Remove mxj, Update gopkg.in/check.v1

This commit is contained in:
Harshavardhana 2015-04-03 18:59:35 -07:00
parent 4079dd1d12
commit 717913bc8a
73 changed files with 74 additions and 11179 deletions

10
Godeps/Godeps.json generated
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@ -1,18 +1,10 @@
{
"ImportPath": "github.com/minio-io/minio",
"GoVersion": "go1.4.2",
"GoVersion": "go1.4",
"Packages": [
"./..."
],
"Deps": [
{
"ImportPath": "github.com/clbanning/mxj",
"Rev": "e11b85050263aff26728fb9863bf2ebaf6591279"
},
{
"ImportPath": "github.com/fatih/structs",
"Rev": "c00d27128bb88e9c1adab1a53cda9c72c6d1ff9b"
},
{
"ImportPath": "github.com/gorilla/context",
"Rev": "50c25fb3b2b3b3cc724e9b6ac75fb44b3bccd0da"

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@ -1,55 +0,0 @@
Copyright (c) 2012-2014 Charles Banning <clbanning@gmail.com>. All rights reserved.
The MIT License (MIT)
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.
===============================================================================
Go Language Copyright & License -
Copyright 2009 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.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following disclaimer
in the documentation and/or other materials provided with the
distribution.
* Neither the name of Google Inc. nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

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@ -1,177 +0,0 @@
package mxj
import (
"encoding/xml"
"reflect"
)
const (
DefaultElementTag = "element"
)
// Encode arbitrary value as XML.
//
// Note: unmarshaling the resultant
// XML may not return the original value, since tag labels may have been injected
// to create the XML representation of the value.
/*
Encode an arbitrary JSON object.
package main
import (
"encoding/json"
"fmt"
"github/clbanning/mxj"
)
func main() {
jsondata := []byte(`[
{ "somekey":"somevalue" },
"string",
3.14159265,
true
]`)
var i interface{}
err := json.Unmarshal(jsondata, &i)
if err != nil {
// do something
}
x, err := anyxml.XmlIndent(i, "", " ", "mydoc")
if err != nil {
// do something else
}
fmt.Println(string(x))
}
output:
<mydoc>
<somekey>somevalue</somekey>
<element>string</element>
<element>3.14159265</element>
<element>true</element>
</mydoc>
*/
// Alternative values for DefaultRootTag and DefaultElementTag can be set as:
// AnyXmlIndent( v, myRootTag, myElementTag).
func AnyXml(v interface{}, tags ...string) ([]byte, error) {
if reflect.TypeOf(v).Kind() == reflect.Struct {
return xml.Marshal(v)
}
var err error
s := new(string)
p := new(pretty)
var rt, et string
if len(tags) == 1 || len(tags) == 2 {
rt = tags[0]
} else {
rt = DefaultRootTag
}
if len(tags) == 2 {
et = tags[1]
} else {
et = DefaultElementTag
}
var ss string
var b []byte
switch v.(type) {
case []interface{}:
ss = "<" + rt + ">"
for _, vv := range v.([]interface{}) {
switch vv.(type) {
case map[string]interface{}:
m := vv.(map[string]interface{})
if len(m) == 1 {
for tag, val := range m {
err = mapToXmlIndent(false, s, tag, val, p)
}
} else {
err = mapToXmlIndent(false, s, et, vv, p)
}
default:
err = mapToXmlIndent(false, s, et, vv, p)
}
if err != nil {
break
}
}
ss += *s + "</" + rt + ">"
b = []byte(ss)
case map[string]interface{}:
m := Map(v.(map[string]interface{}))
b, err = m.Xml(rt)
default:
err = mapToXmlIndent(false, s, rt, v, p)
b = []byte(*s)
}
return b, err
}
// Encode an arbitrary value as a pretty XML string.
// Alternative values for DefaultRootTag and DefaultElementTag can be set as:
// AnyXmlIndent( v, "", " ", myRootTag, myElementTag).
func AnyXmlIndent(v interface{}, prefix, indent string, tags ...string) ([]byte, error) {
if reflect.TypeOf(v).Kind() == reflect.Struct {
return xml.MarshalIndent(v, prefix, indent)
}
var err error
s := new(string)
p := new(pretty)
p.indent = indent
p.padding = prefix
var rt, et string
if len(tags) == 1 || len(tags) == 2 {
rt = tags[0]
} else {
rt = DefaultRootTag
}
if len(tags) == 2 {
et = tags[1]
} else {
et = DefaultElementTag
}
var ss string
var b []byte
switch v.(type) {
case []interface{}:
ss = "<" + rt + ">\n"
p.Indent()
for _, vv := range v.([]interface{}) {
switch vv.(type) {
case map[string]interface{}:
m := vv.(map[string]interface{})
if len(m) == 1 {
for tag, val := range m {
err = mapToXmlIndent(true, s, tag, val, p)
}
} else {
p.start = 1 // we 1 tag in
err = mapToXmlIndent(true, s, et, vv, p)
*s += "\n"
}
default:
p.start = 0 // in case trailing p.start = 1
err = mapToXmlIndent(true, s, et, vv, p)
}
if err != nil {
break
}
}
ss += *s + "</" + rt + ">"
b = []byte(ss)
case map[string]interface{}:
m := Map(v.(map[string]interface{}))
b, err = m.XmlIndent(prefix, indent, rt)
default:
err = mapToXmlIndent(true, s, rt, v, p)
b = []byte(*s)
}
return b, err
}

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@ -1,110 +0,0 @@
package mxj
import (
"encoding/json"
"fmt"
"testing"
)
func TestAnyXmlHeader(t *testing.T) {
fmt.Println("\n---------------- anyxml_test.go ...\n")
}
var anydata = []byte(`[
{
"somekey": "somevalue"
},
{
"somekey": "somevalue"
},
{
"somekey": "somevalue",
"someotherkey": "someothervalue"
},
"string",
3.14159265,
true
]`)
type MyStruct struct {
Somekey string `xml:"somekey"`
B float32 `xml:"floatval"`
}
func TestAnyXml(t *testing.T) {
var i interface{}
err := json.Unmarshal(anydata, &i)
if err != nil {
t.Fatal(err)
}
x, err := AnyXml(i)
if err != nil {
t.Fatal(err)
}
fmt.Println("[]->x:", string(x))
a := []interface{}{"try", "this", 3.14159265, true}
x, err = AnyXml(a)
if err != nil {
t.Fatal(err)
}
fmt.Println("a->x:", string(x))
x, err = AnyXml(a, "myRootTag", "myElementTag")
if err != nil {
t.Fatal(err)
}
fmt.Println("a->x:", string(x))
x, err = AnyXml(3.14159625)
if err != nil {
t.Fatal(err)
}
fmt.Println("f->x:", string(x))
s := MyStruct{"somevalue", 3.14159625}
x, err = AnyXml(s)
if err != nil {
t.Fatal(err)
}
fmt.Println("s->x:", string(x))
}
func TestAnyXmlIndent(t *testing.T) {
var i interface{}
err := json.Unmarshal(anydata, &i)
if err != nil {
t.Fatal(err)
}
x, err := AnyXmlIndent(i, "", " ")
if err != nil {
t.Fatal(err)
}
fmt.Println("[]->x:\n", string(x))
a := []interface{}{"try", "this", 3.14159265, true}
x, err = AnyXmlIndent(a, "", " ")
if err != nil {
t.Fatal(err)
}
fmt.Println("a->x:\n", string(x))
x, err = AnyXmlIndent(3.14159625, "", " ")
if err != nil {
t.Fatal(err)
}
fmt.Println("f->x:\n", string(x))
x, err = AnyXmlIndent(3.14159625, "", " ", "myRootTag", "myElementTag")
if err != nil {
t.Fatal(err)
}
fmt.Println("f->x:\n", string(x))
s := MyStruct{"somevalue", 3.14159625}
x, err = AnyXmlIndent(s, "", " ")
if err != nil {
t.Fatal(err)
}
fmt.Println("s->x:\n", string(x))
}

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@ -1,107 +0,0 @@
// bulk_test.go - uses Handler and Writer functions to process some streams as a demo.
package mxj
import (
"bytes"
"fmt"
"testing"
)
func TestBulkHeader(t *testing.T) {
fmt.Println("\n---------------- bulk_test.go ...\n")
}
var jsonWriter = new(bytes.Buffer)
var xmlWriter = new(bytes.Buffer)
var jsonErrLog = new(bytes.Buffer)
var xmlErrLog = new(bytes.Buffer)
func TestXmlReader(t *testing.T) {
// create Reader for xmldata
xmlReader := bytes.NewReader(xmldata)
// read XML from Readerand pass Map value with the raw XML to handler
err := HandleXmlReader(xmlReader, bxmaphandler, bxerrhandler)
if err != nil {
t.Fatal("err:", err.Error())
}
// get the JSON
j := make([]byte, jsonWriter.Len())
_, _ = jsonWriter.Read(j)
// get the errors
e := make([]byte, xmlErrLog.Len())
_, _ = xmlErrLog.Read(e)
// print the input
fmt.Println("XmlReader, xmldata:\n", string(xmldata))
// print the result
fmt.Println("XmlReader, result :\n", string(j))
// print the errors
fmt.Println("XmlReader, errors :\n", string(e))
}
func bxmaphandler(m Map) bool {
j, err := m.JsonIndent("", " ", true)
if err != nil {
return false
}
_, _ = jsonWriter.Write(j)
// put in a NL to pretty up printing the Writer
_, _ = jsonWriter.Write([]byte("\n"))
return true
}
func bxerrhandler(err error) bool {
// write errors to file
_, _ = xmlErrLog.Write([]byte(err.Error()))
_, _ = xmlErrLog.Write([]byte("\n")) // pretty up
return true
}
func TestJsonReader(t *testing.T) {
jsonReader := bytes.NewReader(jsondata)
// read all the JSON
err := HandleJsonReader(jsonReader, bjmaphandler, bjerrhandler)
if err != nil {
t.Fatal("err:", err.Error())
}
// get the XML
x := make([]byte, xmlWriter.Len())
_, _ = xmlWriter.Read(x)
// get the errors
e := make([]byte, jsonErrLog.Len())
_, _ = jsonErrLog.Read(e)
// print the input
fmt.Println("JsonReader, jsondata:\n", string(jsondata))
// print the result
fmt.Println("JsonReader, result :\n", string(x))
// print the errors
fmt.Println("JsonReader, errors :\n", string(e))
}
func bjmaphandler(m Map) bool {
x, err := m.XmlIndent(" ", " ")
if err != nil {
return false
}
_, _ = xmlWriter.Write(x)
// put in a NL to pretty up printing the Writer
_, _ = xmlWriter.Write([]byte("\n"))
return true
}
func bjerrhandler(err error) bool {
// write errors to file
_, _ = jsonErrLog.Write([]byte(err.Error()))
_, _ = jsonErrLog.Write([]byte("\n")) // pretty up
return true
}

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@ -1,113 +0,0 @@
// bulk_test.go - uses Handler and Writer functions to process some streams as a demo.
package mxj
import (
"bytes"
"fmt"
"testing"
)
func TestBulkRawHeader(t *testing.T) {
fmt.Println("\n---------------- bulkraw_test.go ...\n")
}
// use data from bulk_test.go
var jsonWriterRaw = new(bytes.Buffer)
var xmlWriterRaw = new(bytes.Buffer)
var jsonErrLogRaw = new(bytes.Buffer)
var xmlErrLogRaw = new(bytes.Buffer)
func TestXmlReaderRaw(t *testing.T) {
// create Reader for xmldata
xmlReader := bytes.NewReader(xmldata)
// read XML from Reader and pass Map value with the raw XML to handler
err := HandleXmlReaderRaw(xmlReader, bxmaphandlerRaw, bxerrhandlerRaw)
if err != nil {
t.Fatal("err:", err.Error())
}
// get the JSON
j := make([]byte, jsonWriterRaw.Len())
_, _ = jsonWriterRaw.Read(j)
// get the errors
e := make([]byte, xmlErrLogRaw.Len())
_, _ = xmlErrLogRaw.Read(e)
// print the input
fmt.Println("XmlReaderRaw, xmldata:\n", string(xmldata))
// print the result
fmt.Println("XmlReaderRaw, result :\n", string(j))
// print the errors
fmt.Println("XmlReaderRaw, errors :\n", string(e))
}
func bxmaphandlerRaw(m Map, raw []byte) bool {
j, err := m.JsonIndent("", " ", true)
if err != nil {
return false
}
_, _ = jsonWriterRaw.Write(j)
// put in a NL to pretty up printing the Writer
_, _ = jsonWriterRaw.Write([]byte("\n"))
return true
}
func bxerrhandlerRaw(err error, raw []byte) bool {
// write errors to file
_, _ = xmlErrLogRaw.Write([]byte(err.Error()))
_, _ = xmlErrLogRaw.Write([]byte("\n")) // pretty up
_, _ = xmlErrLogRaw.Write(raw)
_, _ = xmlErrLogRaw.Write([]byte("\n")) // pretty up
return true
}
func TestJsonReaderRaw(t *testing.T) {
jsonReader := bytes.NewReader(jsondata)
// read all the JSON
err := HandleJsonReaderRaw(jsonReader, bjmaphandlerRaw, bjerrhandlerRaw)
if err != nil {
t.Fatal("err:", err.Error())
}
// get the XML
x := make([]byte, xmlWriterRaw.Len())
_, _ = xmlWriterRaw.Read(x)
// get the errors
e := make([]byte, jsonErrLogRaw.Len())
_, _ = jsonErrLogRaw.Read(e)
// print the input
fmt.Println("JsonReaderRaw, jsondata:\n", string(jsondata))
// print the result
fmt.Println("JsonReaderRaw, result :\n", string(x))
// print the errors
fmt.Println("JsonReaderRaw, errors :\n", string(e))
}
func bjmaphandlerRaw(m Map, raw []byte) bool {
x, err := m.XmlIndent(" ", " ")
if err != nil {
return false
}
_, _ = xmlWriterRaw.Write(x)
// put in a NL to pretty up printing the Writer
_, _ = xmlWriterRaw.Write([]byte("\n"))
return true
}
func bjerrhandlerRaw(err error, raw []byte) bool {
// write errors to file
_, _ = jsonErrLogRaw.Write([]byte(err.Error()))
_, _ = jsonErrLogRaw.Write([]byte("\n")) // pretty up, Error() from json.Unmarshal !NL
_, _ = jsonErrLogRaw.Write(raw)
_, _ = jsonErrLogRaw.Write([]byte("\n")) // pretty up
return true
}

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@ -1,38 +0,0 @@
package mxj
var xmldata = []byte(`
<book>
<author>William H. Gaddis</author>
<title>The Recognitions</title>
<review>One of the seminal American novels of the 20th century.</review>
</book>
<book>
<author>William H. Gaddis</author>
<title>JR</title>
<review>Won the National Book Award.</end_tag_error>
</book>
<book>
<author>Austin Tappan Wright</author>
<title>Islandia</title>
<review>An example of earlier 20th century American utopian fiction.</review>
</book>
<book>
<author>John Hawkes</author>
<title>The Beetle Leg</title>
<review>A lyrical novel about the construction of Ft. Peck Dam in Montana.</review>
</book>
<book>
<author>
<first_name>T.E.</first_name>
<last_name>Porter</last_name>
</author>
<title>King's Day</title>
<review>A magical novella.</review>
</book>`)
var jsondata = []byte(`
{"book":{"author":"William H. Gaddis","review":"One of the great seminal American novels of the 20th century.","title":"The Recognitions"}}
{"book":{"author":"Austin Tappan Wright","review":"An example of earlier 20th century American utopian fiction.","title":"Islandia"}}
{"book":{"author":"John Hawkes","review":"A lyrical novel about the construction of Ft. Peck Dam in Montana.","title":"The Beetle Leg"}}
{"book":{"author":{"first_name":"T.E.","last_name":"Porter"},"review":"A magical novella.","title":"King's Day"}}
{ "here":"we", "put":"in", "an":error }`)

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@ -1,84 +0,0 @@
// mxj - A collection of map[string]interface{} and associated XML and JSON utilities.
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
/*
Marshal/Unmarshal XML to/from JSON and map[string]interface{} values, and extract/modify values from maps by key or key-path, including wildcards.
mxj supplants the legacy x2j and j2x packages. If you want the old syntax, use mxj/x2j or mxj/j2x packages.
Note: this library was designed for processing ad hoc anonymous messages. Bulk processing large data sets may be much more efficiently performed using the encoding/xml or encoding/json packages from Go's standard library directly.
Note:
2014-08-02: AnyXml() and AnyXmlIndent() will try to marshal arbitrary values to XML.
SUMMARY
type Map map[string]interface{}
Create a Map value, 'm', from any map[string]interface{} value, 'v':
m := Map(v)
Unmarshal / marshal XML as a Map value, 'm':
m, err := NewMapXml(xmlValue) // unmarshal
xmlValue, err := m.Xml() // marshal
Unmarshal XML from an io.Reader as a Map value, 'm':
m, err := NewMapReader(xmlReader) // repeated calls, as with an os.File Reader, will process stream
m, raw, err := NewMapReaderRaw(xmlReader) // 'raw' is the raw XML that was decoded
Marshal Map value, 'm', to an XML Writer (io.Writer):
err := m.XmlWriter(xmlWriter)
raw, err := m.XmlWriterRaw(xmlWriter) // 'raw' is the raw XML that was written on xmlWriter
Also, for prettified output:
xmlValue, err := m.XmlIndent(prefix, indent, ...)
err := m.XmlIndentWriter(xmlWriter, prefix, indent, ...)
raw, err := m.XmlIndentWriterRaw(xmlWriter, prefix, indent, ...)
Bulk process XML with error handling (note: handlers must return a boolean value):
err := HandleXmlReader(xmlReader, mapHandler(Map), errHandler(error))
err := HandleXmlReaderRaw(xmlReader, mapHandler(Map, []byte), errHandler(error, []byte))
Converting XML to JSON: see Examples for NewMapXml and HandleXmlReader.
There are comparable functions and methods for JSON processing.
Arbitrary structure values can be decoded to / encoded from Map values:
m, err := NewMapStruct(structVal)
err := m.Struct(structPointer)
To work with XML tag values, JSON or Map key values or structure field values, decode the XML, JSON
or structure to a Map value, 'm', or cast a map[string]interface{} value to a Map value, 'm', then:
paths := m.PathsForKey(key)
path := m.PathForKeyShortest(key)
values, err := m.ValuesForKey(key, subkeys)
values, err := m.ValuesForPath(path, subkeys) // 'path' can be dot-notation with wildcards and indexed arrays.
count, err := m.UpdateValuesForPath(newVal, path, subkeys)
Get everything at once, irrespective of path depth:
leafnodes := m.LeafNodes()
leafvalues := m.LeafValues()
A new Map with whatever keys are desired can be created from the current Map and then encoded in XML
or JSON. (Note: keys can use dot-notation. 'oldKey' can also use wildcards and indexed arrays.)
newMap := m.NewMap("oldKey_1:newKey_1", "oldKey_2:newKey_2", ..., "oldKey_N:newKey_N")
newXml := newMap.Xml() // for example
newJson := newMap.Json() // ditto
XML PARSING CONVENTIONS
- Attributes are parsed to map[string]interface{} values by prefixing a hyphen, '-',
to the attribute label. (PrependAttrWithHyphen(false) will override this.)
- If the element is a simple element and has attributes, the element value
is given the key '#text' for its map[string]interface{} representation.
XML ENCODING CONVENTIONS
- 'nil' Map values, which may represent 'null' JSON values, are encoded as "<tag/>".
NOTE: the operation is not symmetric as "<tag/>" elements are decoded as 'tag:""' Map values,
which, then, encode in JSON as '"tag":""' values..
*/
package mxj

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@ -1,344 +0,0 @@
// note - "// Output:" is a key for "go test" to match function ouput with the lines that follow.
// It is also use by "godoc" to build the Output block of the function / method documentation.
// To skip processing Example* functions, use: go test -run "Test*"
// or make sure example function output matches // Output: documentation EXACTLY.
package mxj_test
import (
"bytes"
"fmt"
"github.com/clbanning/mxj"
"io"
)
func ExampleHandleXmlReader() {
/*
Bulk processing XML to JSON seems to be a common requirement.
See: bulk_test.go for working example.
Run "go test" in package directory then scroll back to find output.
The logic is as follows.
// need somewhere to write the JSON.
var jsonWriter io.Writer
// probably want to log any errors in reading the XML stream
var xmlErrLogger io.Writer
// func to handle Map value from XML Reader
func maphandler(m mxj.Map) bool {
// marshal Map as JSON
jsonVal, err := m.Json()
if err != nil {
// log error
return false // stops further processing of XML Reader
}
// write JSON somewhere
_, err = jsonWriter.Write(jsonVal)
if err != nil {
// log error
return false // stops further processing of XML Reader
}
// continue - get next XML from Reader
return true
}
// func to handle error from unmarshaling XML Reader
func errhandler(errVal error) bool {
// log error somewhere
_, err := xmlErrLogger.Write([]byte(errVal.Error()))
if err != nil {
// log error
return false // stops further processing of XML Reader
}
// continue processing
return true
}
// func that starts bulk processing of the XML
...
// set up io.Reader for XML data - perhaps an os.File
...
err := mxj.HandleXmlReader(xmlReader, maphandler, errhandler)
if err != nil {
// handle error
}
...
*/
}
func ExampleHandleXmlReaderRaw() {
/*
See: bulkraw_test.go for working example.
Run "go test" in package directory then scroll back to find output.
Basic logic for bulk XML to JSON processing is in HandleXmlReader example;
the only major difference is in handler function signatures so they are passed
the raw XML. (Read documentation on NewXmlReader regarding performance.)
*/
}
func ExampleHandleJsonReader() {
/*
See: bulk_test.go for working example.
Run "go test" in package directory then scroll back to find output.
Basic logic for bulk JSON to XML processing is similar to that for
bulk XML to JSON processing as outlined in the HandleXmlReader example.
The test case is also a good example.
*/
}
func ExampleHandleJsonReaderRaw() {
/*
See: bulkraw_test.go for working example.
Run "go test" in package directory then scroll back to find output.
Basic logic for bulk JSON to XML processing is similar to that for
bulk XML to JSON processing as outlined in the HandleXmlReader example.
The test case is also a good example.
*/
}
/*
func ExampleNewMapXmlReaderRaw() {
// in an http.Handler
mapVal, raw, err := mxj.NewMapXmlReader(req.Body)
if err != nil {
// handle error
}
logger.Print(string(*raw))
// do something with mapVal
}
*/
func ExampleNewMapStruct() {
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
private string
}
strVal := str{IntVal: 4, StrVal: "now's the time", FloatVal: 3.14159, BoolVal: true, private: "Skies are blue"}
mapVal, merr := mxj.NewMapStruct(strVal)
if merr != nil {
// handle error
}
fmt.Printf("strVal: %#v\n", strVal)
fmt.Printf("mapVal: %#v\n", mapVal)
// Note: example output is conformed to pass "go test". "mxj_test" is example_test.go package name.
// Output:
// strVal: mxj_test.str{IntVal:4, StrVal:"now's the time", FloatVal:3.14159, BoolVal:true, private:"Skies are blue"}
// mapVal: mxj.Map{"int":4, "str":"now's the time", "float":3.14159, "bool":true}
}
func ExampleMap_Struct() {
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
private string
}
mapVal := mxj.Map{"int": 4, "str": "now's the time", "float": 3.14159, "bool": true, "private": "Somewhere over the rainbow"}
var strVal str
mverr := mapVal.Struct(&strVal)
if mverr != nil {
// handle error
}
fmt.Printf("mapVal: %#v\n", mapVal)
fmt.Printf("strVal: %#v\n", strVal)
// Note: example output is conformed to pass "go test". "mxj_test" is example_test.go package name.
// Output:
// mapVal: mxj.Map{"int":4, "str":"now's the time", "float":3.14159, "bool":true, "private":"Somewhere over the rainbow"}
// strVal: mxj_test.str{IntVal:4, StrVal:"now's the time", FloatVal:3.14159, BoolVal:true, private:""}
}
func ExampleMap_ValuesForKeyPath() {
// a snippet from examples/gonuts1.go
// How to compensate for irregular tag labels in data.
// Need to extract from an XML stream the values for "netid" and "idnet".
// Solution: use a wildcard path "data.*" to anonymize the "netid" and "idnet" tags.
var msg1 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<netid>
<disable>no</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</netid>
</data>
`)
var msg2 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<idnet>
<disable>yes</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</idnet>
</data>
`)
// let's create a message stream
buf := new(bytes.Buffer)
// load a couple of messages into it
_, _ = buf.Write(msg1)
_, _ = buf.Write(msg2)
n := 0
for {
n++
// Read the stream as Map values - quit on io.EOF.
// Get the raw XML as well as the Map value.
m, merr := mxj.NewMapXmlReader(buf)
if merr != nil && merr != io.EOF {
// handle error - for demo we just print it and continue
fmt.Printf("msg: %d - merr: %s\n", n, merr.Error())
continue
} else if merr == io.EOF {
break
}
// get the values for "netid" or "idnet" key using path == "data.*"
values, _ := m.ValuesForPath("data.*")
fmt.Println("\nmsg:", n, "> path == data.* - got array of values, len:", len(values))
for i, val := range values {
fmt.Println("ValuesForPath result array member -", i, ":", val)
fmt.Println(" k:v pairs for array member:", i)
for key, val := range val.(map[string]interface{}) {
// You'd probably want to process the value, as appropriate.
// Here we just print it out.
fmt.Println("\t\t", key, ":", val)
}
}
}
// Output:
// msg: 1 > path == data.* - got array of values, len: 1
// ValuesForPath result array member - 0 : map[disable:no text1:default:text word1:default:word]
// k:v pairs for array member: 0
// disable : no
// text1 : default:text
// word1 : default:word
//
// msg: 2 > path == data.* - got array of values, len: 1
// ValuesForPath result array member - 0 : map[disable:yes text1:default:text word1:default:word]
// k:v pairs for array member: 0
// disable : yes
// text1 : default:text
// word1 : default:word
}
func ExampleMap_UpdateValuesForPath() {
/*
var biblioDoc = []byte(`
<biblio>
<author>
<name>William Gaddis</name>
<books>
<book>
<title>The Recognitions</title>
<date>1955</date>
<review>A novel that changed the face of American literature.</review>
</book>
<book>
<title>JR</title>
<date>1975</date>
<review>Winner of National Book Award for Fiction.</review>
</book>
</books>
</author>
</biblio>`)
...
m, merr := mxj.NewMapXml(biblioDoc)
if merr != nil {
// handle error
}
// change 'review' for a book
count, err := m.UpdateValuesForPath("review:National Book Award winner." "*.*.*.*", "title:JR")
if err != nil {
// handle error
}
...
// change 'date' value from string type to float64 type
// Note: the following is equivalent to m, merr := NewMapXml(biblioDoc, mxj.Cast).
path := m.PathForKeyShortest("date")
v, err := m.ValuesForPath(path)
if err != nil {
// handle error
}
var total int
for _, vv := range v {
oldVal := "date:" + vv.(string)
newVal := "date:" + vv.(string) + ":num"
n, err := m.UpdateValuesForPath(newVal, path, oldVal)
if err != nil {
// handle error
}
total += n
}
...
*/
}
func ExampleMap_Copy() {
// Hand-crafted Map values that include structures do NOT Copy() as expected,
// since to simulate a deep copy the original Map value is JSON encoded then decoded.
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
private string
}
s := str{IntVal: 4, StrVal: "now's the time", FloatVal: 3.14159, BoolVal: true, private: "Skies are blue"}
m := make(map[string]interface{}, 0)
m["struct"] = interface{}(s)
m["struct_ptr"] = interface{}(&s)
m["misc"] = interface{}(`Now is the time`)
mv := mxj.Map(m)
cp, _ := mv.Copy()
fmt.Printf("mv:%s\n", mv.StringIndent(2))
fmt.Printf("cp:%s\n", cp.StringIndent(2))
// Output:
// mv:
// struct :[unknown] mxj_test.str{IntVal:4, StrVal:"now's the time", FloatVal:3.14159, BoolVal:true, private:"Skies are blue"}
// struct_ptr :[unknown] &mxj_test.str{IntVal:4, StrVal:"now's the time", FloatVal:3.14159, BoolVal:true, private:"Skies are blue"}
// misc :[string] Now is the time
// cp:
// misc :[string] Now is the time
// struct :
// int :[float64] 4.00e+00
// str :[string] now's the time
// float :[float64] 3.14e+00
// bool :[bool] true
// struct_ptr :
// int :[float64] 4.00e+00
// str :[string] now's the time
// float :[float64] 3.14e+00
// bool :[bool] true
}

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@ -1,124 +0,0 @@
Examples of using ValuesFromTagPath().
A number of interesting examples have shown up in the gonuts discussion group
that could be handled - after a fashion - using the ValuesFromTagPath() function.
gonuts1.go -
Here we see that the message stream has a problem with multiple tag spellings,
though the message structure remains constant. In this example we 'anonymize'
the tag for the variant spellings.
values := m.ValuesForPath("data.*)
where '*' is any possible spelling - "netid" or "idnet"
and the result is a list with 1 member of map[string]interface{} type.
Once we've retrieved the Map, we can parse it using the known keys - "disable",
"text1" and "word1".
gonuts1a.go - (03-mar-14)
Here we just permute the tag labels using m.NewMap() to make all the messages
consistent. Then they can be decoded into a single structure definition.
gonuts2.go -
This is an interesting case where there was a need to handle messages with lists
of "ClaimStatusCodeRecord" entries as well as messages with NONE. (Here we see
some of the vagaries of dealing with mixed messages that are verging on becoming
anonymous.)
msg1 - the message with two ClaimStatusCodeRecord entries
msg2 - the message with one ClaimStatusCodeRecord entry
msg3 - the message with NO ClaimStatusCodeRecord entries
ValuesForPath options:
path == "Envelope.Body.GetClaimStatusCodesResponse.GetClaimStatusCodesResult.ClaimStatusCodeRecord"
for msg == msg1:
returns: a list - []interface{} - with two values of map[string]interface{} type
for msg == msg2:
returns: a list - []interface{} - with one map[string]interface{} type
for msg == msg3:
returns 'nil' - no values
path == "*.*.*.*.*"
for msg == msg1:
returns: a list - []interface{} - with two values of map[string]interface{} type
path == "*.*.*.*.*.Description
for msg == msg1:
returns: a list - []interface{} - with two values of string type, the individual
values from parsing the two map[string]interface{} values where key=="Description"
path == "*.*.*.*.*.*"
for msg == msg1:
returns: a list - []interface{} - with six values of string type, the individual
values from parsing all keys in the two map[string]interface{} values
Think of the wildcard character "*" as anonymizing the tag in the position of the path where
it occurs. The books.go example has a range of use cases.
gonuts3.go -
Uses the ValuesForKey method to extract a list of image "src" file names that are encoded as
attribute values.
gonuts4.go -
Here we use the ValuesForPath to extract attribute values for country names. The attribute
is included in the 'path' argument by prepending it with a hyphen: ""doc.some_tag.geoInfo.country.-name".
gonuts5.go (10-mar-14) -
Extract a node of values using ValuesForPath based on name="list3-1-1-1". Then get the values
for the 'int' entries based on attribute 'name' values - mv.ValuesForKey("int", "-name:"+n).
gonuts5a.go (10-mar-14) -
Extract a node of values using ValuesForPath based on name="list3-1-1-1". Then get the values
for the 'int' entries based on attribute 'name' values - mv.ValuesForKey("*", "-name:"+n).
(Same as gonuts5.go but with wildcarded key value, since we're matching elements on subkey.)
EAT YOUR OWN DOG FOOD ...
I needed to convert a large (14.9 MB) XML data set from an Eclipse metrics report on an
application that had 355,100 lines of code in 211 packages into CSV data sets. The report
included application-, package-, class- and method-level metrics reported in an element,
"Value", with varying attributes.
<Value value=""/>
<Value name="" package="" value=""/>
<Value name="" source="" package="" value=""/>
<Value name="" source="" package="" value="" inrange=""/>
In addition, the metrics were reported with two different "Metric" compound elements:
<Metrics>
<Metric id="" description="">
<Values>
<Value.../>
...
</Values>
</Metric>
...
<Metric id="" description="">
<Value.../>
</Metric>
...
</Metrics>
Using the mxj package seemed a more straightforward approach than using Go vernacular
and the standard xml package. I wrote the program getmetrics.go to do this. Here are
three version to illustrate using
getmetrics1.go - pass os.File handle for metrics_data.xml to NewMapXmlReader.
getmetrics2.go - load metrics_data.xml into an in-memory buffer, then pass it to NewMapXml.
getmetrics3.go - demonstrates overhead of extracting the raw XML while decoding with NewMapXmlReaderRaw.
To run example getmetrics1.go, extract a 120,000+ row data set from metrics_data.zip. Then:
go run getmetrics1.go -file=metrics_data.xml

