#![allow(clippy::derive_partial_eq_without_eq, clippy::unreadable_literal)] #![cfg_attr(feature = "unstable", feature(never_type))] use fnv::FnvHasher; use serde_derive::Serialize; use serde_test::{assert_ser_tokens, assert_ser_tokens_error, Configure, Token}; use std::cell::RefCell; use std::collections::{BTreeMap, BTreeSet, HashMap, HashSet}; use std::ffi::CString; use std::net; use std::num::Wrapping; use std::ops::Bound; use std::path::{Path, PathBuf}; use std::rc::{Rc, Weak as RcWeak}; #[cfg(unix)] use std::str; use std::sync::atomic::{ AtomicBool, AtomicI16, AtomicI32, AtomicI8, AtomicIsize, AtomicU16, AtomicU32, AtomicU8, AtomicUsize, }; #[cfg(target_arch = "x86_64")] use std::sync::atomic::{AtomicI64, AtomicU64}; use std::sync::{Arc, Mutex, RwLock, Weak as ArcWeak}; use std::time::{Duration, UNIX_EPOCH}; #[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(PartialEq, Debug)] struct NotSerializable; #[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, }, OneWithSkipped(#[serde(skip_serializing)] NotSerializable), } ////////////////////////////////////////////////////////////////////////// #[test] fn test_unit() { assert_ser_tokens(&(), &[Token::Unit]); } #[test] fn test_bool() { assert_ser_tokens(&true, &[Token::Bool(true)]); assert_ser_tokens(&false, &[Token::Bool(false)]); } #[test] fn test_isizes() { assert_ser_tokens(&0i8, &[Token::I8(0)]); assert_ser_tokens(&0i16, &[Token::I16(0)]); assert_ser_tokens(&0i32, &[Token::I32(0)]); assert_ser_tokens(&0i64, &[Token::I64(0)]); } #[test] fn test_usizes() { assert_ser_tokens(&0u8, &[Token::U8(0)]); assert_ser_tokens(&0u16, &[Token::U16(0)]); assert_ser_tokens(&0u32, &[Token::U32(0)]); assert_ser_tokens(&0u64, &[Token::U64(0)]); } #[test] fn test_floats() { assert_ser_tokens(&0f32, &[Token::F32(0.)]); assert_ser_tokens(&0f64, &[Token::F64(0.)]); } #[test] fn test_char() { assert_ser_tokens(&'a', &[Token::Char('a')]); } #[test] fn test_str() { assert_ser_tokens(&"abc", &[Token::Str("abc")]); assert_ser_tokens(&"abc".to_owned(), &[Token::Str("abc")]); } #[test] fn test_option() { assert_ser_tokens(&None::, &[Token::None]); assert_ser_tokens(&Some(1), &[Token::Some, Token::I32(1)]); } #[test] fn test_result() { assert_ser_tokens( &Ok::(0), &[ Token::NewtypeVariant { name: "Result", variant: "Ok", }, Token::I32(0), ], ); assert_ser_tokens( &Err::(1), &[ Token::NewtypeVariant { name: "Result", variant: "Err", }, Token::I32(1), ], ); } #[test] fn test_slice() { assert_ser_tokens(&[0][..0], &[Token::Seq { len: Some(0) }, Token::SeqEnd]); assert_ser_tokens( &[1, 2, 3][..], &[ Token::Seq { len: Some(3) }, Token::I32(1), Token::I32(2), Token::I32(3), Token::SeqEnd, ], ); } #[test] fn test_array() { assert_ser_tokens(&[0; 0], &[Token::Tuple { len: 0 }, Token::TupleEnd]); assert_ser_tokens( &[1, 2, 3], &[ Token::Tuple { len: 3 }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleEnd, ], ); } #[test] fn test_vec() { assert_ser_tokens( &Vec::::new(), &[Token::Seq { len: Some(0) }, Token::SeqEnd], ); assert_ser_tokens( &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] fn test_btreeset() { assert_ser_tokens( &BTreeSet::::new(), &[Token::Seq { len: Some(0) }, Token::SeqEnd], ); assert_ser_tokens( &btreeset![1], &[Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd], ); } #[test] fn test_hashset() { assert_ser_tokens( &HashSet::::new(), &[Token::Seq { len: Some(0) }, Token::SeqEnd], ); assert_ser_tokens( &hashset![1], &[Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd], ); assert_ser_tokens( &hashset![FnvHasher @ 1], &[Token::Seq { len: Some(1) }, Token::I32(1), Token::SeqEnd], ); } #[test] fn test_tuple() { assert_ser_tokens( &(1,), &[Token::Tuple { len: 1 }, Token::I32(1), Token::TupleEnd], ); assert_ser_tokens( &(1, 2, 3), &[ Token::Tuple { len: 3 }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleEnd, ], ); } #[test] fn test_btreemap() { assert_ser_tokens( &btreemap![1 => 2], &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], ); assert_ser_tokens( &btreemap![1 => 2, 3 => 4], &[ Token::Map { len: Some(2) }, Token::I32(1), Token::I32(2), Token::I32(3), Token::I32(4), Token::MapEnd, ], ); assert_ser_tokens( &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] fn test_hashmap() { assert_ser_tokens( &HashMap::::new(), &[Token::Map { len: Some(0) }, Token::MapEnd], ); assert_ser_tokens( &hashmap![1 => 2], &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], ); assert_ser_tokens( &hashmap![FnvHasher @ 1 => 2], &[ Token::Map { len: Some(1) }, Token::I32(1), Token::I32(2), Token::MapEnd, ], ); } #[test] fn test_unit_struct() { assert_ser_tokens(&UnitStruct, &[Token::UnitStruct { name: "UnitStruct" }]); } #[test] fn test_tuple_struct() { assert_ser_tokens( &TupleStruct(1, 2, 3), &[ Token::TupleStruct { name: "TupleStruct", len: 3, }, Token::I32(1), Token::I32(2), Token::I32(3), Token::TupleStructEnd, ], ); } #[test] fn test_struct() { assert_ser_tokens( &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] fn test_enum() { assert_ser_tokens( &Enum::Unit, &[Token::UnitVariant { name: "Enum", variant: "Unit", }], ); assert_ser_tokens( &Enum::One(42), &[ Token::NewtypeVariant { name: "Enum", variant: "One", }, Token::I32(42), ], ); assert_ser_tokens( &Enum::Seq(1, 2), &[ Token::TupleVariant { name: "Enum", variant: "Seq", len: 2, }, Token::I32(1), Token::I32(2), Token::TupleVariantEnd, ], ); assert_ser_tokens( &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, ], ); assert_ser_tokens( &Enum::OneWithSkipped(NotSerializable), &[Token::UnitVariant { name: "Enum", variant: "OneWithSkipped", }], ); } #[test] fn test_box() { assert_ser_tokens(&Box::new(0i32), &[Token::I32(0)]); } #[test] fn test_boxed_slice() { assert_ser_tokens( &Box::new([0, 1, 2]), &[ Token::Tuple { len: 3 }, Token::I32(0), Token::I32(1), Token::I32(2), Token::TupleEnd, ], ); } #[test] fn test_duration() { assert_ser_tokens( &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] fn test_system_time() { let system_time = UNIX_EPOCH + Duration::new(1, 200); assert_ser_tokens( &system_time, &[ 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] fn test_range() { assert_ser_tokens( &(1u32..2u32), &[ Token::Struct { name: "Range", len: 2, }, Token::Str("start"), Token::U32(1), Token::Str("end"), Token::U32(2), Token::StructEnd, ], ); } #[test] fn test_range_inclusive() { assert_ser_tokens( &(1u32..