// Copyright 2012 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // Rust JSON serialization library // Copyright (c) 2011 Google Inc. #[forbid(non_camel_case_types)]; #[allow(missing_doc)]; //! json serialization use core::prelude::*; use core::char; use core::float; use core::hashmap::HashMap; use core::io::{WriterUtil, ReaderUtil}; use core::io; use core::str; use core::to_str; use core::vec; use serialize::Encodable; use serialize; use sort::Sort; /// Represents a json value pub enum Json { Number(float), String(~str), Boolean(bool), List(List), Object(~Object), Null, } pub type List = ~[Json]; pub type Object = HashMap<~str, Json>; #[deriving(Eq)] /// If an error occurs while parsing some JSON, this is the structure which is /// returned pub struct Error { /// The line number at which the error occurred line: uint, /// The column number at which the error occurred col: uint, /// A message describing the type of the error msg: @~str, } fn escape_str(s: &str) -> ~str { let mut escaped = ~"\""; for s.iter().advance |c| { match c { '"' => escaped += "\\\"", '\\' => escaped += "\\\\", '\x08' => escaped += "\\b", '\x0c' => escaped += "\\f", '\n' => escaped += "\\n", '\r' => escaped += "\\r", '\t' => escaped += "\\t", _ => escaped += str::from_char(c) } }; escaped += "\""; escaped } fn spaces(n: uint) -> ~str { let mut ss = ~""; for n.times { ss.push_str(" "); } return ss; } /// A structure for implementing serialization to JSON. pub struct Encoder { priv wr: @io::Writer, } /// Creates a new JSON encoder whose output will be written to the writer /// specified. pub fn Encoder(wr: @io::Writer) -> Encoder { Encoder { wr: wr } } impl serialize::Encoder for Encoder { fn emit_nil(&mut self) { self.wr.write_str("null") } fn emit_uint(&mut self, v: uint) { self.emit_float(v as float); } fn emit_u64(&mut self, v: u64) { self.emit_float(v as float); } fn emit_u32(&mut self, v: u32) { self.emit_float(v as float); } fn emit_u16(&mut self, v: u16) { self.emit_float(v as float); } fn emit_u8(&mut self, v: u8) { self.emit_float(v as float); } fn emit_int(&mut self, v: int) { self.emit_float(v as float); } fn emit_i64(&mut self, v: i64) { self.emit_float(v as float); } fn emit_i32(&mut self, v: i32) { self.emit_float(v as float); } fn emit_i16(&mut self, v: i16) { self.emit_float(v as float); } fn emit_i8(&mut self, v: i8) { self.emit_float(v as float); } fn emit_bool(&mut self, v: bool) { if v { self.wr.write_str("true"); } else { self.wr.write_str("false"); } } fn emit_f64(&mut self, v: f64) { self.emit_float(v as float); } fn emit_f32(&mut self, v: f32) { self.emit_float(v as float); } fn emit_float(&mut self, v: float) { self.wr.write_str(float::to_str_digits(v, 6u)); } fn emit_char(&mut self, v: char) { self.emit_str(str::from_char(v)) } fn emit_str(&mut self, v: &str) { self.wr.write_str(escape_str(v)) } fn emit_enum(&mut self, _name: &str, f: &fn(&mut Encoder)) { f(self) } fn emit_enum_variant(&mut self, name: &str, _id: uint, cnt: uint, f: &fn(&mut Encoder)) { // enums are encoded as strings or vectors: // Bunny => "Bunny" // Kangaroo(34,"William") => ["Kangaroo",[34,"William"]] if cnt == 0 { self.wr.write_str(escape_str(name)); } else { self.wr.write_char('['); self.wr.write_str(escape_str(name)); self.wr.write_char(','); f(self); self.wr.write_char(']'); } } fn emit_enum_variant_arg(&mut self, idx: uint, f: &fn(&mut Encoder)) { if idx != 0 { self.wr.write_char(','); } f(self); } fn emit_enum_struct_variant(&mut self, name: &str, id: uint, cnt: uint, f: &fn(&mut Encoder)) { self.emit_enum_variant(name, id, cnt, f) } fn emit_enum_struct_variant_field(&mut self, _: &str, idx: uint, f: &fn(&mut Encoder)) { self.emit_enum_variant_arg(idx, f) } fn emit_struct(&mut self, _: &str, _: uint, f: &fn(&mut Encoder)) { self.wr.write_char('{'); f(self); self.wr.write_char('}'); } fn emit_struct_field(&mut self, name: &str, idx: uint, f: &fn(&mut Encoder)) { if idx != 0 { self.wr.write_char(','); } self.wr.write_str(escape_str(name)); self.wr.write_char(':'); f(self); } fn emit_tuple(&mut self, len: uint, f: &fn(&mut Encoder)) { self.emit_seq(len, f) } fn emit_tuple_arg(&mut self, idx: uint, f: &fn(&mut Encoder)) { self.emit_seq_elt(idx, f) } fn emit_tuple_struct(&mut self, _name: &str, len: uint, f: &fn(&mut Encoder)) { self.emit_seq(len, f) } fn emit_tuple_struct_arg(&mut self, idx: uint, f: &fn(&mut Encoder)) { self.emit_seq_elt(idx, f) } fn emit_option(&mut self, f: &fn(&mut Encoder)) { f(self); } fn emit_option_none(&mut self) { self.emit_nil(); } fn emit_option_some(&mut self, f: &fn(&mut Encoder)) { f(self); } fn emit_seq(&mut self, _len: uint, f: &fn(&mut Encoder)) { self.wr.write_char('['); f(self); self.wr.write_char(']'); } fn emit_seq_elt(&mut self, idx: uint, f: &fn(&mut Encoder)) { if idx != 0 { self.wr.write_char(','); } f(self) } fn emit_map(&mut self, _len: uint, f: &fn(&mut Encoder)) { self.wr.write_char('{'); f(self); self.wr.write_char('}'); } fn emit_map_elt_key(&mut self, idx: uint, f: &fn(&mut Encoder)) { if idx != 0 { self.wr.write_char(','); } f(self) } fn emit_map_elt_val(&mut self, _idx: uint, f: &fn(&mut Encoder)) { self.wr.write_char(':'); f(self) } } /// Another encoder