1
0
mirror of https://github.com/golang/go synced 2024-11-19 16:44:43 -07:00
go/src/runtime/syscall_windows_test.go

1011 lines
23 KiB
Go
Raw Normal View History

// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package runtime_test
import (
"bytes"
"fmt"
"internal/syscall/windows/sysdll"
"internal/testenv"
"io/ioutil"
"os"
"os/exec"
"path/filepath"
"runtime"
"strings"
"syscall"
"testing"
"unsafe"
)
type DLL struct {
*syscall.DLL
t *testing.T
}
func GetDLL(t *testing.T, name string) *DLL {
d, e := syscall.LoadDLL(name)
if e != nil {
t.Fatal(e)
}
return &DLL{DLL: d, t: t}
}
func (d *DLL) Proc(name string) *syscall.Proc {
p, e := d.FindProc(name)
if e != nil {
d.t.Fatal(e)
}
return p
}
func TestStdCall(t *testing.T) {
type Rect struct {
left, top, right, bottom int32
}
res := Rect{}
expected := Rect{1, 1, 40, 60}
a, _, _ := GetDLL(t, "user32.dll").Proc("UnionRect").Call(
uintptr(unsafe.Pointer(&res)),
uintptr(unsafe.Pointer(&Rect{10, 1, 14, 60})),
uintptr(unsafe.Pointer(&Rect{1, 2, 40, 50})))
if a != 1 || res.left != expected.left ||
res.top != expected.top ||
res.right != expected.right ||
res.bottom != expected.bottom {
t.Error("stdcall USER32.UnionRect returns", a, "res=", res)
}
}
func Test64BitReturnStdCall(t *testing.T) {
const (
VER_BUILDNUMBER = 0x0000004
VER_MAJORVERSION = 0x0000002
VER_MINORVERSION = 0x0000001
VER_PLATFORMID = 0x0000008
VER_PRODUCT_TYPE = 0x0000080
VER_SERVICEPACKMAJOR = 0x0000020
VER_SERVICEPACKMINOR = 0x0000010
VER_SUITENAME = 0x0000040
VER_EQUAL = 1
VER_GREATER = 2
VER_GREATER_EQUAL = 3
VER_LESS = 4
VER_LESS_EQUAL = 5
ERROR_OLD_WIN_VERSION syscall.Errno = 1150
)
type OSVersionInfoEx struct {
OSVersionInfoSize uint32
MajorVersion uint32
MinorVersion uint32
BuildNumber uint32
PlatformId uint32
CSDVersion [128]uint16
ServicePackMajor uint16
ServicePackMinor uint16
SuiteMask uint16
ProductType byte
Reserve byte
}
d := GetDLL(t, "kernel32.dll")
var m1, m2 uintptr
VerSetConditionMask := d.Proc("VerSetConditionMask")
m1, m2, _ = VerSetConditionMask.Call(m1, m2, VER_MAJORVERSION, VER_GREATER_EQUAL)
m1, m2, _ = VerSetConditionMask.Call(m1, m2, VER_MINORVERSION, VER_GREATER_EQUAL)
m1, m2, _ = VerSetConditionMask.Call(m1, m2, VER_SERVICEPACKMAJOR, VER_GREATER_EQUAL)
m1, m2, _ = VerSetConditionMask.Call(m1, m2, VER_SERVICEPACKMINOR, VER_GREATER_EQUAL)
vi := OSVersionInfoEx{
MajorVersion: 5,
MinorVersion: 1,
ServicePackMajor: 2,
ServicePackMinor: 0,
}
vi.OSVersionInfoSize = uint32(unsafe.Sizeof(vi))
r, _, e2 := d.Proc("VerifyVersionInfoW").Call(
uintptr(unsafe.Pointer(&vi)),
VER_MAJORVERSION|VER_MINORVERSION|VER_SERVICEPACKMAJOR|VER_SERVICEPACKMINOR,
m1, m2)
if r == 0 && e2 != ERROR_OLD_WIN_VERSION {
t.Errorf("VerifyVersionInfo failed: %s", e2)
}
}
func TestCDecl(t *testing.T) {
var buf [50]byte
fmtp, _ := syscall.BytePtrFromString("%d %d %d")
a, _, _ := GetDLL(t, "user32.dll").Proc("wsprintfA").Call(
uintptr(unsafe.Pointer(&buf[0])),
uintptr(unsafe.Pointer(fmtp)),
1000, 2000, 3000)
if string(buf[:a]) != "1000 2000 3000" {
t.Error("cdecl USER32.wsprintfA returns", a, "buf=", buf[:a])
}
}
func TestEnumWindows(t *testing.T) {
d := GetDLL(t, "user32.dll")
isWindows := d.Proc("IsWindow")
counter := 0
cb := syscall.NewCallback(func(hwnd syscall.Handle, lparam uintptr) uintptr {
if lparam != 888 {
t.Error("lparam was not passed to callback")
}
b, _, _ := isWindows.Call(uintptr(hwnd))
if b == 0 {
t.Error("USER32.IsWindow returns FALSE")
}
counter++
return 1 // continue enumeration
})
a, _, _ := d.Proc("EnumWindows").Call(cb, 888)
if a == 0 {
t.Error("USER32.EnumWindows returns FALSE")
}
if counter == 0 {
t.Error("Callback has been never called or your have no windows")
}
}
func callback(hwnd syscall.Handle, lparam uintptr) uintptr {
(*(*func())(unsafe.Pointer(&lparam)))()
return 0 // stop enumeration
}
// nestedCall calls into Windows, back into Go, and finally to f.
