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dnscrypt-proxy/vendor/github.com/powerman/check/check.go
2023-03-23 12:54:45 +01:00

1362 lines
40 KiB
Go

package check
import (
"bytes"
"encoding/json"
"errors"
"fmt"
"math"
"reflect"
"regexp"
"strings"
"testing"
"time"
pkgerrors "github.com/pkg/errors"
"github.com/powerman/deepequal"
"google.golang.org/grpc/status"
"google.golang.org/protobuf/proto"
"google.golang.org/protobuf/reflect/protoreflect"
)
//nolint:gochecknoglobals // Const.
var (
typString = reflect.TypeOf("")
typBytes = reflect.TypeOf([]byte(nil))
typFloat64 = reflect.TypeOf(0.0)
)
// C wraps *testing.T to make it convenient to call checkers in test.
type C struct {
*testing.T
todo bool
must bool
}
const (
nameActual = "Actual"
nameExpected = "Expected"
)
// Parallel implements an internal workaround which have no visible
// effect, so you should just call t.Parallel() as you usually do - it
// will work as expected.
func (t *C) Parallel() {
t.Helper()
// Goconvey anyway doesn't provide -test.cpu= and mixed output of
// parallel tests result in reporting failed tests at wrong places
// and with wrong failed tests count in web UI.
if !flags.detect().conveyJSON {
t.T.Parallel()
}
}
// T creates and returns new *C, which wraps given tt and supposed to be
// used inplace of it, providing you with access to many useful helpers in
// addition to standard methods of *testing.T.
//
// It's convenient to rename Test function's arg from t to something
// else, create wrapped variable with usual name t and use only t:
//
// func TestSomething(tt *testing.T) {
// t := check.T(tt)
// // use only t in test and don't touch tt anymore
// }
func T(tt *testing.T) *C { //nolint:thelper // With check we name it tt!
return &C{T: tt}
}
// TODO creates and returns new *C, which have only one difference from
// original one: every passing check is now handled as failed and vice
// versa (this doesn't affect boolean value returned by check).
// You can continue using both old and new *C at same time.
//
// Swapping passed/failed gives you ability to temporary mark some failed
// test as passed. For example, this may be useful to avoid broken builds
// in CI. This is often better than commenting, deleting or skipping
// broken test because it will continue to execute, and eventually when
// reason why it fails will be fixed this test will became failed again -
// notifying you the mark can and should be removed from this test now.
//
// func TestSomething(tt *testing.T) {
// t := check.T(tt)
// // Normal tests.
// t.True(true)
// // If you need to mark just one/few broken tests:
// t.TODO().True(false)
// t.True(true)
// // If there are several broken tests mixed with working ones:
// todo := t.TODO()
// t.True(true)
// todo.True(false)
// t.True(true)
// if todo.True(false) {
// panic("never here")
// }
// // If all tests below this point are broken:
// t = t.TODO()
// t.True(false)
// ...
// }
func (t *C) TODO() *C {
return &C{T: t.T, todo: true, must: t.must}
}
// MustAll creates and returns new *C, which have only one difference from
// original one: every failed check will interrupt test using t.FailNow.
// You can continue using both old and new *C at same time.
//
// This provides an easy way to turn all checks into assertion.
func (t *C) MustAll() *C {
return &C{T: t.T, todo: t.todo, must: true}
}
func (t *C) pass() {
statsMu.Lock()
defer statsMu.Unlock()
if stats[t.T] == nil {
stats[t.T] = newTestStat(t.Name(), false)
}
if t.todo {
stats[t.T].forged.value++
} else {
stats[t.T].passed.value++
}
}
func (t *C) fail() {
statsMu.Lock()
defer statsMu.Unlock()
if stats[t.T] == nil {
stats[t.T] = newTestStat(t.Name(), false)
}
stats[t.T].failed.value++
}
func (t *C) report(ok bool, msg []any, checker string, name []string, args []any) bool { //nolint:revive // False positive.
t.Helper()
if ok != t.todo {
t.pass()
return ok
}
if t.todo {
checker = "TODO " + checker
}
dump := make([]dump, 0, len(args))
for _, arg := range args {
dump = append(dump, newDump(arg))
}
failure := new(bytes.Buffer)
fmt.Fprintf(failure, "%s\nChecker: %s%s%s\n",
format(msg...),
ansiYellow, checker, ansiReset,
)
failureShort := failure.String()
// Reverse order to show Actual: last.
for i := len(dump) - 1; i >= 0; i-- {
fmt.Fprintf(failure, "%-10s", name[i]+":")
switch name[i] {
case nameActual:
fmt.Fprint(failure, ansiRed)
default:
fmt.Fprint(failure, ansiGreen)
}
fmt.Fprintf(failure, "%s%s", dump[i], ansiReset)
}
failureLong := failure.String()
wantDiff := len(dump) == 2 && name[0] == nameActual && name[1] == nameExpected
if wantDiff { //nolint:nestif // No idea how to simplify.
