package schema import ( "context" "fmt" "reflect" "strings" "github.com/jinzhu/inflection" "gorm.io/gorm/clause" ) // RelationshipType relationship type type RelationshipType string const ( HasOne RelationshipType = "has_one" // HasOneRel has one relationship HasMany RelationshipType = "has_many" // HasManyRel has many relationship BelongsTo RelationshipType = "belongs_to" // BelongsToRel belongs to relationship Many2Many RelationshipType = "many_to_many" // Many2ManyRel many to many relationship has RelationshipType = "has" ) type Relationships struct { HasOne []*Relationship BelongsTo []*Relationship HasMany []*Relationship Many2Many []*Relationship Relations map[string]*Relationship } type Relationship struct { Name string Type RelationshipType Field *Field Polymorphic *Polymorphic References []*Reference Schema *Schema FieldSchema *Schema JoinTable *Schema foreignKeys, primaryKeys []string } type Polymorphic struct { PolymorphicID *Field PolymorphicType *Field Value string } type Reference struct { PrimaryKey *Field PrimaryValue string ForeignKey *Field OwnPrimaryKey bool } func (schema *Schema) parseRelation(field *Field) *Relationship { var ( err error fieldValue = reflect.New(field.IndirectFieldType).Interface() relation = &Relationship{ Name: field.Name, Field: field, Schema: schema, foreignKeys: toColumns(field.TagSettings["FOREIGNKEY"]), primaryKeys: toColumns(field.TagSettings["REFERENCES"]), } ) cacheStore := schema.cacheStore if relation.FieldSchema, err = getOrParse(fieldValue, cacheStore, schema.namer); err != nil { schema.err = err return nil } if polymorphic := field.TagSettings["POLYMORPHIC"]; polymorphic != "" { schema.buildPolymorphicRelation(relation, field, polymorphic) } else if many2many := field.TagSettings["MANY2MANY"]; many2many != "" { schema.buildMany2ManyRelation(relation, field, many2many) } else if belongsTo := field.TagSettings["BELONGSTO"]; belongsTo != "" { schema.guessRelation(relation, field, guessBelongs) } else { switch field.IndirectFieldType.Kind() { case reflect.Struct: schema.guessRelation(relation, field, guessGuess) case reflect.Slice: schema.guessRelation(relation, field, guessHas) default: schema.err = fmt.Errorf("unsupported data type %v for %v on field %s", relation.FieldSchema, schema, field.Name) } } if relation.Type == has { // don't add relations to embedded schema, which might be shared if relation.FieldSchema != relation.Schema && relation.Polymorphic == nil && field.OwnerSchema == nil { relation.FieldSchema.Relationships.Relations["_"+relation.Schema.Name+"_"+relation.Name] = relation } switch field.IndirectFieldType.Kind() { case reflect.Struct: relation.Type = HasOne case reflect.Slice: relation.Type = HasMany } } if schema.err == nil { schema.Relationships.Relations[relation.Name] = relation switch relation.Type { case HasOne: schema.Relationships.HasOne = append(schema.Relationships.HasOne, relation) case HasMany: schema.Relationships.HasMany = append(schema.Relationships.HasMany, relation) case BelongsTo: schema.Relationships.BelongsTo = append(schema.Relationships.BelongsTo, relation) case Many2Many: schema.Relationships.Many2Many = append(schema.Relationships.Many2Many, relation) } } return relation } // User has many Toys, its `Polymorphic` is `Owner`, Pet has one Toy, its `Polymorphic` is `Owner` // type User struct { // Toys []Toy `gorm:"polymorphic:Owner;"` // } // type Pet struct { // Toy Toy `gorm:"polymorphic:Owner;"` // } // type Toy struct { // OwnerID int // OwnerType string // } func (schema *Schema) buildPolymorphicRelation(relation *Relationship, field *Field, polymorphic