ircd::buffer: Add experimental non-temporal copy device.

2024-11-26 00:32:35 +01:00 · 2020-07-07 14:53:05 -07:00 · 2020-07-07 14:53:05 -07:00 · f1c8eb3c1c
commit f1c8eb3c1c
parent 2235acae61
2 changed files with 143 additions and 0 deletions
--- a/include/ircd/buffer/buffer.h
+++ b/include/ircd/buffer/buffer.h
@ -105,6 +105,7 @@ namespace ircd::buffer::buffers
 #include "const_buffer.h"
 #include "copy.h"
 #include "move.h"
 #include "stream.h"
 #include "fixed_buffer.h"
 #include "window_buffer.h"
 #include "parse_buffer.h"
--- a/include/ircd/buffer/stream.h
+++ b/include/ircd/buffer/stream.h
@ -0,0 +1,142 @@
 // The Construct
 //
 // Copyright (C) The Construct Developers, Authors & Contributors
 // Copyright (C) 2016-2020 Jason Volk <jason@zemos.net>
 //
 // Permission to use, copy, modify, and/or distribute this software for any
 // purpose with or without fee is hereby granted, provided that the above
 // copyright notice and this permission notice is present in all copies. The
 // full license for this software is available in the LICENSE file.
 #pragma once
 #define HAVE_IRCD_BUFFER_STREAM_H
 namespace ircd::buffer
 {
 	size_t stream_aligned(const mutable_buffer &dst, const const_buffer &src);
 }
 /// Non-temporal copy. This copies from an aligned source to an aligned
 /// destination without the data cycling through the d-cache. The alignment
 /// requirements are currently very strict. The source and destination buffers
 /// must begin at a cache-line alignment and the size of the buffers must be
 /// a multiple of something we'll call "register-file size" which is the size
 /// of all named multimedia registers (256 for SSE, 512 for AVX, 2048 for
 /// AVX512) so it's safe to say buffers should just be aligned and padded out
 /// to 4K page-size to be safe. The size of the src argument itself can be an
 /// arbitrary size and this function will return that size, but its backing
 /// buffer must be padded out to alignment.
 ///
 inline size_t
 ircd::buffer::stream_aligned(const mutable_buffer &dst,
                             const const_buffer &src)
 {
 	// Platforms that have non-temporal store support; this is all of x86_64
 	constexpr bool has_nontemporal_store
 	{
 		#if defined(__SSE2__) && !defined(RB_GENERIC)
 			true
 		#else
 			false
 		#endif
 	};
 	// Platforms that have non-temporal load support; sidenote SSE4.1 can do
 	// 16 byte loads and AVX2 can do 32 byte loads; SSE2 cannot do loads.
 	constexpr bool has_nontemporal_load
 	{
 		#if defined(__AVX__) && !defined(RB_GENERIC)
 			true
 		#else
 			false
 		#endif
 	};
 	// Use the AVX512 vector type unconditionally as it conveniently matches
 	// the cache-line size on the relevant platforms and simplifies our syntax
 	// below by being a single object. On those w/o AVX512 it uses an
 	// isomorphic configuration of the best available regs.
 	using block_type = u512x1;
 	// The number of cache lines we'll have "in flight" which is basically
 	// just a gimmick to unroll the loop such that each iteration covers
 	// the full register file. On SSE with 256 bytes of register file we can
 	// name 4 cache lines at once; on AVX with 512 bytes we can name 8, etc.
 	constexpr size_t file_lines
 	{
 		#if defined(__AVX512F__)
 			32
 		#elif defined(__AVX__)
 			8
 		#else
 			4
 		#endif
 	};
 	// Configurable magic number only relevant to SSE2 systems which don't have
 	// non-temporal load instructions. On these platforms we'll conduct a
 	// prefetch loop and mark the lines NTA.
 	constexpr size_t latency
 	{
 		16
 	};
 	// When the constexpr conditions aren't favorable we can fallback to
 	// normal copy here.
 	if constexpr(!has_nontemporal_store && !has_nontemporal_load)
 		return copy(dst, src);
 	// Assert valid arguments
 	assert(!overlap(src, dst));
 	assert(aligned(data(src), sizeof(block_type)));
 	assert(aligned(data(dst), sizeof(block_type)));
 	assert(size(dst) % (sizeof(block_type) * file_lines));
 	// Size in bytes to be copied
 	const size_t copy_size
 	{
 		std::min(size(src), size(dst))
 	};
 	// Number of lines to be copied.
 	const size_t copy_lines
 	{
 		(copy_size / sizeof(block_type)) + bool(copy_size % sizeof(block_type))
 	};
 	// destination base ptr
 	block_type *const __restrict__ out
 	{
 		reinterpret_cast<block_type *__restrict__>(data(dst))
 	};
 	// source base ptr
 	const block_type *const __restrict__ in
 	{
 		reinterpret_cast<const block_type *__restrict__>(data(src))
 	};
 	if constexpr(!has_nontemporal_load)
 		#pragma clang loop unroll(disable)
 		for(size_t i(0); i < latency; ++i)
 			__builtin_prefetch(in + i, 0, 0);
 	for(size_t i(0); i < copy_lines; i += file_lines)
 	{
 		if constexpr(!has_nontemporal_load)
 			for(size_t j(0); j < file_lines; ++j)
 				__builtin_prefetch(in + i + latency + j, 0, 0);
 		block_type block[file_lines];
 		for(size_t j(0); j < file_lines; ++j)
 			block[j] = __builtin_nontemporal_load(in + i + j);
 		for(size_t j(0); j < file_lines; ++j)
 			__builtin_nontemporal_store(block[j], out + i + j);
 	}
 	if constexpr(has_nontemporal_store)
 		asm volatile ("sfence");
 	return copy_size;
 }