if reportToGoConvey(dump[0].String(), dump[1].String(), failureShort) == nil {
t.Fail()
} else {
fmt.Fprintf(failure, "\n%s", colouredDiff(dump[0].diff(dump[1])))
t.Errorf("%s\n", failure)
}
} else {
if reportToGoConvey("", "", failureLong) == nil {
t.Fail()
} else {
t.Errorf("%s\n", failure)
}
}
t.fail()
if t.must {
t.FailNow()
}
return ok
}
func (t *C) reportShould1(funcName string, actual any, msg []any, ok bool) bool {
t.Helper()
return t.report(ok, msg,
"Should "+funcName,
[]string{nameActual},
[]any{actual})
}
func (t *C) reportShould2(funcName string, actual, expected any, msg []any, ok bool) bool {
t.Helper()
return t.report(ok, msg,
"Should "+funcName,
[]string{nameActual, nameExpected},
[]any{actual, expected})
}
func (t *C) report0(msg []any, ok bool) bool {
t.Helper()
return t.report(ok, msg,
callerFuncName(1),
[]string{},
[]any{})
}
func (t *C) report1(actual any, msg []any, ok bool) bool {
t.Helper()
return t.report(ok, msg,
callerFuncName(1),
[]string{nameActual},
[]any{actual})
}
func (t *C) report2(actual, expected any, msg []any, ok bool) bool {
t.Helper()
checker, arg2Name := callerFuncName(1), nameExpected
if strings.Contains(checker, "Match") {
arg2Name = "Regex"
}
return t.report(ok, msg,
checker,
[]string{nameActual, arg2Name},
[]any{actual, expected})
}
func (t *C) report3(actual, expected1, expected2 any, msg []any, ok bool) bool {
t.Helper()
checker, arg2Name, arg3Name := callerFuncName(1), "arg1", "arg2"
switch {
case strings.Contains(checker, "Between"):
arg2Name, arg3Name = "Min", "Max"
case strings.Contains(checker, "Delta"):
arg2Name, arg3Name = nameExpected, "Delta"
case strings.Contains(checker, "SMAPE"):
arg2Name, arg3Name = nameExpected, "SMAPE"
}
return t.report(ok, msg,
checker,
[]string{nameActual, arg2Name, arg3Name},
[]any{actual, expected1, expected2})
}
// Must interrupt test using t.FailNow if called with false value.
//
// This provides an easy way to turn any check into assertion:
//
// t.Must(t.Nil(err))
func (t *C) Must(continueTest bool, msg ...any) { //nolint:revive // False positive.
t.Helper()
t.report0(msg, continueTest)
if !continueTest {
t.FailNow()
}
}
type (
// ShouldFunc1 is like Nil or Zero.
ShouldFunc1 func(t *C, actual any) bool
// ShouldFunc2 is like Equal or Match.
ShouldFunc2 func(t *C, actual, expected any) bool
)
// Should use user-provided check function to do actual check.
//
// anyShouldFunc must have type ShouldFunc1 or ShouldFunc2. It should
// return true if check was successful. There is no need to call t.Error
// in anyShouldFunc - this will be done automatically when it returns.
//
// args must contain at least 1 element for ShouldFunc1 and at least
// 2 elements for ShouldFunc2.
// Rest of elements will be processed as usual msg ...interface{} param.
//
// Example:
//
// func bePositive(_ *check.C, actual interface{}) bool {
// return actual.(int) > 0
// }
// func TestCustomCheck(tt *testing.T) {
// t := check.T(tt)
// t.Should(bePositive, 42, "custom check!!!")
// }
func (t *C) Should(anyShouldFunc any, args ...any) bool {
t.Helper()
switch f := anyShouldFunc.(type) {
case func(t *C, actual any) bool:
return t.should1(f, args...)
case func(t *C, actual, expected any) bool:
return t.should2(f, args...)
default:
panic("anyShouldFunc is not a ShouldFunc1 or ShouldFunc2")
}
}
func (t *C) should1(f ShouldFunc1, args ...any) bool {
t.Helper()
if len(args) < 1 {
panic("not enough params for " + funcName(f))
}
actual, msg := args[0], args[1:]
return t.reportShould1(funcName(f), actual, msg,
f(t, actual))
}
func (t *C) should2(f ShouldFunc2, args ...any) bool {
t.Helper()
const minArgs = 2
if len(args) < minArgs {
panic("not enough params for " + funcName(f))
}
actual, expected, msg := args[0], args[1], args[2:]
return t.reportShould2(funcName(f), actual, expected, msg,
f(t, actual, expected))
}
// Nil checks for actual == nil.
//
// There is one subtle difference between this check and Go `== nil` (if
// this surprises you then you should read
// https://golang.org/doc/faq#nil_error first):
//
// var intPtr *int
// var empty interface{}
// var notEmpty interface{} = intPtr
// t.True(intPtr == nil) // TRUE
// t.True(empty == nil) // TRUE
// t.True(notEmpty == nil) // FALSE
//
// When you call this function your actual value will be stored in
// interface{} argument, and this makes any typed nil pointer value `!=
// nil` inside this function (just like in example above happens with
// notEmpty variable).
