// Copyright 2017 Serde Developers // // 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. #![cfg_attr(feature = "unstable", feature(never_type))] #[macro_use] extern crate serde_derive; use std::cell::RefCell; use std::collections::{BTreeMap, BTreeSet, HashMap, HashSet}; use std::ffi::CString; use std::mem; use std::net; use std::num::Wrapping; use std::path::{Path, PathBuf}; use std::rc::{Rc, Weak as RcWeak}; use std::sync::{Arc, Weak as ArcWeak}; use std::time::{Duration, UNIX_EPOCH}; #[cfg(unix)] use std::str; extern crate serde_test; use self::serde_test::{assert_ser_tokens, assert_ser_tokens_error, Configure, Token}; extern crate fnv; use self::fnv::FnvHasher; #[macro_use] mod macros; ////////////////////////////////////////////////////////////////////////// #[derive(Serialize)] struct UnitStruct; #[derive(Serialize)] struct TupleStruct(i32, i32, i32); #[derive(Serialize)] struct Struct { a: i32, b: i32, c: i32, } #[derive(Serialize, PartialEq, Debug)] enum Enum { Unit, One(i32), Seq(i32, i32), Map { a: i32, b: i32, }, #[serde(skip_serializing)] SkippedUnit, #[serde(skip_serializing)] SkippedOne(i32), #[serde(skip_serializing)] SkippedSeq(i32, i32), #[serde(skip_serializing)] SkippedMap { _a: i32, _b: i32, }, } ////////////////////////////////////////////////////////////////////////// macro_rules! declare_tests { ( $readable:tt $($name:ident { $($value:expr => $tokens:expr,)+ })+ ) => { $( #[test] fn $name() { $( assert_ser_tokens(&$value.$readable(), $tokens); )+ } )+ }; ($($name:ident { $($value:expr => $tokens:expr,)+ })+) => { $( #[test] fn $name() { $( assert_ser_tokens(&$value, $tokens); )+ } )+ } } declare_tests! { test_unit { () => &[Token::Unit], } test_bool { true => &[Token::Bool(true)], false => &[Token::Bool(false)], } test_isizes { 0i8 => &[Token::I8(0)], 0i16 => &[Token::I16(0)], 0i32 => &[Token::I32(0)], 0i64 => &[Token::I64(0)], } test_usizes { 0u8 => &[Token::U8(0)], 0u16 => &[Token::U16(0)], 0u32 => &[Token::U32(0)], 0u64 => &[Token::U64(0)], } test_floats { 0f32 => &[Token::F32(0.)], 0f64 => &[Token::F64(0.)], } test_char { 'a' => &[Token::Char('a')], } test_str { "abc" => &[Token::Str("abc")], "abc".to_owned() => &[Token::Str("abc")], } test_option { None:: => &[Token::None], Some(1) => &[ Token::Some, Token::I32(1), ], } test_result { Ok::(0) => &[ Token::NewtypeVariant { name: "Result", variant: "Ok" }, Token::I32(0), ], Err::(1) => &[ Token::NewtypeVariant { name: "Result", variant: "Err" }, Token::I32(1), ], } test_slice { &[0][..0] => &[ Token::Seq { len: Some(0) }, Token::SeqEnd, ], &[1, 2, 3][..] => &[ Token::Seq { len: Some(3) }, Token::I32(1), Token::I32(2), Token::I32(3), Token::SeqEnd, ], } test_array { [0; 0] => &[ Token::Tuple { len: 0 }, Token::TupleEnd, ], [1, 2, 3] => &[ Token::Tuple { len: 3 }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleEnd, ], } test_vec { Vec::::new() => &[ Token::Seq { len: Some(0) }, Token::SeqEnd, ], vec![vec![], vec![1], vec![2, 3]] => &[ Token::Seq { len: Some(3) }, Token::Seq { len: Some(0) }, Token::SeqEnd, Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd, Token::Seq { len: Some(2) }, Token::I32(2), Token::I32(3), Token::SeqEnd, Token::SeqEnd, ], } test_btreeset { BTreeSet::::new() => &[ Token::Seq { len: Some(0) }, Token::SeqEnd, ], btreeset![1] => &[ Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd, ], } test_hashset { HashSet::::new() => &[ Token::Seq { len: Some(0) }, Token::SeqEnd, ], hashset![1] => &[ Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd, ], hashset![FnvHasher @ 1] => &[ Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd, ], } test_tuple { (1,) => &[ Token::Tuple { len: 1 }, Token::I32(1), Token::TupleEnd, ], (1, 2, 3) => &[ Token::Tuple { len: 3 }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleEnd, ], } test_btreemap { btreemap![1 => 2] => &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], btreemap![1 => 2, 3 => 4] => &[ Token::Map { len: Some(2) }, Token::I32(1), Token::I32(2), Token::I32(3), Token::I32(4), Token::MapEnd, ], btreemap![1 => btreemap![], 2 => btreemap![3 => 4, 5 => 6]] => &[ Token::Map { len: Some(2) }, Token::I32(1), Token::Map { len: Some(0) }, Token::MapEnd, Token::I32(2), Token::Map { len: Some(2) }, Token::I32(3), Token::I32(4), Token::I32(5), Token::I32(6), Token::MapEnd, Token::MapEnd, ], } test_hashmap { HashMap::::new() => &[ Token::Map { len: Some(0) }, Token::MapEnd, ], hashmap![1 => 2] => &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], hashmap![FnvHasher @ 1 => 2] => &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], } test_unit_struct { UnitStruct => &[Token::UnitStruct { name: "UnitStruct" }], } test_tuple_struct { TupleStruct(1, 2, 3) => &[ Token::TupleStruct { name: "TupleStruct", len: 3 }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleStructEnd, ], } test_struct { Struct { a: 1, b: 2, c: 3 } => &[ Token::Struct { name: "Struct", len: 3 }, Token::Str("a"), Token::I32(1), Token::Str("b"), Token::I32(2), Token::Str("c"), Token::I32(3), Token::StructEnd, ], } test_enum { Enum::Unit => &[Token::UnitVariant { name: "Enum", variant: "Unit" }], Enum::One(42) => &[Token::NewtypeVariant { name: "Enum", variant: "One" }, Token::I32(42)], Enum::Seq(1, 2) => &[ Token::TupleVariant { name: "Enum", variant: "Seq", len: 2 }, Token::I32(1), Token::I32(2), Token::TupleVariantEnd, ], Enum::Map { a: 1, b: 2 } => &[ Token::StructVariant { name: "Enum", variant: "Map", len: 2 }, Token::Str("a"), Token::I32(1), Token::Str("b"), Token::I32(2), Token::StructVariantEnd, ], } test_box { Box::new(0i32) => &[Token::I32(0)], } test_boxed_slice { Box::new([0, 1, 2]) => &[ Token::Tuple { len: 3 }, Token::I32(0), Token::I32(1), Token::I32(2), Token::TupleEnd, ], } test_duration { Duration::new(1, 2) => &[ Token::Struct { name: "Duration", len: 2 }, Token::Str("secs"), Token::U64(1), Token::Str("nanos"), Token::U32(2), Token::StructEnd, ], } test_system_time { UNIX_EPOCH + Duration::new(1, 200) => &[ Token::Struct { name: "SystemTime", len: 2 }, Token::Str("secs_since_epoch"), Token::U64(1), Token::Str("nanos_since_epoch"), Token::U32(200), Token::StructEnd, ], } test_range { 1u32..2u32 => &[ Token::Struct { name: "Range", len: 2 }, Token::Str("start"), Token::U32(1), Token::Str("end"), Token::U32(2), Token::StructEnd, ], } test_range_inclusive { 1u32..=2u32 => &[ Token::Struct { name: "RangeInclusive", len: 2 }, Token::Str("start"), Token::U32(1), Token::Str("end"), Token::U32(2), Token::StructEnd, ], } test_path { Path::new("/usr/local/lib") => &[ Token::Str("/usr/local/lib"), ], } test_path_buf { PathBuf::from("/usr/local/lib") => &[ Token::Str("/usr/local/lib"), ], } test_cstring { CString::new("abc").unwrap() => &[ Token::Bytes(b"abc"), ], } test_cstr { (&*CString::new("abc").unwrap()) => &[ Token::Bytes(b"abc"), ], } test_rc { Rc::new(true) => &[ Token::Bool(true), ], } test_rc_weak_some { { let rc = Rc::new(true); mem::forget(rc.clone()); Rc::downgrade(&rc) } => &[ Token::Some, Token::Bool(true), ], } test_rc_weak_none { RcWeak::::new() => &[ Token::None, ], } test_arc { Arc::new(true) => &[ Token::Bool(true), ], } test_arc_weak_some { { let arc = Arc::new(true); mem::forget(arc.clone()); Arc::downgrade(&arc) } => &[ Token::Some, Token::Bool(true), ], } test_arc_weak_none { ArcWeak::::new() => &[ Token::None, ], } test_wrapping { Wrapping(1usize) => &[ Token::U64(1), ], } test_rc_dst { Rc::::from("s") => &[ Token::Str("s"), ], Rc::<[bool]>::from(&[true][..]) => &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], } test_arc_dst { Arc::::from("s") => &[ Token::Str("s"), ], Arc::<[bool]>::from(&[true][..]) => &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], } test_fmt_arguments { format_args!