vendor/go.etcd.io/bbolt/freelist.go - voltha-go - Gitiles

 package bbolt

 import (
 	"fmt"
 	"sort"
 	"unsafe"
 )

 // txPending holds a list of pgids and corresponding allocation txns
 // that are pending to be freed.
 type txPending struct {
 	ids              []pgid
 	alloctx          []txid // txids allocating the ids
 	lastReleaseBegin txid   // beginning txid of last matching releaseRange
 }

 // pidSet holds the set of starting pgids which have the same span size
 type pidSet map[pgid]struct{}

 // freelist represents a list of all pages that are available for allocation.
 // It also tracks pages that have been freed but are still in use by open transactions.
 type freelist struct {
 	freelistType   FreelistType                // freelist type
 	ids            []pgid                      // all free and available free page ids.
 	allocs         map[pgid]txid               // mapping of txid that allocated a pgid.
 	pending        map[txid]*txPending         // mapping of soon-to-be free page ids by tx.
 	cache          map[pgid]bool               // fast lookup of all free and pending page ids.
 	freemaps       map[uint64]pidSet           // key is the size of continuous pages(span), value is a set which contains the starting pgids of same size
 	forwardMap     map[pgid]uint64             // key is start pgid, value is its span size
 	backwardMap    map[pgid]uint64             // key is end pgid, value is its span size
 	allocate       func(txid txid, n int) pgid // the freelist allocate func
 	free_count     func() int                  // the function which gives you free page number
 	mergeSpans     func(ids pgids)             // the mergeSpan func
 	getFreePageIDs func() []pgid               // get free pgids func
 	readIDs        func(pgids []pgid)          // readIDs func reads list of pages and init the freelist
 }

 // newFreelist returns an empty, initialized freelist.
 func newFreelist(freelistType FreelistType) *freelist {
 	f := &freelist{
 		freelistType: freelistType,
 		allocs:       make(map[pgid]txid),
 		pending:      make(map[txid]*txPending),
 		cache:        make(map[pgid]bool),
 		freemaps:     make(map[uint64]pidSet),
 		forwardMap:   make(map[pgid]uint64),
 		backwardMap:  make(map[pgid]uint64),
 	}

 	if freelistType == FreelistMapType {
 		f.allocate = f.hashmapAllocate
 		f.free_count = f.hashmapFreeCount
 		f.mergeSpans = f.hashmapMergeSpans
 		f.getFreePageIDs = f.hashmapGetFreePageIDs
 		f.readIDs = f.hashmapReadIDs
 	} else {
 		f.allocate = f.arrayAllocate
 		f.free_count = f.arrayFreeCount
 		f.mergeSpans = f.arrayMergeSpans
 		f.getFreePageIDs = f.arrayGetFreePageIDs
 		f.readIDs = f.arrayReadIDs
 	}

 	return f
 }

 // size returns the size of the page after serialization.
 func (f *freelist) size() int {
 	n := f.count()
 	if n >= 0xFFFF {
 		// The first element will be used to store the count. See freelist.write.
 		n++
 	}
 	return pageHeaderSize + (int(unsafe.Sizeof(pgid(0))) * n)
 }

 // count returns count of pages on the freelist
 func (f *freelist) count() int {
 	return f.free_count() + f.pending_count()
 }

 // arrayFreeCount returns count of free pages(array version)
 func (f *freelist) arrayFreeCount() int {
 	return len(f.ids)
 }

 // pending_count returns count of pending pages
 func (f *freelist) pending_count() int {
 	var count int
 	for _, txp := range f.pending {
 		count += len(txp.ids)
 	}
 	return count
 }

 // copyall copies into dst a list of all free ids and all pending ids in one sorted list.
 // f.count returns the minimum length required for dst.
 func (f *freelist) copyall(dst []pgid) {
 	m := make(pgids, 0, f.pending_count())
 	for _, txp := range f.pending {
 		m = append(m, txp.ids...)
 	}
 	sort.Sort(m)
 	mergepgids(dst, f.getFreePageIDs(), m)
 }

