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Spracherkennung für: .rs vermutete Sprache: Unknown {[0] [0] [0]} [Methode: Schwerpunktbildung, einfache Gewichte, sechs Dimensionen] // Copyright 2016-2017 The Servo Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! A reduced fork of Firefox's malloc_size_of crate, for bundling with WebRender. extern crate app_units; extern crate euclid; use std::hash::{BuildHasher, Hash}; use std::mem::size_of; use std::ops::Range; use std::os::raw::c_void; use std::path::PathBuf; /// A C function that takes a pointer to a heap allocation and returns its size. type VoidPtrToSizeFn = unsafe extern "C" fn(ptr: *const c_void) -> usize; /// Operations used when measuring heap usage of data structures. pub struct MallocSizeOfOps { /// A function that returns the size of a heap allocation. pub size_of_op: VoidPtrToSizeFn, /// Like `size_of_op`, but can take an interior pointer. Optional because /// not all allocators support this operation. If it's not provided, some /// memory measurements will actually be computed estimates rather than /// real and accurate measurements. pub enclosing_size_of_op: Option<VoidPtrToSizeFn>, } impl MallocSizeOfOps { pub fn new( size_of: VoidPtrToSizeFn, malloc_enclosing_size_of: Option<VoidPtrToSizeFn>, ) -> Self { MallocSizeOfOps { size_of_op: size_of, enclosing_size_of_op: malloc_enclosing_size_of, } } /// Check if an allocation is empty. This relies on knowledge of how Rust /// handles empty allocations, which may change in the future. fn is_empty<T: ?Sized>(ptr: *const T) -> bool { // The correct condition is this: // `ptr as usize <= ::std::mem::align_of::<T>()` // But we can't call align_of() on a ?Sized T. So we approximate it // with the following. 256 is large enough that it should always be // larger than the required alignment, but small enough that it is // always in the first page of memory and therefore not a legitimate // address. ptr as *const usize as usize <= 256 } /// Call `size_of_op` on `ptr`, first checking that the allocation isn't /// empty, because some types (such as `Vec`) utilize empty allocations. pub unsafe fn malloc_size_of<T: ?Sized>(&self, ptr: *const T) -> usize { if MallocSizeOfOps::is_empty(ptr) { 0 } else { (self.size_of_op)(ptr as *const c_void) } } /// Is an `enclosing_size_of_op` available? pub fn has_malloc_enclosing_size_of(&self) -> bool { self.enclosing_size_of_op.is_some() } /// Call `enclosing_size_of_op`, which must be available, on `ptr`, which /// must not be empty. pub unsafe fn malloc_enclosing_size_of<T>(&self, ptr: *const T) -> usize { assert!(!MallocSizeOfOps::is_empty(ptr)); (self.enclosing_size_of_op.unwrap())(ptr as *const c_void) } } /// Trait for measuring the "deep" heap usage of a data structure. This is the /// most commonly-used of the traits. pub trait MallocSizeOf { /// Measure the heap usage of all descendant heap-allocated structures, but /// not the space taken up by the value itself. fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize; } /// Trait for measuring the "shallow" heap usage of a container. pub trait MallocShallowSizeOf { /// Measure the heap usage of immediate heap-allocated descendant /// structures, but not the space taken up by the value itself. Anything /// beyond the immediate descendants must be measured separately, using /// iteration. fn shallow_size_of(&self, ops: &mut MallocSizeOfOps) -> usize; } impl MallocSizeOf for String { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { unsafe { ops.malloc_size_of(self.as_ptr()) } } } impl<T: ?Sized> MallocShallowSizeOf for Box<T> { fn shallow_size_of(&self, ops: &mut MallocSizeOfOps) -> usize { unsafe { ops.malloc_size_of(&**self) } } } impl<T: MallocSizeOf + ?Sized> MallocSizeOf for Box<T> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.shallow_size_of(ops) + (**self).size_of(ops) } } impl