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heap.go
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heap.go
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// Copyright 2016 Platina Systems, Inc. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package elib
import (
"errors"
"fmt"
)
// Index gives common type for indices in Heaps, Pools, Fifos, ...
type Index uint32
const MaxIndex Index = ^Index(0)
// A Heap maintains an allocator for arbitrary sized blocks of an underlying array.
// The array is not part of the Heap.
type Heap struct {
elts []heapElt
// Slices of free elts indices indexed by size.
// "Size" 0 is for large sized chunks.
free freeEltsVec
removed []Index
head, tail Index
// Total number of indices allocated
len Index
// Largest size ever allocated
maxSize Index
// Max limit on heap size in elements.
maxLen Index
}
func (heap *Heap) SetMaxLen(l uint) {
heap.maxLen = Index(l)
}
func (heap *Heap) GetMaxLen() uint { return uint(heap.maxLen) }
type HeapUsage struct {
Used, Free uint64
}
func (heap *Heap) GetUsage() (u HeapUsage) {
for i := range heap.elts {
e := &heap.elts[i]
size := uint64(heap.eltSize(e))
if e.isFree() {
u.Free += size
} else {
u.Used += size
}
}
return
}
type freeElt Index
//go:generate gentemplate -d Package=elib -id freeElt -d VecType=freeEltVec -d Type=freeElt vec.tmpl
//go:generate gentemplate -d Package=elib -id freeElts -d VecType=freeEltsVec -d Type=freeEltVec vec.tmpl
type heapElt struct {
// Offset of this element in heap.
offset Index
// Index on free list for this size or ^uint32(0) if not free.
free Index
// Index of next and previous elements
next, prev Index
}
func (e *heapElt) isFree() bool {
return e.free != MaxIndex
}
func (heap *Heap) freeAfter(ei, eSize, freeSize Index) {
// Fetch elt and new free elt.
fi := heap.newElt()
e, f := &heap.elts[ei], &heap.elts[fi]
f.offset = e.offset + Index(eSize-freeSize)
f.next = e.next
f.prev = ei
if f.next != MaxIndex {
heap.elts[f.next].prev = fi
}
e.next = fi
if ei == heap.tail {
heap.tail = fi
}
heap.freeElt(fi, freeSize)
}
func (heap *Heap) freeBefore(ei, eSize, freeSize Index) {
// Fetch elt and new free elt.
fi := heap.newElt()
e, f := &heap.elts[ei], &heap.elts[fi]
f.offset = e.offset
f.prev = e.prev
f.next = ei
if f.prev == MaxIndex {
heap.head = fi
} else {
heap.elts[f.prev].next = fi
}
e.offset += freeSize
e.prev = fi
heap.freeElt(fi, freeSize)
}
func (heap *Heap) freeElt(ei, size Index) {
if size > heap.maxSize {
size = 0
}
heap.free.Validate(uint(size))
heap.elts[ei].free = Index(len(heap.free[size]))
heap.free[size] = append(heap.free[size], freeElt(ei))
}
var poison heapElt = heapElt{
offset: MaxIndex,
free: MaxIndex,
next: MaxIndex,
prev: MaxIndex,
}
func (heap *Heap) removeFreeElt(ei, size Index) {
e := &heap.elts[ei]
fi := e.free
if size >= Index(len(heap.free)) {
size = 0
}
if l := Index(len(heap.free[size])); fi < l && heap.free[size][fi] == freeElt(ei) {
if fi < l-1 {
gi := heap.free[size][l-1]
heap.free[size][fi] = gi
heap.elts[gi].free = fi
}
heap.free[size] = heap.free[size][:l-1]
*e = poison
heap.removed = append(heap.removed, ei)
return
}
panic(fmt.Errorf("corrupt free list: size %v len(heap.free[size]) %v, fi %v, %v %v\n", size,
len(heap.free[size]), fi, heap.free[size][fi], freeElt(ei)))
}
func (heap *Heap) eltSize(e *heapElt) Index {
o := Index(heap.len)
if e.next != MaxIndex {
o = heap.elts[e.next].offset
}
return o - e.offset
}
func (heap *Heap) size(ei Index) Index { return heap.eltSize(&heap.elts[ei]) }
func (heap *Heap) Len(ei Index) uint {
return uint(heap.size(ei))
}
func (heap *Heap) GetID(ei Index) (offset, len int) {
e := &heap.elts[ei]
return int(e.offset), int(heap.eltSize(e))
}
// Recycle previously removed elts.
func (heap *Heap) newElt() (ei Index) {
if l := len(heap.removed); l > 0 {
ei = heap.removed[l-1]
heap.removed = heap.removed[:l-1]
heap.elts[ei] = poison
} else {
ei = Index(len(heap.elts))
heap.elts = append(heap.elts, poison)
}
return
}
func (heap *Heap) Get(size uint) (id Index, offset uint) { return heap.get(size, Index(size)) }
var ErrHeapOverflow = errors.New("heap overflow")
func (heap *Heap) get(sizeArg uint, size Index) (id Index, offset uint) {
// Keep track of largest size caller asks for.