 // arrayAllocate returns the starting page id of a contiguous list of pages of a given size.
 // If a contiguous block cannot be found then 0 is returned.
 func (f *freelist) arrayAllocate(txid txid, n int) pgid {
 	if len(f.ids) == 0 {
 		return 0
 	}

 	var initial, previd pgid
 	for i, id := range f.ids {
 		if id <= 1 {
 			panic(fmt.Sprintf("invalid page allocation: %d", id))
 		}

 		// Reset initial page if this is not contiguous.
 		if previd == 0 || id-previd != 1 {
 			initial = id
 		}

 		// If we found a contiguous block then remove it and return it.
 		if (id-initial)+1 == pgid(n) {
 			// If we're allocating off the beginning then take the fast path
 			// and just adjust the existing slice. This will use extra memory
 			// temporarily but the append() in free() will realloc the slice
 			// as is necessary.
 			if (i + 1) == n {
 				f.ids = f.ids[i+1:]
 			} else {
 				copy(f.ids[i-n+1:], f.ids[i+1:])
 				f.ids = f.ids[:len(f.ids)-n]
 			}

 			// Remove from the free cache.
 			for i := pgid(0); i < pgid(n); i++ {
 				delete(f.cache, initial+i)
 			}
 			f.allocs[initial] = txid
 			return initial
 		}

 		previd = id
 	}
 	return 0
 }

 // free releases a page and its overflow for a given transaction id.
 // If the page is already free then a panic will occur.
 func (f *freelist) free(txid txid, p *page) {
 	if p.id <= 1 {
 		panic(fmt.Sprintf("cannot free page 0 or 1: %d", p.id))
 	}

 	// Free page and all its overflow pages.
 	txp := f.pending[txid]
 	if txp == nil {
 		txp = &txPending{}
 		f.pending[txid] = txp
 	}
 	allocTxid, ok := f.allocs[p.id]
 	if ok {
 		delete(f.allocs, p.id)
 	} else if (p.flags & freelistPageFlag) != 0 {
 		// Freelist is always allocated by prior tx.
 		allocTxid = txid - 1
 	}

 	for id := p.id; id <= p.id+pgid(p.overflow); id++ {
 		// Verify that page is not already free.
 		if f.cache[id] {
 			panic(fmt.Sprintf("page %d already freed", id))
 		}
 		// Add to the freelist and cache.
 		txp.ids = append(txp.ids, id)
 		txp.alloctx = append(txp.alloctx, allocTxid)
 		f.cache[id] = true
 	}
 }

 // release moves all page ids for a transaction id (or older) to the freelist.
 func (f *freelist) release(txid txid) {
 	m := make(pgids, 0)
 	for tid, txp := range f.pending {
 		if tid <= txid {
 			// Move transaction's pending pages to the available freelist.
 			// Don't remove from the cache since the page is still free.
 			m = append(m, txp.ids...)
 			delete(f.pending, tid)
 		}
 	}
 	f.mergeSpans(m)
 }

 // releaseRange moves pending pages allocated within an extent [begin,end] to the free list.
 func (f *freelist) releaseRange(begin, end txid) {
 	if begin > end {
 		return
 	}
 	var m pgids
 	for tid, txp := range f.pending {
 		if tid < begin || tid > end {
 			continue
 		}
 		// Don't recompute freed pages if ranges haven't updated.
 		if txp.lastReleaseBegin == begin {
 			continue
 		}
 		for i := 0; i < len(txp.ids); i++ {
 			if atx := txp.alloctx[i]; atx < begin || atx > end {
 				continue
 			}
 			m = append(m, txp.ids[i])
 			txp.ids[i] = txp.ids[len(txp.ids)-1]
 			txp.ids = txp.ids[:len(txp.ids)-1]
 			txp.alloctx[i] = txp.alloctx[len(txp.alloctx)-1]
 			txp.alloctx = txp.alloctx[:len(txp.alloctx)-1]
 			i--
 		}
 		txp.lastReleaseBegin = begin
 		if len(txp.ids) == 0 {
 			delete(f.pending, tid)
 		}
 	}
 	f.mergeSpans(m)
 }

