// Copyright (C) 2018 François Laignel // // 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. use glib; use glib::{StaticType, ToValue}; use num_rational::Rational32; use serde::de; use serde::de::{Deserialize, Deserializer, SeqAccess, Visitor}; use serde::ser; use serde::ser::{Serialize, SerializeTuple, Serializer}; use std::{fmt, mem}; use DateTime; use Sample; use value::*; fn get_other_type_id() -> usize { match T::static_type() { glib::Type::Other(type_id) => type_id, type_ => panic!("Expecting `Other` variant, found `{}`", type_), } } lazy_static! { pub(crate) static ref ARRAY_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref BITMASK_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref DATE_TIME_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref FRACTION_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref FRACTION_RANGE_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref INT_RANGE_I32_OTHER_TYPE_ID: usize = get_other_type_id::>(); pub(crate) static ref INT_RANGE_I64_OTHER_TYPE_ID: usize = get_other_type_id::>(); pub(crate) static ref LIST_OTHER_TYPE_ID: usize = get_other_type_id::(); pub(crate) static ref SAMPLE_OTHER_TYPE_ID: usize = get_other_type_id::(); } impl<'a> Serialize for Fraction { fn serialize(&self, serializer: S) -> Result { self.0.serialize(serializer) } } impl<'de> Deserialize<'de> for Fraction { fn deserialize>(deserializer: D) -> Result { Rational32::deserialize(deserializer) .map(|rational| Fraction::new(*rational.numer(), *rational.denom())) } } macro_rules! ser_value ( ($value:expr, $t:ty, $ser_closure:expr) => ( { let value = $value.get::<$t>().unwrap(); $ser_closure(stringify!($t), value) } ); ($value:expr, $ser_closure:expr) => ( match $value.type_() { glib::Type::I8 => ser_value!($value, i8, $ser_closure), glib::Type::U8 => ser_value!($value, u8, $ser_closure), glib::Type::Bool => ser_value!($value, bool, $ser_closure), glib::Type::I32 => ser_value!($value, i32, $ser_closure), glib::Type::U32 => ser_value!($value, u32, $ser_closure), glib::Type::I64 => ser_value!($value, i64, $ser_closure), glib::Type::U64 => ser_value!($value, u64, $ser_closure), glib::Type::F32 => ser_value!($value, f32, $ser_closure), glib::Type::F64 => ser_value!($value, f64, $ser_closure), glib::Type::String => ser_value!($value, String, $ser_closure), glib::Type::Other(type_id) => { if *ARRAY_OTHER_TYPE_ID == type_id { ser_value!($value, Array, $ser_closure) } else if *BITMASK_OTHER_TYPE_ID == type_id { ser_value!($value, Bitmask, $ser_closure) } else if *DATE_TIME_OTHER_TYPE_ID == type_id { ser_value!($value, DateTime, $ser_closure) } else if *FRACTION_OTHER_TYPE_ID == type_id { ser_value!($value, Fraction, $ser_closure) } else if *FRACTION_RANGE_OTHER_TYPE_ID == type_id { ser_value!($value, FractionRange, $ser_closure) } else if *INT_RANGE_I32_OTHER_TYPE_ID == type_id { ser_value!($value, IntRange, $ser_closure) } else if *INT_RANGE_I64_OTHER_TYPE_ID == type_id { ser_value!($value, IntRange, $ser_closure) } else if *LIST_OTHER_TYPE_ID == type_id { ser_value!($value, List, $ser_closure) } else if *SAMPLE_OTHER_TYPE_ID == type_id { ser_value!($value, Sample, $ser_closure) } else { Err( ser::Error::custom( format!("unimplemented `Value` serialization for type {}", glib::Type::Other(type_id), ) ) ) } } type_ => { Err( ser::Error::custom( format!("unimplemented `Value` serialization for type {}", type_) ) ) } } ); ); #[repr(C)] pub(crate) struct SendValue(glib::SendValue); impl SendValue { pub(crate) fn from(send_value: glib::SendValue) -> Self { SendValue(send_value) } } impl From for glib::SendValue { fn from(send_value: SendValue) -> Self { send_value.0 } } impl Serialize for SendValue { fn serialize(&self, serializer: S) -> Result { ser_value!(self.0, |type_, value| { let mut tup = serializer.serialize_tuple(2)?; tup.serialize_element(type_)?; tup.serialize_element(&value)?; tup.end() }) } } macro_rules! impl_ser_send_value_collection ( ($t:ident) => ( impl<'a> Serialize for $t<'a> { fn serialize(&self, serializer: S) -> Result { let send_value_vec = unsafe { &*(self.as_slice() as *const [glib::SendValue] as *const [SendValue]) }; send_value_vec.serialize(serializer) } } ); ); impl_ser_send_value_collection!