cfcbb4227f
This does not yet include support for the //go:embed directive added in this release. * Makefile.am (check-runtime): Don't create check-runtime-dir. (mostlyclean-local): Don't remove check-runtime-dir. (check-go-tool, check-vet): Copy in go.mod and modules.txt. (check-cgo-test, check-carchive-test): Add go.mod file. * Makefile.in: Regenerate. Reviewed-on: https://go-review.googlesource.com/c/gofrontend/+/280172
359 lines
12 KiB
Go
359 lines
12 KiB
Go
// Copyright 2020 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package runtime
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import (
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"internal/cpu"
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"runtime/internal/atomic"
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"runtime/internal/sys"
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"unsafe"
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)
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// A spanSet is a set of *mspans.
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//
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// spanSet is safe for concurrent push and pop operations.
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type spanSet struct {
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// A spanSet is a two-level data structure consisting of a
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// growable spine that points to fixed-sized blocks. The spine
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// can be accessed without locks, but adding a block or
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// growing it requires taking the spine lock.
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//
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// Because each mspan covers at least 8K of heap and takes at
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// most 8 bytes in the spanSet, the growth of the spine is
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// quite limited.
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//
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// The spine and all blocks are allocated off-heap, which
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// allows this to be used in the memory manager and avoids the
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// need for write barriers on all of these. spanSetBlocks are
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// managed in a pool, though never freed back to the operating
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// system. We never release spine memory because there could be
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// concurrent lock-free access and we're likely to reuse it
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// anyway. (In principle, we could do this during STW.)
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spineLock mutex
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spine unsafe.Pointer // *[N]*spanSetBlock, accessed atomically
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spineLen uintptr // Spine array length, accessed atomically
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spineCap uintptr // Spine array cap, accessed under lock
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// index is the head and tail of the spanSet in a single field.
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// The head and the tail both represent an index into the logical
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// concatenation of all blocks, with the head always behind or
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// equal to the tail (indicating an empty set). This field is
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// always accessed atomically.
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//
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// The head and the tail are only 32 bits wide, which means we
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// can only support up to 2^32 pushes before a reset. If every
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// span in the heap were stored in this set, and each span were
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// the minimum size (1 runtime page, 8 KiB), then roughly the
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// smallest heap which would be unrepresentable is 32 TiB in size.
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index headTailIndex
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}
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const (
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spanSetBlockEntries = 512 // 4KB on 64-bit
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spanSetInitSpineCap = 256 // Enough for 1GB heap on 64-bit
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)
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type spanSetBlock struct {
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// Free spanSetBlocks are managed via a lock-free stack.
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lfnode
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// popped is the number of pop operations that have occurred on
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// this block. This number is used to help determine when a block
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// may be safely recycled.
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popped uint32
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// spans is the set of spans in this block.
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spans [spanSetBlockEntries]*mspan
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}
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// push adds span s to buffer b. push is safe to call concurrently
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// with other push and pop operations.
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func (b *spanSet) push(s *mspan) {
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// Obtain our slot.
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cursor := uintptr(b.index.incTail().tail() - 1)
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top, bottom := cursor/spanSetBlockEntries, cursor%spanSetBlockEntries
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// Do we need to add a block?
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spineLen := atomic.Loaduintptr(&b.spineLen)
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var block *spanSetBlock
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retry:
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if top < spineLen {
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spine := atomic.Loadp(unsafe.Pointer(&b.spine))
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blockp := add(spine, sys.PtrSize*top)
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block = (*spanSetBlock)(atomic.Loadp(blockp))
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} else {
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// Add a new block to the spine, potentially growing
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// the spine.
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lock(&b.spineLock)
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// spineLen cannot change until we release the lock,
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// but may have changed while we were waiting.
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spineLen = atomic.Loaduintptr(&b.spineLen)
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if top < spineLen {
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unlock(&b.spineLock)
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goto retry
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}
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if spineLen == b.spineCap {
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// Grow the spine.
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newCap := b.spineCap * 2
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if newCap == 0 {
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newCap = spanSetInitSpineCap
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}
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newSpine := persistentalloc(newCap*sys.PtrSize, cpu.CacheLineSize, &memstats.gcMiscSys)
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if b.spineCap != 0 {
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// Blocks are allocated off-heap, so
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// no write barriers.
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memmove(newSpine, b.spine, b.spineCap*sys.PtrSize)
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}
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// Spine is allocated off-heap, so no write barrier.
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atomic.StorepNoWB(unsafe.Pointer(&b.spine), newSpine)
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b.spineCap = newCap
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// We can't immediately free the old spine
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// since a concurrent push with a lower index
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// could still be reading from it. We let it
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// leak because even a 1TB heap would waste
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// less than 2MB of memory on old spines. If
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// this is a problem, we could free old spines
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// during STW.