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@ -1,71 +0,0 @@
// Note: this illustrates ValuesForKey() and ValuesForPath() methods
package main
import (
"fmt"
"github.com/clbanning/mxj"
"log"
)
var xmldata = []byte(`
<books>
<book seq="1">
<author>William H. Gaddis</author>
<title>The Recognitions</title>
<review>One of the great seminal American novels of the 20th century.</review>
</book>
<book seq="2">
<author>Austin Tappan Wright</author>
<title>Islandia</title>
<review>An example of earlier 20th century American utopian fiction.</review>
</book>
<book seq="3">
<author>John Hawkes</author>
<title>The Beetle Leg</title>
<review>A lyrical novel about the construction of Ft. Peck Dam in Montana.</review>
</book>
<book seq="4">
<author>T.E. Porter</author>
<title>King's Day</title>
<review>A magical novella.</review>
</book>
</books>
`)
func main() {
fmt.Println(string(xmldata))
m, err := mxj.NewMapXml(xmldata)
if err != nil {
log.Fatal("err:", err.Error())
}
v, _ := m.ValuesForKey("books")
fmt.Println("path: books; len(v):", len(v))
fmt.Printf("\t%+v\n", v)
v, _ = m.ValuesForPath("books.book")
fmt.Println("path: books.book; len(v):", len(v))
for _, vv := range v {
fmt.Printf("\t%+v\n", vv)
}
v, _ = m.ValuesForPath("books.*")
fmt.Println("path: books.*; len(v):", len(v))
for _, vv := range v {
fmt.Printf("\t%+v\n", vv)
}
v, _ = m.ValuesForPath("books.*.title")
fmt.Println("path: books.*.title len(v):", len(v))
for _, vv := range v {
fmt.Printf("\t%+v\n", vv)
}
v, _ = m.ValuesForPath("books.*.*")
fmt.Println("path: books.*.*; len(v):", len(v))
for _, vv := range v {
fmt.Printf("\t%+v\n", vv)
}
}

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@ -1,176 +0,0 @@
// getmetrics1.go - transform Eclipse Metrics (v3) XML report into CSV files for each metric
// Uses NewMapXmlReader on os.File without copying the raw XML into a buffer while decoding..
// Shows no significant overhead for not first buffering large XML file as in getmetrics2.go.
/*
I needed to convert a large (14.9 MB) XML data set from an Eclipse metrics report on an
application that had 355,100 lines of code in 211 packages into CSV data sets. The report
included application-, package-, class- and method-level metrics reported in an element,
"Value", with varying attributes.
<Value value=""/>
<Value name="" package="" value=""/>
<Value name="" source="" package="" value=""/>
<Value name="" source="" package="" value="" inrange=""/>
In addition, the metrics were reported with two different "Metric" compound elements:
<Metrics>
<Metric id="" description="">
<Values>
<Value.../>
...
</Values>
</Metric>
...
<Metric id="" description="">
<Value.../>
</Metric>
...
</Metrics>
To run this example, extract the metrics_data.xml file from metrics_data.zip, then:
> go run getmetrics1 -file=metrics_data.xml
The output will be a set of "csv" files.
*/
package main
import (
"flag"
"fmt"
"github.com/clbanning/mxj"
"log"
"os"
"time"
)
func main() {
var file string
flag.StringVar(&file, "file", "", "file to process")
flag.Parse()
fh, fherr := os.Open(file)
if fherr != nil {
fmt.Println("fherr:", fherr.Error())
return
}
defer fh.Close()
fmt.Println(time.Now().String(), "... File Opened:", file)
/*
// Get the XML data set from the file.
fs, _ := fh.Stat()
xmldata := make([]byte, fs.Size())
n, frerr := fh.Read(xmldata)
if frerr != nil {
fmt.Println("frerr:", frerr.Error())
return
}
if int64(n) != fs.Size() {
fmt.Println("n:", n, "fs.Size():", fs.Size())
return
}
fmt.Println(time.Now().String(), "... File Read - size:", fs.Size())
// load XML into a Map value
m, merr := mxj.NewMapXml(xmldata)
*/
// Consume the file using os.File Reader.
// Note: there is a single record with root tag of "Metrics".
m, merr := mxj.NewMapXmlReader(fh)
if merr != nil {
log.Fatal("merr:", merr.Error())
}
fmt.Println(time.Now().String(), "... XML Unmarshaled - len:", len(m))
// Get just the key values of interest.
// Could also use m.ValuesForKey("Metric"),
// since there's just the one path.
metricVals, err := m.ValuesForPath("Metrics.Metric")
if err != nil {
log.Fatal("err:", err.Error())
}
fmt.Println(time.Now().String(), "... ValuesFromKeyPath - len:", len(metricVals))
// now just manipulate Map entries returned as []interface{} array.
for _, v := range metricVals {
aMetricVal := v.(map[string]interface{})
// create file to hold csv data sets
id := aMetricVal["-id"].(string)
desc := aMetricVal["-description"].(string)
mf, mferr := os.OpenFile(id+".csv", os.O_WRONLY|os.O_TRUNC|os.O_CREATE, 0666)
if mferr != nil {
fmt.Println("mferr:", mferr.Error())
return
}
fmt.Print(time.Now().String(), " id: ", id, " desc: ", desc)
mf.WriteString(id + "," + desc + "\n")
// rescan looking for keys with data: Values or Value
for key, val := range aMetricVal {
switch key {
case "Values":
// extract the list of "Value" from map
values := val.(map[string]interface{})["Value"].([]interface{})
fmt.Println(" len(Values):", len(values))
// first line in file is the metric label values (keys)
var gotKeys bool
for _, vval := range values {
valueEntry := vval.(map[string]interface{})
// no guarantee that range on map will follow any sequence
lv := len(valueEntry)
type ev [2]string
list := make([]ev, lv)
var i int
for k, v := range valueEntry {
list[i][0] = k
list[i][1] = v.(string)
i++
}
// extract keys as column header on first pass
if !gotKeys {
// print out the keys
var gotFirstKey bool
// for kk, _ := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstKey {
mf.WriteString(",")
} else {
gotFirstKey = true
}
// strip prepended hyphen
mf.WriteString((list[i][0])[1:])
}
mf.WriteString("\n")
gotKeys = true
}
// print out values
var gotFirstVal bool
// for _, vv := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstVal {
mf.WriteString(",")
} else {
gotFirstVal = true
}
mf.WriteString(list[i][1])
}
// terminate row of data
mf.WriteString("\n")
}
case "Value":
vv := val.(map[string]interface{})
fmt.Println(" len(Value):", len(vv))
mf.WriteString("value\n" + vv["-value"].(string) + "\n")
}
}
mf.Close()
}
}

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@ -1,173 +0,0 @@
// getmetrics2.go - transform Eclipse Metrics (v3) XML report into CSV files for each metric
// Uses an in-memory buffer for the XML data and direct XML decoding of the buffer into a Map.
// Not significantly faster than getmetrics1.go that uses an io.Reader (os.File) to directly
// decode the XML from the file.
/*
I needed to convert a large (14.9 MB) XML data set from an Eclipse metrics report on an
application that had 355,100 lines of code in 211 packages into CSV data sets. The report
included application-, package-, class- and method-level metrics reported in an element,
"Value", with varying attributes.
<Value value=""/>
<Value name="" package="" value=""/>
<Value name="" source="" package="" value=""/>
<Value name="" source="" package="" value="" inrange=""/>
In addition, the metrics were reported with two different "Metric" compound elements:
<Metrics>
<Metric id="" description="">
<Values>
<Value.../>
...
</Values>
</Metric>
...
<Metric id="" description="">
<Value.../>
</Metric>
...
</Metrics>
To run this example, extract the metrics_data.xml file from metrics_data.zip, then:
> go run getmetrics -file=metrics_data.xml
The output will be a set of "csv" files.
*/
package main
import (
"flag"
"fmt"
"github.com/clbanning/mxj"
"log"
"os"
"time"
)
func main() {
var file string
flag.StringVar(&file, "file", "", "file to process")
flag.Parse()
fh, fherr := os.Open(file)
if fherr != nil {
fmt.Println("fherr:", fherr.Error())
return
}
defer fh.Close()
fmt.Println(time.Now().String(), "... File Opened:", file)
// Get the XML data set from the file.
fs, _ := fh.Stat()
xmldata := make([]byte, fs.Size())
n, frerr := fh.Read(xmldata)
if frerr != nil {
fmt.Println("frerr:", frerr.Error())
return
}
if int64(n) != fs.Size() {
fmt.Println("n:", n, "fs.Size():", fs.Size())
return
}
fmt.Println(time.Now().String(), "... File Read - size:", fs.Size())
// load XML into a Map value
// Note: there is a single record with root tag of "Metrics".
m, merr := mxj.NewMapXml(xmldata)
if merr != nil {
log.Fatal("merr:", merr.Error())
}
fmt.Println(time.Now().String(), "... XML Unmarshaled - len:", len(m))
// Get just the key values of interest.
// Could also use m.ValuesForKey("Metric"),
// since there's just the one path.
metricVals, err := m.ValuesForPath("Metrics.Metric")
if err != nil {
log.Fatal("err:", err.Error())
}
fmt.Println(time.Now().String(), "... ValuesFromKeyPath - len:", len(metricVals))
// now just manipulate Map entries returned as []interface{} array.
for _, v := range metricVals {
aMetricVal := v.(map[string]interface{})
// create file to hold csv data sets
id := aMetricVal["-id"].(string)
desc := aMetricVal["-description"].(string)
mf, mferr := os.OpenFile(id+".csv", os.O_WRONLY|os.O_TRUNC|os.O_CREATE, 0666)
if mferr != nil {
fmt.Println("mferr:", mferr.Error())
return
}
fmt.Print(time.Now().String(), " id: ", id, " desc: ", desc)
mf.WriteString(id + "," + desc + "\n")
// rescan looking for keys with data: Values or Value
for key, val := range aMetricVal {
switch key {
case "Values":
// extract the list of "Value" from map
values := val.(map[string]interface{})["Value"].([]interface{})
fmt.Println(" len(Values):", len(values))
// first line in file is the metric label values (keys)
var gotKeys bool
for _, vval := range values {
valueEntry := vval.(map[string]interface{})
// no guarantee that range on map will follow any sequence
lv := len(valueEntry)
type ev [2]string
list := make([]ev, lv)
var i int
for k, v := range valueEntry {
list[i][0] = k
list[i][1] = v.(string)
i++
}
// extract keys as column header on first pass
if !gotKeys {
// print out the keys
var gotFirstKey bool
// for kk, _ := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstKey {
mf.WriteString(",")
} else {
gotFirstKey = true
}
// strip prepended hyphen
mf.WriteString((list[i][0])[1:])
}
mf.WriteString("\n")
gotKeys = true
}
// print out values
var gotFirstVal bool
// for _, vv := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstVal {
mf.WriteString(",")
} else {
gotFirstVal = true
}
mf.WriteString(list[i][1])
}
// terminate row of data
mf.WriteString("\n")
}
case "Value":
vv := val.(map[string]interface{})
fmt.Println(" len(Value):", len(vv))
mf.WriteString("value\n" + vv["-value"].(string) + "\n")
}
}
mf.Close()
}
}

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@ -1,180 +0,0 @@
// getmetrics3.go - transform Eclipse Metrics (v3) XML report into CSV files for each metric
// Uses NewMapXmlReaderRaw that requires loading raw XML into a []byte buffer using a ByteReader.
// Show's performance impact of copying the raw XML while simultaneously decoding it from on os.File
// Reader. (vs. getmetrics1.go) If you're processing a file and need a copy of the raw XML and SPEED,
// should buffer the file in memory and decode using mxj.NewMapXmlReaderRaw as in getmetrics4.go.
/*
I needed to convert a large (14.9 MB) XML data set from an Eclipse metrics report on an
application that had 355,100 lines of code in 211 packages into CSV data sets. The report
included application-, package-, class- and method-level metrics reported in an element,
"Value", with varying attributes.
<Value value=""/>
<Value name="" package="" value=""/>
<Value name="" source="" package="" value=""/>
<Value name="" source="" package="" value="" inrange=""/>
In addition, the metrics were reported with two different "Metric" compound elements:
<Metrics>
<Metric id="" description="">
<Values>
<Value.../>
...
</Values>
</Metric>
...
<Metric id="" description="">
<Value.../>
</Metric>
...
</Metrics>
To run this example, extract the metrics_data.xml file from metrics_data.zip, then:
> go run getmetrics3 -file=metrics_data.xml
The output will be a set of "csv" files.
*/
package main
import (
"flag"
"fmt"
"github.com/clbanning/mxj"
"log"
"os"
"time"
)
func main() {
var file string
flag.StringVar(&file, "file", "", "file to process")
flag.Parse()
fh, fherr := os.Open(file)
if fherr != nil {
fmt.Println("fherr:", fherr.Error())
return
}
defer fh.Close()
fmt.Println(time.Now().String(), "... File Opened:", file)
/*
// Get the XML data set from the file.
fs, _ := fh.Stat()
xmldata := make([]byte, fs.Size())
n, frerr := fh.Read(xmldata)
if frerr != nil {
fmt.Println("frerr:", frerr.Error())
return
}
if int64(n) != fs.Size() {
fmt.Println("n:", n, "fs.Size():", fs.Size())
return
}
fmt.Println(time.Now().String(), "... File Read - size:", fs.Size())
// load XML into a Map value
m, merr := mxj.NewMapXml(xmldata)
*/
// Consume the file using os.File Reader.
// Note: there is a single record with root tag of "Metrics".
// Also: this is MUCH slower than using buffer or not loading raw XML.
m, raw, merr := mxj.NewMapXmlReaderRaw(fh)
if merr != nil {
log.Fatal("merr:", merr.Error())
}
fmt.Println(time.Now().String(), "... XML Unmarshaled - len:", len(m))
fmt.Println("raw XML buffer size (should be same as File size):", len(*raw))
// Get just the key values of interest.
// Could also use m.ValuesForKey("Metric"),
// since there's just the one path.
metricVals, err := m.ValuesForPath("Metrics.Metric")
if err != nil {
log.Fatal("err:", err.Error())
}
fmt.Println(time.Now().String(), "... ValuesFromKeyPath - len:", len(metricVals))
// now just manipulate Map entries returned as []interface{} array.
for _, v := range metricVals {
aMetricVal := v.(map[string]interface{})
// create file to hold csv data sets
id := aMetricVal["-id"].(string)
desc := aMetricVal["-description"].(string)
mf, mferr := os.OpenFile(id+".csv", os.O_WRONLY|os.O_TRUNC|os.O_CREATE, 0666)
if mferr != nil {
fmt.Println("mferr:", mferr.Error())
return
}
fmt.Print(time.Now().String(), " id: ", id, " desc: ", desc)
mf.WriteString(id + "," + desc + "\n")
// rescan looking for keys with data: Values or Value
for key, val := range aMetricVal {
switch key {
case "Values":
// extract the list of "Value" from map
values := val.(map[string]interface{})["Value"].([]interface{})
fmt.Println(" len(Values):", len(values))
// first line in file is the metric label values (keys)
var gotKeys bool
for _, vval := range values {
valueEntry := vval.(map[string]interface{})
// no guarantee that range on map will follow any sequence
lv := len(valueEntry)
type ev [2]string
list := make([]ev, lv)
var i int
for k, v := range valueEntry {
list[i][0] = k
list[i][1] = v.(string)
i++
}
// extract keys as column header on first pass
if !gotKeys {
// print out the keys
var gotFirstKey bool
// for kk, _ := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstKey {
mf.WriteString(",")
} else {
gotFirstKey = true
}
// strip prepended hyphen
mf.WriteString((list[i][0])[1:])
}
mf.WriteString("\n")
gotKeys = true
}
// print out values
var gotFirstVal bool
// for _, vv := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstVal {
mf.WriteString(",")
} else {
gotFirstVal = true
}
mf.WriteString(list[i][1])
}
// terminate row of data
mf.WriteString("\n")
}
case "Value":
vv := val.(map[string]interface{})
fmt.Println(" len(Value):", len(vv))
mf.WriteString("value\n" + vv["-value"].(string) + "\n")
}
}
mf.Close()
}
}

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@ -1,179 +0,0 @@
// getmetrics2.go - transform Eclipse Metrics (v3) XML report into CSV files for each metric
// Uses an in-memory buffer for the XML data and direct XML decoding of the buffer into a Map.
// Then XML buffer is decoded into a Map while the raw XML is copied using NewMapXmlReaderRaw()
// to illustrate processing overhead relative to getmetrics2.go. Not a practical example,
// but confirms the getmetrics1.go vs. getmetrics3.go use case.
/*
I needed to convert a large (14.9 MB) XML data set from an Eclipse metrics report on an
application that had 355,100 lines of code in 211 packages into CSV data sets. The report
included application-, package-, class- and method-level metrics reported in an element,
"Value", with varying attributes.
<Value value=""/>
<Value name="" package="" value=""/>
<Value name="" source="" package="" value=""/>
<Value name="" source="" package="" value="" inrange=""/>
In addition, the metrics were reported with two different "Metric" compound elements:
<Metrics>
<Metric id="" description="">
<Values>
<Value.../>
...
</Values>
</Metric>
...
<Metric id="" description="">
<Value.../>
</Metric>
...
</Metrics>
To run this example, extract the metrics_data.xml file from metrics_data.zip, then:
> go run getmetrics -file=metrics_data.xml
The output will be a set of "csv" files.
*/
package main
import (
"bytes"
"flag"
"fmt"
"github.com/clbanning/mxj"
"log"
"os"
"time"
)
func main() {
var file string
flag.StringVar(&file, "file", "", "file to process")
flag.Parse()
fh, fherr := os.Open(file)
if fherr != nil {
fmt.Println("fherr:", fherr.Error())
return
}
defer fh.Close()
fmt.Println(time.Now().String(), "... File Opened:", file)
// Get the XML data set from the file.
fs, _ := fh.Stat()
xmldata := make([]byte, fs.Size())
n, frerr := fh.Read(xmldata)
if frerr != nil {
fmt.Println("frerr:", frerr.Error())
return
}
if int64(n) != fs.Size() {
fmt.Println("n:", n, "fs.Size():", fs.Size())
return
}
fmt.Println(time.Now().String(), "... File Read - size:", fs.Size())
// wrap the buffer in an io.Reader
xmlReader := bytes.NewBuffer(xmldata)
// load XML into a Map value
// Note: there is a single record with root tag of "Metrics".
m, raw, merr := mxj.NewMapXmlReaderRaw(xmlReader) // don't catch the pointer to raw XML
if merr != nil {
log.Fatal("merr:", merr.Error())
}
fmt.Println(time.Now().String(), "... XML Unmarshaled - len:", len(m))
fmt.Println("raw XML buffer size (should be same as File size):", len(*raw))
// Get just the key values of interest.
// Could also use m.ValuesForKey("Metric"),
// since there's just the one path.
metricVals, err := m.ValuesForPath("Metrics.Metric")
if err != nil {
log.Fatal("err:", err.Error())
}
fmt.Println(time.Now().String(), "... ValuesFromKeyPath - len:", len(metricVals))
// now just manipulate Map entries returned as []interface{} array.
for _, v := range metricVals {
aMetricVal := v.(map[string]interface{})
// create file to hold csv data sets
id := aMetricVal["-id"].(string)
desc := aMetricVal["-description"].(string)
mf, mferr := os.OpenFile(id+".csv", os.O_WRONLY|os.O_TRUNC|os.O_CREATE, 0666)
if mferr != nil {
fmt.Println("mferr:", mferr.Error())
return
}
fmt.Print(time.Now().String(), " id: ", id, " desc: ", desc)
mf.WriteString(id + "," + desc + "\n")
// rescan looking for keys with data: Values or Value
for key, val := range aMetricVal {
switch key {
case "Values":
// extract the list of "Value" from map
values := val.(map[string]interface{})["Value"].([]interface{})
fmt.Println(" len(Values):", len(values))
// first line in file is the metric label values (keys)
var gotKeys bool
for _, vval := range values {
valueEntry := vval.(map[string]interface{})
// no guarantee that range on map will follow any sequence
lv := len(valueEntry)
type ev [2]string
list := make([]ev, lv)
var i int
for k, v := range valueEntry {
list[i][0] = k
list[i][1] = v.(string)
i++
}
// extract keys as column header on first pass
if !gotKeys {
// print out the keys
var gotFirstKey bool
// for kk, _ := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstKey {
mf.WriteString(",")
} else {
gotFirstKey = true
}
// strip prepended hyphen
mf.WriteString((list[i][0])[1:])
}
mf.WriteString("\n")
gotKeys = true
}
// print out values
var gotFirstVal bool
// for _, vv := range valueEntry {
for i := 0; i < lv; i++ {
if gotFirstVal {
mf.WriteString(",")
} else {
gotFirstVal = true
}
mf.WriteString(list[i][1])
}
// terminate row of data
mf.WriteString("\n")
}
case "Value":
vv := val.(map[string]interface{})
fmt.Println(" len(Value):", len(vv))
mf.WriteString("value\n" + vv["-value"].(string) + "\n")
}
}
mf.Close()
}
}

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@ -1,82 +0,0 @@
// https://groups.google.com/forum/#!searchin/golang-nuts/idnet$20netid/golang-nuts/guM3ZHHqSF0/K1pBpMqQSSwJ
// http://play.golang.org/p/BFFDxphKYK
package main
import (
"bytes"
"fmt"
"github.com/clbanning/mxj"
"io"
)
// Demo how to compensate for irregular tag labels in data.
// Need to extract from an XML stream the values for "netid" and "idnet".
// Solution: use a wildcard path "data.*" to anonymize the "netid" and "idnet" tags.
var msg1 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<netid>
<disable>no</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</netid>
</data>
`)
var msg2 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<idnet>
<disable>yes</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</idnet>
</data>
`)
func main() {
// let's create a message stream
buf := new(bytes.Buffer)
// load a couple of messages into it
_, _ = buf.Write(msg1)
_, _ = buf.Write(msg2)
n := 0
for {
n++
// read the stream as Map values - quit on io.EOF
m, raw, merr := mxj.NewMapXmlReaderRaw(buf)
if merr != nil && merr != io.EOF {
// handle error - for demo we just print it and continue
fmt.Printf("msg: %d - merr: %s\n", n, merr.Error())
continue
} else if merr == io.EOF {
break
}
fmt.Println("\nMessage to parse:", string(*raw))
fmt.Println("Map value for XML message:", m.StringIndent())
// get the values for "netid" or "idnet" key using path == "data.*"
values, _ := m.ValuesForPath("data.*")
fmt.Println("\nmsg:", n, "> path == data.* - got array of values, len:", len(values))
for i, val := range values {
fmt.Println("ValuesForPath result array member -", i, ":", val)
fmt.Println(" k:v pairs for array member:", i)
for key, val := range val.(map[string]interface{}) {
// You'd probably want to process the value, as appropriate.
// Here we just print it out.
fmt.Println("\t\t", key, ":", val)
}
}
// This shows what happens if you wildcard the value keys for "idnet" and "netid"
values, _ = m.ValuesForPath("data.*.*")
fmt.Println("\npath == data.*.* - got an array of values, len(v):", len(values))
fmt.Println("(Note: values returned by ValuesForPath are at maximum depth of the tree. So just have values.)")
for i, val := range values {
fmt.Println("ValuesForPath array member -", i, ":", val)
}
}
}

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@ -1,68 +0,0 @@
// https://groups.google.com/forum/#!searchin/golang-nuts/idnet$20netid/golang-nuts/guM3ZHHqSF0/K1pBpMqQSSwJ
// http://play.golang.org/p/BFFDxphKYK
package main
import (
"bytes"
"fmt"
"github.com/clbanning/mxj"
"io"
)
// Demo how to re-label a key using mv.NewMap().
// Need to normalize from an XML stream the tags "netid" and "idnet".
// Solution: make everything "netid".
var msg1 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<netid>
<disable>no</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</netid>
</data>
`)
var msg2 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<idnet>
<disable>yes</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</idnet>
</data>
`)
func main() {
// let's create a message stream
buf := new(bytes.Buffer)
// load a couple of messages into it
_, _ = buf.Write(msg1)
_, _ = buf.Write(msg2)
n := 0
for {
n++
// read the stream as Map values - quit on io.EOF
m, raw, merr := mxj.NewMapXmlReaderRaw(buf)
if merr != nil && merr != io.EOF {
// handle error - for demo we just print it and continue
fmt.Printf("msg: %d - merr: %s\n", n, merr.Error())
continue
} else if merr == io.EOF {
break
}
// the first keypair retains values if data correct
// the second keypair relabels "idnet" to "netid"
n, _ := m.NewMap("data.netid", "data.idnet:data.netid")
x, _ := n.XmlIndent("", " ")
fmt.Println("original value:", string(raw))
fmt.Println("new value:")
fmt.Println(string(x))
}
}

View File

@ -1,240 +0,0 @@
// https://groups.google.com/forum/#!topic/golang-nuts/V83jUKluLnM
// http://play.golang.org/p/alWGk4MDBc
// Here messsages come in one of three forms:
// <GetClaimStatusCodesResult>... list of ClaimStatusCodeRecord ...</GetClaimStatusCodeResult>
// <GetClaimStatusCodesResult>... one instance of ClaimStatusCodeRecord ...</GetClaimStatusCodeResult>
// <GetClaimStatusCodesResult>... empty element ...</GetClaimStatusCodeResult>
// ValueForPath
package main
import (
"fmt"
"github.com/clbanning/mxj"
)
var xmlmsg1 = []byte(`<s:Envelope xmlns:s="http://schemas.xmlsoap.org/soap/envelope/">
<s:Body>
<GetClaimStatusCodesResponse xmlns="http://tempuri.org/">
<GetClaimStatusCodesResult xmlns:a="http://schemas.datacontract.org/2004/07/MRA.Claim.WebService.Domain" xmlns:i="http://www.w3.org/2001/XMLSchema-instance">
<a:ClaimStatusCodeRecord>
<a:Active>true</a:Active>
<a:Code>A</a:Code>
<a:Description>Initial Claim Review/Screening</a:Description>
</a:ClaimStatusCodeRecord>
<a:ClaimStatusCodeRecord>
<a:Active>true</a:Active>
<a:Code>B</a:Code>
<a:Description>Initial Contact Made w/ Provider</a:Description>
</a:ClaimStatusCodeRecord>
</GetClaimStatusCodesResult>
</GetClaimStatusCodesResponse>
</s:Body>
</s:Envelope>
`)
var xmlmsg2 = []byte(`<s:Envelope xmlns:s="http://schemas.xmlsoap.org/soap/envelope/">
<s:Body>
<GetClaimStatusCodesResponse xmlns="http://tempuri.org/">
<GetClaimStatusCodesResult xmlns:a="http://schemas.datacontract.org/2004/07/MRA.Claim.WebService.Domain" xmlns:i="http://www.w3.org/2001/XMLSchema-instance">
<a:ClaimStatusCodeRecord>
<a:Active>true</a:Active>
<a:Code>A</a:Code>
<a:Description>Initial Claim Review/Screening</a:Description>
</a:ClaimStatusCodeRecord>
</GetClaimStatusCodesResult>
</GetClaimStatusCodesResponse>
</s:Body>
</s:Envelope>
`)
var xmlmsg3 = []byte(`<s:Envelope xmlns:s="http://schemas.xmlsoap.org/soap/envelope/">
<s:Body>
<GetClaimStatusCodesResponse xmlns="http://tempuri.org/">
<GetClaimStatusCodesResult xmlns:a="http://schemas.datacontract.org/2004/07/MRA.Claim.WebService.Domain" xmlns:i="http://www.w3.org/2001/XMLSchema-instance">
</GetClaimStatusCodesResult>
</GetClaimStatusCodesResponse>
</s:Body>
</s:Envelope>
`)
func main() {
xmldata := [][]byte{xmlmsg1, xmlmsg2, xmlmsg3}
fullPath(xmldata)
partPath1(xmlmsg1)
partPath2(xmlmsg1)
partPath3(xmlmsg1)
partPath4(xmlmsg1)
partPath5(xmlmsg1)
partPath6(xmlmsg1)
}
func fullPath(xmldata [][]byte) {
for i, msg := range xmldata {
fmt.Println("\ndoc:", i)
fmt.Println(string(msg))
// decode the XML
m, _ := mxj.NewMapXml(msg)
// get the value for the key path of interest
path := "Envelope.Body.GetClaimStatusCodesResponse.GetClaimStatusCodesResult.ClaimStatusCodeRecord"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
continue
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
fmt.Println("values:", values, "\n")
for _, v := range values {
switch v.(type) {
case map[string]interface{}:
fmt.Println("map[string]interface{}:", v.(map[string]interface{}))
case []map[string]interface{}:
fmt.Println("[]map[string]interface{}:", v.([]map[string]interface{}))
case []interface{}:
fmt.Println("[]interface{}:", v.([]interface{}))
case interface{}:
fmt.Println("interface{}:", v.(interface{}))
}
}
}
}
func partPath1(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "Envelope.Body.*.*.ClaimStatusCodeRecord"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}
func partPath2(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "Envelope.Body.*.*.*"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}
func partPath3(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "*.*.*.*.*"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}
func partPath4(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "*.*.*.*.*.Description"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}
func partPath5(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "*.*.*.*.*.*"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}
func partPath6(msg []byte) {
fmt.Println("\nmsg:", string(msg))
m, _ := mxj.NewMapXml(msg)
fmt.Println("m:", m.StringIndent())
path := "*.*.*.*.*.*.*"
values, err := m.ValueForPath(path)
if err != nil {
fmt.Println("err:", err.Error())
return
}
if values == nil {
fmt.Println("path:", path)
fmt.Println("No ClaimStatusCodesResult code records.")
return
}
fmt.Println("\nPath:", path)
fmt.Println("Number of code records:", len(values))
for n, v := range values {
fmt.Printf("\t#%d: %v\n", n, v)
}
}

View File

@ -1,47 +0,0 @@
// https://groups.google.com/forum/#!topic/golang-nuts/cok6xasvI3w
// retrieve 'src' values from 'image' tags
package main
import (
"fmt"
"github.com/clbanning/mxj"
)
var xmldata = []byte(`
<doc>
<image src="something.png"></image>
<something>
<image src="something else.jpg"></image>
<title>something else</title>
</something>
<more_stuff>
<some_images>
<image src="first.gif"></image>
<image src="second.gif"></image>
</some_images>
</more_stuff>
</doc>`)
func main() {
fmt.Println("xmldata:", string(xmldata))
// get all image tag values - []interface{}
m, merr := mxj.NewMapXml(xmldata)
if merr != nil {
fmt.Println("merr:", merr.Error())
return
}
// grab all values for attribute "src"
// Note: attributes are prepended with a hyphen, '-'.
sources, err := m.ValuesForKey("-src")
if err != nil {
fmt.Println("err:", err.Error())
return
}
for _, src := range sources {
fmt.Println(src)
}
}

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@ -1,50 +0,0 @@
// https://groups.google.com/forum/#!topic/golang-nuts/-N9Toa6qlu8
// shows that you can extract attribute values directly from tag/key path.
// NOTE: attribute values are encoded by prepending a hyphen, '-'.
package main
import (
"fmt"
"github.com/clbanning/mxj"
)
var xmldata = []byte(`
<doc>
<some_tag>
<geoInfo>
<city name="SEATTLE"/>
<state name="WA"/>
<country name="USA"/>
</geoInfo>
<geoInfo>
<city name="VANCOUVER"/>
<state name="BC"/>
<country name="CA"/>
</geoInfo>
<geoInfo>
<city name="LONDON"/>
<country name="UK"/>
</geoInfo>
</some_tag>
</doc>`)
func main() {
fmt.Println("xmldata:", string(xmldata))
m, merr := mxj.NewMapXml(xmldata)
if merr != nil {
fmt.Println("merr:", merr)
return
}
// Attributes are keys with prepended hyphen, '-'.
values, err := m.ValuesForPath("doc.some_tag.geoInfo.country.-name")
if err != nil {
fmt.Println("err:", err.Error())
}
for _, v := range values {
fmt.Println("v:", v)
}
}

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@ -1,75 +0,0 @@
// gonuts5.go - from https://groups.google.com/forum/#!topic/golang-nuts/MWoYY19of3o
// problem is to extract entries from <lst name="list3-1-1-1"></lst> by "int name="
package main
import (
"fmt"
"github.com/clbanning/mxj"
)
var xmlData = []byte(`<?xml version="1.0" encoding="UTF-8"?>
<response>
<lst name="list1">
</lst>
<lst name="list2">
</lst>
<lst name="list3">
<int name="docId">1</int>
<lst name="list3-1">
<lst name="list3-1-1">
<lst name="list3-1-1-1">
<int name="field1">1</int>
<int name="field2">2</int>
<int name="field3">3</int>
<int name="field4">4</int>
<int name="field5">5</int>
</lst>
</lst>
<lst name="list3-1-2">
<lst name="list3-1-2-1">
<int name="field1">1</int>
<int name="field2">2</int>
<int name="field3">3</int>
<int name="field4">4</int>
<int name="field5">5</int>
</lst>
</lst>
</lst>
</lst>
</response>`)
func main() {
// parse XML into a Map
m, merr := mxj.NewMapXml(xmlData)
if merr != nil {
fmt.Println("merr:", merr.Error())
return
}
// extract the 'list3-1-1-1' node - there'll be just 1?
// NOTE: attribute keys are prepended with '-'
lstVal, lerr := m.ValuesForPath("*.*.*.*.*", "-name:list3-1-1-1")
if lerr != nil {
fmt.Println("ierr:", lerr.Error())
return
}
// assuming just one value returned - create a new Map
mv := mxj.Map(lstVal[0].(map[string]interface{}))
// extract the 'int' values by 'name' attribute: "-name"
// interate over list of 'name' values of interest
var names = []string{"field1", "field2", "field3", "field4", "field5"}
for _, n := range names {
vals, verr := mv.ValuesForKey("int", "-name:"+n)
if verr != nil {
fmt.Println("verr:", verr.Error(), len(vals))
return
}
// values for simple elements have key '#text'
// NOTE: there can be only one value for key '#text'
fmt.Println(n, ":", vals[0].(map[string]interface{})["#text"])
}
}