 // rollback removes the pages from a given pending tx.
 func (f *freelist) rollback(txid txid) {
 	// Remove page ids from cache.
 	txp := f.pending[txid]
 	if txp == nil {
 		return
 	}
 	var m pgids
 	for i, pgid := range txp.ids {
 		delete(f.cache, pgid)
 		tx := txp.alloctx[i]
 		if tx == 0 {
 			continue
 		}
 		if tx != txid {
 			// Pending free aborted; restore page back to alloc list.
 			f.allocs[pgid] = tx
 		} else {
 			// Freed page was allocated by this txn; OK to throw away.
 			m = append(m, pgid)
 		}
 	}
 	// Remove pages from pending list and mark as free if allocated by txid.
 	delete(f.pending, txid)
 	f.mergeSpans(m)
 }

 // freed returns whether a given page is in the free list.
 func (f *freelist) freed(pgid pgid) bool {
 	return f.cache[pgid]
 }

 // read initializes the freelist from a freelist page.
 func (f *freelist) read(p *page) {
 	if (p.flags & freelistPageFlag) == 0 {
 		panic(fmt.Sprintf("invalid freelist page: %d, page type is %s", p.id, p.typ()))
 	}
 	// If the page.count is at the max uint16 value (64k) then it's considered
 	// an overflow and the size of the freelist is stored as the first element.
 	idx, count := 0, int(p.count)
 	if count == 0xFFFF {
 		idx = 1
 		count = int(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[0])
 	}

 	// Copy the list of page ids from the freelist.
 	if count == 0 {
 		f.ids = nil
 	} else {
 		ids := ((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[idx : idx+count]

 		// copy the ids, so we don't modify on the freelist page directly
 		idsCopy := make([]pgid, count)
 		copy(idsCopy, ids)
 		// Make sure they're sorted.
 		sort.Sort(pgids(idsCopy))

 		f.readIDs(idsCopy)
 	}
 }

 // arrayReadIDs initializes the freelist from a given list of ids.
 func (f *freelist) arrayReadIDs(ids []pgid) {
 	f.ids = ids
 	f.reindex()
 }

 func (f *freelist) arrayGetFreePageIDs() []pgid {
 	return f.ids
 }

 // write writes the page ids onto a freelist page. All free and pending ids are
 // saved to disk since in the event of a program crash, all pending ids will
 // become free.
 func (f *freelist) write(p *page) error {
 	// Combine the old free pgids and pgids waiting on an open transaction.

 	// Update the header flag.
 	p.flags |= freelistPageFlag

 	// The page.count can only hold up to 64k elements so if we overflow that
 	// number then we handle it by putting the size in the first element.
 	lenids := f.count()
 	if lenids == 0 {
 		p.count = uint16(lenids)
 	} else if lenids < 0xFFFF {
 		p.count = uint16(lenids)
 		f.copyall(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[:])
 	} else {
 		p.count = 0xFFFF
 		((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[0] = pgid(lenids)
 		f.copyall(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[1:])
 	}

 	return nil
 }

 // reload reads the freelist from a page and filters out pending items.
 func (f *freelist) reload(p *page) {
 	f.read(p)

 	// Build a cache of only pending pages.
 	pcache := make(map[pgid]bool)
 	for _, txp := range f.pending {
 		for _, pendingID := range txp.ids {
 			pcache[pendingID] = true
 		}
 	}

 	// Check each page in the freelist and build a new available freelist
 	// with any pages not in the pending lists.
 	var a []pgid
 	for _, id := range f.getFreePageIDs() {
 		if !pcache[id] {
 			a = append(a, id)
 		}
 	}

 	f.readIDs(a)
 }

 // noSyncReload reads the freelist from pgids and filters out pending items.
 func (f *freelist) noSyncReload(pgids []pgid) {
 	// Build a cache of only pending pages.
 	pcache := make(map[pgid]bool)
 	for _, txp := range f.pending {
 		for _, pendingID := range txp.ids {
 			pcache[pendingID] = true
 		}
 	}

 	// Check each page in the freelist and build a new available freelist
 	// with any pages not in the pending lists.
 	var a []pgid
 	for _, id := range pgids {
 		if !pcache[id] {
 			a = append(a, id)
 		}
 	}

 	f.readIDs(a)
 }

 // reindex rebuilds the free cache based on available and pending free lists.
 func (f *freelist) reindex() {
 	ids := f.getFreePageIDs()
 	f.cache = make(map[pgid]bool, len(ids))
 	for _, id := range ids {
 		f.cache[id] = true
 	}
 	for _, txp := range f.pending {
 		for _, pendingID := range txp.ids {
 			f.cache[pendingID] = true
 		}
 	}
 }