for JSON, but prints out human-readable JSON instead of /// compact data pub struct PrettyEncoder { priv wr: @io::Writer, priv indent: uint, } /// Creates a new encoder whose output will be written to the specified writer pub fn PrettyEncoder(wr: @io::Writer) -> PrettyEncoder { PrettyEncoder { wr: wr, indent: 0, } } impl serialize::Encoder for PrettyEncoder { fn emit_nil(&mut self) { self.wr.write_str("null") } fn emit_uint(&mut self, v: uint) { self.emit_float(v as float); } fn emit_u64(&mut self, v: u64) { self.emit_float(v as float); } fn emit_u32(&mut self, v: u32) { self.emit_float(v as float); } fn emit_u16(&mut self, v: u16) { self.emit_float(v as float); } fn emit_u8(&mut self, v: u8) { self.emit_float(v as float); } fn emit_int(&mut self, v: int) { self.emit_float(v as float); } fn emit_i64(&mut self, v: i64) { self.emit_float(v as float); } fn emit_i32(&mut self, v: i32) { self.emit_float(v as float); } fn emit_i16(&mut self, v: i16) { self.emit_float(v as float); } fn emit_i8(&mut self, v: i8) { self.emit_float(v as float); } fn emit_bool(&mut self, v: bool) { if v { self.wr.write_str("true"); } else { self.wr.write_str("false"); } } fn emit_f64(&mut self, v: f64) { self.emit_float(v as float); } fn emit_f32(&mut self, v: f32) { self.emit_float(v as float); } fn emit_float(&mut self, v: float) { self.wr.write_str(float::to_str_digits(v, 6u)); } fn emit_char(&mut self, v: char) { self.emit_str(str::from_char(v)) } fn emit_str(&mut self, v: &str) { self.wr.write_str(escape_str(v)); } fn emit_enum(&mut self, _name: &str, f: &fn(&mut PrettyEncoder)) { f(self) } fn emit_enum_variant(&mut self, name: &str, _: uint, cnt: uint, f: &fn(&mut PrettyEncoder)) { if cnt == 0 { self.wr.write_str(escape_str(name)); } else { self.wr.write_char('['); self.indent += 2; self.wr.write_char('\n'); self.wr.write_str(spaces(self.indent)); self.wr.write_str(escape_str(name)); self.wr.write_str(",\n"); f(self); self.wr.write_char('\n'); self.indent -= 2; self.wr.write_str(spaces(self.indent)); self.wr.write_char(']'); } } fn emit_enum_variant_arg(&mut self, idx: uint, f: &fn(&mut PrettyEncoder)) { if idx != 0 { self.wr.write_str(",\n"); } self.wr.write_str(spaces(self.indent)); f(self) } fn emit_enum_struct_variant(&mut self, name: &str, id: uint, cnt: uint, f: &fn(&mut PrettyEncoder)) { self.emit_enum_variant(name, id, cnt, f) } fn emit_enum_struct_variant_field(&mut self, _: &str, idx: uint, f: &fn(&mut PrettyEncoder)) { self.emit_enum_variant_arg(idx, f) } fn emit_struct(&mut self, _: &str, len: uint, f: &fn(&mut PrettyEncoder)) { if len == 0 { self.wr.write_str("{}"); } else { self.wr.write_char('{'); self.indent += 2; f(self); self.wr.write_char('\n'); self.indent -= 2; self.wr.write_str(spaces(self.indent)); self.wr.write_char('}'); } } fn emit_struct_field(&mut self, name: &str, idx: uint, f: &fn(&mut PrettyEncoder)) { if idx == 0 { self.wr.write_char('\n'); } else { self.wr.write_str(",\n"); } self.wr.write_str(spaces(self.indent)); self.wr.write_str(escape_str(name)); self.wr.write_str(": "); f(self); } fn emit_tuple(&mut self, len: uint, f: &fn(&mut PrettyEncoder)) { self.emit_seq(len, f) } fn emit_tuple_arg(&mut self, idx: uint, f: &fn(&mut PrettyEncoder)) { self.emit_seq_elt(idx, f) } fn emit_tuple_struct(&mut self, _: &str, len: uint, f: &fn(&mut PrettyEncoder)) { self.emit_seq(len, f) } fn emit_tuple_struct_arg(&mut self, idx: uint, f: &fn(&mut PrettyEncoder)) { self.emit_seq_elt(idx, f) } fn emit_option(&mut self, f: &fn(&mut PrettyEncoder)) { f(self); } fn emit_option_none(&mut self) { self.emit_nil(); } fn emit_option_some(&mut self, f: &fn(&mut PrettyEncoder)) { f(self); } fn emit_seq(&mut self, len: uint, f: &fn(&mut PrettyEncoder)) { if len == 0 { self.wr.write_str("[]"); } else { self.wr.write_char('['); self.indent += 2; f(self); self.wr.write_char('\n'); self.indent -= 2; self.wr.write_str(spaces(self.indent)); self.wr.write_char(']'); } } fn emit_seq_elt(&mut self, idx: uint, f: &fn(&mut PrettyEncoder)) { if idx == 0 { self.wr.write_char('\n'); } else { self.wr.write_str(",\n"); } self.wr.write_str(spaces(self.indent)); f(self) } fn emit_map(&mut self, len: uint, f: &fn(&mut PrettyEncoder)) { if len == 0 { self.wr.write_str("{}"); } else { self.wr.write_char('{'); self.indent += 2; f(self); self.wr.write_char('\n'); self.indent -= 2; self.wr.write_str(spaces(self.indent)); self.wr.write_char('}'); } } fn emit_map_elt_key(&mut self, idx: uint, f: &fn(&mut PrettyEncoder)) { if idx == 0 { self.wr.write_char('\n'); } else { self.wr.write_str(",\n"); } self.wr.write_str(spaces(self.indent)); f(self); } fn emit_map_elt_val(&mut self, _idx: uint, f: &fn(&mut PrettyEncoder)) { self.wr.write_str(": "); f(self); } } impl serialize::Encodable for Json { fn encode(&self, e: &mut E) { match *self { Number(v) => v.encode(e), String(ref v) => v.encode(e), Boolean(v) => v.encode(e), List(ref v) => v.encode(e), Object(ref v) => v.encode(e), Null => e.emit_nil(), } } } /// Encodes a json value into a io::writer pub fn to_writer(wr: @io::Writer, json: &Json) { let mut encoder = Encoder(wr); json.encode(&mut encoder) } /// Encodes a json value into a string pub fn to_str(json: &Json) -> ~str { io::with_str_writer(|wr| to_writer(wr, json)) } /// Encodes a json value into a io::writer pub fn to_pretty_writer(wr: @io::Writer, json: &Json) { let mut encoder = PrettyEncoder(wr); json.encode(&mut encoder) } /// Encodes a json value into a string pub fn to_pretty_str(json: &Json) -> ~str { io::with_str_writer(|wr| to_pretty_writer(wr, json)) } #[allow(missing_doc)] pub struct Parser { priv rdr: @io::Reader, priv ch: char, priv line: uint, priv col: uint, } /// Decode a json value from an io::reader pub fn Parser(rdr: @io::Reader) -> Parser { Parser { rdr: rdr, ch: rdr.read_char(), line: 1, col: 1, } } impl Parser { pub fn parse(&mut self) -> Result { match self.parse_value() { Ok(value) => { // Skip trailing whitespaces. self.parse_whitespace(); // Make sure there is no trailing characters. if self.eof() { Ok(value) } else { self.error(~"trailing characters") } } Err(e) => Err(e) } } } impl Parser { fn eof(&self) -> bool { self.ch == -1 as char } fn bump(&mut self) { self.ch = self.rdr.read_char(); if self.ch == '\n' { self.line += 1u; self.col = 1u; } else { self.col += 1u; } } fn next_char(&mut self) -> char { self.bump(); self.ch } fn error(&self, msg: ~str) -> Result { Err(Error { line: self.line, col: self.col, msg: @msg }) } fn parse_value(&mut self) -> Result { self.parse_whitespace(); if self.eof() { return self.error(~"EOF while parsing value"); } match self.ch { 'n' => self.parse_ident("ull", Null), 't' => self.parse_ident("rue", Boolean(true)), 'f' => self.parse_ident("alse", Boolean(false)), '0' .. '9' | '-' => self.parse_number(), '"' => match self.parse_str() { Ok(s) => Ok(String(s)), Err(e) => Err(e), }, '[' => self.parse_list(), '{' => self.parse_object(), _ => self.error(~"invalid syntax") } } fn parse_whitespace(&mut self) { while char::is_whitespace(self.ch) { self.bump(); } } fn parse_ident(&mut self, ident: &str, value: Json) -> Result { if ident.iter().all(|c| c == self.next_char()) { self.bump(); Ok(value) } else { self.error(~"invalid syntax") } } fn parse_number(&mut self) -> Result { let mut neg = 1f; if self.ch == '-' { self.bump(); neg = -1f; } let mut res = match self.parse_integer() { Ok(res) => res, Err(e) => return Err(e) }; if self.ch == '.' { match self.parse_decimal(res) { Ok(r) => res = r, Err(e) => return Err(e) } } if self.ch == 'e' || self.ch == 'E' { match self.parse_exponent(res) { Ok(r) => res = r, Err(e) => return Err(e) } } Ok(Number(neg * res)) } fn parse_integer(&mut self) -> Result { let mut res = 0f; match self.ch { '0' => { self.bump(); // There can be only one leading '0'. match self.ch { '0' .. '9' => return self.error(~"invalid number"), _ => () } } '1' .. '9' => { while !self.eof() { match self.ch { '0' .. '9' => { res *= 10f; res += ((self.ch as int) - ('0' as int)) as float; self.bump(); } _ => break } } } _ => return self.error(~"invalid number") } Ok(res) } fn parse_decimal(&mut self, res: float) -> Result { self.bump(); // Make sure a digit follows the decimal place. match self.ch { '0' .. '9' => (), _ => return self.error(~"invalid number") } let mut res = res; let mut dec = 1f; while !self.eof() { match self.ch { '0' .. '9' => { dec /= 10f; res += (((self.ch as int) - ('0' as int)) as float) * dec; self.bump(); } _ => break } } Ok(res) } fn parse_exponent(&mut self, mut res: float) -> Result { self.bump(); let mut exp = 0u; let mut neg_exp = false; match self.ch { '+' => self.bump(), '-' => { self.bump(); neg_exp = true; } _ => () } // Make sure a digit follows the exponent place. match self.ch { '0' .. '9' => (), _ => return self.error(~"invalid number") } while !self.eof() { match self.ch { '0' .. '9' => { exp *= 10u; exp += (self.ch as uint) - ('0' as uint); self.bump(); } _ => break } } let exp = float::pow_with_uint(10u, exp); if neg_exp { res /= exp; } else { res *= exp; } Ok(res) } fn parse_str(&mut self) -> Result<~str, Error> { let mut escape = false; let mut res = ~""; while !self.eof() { self.bump(); if (escape) { match self.ch { '"' => res.push_char('"'), '\\' => res.push_char('\\'), '/' => res.push_char('/'), 'b' => res.push_char('\x08'), 'f' => res.push_char('\x0c'), 'n' => res.push_char('\n'), 'r' => res.push_char('\r'), 't' => res.push_char('\t'), 'u' => { // Parse \u1234. let mut i = 0u; let mut n = 0u; while i < 4u { match self.next_char() { '0' .. '9' => { n = n * 16u + (self.ch as uint) - ('0' as uint); }, 'a' | 'A' => n = n * 16u + 10u, 'b' | 'B' => n = n * 16u + 11u, 'c' | 'C' => n = n * 16u + 12u, 'd' | 'D' => n = n * 16u + 13u, 'e' | 'E' => n = n * 16u + 14u, 'f' | 'F' => n = n * 16u + 15u, _ => return self.error( ~"invalid \\u escape (unrecognized hex)") } i += 1u; } // Error out if we didn't parse 4 digits. if i != 4u { return self.error( ~"invalid \\u escape (not four digits)"); } res.push_char(n as char); } _ => return self.error(~"invalid escape") } escape = false; } else if self.ch == '\\' { escape = true; } else { if self.ch == '"' { self.bump(); return Ok(res); } res.push_char(self.ch); } } self.error(~"EOF while parsing string") } fn parse_list(&mut self) -> Result { self.bump(); self.parse_whitespace(); let mut values = ~[]; if self.ch == ']' { self.bump(); return Ok(List(values)); } loop { match self.parse_value() { Ok(v) => values.push(v), Err(e) => return Err(e) } self.parse_whitespace(); if self.eof() { return self.error(~"EOF while parsing list"); } match self.ch { ',' => self.bump(), ']' => { self.bump(); return Ok(List(values)); } _ => return self.error(~"expected `,` or `]`") } }; } fn parse_object(&mut self) -> Result { self.bump(); self.parse_whitespace(); let mut values = ~HashMap::new(); if self.ch == '}' { self.bump(); return Ok(Object(values)); } while !self.eof() { self.parse_whitespace(); if self.ch != '"' { return self.error(~"key must be a string"); } let key = match self.parse_str() { Ok(key) => key, Err(e) => return Err(e) }; self.parse_whitespace(); if self.ch != ':' { if self.eof() { break; } return self.error(~"expected `:`"); } self.bump(); match self.parse_value() { Ok(value) => { values.insert(key, value); } Err(e) => return Err(e) } self.parse_whitespace(); match self.ch { ',' => self.bump(), '}' => { self.bump(); return Ok(Object(values)); } _ => { if self.eof() { break; } return self.error(~"expected `,` or `}`"); } } } return self.error(~"EOF while parsing object"); } } /// Decodes a json value from an @io::Reader pub fn from_reader(rdr: @io::Reader) -> Result { let mut parser = Parser(rdr); parser.parse() } /// Decodes a json value from a string pub fn from_str(s: &str) -> Result { do io::with_str_reader(s) |rdr| { from_reader(rdr) } } /// A structure to decode JSON to values in rust. pub struct Decoder { priv stack: ~[Json], } /// Creates a new decoder instance for decoding the specified JSON value. pub fn Decoder(json: Json) -> Decoder { Decoder { stack: ~[json] } } impl serialize::Decoder for Decoder { fn read_nil(&mut self) -> () { debug!("read_nil"); match self.stack.pop() { Null => (), value => fail!("not a null: %?", value) } } fn read_u64(&mut self) -> u64 { self.read_float() as u64 } fn read_u32(&mut self) -> u32 { self.read_float() as u32 } fn read_u16(&mut self) -> u16 { self.read_float() as u16 } fn read_u8 (&mut self) -> u8 { self.read_float() as u8 } fn read_uint(&mut self) -> uint { self.read_float() as uint } fn read_i64(&mut self) -> i64 { self.read_float() as i64 } fn read_i32(&mut self) -> i32 { self.read_float() as i32 } fn read_i16(&mut self) -> i16 { self.read_float() as i16 } fn read_i8 (&mut self) -> i8 { self.read_float() as i8 } fn read_int(&mut self) -> int { self.read_float() as int } fn read_bool(&mut self) -> bool { debug!("read_bool"); match self.stack.pop() { Boolean(b) => b, value => fail!("not a boolean: %?", value) } } fn read_f64(&mut self) -> f64 { self.read_float() as f64 } fn read_f32(&mut self) -> f32 { self.read_float() as f32 } fn read_float(&mut self) -> float { debug!("read_float"); match self.stack.pop() { Number(f) => f, value => fail!("not a number: %?", value) } } fn read_char(&mut self) -> char { let mut v = ~[]; let s = self.read_str(); for s.iter().advance |c| { v.push(c) } if v.len() != 1 { fail!("string must have one character") } v[0] } fn read_str(&mut self) -> ~str { debug!("read_str"); match self.stack.pop() { String(s) => s, json => fail!("not a string: %?", json) } } fn read_enum(&mut self, name: &str, f: &fn(&mut Decoder) -> T) -> T { debug!("read_enum(%s)", name); f(self) } fn read_enum_variant(&mut self, names: &[&str], f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_enum_variant(names=%?)", names); let name = match self.stack.pop() { String(s) => s, List(list) => { do vec::consume_reverse(list) |_i, v| { self.stack.push(v); } match self.stack.pop() { String(s) => s, value => fail!("invalid variant name: %?", value), } } ref json => fail!("invalid variant: %?", *json), }; let idx = match vec::position(names, |n| str::eq_slice(*n, name)) { Some(idx) => idx, None => fail!("Unknown variant name: %?", name), }; f(self, idx) } fn read_enum_variant_arg(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_enum_variant_arg(idx=%u)", idx); f(self) } fn read_enum_struct_variant(&mut self, names: &[&str], f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_enum_struct_variant(names=%?)", names); self.read_enum_variant(names, f) } fn read_enum_struct_variant_field(&mut self, name: &str, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_enum_struct_variant_field(name=%?, idx=%u)", name, idx); self.read_enum_variant_arg(idx, f) } fn read_struct(&mut self, name: &str, len: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_struct(name=%s, len=%u)", name, len); let value = f(self); self.stack.pop(); value } fn read_struct_field(&mut self, name: &str, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_struct_field(name=%?, idx=%u)", name, idx); match self.stack.pop() { Object(obj) => { let mut obj = obj; let value = match obj.pop(&name.to_owned()) { None => fail!("no such field: %s", name), Some(json) => { self.stack.push(json); f(self) } }; self.stack.push(Object(obj)); value } value => fail!