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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 kernel
import (
"fmt"
"sync/atomic"
"gvisor.dev/gvisor/pkg/abi"
"gvisor.dev/gvisor/pkg/bits"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/usermem"
)
// maxSyscallNum is the highest supported syscall number.
//
// The types below create fast lookup slices for all syscalls. This maximum
// serves as a sanity check that we don't allocate huge slices for a very large
// syscall. This is checked during registration.
const maxSyscallNum = 2000
// SyscallSupportLevel is a syscall support levels.
type SyscallSupportLevel int
// String returns a human readable represetation of the support level.
func (l SyscallSupportLevel) String() string {
switch l {
case SupportUnimplemented:
return "Unimplemented"
case SupportPartial:
return "Partial Support"
case SupportFull:
return "Full Support"
default:
return "Undocumented"
}
}
const (
// SupportUndocumented indicates the syscall is not documented yet.
SupportUndocumented = iota
// SupportUnimplemented indicates the syscall is unimplemented.
SupportUnimplemented
// SupportPartial indicates the syscall is partially supported.
SupportPartial
// SupportFull indicates the syscall is fully supported.
SupportFull
)
// Syscall includes the syscall implementation and compatibility information.
type Syscall struct {
// Name is the syscall name.
Name string
// Fn is the implementation of the syscall.
Fn SyscallFn
// SupportLevel is the level of support implemented in gVisor.
SupportLevel SyscallSupportLevel
// Note describes the compatibility of the syscall.
Note string
// URLs is set of URLs to any relevant bugs or issues.
URLs []string
}
// SyscallFn is a syscall implementation.
type SyscallFn func(t *Task, args arch.SyscallArguments) (uintptr, *SyscallControl, error)
// MissingFn is a syscall to be called when an implementation is missing.
type MissingFn func(t *Task, sysno uintptr, args arch.SyscallArguments) (uintptr, error)
// Possible flags for SyscallFlagsTable.enable.
const (
// syscallPresent indicates that this is not a missing syscall.
//
// This flag is used internally in SyscallFlagsTable.
syscallPresent = 1 << iota
// StraceEnableLog enables syscall log tracing.
StraceEnableLog
// StraceEnableEvent enables syscall event tracing.
StraceEnableEvent
// ExternalBeforeEnable enables the external hook before syscall execution.
ExternalBeforeEnable
// ExternalAfterEnable enables the external hook after syscall execution.
ExternalAfterEnable
)
// StraceEnableBits combines both strace log and event flags.
const StraceEnableBits = StraceEnableLog | StraceEnableEvent
// SyscallFlagsTable manages a set of enable/disable bit fields on a per-syscall
// basis.
type SyscallFlagsTable struct {
// mu protects writes to the fields below.
//
// Atomic loads are always allowed. Atomic stores are allowed only
// while mu is held.
mu sync.Mutex
// enable contains the enable bits for each syscall.
//
// missing syscalls have the same value in enable as missingEnable to
// avoid an extra branch in Word.
enable []uint32
// missingEnable contains the enable bits for missing syscalls.
missingEnable uint32
}
// Init initializes the struct, with all syscalls in table set to enable.
//
// max is the largest syscall number in table.
func (e *SyscallFlagsTable) init(table map[uintptr]Syscall, max uintptr) {
e.enable = make([]uint32, max+1)
for num := range table {
e.enable[num] = syscallPresent
}
}
// Word returns the enable bitfield for sysno.
func (e *SyscallFlagsTable) Word(sysno uintptr) uint32 {
if sysno < uintptr(len(e.enable)) {
return atomic.LoadUint32(&e.enable[sysno])
}
return atomic.LoadUint32(&e.missingEnable)
}
// Enable sets enable bit bit for all syscalls based on s.
//
// Syscalls missing from s are disabled.
//
// Syscalls missing from the initial table passed to Init cannot be added as
// individual syscalls. If present in s they will be ignored.
//
// Callers to Word may see either the old or new value while this function
// is executing.
func (e *SyscallFlagsTable) Enable(bit uint32, s map[uintptr]bool, missingEnable bool) {
e.mu.Lock()
defer e.mu.Unlock()
missingVal := atomic.LoadUint32(&e.missingEnable)
if missingEnable {
missingVal |= bit
} else {
missingVal &^= bit
}
atomic.StoreUint32(&e.missingEnable, missingVal)
for num := range e.enable {
val := atomic.LoadUint32(&e.enable[num])
if !bits.IsOn32(val, syscallPresent) {
// Missing.
atomic.StoreUint32(&e.enable[num], missingVal)
continue
}
if s[uintptr(num)] {
val |= bit
} else {
val &^= bit
}
atomic.StoreUint32(&e.enable[num], val)
}
}
// EnableAll sets enable bit bit for all syscalls, present and missing.
func (e *SyscallFlagsTable) EnableAll(bit uint32) {
e.mu.Lock()
defer e.mu.Unlock()
missingVal := atomic.LoadUint32(&e.missingEnable)
missingVal |= bit
atomic.StoreUint32(&e.missingEnable, missingVal)
for num := range e.enable {
val := atomic.LoadUint32(&e.enable[num])
if !bits.IsOn32(val, syscallPresent) {
// Missing.
atomic.StoreUint32(&e.enable[num], missingVal)
continue
}
val |= bit
atomic.StoreUint32(&e.enable[num], val)
}
}
// Stracer traces syscall execution.
type Stracer interface {
// SyscallEnter is called on syscall entry.