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@ -1,75 +0,0 @@
// gonuts5.go - from https://groups.google.com/forum/#!topic/golang-nuts/MWoYY19of3o
// problem is to extract entries from <lst name="list3-1-1-1"></lst> by "int name="
package main
import (
"fmt"
"github.com/clbanning/mxj"
)
var xmlData = []byte(`<?xml version="1.0" encoding="UTF-8"?>
<response>
<lst name="list1">
</lst>
<lst name="list2">
</lst>
<lst name="list3">
<int name="docId">1</int>
<lst name="list3-1">
<lst name="list3-1-1">
<lst name="list3-1-1-1">
<int name="field1">1</int>
<int name="field2">2</int>
<int name="field3">3</int>
<int name="field4">4</int>
<int name="field5">5</int>
</lst>
</lst>
<lst name="list3-1-2">
<lst name="list3-1-2-1">
<int name="field1">1</int>
<int name="field2">2</int>
<int name="field3">3</int>
<int name="field4">4</int>
<int name="field5">5</int>
</lst>
</lst>
</lst>
</lst>
</response>`)
func main() {
// parse XML into a Map
m, merr := mxj.NewMapXml(xmlData)
if merr != nil {
fmt.Println("merr:", merr.Error())
return
}
// extract the 'list3-1-1-1' node - there'll be just 1?
// NOTE: attribute keys are prepended with '-'
lstVal, lerr := m.ValuesForPath("*.*.*.*.*", "-name:list3-1-1-1")
if lerr != nil {
fmt.Println("ierr:", lerr.Error())
return
}
// assuming just one value returned - create a new Map
mv := mxj.Map(lstVal[0].(map[string]interface{}))
// extract the 'int' values by 'name' attribute: "-name"
// interate over list of 'name' values of interest
var names = []string{"field1", "field2", "field3", "field4", "field5"}
for _, n := range names {
vals, verr := mv.ValuesForKey("*", "-name:"+n)
if verr != nil {
fmt.Println("verr:", verr.Error(), len(vals))
return
}
// values for simple elements have key '#text'
// NOTE: there can be only one value for key '#text'
fmt.Println(n, ":", vals[0].(map[string]interface{})["#text"])
}
}

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@ -1,43 +0,0 @@
/* https://groups.google.com/forum/#!topic/golang-nuts/EMXHB1nJoBA
package main
import "fmt"
import "encoding/json"
func main() {
var v struct {
DBInstances []struct {
Endpoint struct {
Address string
}
}
}
json.Unmarshal(s, &v)
fmt.Println(v.DBInstances[0].Endpoint.Address)
}
*/
package main
import "fmt"
import "github.com/clbanning/mxj"
func main() {
m, err := mxj.NewMapJson(s)
if err != nil {
fmt.Println("err:", err.Error())
}
v, err := m.ValuesForKey("Address")
// v, err := m.ValuesForPath("DBInstances[0].Endpoint.Address")
if err != nil {
fmt.Println("err:", err.Error())
}
if len(v) > 0 {
fmt.Println(v[0].(string))
} else {
fmt.Println("No value.")
}
}
var s = []byte(`{ "DBInstances": [ { "PubliclyAccessible": true, "MasterUsername": "postgres", "LicenseModel": "postgresql-license", "VpcSecurityGroups": [ { "Status": "active", "VpcSecurityGroupId": "sg-e72a4282" } ], "InstanceCreateTime": "2014-06-29T03:52:59.268Z", "OptionGroupMemberships": [ { "Status": "in-sync", "OptionGroupName": "default:postgres-9-3" } ], "PendingModifiedValues": {}, "Engine": "postgres", "MultiAZ": true, "LatestRestorableTime": "2014-06-29T12:00:34Z", "DBSecurityGroups": [ { "Status": "active", "DBSecurityGroupName": "production-dbsecuritygroup-q4f0ugxpjck8" } ], "DBParameterGroups": [ { "DBParameterGroupName": "default.postgres9.3", "ParameterApplyStatus": "in-sync" } ], "AutoMinorVersionUpgrade": true, "PreferredBackupWindow": "06:59-07:29", "DBSubnetGroup": { "Subnets": [ { "SubnetStatus": "Active", "SubnetIdentifier": "subnet-34e5d01c", "SubnetAvailabilityZone": { "Name": "us-east-1b", "ProvisionedIopsCapable": false } }, { "SubnetStatus": "Active", "SubnetIdentifier": "subnet-50759d27", "SubnetAvailabilityZone": { "Name": "us-east-1c", "ProvisionedIopsCapable": false } }, { "SubnetStatus": "Active", "SubnetIdentifier": "subnet-450a1f03", "SubnetAvailabilityZone": { "Name": "us-east-1d", "ProvisionedIopsCapable": false } } ], "DBSubnetGroupName": "default", "VpcId": "vpc-acb86cc9", "DBSubnetGroupDescription": "default", "SubnetGroupStatus": "Complete" }, "SecondaryAvailabilityZone": "us-east-1b", "ReadReplicaDBInstanceIdentifiers": [], "AllocatedStorage": 15, "BackupRetentionPeriod": 1, "DBName": "deis", "PreferredMaintenanceWindow": "fri:05:52-fri:06:22", "Endpoint": { "Port": 5432, "Address": "production.cfk8mskkbkeu.us-east-1.rds.amazonaws.com" }, "DBInstanceStatus": "available", "EngineVersion": "9.3.3", "AvailabilityZone": "us-east-1c", "DBInstanceClass": "db.m1.small", "DBInstanceIdentifier": "production" } ] }`)

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@ -1,299 +0,0 @@
package mxj
import (
"fmt"
"io"
"os"
)
type Maps []Map
func NewMaps() Maps {
return make(Maps, 0)
}
type MapRaw struct {
M Map
R []byte
}
// NewMapsFromXmlFile - creates an array from a file of JSON values.
func NewMapsFromJsonFile(name string) (Maps, error) {
fi, err := os.Stat(name)
if err != nil {
return nil, err
}
if !fi.Mode().IsRegular() {
return nil, fmt.Errorf("file %s is not a regular file", name)
}
fh, err := os.Open(name)
if err != nil {
return nil, err
}
defer fh.Close()
am := make([]Map, 0)
for {
m, raw, err := NewMapJsonReaderRaw(fh)
if err != nil && err != io.EOF {
return am, fmt.Errorf("error: %s - reading: %s", err.Error(), string(raw))
}
if len(m) > 0 {
am = append(am, m)
}
if err == io.EOF {
break
}
}
return am, nil
}
// ReadMapsFromJsonFileRaw - creates an array of MapRaw from a file of JSON values.
func NewMapsFromJsonFileRaw(name string) ([]MapRaw, error) {
fi, err := os.Stat(name)
if err != nil {
return nil, err
}
if !fi.Mode().IsRegular() {
return nil, fmt.Errorf("file %s is not a regular file", name)
}
fh, err := os.Open(name)
if err != nil {
return nil, err
}
defer fh.Close()
am := make([]MapRaw, 0)
for {
mr := new(MapRaw)
mr.M, mr.R, err = NewMapJsonReaderRaw(fh)
if err != nil && err != io.EOF {
return am, fmt.Errorf("error: %s - reading: %s", err.Error(), string(mr.R))
}
if len(mr.M) > 0 {
am = append(am, *mr)
}
if err == io.EOF {
break
}
}
return am, nil
}
// NewMapsFromXmlFile - creates an array from a file of XML values.
func NewMapsFromXmlFile(name string) (Maps, error) {
x := XmlWriterBufSize
XmlWriterBufSize = 0
defer func() {
XmlWriterBufSize = x
}()
fi, err := os.Stat(name)
if err != nil {
return nil, err
}
if !fi.Mode().IsRegular() {
return nil, fmt.Errorf("file %s is not a regular file", name)
}
fh, err := os.Open(name)
if err != nil {
return nil, err
}
defer fh.Close()
am := make([]Map, 0)
for {
m, raw, err := NewMapXmlReaderRaw(fh)
if err != nil && err != io.EOF {
return am, fmt.Errorf("error: %s - reading: %s", err.Error(), string(raw))
}
if len(m) > 0 {
am = append(am, m)
}
if err == io.EOF {
break
}
}
return am, nil
}
// NewMapsFromXmlFileRaw - creates an array of MapRaw from a file of XML values.
// NOTE: the slice with the raw XML is clean with no extra capacity - unlike NewMapXmlReaderRaw().
// It is slow at parsing a file from disk and is intended for relatively small utility files.
func NewMapsFromXmlFileRaw(name string) ([]MapRaw, error) {
x := XmlWriterBufSize
XmlWriterBufSize = 0
defer func() {
XmlWriterBufSize = x
}()
fi, err := os.Stat(name)
if err != nil {
return nil, err
}
if !fi.Mode().IsRegular() {
return nil, fmt.Errorf("file %s is not a regular file", name)
}
fh, err := os.Open(name)
if err != nil {
return nil, err
}
defer fh.Close()
am := make([]MapRaw, 0)
for {
mr := new(MapRaw)
mr.M, mr.R, err = NewMapXmlReaderRaw(fh)
if err != nil && err != io.EOF {
return am, fmt.Errorf("error: %s - reading: %s", err.Error(), string(mr.R))
}
if len(mr.M) > 0 {
am = append(am, *mr)
}
if err == io.EOF {
break
}
}
return am, nil
}
// ------------------------ Maps writing -------------------------
// These are handy-dandy methods for dumping configuration data, etc.
// JsonString - analogous to mv.Json()
func (mvs Maps) JsonString(safeEncoding ...bool) (string, error) {
var s string
for _, v := range mvs {
j, err := v.Json()
if err != nil {
return s, err
}
s += string(j)
}
return s, nil
}
// JsonStringIndent - analogous to mv.JsonIndent()
func (mvs Maps) JsonStringIndent(prefix, indent string, safeEncoding ...bool) (string, error) {
var s string
var haveFirst bool
for _, v := range mvs {
j, err := v.JsonIndent(prefix, indent)
if err != nil {
return s, err
}
if haveFirst {
s += "\n"
} else {
haveFirst = true
}
s += string(j)
}
return s, nil
}
// XmlString - analogous to mv.Xml()
func (mvs Maps) XmlString() (string, error) {
var s string
for _, v := range mvs {
x, err := v.Xml()
if err != nil {
return s, err
}
s += string(x)
}
return s, nil
}
// XmlStringIndent - analogous to mv.XmlIndent()
func (mvs Maps) XmlStringIndent(prefix, indent string) (string, error) {
var s string
for _, v := range mvs {
x, err := v.XmlIndent(prefix, indent)
if err != nil {
return s, err
}
s += string(x)
}
return s, nil
}
// JsonFile - write Maps to named file as JSON
// Note: the file will be created, if necessary; if it exists it will be truncated.
// If you need to append to a file, open it and use JsonWriter method.
func (mvs Maps) JsonFile(file string, safeEncoding ...bool) error {
var encoding bool
if len(safeEncoding) == 1 {
encoding = safeEncoding[0]
}
s, err := mvs.JsonString(encoding)
if err != nil {
return err
}
fh, err := os.Create(file)
if err != nil {
return err
}
defer fh.Close()
fh.WriteString(s)
return nil
}
// JsonFileIndent - write Maps to named file as pretty JSON
// Note: the file will be created, if necessary; if it exists it will be truncated.
// If you need to append to a file, open it and use JsonIndentWriter method.
func (mvs Maps) JsonFileIndent(file, prefix, indent string, safeEncoding ...bool) error {
var encoding bool
if len(safeEncoding) == 1 {
encoding = safeEncoding[0]
}
s, err := mvs.JsonStringIndent(prefix, indent, encoding)
if err != nil {
return err
}
fh, err := os.Create(file)
if err != nil {
return err
}
defer fh.Close()
fh.WriteString(s)
return nil
}
// XmlFile - write Maps to named file as XML
// Note: the file will be created, if necessary; if it exists it will be truncated.
// If you need to append to a file, open it and use XmlWriter method.
func (mvs Maps) XmlFile(file string) error {
s, err := mvs.XmlString()
if err != nil {
return err
}
fh, err := os.Create(file)
if err != nil {
return err
}
defer fh.Close()
fh.WriteString(s)
return nil
}
// XmlFileIndent - write Maps to named file as pretty XML
// Note: the file will be created,if necessary; if it exists it will be truncated.
// If you need to append to a file, open it and use XmlIndentWriter method.
func (mvs Maps) XmlFileIndent(file, prefix, indent string) error {
s, err := mvs.XmlStringIndent(prefix, indent)
if err != nil {
return err
}
fh, err := os.Create(file)
if err != nil {
return err
}
defer fh.Close()
fh.WriteString(s)
return nil
}

View File

@ -1,2 +0,0 @@
{ "this":"is", "a":"test", "file":"for", "files_test.go":"case" }
{ "with":"some", "bad":JSON, "in":"it" }

View File

@ -1,9 +0,0 @@
<doc>
<some>test</some>
<data>for files.go</data>
</doc>
<msg>
<just>some</just>
<another>doc</other>
<for>test case</for>
</msg>

View File

@ -1,168 +0,0 @@
package mxj
import (
"fmt"
"testing"
)
func TestFilesHeader(t *testing.T) {
fmt.Println("\n---------------- files_test.go ...\n")
}
func TestNewJsonFile(t *testing.T) {
fmt.Println("NewMapsFromJsonFile()")
am, err := NewMapsFromJsonFile("files_test.json")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range am {
fmt.Printf("%v\n", v)
}
am, err = NewMapsFromJsonFile("nil")
if err == nil {
t.Fatal("no error returned for read of nil file")
}
fmt.Println("caught error: ", err.Error())
am, err = NewMapsFromJsonFile("files_test.badjson")
if err == nil {
t.Fatal("no error returned for read of badjson file")
}
fmt.Println("caught error: ", err.Error())
}
func TestNewJsonFileRaw(t *testing.T) {
fmt.Println("NewMapsFromJsonFileRaw()")
mr, err := NewMapsFromJsonFileRaw("files_test.json")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range mr {
fmt.Printf("%v\n", v)
}
mr, err = NewMapsFromJsonFileRaw("nil")
if err == nil {
t.Fatal("no error returned for read of nil file")
}
fmt.Println("caught error: ", err.Error())
mr, err = NewMapsFromJsonFileRaw("files_test.badjson")
if err == nil {
t.Fatal("no error returned for read of badjson file")
}
fmt.Println("caught error: ", err.Error())
}
func TestNewXmFile(t *testing.T) {
fmt.Println("NewMapsFromXmlFile()")
am, err := NewMapsFromXmlFile("files_test.xml")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range am {
fmt.Printf("%v\n", v)
}
am, err = NewMapsFromXmlFile("nil")
if err == nil {
t.Fatal("no error returned for read of nil file")
}
fmt.Println("caught error: ", err.Error())
am, err = NewMapsFromXmlFile("files_test.badxml")
if err == nil {
t.Fatal("no error returned for read of badjson file")
}
fmt.Println("caught error: ", err.Error())
}
func TestNewXmFileRaw(t *testing.T) {
fmt.Println("NewMapsFromXmlFileRaw()")
mr, err := NewMapsFromXmlFileRaw("files_test.xml")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range mr {
fmt.Printf("%v\n", v)
}
mr, err = NewMapsFromXmlFileRaw("nil")
if err == nil {
t.Fatal("no error returned for read of nil file")
}
fmt.Println("caught error: ", err.Error())
mr, err = NewMapsFromXmlFileRaw("files_test.badxml")
if err == nil {
t.Fatal("no error returned for read of badjson file")
}
fmt.Println("caught error: ", err.Error())
}
func TestMaps(t *testing.T) {
fmt.Println("TestMaps()")
mvs := NewMaps()
for i := 0; i < 2; i++ {
m, _ := NewMapJson([]byte(`{ "this":"is", "a":"test" }`))
mvs = append(mvs, m)
}
fmt.Println("mvs:", mvs)
s, _ := mvs.JsonString()
fmt.Println("JsonString():", s)
s, _ = mvs.JsonStringIndent("", " ")
fmt.Println("JsonStringIndent():", s)
s, _ = mvs.XmlString()
fmt.Println("XmlString():", s)
s, _ = mvs.XmlStringIndent("", " ")
fmt.Println("XmlStringIndent():", s)
}
func TestJsonFile(t *testing.T) {
am, err := NewMapsFromJsonFile("files_test.json")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range am {
fmt.Printf("%v\n", v)
}
err = am.JsonFile("files_test_dup.json")
if err != nil {
t.Fatal(err.Error())
}
fmt.Println("files_test_dup.json written")
err = am.JsonFileIndent("files_test_indent.json", "", " ")
if err != nil {
t.Fatal(err.Error())
}
fmt.Println("files_test_indent.json written")
}
func TestXmlFile(t *testing.T) {
am, err := NewMapsFromXmlFile("files_test.xml")
if err != nil {
t.Fatal(err.Error())
}
for _, v := range am {
fmt.Printf("%v\n", v)
}
err = am.XmlFile("files_test_dup.xml")
if err != nil {
t.Fatal(err.Error())
}
fmt.Println("files_test_dup.xml written")
err = am.XmlFileIndent("files_test_indent.xml", "", " ")
if err != nil {
t.Fatal(err.Error())
}
fmt.Println("files_test_indent.xml written")
}

View File

@ -1,2 +0,0 @@
{ "this":"is", "a":"test", "file":"for", "files_test.go":"case" }
{ "with":"just", "two":2, "JSON":"values", "true":true }

View File

@ -1,9 +0,0 @@
<doc>
<some>test</some>
<data>for files.go</data>
</doc>
<msg>
<just>some</just>
<another>doc</another>
<for>test case</for>
</msg>

View File

@ -1 +0,0 @@
{"a":"test","file":"for","files_test.go":"case","this":"is"}{"JSON":"values","true":true,"two":2,"with":"just"}

View File

@ -1 +0,0 @@
<doc><some>test</some><data>for files.go</data></doc><msg><just>some</just><another>doc</another><for>test case</for></msg>

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@ -1,12 +0,0 @@
{
"a": "test",
"file": "for",
"files_test.go": "case",
"this": "is"
}
{
"JSON": "values",
"true": true,
"two": 2,
"with": "just"
}

View File

@ -1,8 +0,0 @@
<doc>
<some>test</some>
<data>for files.go</data>
</doc><msg>
<just>some</just>
<another>doc</another>
<for>test case</for>
</msg>

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@ -1,178 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// j2x.go - For (mostly) backwards compatibility with legacy j2x package.
// Wrappers for end-to-end JSON to XML transformation and value manipulation.
package j2x
import (
. "github.com/clbanning/mxj"
"io"
)
// FromJson() --> map[string]interface{}
func JsonToMap(jsonVal []byte) (map[string]interface{}, error) {
return NewMapJson(jsonVal)
}
// interface{} --> ToJson (w/o safe encoding, default) {
func MapToJson(m map[string]interface{}, safeEncoding ...bool) ([]byte, error) {
return Map(m).Json()
}
// FromJson() --> ToXml().
func JsonToXml(jsonVal []byte) ([]byte, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.Xml()
}
// FromJson() --> ToXmlWriter().
func JsonToXmlWriter(jsonVal []byte, xmlWriter io.Writer) ([]byte, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.XmlWriterRaw(xmlWriter)
}
// FromJsonReader() --> ToXml().
func JsonReaderToXml(jsonReader io.Reader) ([]byte, []byte, error) {
m, jraw, err := NewMapJsonReaderRaw(jsonReader)
if err != nil {
return jraw, nil, err
}
x, xerr := m.Xml()
return jraw, x, xerr
}
// FromJsonReader() --> ToXmlWriter(). Handy for transforming bulk message sets.
func JsonReaderToXmlWriter(jsonReader io.Reader, xmlWriter io.Writer) ([]byte, []byte, error) {
m, jraw, err := NewMapJsonReaderRaw(jsonReader)
if err != nil {
return jraw, nil, err
}
xraw, xerr := m.XmlWriterRaw(xmlWriter)
return jraw, xraw, xerr
}
// JSON wrappers for Map methods implementing key path and value functions.
// Wrap PathsForKey for JSON.
func JsonPathsForKey(jsonVal []byte, key string) ([]string, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
paths := m.PathsForKey(key)
return paths, nil
}
// Wrap PathForKeyShortest for JSON.
func JsonPathForKeyShortest(jsonVal []byte, key string) (string, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return "", err
}
path := m.PathForKeyShortest(key)
return path, nil
}
// Wrap ValuesForKey for JSON.
func JsonValuesForKey(jsonVal []byte, key string, subkeys ...string) ([]interface{}, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.ValuesForKey(key, subkeys...)
}
// Wrap ValuesForKeyPath for JSON.
func JsonValuesForKeyPath(jsonVal []byte, path string, subkeys ...string) ([]interface{}, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.ValuesForPath(path, subkeys...)
}
// Wrap UpdateValuesForPath for JSON
// 'jsonVal' is XML value
// 'newKeyValue' is the value to replace an existing value at the end of 'path'
// 'path' is the dot-notation path with the key whose value is to be replaced at the end
// (can include wildcard character, '*')
// 'subkeys' are key:value pairs of key:values that must match for the key
func JsonUpdateValsForPath(jsonVal []byte, newKeyValue interface{}, path string, subkeys ...string) ([]byte, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
_, err = m.UpdateValuesForPath(newKeyValue, path, subkeys...)
if err != nil {
return nil, err
}
return m.Json()
}
// Wrap NewMap for JSON and return as JSON
// 'jsonVal' is an JSON value
// 'keypairs' are "oldKey:newKey" values that conform to 'keypairs' in (Map)NewMap.
func JsonNewJson(jsonVal []byte, keypairs ...string) ([]byte, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
n, err := m.NewMap(keypairs...)
if err != nil {
return nil, err
}
return n.Json()
}
// Wrap NewMap for JSON and return as XML
// 'jsonVal' is an JSON value
// 'keypairs' are "oldKey:newKey" values that conform to 'keypairs' in (Map)NewMap.
func JsonNewXml(jsonVal []byte, keypairs ...string) ([]byte, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
n, err := m.NewMap(keypairs...)
if err != nil {
return nil, err
}
return n.Xml()
}
// Wrap LeafNodes for JSON.
// 'jsonVal' is an JSON value
func JsonLeafNodes(jsonVal []byte) ([]LeafNode, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.LeafNodes(), nil
}
// Wrap LeafValues for JSON.
// 'jsonVal' is an JSON value
func JsonLeafValues(jsonVal []byte) ([]interface{}, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.LeafValues(), nil
}
// Wrap LeafPath for JSON.
// 'xmlVal' is an JSON value
func JsonLeafPath(jsonVal []byte) ([]string, error) {
m, err := NewMapJson(jsonVal)
if err != nil {
return nil, err
}
return m.LeafPaths(), nil
}

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@ -1,67 +0,0 @@
// thanks to Chris Malek (chris.r.malek@gmail.com) for suggestion to handle JSON list docs.
package j2x
import (
"bytes"
"fmt"
"io/ioutil"
"testing"
)
func TestJsonToXml_1(t *testing.T) {
// mimic a io.Reader
// Body := bytes.NewReader([]byte(`{"some-null-value":"", "a-non-null-value":"bar"}`))
Body := bytes.NewReader([]byte(`[{"some-null-value":"", "a-non-null-value":"bar"}]`))
//body, err := ioutil.ReadAll(req.Body)
body, err := ioutil.ReadAll(Body)
if err != nil {
t.Fatal(err)
}
fmt.Println(string(body))
//if err != nil {
// t.Fatal(err)
//}
var xmloutput []byte
//xmloutput, err = j2x.JsonToXml(body)
xmloutput, err = JsonToXml(body)
//log.Println(string(xmloutput))
if err != nil {
t.Fatal(err)
// log.Println(err)
// http.Error(rw, "Could not convert to xml", 400)
}
fmt.Println("xmloutput:", string(xmloutput))
}
func TestJsonToXml_2(t *testing.T) {
// mimic a io.Reader
Body := bytes.NewReader([]byte(`{"somekey":[{"value":"1st"},{"value":"2nd"}]}`))
//body, err := ioutil.ReadAll(req.Body)
body, err := ioutil.ReadAll(Body)
if err != nil {
t.Fatal(err)
}
fmt.Println(string(body))
//if err != nil {
// t.Fatal(err)
//}
var xmloutput []byte
//xmloutput, err = j2x.JsonToXml(body)
xmloutput, err = JsonToXml(body)
//log.Println(string(xmloutput))
if err != nil {
t.Fatal(err)
// log.Println(err)
// http.Error(rw, "Could not convert to xml", 400)
}
fmt.Println("xmloutput:", string(xmloutput))
}

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@ -1,29 +0,0 @@
package mxj
import (
"fmt"
"testing"
)
var jjdata = []byte(`{ "key1":"string", "key2":34, "key3":true, "key4":"unsafe: <>&", "key5":null }`)
func TestJ2XHeader(t *testing.T) {
fmt.Println("\n---------------- j2x_test .go ...\n")
}
func TestJ2X(t *testing.T) {
m, err := NewMapJson(jjdata)
if err != nil {
t.Fatal("NewMapJson, err:", err)
}
x, err := m.Xml()
if err != nil {
t.Fatal("m.Xml(), err:", err)
}
fmt.Println("j2x, jdata:", string(jjdata))
fmt.Println("j2x, m :", m)
fmt.Println("j2x, xml :", string(x))
}

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@ -1,319 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
package mxj
import (
"bytes"
"encoding/json"
"fmt"
"io"
"time"
)
// ------------------------------ write JSON -----------------------
// Just a wrapper on json.Marshal.
// If option safeEncoding is'true' then safe encoding of '<', '>' and '&'
// is preserved. (see encoding/json#Marshal, encoding/json#Encode)
func (mv Map) Json(safeEncoding ...bool) ([]byte, error) {
var s bool
if len(safeEncoding) == 1 {
s = safeEncoding[0]
}
b, err := json.Marshal(mv)
if !s {
b = bytes.Replace(b, []byte("\\u003c"), []byte("<"), -1)
b = bytes.Replace(b, []byte("\\u003e"), []byte(">"), -1)
b = bytes.Replace(b, []byte("\\u0026"), []byte("&"), -1)
}
return b, err
}
// Just a wrapper on json.MarshalIndent.
// If option safeEncoding is'true' then safe encoding of '<' , '>' and '&'
// is preserved. (see encoding/json#Marshal, encoding/json#Encode)
func (mv Map) JsonIndent(prefix, indent string, safeEncoding ...bool) ([]byte, error) {
var s bool
if len(safeEncoding) == 1 {
s = safeEncoding[0]
}
b, err := json.MarshalIndent(mv, prefix, indent)
if !s {
b = bytes.Replace(b, []byte("\\u003c"), []byte("<"), -1)
b = bytes.Replace(b, []byte("\\u003e"), []byte(">"), -1)
b = bytes.Replace(b, []byte("\\u0026"), []byte("&"), -1)
}
return b, err
}
// The following implementation is provided for symmetry with NewMapJsonReader[Raw]
// The names will also provide a key for the number of return arguments.
// Writes the Map as JSON on the Writer.
// If 'safeEncoding' is 'true', then "safe" encoding of '<', '>' and '&' is preserved.
func (mv Map) JsonWriter(jsonWriter io.Writer, safeEncoding ...bool) error {
b, err := mv.Json(safeEncoding...)
if err != nil {
return err
}
_, err = jsonWriter.Write(b)
return err
}
// Writes the Map as JSON on the Writer. []byte is the raw JSON that was written.
// If 'safeEncoding' is 'true', then "safe" encoding of '<', '>' and '&' is preserved.
func (mv Map) JsonWriterRaw(jsonWriter io.Writer, safeEncoding ...bool) ([]byte, error) {
b, err := mv.Json(safeEncoding...)
if err != nil {
return b, err
}
_, err = jsonWriter.Write(b)
return b, err
}
// Writes the Map as pretty JSON on the Writer.
// If 'safeEncoding' is 'true', then "safe" encoding of '<', '>' and '&' is preserved.
func (mv Map) JsonIndentWriter(jsonWriter io.Writer, prefix, indent string, safeEncoding ...bool) error {
b, err := mv.JsonIndent(prefix, indent, safeEncoding...)
if err != nil {
return err
}
_, err = jsonWriter.Write(b)
return err
}
// Writes the Map as pretty JSON on the Writer. []byte is the raw JSON that was written.
// If 'safeEncoding' is 'true', then "safe" encoding of '<', '>' and '&' is preserved.
func (mv Map) JsonIndentWriterRaw(jsonWriter io.Writer, prefix, indent string, safeEncoding ...bool) ([]byte, error) {
b, err := mv.JsonIndent(prefix, indent, safeEncoding...)
if err != nil {
return b, err
}
_, err = jsonWriter.Write(b)
return b, err
}
// --------------------------- read JSON -----------------------------
// Parse numeric values as json.Number types - see encoding/json#Number
var JsonUseNumber bool
// Just a wrapper on json.Unmarshal
// Converting JSON to XML is a simple as:
// ...
// mapVal, merr := mxj.NewMapJson(jsonVal)
// if merr != nil {
// // handle error
// }
// xmlVal, xerr := mapVal.Xml()
// if xerr != nil {
// // handle error
// }
// NOTE: as a special case, passing a list, e.g., [{"some-null-value":"", "a-non-null-value":"bar"}],
// will be interpreted as having the root key 'object' prepended - {"object":[ ... ]} - to unmarshal to a Map.
// See mxj/j2x/j2x_test.go.
func NewMapJson(jsonVal []byte) (Map, error) {
// empty or nil begets empty
if len(jsonVal) == 0 {
m := make(map[string]interface{}, 0)
return m, nil
}
// handle a goofy case ...
if jsonVal[0] == '[' {
jsonVal = []byte(`{"object":` + string(jsonVal) + `}`)
}
m := make(map[string]interface{})
// err := json.Unmarshal(jsonVal, &m)
buf := bytes.NewReader(jsonVal)
dec := json.NewDecoder(buf)
if JsonUseNumber {
dec.UseNumber()
}
err := dec.Decode(&m)
return m, err
}
// Retrieve a Map value from an io.Reader.
// NOTE: The raw JSON off the reader is buffered to []byte using a ByteReader. If the io.Reader is an
// os.File, there may be significant performance impact. If the io.Reader is wrapping a []byte
// value in-memory, however, such as http.Request.Body you CAN use it to efficiently unmarshal
// a JSON object.
func NewMapJsonReader(jsonReader io.Reader) (Map, error) {
jb, err := getJson(jsonReader)
if err != nil || len(*jb) == 0 {
return nil, err
}
// Unmarshal the 'presumed' JSON string
return NewMapJson(*jb)
}
// Retrieve a Map value and raw JSON - []byte - from an io.Reader.
// NOTE: The raw JSON off the reader is buffered to []byte using a ByteReader. If the io.Reader is an
// os.File, there may be significant performance impact. If the io.Reader is wrapping a []byte
// value in-memory, however, such as http.Request.Body you CAN use it to efficiently unmarshal
// a JSON object and retrieve the raw JSON in a single call.
func NewMapJsonReaderRaw(jsonReader io.Reader) (Map, []byte, error) {
jb, err := getJson(jsonReader)
if err != nil || len(*jb) == 0 {
return nil, *jb, err
}
// Unmarshal the 'presumed' JSON string
m, merr := NewMapJson(*jb)
return m, *jb, merr
}
// Pull the next JSON string off the stream: just read from first '{' to its closing '}'.
// Returning a pointer to the slice saves 16 bytes - maybe unnecessary, but internal to package.
func getJson(rdr io.Reader) (*[]byte, error) {
bval := make([]byte, 1)
jb := make([]byte, 0)
var inQuote, inJson bool
var parenCnt int
var previous byte
// scan the input for a matched set of {...}
// json.Unmarshal will handle syntax checking.
for {
_, err := rdr.Read(bval)
if err != nil {
if err == io.EOF && inJson && parenCnt > 0 {
return &jb, fmt.Errorf("no closing } for JSON string: %s", string(jb))
}
return &jb, err
}
switch bval[0] {
case '{':
if !inQuote {
parenCnt++
inJson = true
}
case '}':
if !inQuote {
parenCnt--
}
if parenCnt < 0 {
return nil, fmt.Errorf("closing } without opening {: %s", string(jb))
}
case '"':
if inQuote {
if previous == '\\' {
break
}
inQuote = false
} else {
inQuote = true
}
case '\n', '\r', '\t', ' ':
if !inQuote {
continue
}
}
if inJson {
jb = append(jb, bval[0])
if parenCnt == 0 {
break
}
}
previous = bval[0]
}
return &jb, nil
}
// ------------------------------- JSON Reader handler via Map values -----------------------
// Default poll delay to keep Handler from spinning on an open stream
// like sitting on os.Stdin waiting for imput.
var jhandlerPollInterval = time.Duration(1e6)
// While unnecessary, we make HandleJsonReader() have the same signature as HandleXmlReader().
// This avoids treating one or other as a special case and discussing the underlying stdlib logic.
// Bulk process JSON using handlers that process a Map value.
// 'rdr' is an io.Reader for the JSON (stream).
// 'mapHandler' is the Map processing handler. Return of 'false' stops io.Reader processing.
// 'errHandler' is the error processor. Return of 'false' stops io.Reader processing and returns the error.
// Note: mapHandler() and errHandler() calls are blocking, so reading and processing of messages is serialized.
// This means that you can stop reading the file on error or after processing a particular message.
// To have reading and handling run concurrently, pass argument to a go routine in handler and return 'true'.
func HandleJsonReader(jsonReader io.Reader, mapHandler func(Map) bool, errHandler func(error) bool) error {
var n int
for {
m, merr := NewMapJsonReader(jsonReader)
n++
// handle error condition with errhandler
if merr != nil && merr != io.EOF {
merr = fmt.Errorf("[jsonReader: %d] %s", n, merr.Error())
if ok := errHandler(merr); !ok {
// caused reader termination
return merr
}
continue
}
// pass to maphandler
if len(m) != 0 {
if ok := mapHandler(m); !ok {
break
}
} else if merr != io.EOF {
<-time.After(jhandlerPollInterval)
}
if merr == io.EOF {
break
}
}
return nil
}
// Bulk process JSON using handlers that process a Map value and the raw JSON.
// 'rdr' is an io.Reader for the JSON (stream).
// 'mapHandler' is the Map and raw JSON - []byte - processor. Return of 'false' stops io.Reader processing.
// 'errHandler' is the error and raw JSON processor. Return of 'false' stops io.Reader processing and returns the error.
// Note: mapHandler() and errHandler() calls are blocking, so reading and processing of messages is serialized.
// This means that you can stop reading the file on error or after processing a particular message.
// To have reading and handling run concurrently, pass argument(s) to a go routine in handler and return 'true'.
func HandleJsonReaderRaw(jsonReader io.Reader, mapHandler func(Map, []byte) bool, errHandler func(error, []byte) bool) error {
var n int
for {
m, raw, merr := NewMapJsonReaderRaw(jsonReader)
n++
// handle error condition with errhandler
if merr != nil && merr != io.EOF {
merr = fmt.Errorf("[jsonReader: %d] %s", n, merr.Error())
if ok := errHandler(merr, raw); !ok {
// caused reader termination
return merr
}
continue
}
// pass to maphandler
if len(m) != 0 {
if ok := mapHandler(m, raw); !ok {
break
}
} else if merr != io.EOF {
<-time.After(jhandlerPollInterval)
}
if merr == io.EOF {
break
}
}
return nil
}

