Go Language dns seeder for Bitcoin based networks
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// Copyright (c) 2015 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package btcjson
import (
"fmt"
"reflect"
"strings"
)
// CmdMethod returns the method for the passed command. The provided command
// type must be a registered type. All commands provided by this package are
// registered by default.
func CmdMethod(cmd interface{}) (string, error) {
// Look up the cmd type and error out if not registered.
rt := reflect.TypeOf(cmd)
registerLock.RLock()
method, ok := concreteTypeToMethod[rt]
registerLock.RUnlock()
if !ok {
str := fmt.Sprintf("%q is not registered", method)
return "", makeError(ErrUnregisteredMethod, str)
}
return method, nil
}
// MethodUsageFlags returns the usage flags for the passed command method. The
// provided method must be associated with a registered type. All commands
// provided by this package are registered by default.
func MethodUsageFlags(method string) (UsageFlag, error) {
// Look up details about the provided method and error out if not
// registered.
registerLock.RLock()
info, ok := methodToInfo[method]
registerLock.RUnlock()
if !ok {
str := fmt.Sprintf("%q is not registered", method)
return 0, makeError(ErrUnregisteredMethod, str)
}
return info.flags, nil
}
// subStructUsage returns a string for use in the one-line usage for the given
// sub struct. Note that this is specifically for fields which consist of
// structs (or an array/slice of structs) as opposed to the top-level command
// struct.
//
// Any fields that include a jsonrpcusage struct tag will use that instead of
// being automatically generated.
func subStructUsage(structType reflect.Type) string {
numFields := structType.NumField()
fieldUsages := make([]string, 0, numFields)
for i := 0; i < structType.NumField(); i++ {
rtf := structType.Field(i)
// When the field has a jsonrpcusage struct tag specified use
// that instead of automatically generating it.
if tag := rtf.Tag.Get("jsonrpcusage"); tag != "" {
fieldUsages = append(fieldUsages, tag)
continue
}
// Create the name/value entry for the field while considering
// the type of the field. Not all possibile types are covered
// here and when one of the types not specifically covered is
// encountered, the field name is simply reused for the value.
fieldName := strings.ToLower(rtf.Name)
fieldValue := fieldName
fieldKind := rtf.Type.Kind()
switch {
case isNumeric(fieldKind):
if fieldKind == reflect.Float32 || fieldKind == reflect.Float64 {
fieldValue = "n.nnn"
} else {
fieldValue = "n"
}
case fieldKind == reflect.String:
fieldValue = `"value"`
case fieldKind == reflect.Struct:
fieldValue = subStructUsage(rtf.Type)
case fieldKind == reflect.Array || fieldKind == reflect.Slice:
fieldValue = subArrayUsage(rtf.Type, fieldName)
}
usage := fmt.Sprintf("%q:%s", fieldName, fieldValue)
fieldUsages = append(fieldUsages, usage)
}
return fmt.Sprintf("{%s}", strings.Join(fieldUsages, ","))
}
// subArrayUsage returns a string for use in the one-line usage for the given
// array or slice. It also contains logic to convert plural field names to
// singular so the generated usage string reads better.
func subArrayUsage(arrayType reflect.Type, fieldName string) string {
// Convert plural field names to singular. Only works for English.
singularFieldName := fieldName
if strings.HasSuffix(fieldName, "ies") {
singularFieldName = strings.TrimSuffix(fieldName, "ies")
singularFieldName = singularFieldName + "y"
} else if strings.HasSuffix(fieldName, "es") {
singularFieldName = strings.TrimSuffix(fieldName, "es")
} else if strings.HasSuffix(fieldName, "s") {
singularFieldName = strings.TrimSuffix(fieldName, "s")
}
elemType := arrayType.Elem()
switch elemType.Kind() {
case reflect.String:
return fmt.Sprintf("[%q,...]", singularFieldName)
case reflect.Struct:
return fmt.Sprintf("[%s,...]", subStructUsage(elemType))
}
// Fall back to simply showing the field name in array syntax.
return fmt.Sprintf(`[%s,...]`, singularFieldName)
}
// fieldUsage returns a string for use in the one-line usage for the struct
// field of a command.
