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// Copyright 2018 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package usermem
import (
"bytes"
"fmt"
"unsafe"
"gvisor.dev/gvisor/pkg/gohacks"
)
// An AddrRangeSeq represents a sequence of AddrRanges.
//
// AddrRangeSeqs are immutable and may be copied by value. The zero value of
// AddrRangeSeq represents an empty sequence.
//
// An AddrRangeSeq may contain AddrRanges with a length of 0. This is necessary
// since zero-length AddrRanges are significant to MM bounds checks.
type AddrRangeSeq struct {
// If length is 0, then the AddrRangeSeq represents no AddrRanges.
// Invariants: data == 0; offset == 0; limit == 0.
//
// If length is 1, then the AddrRangeSeq represents the single
// AddrRange{offset, offset+limit}. Invariants: data == 0.
//
// Otherwise, length >= 2, and the AddrRangeSeq represents the `length`
// AddrRanges in the array of AddrRanges starting at address `data`,
// starting at `offset` bytes into the first AddrRange and limited to the
// following `limit` bytes. (AddrRanges after `limit` are still iterated,
// but are truncated to a length of 0.) Invariants: data != 0; offset <=
// data[0].Length(); limit > 0; offset+limit <= the combined length of all
// AddrRanges in the array.
data unsafe.Pointer
length int
offset Addr
limit Addr
}
// AddrRangeSeqOf returns an AddrRangeSeq representing the single AddrRange ar.
func AddrRangeSeqOf(ar AddrRange) AddrRangeSeq {
return AddrRangeSeq{
length: 1,
offset: ar.Start,
limit: ar.Length(),
}
}
// AddrRangeSeqFromSlice returns an AddrRangeSeq representing all AddrRanges in
// slice.
//
// Whether the returned AddrRangeSeq shares memory with slice is unspecified;
// clients should avoid mutating slices passed to AddrRangeSeqFromSlice.
//
// Preconditions: The combined length of all AddrRanges in slice <=
// math.MaxInt64.
func AddrRangeSeqFromSlice(slice []AddrRange) AddrRangeSeq {
var limit int64
for _, ar := range slice {
len64 := int64(ar.Length())
if len64 < 0 {
panic(fmt.Sprintf("Length of AddrRange %v overflows int64", ar))
}
sum := limit + len64
if sum < limit {
panic(fmt.Sprintf("Total length of AddrRanges %v overflows int64", slice))
}
limit = sum
}
return addrRangeSeqFromSliceLimited(slice, limit)
}
// Preconditions:
// * The combined length of all AddrRanges in slice <= limit.
// * limit >= 0.
// * If len(slice) != 0, then limit > 0.
func addrRangeSeqFromSliceLimited(slice []AddrRange, limit int64) AddrRangeSeq {
switch len(slice) {
case 0:
return AddrRangeSeq{}
case 1:
return AddrRangeSeq{
length: 1,
offset: slice[0].Start,
limit: Addr(limit),
}
default:
return AddrRangeSeq{
data: unsafe.Pointer(&slice[0]),
length: len(slice),
limit: Addr(limit),
}
}
}
// IsEmpty returns true if ars.NumRanges() == 0.
//
// Note that since AddrRangeSeq may contain AddrRanges with a length of zero,
// an AddrRange representing 0 bytes (AddrRangeSeq.NumBytes() == 0) is not
// necessarily empty.
func (ars AddrRangeSeq) IsEmpty() bool {
return ars.length == 0
}
// NumRanges returns the number of AddrRanges in ars.
func (ars AddrRangeSeq) NumRanges() int {
return ars.length
}
// NumBytes returns the number of bytes represented by ars.
func (ars AddrRangeSeq) NumBytes() int64 {
return int64(ars.limit)
}
// Head returns the first AddrRange in ars.
//
// Preconditions: !ars.IsEmpty().
func (ars AddrRangeSeq) Head() AddrRange {
if ars.length == 0 {
panic("empty AddrRangeSeq")
}
if ars.length == 1 {
return AddrRange{ars.offset, ars.offset + ars.limit}
}
ar := *(*AddrRange)(ars.data)
ar.Start += ars.offset
if ar.Length() > ars.limit {
ar.End = ar.Start + ars.limit
}
return ar
}
// Tail returns an AddrRangeSeq consisting of all AddrRanges in ars after the
// first.
