status-go/vendor/go.uber.org/dig/error.go

526 lines
14 KiB
Go

// Copyright (c) 2019 Uber Technologies, Inc.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
package dig
import (
"errors"
"fmt"
"io"
"reflect"
"sort"
"go.uber.org/dig/internal/digreflect"
"go.uber.org/dig/internal/dot"
)
// Error is an interface implemented by all Dig errors.
//
// Use this interface, in conjunction with [RootCause], in order to
// determine if errors you encounter come from Dig, or if they come
// from provided constructors or invoked functions. See [RootCause]
// for more info.
type Error interface {
error
// Writes the message or context for this error in the chain.
//
// Note: the Error interface must always have a private function
// such as this one in order to maintain properly sealed.
//
// verb is either %v or %+v.
writeMessage(w io.Writer, v string)
}
// a digError is a dig.Error with additional functionality for
// internal use - namely the ability to be formatted.
type digError interface {
Error
fmt.Formatter
}
// A PanicError occurs when a panic occurs while running functions given to the container
// with the [RecoverFromPanic] option being set. It contains the panic message from the
// original panic. A PanicError does not wrap other errors, and it does not implement
// dig.Error, meaning it will be returned from [RootCause]. With the [RecoverFromPanic]
// option set, a panic can be distinguished from dig errors and errors from provided/
// invoked/decorated functions like so:
//
// rootCause := dig.RootCause(err)
//
// var pe dig.PanicError
// var de dig.Error
// if errors.As(rootCause, &pe) {
// // This is caused by a panic
// } else if errors.As(err, &de) {
// // This is a dig error
// } else {
// // This is an error from one of my provided/invoked functions or decorators
// }
//
// Or, if only interested in distinguishing panics from errors:
//
// var pe dig.PanicError
// if errors.As(err, &pe) {
// // This is caused by a panic
// } else {
// // This is an error
// }
type PanicError struct {
// The function the panic occurred at
fn *digreflect.Func
// The panic that was returned from recover()
Panic any
}
// Format will format the PanicError, expanding the corresponding function if in +v mode.
func (e PanicError) Format(w fmt.State, c rune) {
if w.Flag('+') && c == 'v' {
fmt.Fprintf(w, "panic: %q in func: %+v", e.Panic, e.fn)
} else {
fmt.Fprintf(w, "panic: %q in func: %v", e.Panic, e.fn)
}
}
func (e PanicError) Error() string {
return fmt.Sprint(e)
}
// formatError will call a dig.Error's writeMessage() method to print the error message
// and then will automatically attempt to print errors wrapped underneath (which can create
// a recursive effect if the wrapped error's Format() method then points back to this function).
func formatError(e digError, w fmt.State, v rune) {
multiline := w.Flag('+') && v == 'v'
verb := "%v"
if multiline {
verb = "%+v"
}
// "context: " or "context:\n"
e.writeMessage(w, verb)
// Will route back to this function recursively if next error
// is also wrapped and points back here
wrappedError := errors.Unwrap(e)
if wrappedError == nil {
return
}
io.WriteString(w, ":")
if multiline {
io.WriteString(w, "\n")
} else {
io.WriteString(w, " ")
}
fmt.Fprintf(w, verb, wrappedError)
}
// RootCause returns the first non-dig.Error in a chain of wrapped
// errors, if there is one. Otherwise, RootCause returns the error
// on the bottom of the chain of wrapped errors.
//
// Use this function and errors.As to differentiate between Dig errors
// and errors thrown by provided constructors or invoked functions:
//
// rootCause := dig.RootCause(err)
// var de dig.Error
// if errors.As(rootCause, &de) {
// // Is a Dig error
// } else {
// // Is an error thrown by one of my provided/invoked/decorated functions
// }
//
// See [PanicError] for an example showing how to additionally detect
// and handle panics in provided/invoked/decorated functions.
func RootCause(err error) error {
var de Error
// Dig down to first non dig.Error, or bottom of chain
for ; errors.As(err, &de); err = errors.Unwrap(de) {
}
if err == nil {
return de
}
return err
}
// errInvalidInput is returned whenever the user provides bad input when
// interacting with the container. May optionally have a more detailed
// error wrapped underneath.
type errInvalidInput struct {
Message string
Cause error
}
var _ digError = errInvalidInput{}
// newErrInvalidInput creates a new errInvalidInput, wrapping the given
// other error that caused this error. If there is no underlying cause,
// pass in nil. This will cause all attempts to unwrap this error to return
// nil, replicating errors.Unwrap's behavior when passed an error without
// an Unwrap() method.