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@ -1,137 +0,0 @@
package mxj
import (
"bytes"
"fmt"
"io"
"testing"
)
var jdata = []byte(`{ "key1":"string", "key2":34, "key3":true, "key4":"unsafe: <>&", "key5":null }`)
var jdata2 = []byte(`{ "key1":"string", "key2":34, "key3":true, "key4":"unsafe: <>&" },
{ "key":"value in new JSON string" }`)
func TestJsonHeader(t *testing.T) {
fmt.Println("\n---------------- json_test.go ...\n")
}
func TestNewMapJson(t *testing.T) {
m, merr := NewMapJson(jdata)
if merr != nil {
t.Fatal("NewMapJson, merr:", merr.Error())
}
fmt.Println("NewMapJson, jdata:", string(jdata))
fmt.Printf("NewMapJson, m : %#v\n", m)
}
func TestNewMapJsonNumber(t *testing.T) {
JsonUseNumber = true
m, merr := NewMapJson(jdata)
if merr != nil {
t.Fatal("NewMapJson, merr:", merr.Error())
}
fmt.Println("NewMapJson, jdata:", string(jdata))
fmt.Printf("NewMapJson, m : %#v\n", m)
JsonUseNumber = false
}
func TestNewMapJsonError(t *testing.T) {
m, merr := NewMapJson(jdata[:len(jdata)-2])
if merr == nil {
t.Fatal("NewMapJsonError, m:", m)
}
fmt.Println("NewMapJsonError, jdata :", string(jdata[:len(jdata)-2]))
fmt.Println("NewMapJsonError, merror:", merr.Error())
newData := []byte(`{ "this":"is", "in":error }`)
m, merr = NewMapJson(newData)
if merr == nil {
t.Fatal("NewMapJsonError, m:", m)
}
fmt.Println("NewMapJsonError, newData :", string(newData))
fmt.Println("NewMapJsonError, merror :", merr.Error())
}
func TestNewMapJsonReader(t *testing.T) {
rdr := bytes.NewBuffer(jdata2)
for {
m, jb, merr := NewMapJsonReaderRaw(rdr)
if merr != nil && merr != io.EOF {
t.Fatal("NewMapJsonReader, merr:", merr.Error())
}
if merr == io.EOF {
break
}
fmt.Println("NewMapJsonReader, jb:", string(jb))
fmt.Printf("NewMapJsonReader, m : %#v\n", m)
}
}
func TestNewMapJsonReaderNumber(t *testing.T) {
JsonUseNumber = true
rdr := bytes.NewBuffer(jdata2)
for {
m, jb, merr := NewMapJsonReaderRaw(rdr)
if merr != nil && merr != io.EOF {
t.Fatal("NewMapJsonReader, merr:", merr.Error())
}
if merr == io.EOF {
break
}
fmt.Println("NewMapJsonReader, jb:", string(jb))
fmt.Printf("NewMapJsonReader, m : %#v\n", m)
}
JsonUseNumber = false
}
func TestJson(t *testing.T) {
m, _ := NewMapJson(jdata)
j, jerr := m.Json()
if jerr != nil {
t.Fatal("Json, jerr:", jerr.Error())
}
fmt.Println("Json, jdata:", string(jdata))
fmt.Println("Json, j :", string(j))
j, _ = m.Json(true)
fmt.Println("Json, j safe:", string(j))
}
func TestJsonWriter(t *testing.T) {
mv := Map(map[string]interface{}{"this": "is a", "float": 3.14159, "and": "a", "bool": true})
w := new(bytes.Buffer)
raw, err := mv.JsonWriterRaw(w)
if err != nil {
t.Fatal("err:", err.Error())
}
b := make([]byte, w.Len())
_, err = w.Read(b)
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("JsonWriter, raw:", string(raw))
fmt.Println("JsonWriter, b :", string(b))
}

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@ -1,620 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// keyvalues.go: Extract values from an arbitrary XML doc. Tag path can include wildcard characters.
package mxj
import (
"fmt"
"strconv"
"strings"
)
// ----------------------------- get everything FOR a single key -------------------------
const (
minArraySize = 32
)
var defaultArraySize int = minArraySize
// Adjust the buffers for expected number of values to return from ValuesForKey() and ValuesForPath().
// This can have the effect of significantly reducing memory allocation-copy functions for large data sets.
// Returns the initial buffer size.
func SetArraySize(size int) int {
if size > minArraySize {
defaultArraySize = size
} else {
defaultArraySize = minArraySize
}
return defaultArraySize
}
// Return all values in Map, 'mv', associated with a 'key'. If len(returned_values) == 0, then no match.
// On error, the returned array is 'nil'. NOTE: 'key' can be wildcard, "*".
// 'subkeys' (optional) are "key:val[:type]" strings representing attributes or elements in a list.
// - By default 'val' is of type string. "key:val:bool" and "key:val:float" to coerce them.
// - For attributes prefix the label with a hyphen, '-', e.g., "-seq:3".
// - If the 'key' refers to a list, then "key:value" could select a list member of the list.
// - The subkey can be wildcarded - "key:*" - to require that it's there with some value.
// - If a subkey is preceeded with the '!' character, the key:value[:type] entry is treated as an
// exclusion critera - e.g., "!author:William T. Gaddis".
func (mv Map) ValuesForKey(key string, subkeys ...string) ([]interface{}, error) {
m := map[string]interface{}(mv)
var subKeyMap map[string]interface{}
if len(subkeys) > 0 {
var err error
subKeyMap, err = getSubKeyMap(subkeys...)
if err != nil {
return nil, err
}
}
ret := make([]interface{}, 0, defaultArraySize)
var cnt int
hasKey(m, key, &ret, &cnt, subKeyMap)
return ret[:cnt], nil
// ret := make([]interface{}, 0)
// hasKey(m, key, &ret, subKeyMap)
// return ret, nil
}
// hasKey - if the map 'key' exists append it to array
// if it doesn't do nothing except scan array and map values
func hasKey(iv interface{}, key string, ret *[]interface{}, cnt *int, subkeys map[string]interface{}) {
// func hasKey(iv interface{}, key string, ret *[]interface{}, subkeys map[string]interface{}) {
switch iv.(type) {
case map[string]interface{}:
vv := iv.(map[string]interface{})
// see if the current value is of interest
if v, ok := vv[key]; ok {
switch v.(type) {
case map[string]interface{}:
if hasSubKeys(v, subkeys) {
*ret = append(*ret, v)
*cnt++
}
case []interface{}:
for _, av := range v.([]interface{}) {
if hasSubKeys(av, subkeys) {
*ret = append(*ret, av)
*cnt++
}
}
default:
if len(subkeys) == 0 {
*ret = append(*ret, v)
*cnt++
}
}
}
// wildcard case
if key == "*" {
for _, v := range vv {
switch v.(type) {
case map[string]interface{}:
if hasSubKeys(v, subkeys) {
*ret = append(*ret, v)
*cnt++
}
case []interface{}:
for _, av := range v.([]interface{}) {
if hasSubKeys(av, subkeys) {
*ret = append(*ret, av)
*cnt++
}
}
default:
if len(subkeys) == 0 {
*ret = append(*ret, v)
*cnt++
}
}
}
}
// scan the rest
for _, v := range vv {
hasKey(v, key, ret, cnt, subkeys)
// hasKey(v, key, ret, subkeys)
}
case []interface{}:
for _, v := range iv.([]interface{}) {
hasKey(v, key, ret, cnt, subkeys)
// hasKey(v, key, ret, subkeys)
}
}
}
// ----------------------- get everything for a node in the Map ---------------------------
// Allow indexed arrays in "path" specification. (Request from Abhijit Kadam - abhijitk100@gmail.com.)
// 2014.04.28 - implementation note.
// Implemented as a wrapper of (old)ValuesForPath() because we need look-ahead logic to handle expansion
// of wildcards and unindexed arrays. Embedding such logic into valuesForKeyPath() would have made the
// code much more complicated; this wrapper is straightforward, easy to debug, and doesn't add significant overhead.
// Retrieve all values for a path from the Map. If len(returned_values) == 0, then no match.
// On error, the returned array is 'nil'.
// 'path' is a dot-separated path of key values.
// - If a node in the path is '*', then everything beyond is walked.
// - 'path' can contain indexed array references, such as, "*.data[1]" and "msgs[2].data[0].field" -
// even "*[2].*[0].field".
// 'subkeys' (optional) are "key:val[:type]" strings representing attributes or elements in a list.
// - By default 'val' is of type string. "key:val:bool" and "key:val:float" to coerce them.
// - For attributes prefix the label with a hyphen, '-', e.g., "-seq:3".
// - If the 'path' refers to a list, then "tag:value" would return member of the list.
// - The subkey can be wildcarded - "key:*" - to require that it's there with some value.
// - If a subkey is preceeded with the '!' character, the key:value[:type] entry is treated as an
// exclusion critera - e.g., "!author:William T. Gaddis".
func (mv Map) ValuesForPath(path string, subkeys ...string) ([]interface{}, error) {
// If there are no array indexes in path, use legacy ValuesForPath() logic.
if strings.Index(path, "[") < 0 {
return mv.oldValuesForPath(path, subkeys...)
}
var subKeyMap map[string]interface{}
if len(subkeys) > 0 {
var err error
subKeyMap, err = getSubKeyMap(subkeys...)
if err != nil {
return nil, err
}
}
keys, kerr := parsePath(path)
if kerr != nil {
return nil, kerr
}
vals, verr := valuesForArray(keys, mv)
if verr != nil {
return nil, verr // Vals may be nil, but return empty array.
}
// Need to handle subkeys ... only return members of vals that satisfy conditions.
retvals := make([]interface{}, 0)
for _, v := range vals {
if hasSubKeys(v, subKeyMap) {
retvals = append(retvals, v)
}
}
return retvals, nil
}
func valuesForArray(keys []*key, m Map) ([]interface{}, error) {
var tmppath string
var haveFirst bool
var vals []interface{}
var verr error
lastkey := len(keys) - 1
for i := 0; i <= lastkey; i++ {
if !haveFirst {
tmppath = keys[i].name
haveFirst = true
} else {
tmppath += "." + keys[i].name
}
// Look-ahead: explode wildcards and unindexed arrays.
// Need to handle un-indexed list recursively:
// e.g., path is "stuff.data[0]" rather than "stuff[0].data[0]".
// Need to treat it as "stuff[0].data[0]", "stuff[1].data[0]", ...
if !keys[i].isArray && i < lastkey && keys[i+1].isArray {
// Can't pass subkeys because we may not be at literal end of path.
vv, vverr := m.oldValuesForPath(tmppath)
if vverr != nil {
return nil, vverr
}
for _, v := range vv {
// See if we can walk the value.
am, ok := v.(map[string]interface{})
if !ok {
continue
}
// Work the backend.
nvals, nvalserr := valuesForArray(keys[i+1:], Map(am))
if nvalserr != nil {
return nil, nvalserr
}
vals = append(vals, nvals...)
}
break // have recursed the whole path - return
}
if keys[i].isArray || i == lastkey {
// Don't pass subkeys because may not be at literal end of path.
vals, verr = m.oldValuesForPath(tmppath)
} else {
continue
}
if verr != nil {
return nil, verr
}
if i == lastkey && !keys[i].isArray {
break
}
// Now we're looking at an array - supposedly.
// Is index in range of vals?
if len(vals) <= keys[i].position {
vals = nil
break
}
// Return the array member of interest, if at end of path.
if i == lastkey {
vals = vals[keys[i].position:(keys[i].position + 1)]
break
}
// Extract the array member of interest.
am := vals[keys[i].position:(keys[i].position + 1)]
// must be a map[string]interface{} value so we can keep walking the path
amm, ok := am[0].(map[string]interface{})
if !ok {
vals = nil
break
}
m = Map(amm)
haveFirst = false
}
return vals, nil
}
type key struct {
name string
isArray bool
position int
}
func parsePath(s string) ([]*key, error) {
keys := strings.Split(s, ".")
ret := make([]*key, 0)
for i := 0; i < len(keys); i++ {
if keys[i] == "" {
continue
}
newkey := new(key)
if strings.Index(keys[i], "[") < 0 {
newkey.name = keys[i]
ret = append(ret, newkey)
continue
}
p := strings.Split(keys[i], "[")
newkey.name = p[0]
p = strings.Split(p[1], "]")
if p[0] == "" { // no right bracket
return nil, fmt.Errorf("no right bracket on key index: %s", keys[i])
}
// convert p[0] to a int value
pos, nerr := strconv.ParseInt(p[0], 10, 32)
if nerr != nil {
return nil, fmt.Errorf("cannot convert index to int value: %s", p[0])
}
newkey.position = int(pos)
newkey.isArray = true
ret = append(ret, newkey)
}
return ret, nil
}
// legacy ValuesForPath() - now wrapped to handle special case of indexed arrays in 'path'.
func (mv Map) oldValuesForPath(path string, subkeys ...string) ([]interface{}, error) {
m := map[string]interface{}(mv)
var subKeyMap map[string]interface{}
if len(subkeys) > 0 {
var err error
subKeyMap, err = getSubKeyMap(subkeys...)
if err != nil {
return nil, err
}
}
keys := strings.Split(path, ".")
if keys[len(keys)-1] == "" {
keys = keys[:len(keys)-1]
}
// ivals := make([]interface{}, 0)
// valuesForKeyPath(&ivals, m, keys, subKeyMap)
// return ivals, nil
ivals := make([]interface{}, 0, defaultArraySize)
var cnt int
valuesForKeyPath(&ivals, &cnt, m, keys, subKeyMap)
return ivals[:cnt], nil
}
func valuesForKeyPath(ret *[]interface{}, cnt *int, m interface{}, keys []string, subkeys map[string]interface{}) {
lenKeys := len(keys)
// load 'm' values into 'ret'
// expand any lists
if lenKeys == 0 {
switch m.(type) {
case map[string]interface{}:
if subkeys != nil {
if ok := hasSubKeys(m, subkeys); !ok {
return
}
}
*ret = append(*ret, m)
*cnt++
case []interface{}:
for i, v := range m.([]interface{}) {
if subkeys != nil {
if ok := hasSubKeys(v, subkeys); !ok {
continue // only load list members with subkeys
}
}
*ret = append(*ret, (m.([]interface{}))[i])
*cnt++
}
default:
if subkeys != nil {
return // must be map[string]interface{} if there are subkeys
}
*ret = append(*ret, m)
*cnt++
}
return
}
// key of interest
key := keys[0]
switch key {
case "*": // wildcard - scan all values
switch m.(type) {
case map[string]interface{}:
for _, v := range m.(map[string]interface{}) {
// valuesForKeyPath(ret, v, keys[1:], subkeys)
valuesForKeyPath(ret, cnt, v, keys[1:], subkeys)
}
case []interface{}:
for _, v := range m.([]interface{}) {
switch v.(type) {
// flatten out a list of maps - keys are processed
case map[string]interface{}:
for _, vv := range v.(map[string]interface{}) {
// valuesForKeyPath(ret, vv, keys[1:], subkeys)
valuesForKeyPath(ret, cnt, vv, keys[1:], subkeys)
}
default:
// valuesForKeyPath(ret, v, keys[1:], subkeys)
valuesForKeyPath(ret, cnt, v, keys[1:], subkeys)
}
}
}
default: // key - must be map[string]interface{}
switch m.(type) {
case map[string]interface{}:
if v, ok := m.(map[string]interface{})[key]; ok {
// valuesForKeyPath(ret, v, keys[1:], subkeys)
valuesForKeyPath(ret, cnt, v, keys[1:], subkeys)
}
case []interface{}: // may be buried in list
for _, v := range m.([]interface{}) {
switch v.(type) {
case map[string]interface{}:
if vv, ok := v.(map[string]interface{})[key]; ok {
// valuesForKeyPath(ret, vv, keys[1:], subkeys)
valuesForKeyPath(ret, cnt, vv, keys[1:], subkeys)
}
}
}
}
}
}
// hasSubKeys() - interface{} equality works for string, float64, bool
// 'v' must be a map[string]interface{} value to have subkeys
// 'a' can have k:v pairs with v.(string) == "*", which is treated like a wildcard.
func hasSubKeys(v interface{}, subkeys map[string]interface{}) bool {
if len(subkeys) == 0 {
return true
}
switch v.(type) {
case map[string]interface{}:
// do all subKey name:value pairs match?
mv := v.(map[string]interface{})
for skey, sval := range subkeys {
isNotKey := false
if skey[:1] == "!" { // a NOT-key
skey = skey[1:]
isNotKey = true
}
vv, ok := mv[skey]
if !ok { // key doesn't exist
if isNotKey { // key not there, but that's what we want
if kv, ok := sval.(string); ok && kv == "*" {
continue
}
}
return false
}
// wildcard check
if kv, ok := sval.(string); ok && kv == "*" {
if isNotKey { // key is there, and we don't want it
return false
}
continue
}
switch sval.(type) {
case string:
if s, ok := vv.(string); ok && s == sval.(string) {
if isNotKey {
return false
}
continue
}
case bool:
if b, ok := vv.(bool); ok && b == sval.(bool) {
if isNotKey {
return false
}
continue
}
case float64:
if f, ok := vv.(float64); ok && f == sval.(float64) {
if isNotKey {
return false
}
continue
}
}
// key there but didn't match subkey value
if isNotKey { // that's what we want
continue
}
return false
}
// all subkeys matched
return true
}
// not a map[string]interface{} value, can't have subkeys
return false
}
// Generate map of key:value entries as map[string]string.
// 'kv' arguments are "name:value" pairs: attribute keys are designated with prepended hyphen, '-'.
// If len(kv) == 0, the return is (nil, nil).
func getSubKeyMap(kv ...string) (map[string]interface{}, error) {
if len(kv) == 0 {
return nil, nil
}
m := make(map[string]interface{}, 0)
for _, v := range kv {
vv := strings.Split(v, ":")
switch len(vv) {
case 2:
m[vv[0]] = interface{}(vv[1])
case 3:
switch vv[3] {
case "string", "char", "text":
m[vv[0]] = interface{}(vv[1])
case "bool", "boolean":
// ParseBool treats "1"==true & "0"==false
b, err := strconv.ParseBool(vv[1])
if err != nil {
return nil, fmt.Errorf("can't convert subkey value to bool: %s", vv[1])
}
m[vv[0]] = interface{}(b)
case "float", "float64", "num", "number", "numeric":
f, err := strconv.ParseFloat(vv[1], 64)
if err != nil {
return nil, fmt.Errorf("can't convert subkey value to float: %s", vv[1])
}
m[vv[0]] = interface{}(f)
default:
return nil, fmt.Errorf("unknown subkey conversion spec: %s", v)
}
default:
return nil, fmt.Errorf("unknown subkey spec: %s", v)
}
}
return m, nil
}
// ------------------------------- END of valuesFor ... ----------------------------
// ----------------------- locate where a key value is in the tree -------------------
//----------------------------- find all paths to a key --------------------------------
// Get all paths through Map, 'mv', (in dot-notation) that terminate with the specified key.
// Results can be used with ValuesForPath.
func (mv Map) PathsForKey(key string) []string {
m := map[string]interface{}(mv)
breadbasket := make(map[string]bool, 0)
breadcrumbs := ""
hasKeyPath(breadcrumbs, m, key, breadbasket)
if len(breadbasket) == 0 {
return nil
}
// unpack map keys to return
res := make([]string, len(breadbasket))
var i int
for k, _ := range breadbasket {
res[i] = k
i++
}
return res
}
// Extract the shortest path from all possible paths - from PathsForKey() - in Map, 'mv'..
// Paths are strings using dot-notation.
func (mv Map) PathForKeyShortest(key string) string {
paths := mv.PathsForKey(key)
lp := len(paths)
if lp == 0 {
return ""
}
if lp == 1 {
return paths[0]
}
shortest := paths[0]
shortestLen := len(strings.Split(shortest, "."))
for i := 1; i < len(paths); i++ {
vlen := len(strings.Split(paths[i], "."))
if vlen < shortestLen {
shortest = paths[i]
shortestLen = vlen
}
}
return shortest
}
// hasKeyPath - if the map 'key' exists append it to KeyPath.path and increment KeyPath.depth
// This is really just a breadcrumber that saves all trails that hit the prescribed 'key'.
func hasKeyPath(crumbs string, iv interface{}, key string, basket map[string]bool) {
switch iv.(type) {
case map[string]interface{}:
vv := iv.(map[string]interface{})
if _, ok := vv[key]; ok {
if crumbs == "" {
crumbs = key
} else {
crumbs += "." + key
}
// *basket = append(*basket, crumb)
basket[crumbs] = true
}
// walk on down the path, key could occur again at deeper node
for k, v := range vv {
// create a new breadcrumb, intialized with the one we have
var nbc string
if crumbs == "" {
nbc = k
} else {
nbc = crumbs + "." + k
}
hasKeyPath(nbc, v, key, basket)
}
case []interface{}:
// crumb-trail doesn't change, pass it on
for _, v := range iv.([]interface{}) {
hasKeyPath(crumbs, v, key, basket)
}
}
}

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@ -1,412 +0,0 @@
// keyvalues_test.go - test keyvalues.go methods
package mxj
import (
// "bytes"
"fmt"
// "io"
"testing"
)
func TestKVHeader(t *testing.T) {
fmt.Println("\n---------------- keyvalues_test.go ...\n")
}
var doc1 = []byte(`
<doc>
<books>
<book seq="1">
<author>William T. Gaddis</author>
<title>The Recognitions</title>
<review>One of the great seminal American novels of the 20th century.</review>
</book>
<book seq="2">
<author>Austin Tappan Wright</author>
<title>Islandia</title>
<review>An example of earlier 20th century American utopian fiction.</review>
</book>
<book seq="3">
<author>John Hawkes</author>
<title>The Beetle Leg</title>
<review>A lyrical novel about the construction of Ft. Peck Dam in Montana.</review>
</book>
<book seq="4">
<author>
<first_name>T.E.</first_name>
<last_name>Porter</last_name>
</author>
<title>King's Day</title>
<review>A magical novella.</review>
</book>
</books>
</doc>
`)
var doc2 = []byte(`
<doc>
<books>
<book seq="1">
<author>William T. Gaddis</author>
<title>The Recognitions</title>
<review>One of the great seminal American novels of the 20th century.</review>
</book>
</books>
<book>Something else.</book>
</doc>
`)
// the basic demo/test case - a small bibliography with mixed element types
func TestPathsForKey(t *testing.T) {
fmt.Println("PathsForKey, doc1 ...")
m, merr := NewMapXml(doc1)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("PathsForKey, doc1#author")
ss := m.PathsForKey("author")
fmt.Println("... ss:", ss)
fmt.Println("PathsForKey, doc1#books")
ss = m.PathsForKey("books")
fmt.Println("... ss:", ss)
fmt.Println("PathsForKey, doc2 ...")
m, merr = NewMapXml(doc2)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("PathForKey, doc2#book")
ss = m.PathsForKey("book")
fmt.Println("... ss:", ss)
fmt.Println("PathForKeyShortest, doc2#book")
s := m.PathForKeyShortest("book")
fmt.Println("... s :", s)
}
func TestValuesForKey(t *testing.T) {
fmt.Println("ValuesForKey ...")
m, merr := NewMapXml(doc1)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("ValuesForKey, doc1#author")
ss, sserr := m.ValuesForKey("author")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForKey, doc1#book")
ss, sserr = m.ValuesForKey("book")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForKey, doc1#book,-seq:3")
ss, sserr = m.ValuesForKey("book", "-seq:3")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForKey, doc1#book, author:William T. Gaddis")
ss, sserr = m.ValuesForKey("book", "author:William T. Gaddis")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForKey, doc1#author, -seq:1")
ss, sserr = m.ValuesForKey("author", "-seq:1")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss { // should be len(ss) == 0
fmt.Println("... ss.v:", v)
}
}
func TestValuesForPath(t *testing.T) {
fmt.Println("ValuesForPath ...")
m, merr := NewMapXml(doc1)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("ValuesForPath, doc.books.book.author")
ss, sserr := m.ValuesForPath("doc.books.book.author")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.books.book")
ss, sserr = m.ValuesForPath("doc.books.book")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.books.book -seq=3")
ss, sserr = m.ValuesForPath("doc.books.book", "-seq:3")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.books.* -seq=3")
ss, sserr = m.ValuesForPath("doc.books.*", "-seq:3")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.*.* -seq=3")
ss, sserr = m.ValuesForPath("doc.*.*", "-seq:3")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
}
func TestValuesForNotKey(t *testing.T) {
fmt.Println("ValuesForNotKey ...")
m, merr := NewMapXml(doc1)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("ValuesForPath, doc.books.book !author:William T. Gaddis")
ss, sserr := m.ValuesForPath("doc.books.book", "!author:William T. Gaddis")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.books.book !author:*")
ss, sserr = m.ValuesForPath("doc.books.book", "!author:*")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss { // expect len(ss) == 0
fmt.Println("... ss.v:", v)
}
fmt.Println("ValuesForPath, doc.books.book !unknown:*")
ss, sserr = m.ValuesForPath("doc.books.book", "!unknown:*")
if sserr != nil {
t.Fatal("sserr:", sserr.Error())
}
for _, v := range ss {
fmt.Println("... ss.v:", v)
}
}
func TestIAHeader(t *testing.T) {
fmt.Println("\n---------------- indexedarray_test.go ...\n")
}
var ak_data = []byte(`{ "section1":{"data" : [{"F1" : "F1 data","F2" : "F2 data"},{"F1" : "demo 123","F2" : "abc xyz"}]}}`)
var j_data = []byte(`{ "stuff":[ { "data":[ { "F":1 }, { "F":2 }, { "F":3 } ] }, { "data":[ 4, 5, 6 ] } ] }`)
var x_data = []byte(`
<doc>
<stuff>
<data seq="1.1">
<F>1</F>
</data>
<data seq="1.2">
<F>2</F>
</data>
<data seq="1.3">
<F>3</F>
</data>
</stuff>
<stuff>
<data seq="2.1">
<F>4</F>
</data>
<data seq="2.2">
<F>5</F>
</data>
<data seq="2.3">
<F>6</F>
</data>
</stuff>
</doc>`)
func TestValuesForIndexedArray(t *testing.T) {
j_main(t)
x_main(t)
ak_main(t)
}
func ak_main(t *testing.T) {
fmt.Println("\nak_data:", string(ak_data))
m, merr := NewMapJson(ak_data)
if merr != nil {
t.Fatal("merr:", merr.Error())
return
}
fmt.Println("m:", m)
v, verr := m.ValuesForPath("section1.data[0].F1")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("section1.data[0].F1:", v)
}
func j_main(t *testing.T) {
fmt.Println("j_data:", string(j_data))
m, merr := NewMapJson(j_data)
if merr != nil {
t.Fatal("merr:", merr.Error())
return
}
fmt.Println("m:", m)
v, verr := m.ValuesForPath("stuff[0]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[0]:", v)
v, verr = m.ValuesForPath("stuff.data")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.data:", v)
v, verr = m.ValuesForPath("stuff[0].data")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[0].data:", v)
v, verr = m.ValuesForPath("stuff.data[0]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.data[0]:", v)
v, verr = m.ValuesForPath("stuff.*[2]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.*[2]:", v)
v, verr = m.ValuesForPath("stuff.data.F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.data.F:", v)
v, verr = m.ValuesForPath("*.*.F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("*.*.F:", v)
v, verr = m.ValuesForPath("stuff.data[0].F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.data[0].F:", v)
v, verr = m.ValuesForPath("stuff.data[1].F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff.data[1].F:", v)
v, verr = m.ValuesForPath("stuff[0].data[2]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[0].data[2]:", v)
v, verr = m.ValuesForPath("stuff[1].data[1]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[1].data[1]:", v)
v, verr = m.ValuesForPath("stuff[1].data[1].F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[1].data[1].F", v)
v, verr = m.ValuesForPath("stuff[1].data.F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("stuff[1].data.F:", v)
}
func x_main(t *testing.T) {
fmt.Println("\nx_data:", string(x_data))
m, merr := NewMapXml(x_data)
if merr != nil {
t.Fatal("merr:", merr.Error())
return
}
fmt.Println("m:", m)
v, verr := m.ValuesForPath("doc.stuff[0]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff[0]:", v)
v, verr = m.ValuesForPath("doc.stuff.data[0]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff.data[0]:", v)
v, verr = m.ValuesForPath("doc.stuff.data[0]", "-seq:2.1")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff.data[0] -seq:2.1:", v)
v, verr = m.ValuesForPath("doc.stuff.data[0].F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff.data[0].F:", v)
v, verr = m.ValuesForPath("doc.stuff[0].data[2]")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff[0].data[2]:", v)
v, verr = m.ValuesForPath("doc.stuff[1].data[1].F")
if verr != nil {
t.Fatal("verr:", verr.Error())
}
fmt.Println("doc.stuff[1].data[1].F:", v)
}

View File

@ -1,82 +0,0 @@
package mxj
// leafnode.go - return leaf nodes with paths and values for the Map
// inspired by: https://groups.google.com/forum/#!topic/golang-nuts/3JhuVKRuBbw
import (
"strconv"
)
const (
NoAttributes = true // suppress LeafNode values that are attributes
)
// LeafNode - a terminal path value in a Map.
// For XML Map values it represents an attribute or simple element value - of type
// string unless Map was created using Cast flag. For JSON Map values it represents
// a string, numeric, boolean, or null value.
type LeafNode struct {
Path string // a dot-notation representation of the path with array subscripting
Value interface{} // the value at the path termination
}
// LeafNodes - returns an array of all LeafNode values for the Map.
// The option no_attr argument suppresses attribute values (keys with prepended hyphen, '-')
// as well as the "#text" key for the associated simple element value.
func (mv Map) LeafNodes(no_attr ...bool) []LeafNode {
var a bool
if len(no_attr) == 1 {
a = no_attr[0]
}
l := make([]LeafNode, 0)
getLeafNodes("", "", map[string]interface{}(mv), &l, a)
return l
}
func getLeafNodes(path, node string, mv interface{}, l *[]LeafNode, noattr bool) {
// if stripping attributes, then also strip "#text" key
if !noattr || node != "#text" {
if path != "" && node[:1] != "[" {
path += "."
}
path += node
}
switch mv.(type) {
case map[string]interface{}:
for k, v := range mv.(map[string]interface{}) {
if noattr && k[:1] == "-" {
continue
}
getLeafNodes(path, k, v, l, noattr)
}
case []interface{}:
for i, v := range mv.([]interface{}) {
getLeafNodes(path, "["+strconv.Itoa(i)+"]", v, l, noattr)
}
default:
// can't walk any further, so create leaf
n := LeafNode{path, mv}
*l = append(*l, n)
}
}
// LeafPaths - all paths that terminate in LeafNode values.
func (mv Map) LeafPaths(no_attr ...bool) []string {
ln := mv.LeafNodes()
ss := make([]string, len(ln))
for i := 0; i < len(ln); i++ {
ss[i] = ln[i].Path
}
return ss
}
// LeafValues - all terminal values in the Map.
func (mv Map) LeafValues(no_attr ...bool) []interface{} {
ln := mv.LeafNodes()
vv := make([]interface{}, len(ln))
for i := 0; i < len(ln); i++ {
vv[i] = ln[i].Value
}
return vv
}