func nestedCall(t *testing.T, f func()) {
c := syscall.NewCallback(callback)
d := GetDLL(t, "user32.dll")
defer d.Release()
d.Proc("EnumWindows").Call(c, uintptr(*(*unsafe.Pointer)(unsafe.Pointer(&f))))
}
func TestCallback(t *testing.T) {
var x = false
nestedCall(t, func() { x = true })
if !x {
t.Fatal("nestedCall did not call func")
}
}
func TestCallbackGC(t *testing.T) {
nestedCall(t, runtime.GC)
}
runtime: handle Go calls C calls Go panic correctly on windows/386 32-bit Windows uses "structured exception handling" (SEH) to handle hardware faults: that there is a per-thread linked list of fault handlers maintained in user space instead of something like Unix's signal handlers. The structures in the linked list are required to live on the OS stack, and the usual discipline is that the function that pushes a record (allocated from the current stack frame) onto the list pops that record before returning. Not to pop the entry before returning creates a dangling pointer error: the list head points to a stack frame that no longer exists. Go pushes an SEH record in the top frame of every OS thread, and that record suffices for all Go execution on that thread, at least until cgo gets involved. If we call into C using cgo, that called C code may push its own SEH records, but by the convention it must pop them before returning back to the Go code. We assume it does, and that's fine. If the C code calls back into Go, we want the Go SEH handler to become active again, not whatever C has set up. So runtime.callbackasm1, which handles a call from C back into Go, pushes a new SEH record before calling the Go code and pops it when the Go code returns. That's also fine. It can happen that when Go calls C calls Go like this, the inner Go code panics. We allow a defer in the outer Go to recover the panic, effectively wiping not only the inner Go frames but also the C calls. This sequence was not popping the SEH stack up to what it was before the cgo calls, so it was creating the dangling pointer warned about above. When eventually the m stack was used enough to overwrite the dangling SEH records, the SEH chain was lost, and any future panic would not end up in Go's handler. The bug in TestCallbackPanic and friends was thus creating a situation where TestSetPanicOnFault - which causes a hardware fault - would not find the Go fault handler and instead crash the binary. Add checks to TestCallbackPanicLocked to diagnose the mistake in that test instead of leaving a bad state for another test case to stumble over. Fix bug by restoring SEH chain during deferred "endcgo" cleanup. This bug is likely present in Go 1.2.1, but since it depends on Go calling C calling Go, with the inner Go panicking and the outer Go recovering the panic, it seems not important enough to bother fixing before Go 1.3. Certainly no one has complained. Fixes #7470. LGTM=alex.brainman R=golang-codereviews, alex.brainman CC=golang-codereviews, iant, khr https://golang.org/cl/71440043
2014-03-05 09:10:40 -07:00
func TestCallbackPanicLocked(t *testing.T) {
runtime.LockOSThread()
defer runtime.UnlockOSThread()
if !runtime.LockedOSThread() {
t.Fatal("runtime.LockOSThread didn't")
}
defer func() {
s := recover()
if s == nil {
t.Fatal("did not panic")
}
if s.(string) != "callback panic" {
t.Fatal("wrong panic:", s)
}
runtime: handle Go calls C calls Go panic correctly on windows/386 32-bit Windows uses "structured exception handling" (SEH) to handle hardware faults: that there is a per-thread linked list of fault handlers maintained in user space instead of something like Unix's signal handlers. The structures in the linked list are required to live on the OS stack, and the usual discipline is that the function that pushes a record (allocated from the current stack frame) onto the list pops that record before returning. Not to pop the entry before returning creates a dangling pointer error: the list head points to a stack frame that no longer exists. Go pushes an SEH record in the top frame of every OS thread, and that record suffices for all Go execution on that thread, at least until cgo gets involved. If we call into C using cgo, that called C code may push its own SEH records, but by the convention it must pop them before returning back to the Go code. We assume it does, and that's fine. If the C code calls back into Go, we want the Go SEH handler to become active again, not whatever C has set up. So runtime.callbackasm1, which handles a call from C back into Go, pushes a new SEH record before calling the Go code and pops it when the Go code returns. That's also fine. It can happen that when Go calls C calls Go like this, the inner Go code panics. We allow a defer in the outer Go to recover the panic, effectively wiping not only the inner Go frames but also the C calls. This sequence was not popping the SEH stack up to what it was before the cgo calls, so it was creating the dangling pointer warned about above. When eventually the m stack was used enough to overwrite the dangling SEH records, the SEH chain was lost, and any future panic would not end up in Go's handler. The bug in TestCallbackPanic and friends was thus creating a situation where TestSetPanicOnFault - which causes a hardware fault - would not find the Go fault handler and instead crash the binary. Add checks to TestCallbackPanicLocked to diagnose the mistake in that test instead of leaving a bad state for another test case to stumble over. Fix bug by restoring SEH chain during deferred "endcgo" cleanup. This bug is likely present in Go 1.2.1, but since it depends on Go calling C calling Go, with the inner Go panicking and the outer Go recovering the panic, it seems not important enough to bother fixing before Go 1.3. Certainly no one has complained. Fixes #7470. LGTM=alex.brainman R=golang-codereviews, alex.brainman CC=golang-codereviews, iant, khr https://golang.org/cl/71440043
