Crate slice_deque [] [src]

A double-ended queue that Derefs into a slice.

The double-ended queue in the standard library (VecDeque) is implemented using a growable ring buffer (0 represents uninitialized memory, and T represents one element in the queue):

// [ 0 | 0 | 0 | T | T | T | 0 ]
//               ^:head  ^:tail

When the queue grows beyond the end of the allocated buffer, its tail wraps around:

// [ T | T | 0 | T | T | T | T ]
//       ^:tail  ^:head

As a consequence, VecDeque cannot Deref into a slice, since its elements do not, in general, occupy a contiguous memory region. This complicates the implementation and its interface (for example, there is no as_slice method, but as_slices returns a pair of slices) and has negative performance consequences (e.g. need to account for wrap around while iterating over the elements).

This crates provides SliceDeque, a double-ended queue implemented with a growable virtual ring-buffer.

A virtual ring-buffer implementation is very similar to the one used in VecDeque. The main difference is that a virtual ring-buffer maps two adjacent regions of virtual memory to the same region of physical memory:

// Virtual memory:
//
//  __________region_0_________ __________region_1_________
// [ 0 | 0 | 0 | T | T | T | 0 | 0 | 0 | 0 | T | T | T | 0 ]
//               ^:head  ^:tail
//
// Physical memory:
//
// [ 0 | 0 | 0 | T | T | T | 0 ]
//               ^:head  ^:tail

That is, both the virtual memory regions 0 and 1 above (top) map to the same physical memory (bottom). Just like VecDeque, when the queue grows beyond the end of the allocated physical memory region, the queue wraps around, and new elements continue to be appended at the beginning of the queue. However, because SliceDeque maps the physical memory to two adjacent memory regions, in virtual memory space the queue maintais the ilusion of a contiguous memory layout:

// Virtual memory:
//
//  __________region_0_________ __________region_1_________
// [ T | T | 0 | T | T | T | T | T | T | 0 | T | T | T | T ]
//               ^:head              ^:tail
//
// Physical memory:
//
// [ T | T | 0 | T | T | T | T ]
//       ^:tail  ^:head

Since processes in many Operating Systems only deal with virtual memory addresses, leaving the mapping to physical memory to the CPU Memory Management Unit (MMU), SliceDeque is able to Derefs into a slice in those systems.

This simplifies SliceDeque's API and implementation, giving it a performance advantage over VecDeque in some situations.

In general, you can think of SliceDeque as a Vec with O(1) pop_front and amortized O(1) push_front methods.

The main drawbacks of SliceDeque are:

  • constrained platform support: by necessity SliceDeque must use the platform-specific virtual memory facilities of the underlying operating system. While SliceDeque can work on all major operating systems, currently only MacOS X is supported.

  • no global allocator support: since the Allocator API does not support virtual memory, to use platform-specific virtual memory support SliceDeque must bypass the global allocator and talk directly to the operating system. This can have negative performance consequences since growing SliceDeque is always going to incur the cost of some system calls.

  • capacity constrained by virtual memory facilities: SliceDeque must allocate two adjacent memory regions that map to the same region of physical memory. Most operating systems allow this operation to be performed exclusively on memory pages (or memory allocations that are multiples of a memory page). As a consequence, the smalles SliceDeque that can be created has typically a capacity of 2 memory pages, and it can grow only to capacities that are a multiple of a memory page.

The main advantages of SliceDeque are:

  • nicer API: since it Derefs to a slice, all operations that work on slices are available for SliceDeque.

  • efficient iteration: as efficient as for slices.

  • simpler serialization: since one can just serialize/deserialize a single slice.

All in all, if your double-ended queues are small (smaller than a memory page) or they get resized very often, VecDeque can perform better than SliceDeque. Otherwise, SliceDeque typically performs better (see the benchmarks), but platform support and global allocator bypass are two reasons to weight in against its usage.

Macros

sdeq

Creates a SliceDeque containing the arguments.

Structs

Buffer

Mirrored memory buffer of length len.

Drain

A draining iterator for SliceDeque<T>.

DrainFilter

An iterator produced by calling drain_filter on SliceDeque.

IntoIter

An iterator that moves out of a deque.

SliceDeque

A double-ended queue that derefs into a slice.

Splice

A splicing iterator for SliceDeque.