package schema import ( "database/sql" "fmt" "reflect" "strings" "time" "github.com/jinzhu/inflection" "github.com/uptrace/bun/internal" "github.com/uptrace/bun/internal/tagparser" ) const ( beforeAppendModelHookFlag internal.Flag = 1 << iota beforeScanHookFlag afterScanHookFlag beforeScanRowHookFlag afterScanRowHookFlag ) var ( baseModelType = reflect.TypeOf((*BaseModel)(nil)).Elem() tableNameInflector = inflection.Plural ) type BaseModel struct{} // SetTableNameInflector overrides the default func that pluralizes // model name to get table name, e.g. my_article becomes my_articles. func SetTableNameInflector(fn func(string) string) { tableNameInflector = fn } // Table represents a SQL table created from Go struct. type Table struct { dialect Dialect Type reflect.Type ZeroValue reflect.Value // reflect.Struct ZeroIface interface{} // struct pointer TypeName string ModelName string Name string SQLName Safe SQLNameForSelects Safe Alias string SQLAlias Safe allFields []*Field // all fields including scanonly Fields []*Field // PKs + DataFields PKs []*Field DataFields []*Field relFields []*Field FieldMap map[string]*Field StructMap map[string]*structField Relations map[string]*Relation Unique map[string][]*Field SoftDeleteField *Field UpdateSoftDeleteField func(fv reflect.Value, tm time.Time) error flags internal.Flag } type structField struct { Index []int Table *Table } func newTable( dialect Dialect, typ reflect.Type, seen map[reflect.Type]*Table, canAddr bool, ) *Table { if table, ok := seen[typ]; ok { return table } table := new(Table) seen[typ] = table table.dialect = dialect table.Type = typ table.ZeroValue = reflect.New(table.Type).Elem() table.ZeroIface = reflect.New(table.Type).Interface() table.TypeName = internal.ToExported(table.Type.Name()) table.ModelName = internal.Underscore(table.Type.Name()) tableName := tableNameInflector(table.ModelName) table.setName(tableName) table.Alias = table.ModelName table.SQLAlias = table.quoteIdent(table.ModelName) table.Fields = make([]*Field, 0, typ.NumField()) table.FieldMap = make(map[string]*Field, typ.NumField()) table.processFields(typ, seen, canAddr) hooks := []struct { typ reflect.Type flag internal.Flag }{ {beforeAppendModelHookType, beforeAppendModelHookFlag}, {beforeScanRowHookType, beforeScanRowHookFlag}, {afterScanRowHookType, afterScanRowHookFlag}, } typ = reflect.PtrTo(table.Type) for _, hook := range hooks { if typ.Implements(hook.typ) { table.flags = table.flags.Set(hook.flag) } } return table } func (t *Table) init() { for _, field := range t.relFields { t.processRelation(field) } t.relFields = nil } func (t *Table) processFields( typ reflect.Type, seen map[reflect.Type]*Table, canAddr bool, ) { type embeddedField struct { prefix string index []int unexported bool subtable *Table subfield *Field } names := make(map[string]struct{}) embedded := make([]embeddedField, 0, 10) for i, n := 0, typ.NumField(); i < n; i++ { sf := typ.Field(i) unexported := sf.PkgPath != "" tagstr := sf.Tag.Get("bun") if tagstr == "-" { names[sf.Name] = struct{}{} continue } tag := tagparser.Parse(tagstr) if unexported && !sf.Anonymous { // unexported continue } if sf.Anonymous { if sf.Name == "BaseModel" && sf.Type == baseModelType { t.processBaseModelField(sf) continue } sfType := sf.Type if sfType.Kind() == reflect.Ptr { sfType = sfType.Elem() } if sfType.Kind() != reflect.Struct { // ignore unexported non-struct types continue } subtable := newTable(t.dialect, sfType, seen, canAddr) for _, subfield := range subtable.allFields { embedded = append(embedded, embeddedField{ index: sf.Index, unexported: unexported, subtable: subtable, subfield: subfield, }) } if tagstr != "" { tag := tagparser.Parse(tagstr) if tag.HasOption("inherit") || tag.HasOption("extend") { t.Name = subtable.Name t.TypeName = subtable.TypeName t.SQLName = subtable.SQLName t.SQLNameForSelects = subtable.SQLNameForSelects t.Alias = subtable.Alias t.SQLAlias = subtable.SQLAlias t.ModelName = subtable.ModelName } } continue } if prefix, ok := tag.Option("embed"); ok { fieldType := indirectType(sf.Type) if fieldType.Kind() != reflect.Struct { panic(fmt.Errorf("bun: embed %s.