2014-03-05 09:10:40 -07:00
if !runtime.LockedOSThread() {
t.Fatal("lost lock on OS thread after panic")
}
}()
nestedCall(t, func() { panic("callback panic") })
panic("nestedCall returned")
}
runtime: handle Go calls C calls Go panic correctly on windows/386 32-bit Windows uses "structured exception handling" (SEH) to handle hardware faults: that there is a per-thread linked list of fault handlers maintained in user space instead of something like Unix's signal handlers. The structures in the linked list are required to live on the OS stack, and the usual discipline is that the function that pushes a record (allocated from the current stack frame) onto the list pops that record before returning. Not to pop the entry before returning creates a dangling pointer error: the list head points to a stack frame that no longer exists. Go pushes an SEH record in the top frame of every OS thread, and that record suffices for all Go execution on that thread, at least until cgo gets involved. If we call into C using cgo, that called C code may push its own SEH records, but by the convention it must pop them before returning back to the Go code. We assume it does, and that's fine. If the C code calls back into Go, we want the Go SEH handler to become active again, not whatever C has set up. So runtime.callbackasm1, which handles a call from C back into Go, pushes a new SEH record before calling the Go code and pops it when the Go code returns. That's also fine. It can happen that when Go calls C calls Go like this, the inner Go code panics. We allow a defer in the outer Go to recover the panic, effectively wiping not only the inner Go frames but also the C calls. This sequence was not popping the SEH stack up to what it was before the cgo calls, so it was creating the dangling pointer warned about above. When eventually the m stack was used enough to overwrite the dangling SEH records, the SEH chain was lost, and any future panic would not end up in Go's handler. The bug in TestCallbackPanic and friends was thus creating a situation where TestSetPanicOnFault - which causes a hardware fault - would not find the Go fault handler and instead crash the binary. Add checks to TestCallbackPanicLocked to diagnose the mistake in that test instead of leaving a bad state for another test case to stumble over. Fix bug by restoring SEH chain during deferred "endcgo" cleanup. This bug is likely present in Go 1.2.1, but since it depends on Go calling C calling Go, with the inner Go panicking and the outer Go recovering the panic, it seems not important enough to bother fixing before Go 1.3. Certainly no one has complained. Fixes #7470. LGTM=alex.brainman R=golang-codereviews, alex.brainman CC=golang-codereviews, iant, khr https://golang.org/cl/71440043
2014-03-05 09:10:40 -07:00
func TestCallbackPanic(t *testing.T) {
// Make sure panic during callback unwinds properly.
if runtime.LockedOSThread() {
t.Fatal("locked OS thread on entry to TestCallbackPanic")
}
defer func() {
s := recover()
if s == nil {
t.Fatal("did not panic")
}
if s.(string) != "callback panic" {
t.Fatal("wrong panic:", s)
}
runtime: handle Go calls C calls Go panic correctly on windows/386 32-bit Windows uses "structured exception handling" (SEH) to handle hardware faults: that there is a per-thread linked list of fault handlers maintained in user space instead of something like Unix's signal handlers. The structures in the linked list are required to live on the OS stack, and the usual discipline is that the function that pushes a record (allocated from the current stack frame) onto the list pops that record before returning. Not to pop the entry before returning creates a dangling pointer error: the list head points to a stack frame that no longer exists. Go pushes an SEH record in the top frame of every OS thread, and that record suffices for all Go execution on that thread, at least until cgo gets involved. If we call into C using cgo, that called C code may push its own SEH records, but by the convention it must pop them before returning back to the Go code. We assume it does, and that's fine. If the C code calls back into Go, we want the Go SEH handler to become active again, not whatever C has set up. So runtime.callbackasm1, which handles a call from C back into Go, pushes a new SEH record before calling the Go code and pops it when the Go code returns. That's also fine. It can happen that when Go calls C calls Go like this, the inner Go code panics. We allow a defer in the outer Go to recover the panic, effectively wiping not only the inner Go frames but also the C calls. This sequence was not popping the SEH stack up to what it was before the cgo calls, so it was creating the dangling pointer warned about above. When eventually the m stack was used enough to overwrite the dangling SEH records, the SEH chain was lost, and any future panic would not end up in Go's handler. The bug in TestCallbackPanic and friends was thus creating a situation where TestSetPanicOnFault - which causes a hardware fault - would not find the Go fault handler and instead crash the binary. Add checks to TestCallbackPanicLocked to diagnose the mistake in that test instead of leaving a bad state for another test case to stumble over. Fix bug by restoring SEH chain during deferred "endcgo" cleanup. This bug is likely present in Go 1.2.1, but since it depends on Go calling C calling Go, with the inner Go panicking and the outer Go recovering the panic, it seems not important enough to bother fixing before Go 1.3. Certainly no one has complained. Fixes #7470. LGTM=alex.brainman R=golang-codereviews, alex.brainman CC=golang-codereviews, iant, khr https://golang.org/cl/71440043