string) { relation.Polymorphic = &Polymorphic{ Value: schema.Table, PolymorphicType: relation.FieldSchema.FieldsByName[polymorphic+"Type"], PolymorphicID: relation.FieldSchema.FieldsByName[polymorphic+"ID"], } if value, ok := field.TagSettings["POLYMORPHICVALUE"]; ok { relation.Polymorphic.Value = strings.TrimSpace(value) } if relation.Polymorphic.PolymorphicType == nil { schema.err = fmt.Errorf("invalid polymorphic type %v for %v on field %s, missing field %s", relation.FieldSchema, schema, field.Name, polymorphic+"Type") } if relation.Polymorphic.PolymorphicID == nil { schema.err = fmt.Errorf("invalid polymorphic type %v for %v on field %s, missing field %s", relation.FieldSchema, schema, field.Name, polymorphic+"ID") } if schema.err == nil { relation.References = append(relation.References, &Reference{ PrimaryValue: relation.Polymorphic.Value, ForeignKey: relation.Polymorphic.PolymorphicType, }) primaryKeyField := schema.PrioritizedPrimaryField if len(relation.foreignKeys) > 0 { if primaryKeyField = schema.LookUpField(relation.foreignKeys[0]); primaryKeyField == nil || len(relation.foreignKeys) > 1 { schema.err = fmt.Errorf("invalid polymorphic foreign keys %+v for %v on field %s", relation.foreignKeys, schema, field.Name) } } // use same data type for foreign keys if copyableDataType(primaryKeyField.DataType) { relation.Polymorphic.PolymorphicID.DataType = primaryKeyField.DataType } relation.Polymorphic.PolymorphicID.GORMDataType = primaryKeyField.GORMDataType if relation.Polymorphic.PolymorphicID.Size == 0 { relation.Polymorphic.PolymorphicID.Size = primaryKeyField.Size } relation.References = append(relation.References, &Reference{ PrimaryKey: primaryKeyField, ForeignKey: relation.Polymorphic.PolymorphicID, OwnPrimaryKey: true, }) } relation.Type = has } func (schema *Schema) buildMany2ManyRelation(relation *Relationship, field *Field, many2many string) { relation.Type = Many2Many var ( err error joinTableFields []reflect.StructField fieldsMap = map[string]*Field{} ownFieldsMap = map[string]*Field{} // fix self join many2many referFieldsMap = map[string]*Field{} joinForeignKeys = toColumns(field.TagSettings["JOINFOREIGNKEY"]) joinReferences = toColumns(field.TagSettings["JOINREFERENCES"]) ) ownForeignFields := schema.PrimaryFields refForeignFields := relation.FieldSchema.PrimaryFields if len(relation.foreignKeys) > 0 { ownForeignFields = []*Field{} for _, foreignKey := range relation.foreignKeys { if field := schema.LookUpField(foreignKey); field != nil { ownForeignFields = append(ownForeignFields, field) } else { schema.err = fmt.Errorf("invalid foreign key: %s", foreignKey) return } } } if len(relation.primaryKeys) > 0 { refForeignFields = []*Field{} for _, foreignKey := range relation.primaryKeys { if field := relation.FieldSchema.LookUpField(foreignKey); field != nil { refForeignFields = append(refForeignFields, field) } else { schema.err = fmt.Errorf("invalid foreign key: %s", foreignKey) return } } } for idx, ownField := range ownForeignFields { joinFieldName := strings.Title(schema.Name) + ownField.Name if len(joinForeignKeys) > idx { joinFieldName = strings.Title(joinForeignKeys[idx]) } ownFieldsMap[joinFieldName] = ownField fieldsMap[joinFieldName] = ownField joinTableFields = append(joinTableFields, reflect.StructField{ Name: joinFieldName, PkgPath: ownField.StructField.PkgPath, Type: ownField.StructField.Type, Tag: removeSettingFromTag(appendSettingFromTag(ownField.StructField.Tag, "primaryKey"), "column", "autoincrement", "index", "unique", "uniqueindex"), }) } for idx, relField := range refForeignFields { joinFieldName := strings.Title(relation.FieldSchema.Name) + relField.Name if _, ok := ownFieldsMap[joinFieldName]; ok { if field.Name != relation.FieldSchema.Name { joinFieldName = inflection.Singular(field.Name) + relField.Name } else { joinFieldName += "Reference" } } if len(joinReferences) > idx { joinFieldName = strings.Title(joinReferences[idx]) } referFieldsMap[joinFieldName] = relField if _, ok := fieldsMap[joinFieldName]; !ok { fieldsMap[joinFieldName] = relField joinTableFields = append(joinTableFields, reflect.StructField{ Name: joinFieldName, PkgPath: relField.StructField.PkgPath, Type: relField.StructField.Type, Tag: removeSettingFromTag(appendSettingFromTag(relField.StructField.Tag, "primaryKey"), "column", "autoincrement", "index", "unique", "uniqueindex"), }) } } joinTableFields = append(joinTableFields, reflect.StructField{ Name: strings.Title(schema.Name) + field.Name, Type: schema.ModelType, Tag: `gorm:"-"`, }) if relation.JoinTable, err = Parse(reflect.New(reflect.StructOf(joinTableFields)).Interface(), schema.cacheStore, schema.namer); err != nil { schema.err = err } relation.JoinTable.Name = many2many relation.JoinTable.Table = schema.namer.JoinTableName(many2many) relation.JoinTable.PrimaryFields = make([]*Field, 0, len(relation.JoinTable.Fields)) relName := relation.Schema.Name relRefName := relation.FieldSchema.Name if relName == relRefName { relRefName = relation.Field.Name } if _, ok := relation.JoinTable.Relationships.Relations[relName]; !ok { relation.JoinTable.Relationships.Relations[relName] = &Relationship{ Name: relName, Type: BelongsTo, Schema: relation.JoinTable, FieldSchema: relation.Schema, } } else { relation.JoinTable.Relationships.Relations[relName].References = []*Reference{} } if _, ok := relation.JoinTable.Relationships.Relations[relRefName]; !ok { relation.JoinTable.Relationships.Relations[relRefName] = &Relationship{ Name: relRefName, Type: BelongsTo, Schema: relation.JoinTable, FieldSchema: relation.FieldSchema, } } else { relation.JoinTable.Relationships.Relations[relRefName].References = []*Reference{} } // build references for _, f := range relation.JoinTable.Fields { if f.Creatable || f.Readable || f.Updatable { // use same data type for foreign keys if copyableDataType(fieldsMap[f.Name].DataType) { f.DataType = fieldsMap[f.Name].DataType } f.GORMDataType = fieldsMap[f.Name].GORMDataType if f.Size == 0 { f.Size = fieldsMap[f.Name].Size } relation.JoinTable.PrimaryFields = append(relation.JoinTable.PrimaryFields, f) if of, ok := ownFieldsMap[f.Name]; ok { joinRel := relation.JoinTable.Relationships.Relations[relName] joinRel.Field = relation.Field joinRel.References = append(joinRel.References, &Reference{ PrimaryKey: of, ForeignKey: f, }) relation.References = append(relation.References, &Reference{ PrimaryKey: of, ForeignKey: f, OwnPrimaryKey: true, }) } if rf, ok := referFieldsMap[f.Name]; ok { joinRefRel := relation.JoinTable.Relationships.Relations[relRefName] if joinRefRel.Field == nil { joinRefRel.Field = relation.Field } joinRefRel.References = append(joinRefRel.References, &Reference{ PrimaryKey: rf, ForeignKey: f, }) relation.References = append(relation.References, &Reference{ PrimaryKey: rf, ForeignKey: f, }) } } } } type guessLevel int const ( guessGuess guessLevel = iota guessBelongs guessEmbeddedBelongs guessHas guessEmbeddedHas ) func (schema *Schema) guessRelation(relation *Relationship, field *Field, cgl guessLevel) { var ( primaryFields, foreignFields []*Field primarySchema, foreignSchema = schema, relation.FieldSchema gl = cgl ) if gl == guessGuess { if field.Schema == relation.FieldSchema { gl = guessBelongs } else { gl = guessHas } } reguessOrErr := func() { switch cgl { case guessGuess: schema.guessRelation(relation, field, guessBelongs) case guessBelongs: schema.guessRelation(relation, field, guessEmbeddedBelongs) case guessEmbeddedBelongs: schema.guessRelation(relation, field, guessHas) case guessHas: schema.guessRelation(relation, field, guessEmbeddedHas) // case guessEmbeddedHas: default: schema.err = fmt.Errorf("invalid field found for struct %v's field %s: define a valid foreign key for relations or implement the Valuer/Scanner interface", schema, field.Name) } } switch gl { case guessBelongs: primarySchema, foreignSchema = relation.FieldSchema, schema case guessEmbeddedBelongs: if field.OwnerSchema == nil { reguessOrErr() return } primarySchema, foreignSchema = relation.FieldSchema, field.OwnerSchema case guessHas: case guessEmbeddedHas: if field.OwnerSchema == nil { reguessOrErr() return } primarySchema, foreignSchema = field.OwnerSchema, relation.FieldSchema } if len(relation.foreignKeys) > 0 { for _, foreignKey := range relation.foreignKeys { f := foreignSchema.LookUpField(foreignKey) if f == nil { reguessOrErr() return } foreignFields = append(foreignFields, f) } } else { var primarySchemaName = primarySchema.Name if primarySchemaName == "" { primarySchemaName = relation.FieldSchema.Name } if len(relation.primaryKeys) > 0 { for _, primaryKey := range relation.primaryKeys { if f := primarySchema.LookUpField(primaryKey); f != nil { primaryFields = append(primaryFields, f) } } } else { primaryFields = primarySchema.PrimaryFields } for _, primaryField := range primaryFields { lookUpName := primarySchemaName + primaryField.Name if gl == guessBelongs { lookUpName = field.Name + primaryField.Name } lookUpNames := []string{lookUpName} if len(primaryFields) == 1 { lookUpNames = append(lookUpNames, strings.TrimSuffix(lookUpName, primaryField.Name)+"ID", strings.TrimSuffix(lookUpName, primaryField.Name)+"Id", schema.namer.ColumnName(foreignSchema.Table, strings.TrimSuffix(lookUpName, primaryField.Name)+"ID")) } for _, name := range lookUpNames { if f := foreignSchema.LookUpField(name); f != nil { foreignFields = append(foreignFields, f) primaryFields = append(primaryFields, primaryField) break } } } } switch { case len(foreignFields) == 0: reguessOrErr() return case len(relation.primaryKeys) > 0: for idx, primaryKey := range relation.primaryKeys { if f := primarySchema.LookUpField(primaryKey); f != nil { if len(primaryFields) < idx+1 { primaryFields = append(primaryFields, f) } else if f != primaryFields[idx] { reguessOrErr() return } } else { reguessOrErr() return } } case len(primaryFields) == 0: if len(foreignFields) == 1 && primarySchema.PrioritizedPrimaryField != nil { primaryFields = append(primaryFields, primarySchema.PrioritizedPrimaryField) } else if len(primarySchema.PrimaryFields) == len(foreignFields) { primaryFields = append(primaryFields, primarySchema.PrimaryFields...) } else { reguessOrErr() return } } // build references for idx, foreignField := range foreignFields { // use same data type for foreign keys if copyableDataType(primaryFields[idx].DataType) { foreignField.DataType = primaryFields[idx].DataType } foreignField.GORMDataType = primaryFields[idx].GORMDataType if foreignField.Size == 0 { foreignField.Size = primaryFields[idx].Size } relation.References = append(relation.References, &Reference{ PrimaryKey: primaryFields[idx], ForeignKey: foreignField, OwnPrimaryKey: (schema == primarySchema && gl == guessHas) || (field.OwnerSchema == primarySchema && gl == guessEmbeddedHas), }) } if gl == guessHas || gl == guessEmbeddedHas { relation.Type = has } else { relation.Type = BelongsTo } } type Constraint struct { Name string Field *Field Schema *Schema ForeignKeys []*Field ReferenceSchema *Schema References []*Field OnDelete string OnUpdate string } func (rel *Relationship) ParseConstraint() *Constraint { str := rel.Field.TagSettings["CONSTRAINT"] if str == "-" { return nil } if rel.Type == BelongsTo { for _, r := range rel.FieldSchema.Relationships.Relations { if r != rel && r.FieldSchema == rel.Schema && len(rel.References) == len(r.References) { matched := true for idx, ref := range r.References { if !(rel.References[idx].PrimaryKey == ref.PrimaryKey && rel.References[idx].ForeignKey == ref.ForeignKey && rel.References[idx].PrimaryValue == ref.PrimaryValue) { matched = false } } if matched { return nil } } } } var ( name string idx = strings.Index(str, ",") settings = ParseTagSetting(str, ",") ) // optimize match english letters and midline // The following code is basically called in for. // In order to avoid the performance problems caused by repeated compilation of regular expressions, // it only needs to be done once outside, so optimization is done here. if idx != -1 && regEnLetterAndMidline.MatchString(str[0:idx]) { name = str[0:idx] } else { name = rel.Schema.namer.RelationshipFKName(*rel) } constraint := Constraint{ Name: name, Field: rel.Field, OnUpdate: settings["ONUPDATE"], OnDelete: settings["ONDELETE"], } for _, ref := range rel.References { if ref.PrimaryKey != nil && (rel.JoinTable == nil || ref.OwnPrimaryKey) { constraint.ForeignKeys = append(constraint.ForeignKeys, ref.ForeignKey) constraint.References = append(constraint.References, ref.PrimaryKey) if ref.OwnPrimaryKey { constraint.Schema = ref.ForeignKey.Schema constraint.ReferenceSchema = rel.Schema } else { constraint.Schema = rel.Schema constraint.ReferenceSchema = ref.PrimaryKey.Schema } } } return &constraint } func (rel *Relationship) ToQueryConditions(ctx context.Context, reflectValue reflect.Value) (conds []clause.Expression) { table := rel.FieldSchema.Table foreignFields := []*Field{} relForeignKeys := []string{} if rel.JoinTable != nil { table = rel.JoinTable.Table for _, ref := range rel.References { if ref.OwnPrimaryKey { foreignFields = append(foreignFields, ref.PrimaryKey) relForeignKeys = append(relForeignKeys, ref.ForeignKey.DBName) } else if ref.PrimaryValue != "" { conds = append(conds, clause.Eq{ Column: clause.Column{Table: rel.JoinTable.Table, Name: ref.ForeignKey.DBName}, Value: ref.PrimaryValue, }) } else { conds = append(conds, clause.Eq{ Column: clause.Column{Table: rel.JoinTable.Table, Name: ref.ForeignKey.DBName}, Value: clause.Column{Table: rel.FieldSchema.Table, Name: ref.PrimaryKey.DBName}, }) } } } else { for _, ref := range rel.References { if ref.OwnPrimaryKey { relForeignKeys = append(relForeignKeys, ref.ForeignKey.DBName) foreignFields = append(foreignFields, ref.PrimaryKey) } else if ref.PrimaryValue != "" { conds = append(conds, clause.Eq{ Column: clause.Column{Table: rel.FieldSchema.Table, Name: ref.ForeignKey.DBName}, Value: ref.PrimaryValue, }) } else { relForeignKeys = append(relForeignKeys, ref.PrimaryKey.DBName) foreignFields = append(foreignFields, ref.ForeignKey) } } } _, foreignValues := GetIdentityFieldValuesMap(ctx, reflectValue, foreignFields) column, values := ToQueryValues(table, relForeignKeys, foreignValues) conds = append(conds, clause.IN{Column: column, Values: values}) return } func copyableDataType(str DataType) bool { for _, s := range []string{"auto_increment", "primary key"} { if strings.Contains(strings.ToLower(string(str)), s) { return false } } return true }