 // arrayMergeSpans try to merge list of pages(represented by pgids) with existing spans but using array
 func (f *freelist) arrayMergeSpans(ids pgids) {
 	sort.Sort(ids)
 	f.ids = pgids(f.ids).merge(ids)
 }
	package bbolt

	import (
	"fmt"
	"sort"
	"unsafe"
	)

	// txPending holds a list of pgids and corresponding allocation txns
	// that are pending to be freed.
	type txPending struct {
	ids []pgid
	alloctx []txid // txids allocating the ids
	lastReleaseBegin txid // beginning txid of last matching releaseRange
	}

	// pidSet holds the set of starting pgids which have the same span size
	type pidSet map[pgid]struct{}

	// freelist represents a list of all pages that are available for allocation.
	// It also tracks pages that have been freed but are still in use by open transactions.
	type freelist struct {
	freelistType FreelistType // freelist type
	ids []pgid // all free and available free page ids.
	allocs map[pgid]txid // mapping of txid that allocated a pgid.
	pending map[txid]*txPending // mapping of soon-to-be free page ids by tx.
	cache map[pgid]bool // fast lookup of all free and pending page ids.
	freemaps map[uint64]pidSet // key is the size of continuous pages(span), value is a set which contains the starting pgids of same size
	forwardMap map[pgid]uint64 // key is start pgid, value is its span size
	backwardMap map[pgid]uint64 // key is end pgid, value is its span size
	allocate func(txid txid, n int) pgid // the freelist allocate func
	free_count func() int // the function which gives you free page number
	mergeSpans func(ids pgids) // the mergeSpan func
	getFreePageIDs func() []pgid // get free pgids func
	readIDs func(pgids []pgid) // readIDs func reads list of pages and init the freelist
	}

	// newFreelist returns an empty, initialized freelist.
	func newFreelist(freelistType FreelistType) *freelist {
	f := &freelist{
	freelistType: freelistType,
	allocs: make(map[pgid]txid),
	pending: make(map[txid]*txPending),
	cache: make(map[pgid]bool),
	freemaps: make(map[uint64]pidSet),
	forwardMap: make(map[pgid]uint64),
	backwardMap: make(map[pgid]uint64),
	}

	if freelistType == FreelistMapType {
	f.allocate = f.hashmapAllocate
	f.free_count = f.hashmapFreeCount
	f.mergeSpans = f.hashmapMergeSpans
	f.getFreePageIDs = f.hashmapGetFreePageIDs
	f.readIDs = f.hashmapReadIDs
	} else {
	f.allocate = f.arrayAllocate
	f.free_count = f.arrayFreeCount
	f.mergeSpans = f.arrayMergeSpans
	f.getFreePageIDs = f.arrayGetFreePageIDs
	f.readIDs = f.arrayReadIDs
	}

	return f
	}

	// size returns the size of the page after serialization.
	func (f *freelist) size() int {
	n := f.count()
	if n >= 0xFFFF {
	// The first element will be used to store the count. See freelist.write.
	n++
	}
	return pageHeaderSize + (int(unsafe.Sizeof(pgid(0))) * n)
	}

	// count returns count of pages on the freelist
	func (f *freelist) count() int {
	return f.free_count() + f.pending_count()
	}

	// arrayFreeCount returns count of free pages(array version)
	func (f *freelist) arrayFreeCount() int {
	return len(f.ids)
	}

	// pending_count returns count of pending pages
	func (f *freelist) pending_count() int {
	var count int
	for _, txp := range f.pending {
	count += len(txp.ids)
	}
	return count
	}

	// copyall copies into dst a list of all free ids and all pending ids in one sorted list.
	// f.count returns the minimum length required for dst.
	func (f *freelist) copyall(dst []pgid) {
	m := make(pgids, 0, f.pending_count())
	for _, txp := range f.pending {
	m = append(m, txp.ids...)
	}
	sort.Sort(m)
	mergepgids(dst, f.getFreePageIDs(), m)
	}