func newErrInvalidInput(msg string, cause error) errInvalidInput {
return errInvalidInput{msg, cause}
}
func (e errInvalidInput) Error() string { return fmt.Sprint(e) }
func (e errInvalidInput) Unwrap() error { return e.Cause }
func (e errInvalidInput) writeMessage(w io.Writer, _ string) {
fmt.Fprintf(w, e.Message)
}
func (e errInvalidInput) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
// errProvide is returned when a constructor could not be Provided into the
// container.
type errProvide struct {
Func *digreflect.Func
Reason error
}
var _ digError = errProvide{}
func (e errProvide) Error() string { return fmt.Sprint(e) }
func (e errProvide) Unwrap() error { return e.Reason }
func (e errProvide) writeMessage(w io.Writer, verb string) {
fmt.Fprintf(w, "cannot provide function "+verb, e.Func)
}
func (e errProvide) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
// errConstructorFailed is returned when a user-provided constructor failed
// with a non-nil error.
type errConstructorFailed struct {
Func *digreflect.Func
Reason error
}
var _ digError = errConstructorFailed{}
func (e errConstructorFailed) Error() string { return fmt.Sprint(e) }
func (e errConstructorFailed) Unwrap() error { return e.Reason }
func (e errConstructorFailed) writeMessage(w io.Writer, verb string) {
fmt.Fprintf(w, "received non-nil error from function "+verb, e.Func)
}
func (e errConstructorFailed) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
// errArgumentsFailed is returned when a function could not be run because one
// of its dependencies failed to build for any reason.
type errArgumentsFailed struct {
Func *digreflect.Func
Reason error
}
var _ digError = errArgumentsFailed{}
func (e errArgumentsFailed) Error() string { return fmt.Sprint(e) }
func (e errArgumentsFailed) Unwrap() error { return e.Reason }
func (e errArgumentsFailed) writeMessage(w io.Writer, verb string) {
fmt.Fprintf(w, "could not build arguments for function "+verb, e.Func)
}
func (e errArgumentsFailed) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
// errMissingDependencies is returned when the dependencies of a function are
// not available in the container.
type errMissingDependencies struct {
Func *digreflect.Func
Reason error
}
var _ digError = errMissingDependencies{}
func (e errMissingDependencies) Error() string { return fmt.Sprint(e) }
func (e errMissingDependencies) Unwrap() error { return e.Reason }
func (e errMissingDependencies) writeMessage(w io.Writer, verb string) {
fmt.Fprintf(w, "missing dependencies for function "+verb, e.Func)
}
func (e errMissingDependencies) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
// errParamSingleFailed is returned when a paramSingle could not be built.
type errParamSingleFailed struct {
Key key
Reason error
CtorID dot.CtorID
}
var _ digError = errParamSingleFailed{}
func (e errParamSingleFailed) Error() string { return fmt.Sprint(e) }
func (e errParamSingleFailed) Unwrap() error { return e.Reason }
func (e errParamSingleFailed) writeMessage(w io.Writer, _ string) {
fmt.Fprintf(w, "failed to build %v", e.Key)
}
func (e errParamSingleFailed) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
func (e errParamSingleFailed) updateGraph(g *dot.Graph) {
failed := &dot.Result{
Node: &dot.Node{
Name: e.Key.name,
Group: e.Key.group,
Type: e.Key.t,
},
}
g.FailNodes([]*dot.Result{failed}, e.CtorID)
}
// errParamGroupFailed is returned when a value group cannot be built because
// any of the values in the group failed to build.
type errParamGroupFailed struct {
Key key
Reason error
CtorID dot.CtorID
}
var _ digError = errParamGroupFailed{}
func (e errParamGroupFailed) Error() string { return fmt.Sprint(e) }
func (e errParamGroupFailed) Unwrap() error { return e.Reason }
func (e errParamGroupFailed) writeMessage(w io.Writer, _ string) {
fmt.Fprintf(w, "could not build value group %v", e.Key)
}
func (e errParamGroupFailed) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
func (e errParamGroupFailed) updateGraph(g *dot.Graph) {
g.FailGroupNodes(e.Key.group, e.Key.t, e.CtorID)
}
// missingType holds information about a type that was missing in the
// container.
type missingType struct {
Key key // item that was missing
// If non-empty, we will include suggestions for what the user may have
// meant.
suggestions []key
}
// Format prints a string representation of missingType.
//
// With %v, it prints a short representation ideal for an itemized list.
//
// io.Writer
// io.Writer: did you mean *bytes.Buffer?
// io.Writer: did you mean *bytes.Buffer, or *os.File?
//
// With %+v, it prints a longer representation ideal for standalone output.
//
// io.Writer: did you mean to Provide it?
// io.Writer: did you mean to use *bytes.Buffer?