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}
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// Allocate a new block from the pool.
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block = spanSetBlockPool.alloc()
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// Add it to the spine.
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blockp := add(b.spine, sys.PtrSize*top)
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// Blocks are allocated off-heap, so no write barrier.
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atomic.StorepNoWB(blockp, unsafe.Pointer(block))
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atomic.Storeuintptr(&b.spineLen, spineLen+1)
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unlock(&b.spineLock)
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}
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// We have a block. Insert the span atomically, since there may be
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// concurrent readers via the block API.
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atomic.StorepNoWB(unsafe.Pointer(&block.spans[bottom]), unsafe.Pointer(s))
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}
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// pop removes and returns a span from buffer b, or nil if b is empty.
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// pop is safe to call concurrently with other pop and push operations.
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func (b *spanSet) pop() *mspan {
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var head, tail uint32
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claimLoop:
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for {
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headtail := b.index.load()
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head, tail = headtail.split()
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if head >= tail {
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// The buf is empty, as far as we can tell.
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return nil
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}
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// Check if the head position we want to claim is actually
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// backed by a block.
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spineLen := atomic.Loaduintptr(&b.spineLen)
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if spineLen <= uintptr(head)/spanSetBlockEntries {
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// We're racing with a spine growth and the allocation of
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// a new block (and maybe a new spine!), and trying to grab
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// the span at the index which is currently being pushed.
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// Instead of spinning, let's just notify the caller that
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// there's nothing currently here. Spinning on this is
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// almost definitely not worth it.
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return nil
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}
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// Try to claim the current head by CASing in an updated head.
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// This may fail transiently due to a push which modifies the
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// tail, so keep trying while the head isn't changing.
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want := head
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for want == head {
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if b.index.cas(headtail, makeHeadTailIndex(want+1, tail)) {
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break claimLoop
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}
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headtail = b.index.load()
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head, tail = headtail.split()
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}
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// We failed to claim the spot we were after and the head changed,
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// meaning a popper got ahead of us. Try again from the top because
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// the buf may not be empty.
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}
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top, bottom := head/spanSetBlockEntries, head%spanSetBlockEntries
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// We may be reading a stale spine pointer, but because the length
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// grows monotonically and we've already verified it, we'll definitely
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// be reading from a valid block.
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spine := atomic.Loadp(unsafe.Pointer(&b.spine))
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blockp := add(spine, sys.PtrSize*uintptr(top))
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// Given that the spine length is correct, we know we will never
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// see a nil block here, since the length is always updated after
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// the block is set.
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block := (*spanSetBlock)(atomic.Loadp(blockp))
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s := (*mspan)(atomic.Loadp(unsafe.Pointer(&block.spans[bottom])))
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for s == nil {
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// We raced with the span actually being set, but given that we
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// know a block for this span exists, the race window here is
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// extremely small. Try again.
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s = (*mspan)(atomic.Loadp(unsafe.Pointer(&block.spans[bottom])))
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}
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// Clear the pointer. This isn't strictly necessary, but defensively
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// avoids accidentally re-using blocks which could lead to memory
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// corruption. This way, we'll get a nil pointer access instead.
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atomic.StorepNoWB(unsafe.Pointer(&block.spans[bottom]), nil)
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// Increase the popped count. If we are the last possible popper
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// in the block (note that bottom need not equal spanSetBlockEntries-1
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// due to races) then it's our resposibility to free the block.
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//
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// If we increment popped to spanSetBlockEntries, we can be sure that
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// we're the last popper for this block, and it's thus safe to free it.
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// Every other popper must have crossed this barrier (and thus finished
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// popping its corresponding mspan) by the time we get here. Because
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// we're the last popper, we also don't have to worry about concurrent
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// pushers (there can't be any). Note that we may not be the popper
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// which claimed the last slot in the block, we're just the last one
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// to finish popping.
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if atomic.Xadd(&block.popped, 1) == spanSetBlockEntries {
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// Clear the block's pointer.
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atomic.StorepNoWB(blockp, nil)
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// Return the block to the block pool.
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spanSetBlockPool.free(block)
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}
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return s
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}
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// reset resets a spanSet which is empty. It will also clean up
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// any left over blocks.
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//
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// Throws if the buf is not empty.
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//
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// reset may not be called concurrently with any other operations
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// on the span set.
