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// Copyright 2024 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build goexperiment.swissmap
package maps
import (
"internal/abi"
"internal/asan"
"internal/msan"
"internal/race"
"internal/runtime/sys"
"unsafe"
)
// Functions below pushed from runtime.
//go:linkname mapKeyError
func mapKeyError(typ *abi.SwissMapType, p unsafe.Pointer) error
// Pushed from runtime in order to use runtime.plainError
//
//go:linkname errNilAssign
var errNilAssign error
// Pull from runtime. It is important that is this the exact same copy as the
// runtime because runtime.mapaccess1_fat compares the returned pointer with
// &runtime.zeroVal[0].
// TODO: move zeroVal to internal/abi?
//
//go:linkname zeroVal runtime.zeroVal
var zeroVal [abi.ZeroValSize]byte
// mapaccess1 returns a pointer to h[key]. Never returns nil, instead
// it will return a reference to the zero object for the elem type if
// the key is not in the map.
// NOTE: The returned pointer may keep the whole map live, so don't
// hold onto it for very long.
//
//go:linkname runtime_mapaccess1 runtime.mapaccess1
func runtime_mapaccess1(typ *abi.SwissMapType, m *Map, key unsafe.Pointer) unsafe.Pointer {
if race.Enabled && m != nil {
callerpc := sys.GetCallerPC()
pc := abi.FuncPCABIInternal(runtime_mapaccess1)
race.ReadPC(unsafe.Pointer(m), callerpc, pc)
race.ReadObjectPC(typ.Key, key, callerpc, pc)
}
if msan.Enabled && m != nil {
msan.Read(key, typ.Key.Size_)
}
if asan.Enabled && m != nil {
asan.Read(key, typ.Key.Size_)
}
if m == nil || m.Used() == 0 {
if err := mapKeyError(typ, key); err != nil {
panic(err) // see issue 23734
}
return unsafe.Pointer(&zeroVal[0])
}
if m.writing != 0 {
fatal("concurrent map read and map write")
}
hash := typ.Hasher(key, m.seed)
if m.dirLen <= 0 {
_, elem, ok := m.getWithKeySmall(typ, hash, key)
if !ok {
return unsafe.Pointer(&zeroVal[0])
}
return elem
}
// Select table.
idx := m.directoryIndex(hash)
t := m.directoryAt(idx)
// Probe table.
seq := makeProbeSeq(h1(hash), t.groups.lengthMask)
for ; ; seq = seq.next() {
g := t.groups.group(typ, seq.offset)
match := g.ctrls().matchH2(h2(hash))
for match != 0 {
i := match.first()
slotKey := g.key(typ, i)
slotKeyOrig := slotKey
if typ.IndirectKey() {
slotKey = *((*unsafe.Pointer)(slotKey))
}
if typ.Key.Equal(key, slotKey) {
slotElem := unsafe.Pointer(uintptr(slotKeyOrig) + typ.ElemOff)
if typ.IndirectElem() {
slotElem = *((*unsafe.Pointer)(slotElem))
}
return slotElem
}
match = match.removeFirst()
}
match = g.ctrls().matchEmpty()
if match != 0 {
// Finding an empty slot means we've reached the end of
// the probe sequence.
return unsafe.Pointer(&zeroVal[0])
}
}
}
//go:linkname runtime_mapaccess2 runtime.mapaccess2
func runtime_mapaccess2(typ *abi.SwissMapType, m *Map, key unsafe.Pointer) (unsafe.Pointer, bool) {
if race.Enabled && m != nil {
callerpc := sys.GetCallerPC()
pc := abi.FuncPCABIInternal(runtime_mapaccess1)
race.ReadPC(unsafe.Pointer(m), callerpc, pc)
race.ReadObjectPC(typ.Key, key, callerpc, pc)
}
if msan.Enabled && m != nil {
msan.Read(key, typ.Key.Size_)
}
if asan.Enabled && m != nil {
asan.Read(key, typ.Key.Size_)
}
if m == nil || m.Used() == 0 {
if err := mapKeyError(typ, key); err != nil {
panic(err) // see issue 23734
}
return unsafe.Pointer(&zeroVal[0]), false
}
if m.writing != 0 {
fatal("concurrent map read and map write")
}
hash := typ.Hasher(key, m.seed)
if m.dirLen == 0 {
_, elem, ok := m.getWithKeySmall(typ, hash, key)
if !ok {
return unsafe.Pointer(&zeroVal[0]), false
}
return elem, true
}
// Select table.
idx := m.directoryIndex(hash)
t := m.directoryAt(idx)
// Probe table.