	// arrayAllocate returns the starting page id of a contiguous list of pages of a given size.
	// If a contiguous block cannot be found then 0 is returned.
	func (f *freelist) arrayAllocate(txid txid, n int) pgid {
	if len(f.ids) == 0 {
	return 0
	}

	var initial, previd pgid
	for i, id := range f.ids {
	if id <= 1 {
	panic(fmt.Sprintf("invalid page allocation: %d", id))
	}

	// Reset initial page if this is not contiguous.
	if previd == 0 \|\| id-previd != 1 {
	initial = id
	}

	// If we found a contiguous block then remove it and return it.
	if (id-initial)+1 == pgid(n) {
	// If we're allocating off the beginning then take the fast path
	// and just adjust the existing slice. This will use extra memory
	// temporarily but the append() in free() will realloc the slice
	// as is necessary.
	if (i + 1) == n {
	f.ids = f.ids[i+1:]
	} else {
	copy(f.ids[i-n+1:], f.ids[i+1:])
	f.ids = f.ids[:len(f.ids)-n]
	}

	// Remove from the free cache.
	for i := pgid(0); i < pgid(n); i++ {
	delete(f.cache, initial+i)
	}
	f.allocs[initial] = txid
	return initial
	}

	previd = id
	}
	return 0
	}

	// free releases a page and its overflow for a given transaction id.
	// If the page is already free then a panic will occur.
	func (f freelist) free(txid txid, p page) {
	if p.id <= 1 {
	panic(fmt.Sprintf("cannot free page 0 or 1: %d", p.id))
	}

	// Free page and all its overflow pages.
	txp := f.pending[txid]
	if txp == nil {
	txp = &txPending{}
	f.pending[txid] = txp
	}
	allocTxid, ok := f.allocs[p.id]
	if ok {
	delete(f.allocs, p.id)
	} else if (p.flags & freelistPageFlag) != 0 {
	// Freelist is always allocated by prior tx.
	allocTxid = txid - 1
	}

	for id := p.id; id <= p.id+pgid(p.overflow); id++ {
	// Verify that page is not already free.
	if f.cache[id] {
	panic(fmt.Sprintf("page %d already freed", id))
	}
	// Add to the freelist and cache.
	txp.ids = append(txp.ids, id)
	txp.alloctx = append(txp.alloctx, allocTxid)
	f.cache[id] = true
	}
	}

	// release moves all page ids for a transaction id (or older) to the freelist.
	func (f *freelist) release(txid txid) {
	m := make(pgids, 0)
	for tid, txp := range f.pending {
	if tid <= txid {
	// Move transaction's pending pages to the available freelist.
	// Don't remove from the cache since the page is still free.
	m = append(m, txp.ids...)
	delete(f.pending, tid)
	}
	}
	f.mergeSpans(m)
	}

	// releaseRange moves pending pages allocated within an extent [begin,end] to the free list.
	func (f *freelist) releaseRange(begin, end txid) {
	if begin > end {
	return
	}
	var m pgids
	for tid, txp := range f.pending {
	if tid < begin \|\| tid > end {
	continue
	}
	// Don't recompute freed pages if ranges haven't updated.
	if txp.lastReleaseBegin == begin {
	continue
	}
	for i := 0; i < len(txp.ids); i++ {
	if atx := txp.alloctx[i]; atx < begin \|\| atx > end {
	continue
	}
	m = append(m, txp.ids[i])
	txp.ids[i] = txp.ids[len(txp.ids)-1]
	txp.ids = txp.ids[:len(txp.ids)-1]
	txp.alloctx[i] = txp.alloctx[len(txp.alloctx)-1]
	txp.alloctx = txp.alloctx[:len(txp.alloctx)-1]
	i--
	}
	txp.lastReleaseBegin = begin
	if len(txp.ids) == 0 {
	delete(f.pending, tid)
	}
	}
	f.mergeSpans(m)
	}

	// rollback removes the pages from a given pending tx.
	func (f *freelist) rollback(txid txid) {
	// Remove page ids from cache.
	txp := f.pending[txid]
	if txp == nil {
	return
	}
	var m pgids
	for i, pgid := range txp.ids {
	delete(f.cache, pgid)
	tx := txp.alloctx[i]
	if tx == 0 {
	continue
	}
	if tx != txid {
	// Pending free aborted; restore page back to alloc list.
	f.allocs[pgid] = tx
	} else {
	// Freed page was allocated by this txn; OK to throw away.
	m = append(m, pgid)
	}
	}
	// Remove pages from pending list and mark as free if allocated by txid.
	delete(f.pending, txid)
	f.mergeSpans(m)
	}