=2u32), &[ Token::Struct { name: "RangeInclusive", len: 2, }, Token::Str("start"), Token::U32(1), Token::Str("end"), Token::U32(2), Token::StructEnd, ], ); } #[test] fn test_bound() { assert_ser_tokens( &Bound::Unbounded::<()>, &[ Token::Enum { name: "Bound" }, Token::Str("Unbounded"), Token::Unit, ], ); assert_ser_tokens( &Bound::Included(0u8), &[ Token::Enum { name: "Bound" }, Token::Str("Included"), Token::U8(0), ], ); assert_ser_tokens( &Bound::Excluded(0u8), &[ Token::Enum { name: "Bound" }, Token::Str("Excluded"), Token::U8(0), ], ); } #[test] fn test_path() { assert_ser_tokens( &Path::new("/usr/local/lib"), &[Token::Str("/usr/local/lib")], ); } #[test] fn test_path_buf() { assert_ser_tokens( &PathBuf::from("/usr/local/lib"), &[Token::Str("/usr/local/lib")], ); } #[test] fn test_cstring() { assert_ser_tokens(&CString::new("abc").unwrap(), &[Token::Bytes(b"abc")]); } #[test] fn test_cstr() { let cstring = CString::new("abc").unwrap(); assert_ser_tokens(cstring.as_c_str(), &[Token::Bytes(b"abc")]); } #[test] fn test_rc() { assert_ser_tokens(&Rc::new(true), &[Token::Bool(true)]); } #[test] fn test_rc_weak_some() { let rc = Rc::new(true); assert_ser_tokens(&Rc::downgrade(&rc), &[Token::Some, Token::Bool(true)]); } #[test] fn test_rc_weak_none() { assert_ser_tokens(&RcWeak::::new(), &[Token::None]); } #[test] fn test_arc() { assert_ser_tokens(&Arc::new(true), &[Token::Bool(true)]); } #[test] fn test_arc_weak_some() { let arc = Arc::new(true); assert_ser_tokens(&Arc::downgrade(&arc), &[Token::Some, Token::Bool(true)]); } #[test] fn test_arc_weak_none() { assert_ser_tokens(&ArcWeak::::new(), &[Token::None]); } #[test] fn test_wrapping() { assert_ser_tokens(&Wrapping(1usize), &[Token::U64(1)]); } #[test] fn test_rc_dst() { assert_ser_tokens(&Rc::::from("s"), &[Token::Str("s")]); assert_ser_tokens( &Rc::<[bool]>::from(&[true][..]), &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], ); } #[test] fn test_arc_dst() { assert_ser_tokens(&Arc::::from("s"), &[Token::Str("s")]); assert_ser_tokens( &Arc::<[bool]>::from(&[true][..]), &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], ); } #[test] fn test_fmt_arguments() { assert_ser_tokens(&format_args!("{}{}", 1, 'a'), &[Token::Str("1a")]); } #[test] fn test_atomic() { assert_ser_tokens(&AtomicBool::new(false), &[Token::Bool(false)]); assert_ser_tokens(&AtomicBool::new(true), &[Token::Bool(true)]); assert_ser_tokens(&AtomicI8::new(63i8), &[Token::I8(63i8)]); assert_ser_tokens(&AtomicI16::new(-318i16), &[Token::I16(-318i16)]); assert_ser_tokens(&AtomicI32::new(65792i32), &[Token::I32(65792i32)]); assert_ser_tokens(&AtomicIsize::new(-65792isize), &[Token::I64(-65792i64)]); assert_ser_tokens(&AtomicU8::new(192u8), &[Token::U8(192u8)]); assert_ser_tokens(&AtomicU16::new(510u16), &[Token::U16(510u16)]); assert_ser_tokens(&AtomicU32::new(131072u32), &[Token::U32(131072u32)]); assert_ser_tokens(&AtomicUsize::new(655360usize), &[Token::U64(655360u64)]); } #[cfg(target_arch = "x86_64")] #[test] fn test_atomic64() { assert_ser_tokens( &AtomicI64::new(-4295032832i64), &[Token::I64(-4295032832i64)], ); assert_ser_tokens( &AtomicU64::new(12884901888u64), &[Token::U64(12884901888u64)], ); } #[test] fn