//
// As it is very common case to check some typed pointer using Nil this
// check has to work around and detect nil even if usual `== nil` return
// false. But this has nasty side effect: if actual value already was of
// interface type and contains some typed nil pointer (which is usually
// bad thing and should be avoid) then Nil check will pass (which may be
// not what you want/expect):
//
// t.Nil(nil) // TRUE
// t.Nil(intPtr) // TRUE
// t.Nil(empty) // TRUE
// t.Nil(notEmpty) // WARNING: also TRUE!
//
// Second subtle case is less usual: uintptr(0) is sorta nil, but not
// really, so Nil(uintptr(0)) will fail. Nil(unsafe.Pointer(nil)) will
// also fail, for the same reason. Please do not use this and consider
// this behaviour undefined, because it may change in the future.
func (t *C) Nil(actual any, msg ...any) bool {
t.Helper()
return t.report1(actual, msg,
isNil(actual))
}
func isNil(actual any) bool {
switch val := reflect.ValueOf(actual); val.Kind() {
case reflect.Invalid:
return actual == nil
case reflect.Chan, reflect.Func, reflect.Map, reflect.Ptr, reflect.Slice:
return val.IsNil()
case reflect.Uintptr, reflect.UnsafePointer: // Subtle cases documented above.
case reflect.Interface: // ???
// Can't be nil:
case reflect.Struct, reflect.Array, reflect.Bool, reflect.String:
case reflect.Complex128, reflect.Complex64, reflect.Float32, reflect.Float64:
case reflect.Int, reflect.Int16, reflect.Int32, reflect.Int64, reflect.Int8:
case reflect.Uint, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uint8:
}
return false
}
// NotNil checks for actual != nil.
//
// See Nil about subtle case in check logic.
func (t *C) NotNil(actual any, msg ...any) bool {
t.Helper()
return t.report0(msg,
!isNil(actual))
}
// Error is equivalent to Log followed by Fail.
//
// It is like t.Errorf with TODO() and statistics support.
func (t *C) Error(msg ...any) {
t.Helper()
t.report0(msg, false)
}
// True checks for cond == true.
//
// This can be useful to use your own custom checks, but this way you
// won't get nice dump/diff for actual/expected values. You'll still have
// statistics about passed/failed checks and it's shorter than usual:
//
// if !cond {
// t.Errorf(msg...)
// }
func (t *C) True(cond bool, msg ...any) bool {
t.Helper()
return t.report0(msg,
cond)
}
// False checks for cond == false.
func (t *C) False(cond bool, msg ...any) bool {
t.Helper()
return t.report0(msg,
!cond)
}
// Equal checks for actual == expected.
//
// Note: For time.Time it uses actual.Equal(expected) instead.
func (t *C) Equal(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
isEqual(actual, expected))
}
func isEqual(actual, expected any) bool {
switch actual := actual.(type) {
case time.Time:
return actual.Equal(expected.(time.Time))
default:
return actual == expected
}
}
// EQ is a synonym for Equal.
func (t *C) EQ(actual, expected any, msg ...any) bool {
t.Helper()
return t.Equal(actual, expected, msg...)
}
// NotEqual checks for actual != expected.
func (t *C) NotEqual(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!isEqual(actual, expected))
}
// NE is a synonym for NotEqual.
func (t *C) NE(actual, expected any, msg ...any) bool {
t.Helper()
return t.NotEqual(actual, expected, msg...)
}
// BytesEqual checks for bytes.Equal(actual, expected).
//
// Hint: BytesEqual([]byte{}, []byte(nil)) is true (unlike DeepEqual).
func (t *C) BytesEqual(actual, expected []byte, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
bytes.Equal(actual, expected))
}
// NotBytesEqual checks for !bytes.Equal(actual, expected).
//
// Hint: NotBytesEqual([]byte{}, []byte(nil)) is false (unlike NotDeepEqual).
func (t *C) NotBytesEqual(actual, expected []byte, msg ...any) bool {
t.Helper()
return t.report1(actual, msg,
!bytes.Equal(actual, expected))
}
// DeepEqual checks for reflect.DeepEqual(actual, expected).
// It will also use Equal method for types which implements it
// (e.g. time.Time, decimal.Decimal, etc.).
// It will use proto.Equal for protobuf messages.
func (t *C) DeepEqual(actual, expected any, msg ...any) bool {
t.Helper()
protoActual, proto1 := actual.(protoreflect.ProtoMessage)
protoExpected, proto2 := expected.(protoreflect.ProtoMessage)
if proto1 && proto2 {
return t.report2(actual, expected, msg,
proto.Equal(protoActual, protoExpected))
}
return t.report2(actual, expected, msg,
deepequal.DeepEqual(actual, expected))
}
// NotDeepEqual checks for !reflect.DeepEqual(actual, expected).
// It will also use Equal method for types which implements it
// (e.g. time.Time, decimal.Decimal, etc.).