2014-03-05 09:10:40 -07:00
if runtime.LockedOSThread() {
t.Fatal("locked OS thread on exit from TestCallbackPanic")
}
}()
nestedCall(t, func() { panic("callback panic") })
panic("nestedCall returned")
}
runtime: handle Go calls C calls Go panic correctly on windows/386 32-bit Windows uses "structured exception handling" (SEH) to handle hardware faults: that there is a per-thread linked list of fault handlers maintained in user space instead of something like Unix's signal handlers. The structures in the linked list are required to live on the OS stack, and the usual discipline is that the function that pushes a record (allocated from the current stack frame) onto the list pops that record before returning. Not to pop the entry before returning creates a dangling pointer error: the list head points to a stack frame that no longer exists. Go pushes an SEH record in the top frame of every OS thread, and that record suffices for all Go execution on that thread, at least until cgo gets involved. If we call into C using cgo, that called C code may push its own SEH records, but by the convention it must pop them before returning back to the Go code. We assume it does, and that's fine. If the C code calls back into Go, we want the Go SEH handler to become active again, not whatever C has set up. So runtime.callbackasm1, which handles a call from C back into Go, pushes a new SEH record before calling the Go code and pops it when the Go code returns. That's also fine. It can happen that when Go calls C calls Go like this, the inner Go code panics. We allow a defer in the outer Go to recover the panic, effectively wiping not only the inner Go frames but also the C calls. This sequence was not popping the SEH stack up to what it was before the cgo calls, so it was creating the dangling pointer warned about above. When eventually the m stack was used enough to overwrite the dangling SEH records, the SEH chain was lost, and any future panic would not end up in Go's handler. The bug in TestCallbackPanic and friends was thus creating a situation where TestSetPanicOnFault - which causes a hardware fault - would not find the Go fault handler and instead crash the binary. Add checks to TestCallbackPanicLocked to diagnose the mistake in that test instead of leaving a bad state for another test case to stumble over. Fix bug by restoring SEH chain during deferred "endcgo" cleanup. This bug is likely present in Go 1.2.1, but since it depends on Go calling C calling Go, with the inner Go panicking and the outer Go recovering the panic, it seems not important enough to bother fixing before Go 1.3. Certainly no one has complained. Fixes #7470. LGTM=alex.brainman R=golang-codereviews, alex.brainman CC=golang-codereviews, iant, khr https://golang.org/cl/71440043
2014-03-05 09:10:40 -07:00
func TestCallbackPanicLoop(t *testing.T) {
// Make sure we don't blow out m->g0 stack.
for i := 0; i < 100000; i++ {
TestCallbackPanic(t)
}
}
func TestBlockingCallback(t *testing.T) {
c := make(chan int)
go func() {
for i := 0; i < 10; i++ {
c <- <-c
}
}()
nestedCall(t, func() {
for i := 0; i < 10; i++ {
c <- i
if j := <-c; j != i {
t.Errorf("out of sync %d != %d", j, i)
}
}
})
}
func TestCallbackInAnotherThread(t *testing.T) {
// TODO: test a function which calls back in another thread: QueueUserAPC() or CreateThread()
}
type cbDLLFunc int // int determines number of callback parameters
func (f cbDLLFunc) stdcallName() string {
return fmt.Sprintf("stdcall%d", f)
}
func (f cbDLLFunc) cdeclName() string {
return fmt.Sprintf("cdecl%d", f)
}
func (f cbDLLFunc) buildOne(stdcall bool) string {
var funcname, attr string
if stdcall {
funcname = f.stdcallName()
attr = "__stdcall"
} else {
funcname = f.cdeclName()
attr = "__cdecl"
}
typename := "t" + funcname
p := make([]string, f)
for i := range p {
p[i] = "uintptr_t"
}
params := strings.Join(p, ",")
for i := range p {
p[i] = fmt.Sprintf("%d", i+1)
}
args := strings.Join(p, ",")
return fmt.Sprintf(`
typedef void %s (*%s)(%s);
void %s(%s f, uintptr_t n) {
uintptr_t i;
for(i=0;i<n;i++){
f(%s);
}
}
`, attr, typename, params, funcname, typename, args)
}
func (f cbDLLFunc) build() string {
return "#include <stdint.h>\n\n" + f.buildOne(false) + f.buildOne(true)
}
var cbFuncs = [...]interface{}{
2: func(i1, i2 uintptr) uintptr {
if i1+i2 != 3 {
panic("bad input")
}
return 0
},
3: func(i1, i2, i3 uintptr) uintptr {
if i1+i2+i3 != 6 {
panic("bad input")
}
return 0
},
4: func(i1, i2, i3, i4 uintptr) uintptr {
if i1+i2+i3+i4 != 10 {
panic("bad input")
}
return 0
},
5: func(i1, i2, i3, i4, i5 uintptr) uintptr {
if i1+i2+i3+i4+i5 != 15 {
panic("bad input")
}
return 0
},
6: func(i1, i2, i3, i4, i5, i6 uintptr) uintptr {
if i1+i2+i3+i4+i5+i6 != 21 {
panic("bad input")
}
return 0
},
7: func(i1, i2, i3, i4, i5, i6, i7 uintptr) uintptr {
if i1+i2+i3+i4+i5+i6+i7 != 28 {
panic("bad input")
}
return 0
},
8: func(i1, i2, i3, i4, i5, i6, i7, i8 uintptr) uintptr {
if i1+i2+i3+i4+i5+i6+i7+i8 != 36 {
panic("bad input")
}
return 0
},
9: func(i1, i2, i3, i4, i5, i6, i7, i8, i9 uintptr) uintptr {
if i1+i2+i3+i4+i5+i6+i7+i8+i9 != 45 {
panic("bad input")
}
return 0
},
}
type cbDLL struct {
name string
buildArgs func(out, src string) []string
}
func (d *cbDLL) buildSrc(t *testing.T, path string) {
f, err := os.Create(path)
if err != nil {
t.Fatalf("failed to create source file: %v", err)
}
defer f.Close()
for i := 2; i < 10; i++ {
fmt.Fprint(f, cbDLLFunc(i).build())
}
}
func (d *cbDLL) build(t *testing.T, dir string) string {
srcname := d.name + ".c"
d.buildSrc(t, filepath.Join(dir, srcname))
outname := d.name + ".dll"
args := d.buildArgs(outname, srcname)
cmd := exec.Command(args[0], args[1:]...)
