr)data}, 'v'); } case Raw_Union: buffer_write_string(fi.buf, "(raw_union)"); case Enum: fmt_enum(fi, v, verb); case Procedure: buffer_write_type(fi.buf, v.type_info); buffer_write_string(fi.buf, " @ "); fmt_pointer(fi, (cast(^rawptr)v.data)^, 'p'); } } fmt_arg :: proc(fi: ^Fmt_Info, arg: any, verb: rune) { if arg.data == nil || arg.type_info == nil { buffer_write_string(fi.buf, ""); return; } fi.arg = arg; if verb == 'T' { ti := arg.type_info; match a in arg { case ^Type_Info: ti = a; } buffer_write_type(fi.buf, ti); return; } base_arg := arg; base_arg.type_info = type_info_base(base_arg.type_info); match a in base_arg { case bool: fmt_bool(fi, a, verb); case f32: fmt_float(fi, cast(f64)a, 32, verb); case f64: fmt_float(fi, a, 64, verb); case int: fmt_int(fi, cast(u64)a, true, verb); case i8: fmt_int(fi, cast(u64)a, true, verb); case i16: fmt_int(fi, cast(u64)a, true, verb); case i32: fmt_int(fi, cast(u64)a, true, verb); case i64: fmt_int(fi, cast(u64)a, true, verb); case uint: fmt_int(fi, cast(u64)a, false, verb); case u8: fmt_int(fi, cast(u64)a, false, verb); case u16: fmt_int(fi, cast(u64)a, false, verb); case u32: fmt_int(fi, cast(u64)a, false, verb); case u64: fmt_int(fi, cast(u64)a, false, verb); case string: fmt_string(fi, a, verb); default: fmt_value(fi, arg, verb); } } bprintf :: proc(b: ^Buffer, fmt: string, args: ...any) -> int { fi := Fmt_Info{}; end := fmt.count; arg_index := 0; was_prev_index := false; for i := 0; i < end; { fi = Fmt_Info{buf = b, good_arg_index = true}; prev_i := i; for i < end && fmt[i] != '%' { i += 1; } if i > prev_i { buffer_write_string(b, fmt[prev_i:i]); } if i >= end { break; } // Process a "verb" i += 1; for ; i < end; i += 1 { skip_loop := false; c := fmt[i]; match c { case '+': fi.plus = true; case '-': fi.minus = true; fi.zero = false; case ' ': fi.space = true; case '#': fi.hash = true; case '0': fi.zero = !fi.minus; default: skip_loop = true; } if skip_loop { break; } } arg_index, i, was_prev_index = _arg_number(^fi, arg_index, fmt, i, args.count); // Width if i < end && fmt[i] == '*' { i += 1; fi.width, arg_index, fi.width_set = int_from_arg(args, arg_index); if !fi.width_set { buffer_write_string(b, "%!(BAD WIDTH)"); } if fi.width < 0 { fi.width = -fi.width; fi.minus = true; fi.zero = false; } was_prev_index = false; } else { fi.width, i, fi.width_set = parse_int(fmt, i); if was_prev_index && fi.width_set { // %[6]2d fi.good_arg_index = false; } } // Precision if i < end && fmt[i] == '.' { i += 1; if was_prev_index { // %[6].2d fi.good_arg_index = false; } if i < end && fmt[i] == '*' { arg_index, i, was_prev_index = _arg_number(^fi, arg_index, fmt, i, args.count); i += 1; fi.prec, arg_index, fi.prec_set = int_from_arg(args, arg_index); if fi.prec < 0 { fi.prec = 0; fi.prec_set = false; } if !fi.prec_set { buffer_write_string(fi.buf, "%!(BAD PRECISION)"); } was_prev_index = false; } else { fi.prec, i, fi.prec_set = parse_int(fmt, i); if !fi.prec_set { fi.prec_set = true; fi.prec = 0; } } } if !was_prev_index { arg_index, i, was_prev_index = _arg_number(^fi, arg_index, fmt, i, args.count); } if i >= end { buffer_write_string(b, "%!(NO VERB)"); break; } verb, w := utf8.decode_rune(fmt[i:]); i += w; if verb == '%' { buffer_write_byte(b, '%'); } else if !fi.good_arg_index { buffer_write_string(b, "%!(BAD ARGUMENT NUMBER)"); } else if arg_index >= args.count { buffer_write_string(b, "%!(MISSING ARGUMENT)"); } else { fmt_arg(^fi, args[arg_index], verb); arg_index += 1; } } if !fi.reordered && arg_index < args.count { buffer_write_string(b, "%!(EXTRA "); for arg, index in args[arg_index:] { if index > 0 { buffer_write_string(b, ", "); } if arg.data == nil || arg.type_info == nil { buffer_write_string(b, ""); } else { fmt_arg(^fi, args[index], 'v'); } } buffer_write_string(b, ")"); } return b.length; }