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// Copyright 2018 Google Inc.
//
// 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.
// +build amd64
package pagetables
import (
"fmt"
)
// Address constraints.
//
// The lowerTop and upperBottom currently apply to four-level pagetables;
// additional refactoring would be necessary to support five-level pagetables.
const (
lowerTop = 0x00007fffffffffff
upperBottom = 0xffff800000000000
pteShift = 12
pmdShift = 21
pudShift = 30
pgdShift = 39
pteMask = 0x1ff << pteShift
pmdMask = 0x1ff << pmdShift
pudMask = 0x1ff << pudShift
pgdMask = 0x1ff << pgdShift
pteSize = 1 << pteShift
pmdSize = 1 << pmdShift
pudSize = 1 << pudShift
pgdSize = 1 << pgdShift
executeDisable = 1 << 63
entriesPerPage = 512
)
// PTEs is a collection of entries.
type PTEs [entriesPerPage]PTE
// next returns the next address quantized by the given size.
func next(start uint64, size uint64) uint64 {
start &= ^(size - 1)
start += size
return start
}
// iterateRange iterates over all appropriate levels of page tables for the given range.
//
// If alloc is set, then Set _must_ be called on all given PTEs. The exception
// is super pages. If a valid super page cannot be installed, then the walk
// will continue to individual entries.
//
// This algorithm will attempt to maximize the use of super pages whenever
// possible. Whether a super page is provided will be clear through the range
// provided in the callback.
//
// Note that if alloc set, then no gaps will be present. However, if alloc is
// not set, then the iteration will likely be full of gaps.
//
// Note that this function should generally be avoided in favor of Map, Unmap,
// etc. when not necessary.
//
// Precondition: startAddr and endAddr must be page-aligned.
//
// Precondition: startStart must be less than endAddr.
//
// Precondition: If alloc is set, then startAddr and endAddr should not span
// non-canonical ranges. If they do, a panic will result.
func (p *PageTables) iterateRange(startAddr, endAddr uintptr, alloc bool, fn func(s, e uintptr, pte *PTE, align uintptr)) {
start := uint64(startAddr)
end := uint64(endAddr)
if start%pteSize != 0 {
panic(fmt.Sprintf("unaligned start: %v", start))
}
if start > end {
panic(fmt.Sprintf("start > end (%v > %v))", start, end))
}
// Deal with cases where we traverse the "gap".
//
// These are all explicitly disallowed if alloc is set, and we must
// traverse an entry for each address explicitly.
switch {
case start < lowerTop && end > lowerTop && end < upperBottom:
if alloc {
panic(fmt.Sprintf("alloc [%x, %x) spans non-canonical range", start, end))
}
p.iterateRange(startAddr, lowerTop, false, fn)
return
case start < lowerTop && end > lowerTop:
if alloc {
panic(fmt.Sprintf("alloc [%x, %x) spans non-canonical range", start, end))
}
p.iterateRange(startAddr, lowerTop, false, fn)
p.iterateRange(upperBottom, endAddr, false, fn)
return
case start > lowerTop && end < upperBottom:
if alloc {
panic(fmt.Sprintf("alloc [%x, %x) spans non-canonical range", start, end))
}
return
case start > lowerTop && start < upperBottom && end > upperBottom:
if alloc {
panic(fmt.Sprintf("alloc [%x, %x) spans non-canonical range", start, end))
}
p.iterateRange(upperBottom, endAddr, false, fn)
return
}
for pgdIndex := int((start & pgdMask) >> pgdShift); start < end && pgdIndex < entriesPerPage; pgdIndex++ {
pgdEntry := &p.root.PTEs()[pgdIndex]
if !pgdEntry.Valid() {
if !alloc {
// Skip over this entry.
start = next(start, pgdSize)
continue
}
// Allocate a new pgd.
p.setPageTable(p.root, pgdIndex, p.allocNode())
}
// Map the next level.
pudNode := p.getPageTable(p.root, pgdIndex)
clearPUDEntries := 0
for pudIndex := int((start & pudMask) >> pudShift); start < end && pudIndex < entriesPerPage; pudIndex++ {
pudEntry := &(pudNode.PTEs()[pudIndex])
if !pudEntry.Valid() {
if !alloc {
// Skip over this entry.
clearPUDEntries++
start = next(start, pudSize)
continue
}
// This level has 1-GB super pages. Is this
// entire region contained in a single PUD
// entry? If so, we can skip allocating a new
// page for the pmd.