cmd.Dir = dir
out, err := cmd.CombinedOutput()
if err != nil {
t.Fatalf("failed to build dll: %v - %v", err, string(out))
}
return filepath.Join(dir, outname)
}
var cbDLLs = []cbDLL{
{
"test",
func(out, src string) []string {
return []string{"gcc", "-shared", "-s", "-Werror", "-o", out, src}
},
},
{
"testO2",
func(out, src string) []string {
return []string{"gcc", "-shared", "-s", "-Werror", "-o", out, "-O2", src}
},
},
}
type cbTest struct {
n int // number of callback parameters
param uintptr // dll function parameter
}
func (test *cbTest) run(t *testing.T, dllpath string) {
dll := syscall.MustLoadDLL(dllpath)
defer dll.Release()
cb := cbFuncs[test.n]
stdcall := syscall.NewCallback(cb)
f := cbDLLFunc(test.n)
test.runOne(t, dll, f.stdcallName(), stdcall)
cdecl := syscall.NewCallbackCDecl(cb)
test.runOne(t, dll, f.cdeclName(), cdecl)
}
func (test *cbTest) runOne(t *testing.T, dll *syscall.DLL, proc string, cb uintptr) {
defer func() {
if r := recover(); r != nil {
t.Errorf("dll call %v(..., %d) failed: %v", proc, test.param, r)
}
}()
dll.MustFindProc(proc).Call(cb, test.param)
}
var cbTests = []cbTest{
{2, 1},
{2, 10000},
{3, 3},
{4, 5},
{4, 6},
{5, 2},
{6, 7},
{6, 8},
{7, 6},
{8, 1},
{9, 8},
{9, 10000},
{3, 4},
{5, 3},
{7, 7},
{8, 2},
{9, 9},
}
func TestStdcallAndCDeclCallbacks(t *testing.T) {
if _, err := exec.LookPath("gcc"); err != nil {
t.Skip("skipping test: gcc is missing")
}
tmp, err := ioutil.TempDir("", "TestCDeclCallback")
if err != nil {
t.Fatal("TempDir failed: ", err)
}
defer os.RemoveAll(tmp)
for _, dll := range cbDLLs {
dllPath := dll.build(t, tmp)
for _, test := range cbTests {
test.run(t, dllPath)
}
}
}
func TestRegisterClass(t *testing.T) {
kernel32 := GetDLL(t, "kernel32.dll")
user32 := GetDLL(t, "user32.dll")
mh, _, _ := kernel32.Proc("GetModuleHandleW").Call(0)
cb := syscall.NewCallback(func(hwnd syscall.Handle, msg uint32, wparam, lparam uintptr) (rc uintptr) {
t.Fatal("callback should never get called")
return 0
})
type Wndclassex struct {
Size uint32
Style uint32
WndProc uintptr
ClsExtra int32
WndExtra int32
Instance syscall.Handle
Icon syscall.Handle
Cursor syscall.Handle
Background syscall.Handle
MenuName *uint16
ClassName *uint16
IconSm syscall.Handle
}
name := syscall.StringToUTF16Ptr("test_window")
wc := Wndclassex{
WndProc: cb,
Instance: syscall.Handle(mh),
ClassName: name,
}
wc.Size = uint32(unsafe.Sizeof(wc))
a, _, err := user32.Proc("RegisterClassExW").Call(uintptr(unsafe.Pointer(&wc)))
if a == 0 {
t.Fatalf("RegisterClassEx failed: %v", err)
}
r, _, err := user32.Proc("UnregisterClassW").Call(uintptr(unsafe.Pointer(name)), 0)
if r == 0 {
t.Fatalf("UnregisterClass failed: %v", err)
}
}
func TestOutputDebugString(t *testing.T) {
d := GetDLL(t, "kernel32.dll")
p := syscall.StringToUTF16Ptr("testing OutputDebugString")
d.Proc("OutputDebugStringW").Call(uintptr(unsafe.Pointer(p)))
}
func TestRaiseException(t *testing.T) {
o := runTestProg(t, "testprog", "RaiseException")
if strings.Contains(o, "RaiseException should not return") {
t.Fatalf("RaiseException did not crash program: %v", o)
}
if !strings.Contains(o, "Exception 0xbad") {
t.Fatalf("No stack trace: %v", o)
}
}
func TestZeroDivisionException(t *testing.T) {
o := runTestProg(t, "testprog", "ZeroDivisionException")
if !strings.Contains(o, "panic: runtime error: integer divide by zero") {
t.Fatalf("No stack trace: %v", o)
}
}
func TestWERDialogue(t *testing.T) {
if os.Getenv("TESTING_WER_DIALOGUE") == "1" {
defer os.Exit(0)
*runtime.TestingWER = true
const EXCEPTION_NONCONTINUABLE = 1
mod := syscall.MustLoadDLL("kernel32.dll")
proc := mod.MustFindProc("RaiseException")
proc.Call(0xbad, EXCEPTION_NONCONTINUABLE, 0, 0)
println("RaiseException should not return")
return
}
cmd := exec.Command(os.Args[0], "-test.run=TestWERDialogue")
cmd.Env = []string{"TESTING_WER_DIALOGUE=1"}
// Child process should not open WER dialogue, but return immediately instead.