%s: got %s, wanted reflect.Struct", t.TypeName, sf.Name, fieldType.Kind())) } subtable := newTable(t.dialect, fieldType, seen, canAddr) for _, subfield := range subtable.allFields { embedded = append(embedded, embeddedField{ prefix: prefix, index: sf.Index, unexported: unexported, subtable: subtable, subfield: subfield, }) } continue } field := t.newField(sf, tag) t.addField(field) names[field.Name] = struct{}{} if field.IndirectType.Kind() == reflect.Struct { if t.StructMap == nil { t.StructMap = make(map[string]*structField) } t.StructMap[field.Name] = &structField{ Index: field.Index, Table: newTable(t.dialect, field.IndirectType, seen, canAddr), } } } // Only unambiguous embedded fields must be serialized. ambiguousNames := make(map[string]int) ambiguousTags := make(map[string]int) // Embedded types can never override a field that was already present at // the top-level. for name := range names { ambiguousNames[name]++ ambiguousTags[name]++ } for _, f := range embedded { ambiguousNames[f.prefix+f.subfield.Name]++ if !f.subfield.Tag.IsZero() { ambiguousTags[f.prefix+f.subfield.Name]++ } } for _, embfield := range embedded { subfield := embfield.subfield.Clone() if ambiguousNames[subfield.Name] > 1 && !(!subfield.Tag.IsZero() && ambiguousTags[subfield.Name] == 1) { continue // ambiguous embedded field } subfield.Index = makeIndex(embfield.index, subfield.Index) if embfield.prefix != "" { subfield.Name = embfield.prefix + subfield.Name subfield.SQLName = t.quoteIdent(subfield.Name) } t.addField(subfield) } } func (t *Table) setName(name string) { t.Name = name t.SQLName = t.quoteIdent(name) t.SQLNameForSelects = t.quoteIdent(name) if t.SQLAlias == "" { t.Alias = name t.SQLAlias = t.quoteIdent(name) } } func (t *Table) String() string { return "model=" + t.TypeName } func (t *Table) CheckPKs() error { if len(t.PKs) == 0 { return fmt.Errorf("bun: %s does not have primary keys", t) } return nil } func (t *Table) addField(field *Field) { t.allFields = append(t.allFields, field) if field.Tag.HasOption("rel") || field.Tag.HasOption("m2m") { t.relFields = append(t.relFields, field) return } if field.Tag.HasOption("join") { internal.Warn.Printf( `%s.%s "join" option must come together with "rel" option`, t.TypeName, field.GoName, ) } t.FieldMap[field.Name] = field if altName, ok := field.Tag.Option("alt"); ok { t.FieldMap[altName] = field } if field.Tag.HasOption("scanonly") { return } if _, ok := field.Tag.Options["soft_delete"]; ok { t.SoftDeleteField = field t.UpdateSoftDeleteField = softDeleteFieldUpdater(field) } t.Fields = append(t.Fields, field) if field.IsPK { t.PKs = append(t.PKs, field) } else { t.DataFields = append(t.DataFields, field) } } func (t *Table) LookupField(name string) *Field { if field, ok := t.FieldMap[name]; ok { return field } table := t var index []int for { structName, columnName, ok := strings.Cut(name, "__") if !ok { field, ok := table.FieldMap[name] if !ok { return nil } return field.WithIndex(index) } name = columnName strct := table.StructMap[structName] if strct == nil { return nil } table = strct.Table index = append(index, strct.Index...) } } func (t *Table) HasField(name string) bool { _, ok := t.FieldMap[name] return ok } func (t *Table) Field(name string) (*Field, error) { field, ok := t.FieldMap[name] if !ok { return nil, fmt.Errorf("bun: %s does not have column=%s", t, name) } return field, nil } func (t *Table) fieldByGoName(name string) *Field { for _, f := range t.allFields { if f.GoName == name { return f } } return nil } func (t *Table) processBaseModelField(f reflect.StructField) { tag := tagparser.Parse(f.Tag.Get("bun")) if isKnownTableOption(tag.Name) { internal.Warn.Printf( "%s.%s tag name %q is also an option name, is it a mistake? Try table:%s.", t.TypeName, f.Name, tag.Name, tag.Name, ) } for name := range tag.Options { if !isKnownTableOption(name) { internal.Warn.Printf("%s.%s has unknown tag option: %q", t.TypeName, f.Name, name) } } if tag.Name != "" { t.setName(tag.Name) } if s, ok := tag.Option("table"); ok { t.setName(s) } if s, ok := tag.Option("select"); ok { t.SQLNameForSelects = t.quoteTableName(s) } if s, ok := tag.Option("alias"); ok { t.Alias = s t.SQLAlias = t.quoteIdent(s) } } // nolint func (t *Table) newField(sf reflect.StructField, tag tagparser.Tag) *Field { sqlName := internal.Underscore(sf.Name) if tag.Name != "" && tag.Name != sqlName { if isKnownFieldOption(tag.Name) { internal.Warn.Printf( "%s.%s tag name %q is also an option name, is it a mistake? Try column:%s.", t.TypeName, sf.Name, tag.Name, tag.Name, ) } sqlName = tag.Name } for name := range tag.Options { if !isKnownFieldOption(name) { internal.Warn.Printf("%s.