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// This file is part of ICU4X. For terms of use, please see the file
// called LICENSE at the top level of the ICU4X source tree
// (online at: https://github.com/unicode-org/icu4x/blob/main/LICENSE ).
use zerovec::ule::AsULE;
use zerovec::ule::EncodeAsVarULE;
use zerovec::*;
#[repr(packed)]
#[derive(ule::ULE, Copy, Clone)]
pub struct FooULE {
a: u8,
b: <u32 as AsULE>::ULE,
c: <char as AsULE>::ULE,
}
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
struct Foo {
a: u8,
b: u32,
c: char,
}
impl AsULE for Foo {
type ULE = FooULE;
fn to_unaligned(self) -> FooULE {
FooULE {
a: self.a,
b: self.b.to_unaligned(),
c: self.c.to_unaligned(),
}
}
fn from_unaligned(other: FooULE) -> Self {
Self {
a: other.a,
b: AsULE::from_unaligned(other.b),
c: AsULE::from_unaligned(other.c),
}
}
}
#[repr(packed)]
#[derive(ule::VarULE)]
pub struct RelationULE {
/// This maps to (AndOr, Polarity, Operand),
/// with the first bit mapping to AndOr (1 == And), the second bit
/// to Polarity (1 == Positive), and the remaining bits to Operand
/// encoded via Operand::encode. It is unsound for the Operand bits to
/// not be a valid encoded Operand.
andor_polarity_operand: u8,
modulo: <u32 as AsULE>::ULE,
range_list: ZeroSlice<Foo>,
}
#[derive(Clone, PartialEq, Debug)]
pub struct Relation<'a> {
andor_polarity_operand: u8,
modulo: u32,
range_list: ZeroVec<'a, Foo>,
}
unsafe impl EncodeAsVarULE<RelationULE> for Relation<'_> {
fn encode_var_ule_as_slices<R>(&self, cb: impl FnOnce(&[&[u8]]) -> R) -> R {
cb(&[
&[self.andor_polarity_operand],
ule::ULE::as_byte_slice(&[self.modulo.to_unaligned()]),
self.range_list.as_bytes(),
])
}
}
impl RelationULE {
pub fn as_relation(&self) -> Relation {
Relation {
andor_polarity_operand: self.andor_polarity_operand,
modulo: u32::from_unaligned(self.modulo),
range_list: self.range_list.as_zerovec(),
}
}
}
const TEST_SLICE: &[Foo] = &[
Foo {
a: 101,
b: 924,
c: '⸘',
},
Foo {
a: 217,
b: 4228,
c: 'ə',
},
Foo {
a: 117,
b: 9090,
c: 'ø',
},
];
const TEST_SLICE2: &[Foo] = &[
Foo {
a: 92,
b: 4,
c: 'å',
},
Foo {
a: 9,
b: 49993,
c: '±',
},
];
fn test_zerovec() {
let zerovec: ZeroVec<Foo> = TEST_SLICE.iter().copied().collect();
assert_eq!(zerovec, TEST_SLICE);
let bytes = zerovec.as_bytes();
let reparsed: ZeroVec<Foo> = ZeroVec::parse_byte_slice(bytes).expect("Parsing should succeed");
assert_eq!(reparsed, TEST_SLICE);
}
fn test_varzerovec() {
let relation1 = Relation {
andor_polarity_operand: 1,
modulo: 5004,
range_list: TEST_SLICE.iter().copied().collect(),
};
let relation2 = Relation {
andor_polarity_operand: 5,
modulo: 909,
range_list: TEST_SLICE2.iter().copied().collect(),
};
let relations = &[relation1, relation2];
let vzv = VarZeroVec::<_>::from(relations);
for (ule, stack) in vzv.iter().zip(relations.iter()) {
assert_eq!(*stack, ule.as_relation());
}
let bytes = vzv.as_bytes();
let recovered: VarZeroVec<RelationULE> =
VarZeroVec::parse_byte_slice(bytes).expect("Parsing should succeed");
for (ule, stack) in recovered.iter().zip(relations.iter()) {
assert_eq!(*stack, ule.as_relation());
}
}
fn main() {
test_zerovec();
test_varzerovec();
}
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