if start&(pudSize-1) == 0 && end-start >= pudSize {
pudEntry.SetSuper()
fn(uintptr(start), uintptr(start+pudSize), pudEntry, pudSize-1)
if pudEntry.Valid() {
start = next(start, pudSize)
continue
}
}
// Allocate a new pud.
p.setPageTable(pudNode, pudIndex, p.allocNode())
} else if pudEntry.IsSuper() {
// Does this page need to be split?
if start&(pudSize-1) != 0 || end < next(start, pudSize) {
currentAddr := uint64(pudEntry.Address())
// Install the relevant entries.
pmdNode := p.allocNode()
pmdEntries := pmdNode.PTEs()
for index := 0; index < entriesPerPage; index++ {
pmdEntry := &pmdEntries[index]
pmdEntry.SetSuper()
pmdEntry.Set(uintptr(currentAddr), pudEntry.Opts())
currentAddr += pmdSize
}
// Reset to point to the new page.
p.setPageTable(pudNode, pudIndex, pmdNode)
} else {
// A super page to be checked directly.
fn(uintptr(start), uintptr(start+pudSize), pudEntry, pudSize-1)
// Might have been cleared.
if !pudEntry.Valid() {
clearPUDEntries++
}
// Note that the super page was changed.
start = next(start, pudSize)
continue
}
}
// Map the next level, since this is valid.
pmdNode := p.getPageTable(pudNode, pudIndex)
clearPMDEntries := 0
for pmdIndex := int((start & pmdMask) >> pmdShift); start < end && pmdIndex < entriesPerPage; pmdIndex++ {
pmdEntry := &pmdNode.PTEs()[pmdIndex]
if !pmdEntry.Valid() {
if !alloc {
// Skip over this entry.
clearPMDEntries++
start = next(start, pmdSize)
continue
}
// This level has 2-MB huge pages. If this
// region is contained in a single PMD entry?
// As above, we can skip allocating a new page.
if start&(pmdSize-1) == 0 && end-start >= pmdSize {
pmdEntry.SetSuper()
fn(uintptr(start), uintptr(start+pmdSize), pmdEntry, pmdSize-1)
if pmdEntry.Valid() {
start = next(start, pmdSize)
continue
}
}
// Allocate a new pmd.
p.setPageTable(pmdNode, pmdIndex, p.allocNode())
} else if pmdEntry.IsSuper() {
// Does this page need to be split?
if start&(pmdSize-1) != 0 || end < next(start, pmdSize) {
currentAddr := uint64(pmdEntry.Address())
// Install the relevant entries.
pteNode := p.allocNode()
pteEntries := pteNode.PTEs()
for index := 0; index < entriesPerPage; index++ {
pteEntry := &pteEntries[index]
pteEntry.Set(uintptr(currentAddr), pmdEntry.Opts())
currentAddr += pteSize
}
// Reset to point to the new page.
p.setPageTable(pmdNode, pmdIndex, pteNode)
} else {
// A huge page to be checked directly.
fn(uintptr(start), uintptr(start+pmdSize), pmdEntry, pmdSize-1)
// Might have been cleared.
if !pmdEntry.Valid() {
clearPMDEntries++
}
// Note that the huge page was changed.
start = next(start, pmdSize)
continue
}
}
// Map the next level, since this is valid.
pteNode := p.getPageTable(pmdNode, pmdIndex)
clearPTEEntries := 0
for pteIndex := int((start & pteMask) >> pteShift); start < end && pteIndex < entriesPerPage; pteIndex++ {
pteEntry := &pteNode.PTEs()[pteIndex]
if !pteEntry.Valid() && !alloc {
clearPTEEntries++
start += pteSize
continue
}
// At this point, we are guaranteed that start%pteSize == 0.
fn(uintptr(start), uintptr(start+pteSize), pteEntry, pteSize-1)
if !pteEntry.Valid() {
if alloc {
panic("PTE not set after iteration with alloc=true!")
}
clearPTEEntries++
}
// Note that the pte was changed.
start += pteSize
continue
}
// Check if we no longer need this page.
if clearPTEEntries == entriesPerPage {
p.clearPageTable(pmdNode, pmdIndex)
clearPMDEntries++
}
}
// Check if we no longer need this page.
if clearPMDEntries == entriesPerPage {
p.clearPageTable(pudNode, pudIndex)
clearPUDEntries++
}
}
// Check if we no longer need this page.
if clearPUDEntries == entriesPerPage {
p.clearPageTable(p.root, pgdIndex)
}
}
}
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