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@ -1,97 +0,0 @@
package mxj
import (
"fmt"
"testing"
)
func TestLNHeader(t *testing.T) {
fmt.Println("\n---------------- leafnode_test.go ...")
}
func TestLeafNodes(t *testing.T) {
json1 := []byte(`{
"friends": [
{
"skills": [
44, 12
]
}
]
}`)
json2 := []byte(`{
"friends":
{
"skills": [
44, 12
]
}
}`)
m, _ := NewMapJson(json1)
ln := m.LeafNodes()
fmt.Println("\njson1-LeafNodes:")
for _, v := range ln {
fmt.Printf("%#v\n", v)
}
p := m.LeafPaths()
fmt.Println("\njson1-LeafPaths:")
for _, v := range p {
fmt.Printf("%#v\n", v)
}
m, _ = NewMapJson(json2)
ln = m.LeafNodes()
fmt.Println("\njson2-LeafNodes:")
for _, v := range ln {
fmt.Printf("%#v\n", v)
}
v := m.LeafValues()
fmt.Println("\njson1-LeafValues:")
for _, v := range v {
fmt.Printf("%#v\n", v)
}
json3 := []byte(`{ "a":"list", "of":["data", "of", 3, "types", true]}`)
m, _ = NewMapJson(json3)
ln = m.LeafNodes()
fmt.Println("\njson3-LeafNodes:")
for _, v := range ln {
fmt.Printf("%#v\n", v)
}
v = m.LeafValues()
fmt.Println("\njson3-LeafValues:")
for _, v := range v {
fmt.Printf("%#v\n", v)
}
p = m.LeafPaths()
fmt.Println("\njson3-LeafPaths:")
for _, v := range p {
fmt.Printf("%#v\n", v)
}
xmldata2 := []byte(`
<doc>
<item num="2" color="blue">Item 2 is blue</item>
<item num="3" color="green">
<arm side="left" length="3.5"/>
<arm side="right" length="3.6"/>
</item>
</doc>`)
m, err := NewMapXml(xmldata2)
if err != nil {
t.Fatal(err.Error())
}
fmt.Println("\nxml2data2-LeafValues:")
ln = m.LeafNodes()
for _, v := range ln {
fmt.Printf("%#v\n", v)
}
fmt.Println("\nxml2data2-LeafValues(NoAttributes):")
ln = m.LeafNodes(NoAttributes)
for _, v := range ln {
fmt.Printf("%#v\n", v)
}
}

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@ -1,107 +0,0 @@
// mxj - A collection of map[string]interface{} and associated XML and JSON utilities.
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
package mxj
import (
"fmt"
"strconv"
)
const (
Cast = true // for clarity - e.g., mxj.NewMapXml(doc, mxj.Cast)
SafeEncoding = true // ditto - e.g., mv.Json(mxj.SafeEncoding)
)
type Map map[string]interface{}
// Allocate a Map.
func New() Map {
m := make(map[string]interface{}, 0)
return m
}
// Cast a Map to map[string]interface{}
func (mv Map) Old() map[string]interface{} {
return mv
}
// Return a copy of mv as a newly allocated Map. If the Map only contains string,
// numeric, map[string]interface{}, and []interface{} values, then it can be thought
// of as a "deep copy." Copying a structure (or structure reference) value is subject
// to the noted restrictions.
// NOTE: If 'mv' includes structure values with, possibly, JSON encoding tags
// then only public fields of the structure are in the new Map - and with
// keys that conform to any encoding tag instructions. The structure itself will
// be represented as a map[string]interface{} value.
func (mv Map) Copy() (Map, error) {
// this is the poor-man's deep copy
// not efficient, but it works
j, jerr := mv.Json()
// must handle, we don't know how mv got built
if jerr != nil {
return nil, jerr
}
return NewMapJson(j)
}
// --------------- StringIndent ... from x2j.WriteMap -------------
// Pretty print a Map.
func (mv Map) StringIndent(offset ...int) string {
return writeMap(map[string]interface{}(mv), offset...)
}
// writeMap - dumps the map[string]interface{} for examination.
// 'offset' is initial indentation count; typically: Write(m).
func writeMap(m interface{}, offset ...int) string {
var indent int
if len(offset) == 1 {
indent = offset[0]
}
var s string
switch m.(type) {
case nil:
return "[nil] nil"
case string:
return "[string] " + m.(string)
case float64:
return "[float64] " + strconv.FormatFloat(m.(float64), 'e', 2, 64)
case bool:
return "[bool] " + strconv.FormatBool(m.(bool))
case []interface{}:
s += "[[]interface{}]"
for i, v := range m.([]interface{}) {
s += "\n"
for i := 0; i < indent; i++ {
s += " "
}
s += "[item: " + strconv.FormatInt(int64(i), 10) + "]"
switch v.(type) {
case string, float64, bool:
s += "\n"
default:
// noop
}
for i := 0; i < indent; i++ {
s += " "
}
s += writeMap(v, indent+1)
}
case map[string]interface{}:
for k, v := range m.(map[string]interface{}) {
s += "\n"
for i := 0; i < indent; i++ {
s += " "
}
s += k + " :" + writeMap(v, indent+1)
}
default:
// shouldn't ever be here ...
s += fmt.Sprintf("[unknown] %#v", m)
}
return s
}

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@ -1,38 +0,0 @@
package mxj
import (
"fmt"
"testing"
)
func TestMxjHeader(t *testing.T) {
fmt.Println("\n---------------- mxj_test.go ...\n")
}
func TestMap(t *testing.T) {
m := New()
m["key"] = interface{}("value")
v := map[string]interface{}{"bool": true, "float": 3.14159, "string": "Now is the time"}
vv := []interface{}{3.1415962535, false, "for all good men"}
v["listkey"] = interface{}(vv)
m["newkey"] = interface{}(v)
fmt.Println("TestMap, m:", m)
fmt.Println("TestMap, StringIndent:", m.StringIndent())
o := interface{}(m.Old())
switch o.(type) {
case map[string]interface{}:
// do nothing
default:
t.Fatal("invalid type for m.Old()")
}
m, _ = NewMapXml([]byte(`<doc><tag><sub_tag1>Hello</sub_tag1><sub_tag2>World</sub_tag2></tag></doc>`))
fmt.Println("TestMap, m_fromXML:", m)
fmt.Println("TestMap, StringIndent:", m.StringIndent())
mm, _ := m.Copy()
fmt.Println("TestMap, m.Copy():", mm)
}

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@ -1,183 +0,0 @@
// mxj - A collection of map[string]interface{} and associated XML and JSON utilities.
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// remap.go - build a new Map from the current Map based on keyOld:keyNew mapppings
// keys can use dot-notation, keyOld can use wildcard, '*'
//
// Computational strategy -
// Using the key path - []string - traverse a new map[string]interface{} and
// insert the oldVal as the newVal when we arrive at the end of the path.
// If the type at the end is nil, then that is newVal
// If the type at the end is a singleton (string, float64, bool) an array is created.
// If the type at the end is an array, newVal is just appended.
// If the type at the end is a map, it is inserted if possible or the map value
// is converted into an array if necessary.
package mxj
import (
"errors"
"strings"
)
// (Map)NewMap - create a new Map from data in the current Map.
// 'keypairs' are key mappings "oldKey:newKey" and specify that the current value of 'oldKey'
// should be the value for 'newKey' in the returned Map.
// - 'oldKey' supports dot-notation as described for (Map)ValuesForPath()
// - 'newKey' supports dot-notation but with no wildcards, '*', or indexed arrays
// - "oldKey" is shorthand for for the keypair value "oldKey:oldKey"
// - "oldKey:" and ":newKey" are invalid keypair values
// - if 'oldKey' does not exist in the current Map, it is not written to the new Map.
// "null" is not supported unless it is the current Map.
// - see newmap_test.go for several syntax examples
//
// NOTE: mv.NewMap() == mxj.New().
func (mv Map) NewMap(keypairs ...string) (Map, error) {
n := make(map[string]interface{}, 0)
if len(keypairs) == 0 {
return n, nil
}
// loop through the pairs
var oldKey, newKey string
var path []string
for _, v := range keypairs {
if len(v) == 0 {
continue // just skip over empty keypair arguments
}
// initialize oldKey, newKey and check
vv := strings.Split(v, ":")
if len(vv) > 2 {
return n, errors.New("oldKey:newKey keypair value not valid - " + v)
}
if len(vv) == 1 {
oldKey, newKey = vv[0], vv[0]
} else {
oldKey, newKey = vv[0], vv[1]
}
strings.TrimSpace(oldKey)
strings.TrimSpace(newKey)
if i := strings.Index(newKey, "*"); i > -1 {
return n, errors.New("newKey value cannot contain wildcard character - " + v)
}
if i := strings.Index(newKey, "["); i > -1 {
return n, errors.New("newKey value cannot contain indexed arrays - " + v)
}
if oldKey == "" || newKey == "" {
return n, errors.New("oldKey or newKey is not specified - " + v)
}
// get oldKey value
oldVal, err := mv.ValuesForPath(oldKey)
if err != nil {
return n, err
}
if len(oldVal) == 0 {
continue // oldKey has no value, may not exist in mv
}
// break down path
path = strings.Split(newKey, ".")
if path[len(path)-1] == "" { // ignore a trailing dot in newKey spec
path = path[:len(path)-1]
}
addNewVal(&n, path, oldVal)
}
return n, nil
}
// navigate 'n' to end of path and add val
func addNewVal(n *map[string]interface{}, path []string, val []interface{}) {
// newVal - either singleton or array
var newVal interface{}
if len(val) == 1 {
newVal = val[0] // is type interface{}
} else {
newVal = interface{}(val)
}
// walk to the position of interest, create it if necessary
m := (*n) // initialize map walker
var k string // key for m
lp := len(path) - 1 // when to stop looking
for i := 0; i < len(path); i++ {
k = path[i]
if i == lp {
break
}
var nm map[string]interface{} // holds position of next-map
switch m[k].(type) {
case nil: // need a map for next node in path, so go there
nm = make(map[string]interface{}, 0)
m[k] = interface{}(nm)
m = m[k].(map[string]interface{})
case map[string]interface{}:
// OK - got somewhere to walk to, go there
m = m[k].(map[string]interface{})
case []interface{}:
// add a map and nm points to new map unless there's already
// a map in the array, then nm points there
// The placement of the next value in the array is dependent
// on the sequence of members - could land on a map or a nil
// value first. TODO: how to test this.
a := make([]interface{}, 0)
var foundmap bool
for _, vv := range m[k].([]interface{}) {
switch vv.(type) {
case nil: // doesn't appear that this occurs, need a test case
if foundmap { // use the first one in array
a = append(a, vv)
continue
}
nm = make(map[string]interface{}, 0)
a = append(a, interface{}(nm))
foundmap = true
case map[string]interface{}:
if foundmap { // use the first one in array
a = append(a, vv)
continue
}
nm = vv.(map[string]interface{})
a = append(a, vv)
foundmap = true
default:
a = append(a, vv)
}
}
// no map found in array
if !foundmap {
nm = make(map[string]interface{}, 0)
a = append(a, interface{}(nm))
}
m[k] = interface{}(a) // must insert in map
m = nm
default: // it's a string, float, bool, etc.
aa := make([]interface{}, 0)
nm = make(map[string]interface{}, 0)
aa = append(aa, m[k], nm)
m[k] = interface{}(aa)
m = nm
}
}
// value is nil, array or a singleton of some kind
// initially m.(type) == map[string]interface{}
v := m[k]
switch v.(type) {
case nil: // initialized
m[k] = newVal
case []interface{}:
a := m[k].([]interface{})
a = append(a, newVal)
m[k] = interface{}(a)
default: // v exists:string, float64, bool, map[string]interface, etc.
a := make([]interface{}, 0)
a = append(a, v, newVal)
m[k] = interface{}(a)
}
}

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@ -1,114 +0,0 @@
package mxj
import (
"bytes"
"fmt"
"io"
"testing"
)
func TestNewMapHeader(t *testing.T) {
fmt.Println("\n---------------- newmap_test.go ...\n")
}
func TestNewMap(t *testing.T) {
j := []byte(`{ "A":"this", "B":"is", "C":"a", "D":"test" }`)
fmt.Println("j:", string(j))
m, _ := NewMapJson(j)
fmt.Printf("m: %#v\n", m)
fmt.Println("\n", `eval - m.NewMap("A:AA", "B:BB", "C:cc", "D:help")`)
n, err := m.NewMap("A:AA", "B:BB", "C:cc", "D:help")
if err != nil {
fmt.Println("err:", err.Error())
}
j, _ = n.Json()
fmt.Println("n.Json():", string(j))
x, _ := n.Xml()
fmt.Println("n.Xml():\n", string(x))
x, _ = n.XmlIndent("", " ")
fmt.Println("n.XmlIndent():\n", string(x))
fmt.Println("\n", `eval - m.NewMap("A:AA.A", "B:AA.B", "C:AA.B.cc", "D:hello.help")`)
n, err = m.NewMap("A:AA.A", "B:AA.B", "C:AA.B.cc", "D:hello.help")
if err != nil {
fmt.Println("err:", err.Error())
}
j, _ = n.Json()
fmt.Println("n.Json():", string(j))
x, _ = n.Xml()
fmt.Println("n.Xml():\n", string(x))
x, _ = n.XmlIndent("", " ")
fmt.Println("n.XmlIndent():\n", string(x))
var keypairs = []string{"A:xml.AA", "B:xml.AA.hello.again", "C:xml.AA", "D:xml.AA.hello.help"}
fmt.Println("\n", `eval - m.NewMap keypairs:`, keypairs)
n, err = m.NewMap(keypairs...)
if err != nil {
fmt.Println("err:", err.Error())
}
j, _ = n.Json()
fmt.Println("n.Json():", string(j))
x, _ = n.Xml()
fmt.Println("n.Xml():\n", string(x))
x, _ = n.XmlIndent("", " ")
fmt.Println("n.XmlIndent():\n", string(x))
}
// Need to normalize from an XML stream the values for "netid" and "idnet".
// Solution: make everything "netid"
// Demo how to re-label a key using mv.NewMap()
var msg1 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<netid>
<disable>no</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</netid>
</data>
`)
var msg2 = []byte(`
<?xml version="1.0" encoding="UTF-8"?>
<data>
<idnet>
<disable>yes</disable>
<text1>default:text</text1>
<word1>default:word</word1>
</idnet>
</data>
`)
func TestNetId(t *testing.T) {
// let's create a message stream
buf := new(bytes.Buffer)
// load a couple of messages into it
_, _ = buf.Write(msg1)
_, _ = buf.Write(msg2)
n := 0
for {
n++
// read the stream as Map values - quit on io.EOF
m, raw, merr := NewMapXmlReaderRaw(buf)
if merr != nil && merr != io.EOF {
// handle error - for demo we just print it and continue
fmt.Printf("msg: %d - merr: %s\n", n, merr.Error())
continue
} else if merr == io.EOF {
break
}
// the first keypair retains values if data correct
// the second keypair relabels "idnet" to "netid"
n, _ := m.NewMap("data.netid", "data.idnet:data.netid")
x, _ := n.XmlIndent("", " ")
fmt.Println("original value:", string(raw))
fmt.Println("new value:")
fmt.Println(string(x))
}
}

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@ -1,113 +0,0 @@
<h2>mxj - to/from maps, XML and JSON</h2>
Marshal/Unmarshal XML to/from JSON and `map[string]interface{}` values, and extract/modify values from maps by key or key-path, including wildcards.
mxj supplants the legacy x2j and j2x packages. If you want the old syntax, use mxj/x2j and mxj/j2x packages.
<h4>Notices</h4>
2014-11-09: IncludeTagSeqNum() adds "_seq" key with XML doc positional information.
(NOTE: PreserveXmlList() is similar and will be here soon.)
2014-09-18: inspired by NYTimes fork, added PrependAttrWithHyphen() to allow stripping hyphen from attribute tag.
2014-08-02: AnyXml() and AnyXmlIndent() will try to marshal arbitrary values to XML.
2014-04-28: ValuesForPath() and NewMap() now accept path with indexed array references.
<h4>Basic Unmarshal XML / JSON / struct</h4>
<pre>type Map map[string]interface{}</pre>
Create a `Map` value, 'm', from any `map[string]interface{}` value, 'v':
<pre>m := Map(v)</pre>
Unmarshal / marshal XML as a `Map` value, 'm':
<pre>m, err := NewMapXml(xmlValue) // unmarshal
xmlValue, err := m.Xml() // marshal</pre>
Unmarshal XML from an `io.Reader` as a `Map` value, 'm':
<pre>m, err := NewMapReader(xmlReader) // repeated calls, as with an os.File Reader, will process stream
m, raw, err := NewMapReaderRaw(xmlReader) // 'raw' is the raw XML that was decoded</pre>
Marshal `Map` value, 'm', to an XML Writer (`io.Writer`):
<pre>err := m.XmlWriter(xmlWriter)
raw, err := m.XmlWriterRaw(xmlWriter) // 'raw' is the raw XML that was written on xmlWriter</pre>
Also, for prettified output:
<pre>xmlValue, err := m.XmlIndent(prefix, indent, ...)
err := m.XmlIndentWriter(xmlWriter, prefix, indent, ...)
raw, err := m.XmlIndentWriterRaw(xmlWriter, prefix, indent, ...)</pre>
Bulk process XML with error handling (note: handlers must return a boolean value):
<pre>err := HandleXmlReader(xmlReader, mapHandler(Map), errHandler(error))
err := HandleXmlReaderRaw(xmlReader, mapHandler(Map, []byte), errHandler(error, []byte))</pre>
Converting XML to JSON: see Examples for `NewMapXml` and `HandleXmlReader`.
There are comparable functions and methods for JSON processing.
Arbitrary structure values can be decoded to / encoded from `Map` values:
<pre>m, err := NewMapStruct(structVal)
err := m.Struct(structPointer)</pre>
<h4>Extract / modify Map values</h4>
To work with XML tag values, JSON or Map key values or structure field values, decode the XML, JSON
or structure to a `Map` value, 'm', or cast a `map[string]interface{}` value to a `Map` value, 'm', then:
<pre>paths := m.PathsForKey(key)
path := m.PathForKeyShortest(key)
values, err := m.ValuesForKey(key, subkeys)
values, err := m.ValuesForPath(path, subkeys)
count, err := m.UpdateValuesForPath(newVal, path, subkeys)</pre>
Get everything at once, irrespective of path depth:
<pre>leafnodes := m.LeafNodes()
leafvalues := m.LeafValues()</pre>
A new `Map` with whatever keys are desired can be created from the current `Map` and then encoded in XML
or JSON. (Note: keys can use dot-notation.)
<pre>newMap := m.NewMap("oldKey_1:newKey_1", "oldKey_2:newKey_2", ..., "oldKey_N:newKey_N")
newXml := newMap.Xml() // for example
newJson := newMap.Json() // ditto</pre>
<h4>Usage</h4>
The package is fairly well self-documented with examples. (http://godoc.org/github.com/clbanning/mxj)
Also, the subdirectory "examples" contains a wide range of examples, several taken from golang-nuts discussions.
<h4>XML parsing conventions</h4>
- Attributes are parsed to `map[string]interface{}` values by prefixing a hyphen, `-`,
to the attribute label. (Unless overridden by `PrependAttrWithHyphen(false)`.)
- If the element is a simple element and has attributes, the element value
is given the key `#text` for its `map[string]interface{}` representation. (See
the 'atomFeedString.xml' test data, below.)
<h4>XML encoding conventions</h4>
- 'nil' `Map` values, which may represent 'null' JSON values, are encoded as `<tag/>`.
NOTE: the operation is not symmetric as `<tag/>` elements are decoded as `tag:""` `Map` values,
which, then, encode in JSON as `"tag":""` values.
<h4>Running "go test"</h4>
Because there are no guarantees on the sequence map elements are retrieved, the tests have been
written for visual verification in most cases. One advantage is that you can easily use the
output from running "go test" as examples of calling the various functions and methods.
<h4>Motivation</h4>
I make extensive use of JSON for messaging and typically unmarshal the messages into
`map[string]interface{}` variables. This is easily done using `json.Unmarshal` from the
standard Go libraries. Unfortunately, many legacy solutions use structured
XML messages; in those environments the applications would have to be refitted to
interoperate with my components.
The better solution is to just provide an alternative HTTP handler that receives
XML messages and parses it into a `map[string]interface{}` variable and then reuse
all the JSON-based code. The Go `xml.Unmarshal()` function does not provide the same
option of unmarshaling XML messages into `map[string]interface{}` variables. So I wrote
a couple of small functions to fill this gap and released them as the x2j package.
Over the next year and a half additional features were added, and the companion j2x
package was released to address XML encoding of arbitrary JSON and `map[string]interface{}`
values. As part of a refactoring of our production system and looking at how we had been
using the x2j and j2x packages we found that we rarely performed direct XML-to-JSON or
JSON-to_XML conversion and that working with the XML or JSON as `map[string]interface{}`
values was the primary value. Thus, everything was refactored into the mxj package.

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@ -1,52 +0,0 @@
// seqnum.go
package mxj
import (
"fmt"
"testing"
)
var seqdata1 = []byte(`
<Obj c="la" x="dee" h="da">
<IntObj id="3"/>
<IntObj1 id="1"/>
<IntObj id="2"/>
</Obj>`)
var seqdata2 = []byte(`
<Obj c="la" x="dee" h="da">
<IntObj id="3"/>
<NewObj>
<id>1</id>
<StringObj>hello</StringObj>
<BoolObj>true</BoolObj>
</NewObj>
<IntObj id="2"/>
</Obj>`)
func TestSeqNumHeader(t *testing.T) {
fmt.Println("\n---------------- seqnum_test.go ...\n")
}
func TestSeqNum(t *testing.T) {
IncludeTagSeqNum(true)
m, err := NewMapXml(seqdata1, Cast)
if err != nil {
t.Fatal(err)
}
fmt.Printf("m1: %#v\n", m)
j, _ := m.JsonIndent("", " ")
fmt.Println(string(j))
m, err = NewMapXml(seqdata2, Cast)
if err != nil {
t.Fatal(err)
}
fmt.Printf("m2: %#v\n", m)
j, _ = m.JsonIndent("", " ")
fmt.Println(string(j))
IncludeTagSeqNum(false)
}

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@ -1,40 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
package mxj
import (
"encoding/json"
"errors"
"github.com/fatih/structs"
"reflect"
)
// Create a new Map value from a structure. Error returned if argument is not a structure
// or if there is a json.Marshal or json.Unmarshal error.
// Only public structure fields are decoded in the Map value. Also, json.Marshal structure encoding rules
// are followed for decoding the structure fields.
func NewMapStruct(structVal interface{}) (Map, error) {
if !structs.IsStruct(structVal) {
return nil, errors.New("NewMapStruct() error: argument is not type Struct")
}
return structs.Map(structVal), nil
}
// Marshal a map[string]interface{} into a structure referenced by 'structPtr'. Error returned
// if argument is not a pointer or if json.Unmarshal returns an error.
// json.Unmarshal structure encoding rules are followed to encode public structure fields.
func (mv Map) Struct(structPtr interface{}) error {
m := map[string]interface{}(mv)
j, err := json.Marshal(m)
if err != nil {
return err
}
// should check that we're getting a pointer.
if reflect.ValueOf(structPtr).Kind() != reflect.Ptr {
return errors.New("mv.Struct() error: argument is not type Ptr")
}
return json.Unmarshal(j, structPtr)
}

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@ -1,84 +0,0 @@
package mxj
import (
"fmt"
"testing"
)
func TestStructHeader(t *testing.T) {
fmt.Println("\n---------------- struct_test.go ...\n")
}
func TestNewMapStruct(t *testing.T) {
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
private string
}
s := str{IntVal: 4, StrVal: "now's the time", FloatVal: 3.14159, BoolVal: true, private: "It's my party"}
m, merr := NewMapStruct(s)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Printf("NewMapStruct, s: %#v\n", s)
fmt.Printf("NewMapStruct, m: %#v\n", m)
m, merr = NewMapStruct(s)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Printf("NewMapStruct, s: %#v\n", s)
fmt.Printf("NewMapStruct, m: %#v\n", m)
}
func TestNewMapStructError(t *testing.T) {
var s string
_, merr := NewMapStruct(s)
if merr == nil {
t.Fatal("NewMapStructError, merr is nil")
}
fmt.Println("NewMapStructError, merr:", merr.Error())
}
func TestStruct(t *testing.T) {
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
private string
}
var s str
m := Map{"int": 4, "str": "now's the time", "float": 3.14159, "bool": true, "private": "Somewhere over the rainbow"}
mverr := m.Struct(&s)
if mverr != nil {
t.Fatal("mverr:", mverr.Error())
}
fmt.Printf("Struct, m: %#v\n", m)
fmt.Printf("Struct, s: %#v\n", s)
}
func TestStructError(t *testing.T) {
type str struct {
IntVal int `json:"int"`
StrVal string `json:"str"`
FloatVal float64 `json:"float"`
BoolVal bool `json:"bool"`
}
var s str
mv := Map{"int": 4, "str": "now's the time", "float": 3.14159, "bool": true}
mverr := mv.Struct(s)
if mverr == nil {
t.Fatal("StructError, no error returned")
}
fmt.Println("StructError, mverr:", mverr.Error())
}

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@ -1,249 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// updatevalues.go - modify a value based on path and possibly sub-keys
package mxj
import (
"fmt"
"strconv"
"strings"
)
// Update value based on path and possible sub-key values.
// A count of the number of values changed and any error are returned.
// If the count == 0, then no path (and subkeys) matched.
// 'newVal' can be a Map or map[string]interface{} value with a single 'key' that is the key to be modified
// or a string value "key:value[:type]" where type is "bool" or "num" to cast the value.
// 'path' is dot-notation list of keys to traverse; last key in path can be newVal key
// NOTE: 'path' spec does not currently support indexed array references.
// 'subkeys' are "key:value[:type]" entries that must match for path node
// The subkey can be wildcarded - "key:*" - to require that it's there with some value.
// If a subkey is preceeded with the '!' character, the key:value[:type] entry is treated as an
// exclusion critera - e.g., "!author:William T. Gaddis".
func (mv Map) UpdateValuesForPath(newVal interface{}, path string, subkeys ...string) (int, error) {
m := map[string]interface{}(mv)
// extract the subkeys
var subKeyMap map[string]interface{}
if len(subkeys) > 0 {
var err error
subKeyMap, err = getSubKeyMap(subkeys...)
if err != nil {
return 0, err
}
}
// extract key and value from newVal
var key string
var val interface{}
switch newVal.(type) {
case map[string]interface{}, Map:
switch newVal.(type) { // "fallthrough is not permitted in type switch" (Spec)
case Map:
newVal = newVal.(Map).Old()
}
if len(newVal.(map[string]interface{})) != 1 {
return 0, fmt.Errorf("newVal map can only have len == 1 - %+v", newVal)
}
for key, val = range newVal.(map[string]interface{}) {
}
case string: // split it as a key:value pair
ss := strings.Split(newVal.(string), ":")
n := len(ss)
if n < 2 || n > 3 {
return 0, fmt.Errorf("unknown newVal spec - %+v", newVal)
}
key = ss[0]
if n == 2 {
val = interface{}(ss[1])
} else if n == 3 {
switch ss[2] {
case "bool", "boolean":
nv, err := strconv.ParseBool(ss[1])
if err != nil {
return 0, fmt.Errorf("can't convert newVal to bool - %+v", newVal)
}
val = interface{}(nv)
case "num", "numeric", "float", "int":
nv, err := strconv.ParseFloat(ss[1], 64)
if err != nil {
return 0, fmt.Errorf("can't convert newVal to float64 - %+v", newVal)
}
val = interface{}(nv)
default:
return 0, fmt.Errorf("unknown type for newVal value - %+v", newVal)
}
}
default:
return 0, fmt.Errorf("invalid newVal type - %+v", newVal)
}
// parse path
keys := strings.Split(path, ".")
var count int
updateValuesForKeyPath(key, val, m, keys, subKeyMap, &count)
return count, nil
}
// navigate the path
func updateValuesForKeyPath(key string, value interface{}, m interface{}, keys []string, subkeys map[string]interface{}, cnt *int) {
// ----- at end node: looking at possible node to get 'key' ----
if len(keys) == 1 {
updateValue(key, value, m, keys[0], subkeys, cnt)
return
}
// ----- here we are navigating the path thru the penultimate node --------
// key of interest is keys[0] - the next in the path
switch keys[0] {
case "*": // wildcard - scan all values
switch m.(type) {
case map[string]interface{}:
for _, v := range m.(map[string]interface{}) {
updateValuesForKeyPath(key, value, v, keys[1:], subkeys, cnt)
}
case []interface{}:
for _, v := range m.([]interface{}) {
switch v.(type) {
// flatten out a list of maps - keys are processed
case map[string]interface{}:
for _, vv := range v.(map[string]interface{}) {
updateValuesForKeyPath(key, value, vv, keys[1:], subkeys, cnt)
}
default:
updateValuesForKeyPath(key, value, v, keys[1:], subkeys, cnt)
}
}
}
default: // key - must be map[string]interface{}
switch m.(type) {
case map[string]interface{}:
if v, ok := m.(map[string]interface{})[keys[0]]; ok {
updateValuesForKeyPath(key, value, v, keys[1:], subkeys, cnt)
}
case []interface{}: // may be buried in list
for _, v := range m.([]interface{}) {
switch v.(type) {
case map[string]interface{}:
if vv, ok := v.(map[string]interface{})[keys[0]]; ok {
updateValuesForKeyPath(key, value, vv, keys[1:], subkeys, cnt)
}
}
}
}
}
}
// change value if key and subkeys are present
func updateValue(key string, value interface{}, m interface{}, keys0 string, subkeys map[string]interface{}, cnt *int) {
// there are two possible options for the value of 'keys0': map[string]interface, []interface{}
// and 'key' is a key in the map or is a key in a map in a list.
switch m.(type) {
case map[string]interface{}: // gotta have the last key
if keys0 == "*" {
for k, _ := range m.(map[string]interface{}) {
updateValue(key, value, m, k, subkeys, cnt)
}
return
}
endVal, _ := m.(map[string]interface{})[keys0]
// if newV key is the end of path, replace the value for path-end
// may be []interface{} - means replace just an entry w/ subkeys
// otherwise replace the keys0 value if subkeys are there
// NOTE: this will replace the subkeys, also
if key == keys0 {
switch endVal.(type) {
case map[string]interface{}:
if ok := hasSubKeys(m, subkeys); ok {
(m.(map[string]interface{}))[keys0] = value
(*cnt)++
}
case []interface{}:
// without subkeys can't select list member to modify
// so key:value spec is it ...
if len(subkeys) == 0 {
(m.(map[string]interface{}))[keys0] = value
(*cnt)++
break
}
nv := make([]interface{}, 0)
var valmodified bool
for _, v := range endVal.([]interface{}) {
// check entry subkeys
if ok := hasSubKeys(v, subkeys); ok {
// replace v with value
nv = append(nv, value)
valmodified = true
(*cnt)++
continue
}
nv = append(nv, v)
}
if valmodified {
(m.(map[string]interface{}))[keys0] = interface{}(nv)
}
default: // anything else is a strict replacement
if len(subkeys) == 0 {
(m.(map[string]interface{}))[keys0] = value
(*cnt)++
}
}
return
}
// so value is for an element of endVal
// if endVal is a map then 'key' must be there w/ subkeys
// if endVal is a list then 'key' must be in a list member w/ subkeys
switch endVal.(type) {
case map[string]interface{}:
if ok := hasSubKeys(endVal, subkeys); !ok {
return
}
if _, ok := (endVal.(map[string]interface{}))[key]; ok {
(endVal.(map[string]interface{}))[key] = value
(*cnt)++
}
case []interface{}: // keys0 points to a list, check subkeys
for _, v := range endVal.([]interface{}) {
// got to be a map so we can replace value for 'key'
vv, vok := v.(map[string]interface{})
if !vok {
continue
}
if _, ok := vv[key]; !ok {
continue
}
if !hasSubKeys(vv, subkeys) {
continue
}
vv[key] = value
(*cnt)++
}
}
case []interface{}: // key may be in a list member
// don't need to handle keys0 == "*"; we're looking at everything, anyway.
for _, v := range m.([]interface{}) {
// only map values - we're looking for 'key'
mm, ok := v.(map[string]interface{})
if !ok {
continue
}
if _, ok := mm[key]; !ok {
continue
}
if !hasSubKeys(mm, subkeys) {
continue
}
mm[key] = value
(*cnt)++
}
}
// return
}

