Improve decoder errors

This commit is contained in:
Alex Crichton 2014-06-23 08:38:45 -07:00
parent 16d5e67fa5
commit 266cd75e92

View file

@ -48,6 +48,7 @@ pub struct Encoder {
/// arbitrary TOML value. /// arbitrary TOML value.
pub struct Decoder { pub struct Decoder {
toml: Option<Value>, toml: Option<Value>,
cur_field: String,
} }
/// Enumeration of errors which can occur while encoding a rust value into a /// Enumeration of errors which can occur while encoding a rust value into a
@ -65,11 +66,13 @@ pub enum Error {
/// Indicates that a type other than a string was attempted to be used as a /// Indicates that a type other than a string was attempted to be used as a
/// map key type. /// map key type.
InvalidMapKeyType, InvalidMapKeyType,
/// Indicates that a type was decoded against a TOML value of a different }
/// type.
InvalidType, /// Description for errors which can occur while decoding a type.
/// Indicates that a field was attempted to be read that does not exist. #[deriving(Show)]
MissingField, pub struct DecodeError {
/// Human-readable description of this error.
pub desc: String,
} }
#[deriving(PartialEq, Show)] #[deriving(PartialEq, Show)]
@ -322,7 +325,7 @@ impl serialize::Encoder<Error> for Encoder {
/// into the type specified. If decoding fails, `None` will be returned. If a /// into the type specified. If decoding fails, `None` will be returned. If a
/// finer-grained error is desired, then it is recommended to use `Decodable` /// finer-grained error is desired, then it is recommended to use `Decodable`
/// directly. /// directly.
pub fn decode<T: serialize::Decodable<Decoder, Error>>(toml: Value) pub fn decode<T: serialize::Decodable<Decoder, DecodeError>>(toml: Value)
-> Option<T> -> Option<T>
{ {
serialize::Decodable::decode(&mut Decoder::new(toml)).ok() serialize::Decodable::decode(&mut Decoder::new(toml)).ok()
@ -334,7 +337,7 @@ pub fn decode<T: serialize::Decodable<Decoder, Error>>(toml: Value)
/// the TOML value into the desired type. If any error occurs `None` is return. /// the TOML value into the desired type. If any error occurs `None` is return.
/// If more fine-grained errors are desired, these steps should be driven /// If more fine-grained errors are desired, these steps should be driven
/// manually. /// manually.
pub fn decode_str<T: serialize::Decodable<Decoder, Error>>(s: &str) pub fn decode_str<T: serialize::Decodable<Decoder, DecodeError>>(s: &str)
-> Option<T> -> Option<T>
{ {
Parser::new(s).parse().and_then(|t| decode(Table(t))) Parser::new(s).parse().and_then(|t| decode(Table(t)))
@ -346,169 +349,207 @@ impl Decoder {
/// This decoder can be passed to the `Decodable` methods or driven /// This decoder can be passed to the `Decodable` methods or driven
/// manually. /// manually.
pub fn new(toml: Value) -> Decoder { pub fn new(toml: Value) -> Decoder {
Decoder { toml: Some(toml) } Decoder { toml: Some(toml), cur_field: "".to_string() }
}
fn sub_decoder(&self, toml: Option<Value>, field: &str) -> Decoder {
Decoder {
toml: toml,
cur_field: if self.cur_field.len() == 0 {
field.to_string()
} else if field.len() == 0 {
self.cur_field.to_string()
} else {
format!("{}.{}", self.cur_field, field)
}
}
}
fn field_error(&self, desc: &str) -> DecodeError {
DecodeError {
desc: format!("{}", desc),
}
}
fn type_error(&self, expected: &str, found: &Option<Value>) -> DecodeError {
DecodeError {
desc: format!("{}expected type `{}`, but found {}",
if self.cur_field.len() > 0 {
format!("for field `{}` ", self.cur_field)
} else {
"".to_string()
},
expected,
match *found {
Some(ref val) => format!("`{}`", val.type_str()),
None => "no value".to_string(),
})
}
} }
} }
impl serialize::Decoder<Error> for Decoder { impl serialize::Decoder<DecodeError> for Decoder {
fn read_nil(&mut self) -> Result<(), Error> { fn read_nil(&mut self) -> Result<(), DecodeError> {
