gitea/vendor/github.com/go-swagger/go-swagger/scan/responses.go
Antoine GIRARD 9fe4437bda Use vendored go-swagger (#8087)
* Use vendored go-swagger

* vendor go-swagger

* revert un wanteed change

* remove un-needed GO111MODULE

* Update Makefile

Co-Authored-By: techknowlogick <matti@mdranta.net>
2019-09-04 22:53:54 +03:00

447 lines
16 KiB
Go

// +build !go1.11
// Copyright 2015 go-swagger maintainers
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package scan
import (
"fmt"
"go/ast"
"strings"
"golang.org/x/tools/go/loader"
"github.com/go-openapi/spec"
)
type responseTypable struct {
in string
header *spec.Header
response *spec.Response
}
func (ht responseTypable) Level() int { return 0 }
func (ht responseTypable) Typed(tpe, format string) {
ht.header.Typed(tpe, format)
}
func bodyTypable(in string, schema *spec.Schema) (swaggerTypable, *spec.Schema) {
if in == "body" {
// get the schema for items on the schema property
if schema == nil {
schema = new(spec.Schema)
}
if schema.Items == nil {
schema.Items = new(spec.SchemaOrArray)
}
if schema.Items.Schema == nil {
schema.Items.Schema = new(spec.Schema)
}
schema.Typed("array", "")
return schemaTypable{schema.Items.Schema, 0}, schema
}
return nil, nil
}
func (ht responseTypable) Items() swaggerTypable {
bdt, schema := bodyTypable(ht.in, ht.response.Schema)
if bdt != nil {
ht.response.Schema = schema
return bdt
}
if ht.header.Items == nil {
ht.header.Items = new(spec.Items)
}
ht.header.Type = "array"
return itemsTypable{ht.header.Items, 1}
}
func (ht responseTypable) SetRef(ref spec.Ref) {
// having trouble seeing the usefulness of this one here
ht.Schema().Ref = ref
}
func (ht responseTypable) Schema() *spec.Schema {
if ht.response.Schema == nil {
ht.response.Schema = new(spec.Schema)
}
return ht.response.Schema
}
func (ht responseTypable) SetSchema(schema *spec.Schema) {
ht.response.Schema = schema
}
func (ht responseTypable) CollectionOf(items *spec.Items, format string) {
ht.header.CollectionOf(items, format)
}
type headerValidations struct {
current *spec.Header
}
func (sv headerValidations) SetMaximum(val float64, exclusive bool) {
sv.current.Maximum = &val
sv.current.ExclusiveMaximum = exclusive
}
func (sv headerValidations) SetMinimum(val float64, exclusive bool) {
sv.current.Minimum = &val
sv.current.ExclusiveMinimum = exclusive
}
func (sv headerValidations) SetMultipleOf(val float64) { sv.current.MultipleOf = &val }
func (sv headerValidations) SetMinItems(val int64) { sv.current.MinItems = &val }
func (sv headerValidations) SetMaxItems(val int64) { sv.current.MaxItems = &val }
func (sv headerValidations) SetMinLength(val int64) { sv.current.MinLength = &val }
func (sv headerValidations) SetMaxLength(val int64) { sv.current.MaxLength = &val }
func (sv headerValidations) SetPattern(val string) { sv.current.Pattern = val }
func (sv headerValidations) SetUnique(val bool) { sv.current.UniqueItems = val }
func (sv headerValidations) SetCollectionFormat(val string) { sv.current.CollectionFormat = val }
func (sv headerValidations) SetEnum(val string) {
sv.current.Enum = parseEnum(val, &spec.SimpleSchema{Type: sv.current.Type, Format: sv.current.Format})
}
func (sv headerValidations) SetDefault(val interface{}) { sv.current.Default = val }
func (sv headerValidations) SetExample(val interface{}) { sv.current.Example = val }
func newResponseDecl(file *ast.File, decl *ast.GenDecl, ts *ast.TypeSpec) responseDecl {
var rd responseDecl
rd.File = file
rd.Decl = decl
rd.TypeSpec = ts
rd.inferNames()
return rd
}
type responseDecl struct {
File *ast.File
Decl *ast.GenDecl