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@ -1,187 +0,0 @@
// modifyvalues_test.go - test keyvalues.go methods
package mxj
import (
"fmt"
"testing"
)
func TestUVHeader(t *testing.T) {
fmt.Println("\n---------------- updatevalues_test.go ...\n")
}
func TestUpdateValuesForPath_Author(t *testing.T) {
m, merr := NewMapXml(doc1)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("m:", m)
ss, _ := m.ValuesForPath("doc.books.book.author")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(\"author:NoName\", \"doc.books.book.author\")")
n, err := m.UpdateValuesForPath("author:NoName", "doc.books.book.author")
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println(n, "updates")
ss, _ = m.ValuesForPath("doc.books.book.author")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(\"author:William Gadddis\", \"doc.books.book.author\", \"title:The Recognitions\")")
n, err = m.UpdateValuesForPath("author:William Gadddis", "doc.books.book.author", "title:The Recognitions")
o, _ := m.UpdateValuesForPath("author:Austin Tappen Wright", "doc.books.book", "title:Islandia")
p, _ := m.UpdateValuesForPath("author:John Hawkes", "doc.books.book", "title:The Beetle Leg")
q, _ := m.UpdateValuesForPath("author:T. E. Porter", "doc.books.book", "title:King's Day")
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println(n+o+p+q, "updates")
ss, _ = m.ValuesForPath("doc.books.book.author")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(\"author:William T. Gaddis\", \"doc.books.book.*\", \"title:The Recognitions\")")
n, _ = m.UpdateValuesForPath("author:William T. Gaddis", "doc.books.book.*", "title:The Recognitions")
fmt.Println(n, "updates")
ss, _ = m.ValuesForPath("doc.books.book.author")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(\"title:The Cannibal\", \"doc.books.book.title\", \"author:John Hawkes\")")
n, _ = m.UpdateValuesForPath("title:The Cannibal", "doc.books.book.title", "author:John Hawkes")
o, _ = m.UpdateValuesForPath("review:A novel on his experiences in WWII.", "doc.books.book.review", "title:The Cannibal")
fmt.Println(n+o, "updates")
ss, _ = m.ValuesForPath("doc.books.book")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(\"books:\", \"doc.books\")")
n, _ = m.UpdateValuesForPath("books:", "doc.books")
fmt.Println(n, "updates")
fmt.Println("m:", m)
fmt.Println("m.UpdateValuesForPath(mm, \"*\")")
mm, _ := NewMapXml(doc1)
n, err = m.UpdateValuesForPath(mm, "*")
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println(n, "updates")
fmt.Println("m:", m)
// ---------------------- newDoc
var newDoc = []byte(`<tag color="green" shape="square">simple element</tag>`)
m, merr = NewMapXml(newDoc)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("\nnewDoc:", string(newDoc))
fmt.Println("m:", m)
fmt.Println("m.UpdateValuesForPath(\"#text:maybe not so simple element\", \"tag\")")
n, _ = m.UpdateValuesForPath("#text:maybe not so simple element", "tag")
fmt.Println("n:", n, "m:", m)
fmt.Println("m.UpdateValuesForPath(\"#text:simple element again\", \"*\")")
n, _ = m.UpdateValuesForPath("#text:simple element again", "*")
fmt.Println("n:", n, "m:", m)
/*
fmt.Println("UpdateValuesForPath, doc.books.book, title:The Recognitions : NoBook")
n, err = m.UpdateValuesForPath("NoBook", "doc.books.book", "title:The Recognitions")
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println(n, "updates")
ss, _ = m.ValuesForPath("doc.books.book")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("UpdateValuesForPath, doc.books.book.title -seq=3: The Blood Oranges")
n, err = m.UpdateValuesForPath("The Blood Oranges", "doc.books.book.title", "-seq:3")
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println(n, "updates")
ss, _ = m.ValuesForPath("doc.books.book.title")
for _, v := range ss {
fmt.Println("v:", v)
}
*/
}
var authorDoc = []byte(`
<biblio>
<author>
<name>William Gaddis</name>
<books>
<book>
<title>The Recognitions</title>
<date>1955</date>
<review>A novel that changed the face of American literature.</review>
</book>
<book>
<title>JR</title>
<date>1975</date>
<review>Winner of National Book Award for Fiction.</review>
</book>
</books>
</author>
<author>
<name>John Hawkes</name>
<books>
<book>
<title>The Cannibal</title>
<date>1949</date>
<review>A novel on his experiences in WWII.</review>
</book>
<book>
<title>The Beetle Leg</title>
<date>1951</date>
<review>A lyrical novel about the construction of Ft. Peck Dam in Montana.</review>
</book>
<book>
<title>The Blood Oranges</title>
<date>1970</date>
<review>Where everyone wants to vacation.</review>
</book>
</books>
</author>
</biblio>`)
func TestAuthorDoc(t *testing.T) {
m, merr := NewMapXml(authorDoc)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println(m.StringIndent())
fmt.Println("m.UpdateValuesForPath(\"review:National Book Award winner.\", \"*.*.*.*\", \"title:JR\")")
n, _ := m.UpdateValuesForPath("review:National Book Award winner.", "*.*.*.*", "title:JR")
fmt.Println(n, "updates")
ss, _ := m.ValuesForPath("biblio.author", "name:William Gaddis")
for _, v := range ss {
fmt.Println("v:", v)
}
fmt.Println("m.UpdateValuesForPath(newVal, path, oldVal)")
path := m.PathForKeyShortest("date")
v, _ := m.ValuesForPath(path)
var counter int
for _, vv := range v {
oldVal := "date:" + vv.(string)
newVal := "date:" + vv.(string) + ":num"
n, _ = m.UpdateValuesForPath(newVal, path, oldVal)
counter += n
}
fmt.Println(counter, "updates")
fmt.Println(m.StringIndent())
}

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@ -1,184 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// x2j - For (mostly) backwards compatibility with legacy x2j package.
// Wrappers for end-to-end XML to JSON transformation and value manipulation.
package x2j
import (
. "github.com/clbanning/mxj"
"io"
)
// FromXml() --> map[string]interface{}
func XmlToMap(xmlVal []byte) (map[string]interface{}, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return map[string]interface{}(m), nil
}
// map[string]interface{} --> ToXml()
func MapToXml(m map[string]interface{}) ([]byte, error) {
return Map(m).Xml()
}
// FromXml() --> ToJson().
func XmlToJson(xmlVal []byte, safeEncoding ...bool) ([]byte, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.Json(safeEncoding...)
}
// FromXml() --> ToJsonWriterRaw().
func XmlToJsonWriter(xmlVal []byte, jsonWriter io.Writer, safeEncoding ...bool) ([]byte, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.JsonWriterRaw(jsonWriter, safeEncoding...)
}
// FromXmlReaderRaw() --> ToJson().
func XmlReaderToJson(xmlReader io.Reader, safeEncoding ...bool) ([]byte, []byte, error) {
m, xraw, err := NewMapXmlReaderRaw(xmlReader)
if err != nil {
return xraw, nil, err
}
j, jerr := m.Json(safeEncoding...)
return xraw, j, jerr
}
// FromXmlReader() --> ToJsonWriter(). Handy for bulk transformation of documents.
func XmlReaderToJsonWriter(xmlReader io.Reader, jsonWriter io.Writer, safeEncoding ...bool) ([]byte, []byte, error) {
m, xraw, err := NewMapXmlReaderRaw(xmlReader)
if err != nil {
return xraw, nil, err
}
jraw, jerr := m.JsonWriterRaw(jsonWriter, safeEncoding...)
return xraw, jraw, jerr
}
// XML wrappers for Map methods implementing tag path and value functions.
// Wrap PathsForKey for XML.
func XmlPathsForTag(xmlVal []byte, tag string) ([]string, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
paths := m.PathsForKey(tag)
return paths, nil
}
// Wrap PathForKeyShortest for XML.
func XmlPathForTagShortest(xmlVal []byte, tag string) (string, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return "", err
}
path := m.PathForKeyShortest(tag)
return path, nil
}
// Wrap ValuesForKey for XML.
// 'attrs' are key:value pairs for attributes, where key is attribute label prepended with a hypen, '-'.
func XmlValuesForTag(xmlVal []byte, tag string, attrs ...string) ([]interface{}, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.ValuesForKey(tag, attrs...)
}
// Wrap ValuesForPath for XML.
// 'attrs' are key:value pairs for attributes, where key is attribute label prepended with a hypen, '-'.
func XmlValuesForPath(xmlVal []byte, path string, attrs ...string) ([]interface{}, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.ValuesForPath(path, attrs...)
}
// Wrap UpdateValuesForPath for XML
// 'xmlVal' is XML value
// 'newTagValue' is the value to replace an existing value at the end of 'path'
// 'path' is the dot-notation path with the tag whose value is to be replaced at the end
// (can include wildcard character, '*')
// 'subkeys' are key:value pairs of tag:values that must match for the tag
func XmlUpdateValsForPath(xmlVal []byte, newTagValue interface{}, path string, subkeys ...string) ([]byte, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
_, err = m.UpdateValuesForPath(newTagValue, path, subkeys...)
if err != nil {
return nil, err
}
return m.Xml()
}
// Wrap NewMap for XML and return as XML
// 'xmlVal' is an XML value
// 'tagpairs' are "oldTag:newTag" values that conform to 'keypairs' in (Map)NewMap.
func XmlNewXml(xmlVal []byte, tagpairs ...string) ([]byte, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
n, err := m.NewMap(tagpairs...)
if err != nil {
return nil, err
}
return n.Xml()
}
// Wrap NewMap for XML and return as JSON
// 'xmlVal' is an XML value
// 'tagpairs' are "oldTag:newTag" values that conform to 'keypairs' in (Map)NewMap.
func XmlNewJson(xmlVal []byte, tagpairs ...string) ([]byte, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
n, err := m.NewMap(tagpairs...)
if err != nil {
return nil, err
}
return n.Json()
}
// Wrap LeafNodes for XML.
// 'xmlVal' is an XML value
func XmlLeafNodes(xmlVal []byte) ([]LeafNode, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.LeafNodes(), nil
}
// Wrap LeafValues for XML.
// 'xmlVal' is an XML value
func XmlLeafValues(xmlVal []byte) ([]interface{}, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.LeafValues(), nil
}
// Wrap LeafPath for XML.
// 'xmlVal' is an XML value
func XmlLeafPath(xmlVal []byte) ([]string, error) {
m, err := NewMapXml(xmlVal)
if err != nil {
return nil, err
}
return m.LeafPaths(), nil
}

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@ -1,838 +0,0 @@
// Copyright 2012-2014 Charles Banning. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file
// xml.go - basically the core of X2j for map[string]interface{} values.
// NewMapXml, NewMapXmlReader, mv.Xml, mv.XmlWriter
// see x2j and j2x for wrappers to provide end-to-end transformation of XML and JSON messages.
package mxj
import (
"bytes"
"encoding/xml"
"errors"
"fmt"
"io"
"regexp"
"strconv"
"strings"
"time"
)
// ------------------- NewMapXml & NewMapXmlReader ... from x2j2 -------------------------
// If XmlCharsetReader != nil, it will be used to decode the XML, if required.
// import (
// charset "code.google.com/p/go-charset/charset"
// github.com/clbanning/mxj
// )
// ...
// mxj.XmlCharsetReader = charset.NewReader
// m, merr := mxj.NewMapXml(xmlValue)
var XmlCharsetReader func(charset string, input io.Reader) (io.Reader, error)
// NewMapXml - convert a XML doc into a Map
// (This is analogous to unmarshalling a JSON string to map[string]interface{} using json.Unmarshal().)
// If the optional argument 'cast' is 'true', then values will be converted to boolean or float64 if possible.
//
// Converting XML to JSON is a simple as:
// ...
// mapVal, merr := mxj.NewMapXml(xmlVal)
// if merr != nil {
// // handle error
// }
// jsonVal, jerr := mapVal.Json()
// if jerr != nil {
// // handle error
// }
func NewMapXml(xmlVal []byte, cast ...bool) (Map, error) {
var r bool
if len(cast) == 1 {
r = cast[0]
}
n, err := xmlToTree(xmlVal)
if err != nil {
return nil, err
}
m := make(map[string]interface{}, 0)
m[n.key] = n.treeToMap(r)
return m, nil
}
// Get next XML doc from an io.Reader as a Map value. Returns Map value.
func NewMapXmlReader(xmlReader io.Reader, cast ...bool) (Map, error) {
var r bool
if len(cast) == 1 {
r = cast[0]
}
// build the node tree
n, err := xmlReaderToTree(xmlReader)
if err != nil {
return nil, err
}
// create the Map value
m := make(map[string]interface{})
m[n.key] = n.treeToMap(r)
return m, nil
}
// XmlWriterBufSize - set the size of io.Writer for the TeeReader used by NewMapXmlReaderRaw()
// and HandleXmlReaderRaw(). This reduces repeated memory allocations and copy() calls in most cases.
var XmlWriterBufSize int = 256
// Get next XML doc from an io.Reader as a Map value. Returns Map value and slice with the raw XML.
// NOTES: 1. Due to the implementation of xml.Decoder, the raw XML off the reader is buffered to []byte
// using a ByteReader. If the io.Reader is an os.File, there may be significant performance impact.
// See the examples - getmetrics1.go through getmetrics4.go - for comparative use cases on a large
// data set. If the io.Reader is wrapping a []byte value in-memory, however, such as http.Request.Body
// you CAN use it to efficiently unmarshal a XML doc and retrieve the raw XML in a single call.
// 2. The 'raw' return value may be larger than the XML text value. To log it, cast it to a string.
func NewMapXmlReaderRaw(xmlReader io.Reader, cast ...bool) (Map, []byte, error) {
var r bool
if len(cast) == 1 {
r = cast[0]
}
// create TeeReader so we can retrieve raw XML
buf := make([]byte, XmlWriterBufSize)
wb := bytes.NewBuffer(buf)
trdr := myTeeReader(xmlReader, wb) // see code at EOF
// build the node tree
n, err := xmlReaderToTree(trdr)
// retrieve the raw XML that was decoded
b := make([]byte, wb.Len())
_, _ = wb.Read(b)
if err != nil {
return nil, b, err
}
// create the Map value
m := make(map[string]interface{})
m[n.key] = n.treeToMap(r)
return m, b, nil
}
// xmlReaderToTree() - parse a XML io.Reader to a tree of nodes
func xmlReaderToTree(rdr io.Reader) (*node, error) {
// parse the Reader
p := xml.NewDecoder(rdr)
p.CharsetReader = XmlCharsetReader
return xmlToTreeParser("", nil, p)
}
// for building the parse tree
type node struct {
dup bool // is member of a list
attr bool // is an attribute
key string // XML tag
val string // element value
nodes []*node
}
// xmlToTree - convert a XML doc into a tree of nodes.
func xmlToTree(doc []byte) (*node, error) {
// xml.Decoder doesn't properly handle whitespace in some doc
// see songTextString.xml test case ...
reg, _ := regexp.Compile("[ \t\n\r]*<")
doc = reg.ReplaceAll(doc, []byte("<"))
b := bytes.NewReader(doc)
p := xml.NewDecoder(b)
p.CharsetReader = XmlCharsetReader
n, berr := xmlToTreeParser("", nil, p)
if berr != nil {
return nil, berr
}
return n, nil
}
// we allow people to drop hyphen when unmarshaling the XML doc.
var useHyphen bool = true
// PrependAttrWithHyphen. Prepend attribute tags with a hyphen.
// Default is 'true'.
// Note:
// If 'false', unmarshaling and marshaling is not symmetric. Attributes will be
// marshal'd as <attr_tag>attr</attr_tag> and may be part of a list.
func PrependAttrWithHyphen(v bool) {
useHyphen = v
}
// Include sequence id with inner tags. - per Sean Murphy, murphysean84@gmail.com.
var includeTagSeqNum bool
// IncludeTagSeqNum - include a "_seq":N key:value pair with each inner tag, denoting
// its position when parsed. E.g.,
/*
<Obj c="la" x="dee" h="da">
<IntObj id="3"/>
<IntObj1 id="1"/>
<IntObj id="2"/>
<StrObj>hello</StrObj>
</Obj>
parses as:
{
Obj:{
"-c":"la",
"-h":"da",
"-x":"dee",
"intObj":[
{
"-id"="3",
"_seq":"0" // if mxj.Cast is passed, then: "_seq":0
},
{
"-id"="2",
"_seq":"2"
}],
"intObj1":{
"-id":"1",
"_seq":"1"
},
"StrObj":{
"#text":"hello", // simple element value gets "#text" tag
"_seq":"3"
}
}
}
*/
func IncludeTagSeqNum(b bool) {
includeTagSeqNum = b
}
// xmlToTreeParser - load a 'clean' XML doc into a tree of *node.
func xmlToTreeParser(skey string, a []xml.Attr, p *xml.Decoder) (*node, error) {
n := new(node)
n.nodes = make([]*node, 0)
var seq int // for includeTagSeqNum
if skey != "" {
n.key = skey
if len(a) > 0 {
for _, v := range a {
na := new(node)
na.attr = true
if useHyphen {
na.key = `-` + v.Name.Local
} else {
na.key = v.Name.Local
}
na.val = v.Value
n.nodes = append(n.nodes, na)
}
}
}
for {
t, err := p.Token()
if err != nil {
if err != io.EOF {
return nil, errors.New("xml.Decoder.Token() - " + err.Error())
}
return nil, err
}
switch t.(type) {
case xml.StartElement:
tt := t.(xml.StartElement)
// handle root
if n.key == "" {
n.key = tt.Name.Local
if len(tt.Attr) > 0 {
for _, v := range tt.Attr {
na := new(node)
na.attr = true
if useHyphen {
na.key = `-` + v.Name.Local
} else {
na.key = v.Name.Local
}
na.val = v.Value
n.nodes = append(n.nodes, na)
}
}
} else {
nn, nnerr := xmlToTreeParser(tt.Name.Local, tt.Attr, p)
if nnerr != nil {
return nil, nnerr
}
n.nodes = append(n.nodes, nn)
if includeTagSeqNum { // 2014.11.09
sn := &node{false, false, "_seq", strconv.Itoa(seq), nil}
nn.nodes = append(nn.nodes, sn)
seq++
}
}
case xml.EndElement:
// scan n.nodes for duplicate n.key values
n.markDuplicateKeys()
return n, nil
case xml.CharData:
tt := string(t.(xml.CharData))
// clean up possible noise
tt = strings.Trim(tt, "\t\r\b\n ")
if len(n.nodes) > 0 && len(tt) > 0 {
// if len(n.nodes) > 0 {
nn := new(node)
nn.key = "#text"
nn.val = tt
n.nodes = append(n.nodes, nn)
} else {
n.val = tt
}
if includeTagSeqNum { // 2014.11.09
if len(n.nodes) == 0 { // treat like a simple element with attributes
nn := new(node)
nn.key = "#text"
nn.val = tt
n.nodes = append(n.nodes, nn)
}
sn := &node{false, false, "_seq", strconv.Itoa(seq), nil}
n.nodes = append(n.nodes, sn)
seq++
}
default:
// noop
}
}
// Logically we can't get here, but provide an error message anyway.
return nil, fmt.Errorf("Unknown parse error in xmlToTree() for: %s", n.key)
}
// (*node)markDuplicateKeys - set node.dup flag for loading map[string]interface{}.
func (n *node) markDuplicateKeys() {
l := len(n.nodes)
for i := 0; i < l; i++ {
if n.nodes[i].dup {
continue
}
for j := i + 1; j < l; j++ {
if n.nodes[i].key == n.nodes[j].key {
n.nodes[i].dup = true
n.nodes[j].dup = true
}
}
}
}
// (*node)treeToMap - convert a tree of nodes into a map[string]interface{}.
// (Parses to map that is structurally the same as from json.Unmarshal().)
// Note: root is not instantiated; call with: "m[n.key] = n.treeToMap(cast)".
func (n *node) treeToMap(r bool) interface{} {
if len(n.nodes) == 0 {
return cast(n.val, r)
}
m := make(map[string]interface{}, 0)
for _, v := range n.nodes {
// 2014.11.9 - may have to back out
if includeTagSeqNum {
if len(v.nodes) == 1 {
m[v.key] = cast(v.val, r)
continue
}
}
// just a value
if !v.dup && len(v.nodes) == 0 {
m[v.key] = cast(v.val, r)
continue
}
// a list of values
if v.dup {
var a []interface{}
if vv, ok := m[v.key]; ok {
a = vv.([]interface{})
} else {
a = make([]interface{}, 0)
}
a = append(a, v.treeToMap(r))
m[v.key] = interface{}(a)
continue
}
// it's a unique key
m[v.key] = v.treeToMap(r)
}
return interface{}(m)
}
// cast - try to cast string values to bool or float64
func cast(s string, r bool) interface{} {
if r {
// handle numeric strings ahead of boolean
if f, err := strconv.ParseFloat(s, 64); err == nil {
return interface{}(f)
}
// ParseBool treats "1"==true & "0"==false
// but be more strick - only allow TRUE, True, true, FALSE, False, false
if s != "t" && s != "T" && s != "f" && s != "F" {
if b, err := strconv.ParseBool(s); err == nil {
return interface{}(b)
}
}
}
return interface{}(s)
}
// ------------------ END: NewMapXml & NewMapXmlReader -------------------------
// ------------------ mv.Xml & mv.XmlWriter - from j2x ------------------------
const (
DefaultRootTag = "doc"
)
var useGoXmlEmptyElemSyntax bool
// XmlGoEmptyElemSyntax() - <tag ...></tag> rather than <tag .../>.
// Go's encoding/xml package marshals empty XML elements as <tag ...></tag>. By default this package
// encodes empty elements as <tag .../>. If you're marshaling Map values that include structures
// (which are passed to xml.Marshal for encoding), this will let you conform to the standard package.
//
// Alternatively, you can replace the encoding/xml/marshal.go file in the standard libary with the
// patched version in the "xml_marshal" folder in this package. Then use xml.SetUseNullEndTag(true)
// to have all XML encoding use <tag .../> for empty elements.
func XmlGoEmptyElemSyntax() {
useGoXmlEmptyElemSyntax = true
}
// XmlDefaultEmptyElemSyntax() - <tag .../> rather than <tag ...></tag>.
// Return XML encoding for empty elements to the default package setting.
// Reverses effect of XmlGoEmptyElemSyntax().
func XmlDefaultEmptyElemSyntax() {
useGoXmlEmptyElemSyntax = false
}
// Encode a Map as XML. The companion of NewMapXml().
// The following rules apply.
// - The key label "#text" is treated as the value for a simple element with attributes.
// - Map keys that begin with a hyphen, '-', are interpreted as attributes.
// It is an error if the attribute doesn't have a []byte, string, number, or boolean value.
// - Map value type encoding:
// > string, bool, float64, int, int32, int64, float32: per "%v" formating
// > []bool, []uint8: by casting to string
// > structures, etc.: handed to xml.Marshal() - if there is an error, the element
// value is "UNKNOWN"
// - Elements with only attribute values or are null are terminated using "/>".
// - If len(mv) == 1 and no rootTag is provided, then the map key is used as the root tag, possible.
// Thus, `{ "key":"value" }` encodes as "<key>value</key>".
// - To encode empty elements in a syntax consistent with encoding/xml call UseGoXmlEmptyElementSyntax().
func (mv Map) Xml(rootTag ...string) ([]byte, error) {
m := map[string]interface{}(mv)
var err error
s := new(string)
p := new(pretty) // just a stub
if len(m) == 1 && len(rootTag) == 0 {
for key, value := range m {
// if it an array, see if all values are map[string]interface{}
// we force a new root tag if we'll end up with no key:value in the list
// so: key:[string_val, bool:true] --> <doc><key>string_val</key><bool>true</bool></doc>
switch value.(type) {
case []interface{}:
for _, v := range value.([]interface{}) {
switch v.(type) {
case map[string]interface{}: // noop
default: // anything else
err = mapToXmlIndent(false, s, DefaultRootTag, m, p)
goto done
}
}
}
err = mapToXmlIndent(false, s, key, value, p)
}
} else if len(rootTag) == 1 {
err = mapToXmlIndent(false, s, rootTag[0], m, p)
} else {
err = mapToXmlIndent(false, s, DefaultRootTag, m, p)
}
done:
return []byte(*s), err
}
// The following implementation is provided only for symmetry with NewMapXmlReader[Raw]
// The names will also provide a key for the number of return arguments.
// Writes the Map as XML on the Writer.
// See Xml() for encoding rules.
func (mv Map) XmlWriter(xmlWriter io.Writer, rootTag ...string) error {
x, err := mv.Xml(rootTag...)
if err != nil {
return err
}
_, err = xmlWriter.Write(x)
return err
}
// Writes the Map as XML on the Writer. []byte is the raw XML that was written.
// See Xml() for encoding rules.
func (mv Map) XmlWriterRaw(xmlWriter io.Writer, rootTag ...string) ([]byte, error) {
x, err := mv.Xml(rootTag...)
if err != nil {
return x, err
}
_, err = xmlWriter.Write(x)
return x, err
}
// Writes the Map as pretty XML on the Writer.
// See Xml() for encoding rules.
func (mv Map) XmlIndentWriter(xmlWriter io.Writer, prefix, indent string, rootTag ...string) error {
x, err := mv.XmlIndent(prefix, indent, rootTag...)
if err != nil {
return err
}
_, err = xmlWriter.Write(x)
return err
}
// Writes the Map as pretty XML on the Writer. []byte is the raw XML that was written.
// See Xml() for encoding rules.
func (mv Map) XmlIndentWriterRaw(xmlWriter io.Writer, prefix, indent string, rootTag ...string) ([]byte, error) {
x, err := mv.XmlIndent(prefix, indent, rootTag...)
if err != nil {
return x, err
}
_, err = xmlWriter.Write(x)
return x, err
}
// -------------------- END: mv.Xml & mv.XmlWriter -------------------------------
// -------------- Handle XML stream by processing Map value --------------------
// Default poll delay to keep Handler from spinning on an open stream
// like sitting on os.Stdin waiting for imput.
var xhandlerPollInterval = time.Duration(1e6)
// Bulk process XML using handlers that process a Map value.
// 'rdr' is an io.Reader for XML (stream)
// 'mapHandler' is the Map processor. Return of 'false' stops io.Reader processing.
// 'errHandler' is the error processor. Return of 'false' stops io.Reader processing and returns the error.
// Note: mapHandler() and errHandler() calls are blocking, so reading and processing of messages is serialized.
// This means that you can stop reading the file on error or after processing a particular message.
// To have reading and handling run concurrently, pass argument to a go routine in handler and return 'true'.
func HandleXmlReader(xmlReader io.Reader, mapHandler func(Map) bool, errHandler func(error) bool) error {
var n int
for {
m, merr := NewMapXmlReader(xmlReader)
n++
// handle error condition with errhandler
if merr != nil && merr != io.EOF {
merr = fmt.Errorf("[xmlReader: %d] %s", n, merr.Error())
if ok := errHandler(merr); !ok {
// caused reader termination
return merr
}
continue
}
// pass to maphandler
if len(m) != 0 {
if ok := mapHandler(m); !ok {
break
}
} else if merr != io.EOF {
<-time.After(xhandlerPollInterval)
}
if merr == io.EOF {
break
}
}
return nil
}
// Bulk process XML using handlers that process a Map value and the raw XML.
// 'rdr' is an io.Reader for XML (stream)
// 'mapHandler' is the Map and raw XML - []byte - processor. Return of 'false' stops io.Reader processing.
// 'errHandler' is the error and raw XML processor. Return of 'false' stops io.Reader processing and returns the error.
// Note: mapHandler() and errHandler() calls are blocking, so reading and processing of messages is serialized.
// This means that you can stop reading the file on error or after processing a particular message.
// To have reading and handling run concurrently, pass argument(s) to a go routine in handler and return 'true'.
// See NewMapXmlReaderRaw for comment on performance associated with retrieving raw XML from a Reader.
func HandleXmlReaderRaw(xmlReader io.Reader, mapHandler func(Map, []byte) bool, errHandler func(error, []byte) bool) error {
var n int
for {
m, raw, merr := NewMapXmlReaderRaw(xmlReader)
n++
// handle error condition with errhandler
if merr != nil && merr != io.EOF {
merr = fmt.Errorf("[xmlReader: %d] %s", n, merr.Error())
if ok := errHandler(merr, raw); !ok {
// caused reader termination
return merr
}
continue
}
// pass to maphandler
if len(m) != 0 {
if ok := mapHandler(m, raw); !ok {
break
}
} else if merr != io.EOF {
<-time.After(xhandlerPollInterval)
}
if merr == io.EOF {
break
}
}
return nil
}
// ----------------- END: Handle XML stream by processing Map value --------------
// -------- a hack of io.TeeReader ... need one that's an io.ByteReader for xml.NewDecoder() ----------
// This is a clone of io.TeeReader with the additional method t.ReadByte().
// Thus, this TeeReader is also an io.ByteReader.
// This is necessary because xml.NewDecoder uses a ByteReader not a Reader. It appears to have been written
// with bufio.Reader or bytes.Reader in mind ... not a generic io.Reader, which doesn't have to have ReadByte()..
// If NewDecoder is passed a Reader that does not satisfy ByteReader() it wraps the Reader with
// bufio.NewReader and uses ReadByte rather than Read that runs the TeeReader pipe logic.
type teeReader struct {
r io.Reader
w io.Writer
b []byte
}
func myTeeReader(r io.Reader, w io.Writer) io.Reader {
b := make([]byte, 1)
return &teeReader{r, w, b}
}
// need for io.Reader - but we don't use it ...
func (t *teeReader) Read(p []byte) (n int, err error) {
return 0, nil
}
func (t *teeReader) ReadByte() (c byte, err error) {
n, err := t.r.Read(t.b)
if n > 0 {
if _, err := t.w.Write(t.b[:1]); err != nil {
return t.b[0], err
}
}
return t.b[0], err
}
// ----------------------- END: io.TeeReader hack -----------------------------------
// ---------------------- XmlIndent - from j2x package ----------------------------
// Encode a map[string]interface{} as a pretty XML string.
// See Xml for encoding rules.
func (mv Map) XmlIndent(prefix, indent string, rootTag ...string) ([]byte, error) {
m := map[string]interface{}(mv)
var err error
s := new(string)
p := new(pretty)
p.indent = indent
p.padding = prefix
if len(m) == 1 && len(rootTag) == 0 {
// this can extract the key for the single map element
// use it if it isn't a key for a list
for key, value := range m {
if _, ok := value.([]interface{}); ok {
err = mapToXmlIndent(true, s, DefaultRootTag, m, p)
} else {
err = mapToXmlIndent(true, s, key, value, p)
}
}
} else if len(rootTag) == 1 {
err = mapToXmlIndent(true, s, rootTag[0], m, p)
} else {
err = mapToXmlIndent(true, s, DefaultRootTag, m, p)
}
return []byte(*s), err
}
type pretty struct {
indent string
cnt int
padding string
mapDepth int
start int
}
func (p *pretty) Indent() {
p.padding += p.indent
p.cnt++
}
func (p *pretty) Outdent() {
if p.cnt > 0 {
p.padding = p.padding[:len(p.padding)-len(p.indent)]
p.cnt--
}
}
// where the work actually happens
// returns an error if an attribute is not atomic
func mapToXmlIndent(doIndent bool, s *string, key string, value interface{}, pp *pretty) error {
var endTag bool
var isSimple bool
p := &pretty{pp.indent, pp.cnt, pp.padding, pp.mapDepth, pp.start}
switch value.(type) {
case map[string]interface{}, []byte, string, float64, bool, int, int32, int64, float32:
if doIndent {
*s += p.padding
}
*s += `<` + key
}
switch value.(type) {
case map[string]interface{}:
vv := value.(map[string]interface{})
lenvv := len(vv)
// scan out attributes - keys have prepended hyphen, '-'
var cntAttr int
for k, v := range vv {
if k[:1] == "-" {
switch v.(type) {
case string, float64, bool, int, int32, int64, float32:
*s += ` ` + k[1:] + `="` + fmt.Sprintf("%v", v) + `"`
cntAttr++
case []byte: // allow standard xml pkg []byte transform, as below
*s += ` ` + k[1:] + `="` + fmt.Sprintf("%v", string(v.([]byte))) + `"`
cntAttr++
default:
return fmt.Errorf("invalid attribute value for: %s", k)
}
}
}
// only attributes?
if cntAttr == lenvv {
break
}
// simple element? Note: '#text" is an invalid XML tag.
if v, ok := vv["#text"]; ok {
if cntAttr+1 < lenvv {
return errors.New("#text key occurs with other non-attribute keys")
}
*s += ">" + fmt.Sprintf("%v", v)
endTag = true
break
}
// close tag with possible attributes
*s += ">"
if doIndent {
*s += "\n"
}
// something more complex
p.mapDepth++
var i int
for k, v := range vv {
if k[:1] == "-" {
continue
}
switch v.(type) {
case []interface{}:
default:
if i == 0 && doIndent {
p.Indent()
}
}
i++
mapToXmlIndent(doIndent, s, k, v, p)
switch v.(type) {
case []interface{}: // handled in []interface{} case
default:
if doIndent {
p.Outdent()
}
}
i--
}
p.mapDepth--
endTag = true
case []interface{}:
for _, v := range value.([]interface{}) {
if doIndent {
p.Indent()
}
mapToXmlIndent(doIndent, s, key, v, p)
if doIndent {
p.Outdent()
}
}
return nil
case nil:
// terminate the tag
*s += "<" + key
break
default: // handle anything - even goofy stuff
switch value.(type) {
case string, float64, bool, int, int32, int64, float32:
*s += ">" + fmt.Sprintf("%v", value)
case []byte: // NOTE: byte is just an alias for uint8
// similar to how xml.Marshal handles []byte structure members
*s += ">" + string(value.([]byte))
default:
var v []byte
var err error
if doIndent {
v, err = xml.MarshalIndent(value, p.padding, p.indent)
} else {
v, err = xml.Marshal(value)
}
if err != nil {
*s += ">UNKNOWN"
} else {
*s += string(v)
}
}
isSimple = true
endTag = true
}
if endTag {
if doIndent {
if !isSimple {
// if p.mapDepth == 0 {
// p.Outdent()
// }
*s += p.padding
}
}
switch value.(type) {
case map[string]interface{}, []byte, string, float64, bool, int, int32, int64, float32:
*s += `</` + key + ">"
}
} else if useGoXmlEmptyElemSyntax {
*s += "></" + key + ">"
} else {
*s += "/>"
}
if doIndent {
if p.cnt > p.start {
*s += "\n"
}
p.Outdent()
}
return nil
}

View File

@ -1,26 +0,0 @@
The mxj package terminates empty elements using '/>' rather than '<tag ...></tag>'.
The Xml(), XmlIndent(), XmlWriter() marshals Map values that can have structures or any other Go type
that xml.Marshal() can encode. If you want to have xml.Marshal() encode empty elements in a manner
consist with maputil, then you need to hack the src/pkg/encoding/xml/marshal.go file to support that
convention.
The marshal.go.v1_2 file in this repo does that for Go v1.2; use it in place of the standard library
marshal.go file.
The example_test.go.v1_2 file extends the package example_test.go file in the src/pkg/encoding/xml
directory to provide an example of the SetUseNullEndTag() function that you'll see in the new godoc
documentation for encoding/xml. xml.SetUseNullEndTag(true) causes xml.Marshal() to encode empty XML
elements as <tag .../>, just like this package.
With the new marshal.go, you can then force all marshaling that uses encoding/xml to use mxj's <tag .../>
syntax rather than the Go standard <tag ...></tag> syntax.
NOTE:
If you install this patch then only use either
- xml.SetUseNullEndTag()
or
- mxj.XmlGoEmptyElemSyntax()
to have consistent encoding of empty XML elements.