// It will use proto.Equal for protobuf messages.
func (t *C) NotDeepEqual(actual, expected any, msg ...any) bool {
t.Helper()
protoActual, proto1 := actual.(protoreflect.ProtoMessage)
protoExpected, proto2 := expected.(protoreflect.ProtoMessage)
if proto1 && proto2 {
return t.report1(actual, msg,
!proto.Equal(protoActual, protoExpected))
}
return t.report1(actual, msg,
!deepequal.DeepEqual(actual, expected))
}
// Match checks for regex.MatchString(actual).
//
// Regex type can be either *regexp.Regexp or string.
//
// Actual type can be:
// - string - will match with actual
// - []byte - will match with string(actual)
// - []rune - will match with string(actual)
// - fmt.Stringer - will match with actual.String()
// - error - will match with actual.Error()
// - nil - will not match (even with empty regex)
func (t *C) Match(actual, regex any, msg ...any) bool {
t.Helper()
ok := isMatch(&actual, regex)
return t.report2(actual, regex, msg,
ok)
}
// isMatch updates actual to be a real string used for matching, to make
// dump easier to understand, but this result in losing type information.
func isMatch(actual *any, regex any) bool { //nolint:gocritic // False positive.
if *actual == nil {
return false
}
if !stringify(actual) {
panic("actual is not a string, []byte, []rune, fmt.Stringer, error or nil")
}
s := (*actual).(string) //nolint:forcetypeassert // False positive.
switch v := regex.(type) {
case *regexp.Regexp:
return v.MatchString(s)
case string:
return regexp.MustCompile(v).MatchString(s)
}
panic("regex is not a *regexp.Regexp or string")
}
func stringify(arg *any) bool { //nolint:gocritic // False positive.
switch v := (*arg).(type) {
case nil:
return false
case error:
*arg = v.Error()
case fmt.Stringer:
*arg = v.String()
default:
typ := reflect.TypeOf(*arg)
switch typ.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.String:
case reflect.Slice:
switch typ.Elem().Kind() { //nolint:exhaustive // Covered by default case.
case reflect.Uint8, reflect.Int32:
default:
return false
}
default:
return false
}
*arg = reflect.ValueOf(*arg).Convert(typString).Interface()
}
return true
}
// NotMatch checks for !regex.MatchString(actual).
//
// See Match about supported actual/regex types and check logic.
func (t *C) NotMatch(actual, regex any, msg ...any) bool {
t.Helper()
ok := !isMatch(&actual, regex)
return t.report2(actual, regex, msg,
ok)
}
// Contains checks is actual contains substring/element expected.
//
// Element of array/slice/map is checked using == expected.
//
// Type of expected depends on type of actual:
// - if actual is a string, then expected should be a string
// - if actual is an array, then expected should have array's element type
// - if actual is a slice, then expected should have slice's element type
// - if actual is a map, then expected should have map's value type
//
// Hint: In a map it looks for a value, if you need to look for a key -
// use HasKey instead.
func (t *C) Contains(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
isContains(actual, expected))
}
func isContains(actual, expected any) (found bool) {
switch valActual := reflect.ValueOf(actual); valActual.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.String:
strActual := valActual.Convert(typString).Interface().(string) //nolint:forcetypeassert // False positive.
valExpected := reflect.ValueOf(expected)
if valExpected.Kind() != reflect.String {
panic("expected underlying type is not a string")
}
strExpected := valExpected.Convert(typString).Interface().(string) //nolint:forcetypeassert // False positive.
found = strings.Contains(strActual, strExpected)
case reflect.Map:
if valActual.Type().Elem() != reflect.TypeOf(expected) {
panic("expected type not match actual element type")
}
keys := valActual.MapKeys()
for i := 0; i < len(keys) && !found; i++ {
found = valActual.MapIndex(keys[i]).Interface() == expected
}
case reflect.Slice, reflect.Array:
if valActual.Type().Elem() != reflect.TypeOf(expected) {
panic("expected type not match actual element type")
}
for i := 0; i < valActual.Len() && !found; i++ {
found = valActual.Index(i).Interface() == expected
}
default:
panic("actual is not a string, array, slice or map")
}
return found
}
// NotContains checks is actual not contains substring/element expected.
//
// See Contains about supported actual/expected types and check logic.
func (t *C) NotContains(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!isContains(actual, expected))
}
// HasKey checks is actual has key expected.
func (t *C) HasKey(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
hasKey(actual, expected))
}
func hasKey(actual, expected any) bool {
return reflect.ValueOf(actual).MapIndex(reflect.ValueOf(expected)).IsValid()
}
// NotHasKey checks is actual has no key expected.
func (t *C) NotHasKey(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!hasKey(actual, expected))
}
// Zero checks is actual is zero value of it's type.
func (t *C) Zero(actual any, msg ...any) bool {
t.Helper()
return t.report1(actual, msg,
isZero(actual))
}
func isZero(actual any) bool {
if isNil(actual) {
return true
} else if typ := reflect.TypeOf(actual); typ.Comparable() {
// Not Func, Map, Slice, Array with non-comparable
// elements, Struct with non-comparable fields.
return actual == reflect.Zero(typ).Interface()
} else if typ.Kind() == reflect.Array {
zero := true
val := reflect.ValueOf(actual)
for i := 0; i < val.Len() && zero; i++ {
zero = isZero(val.Index(i).Interface())
}
return zero
}
// Func, Struct with non-comparable fields.