TypeSpec *ast.TypeSpec
GoName string
Name string
annotated bool
}
func (sd *responseDecl) hasAnnotation() bool {
sd.inferNames()
return sd.annotated
}
func (sd *responseDecl) inferNames() (goName string, name string) {
if sd.GoName != "" {
goName, name = sd.GoName, sd.Name
return
}
goName = sd.TypeSpec.Name.Name
name = goName
if sd.Decl.Doc != nil {
DECLS:
for _, cmt := range sd.Decl.Doc.List {
for _, ln := range strings.Split(cmt.Text, "\n") {
matches := rxResponseOverride.FindStringSubmatch(ln)
if len(matches) > 0 {
sd.annotated = true
}
if len(matches) > 1 && len(matches[1]) > 0 {
name = matches[1]
break DECLS
}
}
}
}
sd.GoName = goName
sd.Name = name
return
}
func newResponseParser(prog *loader.Program) *responseParser {
return &responseParser{prog, nil, newSchemaParser(prog)}
}
type responseParser struct {
program *loader.Program
postDecls []schemaDecl
scp *schemaParser
}
func (rp *responseParser) Parse(gofile *ast.File, target interface{}) error {
tgt := target.(map[string]spec.Response)
for _, decl := range gofile.Decls {
switch x1 := decl.(type) {
// Check for parameters at the package level.
case *ast.GenDecl:
for _, spc := range x1.Specs {
switch x2 := spc.(type) {
case *ast.TypeSpec:
sd := newResponseDecl(gofile, x1, x2)
if sd.hasAnnotation() {
if err := rp.parseDecl(tgt, sd); err != nil {
return err
}
}
}
}
// Check for parameters inside functions.
case *ast.FuncDecl:
for _, b := range x1.Body.List {
switch x2 := b.(type) {
case *ast.DeclStmt:
switch x3 := x2.Decl.(type) {
case *ast.GenDecl:
for _, spc := range x3.Specs {
switch x4 := spc.(type) {
case *ast.TypeSpec:
sd := newResponseDecl(gofile, x3, x4)
if sd.hasAnnotation() {
if err := rp.parseDecl(tgt, sd); err != nil {
return err
}
}
}
}
}
}
}
}
}
return nil
}
func (rp *responseParser) parseDecl(responses map[string]spec.Response, decl responseDecl) error {
// check if there is a swagger:parameters tag that is followed by one or more words,
// these words are the ids of the operations this parameter struct applies to
// once type name is found convert it to a schema, by looking up the schema in the
// parameters dictionary that got passed into this parse method
response := responses[decl.Name]
resPtr := &response
// analyze doc comment for the model
sp := new(sectionedParser)
sp.setDescription = func(lines []string) { resPtr.Description = joinDropLast(lines) }
if err := sp.Parse(decl.Decl.Doc); err != nil {
return err
}
// analyze struct body for fields etc
// each exported struct field:
// * gets a type mapped to a go primitive
// * perhaps gets a format
// * has to document the validations that apply for the type and the field
// * when the struct field points to a model it becomes a ref: #/definitions/ModelName
// * comments that aren't tags is used as the description
if tpe, ok := decl.TypeSpec.Type.(*ast.StructType); ok {
if err := rp.parseStructType(decl.File, resPtr, tpe, make(map[string]struct{})); err != nil {
return err
}
}
responses[decl.Name] = response
return nil
}
func (rp *responseParser) parseEmbeddedStruct(gofile *ast.File, response *spec.Response, expr ast.Expr, seenPreviously map[string]struct{}) error {
switch tpe := expr.(type) {
case *ast.Ident:
// do lookup of type
// take primitives into account, they should result in an error for swagger
pkg, err := rp.scp.packageForFile(gofile, tpe)
if err != nil {
return fmt.Errorf("embedded struct: %v", err)
}
file, _, ts, err := findSourceFile(pkg, tpe.Name)
if err != nil {
return fmt.Errorf("embedded struct: %v", err)
}
if st, ok := ts.Type.(*ast.StructType); ok {
return rp.parseStructType(file, response, st, seenPreviously)
