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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.
// +build amd64
package arch
import (
"bytes"
"fmt"
"math/rand"
"syscall"
"gvisor.dev/gvisor/pkg/cpuid"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/marshal/primitive"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/usermem"
)
// Host specifies the host architecture.
const Host = AMD64
// These constants come directly from Linux.
const (
// maxAddr64 is the maximum userspace address. It is TASK_SIZE in Linux
// for a 64-bit process.
maxAddr64 usermem.Addr = (1 << 47) - usermem.PageSize
// maxStackRand64 is the maximum randomization to apply to the stack.
// It is defined by arch/x86/mm/mmap.c:stack_maxrandom_size in Linux.
maxStackRand64 = 16 << 30 // 16 GB
// maxMmapRand64 is the maximum randomization to apply to the mmap
// layout. It is defined by arch/x86/mm/mmap.c:arch_mmap_rnd in Linux.
maxMmapRand64 = (1 << 28) * usermem.PageSize
// minGap64 is the minimum gap to leave at the top of the address space
// for the stack. It is defined by arch/x86/mm/mmap.c:MIN_GAP in Linux.
minGap64 = (128 << 20) + maxStackRand64
// preferredPIELoadAddr is the standard Linux position-independent
// executable base load address. It is ELF_ET_DYN_BASE in Linux.
//
// The Platform {Min,Max}UserAddress() may preclude loading at this
// address. See other preferredFoo comments below.
preferredPIELoadAddr usermem.Addr = maxAddr64 / 3 * 2
)
// These constants are selected as heuristics to help make the Platform's
// potentially limited address space conform as closely to Linux as possible.
const (
// Select a preferred minimum TopDownBase address.
//
// Some applications (TSAN and other *SANs) are very particular about
// the way the Linux mmap allocator layouts out the address space.
//
// TSAN in particular expects top down allocations to be made in the
// range [0x7e8000000000, 0x800000000000).
//
// The minimum TopDownBase on Linux would be:
// 0x800000000000 - minGap64 - maxMmapRand64 = 0x7efbf8000000.
//
// (minGap64 because TSAN uses a small RLIMIT_STACK.)
//
// 0x7e8000000000 is selected arbitrarily by TSAN to leave room for
// allocations below TopDownBase.
//
// N.B. ASAN and MSAN are more forgiving; ASAN allows allocations all
// the way down to 0x10007fff8000, and MSAN down to 0x700000000000.
//
// Of course, there is no hard minimum to allocation; an allocator can
// search all the way from TopDownBase to Min. However, TSAN declared
// their range "good enough".
//
// We would like to pick a TopDownBase such that it is unlikely that an
// allocator will select an address below TSAN's minimum. We achieve
// this by trying to leave a sizable gap below TopDownBase.
//
// This is all "preferred" because the layout min/max address may not
// allow us to select such a TopDownBase, in which case we have to fall
// back to a layout that TSAN may not be happy with.
preferredTopDownAllocMin usermem.Addr = 0x7e8000000000
preferredAllocationGap = 128 << 30 // 128 GB
preferredTopDownBaseMin = preferredTopDownAllocMin + preferredAllocationGap
// minMmapRand64 is the smallest we are willing to make the
// randomization to stay above preferredTopDownBaseMin.
minMmapRand64 = (1 << 26) * usermem.PageSize
)
// context64 represents an AMD64 context.
//
// +stateify savable
type context64 struct {
State
sigFPState []x86FPState // fpstate to be restored on sigreturn.
}
// Arch implements Context.Arch.
func (c *context64) Arch() Arch {
return AMD64
}
func (c *context64) copySigFPState() []x86FPState {
var sigfps []x86FPState
for _, s := range c.sigFPState {
sigfps = append(sigfps, s.fork())
}
return sigfps
}
// Fork returns an exact copy of this context.
func (c *context64) Fork() Context {
return &context64{
State: c.State.Fork(),
sigFPState: c.copySigFPState(),
}
}
// Return returns the current syscall return value.
func (c *context64) Return() uintptr {
return uintptr(c.Regs.Rax)
}
// SetReturn sets the syscall return value.
func (c *context64) SetReturn(value uintptr) {
c.Regs.Rax = uint64(value)
}
// IP returns the current instruction pointer.
func (c *context64) IP() uintptr {
return uintptr(c.Regs.Rip)
}
// SetIP sets the current instruction pointer.
func (c *context64) SetIP(value uintptr) {
c.Regs.Rip = uint64(value)
}
// Stack returns the current stack pointer.
func (c *context64) Stack() uintptr {
return uintptr(c.Regs.Rsp)
}
// SetStack sets the current stack pointer.
func (c *context64) SetStack(value uintptr) {
c.Regs.Rsp = uint64(value)
}
// TLS returns the current TLS pointer.
func (c *context64) TLS() uintptr {
return uintptr(c.Regs.Fs_base)
}
// SetTLS sets the current TLS pointer. Returns false if value is invalid.
func (c *context64) SetTLS(value uintptr) bool {
if !isValidSegmentBase(uint64(value)) {
return false
}
c.Regs.Fs = 0
c.Regs.Fs_base = uint64(value)
return true
}
// SetOldRSeqInterruptedIP implements Context.SetOldRSeqInterruptedIP.