cmd.CombinedOutput()
}
var used byte
func use(buf []byte) {
for _, c := range buf {
used += c
}
}
func forceStackCopy() (r int) {
var f func(int) int
f = func(i int) int {
var buf [256]byte
use(buf[:])
if i == 0 {
return 0
}
return i + f(i-1)
}
r = f(128)
return
}
func TestReturnAfterStackGrowInCallback(t *testing.T) {
if _, err := exec.LookPath("gcc"); err != nil {
t.Skip("skipping test: gcc is missing")
}
const src = `
#include <stdint.h>
#include <windows.h>
typedef uintptr_t __stdcall (*callback)(uintptr_t);
uintptr_t cfunc(callback f, uintptr_t n) {
uintptr_t r;
r = f(n);
SetLastError(333);
return r;
}
`
tmpdir, err := ioutil.TempDir("", "TestReturnAfterStackGrowInCallback")
if err != nil {
t.Fatal("TempDir failed: ", err)
}
defer os.RemoveAll(tmpdir)
srcname := "mydll.c"
err = ioutil.WriteFile(filepath.Join(tmpdir, srcname), []byte(src), 0)
if err != nil {
t.Fatal(err)
}
outname := "mydll.dll"
cmd := exec.Command("gcc", "-shared", "-s", "-Werror", "-o", outname, srcname)
cmd.Dir = tmpdir
out, err := cmd.CombinedOutput()
if err != nil {
t.Fatalf("failed to build dll: %v - %v", err, string(out))
}
dllpath := filepath.Join(tmpdir, outname)
dll := syscall.MustLoadDLL(dllpath)
defer dll.Release()
proc := dll.MustFindProc("cfunc")
cb := syscall.NewCallback(func(n uintptr) uintptr {
forceStackCopy()
return n
})
// Use a new goroutine so that we get a small stack.
type result struct {
r uintptr
err syscall.Errno
}
c := make(chan result)
go func() {
r, _, err := proc.Call(cb, 100)
c <- result{r, err.(syscall.Errno)}
}()
want := result{r: 100, err: 333}
if got := <-c; got != want {
t.Errorf("got %d want %d", got, want)
}
}
// removeOneCPU removes one (any) cpu from affinity mask.
// It returns new affinity mask.
func removeOneCPU(mask uintptr) (uintptr, error) {
if mask == 0 {
return 0, fmt.Errorf("cpu affinity mask is empty")
}
maskbits := int(unsafe.Sizeof(mask) * 8)
for i := 0; i < maskbits; i++ {
newmask := mask & ^(1 << uint(i))
if newmask != mask {
return newmask, nil
}
}
panic("not reached")
}
func resumeChildThread(kernel32 *syscall.DLL, childpid int) error {
_OpenThread := kernel32.MustFindProc("OpenThread")
_ResumeThread := kernel32.MustFindProc("ResumeThread")
_Thread32First := kernel32.MustFindProc("Thread32First")
_Thread32Next := kernel32.MustFindProc("Thread32Next")
snapshot, err := syscall.CreateToolhelp32Snapshot(syscall.TH32CS_SNAPTHREAD, 0)
if err != nil {
return err
}
defer syscall.CloseHandle(snapshot)
const _THREAD_SUSPEND_RESUME = 0x0002
type ThreadEntry32 struct {
Size uint32
tUsage uint32
ThreadID uint32
OwnerProcessID uint32
BasePri int32
DeltaPri int32
Flags uint32
}
var te ThreadEntry32
te.Size = uint32(unsafe.Sizeof(te))
ret, _, err := _Thread32First.Call(uintptr(snapshot), uintptr(unsafe.Pointer(&te)))
if ret == 0 {
return err
}
for te.OwnerProcessID != uint32(childpid) {
ret, _, err = _Thread32Next.Call(uintptr(snapshot), uintptr(unsafe.Pointer(&te)))
if ret == 0 {
return err
}
}
h, _, err := _OpenThread.Call(_THREAD_SUSPEND_RESUME, 1, uintptr(te.ThreadID))
if h == 0 {
return err
}
defer syscall.Close(syscall.Handle(h))
ret, _, err = _ResumeThread.Call(h)
if ret == 0xffffffff {
return err
}
return nil
}
func TestNumCPU(t *testing.T) {
if os.Getenv("GO_WANT_HELPER_PROCESS") == "1" {
// in child process
fmt.Fprintf(os.Stderr, "%d", runtime.NumCPU())
os.Exit(0)
}