//
// The returned private data is passed to SyscallExit.
SyscallEnter(t *Task, sysno uintptr, args arch.SyscallArguments, flags uint32) interface{}
// SyscallExit is called on syscall exit.
SyscallExit(context interface{}, t *Task, sysno, rval uintptr, err error)
}
// SyscallTable is a lookup table of system calls.
//
// Note that a SyscallTable is not savable directly. Instead, they are saved as
// an OS/Arch pair and lookup happens again on restore.
type SyscallTable struct {
// OS is the operating system that this syscall table implements.
OS abi.OS
// Arch is the architecture that this syscall table targets.
Arch arch.Arch
// The OS version that this syscall table implements.
Version Version
// AuditNumber is a numeric constant that represents the syscall table. If
// non-zero, auditNumber must be one of the AUDIT_ARCH_* values defined by
// linux/audit.h.
AuditNumber uint32
// Table is the collection of functions.
Table map[uintptr]Syscall
// lookup is a fixed-size array that holds the syscalls (indexed by
// their numbers). It is used for fast look ups.
lookup []SyscallFn
// Emulate is a collection of instruction addresses to emulate. The
// keys are addresses, and the values are system call numbers.
Emulate map[usermem.Addr]uintptr
// The function to call in case of a missing system call.
Missing MissingFn
// Stracer traces this syscall table.
Stracer Stracer
// External is used to handle an external callback.
External func(*Kernel)
// ExternalFilterBefore is called before External is called before the syscall is executed.
// External is not called if it returns false.
ExternalFilterBefore func(*Task, uintptr, arch.SyscallArguments) bool
// ExternalFilterAfter is called before External is called after the syscall is executed.
// External is not called if it returns false.
ExternalFilterAfter func(*Task, uintptr, arch.SyscallArguments) bool
// FeatureEnable stores the strace and one-shot enable bits.
FeatureEnable SyscallFlagsTable
}
// MaxSysno returns the largest system call number.
func (s *SyscallTable) MaxSysno() (max uintptr) {
for num := range s.Table {
if num > max {
max = num
}
}
return max
}
// allSyscallTables contains all known tables.
var allSyscallTables []*SyscallTable
// SyscallTables returns a read-only slice of registered SyscallTables.
func SyscallTables() []*SyscallTable {
return allSyscallTables
}
// LookupSyscallTable returns the SyscallCall table for the OS/Arch combination.
func LookupSyscallTable(os abi.OS, a arch.Arch) (*SyscallTable, bool) {
for _, s := range allSyscallTables {
if s.OS == os && s.Arch == a {
return s, true
}
}
return nil, false
}
// RegisterSyscallTable registers a new syscall table for use by a Kernel.
func RegisterSyscallTable(s *SyscallTable) {
if max := s.MaxSysno(); max > maxSyscallNum {
panic(fmt.Sprintf("SyscallTable %+v contains too large syscall number %d", s, max))
}
if _, ok := LookupSyscallTable(s.OS, s.Arch); ok {
panic(fmt.Sprintf("Duplicate SyscallTable registered for OS %v Arch %v", s.OS, s.Arch))
}
allSyscallTables = append(allSyscallTables, s)
s.Init()
}
// Init initializes the system call table.
//
// This should normally be called only during registration.
func (s *SyscallTable) Init() {
if s.Table == nil {
// Ensure non-nil lookup table.
s.Table = make(map[uintptr]Syscall)
}
if s.Emulate == nil {
// Ensure non-nil emulate table.
s.Emulate = make(map[usermem.Addr]uintptr)
}
max := s.MaxSysno() // Checked during RegisterSyscallTable.
// Initialize the fast-lookup table.
s.lookup = make([]SyscallFn, max+1)
for num, sc := range s.Table {
s.lookup[num] = sc.Fn
}
// Initialize all features.
s.FeatureEnable.init(s.Table, max)
}
// Lookup returns the syscall implementation, if one exists.
func (s *SyscallTable) Lookup(sysno uintptr) SyscallFn {
if sysno < uintptr(len(s.lookup)) {
return s.lookup[sysno]
}
return nil
}
// LookupName looks up a syscall name.
func (s *SyscallTable) LookupName(sysno uintptr) string {
if sc, ok := s.Table[sysno]; ok {
return sc.Name
}
return fmt.Sprintf("sys_%d", sysno) // Unlikely.
}
// LookupEmulate looks up an emulation syscall number.
func (s *SyscallTable) LookupEmulate(addr usermem.Addr) (uintptr, bool) {
sysno, ok := s.Emulate[addr]
return sysno, ok
}
// mapLookup is similar to Lookup, except that it only uses the syscall table,
// that is, it skips the fast look array. This is available for benchmarking.
func (s *SyscallTable) mapLookup(sysno uintptr) SyscallFn {
if sc, ok := s.Table[sysno]; ok {
return sc.Fn
}
return nil
}
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