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|
package analysis
import (
"fmt"
"github.com/go-openapi/spec"
"github.com/go-openapi/strfmt"
)
// SchemaOpts configures the schema analyzer
type SchemaOpts struct {
Schema *spec.Schema
Root interface{}
BasePath string
_ struct{}
}
// Schema analysis, will classify the schema according to known
// patterns.
func Schema(opts SchemaOpts) (*AnalyzedSchema, error) {
if opts.Schema == nil {
return nil, fmt.Errorf("no schema to analyze")
}
a := &AnalyzedSchema{
schema: opts.Schema,
root: opts.Root,
basePath: opts.BasePath,
}
a.initializeFlags()
a.inferKnownType()
a.inferEnum()
a.inferBaseType()
if err := a.inferMap(); err != nil {
return nil, err
}
if err := a.inferArray(); err != nil {
return nil, err
}
a.inferTuple()
if err := a.inferFromRef(); err != nil {
return nil, err
}
a.inferSimpleSchema()
return a, nil
}
// AnalyzedSchema indicates what the schema represents
type AnalyzedSchema struct {
schema *spec.Schema
root interface{}
basePath string
hasProps bool
hasAllOf bool
hasItems bool
hasAdditionalProps bool
hasAdditionalItems bool
hasRef bool
IsKnownType bool
IsSimpleSchema bool
IsArray bool
IsSimpleArray bool
IsMap bool
IsSimpleMap bool
IsExtendedObject bool
IsTuple bool
IsTupleWithExtra bool
IsBaseType bool
IsEnum bool
}
// Inherits copies value fields from other onto this schema
func (a *AnalyzedSchema) inherits(other *AnalyzedSchema) {
if other == nil {
return
}
a.hasProps = other.hasProps
a.hasAllOf = other.hasAllOf
a.hasItems = other.hasItems
a.hasAdditionalItems = other.hasAdditionalItems
a.hasAdditionalProps = other.hasAdditionalProps
a.hasRef = other.hasRef
a.IsKnownType = other.IsKnownType
a.IsSimpleSchema = other.IsSimpleSchema
a.IsArray = other.IsArray
a.IsSimpleArray = other.IsSimpleArray
a.IsMap = other.IsMap
a.IsSimpleMap = other.IsSimpleMap
a.IsExtendedObject = other.IsExtendedObject
a.IsTuple = other.IsTuple
a.IsTupleWithExtra = other.IsTupleWithExtra
a.IsBaseType = other.IsBaseType
a.IsEnum = other.IsEnum
}
func (a *AnalyzedSchema) inferFromRef() error {
if a.hasRef {
sch := new(spec.Schema)
sch.Ref = a.schema.Ref
err := spec.ExpandSchema(sch, a.root, nil)
if err != nil {
return err
}
rsch, err := Schema(SchemaOpts{
Schema: sch,
Root: a.root,
BasePath: a.basePath,
})
if err != nil {
// NOTE(fredbi): currently the only cause for errors is
// unresolved ref. Since spec.ExpandSchema() expands the
// schema recursively, there is no chance to get there,
// until we add more causes for error in this schema analysis.