//
// Any fields that include a jsonrpcusage struct tag will use that instead of
// being automatically generated.
func fieldUsage(structField reflect.StructField, defaultVal *reflect.Value) string {
// When the field has a jsonrpcusage struct tag specified use that
// instead of automatically generating it.
if tag := structField.Tag.Get("jsonrpcusage"); tag != "" {
return tag
}
// Indirect the pointer if needed.
fieldType := structField.Type
if fieldType.Kind() == reflect.Ptr {
fieldType = fieldType.Elem()
}
// When there is a default value, it must also be a pointer due to the
// rules enforced by RegisterCmd.
if defaultVal != nil {
indirect := defaultVal.Elem()
defaultVal = &indirect
}
// Handle certain types uniquely to provide nicer usage.
fieldName := strings.ToLower(structField.Name)
switch fieldType.Kind() {
case reflect.String:
if defaultVal != nil {
return fmt.Sprintf("%s=%q", fieldName,
defaultVal.Interface())
}
return fmt.Sprintf("%q", fieldName)
case reflect.Array, reflect.Slice:
return subArrayUsage(fieldType, fieldName)
case reflect.Struct:
return subStructUsage(fieldType)
}
// Simply return the field name when none of the above special cases
// apply.
if defaultVal != nil {
return fmt.Sprintf("%s=%v", fieldName, defaultVal.Interface())
}
return fieldName
}
// methodUsageText returns a one-line usage string for the provided command and
// method info. This is the main work horse for the exported MethodUsageText
// function.
func methodUsageText(rtp reflect.Type, defaults map[int]reflect.Value, method string) string {
// Generate the individual usage for each field in the command. Several
// simplifying assumptions are made here because the RegisterCmd
// function has already rigorously enforced the layout.
rt := rtp.Elem()
numFields := rt.NumField()
reqFieldUsages := make([]string, 0, numFields)
optFieldUsages := make([]string, 0, numFields)
for i := 0; i < numFields; i++ {
rtf := rt.Field(i)
var isOptional bool
if kind := rtf.Type.Kind(); kind == reflect.Ptr {
isOptional = true
}
var defaultVal *reflect.Value
if defVal, ok := defaults[i]; ok {
defaultVal = &defVal
}
// Add human-readable usage to the appropriate slice that is
// later used to generate the one-line usage.
usage := fieldUsage(rtf, defaultVal)
if isOptional {
optFieldUsages = append(optFieldUsages, usage)
} else {
reqFieldUsages = append(reqFieldUsages, usage)
}
}
// Generate and return the one-line usage string.
usageStr := method
if len(reqFieldUsages) > 0 {
usageStr += " " + strings.Join(reqFieldUsages, " ")
}
if len(optFieldUsages) > 0 {
usageStr += fmt.Sprintf(" (%s)", strings.Join(optFieldUsages, " "))
}
return usageStr
}
// MethodUsageText returns a one-line usage string for the provided method. The
// provided method must be associated with a registered type. All commands
// provided by this package are registered by default.
func MethodUsageText(method string) (string, error) {
// Look up details about the provided method and error out if not
// registered.
registerLock.RLock()
rtp, ok := methodToConcreteType[method]
info := methodToInfo[method]
registerLock.RUnlock()
if !ok {
str := fmt.Sprintf("%q is not registered", method)
return "", makeError(ErrUnregisteredMethod, str)
}
// When the usage for this method has already been generated, simply
// return it.
if info.usage != "" {
return info.usage, nil
}
// Generate and store the usage string for future calls and return it.
usage := methodUsageText(rtp, info.defaults, method)
registerLock.Lock()
info.usage = usage
methodToInfo[method] = info
registerLock.Unlock()
return usage, nil
}