// Non-nil Map, Slice.
return false
}
// NotZero checks is actual is not zero value of it's type.
func (t *C) NotZero(actual any, msg ...any) bool {
t.Helper()
return t.report1(actual, msg,
!isZero(actual))
}
// Len checks is len(actual) == expected.
func (t *C) Len(actual any, expected int, msg ...any) bool {
t.Helper()
l := reflect.ValueOf(actual).Len()
return t.report2(l, expected, msg,
l == expected)
}
// NotLen checks is len(actual) != expected.
func (t *C) NotLen(actual any, expected int, msg ...any) bool {
t.Helper()
l := reflect.ValueOf(actual).Len()
return t.report2(l, expected, msg,
l != expected)
}
// Err checks is actual error is the same as expected error.
//
// If errors.Is() fails then it'll use more sofiscated logic:
//
// It tries to recursively unwrap actual before checking using
// errors.Unwrap() and github.com/pkg/errors.Cause().
// In case of multi-error (Unwrap() []error) it use only first error.
//
// It will use proto.Equal for gRPC status errors.
//
// They may be a different instances, but must have same type and value.
//
// Checking for nil is okay, but using Nil(actual) instead is more clean.
func (t *C) Err(actual, expected error, msg ...any) bool {
t.Helper()
actual2 := unwrapErr(actual)
equal := fmt.Sprintf("%#v", actual2) == fmt.Sprintf("%#v", expected)
_, proto1 := actual2.(interface{ GRPCStatus() *status.Status }) //nolint:errorlint // False positive.
_, proto2 := expected.(interface{ GRPCStatus() *status.Status }) //nolint:errorlint // False positive.
if proto1 || proto2 {
equal = proto.Equal(status.Convert(actual2).Proto(), status.Convert(expected).Proto())
}
if !equal {
equal = errors.Is(actual, expected)
}
return t.report2(actual, expected, msg, equal)
}
func unwrapErr(err error) (actual error) {
defer func() { _ = recover() }()
actual = err
for {
actual = pkgerrors.Cause(actual)
var unwrapped error
switch wrapped := actual.(type) { //nolint:errorlint // False positive.
case interface{ Unwrap() error }:
unwrapped = wrapped.Unwrap()
case interface{ Unwrap() []error }:
unwrappeds := wrapped.Unwrap()
if len(unwrappeds) > 0 {
unwrapped = unwrappeds[0]
}
}
if unwrapped == nil {
break
}
actual = unwrapped
}
return actual
}
// NotErr checks is actual error is not the same as expected error.
//
// It tries to recursively unwrap actual before checking using
// errors.Unwrap() and github.com/pkg/errors.Cause().
// In case of multi-error (Unwrap() []error) it use only first error.
//
// It will use !proto.Equal for gRPC status errors.
//
// They must have either different types or values (or one should be nil).
// Different instances with same type and value will be considered the
// same error, and so is both nil.
//
// Finally it'll use !errors.Is().
func (t *C) NotErr(actual, expected error, msg ...any) bool {
t.Helper()
actual2 := unwrapErr(actual)
notEqual := fmt.Sprintf("%#v", actual2) != fmt.Sprintf("%#v", expected)
_, proto1 := actual2.(interface{ GRPCStatus() *status.Status }) //nolint:errorlint // False positive.
_, proto2 := expected.(interface{ GRPCStatus() *status.Status }) //nolint:errorlint // False positive.
if proto1 || proto2 {
notEqual = !proto.Equal(status.Convert(actual2).Proto(), status.Convert(expected).Proto())
}
if notEqual {
notEqual = !errors.Is(actual, expected)
}
return t.report1(actual, msg, notEqual)
}
// Panic checks is actual() panics.
//
// It is able to detect panic(nil)… but you should try to avoid using this.
func (t *C) Panic(actual func(), msg ...any) bool {
t.Helper()
didPanic := true
func() {
defer func() { _ = recover() }()
actual()
didPanic = false
}()
return t.report0(msg,
didPanic)
}
// NotPanic checks is actual() don't panics.
//
// It is able to detect panic(nil)… but you should try to avoid using this.
func (t *C) NotPanic(actual func(), msg ...any) bool {
t.Helper()
didPanic := true
func() {
defer func() { _ = recover() }()
actual()
didPanic = false
}()
return t.report0(msg,
!didPanic)
}
// PanicMatch checks is actual() panics and panic text match regex.
//
// Regex type can be either *regexp.Regexp or string.