(Array); impl_ser_send_value_collection!(List); macro_rules! de_value( ($seq:expr, $t:ty) => ( { let value = $seq .next_element::<$t>()? .map(|base_value| base_value.to_value()); Ok(value) } ); ); macro_rules! de_send_value( ($type_name:expr, $seq:expr, $t:ty) => ( de_send_value!("Value", $type_name, $seq, $t) ); ($outer_type:expr, $type_name:expr, $seq:expr, $t:ty) => ( match de_value!($seq, $t)? { Some(value) => { let glib_send_value = value .try_into_send_value::<$t>() .map_err(|_| de::Error::custom(format!( "Failed to convert `{}` with type {:?} to `SendValue`", $outer_type, $type_name, )) )?; Ok(Some(SendValue::from(glib_send_value))) } None => Ok(None) } ); ($type_name:expr, $seq:expr) => ( match $type_name.as_str() { "i8" => de_send_value!($type_name, $seq, i8), "u8" => de_send_value!($type_name, $seq, u8), "bool" => de_send_value!($type_name, $seq, bool), "i32" => de_send_value!($type_name, $seq, i32), "u32" => de_send_value!($type_name, $seq, u32), "i64" => de_send_value!($type_name, $seq, i64), "u64" => de_send_value!($type_name, $seq, u64), "f32" => de_send_value!($type_name, $seq, f32), "f64" => de_send_value!($type_name, $seq, f64), "String" => de_send_value!($type_name, $seq, String), "Array" => de_send_value!($type_name, $seq, Array), "Bitmask" => de_send_value!($type_name, $seq, Bitmask), "DateTime" => de_send_value!($type_name, $seq, DateTime), "Fraction" => de_send_value!($type_name, $seq, Fraction), "FractionRange" => de_send_value!($type_name, $seq, FractionRange), "IntRange" => de_send_value!($type_name, $seq, IntRange), "IntRange" => de_send_value!($type_name, $seq, IntRange), "Sample" => de_send_value!($type_name, $seq, Sample), _ => return Err( de::Error::custom( format!( "unimplemented deserialization for `Value` with type `{}`", $type_name, ), ) ), } ); ); struct SendValueVisitor; impl<'de> Visitor<'de> for SendValueVisitor { type Value = SendValue; fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { formatter.write_str("a tuple: (name, value)") } fn visit_seq>(self, mut seq: A) -> Result { let type_name = seq .next_element::()? .ok_or_else(|| de::Error::custom("Expected a value for `Value` type"))?; let send_value = de_send_value!(type_name, seq)? .ok_or_else(|| de::Error::custom("Expected a value for `Value`"))?; Ok(send_value) } } impl<'de> Deserialize<'de> for SendValue { fn deserialize>(deserializer: D) -> Result { deserializer.deserialize_tuple(2, SendValueVisitor {}) } } macro_rules! impl_de_send_value_collection ( ($t:ident) => { impl<'a, 'de> Deserialize<'de> for $t<'a> { fn deserialize>(deserializer: D) -> Result { let send_value_vec = Vec::::deserialize(deserializer)?; Ok($t::from_owned(unsafe{ mem::transmute::, Vec>(send_value_vec) })) } } } ); impl_de_send_value_collection!(Array); impl_de_send_value_collection!(List); #[cfg(test)] mod tests { extern crate ron; extern crate serde_json; use Array; use Bitmask; use Fraction; use FractionRange; use IntRange; use List; #[test] fn test_serialize_simple() { ::init().unwrap(); let mut pretty_config = ron::ser::PrettyConfig::default(); pretty_config.new_line = "".to_string(); // Fraction let fraction = Fraction::new(1, 3); let res = ron::ser::to_string_pretty(&fraction, pretty_config.clone()); assert_eq!(Ok("(1, 3)".to_owned()), res); let res = serde_json::to_string(&fraction).unwrap(); assert_eq!("[1,3]".to_owned(), res); // FractionRange let fraction_range = FractionRange::new(Fraction::new(1, 3), Fraction::new(1, 2)); let res = ron::ser::to_string_pretty(&fraction_range, pretty_config.clone()); assert_eq!(Ok("( min: (1, 3), max: (1, 2),)".to_owned()), res); let res = serde_json::to_string(&fraction_range).unwrap(); assert_eq!("{\"min\":[1,3],\"max\":[1,2]}".to_owned(), res); // IntRange let int_range = IntRange::::new_with_step(0, 42, 21); let res = ron::ser::to_string_pretty(&int_range, pretty_config.clone()); assert_eq!(Ok("( min: 0, max: 42, step: 21,)".to_owned()), res,); let res = serde_json::to_string(&int_range).unwrap(); assert_eq!