// 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 buffer provides the implementation of a buffer view. package buffer import ( "bytes" "fmt" "io" ) // View is a slice of a buffer, with convenience methods. type View []byte // NewView allocates a new buffer and returns an initialized view that covers // the whole buffer. func NewView(size int) View { return make(View, size) } // NewViewFromBytes allocates a new buffer and copies in the given bytes. func NewViewFromBytes(b []byte) View { return append(View(nil), b...) } // TrimFront removes the first "count" bytes from the visible section of the // buffer. func (v *View) TrimFront(count int) { *v = (*v)[count:] } // CapLength irreversibly reduces the length of the visible section of the // buffer to the value specified. func (v *View) CapLength(length int) { // We also set the slice cap because if we don't, one would be able to // expand the view back to include the region just excluded. We want to // prevent that to avoid potential data leak if we have uninitialized // data in excluded region. *v = (*v)[:length:length] } // Reader returns a bytes.Reader for v. func (v *View) Reader() bytes.Reader { var r bytes.Reader r.Reset(*v) return r } // ToVectorisedView returns a VectorisedView containing the receiver. func (v View) ToVectorisedView() VectorisedView { if len(v) == 0 { return VectorisedView{} } return NewVectorisedView(len(v), []View{v}) } // IsEmpty returns whether v is of length zero. func (v View) IsEmpty() bool { return len(v) == 0 } // Size returns the length of v. func (v View) Size() int { return len(v) } // VectorisedView is a vectorised version of View using non contiguous memory. // It supports all the convenience methods supported by View. // // +stateify savable type VectorisedView struct { views []View size int } // NewVectorisedView creates a new vectorised view from an already-allocated // slice of View and sets its size. func NewVectorisedView(size int, views []View) VectorisedView { return VectorisedView{views: views, size: size} } // TrimFront removes the first "count" bytes of the vectorised view. It panics // if count > vv.Size(). func (vv *VectorisedView) TrimFront(count int) { for count > 0 && len(vv.views) > 0 { if count < len(vv.views[0]) { vv.size -= count vv.views[0].TrimFront(count) return } count -= len(vv.views[0]) vv.removeFirst() } } // Read implements io.Reader. func (vv *VectorisedView) Read(b []byte) (copied int, err error) { count := len(b) for count > 0 && len(vv.views) > 0 { if count < len(vv.views[0]) { vv.size -= count copy(b[copied:], vv.views[0][:count]) vv.views[0].TrimFront(count) copied += count return copied, nil } count -= len(vv.views[0]) copy(b[copied:], vv.views[0]) copied += len(vv.views[0]) vv.removeFirst() } if copied == 0 { return 0, io.EOF } return copied, nil } // ReadToVV reads up to n bytes from vv to dstVV and removes them from vv. It // returns the number of bytes copied. func (vv *VectorisedView) ReadToVV(dstVV *VectorisedView, count int) (copied int) { for count > 0 && len(vv.views) > 0 { if count < len(vv.views[0]) { vv.size -= count dstVV.AppendView(vv.views[0][:count]) vv.views[0].TrimFront(count) copied += count return } count -= len(vv.views[0]) dstVV.AppendView(vv.views[0]) copied += len(vv.views[0]) vv.removeFirst() } return copied } // ReadTo reads up to count bytes from vv to dst. It also removes them from vv // unless peek is true. func (vv *VectorisedView) ReadTo(dst io.Writer, peek bool) (int, error) { var err error done := 0 for _, v := range vv.Views() { var n int n, err = dst.Write(v) done += n if err != nil { break } if n != len(v) { panic(fmt.Sprintf("io.Writer.Write succeeded with incomplete write: %d != %d", n, len(v))) } } if !peek { vv.TrimFront(done) } return done, err } // CapLength irreversibly reduces the length of the vectorised view. func (vv *VectorisedView) CapLength(length int) { if length < 0 { length = 0 } if vv.size < length { return } vv.size = length for i := range vv.views { v := &vv.views[i] if len(*v) >= length { if length == 0 { vv.views = vv.views[:i] } else { v.CapLength(length) vv.views = vv.views[:i+1] } return } length -= len(*v) } } // Clone returns a clone of this VectorisedView. // If the buffer argument is large enough to contain all the Views of this // VectorisedView, the method will avoid allocations and use the buffer to // store the Views of the clone. func (vv *VectorisedView) Clone(buffer []View) VectorisedView { return VectorisedView{views: append(buffer[:0], vv.views...), size: vv.size} } // PullUp returns the first "count" bytes of the vectorised view. If those // bytes aren't already contiguous inside the vectorised view, PullUp will // reallocate as needed to make them contiguous. PullUp fails and returns false // when count > vv.Size(). func (vv *VectorisedView) PullUp(count int) (View, bool) { if len(vv.views) == 0 { return nil, count == 0 } if count <= len(vv.views[0]) { return vv.views[0][:count], true } if count > vv.size { return nil, false } newFirst := NewView(count) i := 0 for offset := 0; offset < count; i++ { copy(newFirst[offset:], vv.views[i]) if count-offset < len(vv.views[i]) { vv.views[i].TrimFront(count - offset) break } offset += len(vv.views[i]) vv.views[i] = nil } // We're guaranteed that i > 0, since count is too large for the first // view. vv.views[i-1] = newFirst vv.views = vv.views[i-1:] return newFirst, true } // Size returns the size in bytes of the entire content stored in the // vectorised view. func (vv *VectorisedView) Size() int { return vv.size } // ToView returns a single view containing the content of the vectorised view. // // If the vectorised view contains a single view, that view will be returned // directly. func (vv *VectorisedView) ToView() View { if len(vv.views) == 1 { return vv.views[0] } return vv.ToOwnedView() } // ToOwnedView returns a single view containing the content of the vectorised // view that vv does not own. func (vv *VectorisedView) ToOwnedView() View { u := make([]byte, 0, vv.size) for _, v := range vv.views { u = append(u, v...) } return u } // Views returns the slice containing the all views. func (vv *VectorisedView) Views() []View { return vv.views } // Append appends the views in a vectorised view to this vectorised view. func (vv *VectorisedView) Append(vv2 VectorisedView) { vv.views = append(vv.views, vv2.views...) vv.size += vv2.size } // AppendView appends the given view into this vectorised view. func (vv *VectorisedView) AppendView(v View) { if len(v) == 0 { return } vv.views = append(vv.views, v) vv.size += len(v) } // Readers returns a bytes.Reader for each of vv's views. func (vv *VectorisedView) Readers() []bytes.Reader { readers := make([]bytes.Reader, 0, len(vv.views)) for _, v := range vv.views { readers = append(readers, v.Reader()) } return readers } // removeFirst panics when len(vv.views) < 1. func (vv *VectorisedView) removeFirst() { vv.size -= len(vv.views[0]) vv.views[0] = nil vv.views = vv.views[1:] }