View File

@ -1,211 +0,0 @@
// Copyright 2012 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 xml_test
import (
"encoding/xml"
"fmt"
"os"
)
func ExampleMarshalIndent() {
type Address struct {
City, State string
}
type Person struct {
XMLName xml.Name `xml:"person"`
Id int `xml:"id,attr"`
FirstName string `xml:"name>first"`
LastName string `xml:"name>last"`
Age int `xml:"age"`
Height float32 `xml:"height,omitempty"`
Married bool
Address
Comment string `xml:",comment"`
}
v := &Person{Id: 13, FirstName: "John", LastName: "Doe", Age: 42}
v.Comment = " Need more details. "
v.Address = Address{"Hanga Roa", "Easter Island"}
output, err := xml.MarshalIndent(v, " ", " ")
if err != nil {
fmt.Printf("error: %v\n", err)
}
os.Stdout.Write(output)
// Output:
// <person id="13">
// <name>
// <first>John</first>
// <last>Doe</last>
// </name>
// <age>42</age>
// <Married>false</Married>
// <City>Hanga Roa</City>
// <State>Easter Island</State>
// <!-- Need more details. -->
// </person>
}
func ExampleEncoder() {
type Address struct {
City, State string
}
type Person struct {
XMLName xml.Name `xml:"person"`
Id int `xml:"id,attr"`
FirstName string `xml:"name>first"`
LastName string `xml:"name>last"`
Age int `xml:"age"`
Height float32 `xml:"height,omitempty"`
Married bool
Address
Comment string `xml:",comment"`
}
v := &Person{Id: 13, FirstName: "John", LastName: "Doe", Age: 42}
v.Comment = " Need more details. "
v.Address = Address{"Hanga Roa", "Easter Island"}
enc := xml.NewEncoder(os.Stdout)
enc.Indent(" ", " ")
if err := enc.Encode(v); err != nil {
fmt.Printf("error: %v\n", err)
}
// Output:
// <person id="13">
// <name>
// <first>John</first>
// <last>Doe</last>
// </name>
// <age>42</age>
// <Married>false</Married>
// <City>Hanga Roa</City>
// <State>Easter Island</State>
// <!-- Need more details. -->
// </person>
}
// This example demonstrates unmarshaling an XML excerpt into a value with
// some preset fields. Note that the Phone field isn't modified and that
// the XML <Company> element is ignored. Also, the Groups field is assigned
// considering the element path provided in its tag.
func ExampleUnmarshal() {
type Email struct {
Where string `xml:"where,attr"`
Addr string
}
type Address struct {
City, State string
}
type Result struct {
XMLName xml.Name `xml:"Person"`
Name string `xml:"FullName"`
Phone string
Email []Email
Groups []string `xml:"Group>Value"`
Address
}
v := Result{Name: "none", Phone: "none"}
data := `
<Person>
<FullName>Grace R. Emlin</FullName>
<Company>Example Inc.</Company>
<Email where="home">
<Addr>gre@example.com</Addr>
</Email>
<Email where='work'>
<Addr>gre@work.com</Addr>
</Email>
<Group>
<Value>Friends</Value>
<Value>Squash</Value>
</Group>
<City>Hanga Roa</City>
<State>Easter Island</State>
</Person>
`
err := xml.Unmarshal([]byte(data), &v)
if err != nil {
fmt.Printf("error: %v", err)
return
}
fmt.Printf("XMLName: %#v\n", v.XMLName)
fmt.Printf("Name: %q\n", v.Name)
fmt.Printf("Phone: %q\n", v.Phone)
fmt.Printf("Email: %v\n", v.Email)
fmt.Printf("Groups: %v\n", v.Groups)
fmt.Printf("Address: %v\n", v.Address)
// Output:
// XMLName: xml.Name{Space:"", Local:"Person"}
// Name: "Grace R. Emlin"
// Phone: "none"
// Email: [{home gre@example.com} {work gre@work.com}]
// Groups: [Friends Squash]
// Address: {Hanga Roa Easter Island}
}
// This example demonstrates how SetUseNullEndTag changes the end tag syntax for Marshal.
func ExampleSetUseNullEndTag() {
type NullValStruct struct {
I int
B []byte
S string
}
s := new(NullValStruct)
v, err := xml.Marshal(s)
if err != nil {
fmt.Println("err:", err.Error())
} else {
fmt.Println("s:", string(v))
}
xml.SetUseNullEndTag(true)
v, err = xml.Marshal(s)
if err != nil {
fmt.Println("err:", err.Error())
} else {
fmt.Println("s:", string(v))
}
type NewStruct struct {
NVS NullValStruct
S string
F float64
}
ss := new(NewStruct)
v, err = xml.Marshal(ss)
if err != nil {
fmt.Println("err:", err.Error())
} else {
fmt.Println("ss:", string(v))
}
v, err = xml.MarshalIndent(ss," "," ")
if err != nil {
fmt.Println("err:", err.Error())
} else {
fmt.Println("ss indent:\n",string(v))
}
// Output:
// s: <NullValStruct><I>0</I><B></B><S></S></NullValStruct>
// s: <NullValStruct><I>0</I><B/><S/></NullValStruct>
// ss: <NewStruct><NVS><I>0</I><B/><S/></NVS><S/><F>0</F></NewStruct>
// ss indent:
// <NewStruct>
// <NVS>
// <I>0</I>
// <B/>
// <S/>
// </NVS>
// <S/>
// <F>0</F>
// </NewStruct>
}

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@ -1,207 +0,0 @@
package mxj
import (
"bytes"
"fmt"
"io"
"testing"
)
func TestXmlHeader(t *testing.T) {
fmt.Println("\n---------------- xml_test.go ...\n")
}
func TestNewMapXml(t *testing.T) {
x := []byte(`<root2><newtag newattr="some_attr_value">something more</newtag><list listattr="val"><item>1</item><item>2</item></list></root2>`)
mv, merr := NewMapXml(x)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("NewMapXml, x :", string(x))
fmt.Println("NewMapXml, mv:", mv)
}
func TestAttrHyphenFalse(t *testing.T) {
PrependAttrWithHyphen(false)
x := []byte(`<root2><newtag newattr="some_attr_value">something more</newtag><list listattr="val"><item>1</item><item>2</item></list></root2>`)
mv, merr := NewMapXml(x)
if merr != nil {
t.Fatal("merr:", merr.Error())
}
fmt.Println("AttrHyphenFalse, x :", string(x))
fmt.Println("AttrHyphenFalse, mv:", mv)
PrependAttrWithHyphen(true)
}
func TestNewMapXmlError(t *testing.T) {
x := []byte(`<root2><newtag>something more</newtag><list><item>1</item><item>2</item></list>`)
m, merr := NewMapJson(x)
if merr == nil {
t.Fatal("NewMapXmlError, m:", m)
}
fmt.Println("NewMapXmlError, x :", string(x))
fmt.Println("NewMapXmlError, merr:", merr.Error())
x = []byte(`<root2><newtag>something more</newtag><list><item>1<item>2</item></list></root2>`)
m, merr = NewMapJson(x)
if merr == nil {
t.Fatal("NewMapXmlError, m:", m)
}
fmt.Println("NewMapXmlError, x :", string(x))
fmt.Println("NewMapXmlError, merr:", merr.Error())
}
func TestNewMapXmlReader(t *testing.T) {
x := []byte(`<root><this>is a test</this></root><root2><newtag>something more</newtag><list><item>1</item><item>2</item></list></root2>`)
r := bytes.NewReader(x)
for {
m, raw, err := NewMapXmlReaderRaw(r)
if err != nil && err != io.EOF {
t.Fatal("err:", err.Error())
}
if err == io.EOF && len(m) == 0 {
break
}
fmt.Println("NewMapXmlReader, raw:", string(raw))
fmt.Println("NewMapXmlReader, m :", m)
}
}
// --------------------- Xml() and XmlWriter() test cases -------------------
func TestXml_1(t *testing.T) {
mv := Map{"tag1": "some data", "tag2": "more data", "boolean": true, "float": 3.14159625, "null": nil}
x, err := mv.Xml()
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("Xml_1, mv:", mv)
fmt.Println("Xml_1, x :", string(x))
}
func TestXml_2(t *testing.T) {
a := []interface{}{"string", true, 36.4}
mv := Map{"array": a}
x, err := mv.Xml()
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("Xml_2, mv:", mv)
fmt.Println("Xml_2, x :", string(x))
}
func TestXml_3(t *testing.T) {
a := []interface{}{"string", true, 36.4}
mv := Map{"array": []interface{}{a, "string2"}}
x, err := mv.Xml()
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("Xml_3, mv:", mv)
fmt.Println("Xml_3, x :", string(x))
}
func TestXml_4(t *testing.T) {
a := []interface{}{"string", true, 36.4}
mv := Map{"array": map[string]interface{}{"innerkey": []interface{}{a, "string2"}}}
x, err := mv.Xml()
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("Xml_4, mv:", mv)
fmt.Println("Xml_4, x :", string(x))
}
func TestXml_5(t *testing.T) {
a := []interface{}{"string", true, 36.4}
mv := Map{"array": []interface{}{map[string]interface{}{"innerkey": []interface{}{a, "string2"}}, map[string]interface{}{"some": "more"}}}
x, err := mv.Xml()
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("Xml_5, mv:", mv)
fmt.Println("Xml_5, x :", string(x))
}
func TestXmlWriter(t *testing.T) {
mv := Map{"tag1": "some data", "tag2": "more data", "boolean": true, "float": 3.14159625}
w := new(bytes.Buffer)
raw, err := mv.XmlWriterRaw(w, "myRootTag")
if err != nil {
t.Fatal("err:", err.Error())
}
b := make([]byte, w.Len())
_, err = w.Read(b)
if err != nil {
t.Fatal("err:", err.Error())
}
fmt.Println("XmlWriter, raw:", string(raw))
fmt.Println("XmlWriter, b :", string(b))
}
// -------------------------- XML Handler test cases -------------------------
/* tested in bulk_test.go ...
var xhdata = []byte(`<root><this>is a test</this></root><root2><newtag>something more</newtag><list><item>1</item><item>2</item></list></root2><root3><tag></root3>`)
func TestHandleXmlReader(t *testing.T) {
fmt.Println("HandleXmlReader:", string(xhdata))
rdr := bytes.NewReader(xhdata)
err := HandleXmlReader(rdr, xmhandler, xehandler)
if err != nil {
t.Fatal("err:", err.Error())
}
}
var xt *testing.T
func xmhandler(m Map, raw []byte) bool {
x, xerr := m.Xml()
if xerr != nil {
xt.Fatal("... xmhandler:", xerr.Error())
return false
}
fmt.Println("... xmhandler, raw:", string(raw))
fmt.Println("... xmhandler, x :", string(x))
return true
}
func xehandler(err error, raw []byte) bool {
if err == nil {
// shouldn't be here
xt.Fatal("... xehandler: <nil>")
return false
}
if err == io.EOF {
return true
}
fmt.Println("... xehandler raw:", string(raw))
fmt.Println("... xehandler err:", err.Error())
return true
}
*/

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@ -1,23 +0,0 @@
# Compiled Object files, Static and Dynamic libs (Shared Objects)
*.o
*.a
*.so
# Folders
_obj
_test
# Architecture specific extensions/prefixes
*.[568vq]
[568vq].out
*.cgo1.go
*.cgo2.c
_cgo_defun.c
_cgo_gotypes.go
_cgo_export.*
_testmain.go
*.exe
*.test

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@ -1,11 +0,0 @@
language: go
go: 1.3
before_install:
- go get github.com/axw/gocov/gocov
- go get github.com/mattn/goveralls
- go get code.google.com/p/go.tools/cmd/cover
script:
- $HOME/gopath/bin/goveralls -repotoken $COVERALLS_TOKEN
env:
global:
- secure: hkc+92KPmMFqIH9n4yWdnH1JpZjahmOyDJwpTh8Yl0JieJNG0XEXpOqNao27eA0cLF+UHdyjFeGcPUJKNmgE46AoQjtovt+ICjCXKR2yF6S2kKJcUOz/Vd6boZF7qHV06jjxyxOebpID5iSoW6UfFr001bFxpd3jaSLFTzSHWRQ=

View File

@ -1,21 +0,0 @@
The MIT License (MIT)
Copyright (c) 2014 Fatih Arslan
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.

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@ -1,159 +0,0 @@
# Structs [![GoDoc](http://img.shields.io/badge/go-documentation-blue.svg?style=flat-square)](http://godoc.org/github.com/fatih/structs) [![Build Status](http://img.shields.io/travis/fatih/structs.svg?style=flat-square)](https://travis-ci.org/fatih/structs) [![Coverage Status](http://img.shields.io/coveralls/fatih/structs.svg?style=flat-square)](https://coveralls.io/r/fatih/structs)
Structs contains various utilities to work with Go (Golang) structs. It was
initially used by me to convert a struct into a `map[string]interface{}`. With
time I've added other utilities for structs. It's basically a high level
package based on primitives from the reflect package. Feel free to add new
functions or improve the existing code.
## Install
```bash
go get github.com/fatih/structs
```
## Usage and Examples
Just like the standard lib `strings`, `bytes` and co packages, `structs` has
many global functions to manipulate or organize your struct data. Lets define
and declare a struct:
```go
type Server struct {
Name string `json:"name,omitempty"`
ID int
Enabled bool
users []string // not exported
http.Server // embedded
}
server := &Server{
Name: "gopher",
ID: 123456,
Enabled: true,
}
```
```go
// Convert a struct to a map[string]interface{}
// => {"Name":"gopher", "ID":123456, "Enabled":true}
m := structs.Map(server)
// Convert the values of a struct to a []interface{}
// => ["gopher", 123456, true]
v := structs.Values(server)
// Convert the values of a struct to a []*Field
// (see "Field methods" for more info about fields)
f := structs.Fields(server)
// Return the struct name => "Server"
n := structs.Name(server)
// Check if any field of a struct is initialized or not.
h := structs.HasZero(server)
// Check if all fields of a struct is initialized or not.
z := structs.IsZero(server)
// Check if server is a struct or a pointer to struct
i := structs.IsStruct(server)
```
### Struct methods
The structs functions can be also used as independent methods by creating a new
`*structs.Struct`. This is handy if you want to have more control over the
structs (such as retrieving a single Field).
```go
// Create a new struct type:
s := structs.New(server)
m := s.Map() // Get a map[string]interface{}
v := s.Values() // Get a []interface{}
f := s.Fields() // Get a []*Field
f := s.Field(name) // Get a *Field based on the given field name
f, ok := s.FieldsOk(name) // Get a *Field based on the given field name
n := s.Name() // Get the struct name
h := s.HasZero() // Check if any field is initialized
z := s.IsZero() // Check if all fields are initialized
```
### Field methods
We can easily examine a single Field for more detail. Below you can see how we
get and interact with various field methods:
```go
s := structs.New(server)
// Get the Field struct for the "Name" field
name := s.Field("Name")
// Get the underlying value, value => "gopher"
value := name.Value().(string)
// Set the field's value
name.Set("another gopher")
// Get the field's kind, kind => "string"
name.Kind()
// Check if the field is exported or not
if name.IsExported() {
fmt.Println("Name field is exported")
}
// Check if the value is a zero value, such as "" for string, 0 for int
if !name.IsZero() {
fmt.Println("Name is initialized")
}
// Check if the field is an anonymous (embedded) field
if !name.IsEmbedded() {
fmt.Println("Name is not an embedded field")
}
// Get the Field's tag value for tag name "json", tag value => "name,omitempty"
tagValue := name.Tag("json")
```
Nested structs are supported too:
```go
addrField := s.Field("Server").Field("Addr")
// Get the value for addr
a := addrField.Value().(string)
// Or get all fields
httpServer := s.Field("Server").Fields()
```
We can also get a slice of Fields from the Struct type to iterate over all
fields. This is handy if you wish to examine all fields:
```go
// Convert the fields of a struct to a []*Field
fields := s.Fields()
for _, f := range fields {
fmt.Printf("field name: %+v\n", f.Name())
if f.IsExported() {
fmt.Printf("value : %+v\n", f.Value())
fmt.Printf("is zero : %+v\n", f.IsZero())
}
}
```
## Credits
* [Fatih Arslan](https://github.com/fatih)
* [Cihangir Savas](https://github.com/cihangir)
## License
The MIT License (MIT) - see LICENSE.md for more details

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@ -1,126 +0,0 @@
package structs
import (
"errors"
"fmt"
"reflect"
)
var (
errNotExported = errors.New("field is not exported")
errNotSettable = errors.New("field is not settable")
)
// Field represents a single struct field that encapsulates high level
// functions around the field.
type Field struct {
value reflect.Value
field reflect.StructField
defaultTag string
}
// Tag returns the value associated with key in the tag string. If there is no
// such key in the tag, Tag returns the empty string.
func (f *Field) Tag(key string) string {
return f.field.Tag.Get(key)
}
// Value returns the underlying value of of the field. It panics if the field
// is not exported.
func (f *Field) Value() interface{} {
return f.value.Interface()
}
// IsEmbedded returns true if the given field is an anonymous field (embedded)
func (f *Field) IsEmbedded() bool {
return f.field.Anonymous
}
// IsExported returns true if the given field is exported.
func (f *Field) IsExported() bool {
return f.field.PkgPath == ""
}
// IsZero returns true if the given field is not initalized (has a zero value).
// It panics if the field is not exported.
func (f *Field) IsZero() bool {
zero := reflect.Zero(f.value.Type()).Interface()
current := f.Value()
return reflect.DeepEqual(current, zero)
}
// Name returns the name of the given field
func (f *Field) Name() string {
return f.field.Name
}
// Kind returns the fields kind, such as "string", "map", "bool", etc ..
func (f *Field) Kind() reflect.Kind {
return f.value.Kind()
}
// Set sets the field to given value v. It retuns an error if the field is not
// settable (not addresable or not exported) or if the given value's type
// doesn't match the fields type.
func (f *Field) Set(val interface{}) error {
// we can't set unexported fields, so be sure this field is exported
if !f.IsExported() {
return errNotExported
}
// do we get here? not sure...
if !f.value.CanSet() {
return errNotSettable
}
given := reflect.ValueOf(val)
if f.value.Kind() != given.Kind() {
return fmt.Errorf("wrong kind. got: %s want: %s", given.Kind(), f.value.Kind())
}
f.value.Set(given)
return nil
}
// Fields returns a slice of Fields. This is particular handy to get the fields
// of a nested struct . A struct tag with the content of "-" ignores the
// checking of that particular field. Example:
//
// // Field is ignored by this package.
// Field *http.Request `structs:"-"`
//
// It panics if field is not exported or if field's kind is not struct
func (f *Field) Fields() []*Field {
return getFields(f.value, f.defaultTag)
}
// Field returns the field from a nested struct. It panics if the nested struct
// is not exported or if the field was not found.
func (f *Field) Field(name string) *Field {
field, ok := f.FieldOk(name)
if !ok {
panic("field not found")
}
return field
}
// Field returns the field from a nested struct. The boolean returns true if
// the field was found. It panics if the nested struct is not exported or if
// the field was not found.
func (f *Field) FieldOk(name string) (*Field, bool) {
v := strctVal(f.value.Interface())
t := v.Type()
field, ok := t.FieldByName(name)
if !ok {
return nil, false
}
return &Field{
field: field,
value: v.FieldByName(name),
}, true
}

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@ -1,324 +0,0 @@
package structs
import (
"reflect"
"testing"
)
// A test struct that defines all cases
type Foo struct {
A string
B int `structs:"y"`
C bool `json:"c"`
d string // not exported
E *Baz
x string `xml:"x"` // not exported, with tag
Y []string
Z map[string]interface{}
*Bar // embedded
}
type Baz struct {
A string
B int
}
type Bar struct {
E string
F int
g []string
}
func newStruct() *Struct {
b := &Bar{
E: "example",
F: 2,
g: []string{"zeynep", "fatih"},
}
// B and x is not initialized for testing
f := &Foo{
A: "gopher",
C: true,
d: "small",
E: nil,
Y: []string{"example"},
Z: nil,
}
f.Bar = b
return New(f)
}
func TestField_Set(t *testing.T) {
s := newStruct()
f := s.Field("A")
err := f.Set("fatih")
if err != nil {
t.Error(err)
}
if f.Value().(string) != "fatih" {
t.Errorf("Setted value is wrong: %s want: %s", f.Value().(string), "fatih")
}
f = s.Field("Y")
err = f.Set([]string{"override", "with", "this"})
if err != nil {
t.Error(err)
}
sliceLen := len(f.Value().([]string))
if sliceLen != 3 {
t.Errorf("Setted values slice length is wrong: %d, want: %d", sliceLen, 3)
}
f = s.Field("C")
err = f.Set(false)
if err != nil {
t.Error(err)
}
if f.Value().(bool) {
t.Errorf("Setted value is wrong: %s want: %s", f.Value().(bool), false)
}
// let's pass a different type
f = s.Field("A")
err = f.Set(123) // Field A is of type string, but we are going to pass an integer
if err == nil {
t.Error("Setting a field's value with a different type than the field's type should return an error")
}
// old value should be still there :)
if f.Value().(string) != "fatih" {
t.Errorf("Setted value is wrong: %s want: %s", f.Value().(string), "fatih")
}
// let's access an unexported field, which should give an error
f = s.Field("d")
err = f.Set("large")
if err != errNotExported {
t.Error(err)
}
// let's set a pointer to struct
b := &Bar{
E: "gopher",
F: 2,
}
f = s.Field("Bar")
err = f.Set(b)
if err != nil {
t.Error(err)
}
baz := &Baz{
A: "helloWorld",
B: 42,
}
f = s.Field("E")
err = f.Set(baz)
if err != nil {
t.Error(err)
}
ba := s.Field("E").Value().(*Baz)
if ba.A != "helloWorld" {
t.Errorf("could not set baz. Got: %s Want: helloWorld", ba.A)
}
}
func TestField(t *testing.T) {
s := newStruct()
defer func() {
err := recover()
if err == nil {
t.Error("Retrieveing a non existing field from the struct should panic")
}
}()
_ = s.Field("no-field")
}
func TestField_Kind(t *testing.T) {
s := newStruct()
f := s.Field("A")
if f.Kind() != reflect.String {
t.Errorf("Field A has wrong kind: %s want: %s", f.Kind(), reflect.String)
}
f = s.Field("B")
if f.Kind() != reflect.Int {
t.Errorf("Field B has wrong kind: %s want: %s", f.Kind(), reflect.Int)
}
// unexported
f = s.Field("d")
if f.Kind() != reflect.String {
t.Errorf("Field d has wrong kind: %s want: %s", f.Kind(), reflect.String)
}
}
func TestField_Tag(t *testing.T) {
s := newStruct()
v := s.Field("B").Tag("json")
if v != "" {
t.Errorf("Field's tag value of a non existing tag should return empty, got: %s", v)
}
v = s.Field("C").Tag("json")
if v != "c" {
t.Errorf("Field's tag value of the existing field C should return 'c', got: %s", v)
}
v = s.Field("d").Tag("json")
if v != "" {
t.Errorf("Field's tag value of a non exported field should return empty, got: %s", v)
}
v = s.Field("x").Tag("xml")
if v != "x" {
t.Errorf("Field's tag value of a non exported field with a tag should return 'x', got: %s", v)
}
v = s.Field("A").Tag("json")
if v != "" {
t.Errorf("Field's tag value of a existing field without a tag should return empty, got: %s", v)
}
}
func TestField_Value(t *testing.T) {
s := newStruct()
v := s.Field("A").Value()
val, ok := v.(string)
if !ok {
t.Errorf("Field's value of a A should be string")
}
if val != "gopher" {
t.Errorf("Field's value of a existing tag should return 'gopher', got: %s", val)
}
defer func() {
err := recover()
if err == nil {
t.Error("Value of a non exported field from the field should panic")
}
}()
// should panic
_ = s.Field("d").Value()
}
func TestField_IsEmbedded(t *testing.T) {
s := newStruct()
if !s.Field("Bar").IsEmbedded() {
t.Errorf("Fields 'Bar' field is an embedded field")
}
if s.Field("d").IsEmbedded() {
t.Errorf("Fields 'd' field is not an embedded field")
}
}
func TestField_IsExported(t *testing.T) {
s := newStruct()
if !s.Field("Bar").IsExported() {
t.Errorf("Fields 'Bar' field is an exported field")
}
if !s.Field("A").IsExported() {
t.Errorf("Fields 'A' field is an exported field")
}
if s.Field("d").IsExported() {
t.Errorf("Fields 'd' field is not an exported field")
}
}
func TestField_IsZero(t *testing.T) {
s := newStruct()
if s.Field("A").IsZero() {
t.Errorf("Fields 'A' field is an initialized field")
}
if !s.Field("B").IsZero() {
t.Errorf("Fields 'B' field is not an initialized field")
}
}
func TestField_Name(t *testing.T) {
s := newStruct()
if s.Field("A").Name() != "A" {
t.Errorf("Fields 'A' field should have the name 'A'")
}
}
func TestField_Field(t *testing.T) {
s := newStruct()
e := s.Field("Bar").Field("E")
val, ok := e.Value().(string)
if !ok {
t.Error("The value of the field 'e' inside 'Bar' struct should be string")
}
if val != "example" {
t.Errorf("The value of 'e' should be 'example, got: %s", val)
}
defer func() {
err := recover()
if err == nil {
t.Error("Field of a non existing nested struct should panic")
}
}()
_ = s.Field("Bar").Field("e")
}
func TestField_Fields(t *testing.T) {
s := newStruct()
fields := s.Field("Bar").Fields()
if len(fields) != 3 {
t.Errorf("We expect 3 fields in embedded struct, was: %d", len(fields))
}
}
func TestField_FieldOk(t *testing.T) {
s := newStruct()
b, ok := s.FieldOk("Bar")
if !ok {
t.Error("The field 'Bar' should exists.")
}
e, ok := b.FieldOk("E")
if !ok {
t.Error("The field 'E' should exists.")
}
val, ok := e.Value().(string)
if !ok {
t.Error("The value of the field 'e' inside 'Bar' struct should be string")
}
if val != "example" {
t.Errorf("The value of 'e' should be 'example, got: %s", val)
}
}