match self.toml { match self.toml {
Some(String(ref s)) if s.len() == 0 => Ok(()), Some(String(ref s)) if s.len() == 0 => Ok(()),
_ => Err(InvalidType), Some(String(..)) => Err(self.field_error("expected 0-length string")),
ref found => Err(self.type_error("string", found)),
} }
} }
fn read_uint(&mut self) -> Result<uint, Error> { fn read_uint(&mut self) -> Result<uint, DecodeError> {
self.read_i64().map(|i| i as uint) self.read_i64().map(|i| i as uint)
} }
fn read_u64(&mut self) -> Result<u64, Error> { fn read_u64(&mut self) -> Result<u64, DecodeError> {
self.read_i64().map(|i| i as u64) self.read_i64().map(|i| i as u64)
} }
fn read_u32(&mut self) -> Result<u32, Error> { fn read_u32(&mut self) -> Result<u32, DecodeError> {
self.read_i64().map(|i| i as u32) self.read_i64().map(|i| i as u32)
} }
fn read_u16(&mut self) -> Result<u16, Error> { fn read_u16(&mut self) -> Result<u16, DecodeError> {
self.read_i64().map(|i| i as u16) self.read_i64().map(|i| i as u16)
} }
fn read_u8(&mut self) -> Result<u8, Error> { fn read_u8(&mut self) -> Result<u8, DecodeError> {
self.read_i64().map(|i| i as u8) self.read_i64().map(|i| i as u8)
} }
fn read_int(&mut self) -> Result<int, Error> { fn read_int(&mut self) -> Result<int, DecodeError> {
self.read_i64().map(|i| i as int) self.read_i64().map(|i| i as int)
} }
fn read_i64(&mut self) -> Result<i64, Error> { fn read_i64(&mut self) -> Result<i64, DecodeError> {
match self.toml { match self.toml {
Some(Integer(i)) => Ok(i), Some(Integer(i)) => Ok(i),
_ => Err(InvalidType), ref found => Err(self.type_error("integer", found)),
} }
} }
fn read_i32(&mut self) -> Result<i32, Error> { fn read_i32(&mut self) -> Result<i32, DecodeError> {
self.read_i64().map(|i| i as i32) self.read_i64().map(|i| i as i32)
} }
fn read_i16(&mut self) -> Result<i16, Error> { fn read_i16(&mut self) -> Result<i16, DecodeError> {
self.read_i64().map(|i| i as i16) self.read_i64().map(|i| i as i16)
} }
fn read_i8(&mut self) -> Result<i8, Error> { fn read_i8(&mut self) -> Result<i8, DecodeError> {
self.read_i64().map(|i| i as i8) self.read_i64().map(|i| i as i8)
} }
fn read_bool(&mut self) -> Result<bool, Error> { fn read_bool(&mut self) -> Result<bool, DecodeError> {
match self.toml { match self.toml {
Some(Boolean(b)) => Ok(b), Some(Boolean(b)) => Ok(b),
_ => Err(InvalidType), ref found => Err(self.type_error("bool", found)),
} }
} }
fn read_f64(&mut self) -> Result<f64, Error> { fn read_f64(&mut self) -> Result<f64, DecodeError> {
match self.toml { match self.toml {
Some(Float(f)) => Ok(f), Some(Float(f)) => Ok(f),
_ => Err(InvalidType), ref found => Err(self.type_error("float", found)),
} }
} }
fn read_f32(&mut self) -> Result<f32, Error> { fn read_f32(&mut self) -> Result<f32, DecodeError> {
self.read_f64().map(|f| f as f32) self.read_f64().map(|f| f as f32)
} }
fn read_char(&mut self) -> Result<char, Error> { fn read_char(&mut self) -> Result<char, DecodeError> {
match self.toml { match self.toml {
Some(String(ref s)) if s.as_slice().char_len() == 1 => Some(String(ref s)) if s.as_slice().char_len() == 1 =>
Ok(s.as_slice().char_at(0)), Ok(s.as_slice().char_at(0)),
_ => Err(InvalidType), ref found => Err(self.type_error("string", found)),
} }
} }
fn read_str(&mut self) -> Result<String, Error> { fn read_str(&mut self) -> Result<String, DecodeError> {
match self.toml.take() { match self.toml.take() {
Some(String(s)) => Ok(s), Some(String(s)) => Ok(s),
toml => { self.toml = toml; Err(InvalidType) } ref found => Err(self.type_error("string", found)),
} }
} }
// Compound types: // Compound types:
fn read_enum<T>(&mut self, _name: &str, fn read_enum<T>(&mut self, _name: &str,
_f: |&mut Decoder| -> Result<T, Error>) -> Result<T, Error> { _f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, DecodeError>
{
fail!() fail!()
} }