seq := makeProbeSeq(h1(hash), t.groups.lengthMask)
for ; ; seq = seq.next() {
g := t.groups.group(typ, seq.offset)
match := g.ctrls().matchH2(h2(hash))
for match != 0 {
i := match.first()
slotKey := g.key(typ, i)
slotKeyOrig := slotKey
if typ.IndirectKey() {
slotKey = *((*unsafe.Pointer)(slotKey))
}
if typ.Key.Equal(key, slotKey) {
slotElem := unsafe.Pointer(uintptr(slotKeyOrig) + typ.ElemOff)
if typ.IndirectElem() {
slotElem = *((*unsafe.Pointer)(slotElem))
}
return slotElem, true
}
match = match.removeFirst()
}
match = g.ctrls().matchEmpty()
if match != 0 {
// Finding an empty slot means we've reached the end of
// the probe sequence.
return unsafe.Pointer(&zeroVal[0]), false
}
}
}
//go:linkname runtime_mapassign runtime.mapassign
func runtime_mapassign(typ *abi.SwissMapType, m *Map, key unsafe.Pointer) unsafe.Pointer {
if m == nil {
panic(errNilAssign)
}
if race.Enabled {
callerpc := sys.GetCallerPC()
pc := abi.FuncPCABIInternal(runtime_mapassign)
race.WritePC(unsafe.Pointer(m), callerpc, pc)
race.ReadObjectPC(typ.Key, key, callerpc, pc)
}
if msan.Enabled {
msan.Read(key, typ.Key.Size_)
}
if asan.Enabled {
asan.Read(key, typ.Key.Size_)
}
if m.writing != 0 {
fatal("concurrent map writes")
}
hash := typ.Hasher(key, m.seed)
// Set writing after calling Hasher, since Hasher may panic, in which
// case we have not actually done a write.
m.writing ^= 1 // toggle, see comment on writing
if m.dirPtr == nil {
m.growToSmall(typ)
}
if m.dirLen == 0 {
if m.used < abi.SwissMapGroupSlots {
elem := m.putSlotSmall(typ, hash, key)
if m.writing == 0 {
fatal("concurrent map writes")
}
m.writing ^= 1
return elem
}
// Can't fit another entry, grow to full size map.
m.growToTable(typ)
}
var slotElem unsafe.Pointer
outer:
for {
// Select table.
idx := m.directoryIndex(hash)
t := m.directoryAt(idx)
seq := makeProbeSeq(h1(hash), t.groups.lengthMask)
// As we look for a match, keep track of the first deleted slot
// we find, which we'll use to insert the new entry if
// necessary.
var firstDeletedGroup groupReference
var firstDeletedSlot uintptr
for ; ; seq = seq.next() {
g := t.groups.group(typ, seq.offset)
match := g.ctrls().matchH2(h2(hash))
// Look for an existing slot containing this key.
for match != 0 {
i := match.first()
slotKey := g.key(typ, i)
slotKeyOrig := slotKey
if typ.IndirectKey() {
slotKey = *((*unsafe.Pointer)(slotKey))
}
if typ.Key.Equal(key, slotKey) {
if typ.NeedKeyUpdate() {
typedmemmove(typ.Key, slotKey, key)
}
slotElem = unsafe.Pointer(uintptr(slotKeyOrig) + typ.ElemOff)
if typ.IndirectElem() {
slotElem = *((*unsafe.Pointer)(slotElem))
}
t.checkInvariants(typ, m)
break outer
}
match = match.removeFirst()
}
// No existing slot for this key in this group. Is this the end
// of the probe sequence?
match = g.ctrls().matchEmpty()
if match != 0 {
// Finding an empty slot means we've reached the end of
// the probe sequence.
var i uintptr
// If we found a deleted slot along the way, we
// can replace it without consuming growthLeft.
if firstDeletedGroup.data != nil {
g = firstDeletedGroup
i = firstDeletedSlot
t.growthLeft++ // will be decremented below to become a no-op.
} else {
// Otherwise, use the empty slot.
i = match.first()
}
// If there is room left to grow, just insert the new entry.
if t.growthLeft > 0 {
slotKey := g.key(typ, i)
slotKeyOrig := slotKey
if typ.IndirectKey() {
kmem := newobject(typ.Key)
*(*unsafe.Pointer)(slotKey) = kmem
slotKey = kmem
}
typedmemmove(typ.Key, slotKey, key)
slotElem = unsafe.Pointer(uintptr(slotKeyOrig) + typ.ElemOff)
if typ.IndirectElem() {
emem := newobject(typ.Elem)
*(*unsafe.Pointer)(slotElem) = emem
slotElem = emem
}
g.ctrls().set(i, ctrl(h2(hash)))
t.growthLeft--
t.used++
m.used++
t.checkInvariants(typ, m)
break outer
}
t.rehash(typ, m)
continue outer
}
// No empty slots in this group. Check for a deleted
// slot, which we'll use if we don't find a match later
// in the probe sequence.
//
// We only need to remember a single deleted slot.
if firstDeletedGroup.data == nil {
// Since we already checked for empty slots
// above, matches here must be deleted slots.
match = g.ctrls().matchEmptyOrDeleted()
if match != 0 {
firstDeletedGroup = g
firstDeletedSlot = match.first()
}
}
}
}
if m.writing == 0 {
fatal("concurrent map writes")
}
m.writing ^= 1
return slotElem
}
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