MallocSizeOf for () { fn size_of(&self, _ops: &mut MallocSizeOfOps) -> usize { 0 } } impl<T1, T2> MallocSizeOf for (T1, T2) where T1: MallocSizeOf, T2: MallocSizeOf, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.0.size_of(ops) + self.1.size_of(ops) } } impl<T1, T2, T3> MallocSizeOf for (T1, T2, T3) where T1: MallocSizeOf, T2: MallocSizeOf, T3: MallocSizeOf, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.0.size_of(ops) + self.1.size_of(ops) + self.2.size_of(ops) } } impl<T1, T2, T3, T4> MallocSizeOf for (T1, T2, T3, T4) where T1: MallocSizeOf, T2: MallocSizeOf, T3: MallocSizeOf, T4: MallocSizeOf, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.0.size_of(ops) + self.1.size_of(ops) + self.2.size_of(ops) + self.3.size_of(ops) } } impl<T: MallocSizeOf> MallocSizeOf for Option<T> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { if let Some(val) = self.as_ref() { val.size_of(ops) } else { 0 } } } impl<T: MallocSizeOf, E: MallocSizeOf> MallocSizeOf for Result<T, E> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { match *self { Ok(ref x) => x.size_of(ops), Err(ref e) => e.size_of(ops), } } } impl<T: MallocSizeOf + Copy> MallocSizeOf for std::cell::Cell<T> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.get().size_of(ops) } } impl<T: MallocSizeOf> MallocSizeOf for std::cell::RefCell<T> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.borrow().size_of(ops) } } impl<'a, B: ?Sized + ToOwned> MallocSizeOf for std::borrow::Cow<'a, B> where B::Owned: MallocSizeOf, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { match *self { std::borrow::Cow::Borrowed(_) => 0, std::borrow::Cow::Owned(ref b) => b.size_of(ops), } } } impl<T: MallocSizeOf> MallocSizeOf for [T] { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { let mut n = 0; for elem in self.iter() { n += elem.size_of(ops); } n } } impl<T> MallocShallowSizeOf for Vec<T> { fn shallow_size_of(&self, ops: &mut MallocSizeOfOps) -> usize { unsafe { ops.malloc_size_of(self.as_ptr()) } } } impl<T: MallocSizeOf> MallocSizeOf for Vec<T> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { let mut n = self.shallow_size_of(ops); for elem in self.iter() { n += elem.size_of(ops); } n } } macro_rules! malloc_size_of_hash_set { ($ty:ty) => { impl<T, S> MallocShallowSizeOf for $ty where T: Eq + Hash, S: BuildHasher, { fn shallow_size_of(&self, ops: &mut MallocSizeOfOps) -> usize { if ops.has_malloc_enclosing_size_of() { // The first value from the iterator gives us an interior pointer. // `ops.malloc_enclosing_size_of()` then gives us the storage size. // This assumes that the `HashSet`'s contents (values and hashes) // are all stored in a single contiguous heap allocation. self.iter() .next() .map_or(0, |t| unsafe { ops.malloc_enclosing_size_of(t) }) } else { // An estimate. self.capacity() * (size_of::<T>() + size_of::<usize>()) } } } impl<T, S> MallocSizeOf for $ty where T: Eq + Hash + MallocSizeOf, S: BuildHasher, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { let mut n = self.shallow_size_of(ops); for t in self.iter() { n += t.size_of(ops); } n } } }; } malloc_size_of_hash_set!(std::collections::HashSet<T, S>); macro_rules! malloc_size_of_hash_map { ($ty:ty) => { impl<K, V, S> MallocShallowSizeOf for $ty where K: Eq + Hash, S: BuildHasher, { fn shallow_size_of(&self, ops: &mut MallocSizeOfOps) -> usize { // See the implementation for std::collections::HashSet for details. if ops.has_malloc_enclosing_size_of() { self.values() .next() .map_or(0, |v| unsafe { ops.malloc_enclosing_size_of(v) }) } else { self.capacity() * (size_of::<V>() + size_of::<K>() + size_of::<usize>()) } } } impl<K, V, S> MallocSizeOf for $ty where K: Eq + Hash + MallocSizeOf, V: MallocSizeOf, S: BuildHasher, { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { let mut n = self.shallow_size_of(ops); for (k, v) in self.iter() { n += k.size_of(ops); n += v.size_of(ops); } n } } }; } malloc_size_of_hash_map!