fn read_enum_variant<T>(&mut self, fn read_enum_variant<T>(&mut self,
_names: &[&str], _names: &[&str],
_f: |&mut Decoder, uint| -> Result<T, Error>) _f: |&mut Decoder, uint| -> Result<T, DecodeError>)
-> Result<T, Error> { -> Result<T, DecodeError> {
fail!() fail!()
} }
fn read_enum_variant_arg<T>(&mut self, fn read_enum_variant_arg<T>(&mut self,
_a_idx: uint, _a_idx: uint,
_f: |&mut Decoder| -> Result<T, Error>) _f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> { -> Result<T, DecodeError> {
fail!() fail!()
} }
fn read_enum_struct_variant<T>(&mut self, fn read_enum_struct_variant<T>(&mut self,
_names: &[&str], _names: &[&str],
_f: |&mut Decoder, uint| -> Result<T, Error>) _f: |&mut Decoder, uint|
-> Result<T, Error> { -> Result<T, DecodeError>)
-> Result<T, DecodeError>
{
fail!() fail!()
} }
fn read_enum_struct_variant_field<T>(&mut self, fn read_enum_struct_variant_field<T>(&mut self,
_f_name: &str, _f_name: &str,
_f_idx: uint, _f_idx: uint,
_f: |&mut Decoder| -> Result<T, Error>) _f: |&mut Decoder|
-> Result<T, Error> { -> Result<T, DecodeError>)
-> Result<T, DecodeError>
{
fail!() fail!()
} }
fn read_struct<T>(&mut self, _s_name: &str, _len: uint, fn read_struct<T>(&mut self, _s_name: &str, _len: uint,
f: |&mut Decoder| -> Result<T, Error>) f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
match self.toml { match self.toml {
Some(Table(..)) => f(self), Some(Table(..)) => f(self),
_ => Err(InvalidType), ref found => Err(self.type_error("table", found)),
} }
} }
fn read_struct_field<T>(&mut self, fn read_struct_field<T>(&mut self,
f_name: &str, f_name: &str,
_f_idx: uint, _f_idx: uint,
f: |&mut Decoder| -> Result<T, Error>) f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> { -> Result<T, DecodeError> {
match self.toml { let toml = match self.toml {
Some(Table(ref mut table)) => { Some(Table(ref mut table)) => table.pop(&f_name.to_string()),
match table.pop(&f_name.to_string()) { ref found => return Err(self.type_error("table", found)),
Some(field) => f(&mut Decoder::new(field)), };
None => f(&mut Decoder { toml: None }), f(&mut self.sub_decoder(toml, f_name))
}
}
_ => Err(InvalidType)
}
} }
fn read_tuple<T>(&mut self, fn read_tuple<T>(&mut self,
f: |&mut Decoder, uint| -> Result<T, Error>) f: |&mut Decoder, uint| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
self.read_seq(f) self.read_seq(f)
} }
fn read_tuple_arg<T>(&mut self, a_idx: uint, fn read_tuple_arg<T>(&mut self, a_idx: uint,
f: |&mut Decoder| -> Result<T, Error>) f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
self.read_seq_elt(a_idx, f) self.read_seq_elt(a_idx, f)
} }
fn read_tuple_struct<T>(&mut self, fn read_tuple_struct<T>(&mut self,
_s_name: &str, _s_name: &str,
_f: |&mut Decoder, uint| -> Result<T, Error>) _f: |&mut Decoder, uint| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
fail!() fail!()
} }
fn read_tuple_struct_arg<T>(&mut self, fn read_tuple_struct_arg<T>(&mut self,
_a_idx: uint, _a_idx: uint,
_f: |&mut Decoder| -> Result<T, Error>) _f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
fail!() fail!()
} }
// Specialized types: // Specialized types:
fn read_option<T>(&mut self, fn read_option<T>(&mut self,
f: |&mut Decoder, bool| -> Result<T, Error>) f: |&mut Decoder, bool| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
match self.toml { match self.toml {
Some(..) => f(self, true), Some(..) => f(self, true),
@ -516,66 +557,71 @@ impl serialize::Decoder<Error> for Decoder {
} }
} }
fn read_seq<T>(&mut self, f: |&mut Decoder, uint| -> Result<T, Error>) fn read_seq<T>(&mut self, f: |&mut Decoder, uint| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
let len = match self.toml { let len = match self.toml {
Some(Array(ref arr)) => arr.len(), Some(Array(ref arr)) => arr.len(),
_ => return Err(InvalidType), ref found => return Err(self.type_error("array", found)),
}; };