//
// In case of panic(nil) it will match like panic("<nil>").
func (t *C) PanicMatch(actual func(), regex any, msg ...any) bool {
t.Helper()
var panicVal any
didPanic := true
func() {
defer func() { panicVal = recover() }()
actual()
didPanic = false
}()
if !didPanic {
return t.report0(msg,
false)
}
switch panicVal.(type) {
case string, error:
default:
panicVal = fmt.Sprintf("%#v", panicVal)
}
ok := isMatch(&panicVal, regex)
return t.report2(panicVal, regex, msg,
ok)
}
// PanicNotMatch checks is actual() panics and panic text not match regex.
//
// Regex type can be either *regexp.Regexp or string.
//
// In case of panic(nil) it will match like panic("<nil>").
func (t *C) PanicNotMatch(actual func(), regex any, msg ...any) bool {
t.Helper()
var panicVal any
didPanic := true
func() {
defer func() { panicVal = recover() }()
actual()
didPanic = false
}()
if !didPanic {
return t.report0(msg,
false)
}
switch panicVal.(type) {
case string, error:
default:
panicVal = fmt.Sprintf("%#v", panicVal)
}
ok := !isMatch(&panicVal, regex)
return t.report2(panicVal, regex, msg,
ok)
}
// Less checks for actual < expected.
//
// Both actual and expected must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) Less(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
isLess(actual, expected))
}
func isLess(actual, expected any) bool {
switch v1, v2 := reflect.ValueOf(actual), reflect.ValueOf(expected); v1.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return v1.Int() < v2.Int()
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
return v1.Uint() < v2.Uint()
case reflect.Float32, reflect.Float64:
return v1.Float() < v2.Float()
case reflect.String:
return v1.String() < v2.String()
default:
if actualTime, ok := actual.(time.Time); ok {
return actualTime.Before(expected.(time.Time))
}
}
panic("actual is not a number, string or time.Time")
}
// LT is a synonym for Less.
func (t *C) LT(actual, expected any, msg ...any) bool {
t.Helper()
return t.Less(actual, expected, msg...)
}
// LessOrEqual checks for actual <= expected.
//
// Both actual and expected must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) LessOrEqual(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!isGreater(actual, expected))
}
func isGreater(actual, expected any) bool {
switch v1, v2 := reflect.ValueOf(actual), reflect.ValueOf(expected); v1.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return v1.Int() > v2.Int()
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
return v1.Uint() > v2.Uint()
case reflect.Float32, reflect.Float64:
return v1.Float() > v2.Float()
case reflect.String:
return v1.String() > v2.String()
default:
if actualTime, ok := actual.(time.Time); ok {
return actualTime.After(expected.(time.Time))
}
}
panic("actual is not a number, string or time.Time")
}
// LE is a synonym for LessOrEqual.
func (t *C) LE(actual, expected any, msg ...any) bool {
t.Helper()
return t.LessOrEqual(actual, expected, msg...)
}
// Greater checks for actual > expected.
//
// Both actual and expected must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) Greater(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
isGreater(actual, expected))
}
// GT is a synonym for Greater.
func (t *C) GT(actual, expected any, msg ...any) bool {
t.Helper()
return t.Greater(actual, expected, msg...)
}
// GreaterOrEqual checks for actual >= expected.
//
// Both actual and expected must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) GreaterOrEqual(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!isLess(actual, expected))
}
// GE is a synonym for GreaterOrEqual.
func (t *C) GE(actual, expected any, msg ...any) bool {
t.Helper()
return t.GreaterOrEqual(actual, expected, msg...)
}
// Between checks for min < actual < max.
//
// All three actual, min and max must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) Between(actual, min, max any, msg ...any) bool {
t.Helper()
return t.report3(actual, min, max, msg,
isBetween(actual, min, max))
}
func isBetween(actual, min, max any) bool {
switch v, vmin, vmax := reflect.ValueOf(actual), reflect.ValueOf(min), reflect.ValueOf(max); v.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return vmin.Int() < v.Int() && v.Int() < vmax.Int()
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
return vmin.Uint() < v.Uint() && v.Uint() < vmax.Uint()
case reflect.Float32, reflect.Float64:
return vmin.Float() < v.Float() && v.Float() < vmax.Float()
case reflect.String:
return vmin.String() < v.String() && v.String() < vmax.String()
default:
if actualTime, ok := actual.(time.Time); ok {
minTime := min.(time.Time) //nolint:forcetypeassert // Want panic.
maxTime := max.(time.Time) //nolint:forcetypeassert // Want panic.
return minTime.Before(actualTime) && actualTime.Before(maxTime)
}
}
panic("actual is not a number, string or time.Time")
}
// NotBetween checks for actual <= min or max <= actual.
//
// All three actual, min and max must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) NotBetween(actual, min, max any, msg ...any) bool {
t.Helper()
return t.report3(actual, min, max, msg,
!isBetween(actual, min, max))
}
// BetweenOrEqual checks for min <= actual <= max.