}
case *ast.SelectorExpr:
// look up package, file and then type
pkg, err := rp.scp.packageForSelector(gofile, tpe.X)
if err != nil {
return fmt.Errorf("embedded struct: %v", err)
}
file, _, ts, err := findSourceFile(pkg, tpe.Sel.Name)
if err != nil {
return fmt.Errorf("embedded struct: %v", err)
}
if st, ok := ts.Type.(*ast.StructType); ok {
return rp.parseStructType(file, response, st, seenPreviously)
}
case *ast.StarExpr:
return rp.parseEmbeddedStruct(gofile, response, tpe.X, seenPreviously)
}
fmt.Printf("1%#v\n", expr)
return fmt.Errorf("unable to resolve embedded struct for: %v", expr)
}
func (rp *responseParser) parseStructType(gofile *ast.File, response *spec.Response, tpe *ast.StructType, seenPreviously map[string]struct{}) error {
if tpe.Fields != nil {
seenProperties := seenPreviously
for _, fld := range tpe.Fields.List {
if len(fld.Names) == 0 {
// when the embedded struct is annotated with swagger:allOf it will be used as allOf property
// otherwise the fields will just be included as normal properties
if err := rp.parseEmbeddedStruct(gofile, response, fld.Type, seenProperties); err != nil {
return err
}
}
}
for _, fld := range tpe.Fields.List {
if len(fld.Names) > 0 && fld.Names[0] != nil && fld.Names[0].IsExported() {
nm, ignore, _, err := parseJSONTag(fld)
if err != nil {
return err
}
if ignore {
continue
}
var in string
// scan for param location first, this changes some behavior down the line
if fld.Doc != nil {
for _, cmt := range fld.Doc.List {
for _, line := range strings.Split(cmt.Text, "\n") {
matches := rxIn.FindStringSubmatch(line)
if len(matches) > 0 && len(strings.TrimSpace(matches[1])) > 0 {
in = strings.TrimSpace(matches[1])
}
}
}
}
ps := response.Headers[nm]
// support swagger:file for response
// An API operation can return a file, such as an image or PDF. In this case,
// define the response schema with type: file and specify the appropriate MIME types in the produces section.
if fld.Doc != nil && fileParam(fld.Doc) {
response.Schema = &spec.Schema{}
response.Schema.Typed("file", "")
} else if err := rp.scp.parseNamedType(gofile, fld.Type, responseTypable{in, &ps, response}); err != nil {
return err
}
if strfmtName, ok := strfmtName(fld.Doc); ok {
ps.Typed("string", strfmtName)
}
sp := new(sectionedParser)
sp.setDescription = func(lines []string) { ps.Description = joinDropLast(lines) }
sp.taggers = []tagParser{
newSingleLineTagParser("maximum", &setMaximum{headerValidations{&ps}, rxf(rxMaximumFmt, "")}),
newSingleLineTagParser("minimum", &setMinimum{headerValidations{&ps}, rxf(rxMinimumFmt, "")}),
newSingleLineTagParser("multipleOf", &setMultipleOf{headerValidations{&ps}, rxf(rxMultipleOfFmt, "")}),
newSingleLineTagParser("minLength", &setMinLength{headerValidations{&ps}, rxf(rxMinLengthFmt, "")}),
newSingleLineTagParser("maxLength", &setMaxLength{headerValidations{&ps}, rxf(rxMaxLengthFmt, "")}),
newSingleLineTagParser("pattern", &setPattern{headerValidations{&ps}, rxf(rxPatternFmt, "")}),
newSingleLineTagParser("collectionFormat", &setCollectionFormat{headerValidations{&ps}, rxf(rxCollectionFormatFmt, "")}),
newSingleLineTagParser("minItems", &setMinItems{headerValidations{&ps}, rxf(rxMinItemsFmt, "")}),
newSingleLineTagParser("maxItems", &setMaxItems{headerValidations{&ps}, rxf(rxMaxItemsFmt, "")}),
newSingleLineTagParser("unique", &setUnique{headerValidations{&ps}, rxf(rxUniqueFmt, "")}),
newSingleLineTagParser("enum", &setEnum{headerValidations{&ps}, rxf(rxEnumFmt, "")}),
newSingleLineTagParser("default", &setDefault{&ps.SimpleSchema, headerValidations{&ps}, rxf(rxDefaultFmt, "")}),