("not an object: %?", value) } } fn read_tuple(&mut self, f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_tuple()"); self.read_seq(f) } fn read_tuple_arg(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_tuple_arg(idx=%u)", idx); self.read_seq_elt(idx, f) } fn read_tuple_struct(&mut self, name: &str, f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_tuple_struct(name=%?)", name); self.read_tuple(f) } fn read_tuple_struct_arg(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_tuple_struct_arg(idx=%u)", idx); self.read_tuple_arg(idx, f) } fn read_option(&mut self, f: &fn(&mut Decoder, bool) -> T) -> T { match self.stack.pop() { Null => f(self, false), value => { self.stack.push(value); f(self, true) } } } fn read_seq(&mut self, f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_seq()"); let len = match self.stack.pop() { List(list) => { let len = list.len(); do vec::consume_reverse(list) |_i, v| { self.stack.push(v); } len } _ => fail!("not a list"), }; f(self, len) } fn read_seq_elt(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_seq_elt(idx=%u)", idx); f(self) } fn read_map(&mut self, f: &fn(&mut Decoder, uint) -> T) -> T { debug!("read_map()"); let len = match self.stack.pop() { Object(obj) => { let mut obj = obj; let len = obj.len(); do obj.consume |key, value| { self.stack.push(value); self.stack.push(String(key)); } len } json => fail!("not an object: %?", json), }; f(self, len) } fn read_map_elt_key(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_map_elt_key(idx=%u)", idx); f(self) } fn read_map_elt_val(&mut self, idx: uint, f: &fn(&mut Decoder) -> T) -> T { debug!("read_map_elt_val(idx=%u)", idx); f(self) } } impl Eq for Json { fn eq(&self, other: &Json) -> bool { match (self) { &Number(f0) => match other { &Number(f1) => f0 == f1, _ => false }, &String(ref s0) => match other { &String(ref s1) => s0 == s1, _ => false }, &Boolean(b0) => match other { &Boolean(b1) => b0 == b1, _ => false }, &Null => match other { &Null => true, _ => false }, &List(ref v0) => match other { &List(ref v1) => v0 == v1, _ => false }, &Object(ref d0) => { match other { &Object(ref d1) => { if d0.len() == d1.len() { let mut equal = true; for d0.each |k, v0| { match d1.find(k) { Some(v1) if v0 == v1 => { }, _ => { equal = false; break } } }; equal } else { false } } _ => false } } } } fn ne(&self, other: &Json) -> bool { !self.eq(other) } } /// Test if two json values are less than one another impl Ord for Json { fn lt(&self, other: &Json) -> bool { match (*self) { Number(f0) => { match *other { Number(f1) => f0 < f1, String(_) | Boolean(_) | List(_) | Object(_) | Null => true } } String(ref s0) => { match *other { Number(_) => false, String(ref s1) => s0 < s1, Boolean(_) | List(_) | Object(_) | Null => true } } Boolean(b0) => { match *other { Number(_) | String(_) => false, Boolean(b1) => b0 < b1, List(_) | Object(_) | Null => true } } List(ref l0) => { match *other { Number(_) | String(_) | Boolean(_) => false, List(ref l1) => (*l0) < (*l1), Object(_) | Null => true } } Object(ref d0) => { match *other { Number(_) | String(_) | Boolean(_) | List(_) => false, Object(ref d1) => { let mut d0_flat = ~[]; let mut d1_flat = ~[]; // FIXME #4430: this is horribly inefficient... for d0.each |k, v| { d0_flat.push((@copy *k, @copy *v)); } d0_flat.qsort(); for d1.each |k, v| { d1_flat.push((@copy *k, @copy *v)); } d1_flat.qsort(); d0_flat < d1_flat } Null => true } } Null => { match *other { Number(_) | String(_) | Boolean(_) | List(_) | Object(_) => false, Null => true } } } } fn le(&self, other: &Json) -> bool { !(*other).lt(&(*self)) } fn ge(&self, other: &Json) -> bool { !(*self).lt(other) } fn gt(&self, other: &Json) -> bool { (*other).lt(&(*self)) } } /// A trait for converting values to JSON trait ToJson { /// Converts the value of `self` to an instance of JSON fn to_json(&self) -> Json; } impl ToJson for Json { fn to_json(&self) -> Json { copy *self } } impl ToJson for @Json { fn to_json(&self) -> Json { (**self).to_json() } } impl ToJson for int { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for i8 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for i16 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for i32 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for i64 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for uint { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for u8 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for u16 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for u32 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for u64 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for float { fn to_json(&self) -> Json { Number(*self) } } impl ToJson for f32 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for f64 { fn to_json(&self) -> Json { Number(*self as float) } } impl ToJson for () { fn to_json(&self) -> Json { Null } } impl ToJson for bool { fn to_json(&self) -> Json { Boolean(*self) } } impl ToJson for ~str { fn to_json(&self) -> Json { String(copy *self) } } impl ToJson for @~str { fn to_json(&self) -> Json { String(copy **self) } } impl ToJson for (A, B) { fn to_json(&self) -> Json { match *self { (ref a, ref b) => { List(~[a.to_json(), b.to_json()]) } } } } impl ToJson for (A, B, C) { fn to_json(&self) -> Json { match *self { (ref a, ref b, ref c) => { List(~[a.to_json(), b.to_json(), c.to_json()]) } } } } impl ToJson for ~[A] { fn to_json(&self) -> Json { List(self.map(|elt| elt.to_json())) } } impl ToJson for HashMap<~str, A> { fn to_json(&self) -> Json { let mut d = HashMap::new(); for self.each |key, value| { d.insert(copy *key, value.to_json()); } Object(~d) } } impl ToJson for Option { fn to_json(&self) -> Json { match *self { None => Null, Some(ref value) => value.to_json() } } } impl to_str::ToStr for Json { fn to_str(&self) -> ~str { to_str(self) } } impl to_str::ToStr for Error { fn to_str(&self) -> ~str { fmt!