(std::collections::HashMap<K, V, S>); // PhantomData is always 0. impl<T> MallocSizeOf for std::marker::PhantomData<T> { fn size_of(&self, _ops: &mut MallocSizeOfOps) -> usize { 0 } } impl MallocSizeOf for PathBuf { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { match self.to_str() { Some(s) => unsafe { ops.malloc_size_of(s.as_ptr()) }, None => self.as_os_str().len(), } } } impl<T: MallocSizeOf, Unit> MallocSizeOf for euclid::Length<T, Unit> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.0.size_of(ops) } } impl<T: MallocSizeOf, Src, Dst> MallocSizeOf for euclid::Scale<T, Src, Dst> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.0.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::Point2D<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.x.size_of(ops) + self.y.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::Rect<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.origin.size_of(ops) + self.size.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::Box2D<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.min.size_of(ops) + self.max.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::SideOffsets2D<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.top.size_of(ops) + self.right.size_of(ops) + self.bottom.size_of(ops) + self.left.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::Size2D<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.width.size_of(ops) + self.height.size_of(ops) } } impl<T: MallocSizeOf, Src, Dst> MallocSizeOf for euclid::Transform2D<T, Src, Dst> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.m11.size_of(ops) + self.m12.size_of(ops) + self.m21.size_of(ops) + self.m22.size_of(ops) + self.m31.size_of(ops) + self.m32.size_of(ops) } } impl<T: MallocSizeOf, Src, Dst> MallocSizeOf for euclid::Transform3D<T, Src, Dst> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.m11.size_of(ops) + self.m12.size_of(ops) + self.m13.size_of(ops) + self.m14.size_of(ops) + self.m21.size_of(ops) + self.m22.size_of(ops) + self.m23.size_of(ops) + self.m24.size_of(ops) + self.m31.size_of(ops) + self.m32.size_of(ops) + self.m33.size_of(ops) + self.m34.size_of(ops) + self.m41.size_of(ops) + self.m42.size_of(ops) + self.m43.size_of(ops) + self.m44.size_of(ops) } } impl<T: MallocSizeOf, U> MallocSizeOf for euclid::Vector2D<T, U> { fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize { self.x.size_of(ops) + self.y.size_of(ops) } } /// For use on types where size_of() returns 0. #[macro_export] macro_rules! malloc_size_of_is_0( ($($ty:ty),+) => ( $( impl $crate::MallocSizeOf for $ty { #[inline(always)] fn size_of(&self, _: &mut $crate::MallocSizeOfOps) -> usize { 0 } } )+ ); ($($ty:ident<$($gen:ident),+>),+) => ( $( impl<$($gen: $crate::MallocSizeOf),+> $crate::MallocSizeOf for $ty<$($gen),+> { #[inline(always)] fn size_of(&self, _: &mut $crate::MallocSizeOfOps) -> usize { 0 } } )+ ); ); malloc_size_of_is_0!(bool, char, str); malloc_size_of_is_0!(u8, u16, u32, u64, u128, usize); malloc_size_of_is_0!(i8, i16, i32, i64, i128, isize); malloc_size_of_is_0!(f32, f64); malloc_size_of_is_0!(std::sync::atomic::AtomicBool); malloc_size_of_is_0!(std::sync::atomic::AtomicIsize); malloc_size_of_is_0!(std::sync::atomic::AtomicUsize); malloc_size_of_is_0!(std::num::NonZeroUsize); malloc_size_of_is_0!(std::num::NonZeroU32); malloc_size_of_is_0!(std::time::Duration); malloc_size_of_is_0!(std::time::Instant); malloc_size_of_is_0!(std::time::SystemTime); malloc_size_of_is_0!(Range<u8>, Range<u16>, Range<u32>, Range<u64>, Range<usize>); malloc_size_of_is_0!(Range<i8>, Range<i16>, Range<i32>, Range<i64>, Range<isize>); malloc_size_of_is_0!(Range<f32>, Range<f64>); malloc_size_of_is_0!(app_units::Au); [ Dauer der Verarbeitung: 0.39 Sekunden ] |
2026-04-04