newSingleLineTagParser("example", &setExample{&ps.SimpleSchema, headerValidations{&ps}, rxf(rxExampleFmt, "")}),
}
itemsTaggers := func(items *spec.Items, level int) []tagParser {
// the expression is 1-index based not 0-index
itemsPrefix := fmt.Sprintf(rxItemsPrefixFmt, level+1)
return []tagParser{
newSingleLineTagParser(fmt.Sprintf("items%dMaximum", level), &setMaximum{itemsValidations{items}, rxf(rxMaximumFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMinimum", level), &setMinimum{itemsValidations{items}, rxf(rxMinimumFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMultipleOf", level), &setMultipleOf{itemsValidations{items}, rxf(rxMultipleOfFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMinLength", level), &setMinLength{itemsValidations{items}, rxf(rxMinLengthFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMaxLength", level), &setMaxLength{itemsValidations{items}, rxf(rxMaxLengthFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dPattern", level), &setPattern{itemsValidations{items}, rxf(rxPatternFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dCollectionFormat", level), &setCollectionFormat{itemsValidations{items}, rxf(rxCollectionFormatFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMinItems", level), &setMinItems{itemsValidations{items}, rxf(rxMinItemsFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dMaxItems", level), &setMaxItems{itemsValidations{items}, rxf(rxMaxItemsFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dUnique", level), &setUnique{itemsValidations{items}, rxf(rxUniqueFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dEnum", level), &setEnum{itemsValidations{items}, rxf(rxEnumFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dDefault", level), &setDefault{&items.SimpleSchema, itemsValidations{items}, rxf(rxDefaultFmt, itemsPrefix)}),
newSingleLineTagParser(fmt.Sprintf("items%dExample", level), &setExample{&items.SimpleSchema, itemsValidations{items}, rxf(rxExampleFmt, itemsPrefix)}),
}
}
var parseArrayTypes func(expr ast.Expr, items *spec.Items, level int) ([]tagParser, error)
parseArrayTypes = func(expr ast.Expr, items *spec.Items, level int) ([]tagParser, error) {
if items == nil {
return []tagParser{}, nil
}
switch iftpe := expr.(type) {
case *ast.ArrayType:
eleTaggers := itemsTaggers(items, level)
sp.taggers = append(eleTaggers, sp.taggers...)
otherTaggers, err := parseArrayTypes(iftpe.Elt, items.Items, level+1)
if err != nil {
return nil, err
}
return otherTaggers, nil
case *ast.Ident:
taggers := []tagParser{}
if iftpe.Obj == nil {
taggers = itemsTaggers(items, level)
}
otherTaggers, err := parseArrayTypes(expr, items.Items, level+1)
if err != nil {
return nil, err
}
return append(taggers, otherTaggers...), nil
case *ast.StarExpr:
otherTaggers, err := parseArrayTypes(iftpe.X, items, level)
if err != nil {
return nil, err
}
return otherTaggers, nil
default:
return nil, fmt.Errorf("unknown field type ele for %q", nm)
}
}
// check if this is a primitive, if so parse the validations from the
// doc comments of the slice declaration.
if ftped, ok := fld.Type.(*ast.ArrayType); ok {
taggers, err := parseArrayTypes(ftped.Elt, ps.Items, 0)
if err != nil {
return err
}
sp.taggers = append(taggers, sp.taggers...)
}
if err := sp.Parse(fld.Doc); err != nil {
return err
}
if in != "body" {
seenProperties[nm] = struct{}{}
if response.Headers == nil {
response.Headers = make(map[string]spec.Header)
}
response.Headers[nm] = ps
}
}
}
for k := range response.Headers {
if _, ok := seenProperties[k]; !ok {
delete(response.Headers, k)
}
}
}
return nil
}