src/runtime/mranges.go - go - Git at Google

 // Copyright 2019 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.

 // Address range data structure.
 //
 // This file contains an implementation of a data structure which
 // manages ordered address ranges.

 package runtime

 import (
 	"runtime/internal/sys"
 	"unsafe"
 )

 // addrRange represents a region of address space.
 type addrRange struct {
 	// base and limit together represent the region of address space
 	// [base, limit). That is, base is inclusive, limit is exclusive.
 	base, limit uintptr
 }

 // size returns the size of the range represented in bytes.
 func (a addrRange) size() uintptr {
 	if a.limit <= a.base {
 		return 0
 	}
 	return a.limit - a.base
 }

 // contains returns whether or not the range contains a given address.
 func (a addrRange) contains(addr uintptr) bool {
 	return addr >= a.base && addr < a.limit
 }

 // subtract takes the addrRange toPrune and cuts out any overlap with
 // from, then returns the new range. subtract assumes that a and b
 // either don't overlap at all, only overlap on one side, or are equal.
 // If b is strictly contained in a, thus forcing a split, it will throw.
 func (a addrRange) subtract(b addrRange) addrRange {
 	if a.base >= b.base && a.limit <= b.limit {
 		return addrRange{}
 	} else if a.base < b.base && a.limit > b.limit {
 		throw("bad prune")
 	} else if a.limit > b.limit && a.base < b.limit {
 		a.base = b.limit
 	} else if a.base < b.base && a.limit > b.base {
 		a.limit = b.base
 	}
 	return a
 }

 // addrRanges is a data structure holding a collection of ranges of
 // address space.
 //
 // The ranges are coalesced eagerly to reduce the
 // number ranges it holds.
 //
 // The slice backing store for this field is persistentalloc'd
 // and thus there is no way to free it.
 //
 // addrRanges is not thread-safe.
 type addrRanges struct {
 	// ranges is a slice of ranges sorted by base.
 	ranges []addrRange

 	// sysStat is the stat to track allocations by this type
 	sysStat *uint64
 }

 func (a *addrRanges) init(sysStat *uint64) {
 	ranges := (*notInHeapSlice)(unsafe.Pointer(&a.ranges))
 	ranges.len = 0
 	ranges.cap = 16
 	ranges.array = (*notInHeap)(persistentalloc(unsafe.Sizeof(addrRange{})*uintptr(ranges.cap), sys.PtrSize, sysStat))
 	a.sysStat = sysStat
 }

 // findSucc returns the first index in a such that base is
 // less than the base of the addrRange at that index.
 func (a *addrRanges) findSucc(base uintptr) int {
 	// TODO(mknyszek): Consider a binary search for large arrays.
 	// While iterating over these ranges is potentially expensive,
 	// the expected number of ranges is small, ideally just 1,
 	// since Go heaps are usually mostly contiguous.
 	for i := range a.ranges {
 		if base < a.ranges[i].base {
 			return i
 		}
 	}
 	return len(a.ranges)
 }

 // contains returns true if a covers the address addr.
 func (a *addrRanges) contains(addr uintptr) bool {
 	i := a.findSucc(addr)
 	if i == 0 {
 		return false
 	}
 	return a.ranges[i-1].contains(addr)
 }

 // add inserts a new address range to a.
 //
 // r must not overlap with any address range in a.
 func (a *addrRanges) add(r addrRange) {
 	// The copies in this function are potentially expensive, but this data
 	// structure is meant to represent the Go heap. At worst, copying this
 	// would take ~160µs assuming a conservative copying rate of 25 GiB/s (the
 	// copy will almost never trigger a page fault) for a 1 TiB heap with 4 MiB
 	// arenas which is completely discontiguous. ~160µs is still a lot, but in
 	// practice most platforms have 64 MiB arenas (which cuts this by a factor
 	// of 16) and Go heaps are usually mostly contiguous, so the chance that
 	// an addrRanges even grows to that size is extremely low.