("%u:%u: %s", self.line, self.col, *self.msg) } } #[cfg(test)] mod tests { use core::prelude::*; use super::*; use core::hashmap::HashMap; use core::io; use core::result; use std::serialize::Decodable; #[deriving(Eq, Encodable, Decodable)] enum Animal { Dog, Frog(~str, int) } #[deriving(Eq, Encodable, Decodable)] struct Inner { a: (), b: uint, c: ~[~str], } #[deriving(Eq, Encodable, Decodable)] struct Outer { inner: ~[Inner], } fn mk_object(items: &[(~str, Json)]) -> Json { let mut d = ~HashMap::new(); for items.each |item| { match *item { (ref key, ref value) => { d.insert(copy *key, copy *value); }, } }; Object(d) } #[test] fn test_write_null() { assert_eq!(to_str(&Null), ~"null"); assert_eq!(to_pretty_str(&Null), ~"null"); } #[test] fn test_write_number() { assert_eq!(to_str(&Number(3f)), ~"3"); assert_eq!(to_pretty_str(&Number(3f)), ~"3"); assert_eq!(to_str(&Number(3.1f)), ~"3.1"); assert_eq!(to_pretty_str(&Number(3.1f)), ~"3.1"); assert_eq!(to_str(&Number(-1.5f)), ~"-1.5"); assert_eq!(to_pretty_str(&Number(-1.5f)), ~"-1.5"); assert_eq!(to_str(&Number(0.5f)), ~"0.5"); assert_eq!(to_pretty_str(&Number(0.5f)), ~"0.5"); } #[test] fn test_write_str() { assert_eq!(to_str(&String(~"")), ~"\"\""); assert_eq!(to_pretty_str(&String(~"")), ~"\"\""); assert_eq!(to_str(&String(~"foo")), ~"\"foo\""); assert_eq!(to_pretty_str(&String(~"foo")), ~"\"foo\""); } #[test] fn test_write_bool() { assert_eq!(to_str(&Boolean(true)), ~"true"); assert_eq!(to_pretty_str(&Boolean(true)), ~"true"); assert_eq!(to_str(&Boolean(false)), ~"false"); assert_eq!(to_pretty_str(&Boolean(false)), ~"false"); } #[test] fn test_write_list() { assert_eq!(to_str(&List(~[])), ~"[]"); assert_eq!(to_pretty_str(&List(~[])), ~"[]"); assert_eq!(to_str(&List(~[Boolean(true)])), ~"[true]"); assert_eq!( to_pretty_str(&List(~[Boolean(true)])), ~"\ [\n \ true\n\ ]" ); assert_eq!(to_str(&List(~[ Boolean(false), Null, List(~[String(~"foo\nbar"), Number(3.5f)]) ])), ~"[false,null,[\"foo\\nbar\",3.5]]"); assert_eq!( to_pretty_str(&List(~[ Boolean(false), Null, List(~[String(~"foo\nbar"), Number(3.5f)]) ])), ~"\ [\n \ false,\n \ null,\n \ [\n \ \"foo\\nbar\",\n \ 3.5\n \ ]\n\ ]" ); } #[test] fn test_write_object() { assert_eq!(to_str(&mk_object([])), ~"{}"); assert_eq!(to_pretty_str(&mk_object([])), ~"{}"); assert_eq!( to_str(&mk_object([(~"a", Boolean(true))])), ~"{\"a\":true}" ); assert_eq!( to_pretty_str(&mk_object([(~"a", Boolean(true))])), ~"\ {\n \ \"a\": true\n\ }" ); assert_eq!( to_str(&mk_object([ (~"b", List(~[ mk_object([(~"c", String(~"\x0c\r"))]), mk_object([(~"d", String(~""))]) ])) ])), ~"{\ \"b\":[\ {\"c\":\"\\f\\r\"},\ {\"d\":\"\"}\ ]\ }" ); assert_eq!( to_pretty_str(&mk_object([ (~"b", List(~[ mk_object([(~"c", String(~"\x0c\r"))]), mk_object([(~"d", String(~""))]) ])) ])), ~"\ {\n \ \"b\": [\n \ {\n \ \"c\": \"\\f\\r\"\n \ },\n \ {\n \ \"d\": \"\"\n \ }\n \ ]\n\ }" ); let a = mk_object([ (~"a", Boolean(true)), (~"b", List(~[ mk_object([(~"c", String(~"\x0c\r"))]), mk_object([(~"d", String(~""))]) ])) ]); // We can't compare the strings directly because the object fields be // printed in a different order. assert_eq!(copy a, from_str(to_str(&a)).unwrap()); assert_eq!(copy a, from_str(to_pretty_str(&a)).unwrap()); } #[test] fn test_write_enum() { let animal = Dog; assert_eq!( do io::with_str_writer |wr| { let mut encoder = Encoder(wr); animal.encode(&mut encoder); }, ~"\"Dog\"" ); assert_eq!( do io::with_str_writer |wr| { let mut encoder = PrettyEncoder(wr); animal.encode(&mut encoder); }, ~"\"Dog\"" ); let animal = Frog(~"Henry", 349); assert_eq!( do io::with_str_writer |wr| { let mut encoder = Encoder(wr); animal.encode(&mut encoder); }, ~"[\"Frog\",\"Henry\",349]" ); assert_eq!( do io::with_str_writer |wr| { let mut encoder = PrettyEncoder(wr); animal.encode(&mut encoder); }, ~"\ [\n \ \"Frog\",\n \ \"Henry\",\n \ 349\n\ ]" ); } #[test] fn test_write_some() { let value = Some(~"jodhpurs"); let s = do io::with_str_writer |wr| { let mut encoder = Encoder(wr); value.encode(&mut encoder); }; assert_eq!(s, ~"\"jodhpurs\""); let value = Some(~"jodhpurs"); let s = do io::with_str_writer |wr| { let mut encoder = PrettyEncoder(wr); value.encode(&mut encoder); }; assert_eq!(s, ~"\"jodhpurs\""); } #[test] fn test_write_none() { let value: Option<~str> = None; let s = do io::with_str_writer |wr| { let mut encoder = Encoder(wr); value.encode(&mut encoder); }; assert_eq!(s, ~"null"); let s = do io::with_str_writer |wr| { let mut encoder = Encoder(wr); value.encode(&mut encoder); }; assert_eq!(s, ~"null"); } #[test] fn test_trailing_characters() { assert_eq!(from_str("nulla"), Err(Error {line: 1u, col: 5u, msg: @~"trailing characters"})); assert_eq!