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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 arch provides abstractions around architecture-dependent details,
// such as syscall calling conventions, native types, etc.
package arch
import (
"fmt"
"io"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/cpuid"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/marshal"
"gvisor.dev/gvisor/pkg/sentry/arch/fpu"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/usermem"
)
// Arch describes an architecture.
type Arch int
const (
// AMD64 is the x86-64 architecture.
AMD64 Arch = iota
// ARM64 is the aarch64 architecture.
ARM64
)
// String implements fmt.Stringer.
func (a Arch) String() string {
switch a {
case AMD64:
return "amd64"
case ARM64:
return "arm64"
default:
return fmt.Sprintf("Arch(%d)", a)
}
}
// Context provides architecture-dependent information for a specific thread.
//
// NOTE(b/34169503): Currently we use uintptr here to refer to a generic native
// register value. While this will work for the foreseeable future, it isn't
// strictly correct. We may want to create some abstraction that makes this
// more clear or enables us to store values of arbitrary widths. This is
// particularly true for RegisterMap().
type Context interface {
// Arch returns the architecture for this Context.
Arch() Arch
// Native converts a generic type to a native value.
//
// Because the architecture is not specified here, we may be dealing
// with return values of varying sizes (for example ARCH_GETFS). This
// is a simple utility function to convert to the native size in these
// cases, and then we can CopyOut.
Native(val uintptr) marshal.Marshallable
// Value converts a native type back to a generic value.
// Once a value has been converted to native via the above call -- it
// can be converted back here.
Value(val marshal.Marshallable) uintptr
// Width returns the number of bytes for a native value.
Width() uint
// Fork creates a clone of the context.
Fork() Context
// SyscallNo returns the syscall number.
SyscallNo() uintptr
// SyscallSaveOrig save orignal register value.
SyscallSaveOrig()
// SyscallArgs returns the syscall arguments in an array.
SyscallArgs() SyscallArguments
// Return returns the return value for a system call.
Return() uintptr
// SetReturn sets the return value for a system call.
SetReturn(value uintptr)
// RestartSyscall reverses over the current syscall instruction, such that
// when the application resumes execution the syscall will be re-attempted.
RestartSyscall()
// RestartSyscallWithRestartBlock reverses over the current syscall
// instraction and overwrites the current syscall number with that of
// restart_syscall(2). This causes the application to restart the current
// syscall with a custom function when execution resumes.
RestartSyscallWithRestartBlock()
// IP returns the current instruction pointer.
IP() uintptr
// SetIP sets the current instruction pointer.
SetIP(value uintptr)
// Stack returns the current stack pointer.
Stack() uintptr
// SetStack sets the current stack pointer.
SetStack(value uintptr)
// TLS returns the current TLS pointer.
TLS() uintptr
// SetTLS sets the current TLS pointer. Returns false if value is invalid.
SetTLS(value uintptr) bool
// SetOldRSeqInterruptedIP sets the register that contains the old IP
// when an "old rseq" restartable sequence is interrupted.
SetOldRSeqInterruptedIP(value uintptr)
// StateData returns a pointer to underlying architecture state.
StateData() *State
// RegisterMap returns a map of all registers.
RegisterMap() (map[string]uintptr, error)
// NewSignalAct returns a new object that is equivalent to struct sigaction
// in the guest architecture.
NewSignalAct() NativeSignalAct
// NewSignalStack returns a new object that is equivalent to stack_t in the
// guest architecture.
NewSignalStack() NativeSignalStack
// SignalSetup modifies the context in preparation for handling the
// given signal.
//
// st is the stack where the signal handler frame should be
// constructed.
//
// act is the SignalAct that specifies how this signal is being
// handled.
//
// info is the SignalInfo of the signal being delivered.
//
// alt is the alternate signal stack (even if the alternate signal
// stack is not going to be used).
//
// sigset is the signal mask before entering the signal handler.
SignalSetup(st *Stack, act *SignalAct, info *SignalInfo, alt *SignalStack, sigset linux.SignalSet) error
// SignalRestore restores context after returning from a signal
// handler.
//
// st is the current thread stack.
//
// rt is true if SignalRestore is being entered from rt_sigreturn and
// false if SignalRestore is being entered from sigreturn.
// SignalRestore returns the thread's new signal mask.
SignalRestore(st *Stack, rt bool) (linux.SignalSet, SignalStack, error)
// CPUIDEmulate emulates a CPUID instruction according to current register state.
CPUIDEmulate(l log.Logger)
// SingleStep returns true if single stepping is enabled.
SingleStep() bool
// SetSingleStep enables single stepping.
SetSingleStep()
// ClearSingleStep disables single stepping.
ClearSingleStep()
// FloatingPointData will be passed to underlying save routines.
FloatingPointData() *fpu.State
// NewMmapLayout returns a layout for a new MM, where MinAddr for the
// returned layout must be no lower than min, and MaxAddr for the returned
// layout must be no higher than max. Repeated calls to NewMmapLayout may
// return different layouts.
NewMmapLayout(min, max usermem.Addr, limits *limits.LimitSet) (MmapLayout, error)
// PIELoadAddress returns a preferred load address for a
// position-independent executable within l.