("{\"min\":0,\"max\":42,\"step\":21}".to_owned(), res); // Bitmask let bitmask = Bitmask::new(1024 + 128 + 32); let res = ron::ser::to_string_pretty(&bitmask, pretty_config.clone()); assert_eq!(Ok("(1184)".to_owned()), res); let res = serde_json::to_string(&bitmask).unwrap(); assert_eq!("1184".to_owned(), res); } #[test] fn test_serialize_collections() { use glib::value::ToValue; use Fraction; use List; ::init().unwrap(); let mut pretty_config = ron::ser::PrettyConfig::default(); pretty_config.new_line = "".to_string(); // Array let value_13 = Fraction::new(1, 3).to_value(); let send_value_13 = value_13.try_into_send_value::().unwrap(); let value_12 = Fraction::new(1, 2).to_value(); let send_value_12 = value_12.try_into_send_value::().unwrap(); let value_str = "test str".to_value(); let send_value_str = value_str.try_into_send_value::().unwrap(); let array = Array::new(&[&send_value_13, &send_value_12, &send_value_str]); let res = ron::ser::to_string_pretty(&array, pretty_config.clone()); assert_eq!( Ok(concat!( "[", " (\"Fraction\", (1, 3)),", " (\"Fraction\", (1, 2)),", " (\"String\", \"test str\"),", "]" ) .to_owned()), res, ); let res = serde_json::to_string(&array).unwrap(); assert_eq!( "[[\"Fraction\",[1,3]],[\"Fraction\",[1,2]],[\"String\",\"test str\"]]".to_owned(), res ); // List let value_12 = Fraction::new(1, 2).to_value(); let send_value_12 = value_12.try_into_send_value::().unwrap(); let value_str = "test str".to_value(); let send_value_str = value_str.try_into_send_value::().unwrap(); let list = List::new(&[&send_value_12, &send_value_str]); let res = ron::ser::to_string_pretty(&list, pretty_config.clone()); assert_eq!( Ok(concat!( "[", " (\"Fraction\", (1, 2)),", " (\"String\", \"test str\"),", "]" ) .to_owned()), res, ); } #[cfg(feature = "ser_de")] #[test] fn test_deserialize_simple() { ::init().unwrap(); // Fraction let fraction_ron = "(1, 3)"; let fraction: Fraction = ron::de::from_str(fraction_ron).unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &3); let fraction_json = "[1,3]"; let fraction: Fraction = serde_json::from_str(fraction_json).unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &3); // FractionRange let fraction_range_ron = "(min: (1, 3), max: (1, 2))"; let fraction_range: FractionRange = ron::de::from_str(fraction_range_ron).unwrap(); assert_eq!(fraction_range.min().0.denom(), &3); assert_eq!(fraction_range.max().0.denom(), &2); let fraction_range_json = "{\"min\":[1,3],\"max\":[1,2]}"; let fraction_range: FractionRange = serde_json::from_str(fraction_range_json).unwrap(); assert_eq!(fraction_range.min().0.denom(), &3); assert_eq!(fraction_range.max().0.denom(), &2); // IntRange let int_range_ron = "(min: 0, max: 42, step: 21)"; let int_range: IntRange = ron::de::from_str(int_range_ron).unwrap(); assert_eq!(int_range.min(), 0); assert_eq!(int_range.max(), 42); assert_eq!(int_range.step(), 21); let int_range_json = "{\"min\":0,\"max\":42,\"step\":21}"; let int_range: IntRange = serde_json::from_str(int_range_json).unwrap(); assert_eq!(int_range.min(), 0); assert_eq!(int_range.max(), 42); assert_eq!(int_range.step(), 21); // Bitmask let bitmask_ref = Bitmask::new(1024 + 128 + 32); let bitmask_ron = "(1184)"; let bitmask: Bitmask = ron::de::from_str(bitmask_ron).unwrap(); assert_eq!(bitmask_ref, bitmask); let bitmask_json = "1184"; let bitmask: Bitmask = serde_json::from_str(bitmask_json).unwrap(); assert_eq!(bitmask_ref, bitmask); } #[cfg(feature = "ser_de")] #[test] fn test_serde_roundtrip_simple() { ::init().unwrap(); // Fraction let fraction = Fraction::new(1, 3); let fraction_ser = ron::ser::to_string(&fraction).unwrap(); let fraction_de: Fraction = ron::de::from_str(fraction_ser.as_str()).unwrap(); assert_eq!(fraction_de.0.numer(), fraction.0.numer()); assert_eq!(fraction_de.0.denom(), fraction.0.denom()); // FractionRange let fraction_range = FractionRange::new(Fraction::new(1, 3), Fraction::new(1, 2)); let fraction_range_ser = ron::ser::to_string(&fraction_range).unwrap(); let fraction_range_de: FractionRange = ron::de::from_str(fraction_range_ser.as_str()).unwrap(); assert_eq!