starlark/int_posix64.go - platform/external/starlark-go - Git at Google

 // For the android builds, ignore this file to avoid dependency
 // on yet another package (golang.org/x/sys/unix)
 //+build ignore

 package starlark

 // This file defines an optimized Int implementation for 64-bit machines
 // running POSIX. It reserves a 4GB portion of the address space using
 // mmap and represents int32 values as addresses within that range. This
 // disambiguates int32 values from *big.Int pointers, letting all Int
 // values be represented as an unsafe.Pointer, so that Int-to-Value
 // interface conversion need not allocate.

 // Although iOS (arm64,darwin) claims to be a POSIX-compliant,
 // it limits each process to about 700MB of virtual address space,
 // which defeats the optimization.
 //
 // TODO(golang.org/issue/38485): darwin,arm64 may refer to macOS in the future.
 // Update this when there are distinct GOOS values for macOS, iOS, and other Apple
 // operating systems on arm64.

 import (
 	"log"
 	"math"
 	"math/big"
 	"unsafe"

 	"golang.org/x/sys/unix"
 )

 // intImpl represents a union of (int32, *big.Int) in a single pointer,
 // so that Int-to-Value conversions need not allocate.
 //
 // The pointer is either a *big.Int, if the value is big, or a pointer into a
 // reserved portion of the address space (smallints), if the value is small.
 //
 // See int_generic.go for the basic representation concepts.
 type intImpl unsafe.Pointer

 // get returns the (small, big) arms of the union.
 func (i Int) get() (int64, *big.Int) {
 	ptr := uintptr(i.impl)
 	if ptr >= smallints && ptr < smallints+1<<32 {
 		return math.MinInt32 + int64(ptr-smallints), nil
 	}
 	return 0, (*big.Int)(i.impl)
 }

 // Precondition: math.MinInt32 <= x && x <= math.MaxInt32
 func makeSmallInt(x int64) Int {
 	return Int{intImpl(uintptr(x-math.MinInt32) + smallints)}
 }

 // Precondition: x cannot be represented as int32.
 func makeBigInt(x *big.Int) Int { return Int{intImpl(x)} }

 // smallints is the base address of a 2^32 byte memory region.
 // Pointers to addresses in this region represent int32 values.
 // We assume smallints is not at the very top of the address space.
 var smallints = reserveAddresses(1 << 32)

 func reserveAddresses(len int) uintptr {
 	b, err := unix.Mmap(-1, 0, len, unix.PROT_READ, unix.MAP_PRIVATE|unix.MAP_ANON)
 	if err != nil {
 		log.Fatalf("mmap: %v", err)
 	}
 	return uintptr(unsafe.Pointer(&b[0]))
 }
	// For the android builds, ignore this file to avoid dependency
	// on yet another package (golang.org/x/sys/unix)
	//+build ignore

	package starlark

	// This file defines an optimized Int implementation for 64-bit machines
	// running POSIX. It reserves a 4GB portion of the address space using
	// mmap and represents int32 values as addresses within that range. This
	// disambiguates int32 values from *big.Int pointers, letting all Int
	// values be represented as an unsafe.Pointer, so that Int-to-Value
	// interface conversion need not allocate.

	// Although iOS (arm64,darwin) claims to be a POSIX-compliant,
	// it limits each process to about 700MB of virtual address space,
	// which defeats the optimization.
	//
	// TODO(golang.org/issue/38485): darwin,arm64 may refer to macOS in the future.
	// Update this when there are distinct GOOS values for macOS, iOS, and other Apple
	// operating systems on arm64.

	import (
	"log"
	"math"
	"math/big"
	"unsafe"

	"golang.org/x/sys/unix"
	)

	// intImpl represents a union of (int32, *big.Int) in a single pointer,
	// so that Int-to-Value conversions need not allocate.
	//
	// The pointer is either a *big.Int, if the value is big, or a pointer into a
	// reserved portion of the address space (smallints), if the value is small.
	//
	// See int_generic.go for the basic representation concepts.
	type intImpl unsafe.Pointer

	// get returns the (small, big) arms of the union.
	func (i Int) get() (int64, *big.Int) {
	ptr := uintptr(i.impl)
	if ptr >= smallints && ptr < smallints+1<<32 {
	return math.MinInt32 + int64(ptr-smallints), nil
	}
	return 0, (*big.Int)(i.impl)
	}

	// Precondition: math.MinInt32 <= x && x <= math.MaxInt32
	func makeSmallInt(x int64) Int {
	return Int{intImpl(uintptr(x-math.MinInt32) + smallints)}
	}

	// Precondition: x cannot be represented as int32.
	func makeBigInt(x *big.Int) Int { return Int{intImpl(x)} }

	// smallints is the base address of a 2^32 byte memory region.
	// Pointers to addresses in this region represent int32 values.
	// We assume smallints is not at the very top of the address space.
	var smallints = reserveAddresses(1 << 32)

	func reserveAddresses(len int) uintptr {
	b, err := unix.Mmap(-1, 0, len, unix.PROT_READ, unix.MAP_PRIVATE\|unix.MAP_ANON)
	if err != nil {
	log.Fatalf("mmap: %v", err)
	}
	return uintptr(unsafe.Pointer(&b[0]))
	}