("{}{}", 1, 'a') => &[ Token::Str("1a"), ], } } declare_tests! { readable test_net_ipv4addr_readable { "1.2.3.4".parse::().unwrap() => &[Token::Str("1.2.3.4")], } test_net_ipv6addr_readable { "::1".parse::().unwrap() => &[Token::Str("::1")], } test_net_ipaddr_readable { "1.2.3.4".parse::().unwrap() => &[Token::Str("1.2.3.4")], } test_net_socketaddr_readable { "1.2.3.4:1234".parse::().unwrap() => &[Token::Str("1.2.3.4:1234")], "1.2.3.4:1234".parse::().unwrap() => &[Token::Str("1.2.3.4:1234")], "[::1]:1234".parse::().unwrap() => &[Token::Str("[::1]:1234")], } } declare_tests! { compact test_net_ipv4addr_compact { net::Ipv4Addr::from(*b"1234") => &seq![ Token::Tuple { len: 4 }, seq b"1234".iter().map(|&b| Token::U8(b)), Token::TupleEnd, ], } test_net_ipv6addr_compact { net::Ipv6Addr::from(*b"1234567890123456") => &seq![ Token::Tuple { len: 16 }, seq b"1234567890123456".iter().map(|&b| Token::U8(b)), Token::TupleEnd, ], } test_net_ipaddr_compact { net::IpAddr::from(*b"1234") => &seq![ Token::NewtypeVariant { name: "IpAddr", variant: "V4" }, Token::Tuple { len: 4 }, seq b"1234".iter().map(|&b| Token::U8(b)), Token::TupleEnd, ], } test_net_socketaddr_compact { net::SocketAddr::from((*b"1234567890123456", 1234)) => &seq![ Token::NewtypeVariant { name: "SocketAddr", variant: "V6" }, Token::Tuple { len: 2 }, Token::Tuple { len: 16 }, seq b"1234567890123456".iter().map(|&b| Token::U8(b)), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], net::SocketAddrV4::new(net::Ipv4Addr::from(*b"1234"), 1234) => &seq![ Token::Tuple { len: 2 }, Token::Tuple { len: 4 }, seq b"1234".iter().map(|&b| Token::U8(b)), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], net::SocketAddrV6::new(net::Ipv6Addr::from(*b"1234567890123456"), 1234, 0, 0) => &seq![ Token::Tuple { len: 2 }, Token::Tuple { len: 16 }, seq b"1234567890123456".iter().map(|&b| Token::U8(b)), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], } } #[cfg(feature = "unstable")] declare_tests! { test_never_result { Ok::(0) => &[ Token::NewtypeVariant { name: "Result", variant: "Ok" }, Token::U8(0), ], } } #[test] #[cfg(unix)] fn test_cannot_serialize_paths() { let path = unsafe { str::from_utf8_unchecked(b"Hello \xF0\x90\x80World") }; assert_ser_tokens_error( &Path::new(path), &[], "path contains invalid UTF-8 characters", ); let mut path_buf = PathBuf::new(); path_buf.push(path); assert_ser_tokens_error(&path_buf, &[], "path contains invalid UTF-8 characters"); } #[test] fn test_cannot_serialize_mutably_borrowed_ref_cell() { let ref_cell = RefCell::new(42); let _reference = ref_cell.borrow_mut(); assert_ser_tokens_error(&ref_cell, &[], "already mutably borrowed"); } #[test] fn test_enum_skipped() { assert_ser_tokens_error( &Enum::SkippedUnit, &[], "the enum variant Enum::SkippedUnit cannot be serialized", ); assert_ser_tokens_error( &Enum::SkippedOne(42), &[], "the enum variant Enum::SkippedOne cannot be serialized", ); assert_ser_tokens_error( &Enum::SkippedSeq(1, 2), &[], "the enum variant Enum::SkippedSeq cannot be serialized", ); assert_ser_tokens_error( &Enum::SkippedMap { _a: 1, _b: 2 }, &[], "the enum variant Enum::SkippedMap cannot be serialized", ); } #[test] fn test_integer128() { assert_ser_tokens_error(&1i128, &[], "i128 is not supported"); assert_ser_tokens_error(&1u128, &[], "u128 is not supported"); }