(from_str("truea"), Err(Error {line: 1u, col: 5u, msg: @~"trailing characters"})); assert_eq!(from_str("falsea"), Err(Error {line: 1u, col: 6u, msg: @~"trailing characters"})); assert_eq!(from_str("1a"), Err(Error {line: 1u, col: 2u, msg: @~"trailing characters"})); assert_eq!(from_str("[]a"), Err(Error {line: 1u, col: 3u, msg: @~"trailing characters"})); assert_eq!(from_str("{}a"), Err(Error {line: 1u, col: 3u, msg: @~"trailing characters"})); } #[test] fn test_read_identifiers() { assert_eq!(from_str("n"), Err(Error {line: 1u, col: 2u, msg: @~"invalid syntax"})); assert_eq!(from_str("nul"), Err(Error {line: 1u, col: 4u, msg: @~"invalid syntax"})); assert_eq!(from_str("t"), Err(Error {line: 1u, col: 2u, msg: @~"invalid syntax"})); assert_eq!(from_str("truz"), Err(Error {line: 1u, col: 4u, msg: @~"invalid syntax"})); assert_eq!(from_str("f"), Err(Error {line: 1u, col: 2u, msg: @~"invalid syntax"})); assert_eq!(from_str("faz"), Err(Error {line: 1u, col: 3u, msg: @~"invalid syntax"})); assert_eq!(from_str("null"), Ok(Null)); assert_eq!(from_str("true"), Ok(Boolean(true))); assert_eq!(from_str("false"), Ok(Boolean(false))); assert_eq!(from_str(" null "), Ok(Null)); assert_eq!(from_str(" true "), Ok(Boolean(true))); assert_eq!(from_str(" false "), Ok(Boolean(false))); } #[test] fn test_decode_identifiers() { let mut decoder = Decoder(from_str("null").unwrap()); let v: () = Decodable::decode(&mut decoder); assert_eq!(v, ()); let mut decoder = Decoder(from_str("true").unwrap()); let v: bool = Decodable::decode(&mut decoder); assert_eq!(v, true); let mut decoder = Decoder(from_str("false").unwrap()); let v: bool = Decodable::decode(&mut decoder); assert_eq!(v, false); } #[test] fn test_read_number() { assert_eq!(from_str("+"), Err(Error {line: 1u, col: 1u, msg: @~"invalid syntax"})); assert_eq!(from_str("."), Err(Error {line: 1u, col: 1u, msg: @~"invalid syntax"})); assert_eq!(from_str("-"), Err(Error {line: 1u, col: 2u, msg: @~"invalid number"})); assert_eq!(from_str("00"), Err(Error {line: 1u, col: 2u, msg: @~"invalid number"})); assert_eq!(from_str("1."), Err(Error {line: 1u, col: 3u, msg: @~"invalid number"})); assert_eq!(from_str("1e"), Err(Error {line: 1u, col: 3u, msg: @~"invalid number"})); assert_eq!(from_str("1e+"), Err(Error {line: 1u, col: 4u, msg: @~"invalid number"})); assert_eq!(from_str("3"), Ok(Number(3f))); assert_eq!(from_str("3.1"), Ok(Number(3.1f))); assert_eq!(from_str("-1.2"), Ok(Number(-1.2f))); assert_eq!(from_str("0.4"), Ok(Number(0.4f))); assert_eq!(from_str("0.4e5"), Ok(Number(0.4e5f))); assert_eq!(from_str("0.4e+15"), Ok(Number(0.4e15f))); assert_eq!(from_str("0.4e-01"), Ok(Number(0.4e-01f))); assert_eq!(from_str(" 3 "), Ok(Number(3f))); } #[test] fn test_decode_numbers() { let mut decoder = Decoder(from_str("3").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 3f); let mut decoder = Decoder(from_str("3.1").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 3.1f); let mut decoder = Decoder(from_str("-1.2").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, -1.2f); let mut decoder = Decoder(from_str("0.4").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 0.4f); let mut decoder = Decoder(from_str("0.4e5").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 0.4e5f); let mut decoder = Decoder(from_str("0.4e15").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 0.4e15f); let mut decoder = Decoder(from_str("0.4e-01").unwrap()); let v: float = Decodable::decode(&mut decoder); assert_eq!(v, 0.4e-01f); } #[test] fn test_read_str() { assert_eq!(from_str("\""), Err(Error {line: 1u, col: 2u, msg: @~"EOF while parsing string" })); assert_eq!(from_str("\"lol"), Err(Error {line: 1u, col: 5u, msg: @~"EOF while parsing string" })); assert_eq!(from_str("\"\""), Ok(String(~""))); assert_eq!(from_str("\"foo\""), Ok(String(~"foo"))); assert_eq!(from_str("\"\\\"\""), Ok(String(~"\""))); assert_eq!(from_str("\"\\b\""), Ok(String(~"\x08"))); assert_eq!(from_str("\"\\n\""), Ok(String(~"\n"))); assert_eq!(from_str("\"\\r\""), Ok(String(~"\r"))); assert_eq!(from_str("\"\\t\""), Ok(String(~"\t"))); assert_eq!(from_str(" \"foo\" "), Ok(String(~"foo"))); assert_eq!(from_str("\"\\u12ab\""), Ok(String(~"\u12ab"))); assert_eq!(from_str("\"\\uAB12\""), Ok(String(~"\uAB12"))); } #[test] fn test_decode_str() { let mut decoder = Decoder(from_str("\"\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~""); let mut decoder = Decoder(from_str("\"foo\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"foo"); let mut decoder = Decoder(from_str("\"\\\"\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\""); let mut decoder = Decoder(from_str("\"\\b\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\x08"); let mut decoder = Decoder(from_str("\"\\n\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\n"); let mut decoder = Decoder(from_str("\"\\r\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\r"); let mut decoder = Decoder(from_str("\"\\t\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\t"); let mut decoder = Decoder(from_str("\"\\u12ab\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\u12ab"); let mut decoder = Decoder(from_str("\"\\uAB12\"").unwrap()); let v: ~str = Decodable::decode(&mut decoder); assert_eq!