( fraction_range_de.min().0.denom(), fraction_range.min().0.denom() ); assert_eq!( fraction_range_de.max().0.denom(), fraction_range.max().0.denom() ); // IntRange let int_range = IntRange::::new_with_step(0, 42, 21); let int_range_ser = ron::ser::to_string(&int_range).unwrap(); let int_range_de: IntRange = ron::de::from_str(int_range_ser.as_str()).unwrap(); assert_eq!(int_range_de.min(), int_range.min()); assert_eq!(int_range_de.max(), int_range.max()); assert_eq!(int_range_de.step(), int_range.step()); // Bitmask let bitmask = Bitmask::new(1024 + 128 + 32); let bitmask_ser = ron::ser::to_string(&bitmask).unwrap(); let bitmask_de: Bitmask = ron::de::from_str(bitmask_ser.as_str()).unwrap(); assert_eq!(bitmask_de, bitmask); } #[cfg(feature = "ser_de")] #[test] fn test_deserialize_collections() { ::init().unwrap(); // Array let array_ron = r#"[ ("Fraction", (1, 3)), ("Fraction", (1, 2)), ("String", "test str"), ]"#; let array: Array = ron::de::from_str(array_ron).unwrap(); let slice = array.as_slice(); assert_eq!(3, slice.len()); let fraction = slice[0].get::().unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &3); let fraction = slice[1].get::().unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &2); assert_eq!("test str".to_owned(), slice[2].get::().unwrap()); let array_json = r#"[["Fraction",[1,3]],["Fraction",[1,2]],["String","test str"]]"#; let array: Array = serde_json::from_str(array_json).unwrap(); let slice = array.as_slice(); assert_eq!(3, slice.len()); let fraction = slice[0].get::().unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &3); let fraction = slice[1].get::().unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &2); assert_eq!("test str".to_owned(), slice[2].get::().unwrap()); // List let list_ron = r#"[ ("Fraction", (1, 2)), ("String", "test str"), ]"#; let list: List = ron::de::from_str(list_ron).unwrap(); let slice = list.as_slice(); assert_eq!(2, slice.len()); let fraction = slice[0].get::().unwrap(); assert_eq!(fraction.0.numer(), &1); assert_eq!(fraction.0.denom(), &2); assert_eq!("test str".to_owned(), slice[1].get::().unwrap()); } #[cfg(feature = "ser_de")] #[test] fn test_serde_roundtrip_collection() { use glib::value::ToValue; ::init().unwrap(); // Array let value_13 = Fraction::new(1, 3).to_value(); let send_value_13 = value_13.try_into_send_value::().unwrap(); let value_12 = Fraction::new(1, 2).to_value(); let send_value_12 = value_12.try_into_send_value::().unwrap(); let value_str = "test str".to_value(); let send_value_str = value_str.try_into_send_value::().unwrap(); let array = Array::new(&[&send_value_13, &send_value_12, &send_value_str]); let array_ser = ron::ser::to_string(&array).unwrap(); let array_de: Array = ron::de::from_str(array_ser.as_str()).unwrap(); let slice_de = array_de.as_slice(); let slice = array.as_slice(); assert_eq!(slice_de.len(), slice.len()); let fraction_de = slice_de[0].get::().unwrap(); let fraction = slice[0].get::().unwrap(); assert_eq!(fraction_de.0.numer(), fraction.0.numer()); assert_eq!(fraction_de.0.denom(), fraction.0.denom()); let fraction_de = slice_de[1].get::().unwrap(); let fraction = slice[1].get::().unwrap(); assert_eq!(fraction_de.0.numer(), fraction.0.numer()); assert_eq!(fraction.0.denom(), fraction.0.denom()); assert_eq!( slice_de[2].get::().unwrap(), slice[2].get::().unwrap() ); // List let value_12 = Fraction::new(1, 2).to_value(); let send_value_12 = value_12.try_into_send_value::().unwrap(); let value_str = "test str".to_value(); let send_value_str = value_str.try_into_send_value::().unwrap(); let list = List::new(&[&send_value_12, &send_value_str]); let list_ser = ron::ser::to_string(&list).unwrap(); let list_de: List = ron::de::from_str(list_ser.as_str()).unwrap(); let slice_de = list_de.as_slice(); let slice = list.as_slice(); assert_eq!(slice_de.len(), slice.len()); let fraction_de = slice_de[0].get::().unwrap(); let fraction = slice[0].get::().unwrap(); assert_eq!(fraction_de.0.numer(), fraction.0.numer()); assert_eq!(fraction_de.0.denom(), fraction.0.denom()); assert_eq!( slice_de[1].get::().unwrap(), slice[1].get::().unwrap() ); } }