test_net_ipv4addr_readable() { assert_ser_tokens( &"1.2.3.4".parse::().unwrap().readable(), &[Token::Str("1.2.3.4")], ); } #[test] fn test_net_ipv6addr_readable() { assert_ser_tokens( &"::1".parse::().unwrap().readable(), &[Token::Str("::1")], ); } #[test] fn test_net_ipaddr_readable() { assert_ser_tokens( &"1.2.3.4".parse::().unwrap().readable(), &[Token::Str("1.2.3.4")], ); } #[test] fn test_net_socketaddr_readable() { assert_ser_tokens( &"1.2.3.4:1234" .parse::() .unwrap() .readable(), &[Token::Str("1.2.3.4:1234")], ); assert_ser_tokens( &"1.2.3.4:1234" .parse::() .unwrap() .readable(), &[Token::Str("1.2.3.4:1234")], ); assert_ser_tokens( &"[::1]:1234" .parse::() .unwrap() .readable(), &[Token::Str("[::1]:1234")], ); } #[test] fn test_net_ipv4addr_compact() { assert_ser_tokens( &net::Ipv4Addr::from(*b"1234").compact(), &seq![ Token::Tuple { len: 4 }, b"1234".iter().copied().map(Token::U8), Token::TupleEnd, ], ); } #[test] fn test_net_ipv6addr_compact() { assert_ser_tokens( &net::Ipv6Addr::from(*b"1234567890123456").compact(), &seq![ Token::Tuple { len: 16 }, b"1234567890123456".iter().copied().map(Token::U8), Token::TupleEnd, ], ); } #[test] fn test_net_ipaddr_compact() { assert_ser_tokens( &net::IpAddr::from(*b"1234").compact(), &seq![ Token::NewtypeVariant { name: "IpAddr", variant: "V4" }, Token::Tuple { len: 4 }, b"1234".iter().copied().map(Token::U8), Token::TupleEnd, ], ); } #[test] fn test_net_socketaddr_compact() { assert_ser_tokens( &net::SocketAddr::from((*b"1234567890123456", 1234)).compact(), &seq![ Token::NewtypeVariant { name: "SocketAddr", variant: "V6" }, Token::Tuple { len: 2 }, Token::Tuple { len: 16 }, b"1234567890123456".iter().copied().map(Token::U8), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], ); assert_ser_tokens( &net::SocketAddrV4::new(net::Ipv4Addr::from(*b"1234"), 1234).compact(), &seq![ Token::Tuple { len: 2 }, Token::Tuple { len: 4 }, b"1234".iter().copied().map(Token::U8), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], ); assert_ser_tokens( &net::SocketAddrV6::new(net::Ipv6Addr::from(*b"1234567890123456"), 1234, 0, 0).compact(), &seq![ Token::Tuple { len: 2 }, Token::Tuple { len: 16 }, b"1234567890123456".iter().copied().map(Token::U8), Token::TupleEnd, Token::U16(1234), Token::TupleEnd, ], ); } #[cfg(feature = "unstable")] #[test] fn test_never_result() { assert_ser_tokens( &Ok::(0), &[ Token::NewtypeVariant { name: "Result", variant: "Ok", }, Token::U8(0), ], ); } #[test] #[cfg(unix)] fn test_cannot_serialize_paths() { use std::ffi::OsStr; use std::os::unix::ffi::OsStrExt; assert_ser_tokens_error( &Path::new(OsStr::from_bytes(b"Hello \xF0\x90\x80World")), &[], "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"); } #[test] fn test_refcell_dst() { assert_ser_tokens( &RefCell::new([true]) as &RefCell<[bool]>, &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], ); } #[test] fn test_mutex_dst() { assert_ser_tokens( &Mutex::new([true]) as &Mutex<[bool]>, &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], ); } #[test] fn test_rwlock_dst() { assert_ser_tokens( &RwLock::new([true]) as &RwLock<[bool]>, &[ Token::Seq { len: Some(1) }, Token::Bool(true), Token::SeqEnd, ], ); }