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func (b *spanSet) reset() {
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head, tail := b.index.load().split()
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if head < tail {
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print("head = ", head, ", tail = ", tail, "\n")
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throw("attempt to clear non-empty span set")
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}
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top := head / spanSetBlockEntries
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if uintptr(top) < b.spineLen {
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// If the head catches up to the tail and the set is empty,
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// we may not clean up the block containing the head and tail
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// since it may be pushed into again. In order to avoid leaking
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// memory since we're going to reset the head and tail, clean
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// up such a block now, if it exists.
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blockp := (**spanSetBlock)(add(b.spine, sys.PtrSize*uintptr(top)))
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block := *blockp
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if block != nil {
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// Sanity check the popped value.
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if block.popped == 0 {
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// popped should never be zero because that means we have
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// pushed at least one value but not yet popped if this
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// block pointer is not nil.
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throw("span set block with unpopped elements found in reset")
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}
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if block.popped == spanSetBlockEntries {
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// popped should also never be equal to spanSetBlockEntries
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// because the last popper should have made the block pointer
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// in this slot nil.
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throw("fully empty unfreed span set block found in reset")
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}
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// Clear the pointer to the block.
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atomic.StorepNoWB(unsafe.Pointer(blockp), nil)
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// Return the block to the block pool.
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spanSetBlockPool.free(block)
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}
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}
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b.index.reset()
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atomic.Storeuintptr(&b.spineLen, 0)
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}
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// gccgoAlignment is used to get spanSetBlockPool aligned on a 64-bit
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// boundary on 32-bit x86.
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var gccgoAlignment uint64
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// spanSetBlockPool is a global pool of spanSetBlocks.
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var spanSetBlockPool = (*spanSetBlockAlloc)(unsafe.Pointer(&gccgoAlignment))
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// spanSetBlockAlloc represents a concurrent pool of spanSetBlocks.
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type spanSetBlockAlloc struct {
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stack lfstack
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}
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// alloc tries to grab a spanSetBlock out of the pool, and if it fails
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// persistentallocs a new one and returns it.
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func (p *spanSetBlockAlloc) alloc() *spanSetBlock {
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if s := (*spanSetBlock)(p.stack.pop()); s != nil {
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return s
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}
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return (*spanSetBlock)(persistentalloc(unsafe.Sizeof(spanSetBlock{}), cpu.CacheLineSize, &memstats.gcMiscSys))
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}
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// free returns a spanSetBlock back to the pool.
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func (p *spanSetBlockAlloc) free(block *spanSetBlock) {
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atomic.Store(&block.popped, 0)
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p.stack.push(&block.lfnode)
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}
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// haidTailIndex represents a combined 32-bit head and 32-bit tail
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// of a queue into a single 64-bit value.
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type headTailIndex uint64
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// makeHeadTailIndex creates a headTailIndex value from a separate
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// head and tail.
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func makeHeadTailIndex(head, tail uint32) headTailIndex {
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return headTailIndex(uint64(head)<<32 | uint64(tail))
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}
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// head returns the head of a headTailIndex value.
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func (h headTailIndex) head() uint32 {
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return uint32(h >> 32)
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}
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// tail returns the tail of a headTailIndex value.
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func (h headTailIndex) tail() uint32 {
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return uint32(h)
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}
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// split splits the headTailIndex value into its parts.
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func (h headTailIndex) split() (head uint32, tail uint32) {
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return h.head(), h.tail()
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}
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// load atomically reads a headTailIndex value.
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func (h *headTailIndex) load() headTailIndex {
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return headTailIndex(atomic.Load64((*uint64)(h)))
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}
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// cas atomically compares-and-swaps a headTailIndex value.
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func (h *headTailIndex) cas(old, new headTailIndex) bool {
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return atomic.Cas64((*uint64)(h), uint64(old), uint64(new))
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}
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// incHead atomically increments the head of a headTailIndex.
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func (h *headTailIndex) incHead() headTailIndex {
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return headTailIndex(atomic.Xadd64((*uint64)(h), (1 << 32)))
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}
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// decHead atomically decrements the head of a headTailIndex.
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func (h *headTailIndex) decHead() headTailIndex {
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return headTailIndex(atomic.Xadd64((*uint64)(h), -(1 << 32)))
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}
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// incTail atomically increments the tail of a headTailIndex.
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func (h *headTailIndex) incTail() headTailIndex {
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ht := headTailIndex(atomic.Xadd64((*uint64)(h), +1))
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// Check for overflow.
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if ht.tail() == 0 {
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print("runtime: head = ", ht.head(), ", tail = ", ht.tail(), "\n")
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throw("headTailIndex overflow")
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}
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return ht
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}
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// reset clears the headTailIndex to (0, 0).
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func (h *headTailIndex) reset() {
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atomic.Store64((*uint64)(h), 0)
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}
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