switch n := runtime.NumberOfProcessors(); {
case n < 1:
t.Fatalf("system cannot have %d cpu(s)", n)
case n == 1:
if runtime.NumCPU() != 1 {
t.Fatalf("runtime.NumCPU() returns %d on single cpu system", runtime.NumCPU())
}
return
}
const (
_CREATE_SUSPENDED = 0x00000004
_PROCESS_ALL_ACCESS = syscall.STANDARD_RIGHTS_REQUIRED | syscall.SYNCHRONIZE | 0xfff
)
kernel32 := syscall.MustLoadDLL("kernel32.dll")
_GetProcessAffinityMask := kernel32.MustFindProc("GetProcessAffinityMask")
_SetProcessAffinityMask := kernel32.MustFindProc("SetProcessAffinityMask")
cmd := exec.Command(os.Args[0], "-test.run=TestNumCPU")
cmd.Env = append(os.Environ(), "GO_WANT_HELPER_PROCESS=1")
var buf bytes.Buffer
cmd.Stdout = &buf
cmd.Stderr = &buf
cmd.SysProcAttr = &syscall.SysProcAttr{CreationFlags: _CREATE_SUSPENDED}
err := cmd.Start()
if err != nil {
t.Fatal(err)
}
defer func() {
err = cmd.Wait()
childOutput := string(buf.Bytes())
if err != nil {
t.Fatalf("child failed: %v: %v", err, childOutput)
}
// removeOneCPU should have decreased child cpu count by 1
want := fmt.Sprintf("%d", runtime.NumCPU()-1)
if childOutput != want {
t.Fatalf("child output: want %q, got %q", want, childOutput)
}
}()
defer func() {
err = resumeChildThread(kernel32, cmd.Process.Pid)
if err != nil {
t.Fatal(err)
}
}()
ph, err := syscall.OpenProcess(_PROCESS_ALL_ACCESS, false, uint32(cmd.Process.Pid))
if err != nil {
t.Fatal(err)
}
defer syscall.CloseHandle(ph)
var mask, sysmask uintptr
ret, _, err := _GetProcessAffinityMask.Call(uintptr(ph), uintptr(unsafe.Pointer(&mask)), uintptr(unsafe.Pointer(&sysmask)))
if ret == 0 {
t.Fatal(err)
}
newmask, err := removeOneCPU(mask)
if err != nil {
t.Fatal(err)
}
ret, _, err = _SetProcessAffinityMask.Call(uintptr(ph), newmask)
if ret == 0 {
t.Fatal(err)
}
ret, _, err = _GetProcessAffinityMask.Call(uintptr(ph), uintptr(unsafe.Pointer(&mask)), uintptr(unsafe.Pointer(&sysmask)))
if ret == 0 {
t.Fatal(err)
}
if newmask != mask {
t.Fatalf("SetProcessAffinityMask didn't set newmask of 0x%x. Current mask is 0x%x.", newmask, mask)
}
}
// See Issue 14959
func TestDLLPreloadMitigation(t *testing.T) {
if _, err := exec.LookPath("gcc"); err != nil {
t.Skip("skipping test: gcc is missing")
}
dir0, err := os.Getwd()
if err != nil {
t.Fatal(err)
}
defer os.Chdir(dir0)
const src = `
#include <stdint.h>
#include <windows.h>
uintptr_t cfunc() {
SetLastError(123);
}
`
tmpdir, err := ioutil.TempDir("", "TestDLLPreloadMitigation")
if err != nil {
t.Fatal("TempDir failed: ", err)
}
defer os.RemoveAll(tmpdir)
srcname := "nojack.c"
err = ioutil.WriteFile(filepath.Join(tmpdir, srcname), []byte(src), 0)
if err != nil {
t.Fatal(err)
}
name := "nojack.dll"
cmd := exec.Command("gcc", "-shared", "-s", "-Werror", "-o", name, srcname)
cmd.Dir = tmpdir
out, err := cmd.CombinedOutput()
if err != nil {
t.Fatalf("failed to build dll: %v - %v", err, string(out))
}
dllpath := filepath.Join(tmpdir, name)
dll := syscall.MustLoadDLL(dllpath)
dll.MustFindProc("cfunc")
dll.Release()
// Get into the directory with the DLL we'll load by base name
// ("nojack.dll") Think of this as the user double-clicking an
// installer from their Downloads directory where a browser
// silently downloaded some malicious DLLs.
os.Chdir(tmpdir)
// First before we can load a DLL from the current directory,
// loading it only as "nojack.dll", without an absolute path.