//
// All three actual, min and max must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) BetweenOrEqual(actual, min, max any, msg ...any) bool {
t.Helper()
return t.report3(actual, min, max, msg,
isBetween(actual, min, max) || isEqual(actual, min) || isEqual(actual, max))
}
// NotBetweenOrEqual checks for actual < min or max < actual.
//
// All three actual, min and max must be either:
// - signed integers
// - unsigned integers
// - floats
// - strings
// - time.Time
func (t *C) NotBetweenOrEqual(actual, min, max any, msg ...any) bool {
t.Helper()
return t.report3(actual, min, max, msg,
!(isBetween(actual, min, max) || isEqual(actual, min) || isEqual(actual, max)))
}
// InDelta checks for expected-delta <= actual <= expected+delta.
//
// All three actual, expected and delta must be either:
// - signed integers
// - unsigned integers
// - floats
// - time.Time (in this case delta must be time.Duration)
func (t *C) InDelta(actual, expected, delta any, msg ...any) bool {
t.Helper()
return t.report3(actual, expected, delta, msg,
isInDelta(actual, expected, delta))
}
func isInDelta(actual, expected, delta any) bool {
switch v, e, d := reflect.ValueOf(actual), reflect.ValueOf(expected), reflect.ValueOf(delta); v.Kind() { //nolint:exhaustive // Covered by default case.
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
min, max := e.Int()-d.Int(), e.Int()+d.Int()
return min <= v.Int() && v.Int() <= max
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
min, max := e.Uint()-d.Uint(), e.Uint()+d.Uint()
return min <= v.Uint() && v.Uint() <= max
case reflect.Float32, reflect.Float64:
min, max := e.Float()-d.Float(), e.Float()+d.Float()
return min <= v.Float() && v.Float() <= max
default:
if actualTime, ok := actual.(time.Time); ok {
expectedTime := expected.(time.Time) //nolint:forcetypeassert // Want panic.
dur := delta.(time.Duration) //nolint:forcetypeassert // Want panic.
minTime, maxTime := expectedTime.Add(-dur), expectedTime.Add(dur)
return minTime.Before(actualTime) && actualTime.Before(maxTime) ||
actualTime.Equal(minTime) ||
actualTime.Equal(maxTime)
}
}
panic("actual is not a number or time.Time")
}
// NotInDelta checks for actual < expected-delta or expected+delta < actual.
//
// All three actual, expected and delta must be either:
// - signed integers
// - unsigned integers
// - floats
// - time.Time (in this case delta must be time.Duration)
func (t *C) NotInDelta(actual, expected, delta any, msg ...any) bool {
t.Helper()
return t.report3(actual, expected, delta, msg,
!isInDelta(actual, expected, delta))
}
// InSMAPE checks that actual and expected have a symmetric mean absolute
// percentage error (SMAPE) is less than given smape.
//
// Both actual and expected must be either:
// - signed integers
// - unsigned integers
// - floats
//
// Allowed smape values are: 0.0 < smape < 100.0.
//
// Used formula returns SMAPE value between 0 and 100 (percents):
// - 0.0 when actual == expected
// - ~0.5 when they differs in ~1%
// - ~5 when they differs in ~10%
// - ~20 when they differs in 1.5 times
// - ~33 when they differs in 2 times
// - 50.0 when they differs in 3 times
// - ~82 when they differs in 10 times
// - 99.0+ when actual and expected differs in 200+ times
// - 100.0 when only one of actual or expected is 0 or one of them is
// positive while another is negative
func (t *C) InSMAPE(actual, expected any, smape float64, msg ...any) bool {
t.Helper()
return t.report3(actual, expected, smape, msg,
isInSMAPE(actual, expected, smape))
}
func isInSMAPE(actual, expected any, smape float64) bool {
if !(0 < smape && smape < 100) {
panic("smape is not in allowed range: 0 < smape < 100")
}
a := reflect.ValueOf(actual).Convert(typFloat64).Float()
e := reflect.ValueOf(expected).Convert(typFloat64).Float()
if a == 0 && e == 0 {
return true // avoid division by zero in legal use case
}
return 100*math.Abs(e-a)/(math.Abs(e)+math.Abs(a)) < smape
}
// NotInSMAPE checks that actual and expected have a symmetric mean
// absolute percentage error (SMAPE) is greater than or equal to given
// smape.
//
// See InSMAPE about supported actual/expected types and check logic.
func (t *C) NotInSMAPE(actual, expected any, smape float64, msg ...any) bool {
t.Helper()
return t.report3(actual, expected, smape, msg,
!isInSMAPE(actual, expected, smape))
}
// HasPrefix checks for strings.HasPrefix(actual, expected).