(v, ~"\uAB12"); } #[test] fn test_read_list() { assert_eq!(from_str("["), Err(Error {line: 1u, col: 2u, msg: @~"EOF while parsing value"})); assert_eq!(from_str("[1"), Err(Error {line: 1u, col: 3u, msg: @~"EOF while parsing list"})); assert_eq!(from_str("[1,"), Err(Error {line: 1u, col: 4u, msg: @~"EOF while parsing value"})); assert_eq!(from_str("[1,]"), Err(Error {line: 1u, col: 4u, msg: @~"invalid syntax"})); assert_eq!(from_str("[6 7]"), Err(Error {line: 1u, col: 4u, msg: @~"expected `,` or `]`"})); assert_eq!(from_str("[]"), Ok(List(~[]))); assert_eq!(from_str("[ ]"), Ok(List(~[]))); assert_eq!(from_str("[true]"), Ok(List(~[Boolean(true)]))); assert_eq!(from_str("[ false ]"), Ok(List(~[Boolean(false)]))); assert_eq!(from_str("[null]"), Ok(List(~[Null]))); assert_eq!(from_str("[3, 1]"), Ok(List(~[Number(3f), Number(1f)]))); assert_eq!(from_str("\n[3, 2]\n"), Ok(List(~[Number(3f), Number(2f)]))); assert_eq!(from_str("[2, [4, 1]]"), Ok(List(~[Number(2f), List(~[Number(4f), Number(1f)])]))); } #[test] fn test_decode_list() { let mut decoder = Decoder(from_str("[]").unwrap()); let v: ~[()] = Decodable::decode(&mut decoder); assert_eq!(v, ~[]); let mut decoder = Decoder(from_str("[null]").unwrap()); let v: ~[()] = Decodable::decode(&mut decoder); assert_eq!(v, ~[()]); let mut decoder = Decoder(from_str("[true]").unwrap()); let v: ~[bool] = Decodable::decode(&mut decoder); assert_eq!(v, ~[true]); let mut decoder = Decoder(from_str("[true]").unwrap()); let v: ~[bool] = Decodable::decode(&mut decoder); assert_eq!(v, ~[true]); let mut decoder = Decoder(from_str("[3, 1]").unwrap()); let v: ~[int] = Decodable::decode(&mut decoder); assert_eq!(v, ~[3, 1]); let mut decoder = Decoder(from_str("[[3], [1, 2]]").unwrap()); let v: ~[~[uint]] = Decodable::decode(&mut decoder); assert_eq!(v, ~[~[3], ~[1, 2]]); } #[test] fn test_read_object() { assert_eq!(from_str("{"), Err(Error { line: 1u, col: 2u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{ "), Err(Error { line: 1u, col: 3u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{1"), Err(Error { line: 1u, col: 2u, msg: @~"key must be a string"})); assert_eq!(from_str("{ \"a\""), Err(Error { line: 1u, col: 6u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{\"a\""), Err(Error { line: 1u, col: 5u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{\"a\" "), Err(Error { line: 1u, col: 6u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{\"a\" 1"), Err(Error {line: 1u, col: 6u, msg: @~"expected `:`"})); assert_eq!(from_str("{\"a\":"), Err(Error {line: 1u, col: 6u, msg: @~"EOF while parsing value"})); assert_eq!(from_str("{\"a\":1"), Err(Error { line: 1u, col: 7u, msg: @~"EOF while parsing object"})); assert_eq!(from_str("{\"a\":1 1"), Err(Error {line: 1u, col: 8u, msg: @~"expected `,` or `}`"})); assert_eq!(from_str("{\"a\":1,"), Err(Error { line: 1u, col: 8u, msg: @~"EOF while parsing object"})); assert_eq!(result::unwrap(from_str("{}")), mk_object([])); assert_eq!(result::unwrap(from_str("{\"a\": 3}")), mk_object([(~"a", Number(3.0f))])); assert_eq!(result::unwrap(from_str( "{ \"a\": null, \"b\" : true }")), mk_object([ (~"a", Null), (~"b", Boolean(true))])); assert_eq!(result::unwrap( from_str("\n{ \"a\": null, \"b\" : true }\n")), mk_object([ (~"a", Null), (~"b", Boolean(true))])); assert_eq!(result::unwrap(from_str( "{\"a\" : 1.0 ,\"b\": [ true ]}")), mk_object([ (~"a", Number(1.0)), (~"b", List(~[Boolean(true)])) ])); assert_eq!(result::unwrap(from_str( ~"{" + "\"a\": 1.0, " + "\"b\": [" + "true," + "\"foo\\nbar\", " + "{ \"c\": {\"d\": null} } " + "]" + "}")), mk_object([ (~"a", Number(1.0f)), (~"b", List(~[ Boolean(true), String(~"foo\nbar"), mk_object([ (~"c", mk_object([(~"d", Null)])) ]) ])) ])); } #[test] fn test_decode_struct() { let s = ~"{ \"inner\": [ { \"a\": null, \"b\": 2, \"c\": [\"abc\", \"xyz\"] } ] }"; let mut decoder = Decoder(from_str(s).unwrap()); let v: Outer = Decodable::decode(&mut decoder); assert_eq!( v, Outer { inner: ~[ Inner { a: (), b: 2, c: ~[~"abc", ~"xyz"] } ] } ); } #[test] fn test_decode_option() { let mut decoder = Decoder(from_str("null").unwrap()); let value: Option<~str> = Decodable::decode(&mut decoder); assert_eq!(value, None); let mut decoder = Decoder(from_str("\"jodhpurs\"").unwrap()); let value: Option<~str> = Decodable::decode(&mut decoder); assert_eq!(value, Some(~"jodhpurs")); } #[test] fn test_decode_enum() { let mut decoder = Decoder(from_str("\"Dog\"").unwrap()); let value: Animal = Decodable::decode(&mut decoder); assert_eq!(value, Dog); let mut decoder = Decoder(from_str("[\"Frog\",\"Henry\",349]").unwrap()); let value: Animal = Decodable::decode(&mut decoder); assert_eq!(value, Frog(~"Henry", 349)); } #[test] fn test_decode_map() { let s = ~"{\"a\": \"Dog\", \"b\": [\"Frog\", \"Henry\", 349]}"; let mut decoder = Decoder(from_str(s).unwrap()); let mut map: HashMap<~str, Animal> = Decodable::decode(&mut decoder); assert_eq!(map.pop(&~"a"), Some(Dog)); assert_eq!(map.pop(&~"b"), Some(Frog(~"Henry", 349))); } #[test] fn test_multiline_errors() { assert_eq!(from_str("{\n \"foo\":\n \"bar\""), Err(Error { line: 3u, col: 8u, msg: @~"EOF while parsing object"})); } }