return err
}
a.inherits(rsch)
}
return nil
}
func (a *AnalyzedSchema) inferSimpleSchema() {
a.IsSimpleSchema = a.IsKnownType || a.IsSimpleArray || a.IsSimpleMap
}
func (a *AnalyzedSchema) inferKnownType() {
tpe := a.schema.Type
format := a.schema.Format
a.IsKnownType = tpe.Contains("boolean") ||
tpe.Contains("integer") ||
tpe.Contains("number") ||
tpe.Contains("string") ||
(format != "" && strfmt.Default.ContainsName(format)) ||
(a.isObjectType() && !a.hasProps && !a.hasAllOf && !a.hasAdditionalProps && !a.hasAdditionalItems)
}
func (a *AnalyzedSchema) inferMap() error {
if !a.isObjectType() {
return nil
}
hasExtra := a.hasProps || a.hasAllOf
a.IsMap = a.hasAdditionalProps && !hasExtra
a.IsExtendedObject = a.hasAdditionalProps && hasExtra
if !a.IsMap {
return nil
}
// maps
if a.schema.AdditionalProperties.Schema != nil {
msch, err := Schema(SchemaOpts{
Schema: a.schema.AdditionalProperties.Schema,
Root: a.root,
BasePath: a.basePath,
})
if err != nil {
return err
}
a.IsSimpleMap = msch.IsSimpleSchema
} else if a.schema.AdditionalProperties.Allows {
a.IsSimpleMap = true
}
return nil
}
func (a *AnalyzedSchema) inferArray() error {
// an array has Items defined as an object schema, otherwise we qualify this JSON array as a tuple
// (yes, even if the Items array contains only one element).
// arrays in JSON schema may be unrestricted (i.e no Items specified).
// Note that arrays in Swagger MUST have Items. Nonetheless, we analyze unrestricted arrays.
//
// NOTE: the spec package misses the distinction between:
// items: [] and items: {}, so we consider both arrays here.
a.IsArray = a.isArrayType() && (a.schema.Items == nil || a.schema.Items.Schemas == nil)
if a.IsArray && a.hasItems {
if a.schema.Items.Schema != nil {
itsch, err := Schema(SchemaOpts{
Schema: a.schema.Items.Schema,
Root: a.root,
BasePath: a.basePath,
})
if err != nil {
return err
}
a.IsSimpleArray = itsch.IsSimpleSchema
}
}
if a.IsArray && !a.hasItems {
a.IsSimpleArray = true
}
return nil
}
func (a *AnalyzedSchema) inferTuple() {
tuple := a.hasItems && a.schema.Items.Schemas != nil
a.IsTuple = tuple && !a.hasAdditionalItems
a.IsTupleWithExtra = tuple && a.hasAdditionalItems
}
func (a *AnalyzedSchema) inferBaseType() {
if a.isObjectType() {
a.IsBaseType = a.schema.Discriminator != ""
}
}
func (a *AnalyzedSchema) inferEnum() {
a.IsEnum = len(a.schema.Enum) > 0
}
func (a *AnalyzedSchema) initializeFlags() {
a.hasProps = len(a.schema.Properties) > 0
a.hasAllOf = len(a.schema.AllOf) > 0
a.hasRef = a.schema.Ref.String() != ""
a.hasItems = a.schema.Items != nil &&
(a.schema.Items.Schema != nil || len(a.schema.Items.Schemas) > 0)
a.hasAdditionalProps = a.schema.AdditionalProperties != nil &&
(a.schema.AdditionalProperties.Schema != nil || a.schema.AdditionalProperties.Allows)
a.hasAdditionalItems = a.schema.AdditionalItems != nil &&
(a.schema.AdditionalItems.Schema != nil || a.schema.AdditionalItems.Allows)
}
func (a *AnalyzedSchema) isObjectType() bool {
return !a.hasRef && (a.schema.Type == nil || a.schema.Type.Contains("") || a.schema.Type.Contains("object"))
}
func (a *AnalyzedSchema) isArrayType() bool {
return !a.hasRef && (a.schema.Type != nil && a.schema.Type.Contains("array"))
}
// isAnalyzedAsComplex determines if an analyzed schema is eligible to flattening (i.e. it is "complex").
//
// Complex means the schema is any of:
// - a simple type (primitive)
// - an array of something (items are possibly complex ; if this is the case, items will generate a definition)
// - a map of something (additionalProperties are possibly complex ; if this is the case, additionalProperties will
// generate a definition)
func (a *AnalyzedSchema) isAnalyzedAsComplex() bool {
return !a.IsSimpleSchema && !a.IsArray && !a.IsMap
}
|