delete(sysdll.IsSystemDLL, name) // in case test was run repeatedly
dll, err = syscall.LoadDLL(name)
if err != nil {
t.Fatalf("failed to load %s by base name before sysdll registration: %v", name, err)
}
dll.Release()
// And now verify that if we register it as a system32-only
// DLL, the implicit loading from the current directory no
// longer works.
sysdll.IsSystemDLL[name] = true
dll, err = syscall.LoadDLL(name)
if err == nil {
dll.Release()
if wantLoadLibraryEx() {
t.Fatalf("Bad: insecure load of DLL by base name %q before sysdll registration: %v", name, err)
}
t.Skip("insecure load of DLL, but expected")
}
}
// wantLoadLibraryEx reports whether we expect LoadLibraryEx to work for tests.
func wantLoadLibraryEx() bool {
return testenv.Builder() == "windows-amd64-gce" || testenv.Builder() == "windows-386-gce"
}
func TestLoadLibraryEx(t *testing.T) {
use, have, flags := runtime.LoadLibraryExStatus()
if use {
return // success.
}
if wantLoadLibraryEx() {
t.Fatalf("Expected LoadLibraryEx+flags to be available. (LoadLibraryEx=%v; flags=%v)",
have, flags)
}
t.Skipf("LoadLibraryEx not usable, but not expected. (LoadLibraryEx=%v; flags=%v)",
have, flags)
}
var (
modwinmm = syscall.NewLazyDLL("winmm.dll")
modkernel32 = syscall.NewLazyDLL("kernel32.dll")
proctimeBeginPeriod = modwinmm.NewProc("timeBeginPeriod")
proctimeEndPeriod = modwinmm.NewProc("timeEndPeriod")
procCreateEvent = modkernel32.NewProc("CreateEventW")
procSetEvent = modkernel32.NewProc("SetEvent")
)
func timeBeginPeriod(period uint32) {
syscall.Syscall(proctimeBeginPeriod.Addr(), 1, uintptr(period), 0, 0)
}
func timeEndPeriod(period uint32) {
syscall.Syscall(proctimeEndPeriod.Addr(), 1, uintptr(period), 0, 0)
}
func createEvent() (syscall.Handle, error) {
r0, _, e0 := syscall.Syscall6(procCreateEvent.Addr(), 4, 0, 0, 0, 0, 0, 0)
if r0 == 0 {
return 0, syscall.Errno(e0)
}
return syscall.Handle(r0), nil
}
func setEvent(h syscall.Handle) error {
r0, _, e0 := syscall.Syscall(procSetEvent.Addr(), 1, uintptr(h), 0, 0)
if r0 == 0 {
return syscall.Errno(e0)
}
return nil
}
func benchChanToSyscallPing(b *testing.B) {
ch := make(chan int)
event, err := createEvent()
if err != nil {
b.Fatal(err)
}
go func() {
for i := 0; i < b.N; i++ {
syscall.WaitForSingleObject(event, syscall.INFINITE)
ch <- 1
}
}()
for i := 0; i < b.N; i++ {
err := setEvent(event)
if err != nil {
b.Fatal(err)
}
<-ch
}
}
func BenchmarkChanToSyscallPing1ms(b *testing.B) {
timeBeginPeriod(1)
benchChanToSyscallPing(b)
timeEndPeriod(1)
}
func BenchmarkChanToSyscallPing15ms(b *testing.B) {
benchChanToSyscallPing(b)
}
func benchSyscallToSyscallPing(b *testing.B) {
event1, err := createEvent()
if err != nil {
b.Fatal(err)
}
event2, err := createEvent()
if err != nil {
b.Fatal(err)
}
go func() {
for i := 0; i < b.N; i++ {
syscall.WaitForSingleObject(event1, syscall.INFINITE)
err := setEvent(event2)
if err != nil {
b.Fatal(err)
}
}
}()
for i := 0; i < b.N; i++ {
err := setEvent(event1)
if err != nil {
b.Fatal(err)
}
syscall.WaitForSingleObject(event2, syscall.INFINITE)
}
}
func BenchmarkSyscallToSyscallPing1ms(b *testing.B) {
timeBeginPeriod(1)
benchSyscallToSyscallPing(b)
timeEndPeriod(1)
}
func BenchmarkSyscallToSyscallPing15ms(b *testing.B) {
benchSyscallToSyscallPing(b)
}
func benchChanToChanPing(b *testing.B) {
ch1 := make(chan int)
ch2 := make(chan int)
go func() {
for i := 0; i < b.N; i++ {
<-ch1
ch2 <- 1
}
}()
for i := 0; i < b.N; i++ {
ch1 <- 1
<-ch2
}
}
func BenchmarkChanToChanPing1ms(b *testing.B) {
timeBeginPeriod(1)
benchChanToChanPing(b)
timeEndPeriod(1)
}
func BenchmarkChanToChanPing15ms(b *testing.B) {
benchChanToChanPing(b)
}
func benchOsYield(b *testing.B) {
for i := 0; i < b.N; i++ {
runtime.OsYield()
}
}
func BenchmarkOsYield1ms(b *testing.B) {
timeBeginPeriod(1)
benchOsYield(b)
timeEndPeriod(1)
}
func BenchmarkOsYield15ms(b *testing.B) {
benchOsYield(b)
}