 	// Because we assume r is not currently represented in a,
 	// findSucc gives us our insertion index.
 	i := a.findSucc(r.base)
 	coalescesDown := i > 0 && a.ranges[i-1].limit == r.base
 	coalescesUp := i < len(a.ranges) && r.limit == a.ranges[i].base
 	if coalescesUp && coalescesDown {
 		// We have neighbors and they both border us.
 		// Merge a.ranges[i-1], r, and a.ranges[i] together into a.ranges[i-1].
 		a.ranges[i-1].limit = a.ranges[i].limit

 		// Delete a.ranges[i].
 		copy(a.ranges[i:], a.ranges[i+1:])
 		a.ranges = a.ranges[:len(a.ranges)-1]
 	} else if coalescesDown {
 		// We have a neighbor at a lower address only and it borders us.
 		// Merge the new space into a.ranges[i-1].
 		a.ranges[i-1].limit = r.limit
 	} else if coalescesUp {
 		// We have a neighbor at a higher address only and it borders us.
 		// Merge the new space into a.ranges[i].
 		a.ranges[i].base = r.base
 	} else {
 		// We may or may not have neighbors which don't border us.
 		// Add the new range.
 		if len(a.ranges)+1 > cap(a.ranges) {
 			// Grow the array. Note that this leaks the old array, but since
 			// we're doubling we have at most 2x waste. For a 1 TiB heap and
 			// 4 MiB arenas which are all discontiguous (both very conservative
 			// assumptions), this would waste at most 4 MiB of memory.
 			oldRanges := a.ranges
 			ranges := (*notInHeapSlice)(unsafe.Pointer(&a.ranges))
 			ranges.len = len(oldRanges) + 1
 			ranges.cap = cap(oldRanges) * 2
 			ranges.array = (*notInHeap)(persistentalloc(unsafe.Sizeof(addrRange{})*uintptr(ranges.cap), sys.PtrSize, a.sysStat))

 			// Copy in the old array, but make space for the new range.
 			copy(a.ranges[:i], oldRanges[:i])
 			copy(a.ranges[i+1:], oldRanges[i:])
 		} else {
 			a.ranges = a.ranges[:len(a.ranges)+1]
 			copy(a.ranges[i+1:], a.ranges[i:])
 		}
 		a.ranges[i] = r
 	}
 }
	// Copyright 2019 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.

	// Address range data structure.
	//
	// This file contains an implementation of a data structure which
	// manages ordered address ranges.

	package runtime

	import (
	"runtime/internal/sys"
	"unsafe"
	)

	// addrRange represents a region of address space.
	type addrRange struct {
	// base and limit together represent the region of address space
	// [base, limit). That is, base is inclusive, limit is exclusive.
	base, limit uintptr
	}

	// size returns the size of the range represented in bytes.
	func (a addrRange) size() uintptr {
	if a.limit <= a.base {
	return 0
	}
	return a.limit - a.base
	}

	// contains returns whether or not the range contains a given address.
	func (a addrRange) contains(addr uintptr) bool {
	return addr >= a.base && addr < a.limit
	}

	// subtract takes the addrRange toPrune and cuts out any overlap with
	// from, then returns the new range. subtract assumes that a and b
	// either don't overlap at all, only overlap on one side, or are equal.
	// If b is strictly contained in a, thus forcing a split, it will throw.
	func (a addrRange) subtract(b addrRange) addrRange {
	if a.base >= b.base && a.limit <= b.limit {
	return addrRange{}
	} else if a.base < b.base && a.limit > b.limit {
	throw("bad prune")
	} else if a.limit > b.limit && a.base < b.limit {
	a.base = b.limit
	} else if a.base < b.base && a.limit > b.base {
	a.limit = b.base
	}
	return a
	}

	// addrRanges is a data structure holding a collection of ranges of
	// address space.
	//
	// The ranges are coalesced eagerly to reduce the
	// number ranges it holds.
	//
	// The slice backing store for this field is persistentalloc'd
	// and thus there is no way to free it.
	//
	// addrRanges is not thread-safe.
	type addrRanges struct {
	// ranges is a slice of ranges sorted by base.
	ranges []addrRange