f(self, len) f(self, len)
} }
fn read_seq_elt<T>(&mut self, idx: uint, f: |&mut Decoder| -> Result<T, Error>) fn read_seq_elt<T>(&mut self, idx: uint,
-> Result<T, Error> f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, DecodeError>
{ {
match self.toml { let toml = match self.toml {
Some(Array(ref mut arr)) => { Some(Array(ref mut arr)) => mem::replace(arr.get_mut(idx), Integer(0)),
f(&mut Decoder::new(mem::replace(arr.get_mut(idx), Integer(0)))) ref found => return Err(self.type_error("array", found)),
} };
_ => Err(InvalidType), f(&mut self.sub_decoder(Some(toml), ""))
}
} }
fn read_map<T>(&mut self, f: |&mut Decoder, uint| -> Result<T, Error>) fn read_map<T>(&mut self, f: |&mut Decoder, uint| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
let len = match self.toml { let len = match self.toml {
Some(Table(ref table)) => table.len(), Some(Table(ref table)) => table.len(),
_ => return Err(InvalidType), ref found => return Err(self.type_error("table", found)),
}; };
f(self, len) f(self, len)
} }
fn read_map_elt_key<T>(&mut self, idx: uint, fn read_map_elt_key<T>(&mut self, idx: uint,
f: |&mut Decoder| -> Result<T, Error>) f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
match self.toml { match self.toml {
Some(Table(ref table)) => { Some(Table(ref table)) => {
match table.keys().skip(idx).next() { match table.keys().skip(idx).next() {
Some(key) => { Some(key) => {
f(&mut Decoder::new(String(key.to_str()))) f(&mut self.sub_decoder(Some(String(key.to_string())),
key.as_slice()))
} }
None => Err(InvalidType), None => Err(DecodeError {
desc: format!("map key `{}` does not exist", idx),
}),
} }
} }
_ => Err(InvalidType), ref found => Err(self.type_error("table", found)),
} }
} }
fn read_map_elt_val<T>(&mut self, idx: uint, fn read_map_elt_val<T>(&mut self, idx: uint,
f: |&mut Decoder| -> Result<T, Error>) f: |&mut Decoder| -> Result<T, DecodeError>)
-> Result<T, Error> -> Result<T, DecodeError>
{ {
match self.toml { match self.toml {
Some(Table(ref table)) => { Some(Table(ref table)) => {
match table.values().skip(idx).next() { match table.values().skip(idx).next() {
Some(key) => { Some(key) => {
// XXX: this shouldn't clone // XXX: this shouldn't clone
f(&mut Decoder::new(key.clone())) f(&mut self.sub_decoder(Some(key.clone()), ""))
} }
None => Err(InvalidType), None => Err(DecodeError {
desc: format!("map element `{}` does not exist", idx),
})
} }
} }
_ => Err(InvalidType), ref found => Err(self.type_error("table", found)),
} }
} }
} }
@ -585,7 +631,7 @@ mod tests {
use std::collections::{HashMap, HashSet}; use std::collections::{HashMap, HashSet};
use serialize::{Encodable, Decodable}; use serialize::{Encodable, Decodable};
use super::{Encoder, Decoder}; use super::{Encoder, Decoder, DecodeError};
use {Table, Integer, String, Array, Float}; use {Table, Integer, String, Array, Float};
macro_rules! encode( ($t:expr) => ({ macro_rules! encode( ($t:expr) => ({
@ -754,4 +800,43 @@ mod tests {
); );
assert_eq!(v, decode!(Table(encode!(v)))); assert_eq!(v, decode!(Table(encode!(v))));
} }
#[test]
fn table_array() {
#[deriving(Encodable, Decodable, PartialEq, Show)]
struct Foo { a: Vec<Bar>, }
#[deriving(Encodable, Decodable, PartialEq, Show)]
struct Bar { a: int }
let v = Foo { a: vec![Bar { a: 1 }, Bar { a: 2 }] };
assert_eq!(
encode!(v),
map! {
a: Array(vec![
Table(map!{ a: Integer(1) }),
Table(map!{ a: Integer(2) }),
])
}
);
assert_eq!(v, decode!(Table(encode!(v))));
}
#[test]
fn errors() {
#[deriving(Encodable, Decodable, PartialEq, Show)]
struct Foo { bar: int }
let mut d = Decoder::new(Table(map! {
bar: Float(1.0)
}));
let a: Result<Foo, DecodeError> = Decodable::decode(&mut d);
match a {
Ok(..) => fail!("should not have decoded"),
Err(e) => {
assert_eq!(e.desc.as_slice(),
"for field `bar` expected type `integer`, but \
found `float`");
}
}
}
} }