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@ -1,422 +0,0 @@
// Package structs contains various utilities functions to work with structs.
package structs
import "reflect"
var (
// DefaultTagName is the default tag name for struct fields which provides
// a more granular to tweak certain structs. Lookup the necessary functions
// for more info.
DefaultTagName = "structs" // struct's field default tag name
)
// Struct encapsulates a struct type to provide several high level functions
// around the struct.
type Struct struct {
raw interface{}
value reflect.Value
TagName string
}
// New returns a new *Struct with the struct s. It panics if the s's kind is
// not struct.
func New(s interface{}) *Struct {
return &Struct{
raw: s,
value: strctVal(s),
TagName: DefaultTagName,
}
}
// Map converts the given struct to a map[string]interface{}, where the keys
// of the map are the field names and the values of the map the associated
// values of the fields. The default key string is the struct field name but
// can be changed in the struct field's tag value. The "structs" key in the
// struct's field tag value is the key name. Example:
//
// // Field appears in map as key "myName".
// Name string `structs:"myName"`
//
// A tag value with the content of "-" ignores that particular field. Example:
//
// // Field is ignored by this package.
// Field bool `structs:"-"`
//
// A tag value with the option of "omitnested" stops iterating further if the type
// is a struct. Example:
//
// // Field is not processed further by this package.
// Field time.Time `structs:"myName,omitnested"`
// Field *http.Request `structs:",omitnested"`
//
// A tag value with the option of "omitempty" ignores that particular field if
// the field value is empty. Example:
//
// // Field appears in map as key "myName", but the field is
// // skipped if empty.
// Field string `structs:"myName,omitempty"`
//
// // Field appears in map as key "Field" (the default), but
// // the field is skipped if empty.
// Field string `structs:",omitempty"`
//
// Note that only exported fields of a struct can be accessed, non exported
// fields will be neglected.
func (s *Struct) Map() map[string]interface{} {
out := make(map[string]interface{})
fields := s.structFields()
for _, field := range fields {
name := field.Name
val := s.value.FieldByName(name)
var finalVal interface{}
tagName, tagOpts := parseTag(field.Tag.Get(s.TagName))
if tagName != "" {
name = tagName
}
// if the value is a zero value and the field is marked as omitempty do
// not include
if tagOpts.Has("omitempty") {
zero := reflect.Zero(val.Type()).Interface()
current := val.Interface()
if reflect.DeepEqual(current, zero) {
continue
}
}
if IsStruct(val.Interface()) && !tagOpts.Has("omitnested") {
// look out for embedded structs, and convert them to a
// map[string]interface{} too
finalVal = Map(val.Interface())
} else {
finalVal = val.Interface()
}
out[name] = finalVal
}
return out
}
// Values converts the given s struct's field values to a []interface{}. A
// struct tag with the content of "-" ignores the that particular field.
// Example:
//
// // Field is ignored by this package.
// Field int `structs:"-"`
//
// A value with the option of "omitnested" stops iterating further if the type
// is a struct. Example:
//
// // Fields is not processed further by this package.
// Field time.Time `structs:",omitnested"`
// Field *http.Request `structs:",omitnested"`
//
// A tag value with the option of "omitempty" ignores that particular field and
// is not added to the values if the field value is empty. Example:
//
// // Field is skipped if empty
// Field string `structs:",omitempty"`
//
// Note that only exported fields of a struct can be accessed, non exported
// fields will be neglected.
func (s *Struct) Values() []interface{} {
fields := s.structFields()
var t []interface{}
for _, field := range fields {
val := s.value.FieldByName(field.Name)
_, tagOpts := parseTag(field.Tag.Get(s.TagName))
// if the value is a zero value and the field is marked as omitempty do
// not include
if tagOpts.Has("omitempty") {
zero := reflect.Zero(val.Type()).Interface()
current := val.Interface()
if reflect.DeepEqual(current, zero) {
continue
}
}
if IsStruct(val.Interface()) && !tagOpts.Has("omitnested") {
// look out for embedded structs, and convert them to a
// []interface{} to be added to the final values slice
for _, embeddedVal := range Values(val.Interface()) {
t = append(t, embeddedVal)
}
} else {
t = append(t, val.Interface())
}
}
return t
}
// Fields returns a slice of Fields. A struct tag with the content of "-"
// ignores the checking of that particular field. Example:
//
// // Field is ignored by this package.
// Field bool `structs:"-"`
//
// It panics if s's kind is not struct.
func (s *Struct) Fields() []*Field {
return getFields(s.value, s.TagName)
}
func getFields(v reflect.Value, tagName string) []*Field {
if v.Kind() == reflect.Ptr {
v = v.Elem()
}
t := v.Type()
var fields []*Field
for i := 0; i < t.NumField(); i++ {
field := t.Field(i)
if tag := field.Tag.Get(tagName); tag == "-" {
continue
}
f := &Field{
field: field,
value: v.FieldByName(field.Name),
}
fields = append(fields, f)
}
return fields
}
// Field returns a new Field struct that provides several high level functions
// around a single struct field entity. It panics if the field is not found.
func (s *Struct) Field(name string) *Field {
f, ok := s.FieldOk(name)
if !ok {
panic("field not found")
}
return f
}
// Field returns a new Field struct that provides several high level functions
// around a single struct field entity. The boolean returns true if the field
// was found.
func (s *Struct) FieldOk(name string) (*Field, bool) {
t := s.value.Type()
field, ok := t.FieldByName(name)
if !ok {
return nil, false
}
return &Field{
field: field,
value: s.value.FieldByName(name),
defaultTag: s.TagName,
}, true
}
// IsZero returns true if all fields in a struct is a zero value (not
// initialized) A struct tag with the content of "-" ignores the checking of
// that particular field. Example:
//
// // Field is ignored by this package.
// Field bool `structs:"-"`
//
// A value with the option of "omitnested" stops iterating further if the type
// is a struct. Example:
//
// // Field is not processed further by this package.
// Field time.Time `structs:"myName,omitnested"`
// Field *http.Request `structs:",omitnested"`
//
// Note that only exported fields of a struct can be accessed, non exported
// fields will be neglected. It panics if s's kind is not struct.
func (s *Struct) IsZero() bool {
fields := s.structFields()
for _, field := range fields {
val := s.value.FieldByName(field.Name)
_, tagOpts := parseTag(field.Tag.Get(s.TagName))
if IsStruct(val.Interface()) && !tagOpts.Has("omitnested") {
ok := IsZero(val.Interface())
if !ok {
return false
}
continue
}
// zero value of the given field, such as "" for string, 0 for int
zero := reflect.Zero(val.Type()).Interface()
// current value of the given field
current := val.Interface()
if !reflect.DeepEqual(current, zero) {
return false
}
}
return true
}
// HasZero returns true if a field in a struct is not initialized (zero value).
// A struct tag with the content of "-" ignores the checking of that particular
// field. Example:
//
// // Field is ignored by this package.
// Field bool `structs:"-"`
//
// A value with the option of "omitnested" stops iterating further if the type
// is a struct. Example:
//
// // Field is not processed further by this package.
// Field time.Time `structs:"myName,omitnested"`
// Field *http.Request `structs:",omitnested"`
//
// Note that only exported fields of a struct can be accessed, non exported
// fields will be neglected. It panics if s's kind is not struct.
func (s *Struct) HasZero() bool {
fields := s.structFields()
for _, field := range fields {
val := s.value.FieldByName(field.Name)
_, tagOpts := parseTag(field.Tag.Get(s.TagName))
if IsStruct(val.Interface()) && !tagOpts.Has("omitnested") {
ok := HasZero(val.Interface())
if ok {
return true
}
continue
}
// zero value of the given field, such as "" for string, 0 for int
zero := reflect.Zero(val.Type()).Interface()
// current value of the given field
current := val.Interface()
if reflect.DeepEqual(current, zero) {
return true
}
}
return false
}
// Name returns the structs's type name within its package. For more info refer
// to Name() function.
func (s *Struct) Name() string {
return s.value.Type().Name()
}
// structFields returns the exported struct fields for a given s struct. This
// is a convenient helper method to avoid duplicate code in some of the
// functions.
func (s *Struct) structFields() []reflect.StructField {
t := s.value.Type()
var f []reflect.StructField
for i := 0; i < t.NumField(); i++ {
field := t.Field(i)
// we can't access the value of unexported fields
if field.PkgPath != "" {
continue
}
// don't check if it's omitted
if tag := field.Tag.Get(s.TagName); tag == "-" {
continue
}
f = append(f, field)
}
return f
}
func strctVal(s interface{}) reflect.Value {
v := reflect.ValueOf(s)
// if pointer get the underlying element≤
if v.Kind() == reflect.Ptr {
v = v.Elem()
}
if v.Kind() != reflect.Struct {
panic("not struct")
}
return v
}
// Map converts the given struct to a map[string]interface{}. For more info
// refer to Struct types Map() method. It panics if s's kind is not struct.
func Map(s interface{}) map[string]interface{} {
return New(s).Map()
}
// Values converts the given struct to a []interface{}. For more info refer to
// Struct types Values() method. It panics if s's kind is not struct.
func Values(s interface{}) []interface{} {
return New(s).Values()
}
// Fields returns a slice of *Field. For more info refer to Struct types
// Fields() method. It panics if s's kind is not struct.
func Fields(s interface{}) []*Field {
return New(s).Fields()
}
// IsZero returns true if all fields is equal to a zero value. For more info
// refer to Struct types IsZero() method. It panics if s's kind is not struct.
func IsZero(s interface{}) bool {
return New(s).IsZero()
}
// HasZero returns true if any field is equal to a zero value. For more info
// refer to Struct types HasZero() method. It panics if s's kind is not struct.
func HasZero(s interface{}) bool {
return New(s).HasZero()
}
// IsStruct returns true if the given variable is a struct or a pointer to
// struct.
func IsStruct(s interface{}) bool {
v := reflect.ValueOf(s)
if v.Kind() == reflect.Ptr {
v = v.Elem()
}
// uninitialized zero value of a struct
if v.Kind() == reflect.Invalid {
return false
}
return v.Kind() == reflect.Struct
}
// Name returns the structs's type name within its package. It returns an
// empty string for unnamed types. It panics if s's kind is not struct.
func Name(s interface{}) string {
return New(s).Name()
}

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@ -1,351 +0,0 @@
package structs
import (
"fmt"
"time"
)
func ExampleNew() {
type Server struct {
Name string
ID int32
Enabled bool
}
server := &Server{
Name: "Arslan",
ID: 123456,
Enabled: true,
}
s := New(server)
fmt.Printf("Name : %v\n", s.Name())
fmt.Printf("Values : %v\n", s.Values())
fmt.Printf("Value of ID : %v\n", s.Field("ID").Value())
// Output:
// Name : Server
// Values : [Arslan 123456 true]
// Value of ID : 123456
}
func ExampleMap() {
type Server struct {
Name string
ID int32
Enabled bool
}
s := &Server{
Name: "Arslan",
ID: 123456,
Enabled: true,
}
m := Map(s)
fmt.Printf("%#v\n", m["Name"])
fmt.Printf("%#v\n", m["ID"])
fmt.Printf("%#v\n", m["Enabled"])
// Output:
// "Arslan"
// 123456
// true
}
func ExampleMap_tags() {
// Custom tags can change the map keys instead of using the fields name
type Server struct {
Name string `structs:"server_name"`
ID int32 `structs:"server_id"`
Enabled bool `structs:"enabled"`
}
s := &Server{
Name: "Zeynep",
ID: 789012,
}
m := Map(s)
// access them by the custom tags defined above
fmt.Printf("%#v\n", m["server_name"])
fmt.Printf("%#v\n", m["server_id"])
fmt.Printf("%#v\n", m["enabled"])
// Output:
// "Zeynep"
// 789012
// false
}
func ExampleMap_nested() {
// By default field with struct types are processed too. We can stop
// processing them via "omitnested" tag option.
type Server struct {
Name string `structs:"server_name"`
ID int32 `structs:"server_id"`
Time time.Time `structs:"time,omitnested"` // do not convert to map[string]interface{}
}
const shortForm = "2006-Jan-02"
t, _ := time.Parse("2006-Jan-02", "2013-Feb-03")
s := &Server{
Name: "Zeynep",
ID: 789012,
Time: t,
}
m := Map(s)
// access them by the custom tags defined above
fmt.Printf("%v\n", m["server_name"])
fmt.Printf("%v\n", m["server_id"])
fmt.Printf("%v\n", m["time"].(time.Time))
// Output:
// Zeynep
// 789012
// 2013-02-03 00:00:00 +0000 UTC
}
func ExampleMap_omitEmpty() {
// By default field with struct types of zero values are processed too. We
// can stop processing them via "omitempty" tag option.
type Server struct {
Name string `structs:",omitempty"`
ID int32 `structs:"server_id,omitempty"`
Location string
}
// Only add location
s := &Server{
Location: "Tokyo",
}
m := Map(s)
// map contains only the Location field
fmt.Printf("%v\n", m)
// Output:
// map[Location:Tokyo]
}
func ExampleValues() {
type Server struct {
Name string
ID int32
Enabled bool
}
s := &Server{
Name: "Fatih",
ID: 135790,
Enabled: false,
}
m := Values(s)
fmt.Printf("Values: %+v\n", m)
// Output:
// Values: [Fatih 135790 false]
}
func ExampleValues_omitEmpty() {
// By default field with struct types of zero values are processed too. We
// can stop processing them via "omitempty" tag option.
type Server struct {
Name string `structs:",omitempty"`
ID int32 `structs:"server_id,omitempty"`
Location string
}
// Only add location
s := &Server{
Location: "Ankara",
}
m := Values(s)
// values contains only the Location field
fmt.Printf("Values: %+v\n", m)
// Output:
// Values: [Ankara]
}
func ExampleValues_tags() {
type Location struct {
City string
Country string
}
type Server struct {
Name string
ID int32
Enabled bool
Location Location `structs:"-"` // values from location are not included anymore
}
s := &Server{
Name: "Fatih",
ID: 135790,
Enabled: false,
Location: Location{City: "Ankara", Country: "Turkey"},
}
// Let get all values from the struct s. Note that we don't include values
// from the Location field
m := Values(s)
fmt.Printf("Values: %+v\n", m)
// Output:
// Values: [Fatih 135790 false]
}
func ExampleFields() {
type Access struct {
Name string
LastAccessed time.Time
Number int
}
s := &Access{
Name: "Fatih",
LastAccessed: time.Now(),
Number: 1234567,
}
fields := Fields(s)
for i, field := range fields {
fmt.Printf("[%d] %+v\n", i, field.Name())
}
// Output:
// [0] Name
// [1] LastAccessed
// [2] Number
}
func ExampleFields_nested() {
type Person struct {
Name string
Number int
}
type Access struct {
Person Person
HasPermission bool
LastAccessed time.Time
}
s := &Access{
Person: Person{Name: "fatih", Number: 1234567},
LastAccessed: time.Now(),
HasPermission: true,
}
// Let's get all fields from the struct s.
fields := Fields(s)
for _, field := range fields {
if field.Name() == "Person" {
fmt.Printf("Access.Person.Name: %+v\n", field.Field("Name").Value())
}
}
// Output:
// Access.Person.Name: fatih
}
func ExampleField() {
type Person struct {
Name string
Number int
}
type Access struct {
Person Person
HasPermission bool
LastAccessed time.Time
}
access := &Access{
Person: Person{Name: "fatih", Number: 1234567},
LastAccessed: time.Now(),
HasPermission: true,
}
// Create a new Struct type
s := New(access)
// Get the Field type for "Person" field
p := s.Field("Person")
// Get the underlying "Name field" and print the value of it
name := p.Field("Name")
fmt.Printf("Value of Person.Access.Name: %+v\n", name.Value())
// Output:
// Value of Person.Access.Name: fatih
}
func ExampleIsZero() {
type Server struct {
Name string
ID int32
Enabled bool
}
// Nothing is initalized
a := &Server{}
isZeroA := IsZero(a)
// Name and Enabled is initialized, but not ID
b := &Server{
Name: "Golang",
Enabled: true,
}
isZeroB := IsZero(b)
fmt.Printf("%#v\n", isZeroA)
fmt.Printf("%#v\n", isZeroB)
// Output:
// true
// false
}
func ExampleHasZero() {
// Let's define an Access struct. Note that the "Enabled" field is not
// going to be checked because we added the "structs" tag to the field.
type Access struct {
Name string
LastAccessed time.Time
Number int
Enabled bool `structs:"-"`
}
// Name and Number is not initialized.
a := &Access{
LastAccessed: time.Now(),
}
hasZeroA := HasZero(a)
// Name and Number is initialized.
b := &Access{
Name: "Fatih",
LastAccessed: time.Now(),
Number: 12345,
}
hasZeroB := HasZero(b)
fmt.Printf("%#v\n", hasZeroA)
fmt.Printf("%#v\n", hasZeroB)
// Output:
// true
// false
}

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@ -1,847 +0,0 @@
package structs
import (
"fmt"
"reflect"
"testing"
"time"
)
func TestMapNonStruct(t *testing.T) {
foo := []string{"foo"}
defer func() {
err := recover()
if err == nil {
t.Error("Passing a non struct into Map should panic")
}
}()
// this should panic. We are going to recover and and test it
_ = Map(foo)
}
func TestStructIndexes(t *testing.T) {
type C struct {
something int
Props map[string]interface{}
}
defer func() {
err := recover()
if err != nil {
fmt.Printf("err %+v\n", err)
t.Error("Using mixed indexes should not panic")
}
}()
// They should not panic
_ = Map(&C{})
_ = Fields(&C{})
_ = Values(&C{})
_ = IsZero(&C{})
_ = HasZero(&C{})
}
func TestMap(t *testing.T) {
var T = struct {
A string
B int
C bool
}{
A: "a-value",
B: 2,
C: true,
}
a := Map(T)
if typ := reflect.TypeOf(a).Kind(); typ != reflect.Map {
t.Errorf("Map should return a map type, got: %v", typ)
}
// we have three fields
if len(a) != 3 {
t.Errorf("Map should return a map of len 3, got: %d", len(a))
}
inMap := func(val interface{}) bool {
for _, v := range a {
if reflect.DeepEqual(v, val) {
return true
}
}
return false
}
for _, val := range []interface{}{"a-value", 2, true} {
if !inMap(val) {
t.Errorf("Map should have the value %v", val)
}
}
}
func TestMap_Tag(t *testing.T) {
var T = struct {
A string `structs:"x"`
B int `structs:"y"`
C bool `structs:"z"`
}{
A: "a-value",
B: 2,
C: true,
}
a := Map(T)
inMap := func(key interface{}) bool {
for k := range a {
if reflect.DeepEqual(k, key) {
return true
}
}
return false
}
for _, key := range []string{"x", "y", "z"} {
if !inMap(key) {
t.Errorf("Map should have the key %v", key)
}
}
}
func TestMap_CustomTag(t *testing.T) {
var T = struct {
A string `dd:"x"`
B int `dd:"y"`
C bool `dd:"z"`
}{
A: "a-value",
B: 2,
C: true,
}
s := New(T)
s.TagName = "dd"
a := s.Map()
inMap := func(key interface{}) bool {
for k := range a {
if reflect.DeepEqual(k, key) {
return true
}
}
return false
}
for _, key := range []string{"x", "y", "z"} {
if !inMap(key) {
t.Errorf("Map should have the key %v", key)
}
}
}
func TestMap_MultipleCustomTag(t *testing.T) {
var A = struct {
X string `aa:"ax"`
}{"a_value"}
aStruct := New(A)
aStruct.TagName = "aa"
var B = struct {
X string `bb:"bx"`
}{"b_value"}
bStruct := New(B)
bStruct.TagName = "bb"
a, b := aStruct.Map(), bStruct.Map()
if !reflect.DeepEqual(a, map[string]interface{}{"ax": "a_value"}) {
t.Error("Map should have field ax with value a_value")
}
if !reflect.DeepEqual(b, map[string]interface{}{"bx": "b_value"}) {
t.Error("Map should have field bx with value b_value")
}
}
func TestMap_OmitEmpty(t *testing.T) {
type A struct {
Name string
Value string `structs:",omitempty"`
Time time.Time `structs:",omitempty"`
}
a := A{}
m := Map(a)
_, ok := m["Value"].(map[string]interface{})
if ok {
t.Error("Map should not contain the Value field that is tagged as omitempty")
}
_, ok = m["Time"].(map[string]interface{})
if ok {
t.Error("Map should not contain the Time field that is tagged as omitempty")
}
}
func TestMap_OmitNested(t *testing.T) {
type A struct {
Name string
Value string
Time time.Time `structs:",omitnested"`
}
a := A{Time: time.Now()}
type B struct {
Desc string
A A
}
b := &B{A: a}
m := Map(b)
in, ok := m["A"].(map[string]interface{})
if !ok {
t.Error("Map nested structs is not available in the map")
}
// should not happen
if _, ok := in["Time"].(map[string]interface{}); ok {
t.Error("Map nested struct should omit recursiving parsing of Time")
}
if _, ok := in["Time"].(time.Time); !ok {
t.Error("Map nested struct should stop parsing of Time at is current value")
}
}
func TestMap_Nested(t *testing.T) {
type A struct {
Name string
}
a := &A{Name: "example"}
type B struct {
A *A
}
b := &B{A: a}
m := Map(b)
if typ := reflect.TypeOf(m).Kind(); typ != reflect.Map {
t.Errorf("Map should return a map type, got: %v", typ)
}
in, ok := m["A"].(map[string]interface{})
if !ok {
t.Error("Map nested structs is not available in the map")
}
if name := in["Name"].(string); name != "example" {
t.Errorf("Map nested struct's name field should give example, got: %s", name)
}
}
func TestMap_Anonymous(t *testing.T) {
type A struct {
Name string
}
a := &A{Name: "example"}
type B struct {
*A
}
b := &B{}
b.A = a
m := Map(b)
if typ := reflect.TypeOf(m).Kind(); typ != reflect.Map {
t.Errorf("Map should return a map type, got: %v", typ)
}
in, ok := m["A"].(map[string]interface{})
if !ok {
t.Error("Embedded structs is not available in the map")
}
if name := in["Name"].(string); name != "example" {
t.Errorf("Embedded A struct's Name field should give example, got: %s", name)
}
}
func TestStruct(t *testing.T) {
var T = struct{}{}
if !IsStruct(T) {
t.Errorf("T should be a struct, got: %T", T)
}
if !IsStruct(&T) {
t.Errorf("T should be a struct, got: %T", T)
}
}
func TestValues(t *testing.T) {
var T = struct {
A string
B int
C bool
}{
A: "a-value",
B: 2,
C: true,
}
s := Values(T)
if typ := reflect.TypeOf(s).Kind(); typ != reflect.Slice {
t.Errorf("Values should return a slice type, got: %v", typ)
}
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v, val) {
return true
}
}
return false
}
for _, val := range []interface{}{"a-value", 2, true} {
if !inSlice(val) {
t.Errorf("Values should have the value %v", val)
}
}
}
func TestValues_OmitEmpty(t *testing.T) {
type A struct {
Name string
Value int `structs:",omitempty"`
}
a := A{Name: "example"}
s := Values(a)
if len(s) != 1 {
t.Errorf("Values of omitted empty fields should be not counted")
}
if s[0].(string) != "example" {
t.Errorf("Values of omitted empty fields should left the value example")
}
}
func TestValues_OmitNested(t *testing.T) {
type A struct {
Name string
Value int
}
a := A{
Name: "example",
Value: 123,
}
type B struct {
A A `structs:",omitnested"`
C int
}
b := &B{A: a, C: 123}
s := Values(b)
if len(s) != 2 {
t.Errorf("Values of omitted nested struct should be not counted")
}
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v, val) {
return true
}
}
return false
}
for _, val := range []interface{}{123, a} {
if !inSlice(val) {
t.Errorf("Values should have the value %v", val)
}
}
}
func TestValues_Nested(t *testing.T) {
type A struct {
Name string
}
a := A{Name: "example"}
type B struct {
A A
C int
}
b := &B{A: a, C: 123}
s := Values(b)
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v, val) {
return true
}
}
return false
}
for _, val := range []interface{}{"example", 123} {
if !inSlice(val) {
t.Errorf("Values should have the value %v", val)
}
}
}
func TestValues_Anonymous(t *testing.T) {
type A struct {
Name string
}
a := A{Name: "example"}
type B struct {
A
C int
}
b := &B{C: 123}
b.A = a
s := Values(b)
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v, val) {
return true
}
}
return false
}
for _, val := range []interface{}{"example", 123} {
if !inSlice(val) {
t.Errorf("Values should have the value %v", val)
}
}
}
func TestFields(t *testing.T) {
var T = struct {
A string
B int
C bool
}{
A: "a-value",
B: 2,
C: true,
}
s := Fields(T)
if len(s) != 3 {
t.Errorf("Fields should return a slice of len 3, got: %d", len(s))
}
inSlice := func(val string) bool {
for _, v := range s {
if reflect.DeepEqual(v.Name(), val) {
return true
}
}
return false
}
for _, val := range []string{"A", "B", "C"} {
if !inSlice(val) {
t.Errorf("Fields should have the value %v", val)
}
}
}
func TestFields_OmitNested(t *testing.T) {
type A struct {
Name string
Enabled bool
}
a := A{Name: "example"}
type B struct {
A A
C int
Value string `structs:"-"`
Number int
}
b := &B{A: a, C: 123}
s := Fields(b)
if len(s) != 3 {
t.Errorf("Fields should omit nested struct. Expecting 2 got: %d", len(s))
}
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v.Name(), val) {
return true
}
}
return false
}
for _, val := range []interface{}{"A", "C"} {
if !inSlice(val) {
t.Errorf("Fields should have the value %v", val)
}
}
}
func TestFields_Anonymous(t *testing.T) {
type A struct {
Name string
}
a := A{Name: "example"}
type B struct {
A
C int
}
b := &B{C: 123}
b.A = a
s := Fields(b)
inSlice := func(val interface{}) bool {
for _, v := range s {
if reflect.DeepEqual(v.Name(), val) {
return true
}
}
return false
}
for _, val := range []interface{}{"A", "C"} {
if !inSlice(val) {
t.Errorf("Fields should have the value %v", val)
}
}
}
func TestIsZero(t *testing.T) {
var T = struct {
A string
B int
C bool `structs:"-"`
D []string
}{}
ok := IsZero(T)
if !ok {
t.Error("IsZero should return true because none of the fields are initialized.")
}
var X = struct {
A string
F *bool
}{
A: "a-value",
}
ok = IsZero(X)
if ok {
t.Error("IsZero should return false because A is initialized")
}
var Y = struct {
A string
B int
}{
A: "a-value",
B: 123,
}
ok = IsZero(Y)
if ok {
t.Error("IsZero should return false because A and B is initialized")
}
}
func TestIsZero_OmitNested(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A A `structs:",omitnested"`
C int
}
b := &B{A: a, C: 123}
ok := IsZero(b)
if ok {
t.Error("IsZero should return false because A, B and C are initialized")
}
aZero := A{}
bZero := &B{A: aZero}
ok = IsZero(bZero)
if !ok {
t.Error("IsZero should return true because neither A nor B is initialized")
}
}
func TestIsZero_Nested(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A A
C int
}
b := &B{A: a, C: 123}
ok := IsZero(b)
if ok {
t.Error("IsZero should return false because A, B and C are initialized")
}
aZero := A{}
bZero := &B{A: aZero}
ok = IsZero(bZero)
if !ok {
t.Error("IsZero should return true because neither A nor B is initialized")
}
}
func TestIsZero_Anonymous(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A
C int
}
b := &B{C: 123}
b.A = a
ok := IsZero(b)
if ok {
t.Error("IsZero should return false because A, B and C are initialized")
}
aZero := A{}
bZero := &B{}
bZero.A = aZero
ok = IsZero(bZero)
if !ok {
t.Error("IsZero should return true because neither A nor B is initialized")
}
}
func TestHasZero(t *testing.T) {
var T = struct {
A string
B int
C bool `structs:"-"`
D []string
}{
A: "a-value",
B: 2,
}
ok := HasZero(T)
if !ok {
t.Error("HasZero should return true because A and B are initialized.")
}
var X = struct {
A string
F *bool
}{
A: "a-value",
}
ok = HasZero(X)
if !ok {
t.Error("HasZero should return true because A is initialized")
}
var Y = struct {
A string
B int
}{
A: "a-value",
B: 123,
}
ok = HasZero(Y)
if ok {
t.Error("HasZero should return false because A and B is initialized")
}
}
func TestHasZero_OmitNested(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A A `structs:",omitnested"`
C int
}
b := &B{A: a, C: 123}
// Because the Field A inside B is omitted HasZero should return false
// because it will stop iterating deeper andnot going to lookup for D
ok := HasZero(b)
if ok {
t.Error("HasZero should return false because A and C are initialized")
}
}
func TestHasZero_Nested(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A A
C int
}
b := &B{A: a, C: 123}
ok := HasZero(b)
if !ok {
t.Error("HasZero should return true because D is not initialized")
}
}
func TestHasZero_Anonymous(t *testing.T) {
type A struct {
Name string
D string
}
a := A{Name: "example"}
type B struct {
A
C int
}
b := &B{C: 123}
b.A = a
ok := HasZero(b)
if !ok {
t.Error("HasZero should return false because D is not initialized")
}
}
func TestName(t *testing.T) {
type Foo struct {
A string
B bool
}
f := &Foo{}
n := Name(f)
if n != "Foo" {
t.Errorf("Name should return Foo, got: %s", n)
}
unnamed := struct{ Name string }{Name: "Cihangir"}
m := Name(unnamed)
if m != "" {
t.Errorf("Name should return empty string for unnamed struct, got: %s", n)
}
defer func() {
err := recover()
if err == nil {
t.Error("Name should panic if a non struct is passed")
}
}()
Name([]string{})
}
func TestNestedNilPointer(t *testing.T) {
type Collar struct {
Engraving string
}
type Dog struct {
Name string
Collar *Collar
}
type Person struct {
Name string
Dog *Dog
}
person := &Person{
Name: "John",
}
personWithDog := &Person{
Name: "Ron",
Dog: &Dog{
Name: "Rover",
},
}
personWithDogWithCollar := &Person{
Name: "Kon",
Dog: &Dog{
Name: "Ruffles",
Collar: &Collar{
Engraving: "If lost, call Kon",
},
},
}
defer func() {
err := recover()
if err != nil {
fmt.Printf("err %+v\n", err)
t.Error("Internal nil pointer should not panic")
}
}()
_ = Map(person) // Panics
_ = Map(personWithDog) // Panics
_ = Map(personWithDogWithCollar) // Doesn't panic
}

View File

@ -1,32 +0,0 @@
package structs
import "strings"
// tagOptions contains a slice of tag options
type tagOptions []string
// Has returns true if the given optiton is available in tagOptions
func (t tagOptions) Has(opt string) bool {
for _, tagOpt := range t {
if tagOpt == opt {
return true
}
}
return false
}
// parseTag splits a struct field's tag into its name and a list of options
// which comes after a name. A tag is in the form of: "name,option1,option2".
// The name can be neglectected.
func parseTag(tag string) (string, tagOptions) {
// tag is one of followings:
// ""
// "name"
// "name,opt"
// "name,opt,opt2"
// ",opt"
res := strings.Split(tag, ",")
return res[0], res[1:]
}

View File

@ -1,46 +0,0 @@
package structs
import "testing"
func TestParseTag_Name(t *testing.T) {
tags := []struct {
tag string
has bool
}{
{"", false},
{"name", true},
{"name,opt", true},
{"name , opt, opt2", false}, // has a single whitespace
{", opt, opt2", false},
}
for _, tag := range tags {
name, _ := parseTag(tag.tag)
if (name != "name") && tag.has {
t.Errorf("Parse tag should return name: %#v", tag)
}
}
}
func TestParseTag_Opts(t *testing.T) {
tags := []struct {
opts string
has bool
}{
{"name", false},
{"name,opt", true},
{"name , opt, opt2", false}, // has a single whitespace
{",opt, opt2", true},
{", opt3, opt4", false},
}
// search for "opt"
for _, tag := range tags {
_, opts := parseTag(tag.opts)
if opts.Has("opt") != tag.has {
t.Errorf("Tag opts should have opt: %#v", tag)
}
}
}

View File

@ -3,8 +3,8 @@
package check_test
import (
. "gopkg.in/check.v1"
"time"
. "gopkg.in/check.v1"
)
var benchmarkS = Suite(&BenchmarkS{})

View File

@ -1,7 +1,7 @@
package check_test
import (
. "gopkg.in/check.v1"
. "gopkg.in/check.v1"
)
var _ = Suite(&PrinterS{})
@ -9,101 +9,96 @@ var _ = Suite(&PrinterS{})
type PrinterS struct{}
func (s *PrinterS) TestCountSuite(c *C) {
suitesRun += 1
suitesRun += 1
}
var printTestFuncLine int
func init() {
printTestFuncLine = getMyLine() + 3
printTestFuncLine = getMyLine() + 3
}
func printTestFunc() {
println(1) // Comment1
if 2 == 2 { // Comment2
println(3) // Comment3
}
switch 5 {
case 6:
println(6) // Comment6
println(7)
}
switch interface{}(9).(type) { // Comment9
case int:
println(10)
println(11)
}
select {
case <-(chan bool)(nil):
println(14)
println(15)
default:
println(16)
println(17)
}
println(19,
20)
_ = func() {
println(21)
println(22)
}
println(24, func() {
println(25)
})
// Leading comment
// with multiple lines.
println(29) // Comment29
println(1) // Comment1
if 2 == 2 { // Comment2
println(3) // Comment3
}
switch 5 {
case 6: println(6) // Comment6
println(7)
}
switch interface{}(9).(type) {// Comment9
case int: println(10)
println(11)
}
select {
case <-(chan bool)(nil): println(14)
println(15)
default: println(16)
println(17)
}
println(19,
20)
_ = func() { println(21)
println(22)
}
println(24, func() {
println(25)
})
// Leading comment
// with multiple lines.
println(29) // Comment29
}
var printLineTests = []struct {
line int
output string
line int
output string
}{
{1, "println(1) // Comment1"},
{2, "if 2 == 2 { // Comment2\n ...\n}"},
{3, "println(3) // Comment3"},
{5, "switch 5 {\n...\n}"},
{6, "case 6:\n println(6) // Comment6\n ..."},
{7, "println(7)"},
{9, "switch interface{}(9).(type) { // Comment9\n...\n}"},
{10, "case int:\n println(10)\n ..."},
{14, "case <-(chan bool)(nil):\n println(14)\n ..."},
{15, "println(15)"},
{16, "default:\n println(16)\n ..."},
{17, "println(17)"},
{19, "println(19,\n 20)"},
{20, "println(19,\n 20)"},
{21, "_ = func() {\n println(21)\n println(22)\n}"},
{22, "println(22)"},
{24, "println(24, func() {\n println(25)\n})"},
{25, "println(25)"},
{26, "println(24, func() {\n println(25)\n})"},
{29, "// Leading comment\n// with multiple lines.\nprintln(29) // Comment29"},
{1, "println(1) // Comment1"},
{2, "if 2 == 2 { // Comment2\n ...\n}"},
{3, "println(3) // Comment3"},
{5, "switch 5 {\n...\n}"},
{6, "case 6:\n println(6) // Comment6\n ..."},
{7, "println(7)"},
{9, "switch interface{}(9).(type) { // Comment9\n...\n}"},
{10, "case int:\n println(10)\n ..."},
{14, "case <-(chan bool)(nil):\n println(14)\n ..."},
{15, "println(15)"},
{16, "default:\n println(16)\n ..."},
{17, "println(17)"},
{19, "println(19,\n 20)"},
{20, "println(19,\n 20)"},
{21, "_ = func() {\n println(21)\n println(22)\n}"},
{22, "println(22)"},
{24, "println(24, func() {\n println(25)\n})"},
{25, "println(25)"},
{26, "println(24, func() {\n println(25)\n})"},
{29, "// Leading comment\n// with multiple lines.\nprintln(29) // Comment29"},
}
func (s *PrinterS) TestPrintLine(c *C) {
for _, test := range printLineTests {
output, err := PrintLine("printer_test.go", printTestFuncLine+test.line)
c.Assert(err, IsNil)
c.Assert(output, Equals, test.output)
}
for _, test := range printLineTests {
output, err := PrintLine("printer_test.go", printTestFuncLine+test.line)
c.Assert(err, IsNil)
c.Assert(output, Equals, test.output)
}
}
var indentTests = []struct {
in, out string
in, out string
}{
{"", ""},
{"\n", "\n"},
{"a", ">>>a"},
{"a\n", ">>>a\n"},
{"a\nb", ">>>a\n>>>b"},
{" ", ">>> "},
{"", ""},
{"\n", "\n"},
{"a", ">>>a"},
{"a\n", ">>>a\n"},
{"a\nb", ">>>a\n>>>b"},
{" ", ">>> "},
}
func (s *PrinterS) TestIndent(c *C) {
for _, test := range indentTests {
out := Indent(test.in, ">>>")
c.Assert(out, Equals, test.out)
}
for _, test := range indentTests {
out := Indent(test.in, ">>>")
c.Assert(out, Equals, test.out)
}
}

View File

@ -400,7 +400,7 @@ func (s *RunS) TestStreamModeWithMiss(c *C) {
// -----------------------------------------------------------------------
// Verify that that the keep work dir request indeed does so.
type WorkDirSuite struct{}
type WorkDirSuite struct {}
func (s *WorkDirSuite) Test(c *C) {
c.MkDir()
@ -411,7 +411,7 @@ func (s *RunS) TestKeepWorkDir(c *C) {
runConf := RunConf{Output: &output, Verbose: true, KeepWorkDir: true}
result := Run(&WorkDirSuite{}, &runConf)
c.Assert(result.String(), Matches, ".*\nWORK="+result.WorkDir)
c.Assert(result.String(), Matches, ".*\nWORK=" + result.WorkDir)
stat, err := os.Stat(result.WorkDir)
c.Assert(err, IsNil)