if Index(sizeArg) > heap.maxSize {
heap.maxSize = Index(sizeArg)
}
if size <= 0 {
panic(fmt.Errorf("heap get bad size: %d", size))
}
// Quickly allocate from free list of given size.
if int(size) < len(heap.free) {
if l := len(heap.free[size]); l > 0 {
ei := heap.free[size][l-1]
e := &heap.elts[ei]
heap.free[size] = heap.free[size][:l-1]
e.free = MaxIndex
offset = uint(e.offset)
id = Index(ei)
return
}
}
// Search free list 0: where free objects > max requested size are kept.
if len(heap.free) > 0 {
l := Index(len(heap.free[0]))
for fi := Index(0); fi < l; fi++ {
ei := heap.free[0][fi]
e := &heap.elts[ei]
es := heap.eltSize(e)
fs := int(es) - int(size)
if fs < 0 {
continue
}
if fi < l-1 {
gi := heap.free[0][l-1]
heap.free[0][fi] = gi
heap.elts[gi].free = fi
}
heap.free[0] = heap.free[0][:l-1]
offset = uint(e.offset)
e.free = MaxIndex
id = Index(ei)
if fs > 0 {
heap.freeAfter(Index(ei), es, Index(fs))
}
return
}
}
if heap.maxLen != 0 && heap.len+size > heap.maxLen {
panic(ErrHeapOverflow)
}
if heap.len == 0 {
heap.head = 0
heap.tail = MaxIndex
}
ei := heap.newElt()
e := &heap.elts[ei]
offset = uint(heap.len)
heap.len += size
e.offset = Index(offset)
e.next = MaxIndex
e.prev = heap.tail
e.free = MaxIndex
heap.tail = ei
if e.prev != MaxIndex {
heap.elts[e.prev].next = ei
}
id = ei
return
}
func (heap *Heap) newEltBefore(ei Index) (pi Index) {
pi = heap.newElt()
e, p := &heap.elts[ei], &heap.elts[pi]
p.next = ei
p.prev = e.prev
if p.prev == MaxIndex {
heap.head = pi
} else {
heap.elts[p.prev].next = pi
}
e.prev = pi
return
}
func (heap *Heap) newEltAfter(ei Index) (ni Index) {
ni = heap.newElt()
e, n := &heap.elts[ei], &heap.elts[ni]
n.prev = ei
n.next = e.next
if n.next == MaxIndex {
heap.tail = ni
} else {
heap.elts[n.next].prev = ni
}
e.next = ni
return
}
func (heap *Heap) GetAligned(sizeArg, log2Alignment uint) (id Index, offset uint) {
// Adjust size for alignment so we guarantee a large enough block.
a := Index(1) << log2Alignment
size := sizeArg + uint(a) - 1
sa := Index(sizeArg)
s := Index(size)
ei, offset := heap.get(sizeArg, s)
o := Index(offset)
// Aligned offset.
ao := (o + a - 1) &^ (a - 1)
if log2Alignment > 0 {
if d := ao - o; d != 0 {
pi := heap.newEltBefore(ei)
e, p := &heap.elts[ei], &heap.elts[pi]
p.offset = o
e.offset = ao
heap.Put(pi)
}
if d := int(o+s) - int(ao+sa); d > 0 {
ni := heap.newEltAfter(ei)
e, n := &heap.elts[ei], &heap.elts[ni]
e.offset = ao
n.offset = ao + sa
heap.Put(ni)
}
}
id = ei
offset = uint(ao)
return
}
func (heap *Heap) IsFree(ei Index) bool {
e := &heap.elts[ei]
return e.isFree()
}
func (heap *Heap) Put(ei Index) {
e := &heap.elts[ei]
if e.isFree() {
panic(fmt.Errorf("duplicate free %d", ei))
}
// If previous element is free combine free elements.
if e.prev != MaxIndex {
prev := &heap.elts[e.prev]
if prev.isFree() {
ps := e.offset - prev.offset
e.offset = prev.offset
pi := e.prev
e.prev = prev.prev
if e.prev != MaxIndex {
heap.elts[e.prev].next = ei
}
heap.removeFreeElt(pi, ps)
if pi == heap.head {
heap.head = ei
}
}
}
// If next element is free also combine.
if e.next != MaxIndex {
next := &heap.elts[e.next]
if next.isFree() {
ni := e.next
ns := heap.size(ni)
e.next = next.next
if e.next != MaxIndex {
heap.elts[e.next].prev = ei
}
heap.removeFreeElt(ni, ns)
if ni == heap.tail {
heap.tail = ei
}
}
}
es := heap.size(ei)
heap.freeElt(ei, es)
}
func (heap *Heap) String() (s string) {
s = fmt.Sprintf("%d elts", len(heap.elts))
if heap.maxLen != 0 {
s += fmt.Sprintf(", max %d elts (0x%x)", heap.maxLen, heap.maxLen)
}
return
}
func (heap *Heap) Foreach(f func(offset, len uint)) {
for ei := range heap.elts {
e := &heap.elts[ei]
if !e.isFree() {
f(uint(e.offset), uint(heap.eltSize(e)))
}
}
}