//
// Preconditions: !ars.IsEmpty().
func (ars AddrRangeSeq) Tail() AddrRangeSeq {
if ars.length == 0 {
panic("empty AddrRangeSeq")
}
if ars.length == 1 {
return AddrRangeSeq{}
}
return ars.externalTail()
}
// Preconditions: ars.length >= 2.
func (ars AddrRangeSeq) externalTail() AddrRangeSeq {
headLen := (*AddrRange)(ars.data).Length() - ars.offset
var tailLimit int64
if ars.limit > headLen {
tailLimit = int64(ars.limit - headLen)
}
var extSlice []AddrRange
extSliceHdr := (*gohacks.SliceHeader)(unsafe.Pointer(&extSlice))
extSliceHdr.Data = ars.data
extSliceHdr.Len = ars.length
extSliceHdr.Cap = ars.length
return addrRangeSeqFromSliceLimited(extSlice[1:], tailLimit)
}
// DropFirst returns an AddrRangeSeq equivalent to ars, but with the first n
// bytes omitted. If n > ars.NumBytes(), DropFirst returns an empty
// AddrRangeSeq.
//
// If !ars.IsEmpty() and ars.Head().Length() == 0, DropFirst will always omit
// at least ars.Head(), even if n == 0. This guarantees that the basic pattern
// of:
//
// for !ars.IsEmpty() {
// n, err = doIOWith(ars.Head())
// if err != nil {
// return err
// }
// ars = ars.DropFirst(n)
// }
//
// works even in the presence of zero-length AddrRanges.
//
// Preconditions: n >= 0.
func (ars AddrRangeSeq) DropFirst(n int) AddrRangeSeq {
if n < 0 {
panic(fmt.Sprintf("invalid n: %d", n))
}
return ars.DropFirst64(int64(n))
}
// DropFirst64 is equivalent to DropFirst but takes an int64.
func (ars AddrRangeSeq) DropFirst64(n int64) AddrRangeSeq {
if n < 0 {
panic(fmt.Sprintf("invalid n: %d", n))
}
if Addr(n) > ars.limit {
return AddrRangeSeq{}
}
// Handle initial empty AddrRange.
switch ars.length {
case 0:
return AddrRangeSeq{}
case 1:
if ars.limit == 0 {
return AddrRangeSeq{}
}
default:
if rawHeadLen := (*AddrRange)(ars.data).Length(); ars.offset == rawHeadLen {
ars = ars.externalTail()
}
}
for n != 0 {
// Calling ars.Head() here is surprisingly expensive, so inline getting
// the head's length.
var headLen Addr
if ars.length == 1 {
headLen = ars.limit
} else {
headLen = (*AddrRange)(ars.data).Length() - ars.offset
}
if Addr(n) < headLen {
// Dropping ends partway through the head AddrRange.
ars.offset += Addr(n)
ars.limit -= Addr(n)
return ars
}
n -= int64(headLen)
ars = ars.Tail()
}
return ars
}
// TakeFirst returns an AddrRangeSeq equivalent to ars, but iterating at most n
// bytes. TakeFirst never removes AddrRanges from ars; AddrRanges beyond the
// first n bytes are reduced to a length of zero, but will still be iterated.
//
// Preconditions: n >= 0.
func (ars AddrRangeSeq) TakeFirst(n int) AddrRangeSeq {
if n < 0 {
panic(fmt.Sprintf("invalid n: %d", n))
}
return ars.TakeFirst64(int64(n))
}
// TakeFirst64 is equivalent to TakeFirst but takes an int64.
func (ars AddrRangeSeq) TakeFirst64(n int64) AddrRangeSeq {
if n < 0 {
panic(fmt.Sprintf("invalid n: %d", n))
}
if ars.limit > Addr(n) {
ars.limit = Addr(n)
}
return ars
}
// String implements fmt.Stringer.String.
func (ars AddrRangeSeq) String() string {
// This is deliberately chosen to be the same as fmt's automatic stringer
// for []AddrRange.
var buf bytes.Buffer
buf.WriteByte('[')
var sep string
for !ars.IsEmpty() {
buf.WriteString(sep)
sep = " "
buf.WriteString(ars.Head().String())
ars = ars.Tail()
}
buf.WriteByte(']')
return buf.String()
}
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