// io.Writer: did you mean to use one of *bytes.Buffer, or *os.File?
func (mt missingType) Format(w fmt.State, v rune) {
plusV := w.Flag('+') && v == 'v'
fmt.Fprint(w, mt.Key)
switch len(mt.suggestions) {
case 0:
if plusV {
io.WriteString(w, " (did you mean to Provide it?)")
}
case 1:
sug := mt.suggestions[0]
if plusV {
fmt.Fprintf(w, " (did you mean to use %v?)", sug)
} else {
fmt.Fprintf(w, " (did you mean %v?)", sug)
}
default:
if plusV {
io.WriteString(w, " (did you mean to use one of ")
} else {
io.WriteString(w, " (did you mean ")
}
lastIdx := len(mt.suggestions) - 1
for i, sug := range mt.suggestions {
if i > 0 {
io.WriteString(w, ", ")
if i == lastIdx {
io.WriteString(w, "or ")
}
}
fmt.Fprint(w, sug)
}
io.WriteString(w, "?)")
}
}
// errMissingType is returned when one or more values that were expected in
// the container were not available.
//
// Multiple instances of this error may be merged together by appending them.
type errMissingTypes []missingType // inv: len > 0
var _ digError = errMissingTypes(nil)
func newErrMissingTypes(c containerStore, k key) errMissingTypes {
// Possible types we will look for in the container. We will always look
// for pointers to the requested type and some extras on a per-Kind basis.
suggestions := []reflect.Type{reflect.PtrTo(k.t)}
if k.t.Kind() == reflect.Ptr {
// The user requested a pointer but maybe we have a value.
suggestions = append(suggestions, k.t.Elem())
}
if k.t.Kind() == reflect.Slice {
// Maybe the user meant a slice of pointers while we have the slice of elements
suggestions = append(suggestions, reflect.SliceOf(reflect.PtrTo(k.t.Elem())))
// Maybe the user meant a slice of elements while we have the slice of pointers
sliceElement := k.t.Elem()
if sliceElement.Kind() == reflect.Ptr {
suggestions = append(suggestions, reflect.SliceOf(sliceElement.Elem()))
}
}
if k.t.Kind() == reflect.Array {
// Maybe the user meant an array of pointers while we have the array of elements
suggestions = append(suggestions, reflect.ArrayOf(k.t.Len(), reflect.PtrTo(k.t.Elem())))
// Maybe the user meant an array of elements while we have the array of pointers
arrayElement := k.t.Elem()
if arrayElement.Kind() == reflect.Ptr {
suggestions = append(suggestions, reflect.ArrayOf(k.t.Len(), arrayElement.Elem()))
}
}
knownTypes := c.knownTypes()
if k.t.Kind() == reflect.Interface {
// Maybe we have an implementation of the interface.
for _, t := range knownTypes {
if t.Implements(k.t) {
suggestions = append(suggestions, t)
}
}
} else {
// Maybe we have an interface that this type implements.
for _, t := range knownTypes {
if t.Kind() == reflect.Interface {
if k.t.Implements(t) {
suggestions = append(suggestions, t)
}
}
}
}
// range through c.providers is non-deterministic. Let's sort the list of
// suggestions.
sort.Sort(byTypeName(suggestions))
mt := missingType{Key: k}
for _, t := range suggestions {
if len(c.getValueProviders(k.name, t)) > 0 {
k.t = t
mt.suggestions = append(mt.suggestions, k)
}
}
return errMissingTypes{mt}
}
func (e errMissingTypes) Error() string { return fmt.Sprint(e) }
func (e errMissingTypes) writeMessage(w io.Writer, v string) {
multiline := v == "%+v"
if len(e) == 1 {
io.WriteString(w, "missing type:")
} else {
io.WriteString(w, "missing types:")
}
if !multiline {
// With %v, we need a space between : since the error
// won't be on a new line.
io.WriteString(w, " ")
}
for i, mt := range e {
if multiline {
io.WriteString(w, "\n\t- ")
} else if i > 0 {
io.WriteString(w, "; ")
}
if multiline {
fmt.Fprintf(w, "%+v", mt)
} else {
fmt.Fprintf(w, "%v", mt)
}
}
}
func (e errMissingTypes) Format(w fmt.State, c rune) {
formatError(e, w, c)
}
func (e errMissingTypes) updateGraph(g *dot.Graph) {
missing := make([]*dot.Result, len(e))
for i, mt := range e {
missing[i] = &dot.Result{
Node: &dot.Node{
Name: mt.Key.name,
Group: mt.Key.group,
Type: mt.Key.t,
},
}
}
g.AddMissingNodes(missing)
}
type errVisualizer interface {
updateGraph(*dot.Graph)
}