func (c *context64) SetOldRSeqInterruptedIP(value uintptr) {
c.Regs.R10 = uint64(value)
}
// Native returns the native type for the given val.
func (c *context64) Native(val uintptr) marshal.Marshallable {
v := primitive.Uint64(val)
return &v
}
// Value returns the generic val for the given native type.
func (c *context64) Value(val marshal.Marshallable) uintptr {
return uintptr(*val.(*primitive.Uint64))
}
// Width returns the byte width of this architecture.
func (c *context64) Width() uint {
return 8
}
// FeatureSet returns the FeatureSet in use.
func (c *context64) FeatureSet() *cpuid.FeatureSet {
return c.State.FeatureSet
}
// mmapRand returns a random adjustment for randomizing an mmap layout.
func mmapRand(max uint64) usermem.Addr {
return usermem.Addr(rand.Int63n(int64(max))).RoundDown()
}
// NewMmapLayout implements Context.NewMmapLayout consistently with Linux.
func (c *context64) NewMmapLayout(min, max usermem.Addr, r *limits.LimitSet) (MmapLayout, error) {
min, ok := min.RoundUp()
if !ok {
return MmapLayout{}, syscall.EINVAL
}
if max > maxAddr64 {
max = maxAddr64
}
max = max.RoundDown()
if min > max {
return MmapLayout{}, syscall.EINVAL
}
stackSize := r.Get(limits.Stack)
// MAX_GAP in Linux.
maxGap := (max / 6) * 5
gap := usermem.Addr(stackSize.Cur)
if gap < minGap64 {
gap = minGap64
}
if gap > maxGap {
gap = maxGap
}
defaultDir := MmapTopDown
if stackSize.Cur == limits.Infinity {
defaultDir = MmapBottomUp
}
topDownMin := max - gap - maxMmapRand64
maxRand := usermem.Addr(maxMmapRand64)
if topDownMin < preferredTopDownBaseMin {
// Try to keep TopDownBase above preferredTopDownBaseMin by
// shrinking maxRand.
maxAdjust := maxRand - minMmapRand64
needAdjust := preferredTopDownBaseMin - topDownMin
if needAdjust <= maxAdjust {
maxRand -= needAdjust
}
}
rnd := mmapRand(uint64(maxRand))
l := MmapLayout{
MinAddr: min,
MaxAddr: max,
// TASK_UNMAPPED_BASE in Linux.
BottomUpBase: (max/3 + rnd).RoundDown(),
TopDownBase: (max - gap - rnd).RoundDown(),
DefaultDirection: defaultDir,
// We may have reduced the maximum randomization to keep
// TopDownBase above preferredTopDownBaseMin while maintaining
// our stack gap. Stack allocations must use that max
// randomization to avoiding eating into the gap.
MaxStackRand: uint64(maxRand),
}
// Final sanity check on the layout.
if !l.Valid() {
panic(fmt.Sprintf("Invalid MmapLayout: %+v", l))
}
return l, nil
}
// PIELoadAddress implements Context.PIELoadAddress.
func (c *context64) PIELoadAddress(l MmapLayout) usermem.Addr {
base := preferredPIELoadAddr
max, ok := base.AddLength(maxMmapRand64)
if !ok {
panic(fmt.Sprintf("preferredPIELoadAddr %#x too large", base))
}
if max > l.MaxAddr {
// preferredPIELoadAddr won't fit; fall back to the standard
// Linux behavior of 2/3 of TopDownBase. TSAN won't like this.
//
// Don't bother trying to shrink the randomization for now.
base = l.TopDownBase / 3 * 2
}
return base + mmapRand(maxMmapRand64)
}
// userStructSize is the size in bytes of Linux's struct user on amd64.
const userStructSize = 928
// PtracePeekUser implements Context.PtracePeekUser.
func (c *context64) PtracePeekUser(addr uintptr) (marshal.Marshallable, error) {
if addr&7 != 0 || addr >= userStructSize {
return nil, syscall.EIO
}
// PTRACE_PEEKUSER and PTRACE_POKEUSER are only effective on regs and
// u_debugreg, returning 0 or silently no-oping for other fields
// respectively.
if addr < uintptr(ptraceRegistersSize) {
regs := c.ptraceGetRegs()
buf := make([]byte, regs.SizeBytes())
regs.MarshalUnsafe(buf)
return c.Native(uintptr(usermem.ByteOrder.Uint64(buf[addr:]))), nil
}
// Note: x86 debug registers are missing.
return c.Native(0), nil
}
// PtracePokeUser implements Context.PtracePokeUser.
func (c *context64) PtracePokeUser(addr, data uintptr) error {
if addr&7 != 0 || addr >= userStructSize {
return syscall.EIO
}
if addr < uintptr(ptraceRegistersSize) {
regs := c.ptraceGetRegs()
buf := make([]byte, regs.SizeBytes())
regs.MarshalUnsafe(buf)
usermem.ByteOrder.PutUint64(buf[addr:], uint64(data))
_, err := c.PtraceSetRegs(bytes.NewBuffer(buf))
return err
}
// Note: x86 debug registers are missing.
return nil
}
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