vendor/github.com/boljen/go-bitmap/atomic.go - voltha-openolt-adapter - Gitiles

 package bitmap

 import (
 	"sync/atomic"
 	"unsafe"
 )

 var oobPanic = "SetAtomic not allowed on a bitmapSlice of cap() < 4"

 // SetAtomic is similar to Set except that it performs the operation atomically.
 func SetAtomic(bitmap []byte, targetBit int, targetValue bool) {
 	ov := (*[1]uint32)(unsafe.Pointer(&bitmap[targetBit/32]))[:]
 	SetAtomicUint32(ov, targetBit%32, targetValue)
 }

 // SetAtomic is similar to Set except that it performs the operation atomically.
 // It needs a bitmapSlice where the capacity is at least 4 bytes.
 func _SetAtomic(bitmapSlice []byte, targetBit int, targetValue bool) {
 	targetByteIndex := targetBit / 8
 	targetBitIndex := targetBit % 8
 	targetOffset := 0

 	// SetAtomic needs to modify 4 bytes of data so we panic when the slice
 	// doesn't have a capacity of at least 4 bytes.
 	if cap(bitmapSlice) < 4 {
 		panic(oobPanic)
 	}

 	// Calculate the Offset of the targetByte inside the 4-byte atomic batch.
 	// This is needed to ensure that atomic operations can happen as long as
 	// the bitmapSlice equals 4 bytes or more.
 	if cap(bitmapSlice) < targetByteIndex+3 {
 		targetOffset = cap(bitmapSlice) - targetByteIndex
 	}

 	// This gets a pointer to the memory of 4 bytes inside the bitmapSlice.
 	// It stores this pointer as an *uint32 so that it can be used to
 	// execute sync.atomic operations.
 	targetBytePointer := (*uint32)(unsafe.Pointer(&bitmapSlice[targetByteIndex-targetOffset]))

 	for {
 		// localValue is a copy of the uint32 value at *targetBytePointer.
 		// It's used to check whether the targetBit must be updated,
 		// and if so, to construct the new value for targetBytePointer.
 		localValue := atomic.LoadUint32(targetBytePointer)

 		// This "neutralizes" the uint32 conversion by getting a pointer to the
 		// 4-byte array stored undereneath the uint32.
 		targetByteCopyPointer := (*[4]byte)(unsafe.Pointer(&localValue))

 		// Work is done when targetBit is already set to targetValue.
 		if GetBit(targetByteCopyPointer[targetOffset], targetBitIndex) == targetValue {
 			return
 		}

 		// Modify the targetBit and update memory so that the targetBit is the only bit
 		// that has been modified in the batch.
 		referenceValue := localValue
 		SetBitRef(&targetByteCopyPointer[targetOffset], targetBitIndex, targetValue)
 		if atomic.CompareAndSwapUint32(targetBytePointer, referenceValue, localValue) {
 			break
 		}
 	}
 }
	package bitmap

	import (
	"sync/atomic"
	"unsafe"
	)

	var oobPanic = "SetAtomic not allowed on a bitmapSlice of cap() < 4"

	// SetAtomic is similar to Set except that it performs the operation atomically.
	func SetAtomic(bitmap []byte, targetBit int, targetValue bool) {
	ov := (*[1]uint32)(unsafe.Pointer(&bitmap[targetBit/32]))[:]
	SetAtomicUint32(ov, targetBit%32, targetValue)
	}

	// SetAtomic is similar to Set except that it performs the operation atomically.
	// It needs a bitmapSlice where the capacity is at least 4 bytes.
	func _SetAtomic(bitmapSlice []byte, targetBit int, targetValue bool) {
	targetByteIndex := targetBit / 8
	targetBitIndex := targetBit % 8
	targetOffset := 0

	// SetAtomic needs to modify 4 bytes of data so we panic when the slice
	// doesn't have a capacity of at least 4 bytes.
	if cap(bitmapSlice) < 4 {
	panic(oobPanic)
	}

	// Calculate the Offset of the targetByte inside the 4-byte atomic batch.
	// This is needed to ensure that atomic operations can happen as long as
	// the bitmapSlice equals 4 bytes or more.
	if cap(bitmapSlice) < targetByteIndex+3 {
	targetOffset = cap(bitmapSlice) - targetByteIndex
	}

	// This gets a pointer to the memory of 4 bytes inside the bitmapSlice.
	// It stores this pointer as an *uint32 so that it can be used to
	// execute sync.atomic operations.
	targetBytePointer := (*uint32)(unsafe.Pointer(&bitmapSlice[targetByteIndex-targetOffset]))

	for {
	// localValue is a copy of the uint32 value at *targetBytePointer.
	// It's used to check whether the targetBit must be updated,
	// and if so, to construct the new value for targetBytePointer.
	localValue := atomic.LoadUint32(targetBytePointer)

	// This "neutralizes" the uint32 conversion by getting a pointer to the
	// 4-byte array stored undereneath the uint32.
	targetByteCopyPointer := (*[4]byte)(unsafe.Pointer(&localValue))

	// Work is done when targetBit is already set to targetValue.
	if GetBit(targetByteCopyPointer[targetOffset], targetBitIndex) == targetValue {
	return
	}

	// Modify the targetBit and update memory so that the targetBit is the only bit
	// that has been modified in the batch.
	referenceValue := localValue
	SetBitRef(&targetByteCopyPointer[targetOffset], targetBitIndex, targetValue)
	if atomic.CompareAndSwapUint32(targetBytePointer, referenceValue, localValue) {
	break
	}
	}
	}