	// sysStat is the stat to track allocations by this type
	sysStat *uint64
	}

	func (a addrRanges) init(sysStat uint64) {
	ranges := (*notInHeapSlice)(unsafe.Pointer(&a.ranges))
	ranges.len = 0
	ranges.cap = 16
	ranges.array = (notInHeap)(persistentalloc(unsafe.Sizeof(addrRange{})uintptr(ranges.cap), sys.PtrSize, sysStat))
	a.sysStat = sysStat
	}

	// findSucc returns the first index in a such that base is
	// less than the base of the addrRange at that index.
	func (a *addrRanges) findSucc(base uintptr) int {
	// TODO(mknyszek): Consider a binary search for large arrays.
	// While iterating over these ranges is potentially expensive,
	// the expected number of ranges is small, ideally just 1,
	// since Go heaps are usually mostly contiguous.
	for i := range a.ranges {
	if base < a.ranges[i].base {
	return i
	}
	}
	return len(a.ranges)
	}

	// contains returns true if a covers the address addr.
	func (a *addrRanges) contains(addr uintptr) bool {
	i := a.findSucc(addr)
	if i == 0 {
	return false
	}
	return a.ranges[i-1].contains(addr)
	}

	// add inserts a new address range to a.
	//
	// r must not overlap with any address range in a.
	func (a *addrRanges) add(r addrRange) {
	// The copies in this function are potentially expensive, but this data
	// structure is meant to represent the Go heap. At worst, copying this
	// would take ~160µs assuming a conservative copying rate of 25 GiB/s (the
	// copy will almost never trigger a page fault) for a 1 TiB heap with 4 MiB
	// arenas which is completely discontiguous. ~160µs is still a lot, but in
	// practice most platforms have 64 MiB arenas (which cuts this by a factor
	// of 16) and Go heaps are usually mostly contiguous, so the chance that
	// an addrRanges even grows to that size is extremely low.

	// Because we assume r is not currently represented in a,
	// findSucc gives us our insertion index.
	i := a.findSucc(r.base)
	coalescesDown := i > 0 && a.ranges[i-1].limit == r.base
	coalescesUp := i < len(a.ranges) && r.limit == a.ranges[i].base
	if coalescesUp && coalescesDown {
	// We have neighbors and they both border us.
	// Merge a.ranges[i-1], r, and a.ranges[i] together into a.ranges[i-1].
	a.ranges[i-1].limit = a.ranges[i].limit

	// Delete a.ranges[i].
	copy(a.ranges[i:], a.ranges[i+1:])
	a.ranges = a.ranges[:len(a.ranges)-1]
	} else if coalescesDown {
	// We have a neighbor at a lower address only and it borders us.
	// Merge the new space into a.ranges[i-1].
	a.ranges[i-1].limit = r.limit
	} else if coalescesUp {
	// We have a neighbor at a higher address only and it borders us.
	// Merge the new space into a.ranges[i].
	a.ranges[i].base = r.base
	} else {
	// We may or may not have neighbors which don't border us.
	// Add the new range.
	if len(a.ranges)+1 > cap(a.ranges) {
	// Grow the array. Note that this leaks the old array, but since
	// we're doubling we have at most 2x waste. For a 1 TiB heap and
	// 4 MiB arenas which are all discontiguous (both very conservative
	// assumptions), this would waste at most 4 MiB of memory.
	oldRanges := a.ranges
	ranges := (*notInHeapSlice)(unsafe.Pointer(&a.ranges))
	ranges.len = len(oldRanges) + 1
	ranges.cap = cap(oldRanges) * 2
	ranges.array = (notInHeap)(persistentalloc(unsafe.Sizeof(addrRange{})uintptr(ranges.cap), sys.PtrSize, a.sysStat))

	// Copy in the old array, but make space for the new range.
	copy(a.ranges[:i], oldRanges[:i])
	copy(a.ranges[i+1:], oldRanges[i:])
	} else {
	a.ranges = a.ranges[:len(a.ranges)+1]
	copy(a.ranges[i+1:], a.ranges[i:])
	}
	a.ranges[i] = r
	}
	}