	// freed returns whether a given page is in the free list.
	func (f *freelist) freed(pgid pgid) bool {
	return f.cache[pgid]
	}

	// read initializes the freelist from a freelist page.
	func (f freelist) read(p page) {
	if (p.flags & freelistPageFlag) == 0 {
	panic(fmt.Sprintf("invalid freelist page: %d, page type is %s", p.id, p.typ()))
	}
	// If the page.count is at the max uint16 value (64k) then it's considered
	// an overflow and the size of the freelist is stored as the first element.
	idx, count := 0, int(p.count)
	if count == 0xFFFF {
	idx = 1
	count = int(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[0])
	}

	// Copy the list of page ids from the freelist.
	if count == 0 {
	f.ids = nil
	} else {
	ids := ((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[idx : idx+count]

	// copy the ids, so we don't modify on the freelist page directly
	idsCopy := make([]pgid, count)
	copy(idsCopy, ids)
	// Make sure they're sorted.
	sort.Sort(pgids(idsCopy))

	f.readIDs(idsCopy)
	}
	}

	// arrayReadIDs initializes the freelist from a given list of ids.
	func (f *freelist) arrayReadIDs(ids []pgid) {
	f.ids = ids
	f.reindex()
	}

	func (f *freelist) arrayGetFreePageIDs() []pgid {
	return f.ids
	}

	// write writes the page ids onto a freelist page. All free and pending ids are
	// saved to disk since in the event of a program crash, all pending ids will
	// become free.
	func (f freelist) write(p page) error {
	// Combine the old free pgids and pgids waiting on an open transaction.

	// Update the header flag.
	p.flags \|= freelistPageFlag

	// The page.count can only hold up to 64k elements so if we overflow that
	// number then we handle it by putting the size in the first element.
	lenids := f.count()
	if lenids == 0 {
	p.count = uint16(lenids)
	} else if lenids < 0xFFFF {
	p.count = uint16(lenids)
	f.copyall(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[:])
	} else {
	p.count = 0xFFFF
	((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[0] = pgid(lenids)
	f.copyall(((*[maxAllocSize]pgid)(unsafe.Pointer(&p.ptr)))[1:])
	}

	return nil
	}

	// reload reads the freelist from a page and filters out pending items.
	func (f freelist) reload(p page) {
	f.read(p)

	// Build a cache of only pending pages.
	pcache := make(map[pgid]bool)
	for _, txp := range f.pending {
	for _, pendingID := range txp.ids {
	pcache[pendingID] = true
	}
	}

	// Check each page in the freelist and build a new available freelist
	// with any pages not in the pending lists.
	var a []pgid
	for _, id := range f.getFreePageIDs() {
	if !pcache[id] {
	a = append(a, id)
	}
	}

	f.readIDs(a)
	}

	// noSyncReload reads the freelist from pgids and filters out pending items.
	func (f *freelist) noSyncReload(pgids []pgid) {
	// Build a cache of only pending pages.
	pcache := make(map[pgid]bool)
	for _, txp := range f.pending {
	for _, pendingID := range txp.ids {
	pcache[pendingID] = true
	}
	}

	// Check each page in the freelist and build a new available freelist
	// with any pages not in the pending lists.
	var a []pgid
	for _, id := range pgids {
	if !pcache[id] {
	a = append(a, id)
	}
	}

	f.readIDs(a)
	}

	// reindex rebuilds the free cache based on available and pending free lists.
	func (f *freelist) reindex() {
	ids := f.getFreePageIDs()
	f.cache = make(map[pgid]bool, len(ids))
	for _, id := range ids {
	f.cache[id] = true
	}
	for _, txp := range f.pending {
	for _, pendingID := range txp.ids {
	f.cache[pendingID] = true
	}
	}
	}

	// arrayMergeSpans try to merge list of pages(represented by pgids) with existing spans but using array
	func (f *freelist) arrayMergeSpans(ids pgids) {
	sort.Sort(ids)
	f.ids = pgids(f.ids).merge(ids)
	}