//
// Both actual and expected may have any of these types:
// - string - will use as is
// - []byte - will convert with string()
// - []rune - will convert with string()
// - fmt.Stringer - will convert with actual.String()
// - error - will convert with actual.Error()
// - nil - check will always fail
func (t *C) HasPrefix(actual, expected any, msg ...any) bool {
t.Helper()
ok := isHasPrefix(&actual, &expected)
return t.report2(actual, expected, msg,
ok)
}
// isHasPrefix updates actual and expected to be a real string used for check,
// to make dump easier to understand, but this result in losing type information.
func isHasPrefix(actual, expected *any) bool { //nolint:gocritic // False positive.
if *actual == nil || *expected == nil {
return false
}
if !stringify(actual) {
panic("actual is not a string, []byte, []rune, fmt.Stringer, error or nil")
}
if !stringify(expected) {
panic("expected is not a string, []byte, []rune, fmt.Stringer, error or nil")
}
return strings.HasPrefix((*actual).(string), (*expected).(string))
}
// NotHasPrefix checks for !strings.HasPrefix(actual, expected).
//
// See HasPrefix about supported actual/expected types and check logic.
func (t *C) NotHasPrefix(actual, expected any, msg ...any) bool {
t.Helper()
ok := !isHasPrefix(&actual, &expected)
return t.report2(actual, expected, msg,
ok)
}
// HasSuffix checks for strings.HasSuffix(actual, expected).
//
// Both actual and expected may have any of these types:
// - string - will use as is
// - []byte - will convert with string()
// - []rune - will convert with string()
// - fmt.Stringer - will convert with actual.String()
// - error - will convert with actual.Error()
// - nil - check will always fail
func (t *C) HasSuffix(actual, expected any, msg ...any) bool {
t.Helper()
ok := isHasSuffix(&actual, &expected)
return t.report2(actual, expected, msg,
ok)
}
// isHasSuffix updates actual and expected to be a real string used for check,
// to make dump easier to understand, but this result in losing type information.
func isHasSuffix(actual, expected *any) bool { //nolint:gocritic // False positive.
if *actual == nil || *expected == nil {
return false
}
if !stringify(actual) {
panic("actual is not a string, []byte, []rune, fmt.Stringer, error or nil")
}
if !stringify(expected) {
panic("expected is not a string, []byte, []rune, fmt.Stringer, error or nil")
}
return strings.HasSuffix((*actual).(string), (*expected).(string))
}
// NotHasSuffix checks for !strings.HasSuffix(actual, expected).
//
// See HasSuffix about supported actual/expected types and check logic.
func (t *C) NotHasSuffix(actual, expected any, msg ...any) bool {
t.Helper()
ok := !isHasSuffix(&actual, &expected)
return t.report2(actual, expected, msg,
ok)
}
// JSONEqual normalize formatting of actual and expected (if they're valid
// JSON) and then checks for bytes.Equal(actual, expected).
//
// Both actual and expected may have any of these types:
// - string
// - []byte
// - json.RawMessage
// - *json.RawMessage
// - nil
//
// In case any of actual or expected is nil or empty or (for string or
// []byte) is invalid JSON - check will fail.
func (t *C) JSONEqual(actual, expected any, msg ...any) bool {
t.Helper()
ok := isJSONEqual(actual, expected)
if !ok {
if buf := jsonify(actual); len(buf) != 0 {
actual = buf
}
if buf := jsonify(expected); len(buf) != 0 {
expected = buf
}
}
return t.report2(actual, expected, msg,
ok)
}
func isJSONEqual(actual, expected any) bool {
jsonActual, jsonExpected := jsonify(actual), jsonify(expected)
return len(jsonActual) != 0 && len(jsonExpected) != 0 &&
bytes.Equal(jsonActual, jsonExpected)
}
func jsonify(arg any) json.RawMessage {
switch v := (arg).(type) {
case nil:
return nil
case json.RawMessage:
return v
case *json.RawMessage:
if v == nil {
return nil
}
return *v
}
buf := reflect.ValueOf(arg).Convert(typBytes).Interface().([]byte) //nolint:forcetypeassert // Want panic.
var v any
err := json.Unmarshal(buf, &v)
if err != nil {
return nil
}
buf, err = json.Marshal(v)
if err != nil {
return nil
}
return buf
}
// HasType checks is actual has same type as expected.
func (t *C) HasType(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
reflect.TypeOf(actual) == reflect.TypeOf(expected))
}
// NotHasType checks is actual has not same type as expected.
func (t *C) NotHasType(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
reflect.TypeOf(actual) != reflect.TypeOf(expected))
}
// Implements checks is actual implements interface pointed by expected.
//
// You must use pointer to interface type in expected:
//
// t.Implements(os.Stdin, (*io.Reader)(nil))
func (t *C) Implements(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
isImplements(actual, expected))
}
func isImplements(actual, expected any) bool {
typActual := reflect.TypeOf(actual)
if typActual.Kind() != reflect.Ptr {
typActual = reflect.PtrTo(typActual)
}
return typActual.Implements(reflect.TypeOf(expected).Elem())
}
// NotImplements checks is actual does not implements interface pointed by expected.
//
// You must use pointer to interface type in expected:
//
// t.NotImplements(os.Stdin, (*fmt.Stringer)(nil))
func (t *C) NotImplements(actual, expected any, msg ...any) bool {
t.Helper()
return t.report2(actual, expected, msg,
!isImplements(actual, expected))
}