PIELoadAddress(l MmapLayout) usermem.Addr
// FeatureSet returns the FeatureSet in use in this context.
FeatureSet() *cpuid.FeatureSet
// Hack around our package dependences being too broken to support the
// equivalent of arch_ptrace():
// PtracePeekUser implements ptrace(PTRACE_PEEKUSR).
PtracePeekUser(addr uintptr) (marshal.Marshallable, error)
// PtracePokeUser implements ptrace(PTRACE_POKEUSR).
PtracePokeUser(addr, data uintptr) error
// PtraceGetRegs implements ptrace(PTRACE_GETREGS) by writing the
// general-purpose registers represented by this Context to dst and
// returning the number of bytes written.
PtraceGetRegs(dst io.Writer) (int, error)
// PtraceSetRegs implements ptrace(PTRACE_SETREGS) by reading
// general-purpose registers from src into this Context and returning the
// number of bytes read.
PtraceSetRegs(src io.Reader) (int, error)
// PtraceGetRegSet implements ptrace(PTRACE_GETREGSET) by writing the
// register set given by architecture-defined value regset from this
// Context to dst and returning the number of bytes written, which must be
// less than or equal to maxlen.
PtraceGetRegSet(regset uintptr, dst io.Writer, maxlen int) (int, error)
// PtraceSetRegSet implements ptrace(PTRACE_SETREGSET) by reading the
// register set given by architecture-defined value regset from src and
// returning the number of bytes read, which must be less than or equal to
// maxlen.
PtraceSetRegSet(regset uintptr, src io.Reader, maxlen int) (int, error)
// FullRestore returns 'true' if all CPU registers must be restored
// when switching to the untrusted application. Typically a task enters
// and leaves the kernel via a system call. Platform.Switch() may
// optimize for this by not saving/restoring all registers if allowed
// by the ABI. For e.g. the amd64 ABI specifies that syscall clobbers
// %rcx and %r11. If FullRestore returns true then these optimizations
// must be disabled and all registers restored.
FullRestore() bool
}
// MmapDirection is a search direction for mmaps.
type MmapDirection int
const (
// MmapBottomUp instructs mmap to prefer lower addresses.
MmapBottomUp MmapDirection = iota
// MmapTopDown instructs mmap to prefer higher addresses.
MmapTopDown
)
// MmapLayout defines the layout of the user address space for a particular
// MemoryManager.
//
// Note that "highest address" below is always exclusive.
//
// +stateify savable
type MmapLayout struct {
// MinAddr is the lowest mappable address.
MinAddr usermem.Addr
// MaxAddr is the highest mappable address.
MaxAddr usermem.Addr
// BottomUpBase is the lowest address that may be returned for a
// MmapBottomUp mmap.
BottomUpBase usermem.Addr
// TopDownBase is the highest address that may be returned for a
// MmapTopDown mmap.
TopDownBase usermem.Addr
// DefaultDirection is the direction for most non-fixed mmaps in this
// layout.
DefaultDirection MmapDirection
// MaxStackRand is the maximum randomization to apply to stack
// allocations to maintain a proper gap between the stack and
// TopDownBase.
MaxStackRand uint64
}
// Valid returns true if this layout is valid.
func (m *MmapLayout) Valid() bool {
if m.MinAddr > m.MaxAddr {
return false
}
if m.BottomUpBase < m.MinAddr {
return false
}
if m.BottomUpBase > m.MaxAddr {
return false
}
if m.TopDownBase < m.MinAddr {
return false
}
if m.TopDownBase > m.MaxAddr {
return false
}
return true
}
// SyscallArgument is an argument supplied to a syscall implementation. The
// methods used to access the arguments are named after the ***C type name*** and
// they convert to the closest Go type available. For example, Int() refers to a
// 32-bit signed integer argument represented in Go as an int32.
//
// Using the accessor methods guarantees that the conversion between types is
// correct, taking into account size and signedness (i.e., zero-extension vs
// signed-extension).
type SyscallArgument struct {
// Prefer to use accessor methods instead of 'Value' directly.
Value uintptr
}
// SyscallArguments represents the set of arguments passed to a syscall.
type SyscallArguments [6]SyscallArgument
// Pointer returns the usermem.Addr representation of a pointer argument.
func (a SyscallArgument) Pointer() usermem.Addr {
return usermem.Addr(a.Value)
}
// Int returns the int32 representation of a 32-bit signed integer argument.
func (a SyscallArgument) Int() int32 {
return int32(a.Value)
}
// Uint returns the uint32 representation of a 32-bit unsigned integer argument.
func (a SyscallArgument) Uint() uint32 {
return uint32(a.Value)
}
// Int64 returns the int64 representation of a 64-bit signed integer argument.
func (a SyscallArgument) Int64() int64 {
return int64(a.Value)
}
// Uint64 returns the uint64 representation of a 64-bit unsigned integer argument.
func (a SyscallArgument) Uint64() uint64 {
return uint64(a.Value)
}
// SizeT returns the uint representation of a size_t argument.
func (a SyscallArgument) SizeT() uint {
return uint(a.Value)
}
// ModeT returns the int representation of a mode_t argument.
func (a SyscallArgument) ModeT() uint {
return uint(uint16(a.Value))
}
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