%s has unknown tag option: %q", t.TypeName, sf.Name, name) } } field := &Field{ StructField: sf, IsPtr: sf.Type.Kind() == reflect.Ptr, Tag: tag, IndirectType: indirectType(sf.Type), Index: sf.Index, Name: sqlName, GoName: sf.Name, SQLName: t.quoteIdent(sqlName), } field.NotNull = tag.HasOption("notnull") field.NullZero = tag.HasOption("nullzero") if tag.HasOption("pk") { field.IsPK = true field.NotNull = true } if tag.HasOption("autoincrement") { field.AutoIncrement = true field.NullZero = true } if tag.HasOption("identity") { field.Identity = true } if v, ok := tag.Options["unique"]; ok { var names []string if len(v) == 1 { // Split the value by comma, this will allow multiple names to be specified. // We can use this to create multiple named unique constraints where a single column // might be included in multiple constraints. names = strings.Split(v[0], ",") } else { names = v } for _, uniqueName := range names { if t.Unique == nil { t.Unique = make(map[string][]*Field) } t.Unique[uniqueName] = append(t.Unique[uniqueName], field) } } if s, ok := tag.Option("default"); ok { field.SQLDefault = s } if s, ok := field.Tag.Option("type"); ok { field.UserSQLType = s } field.DiscoveredSQLType = DiscoverSQLType(field.IndirectType) field.Append = FieldAppender(t.dialect, field) field.Scan = FieldScanner(t.dialect, field) field.IsZero = zeroChecker(field.StructField.Type) return field } //--------------------------------------------------------------------------------------- func (t *Table) processRelation(field *Field) { if rel, ok := field.Tag.Option("rel"); ok { t.initRelation(field, rel) return } if field.Tag.HasOption("m2m") { t.addRelation(t.m2mRelation(field)) return } panic("not reached") } func (t *Table) initRelation(field *Field, rel string) { switch rel { case "belongs-to": t.addRelation(t.belongsToRelation(field)) case "has-one": t.addRelation(t.hasOneRelation(field)) case "has-many": t.addRelation(t.hasManyRelation(field)) default: panic(fmt.Errorf("bun: unknown relation=%s on field=%s", rel, field.GoName)) } } func (t *Table) addRelation(rel *Relation) { if t.Relations == nil { t.Relations = make(map[string]*Relation) } _, ok := t.Relations[rel.Field.GoName] if ok { panic(fmt.Errorf("%s already has %s", t, rel)) } t.Relations[rel.Field.GoName] = rel } func (t *Table) belongsToRelation(field *Field) *Relation { joinTable := t.dialect.Tables().InProgress(field.IndirectType) if err := joinTable.CheckPKs(); err != nil { panic(err) } rel := &Relation{ Type: BelongsToRelation, Field: field, JoinTable: joinTable, } if field.Tag.HasOption("join_on") { rel.Condition = field.Tag.Options["join_on"] } rel.OnUpdate = "ON UPDATE NO ACTION" if onUpdate, ok := field.Tag.Options["on_update"]; ok { if len(onUpdate) > 1 { panic(fmt.Errorf("bun: %s belongs-to %s: on_update option must be a single field", t.TypeName, field.GoName)) } rule := strings.ToUpper(onUpdate[0]) if !isKnownFKRule(rule) { internal.Warn.Printf("bun: %s belongs-to %s: unknown on_update rule %s", t.TypeName, field.GoName, rule) } s := fmt.Sprintf("ON UPDATE %s", rule) rel.OnUpdate = s } rel.OnDelete = "ON DELETE NO ACTION" if onDelete, ok := field.Tag.Options["on_delete"]; ok { if len(onDelete) > 1 { panic(fmt.Errorf("bun: %s belongs-to %s: on_delete option must be a single field", t.TypeName, field.GoName)) } rule := strings.ToUpper(onDelete[0]) if !isKnownFKRule(rule) { internal.Warn.Printf("bun: %s belongs-to %s: unknown on_delete rule %s", t.TypeName, field.GoName, rule) } s := fmt.Sprintf("ON DELETE %s", rule) rel.OnDelete = s } if join, ok := field.Tag.Options["join"]; ok { baseColumns, joinColumns := parseRelationJoin(join) for i, baseColumn := range baseColumns { joinColumn := joinColumns[i] if f := t.FieldMap[baseColumn]; f != nil { rel.BaseFields = append(rel.BaseFields, f) } else { panic(fmt.Errorf( "bun: %s belongs-to %s: %s must have column %s", t.TypeName, field.GoName, t.TypeName, baseColumn, )) } if f := joinTable.FieldMap[joinColumn]; f != nil { rel.JoinFields = append(rel.JoinFields, f) } else { panic(fmt.Errorf( "bun: %s belongs-to %s: %s must have column %s", t.TypeName, field.GoName, joinTable.TypeName, joinColumn, )) } } return rel } rel.JoinFields = joinTable.PKs fkPrefix := internal.Underscore(field.GoName) + "_" for _, joinPK := range joinTable.PKs { fkName := fkPrefix + joinPK.Name if fk := t.FieldMap[fkName]; fk != nil { rel.BaseFields = append(rel.BaseFields, fk) continue } if fk := t.FieldMap[joinPK.Name]; fk != nil { rel.BaseFields = append(rel.BaseFields, fk) continue } panic(fmt.Errorf( "bun: %s belongs-to %s: %s must have column %s "+ "(to override, use join:base_column=join_column tag on %s field)", t.TypeName, field.GoName, t.TypeName, fkName, field.GoName, )) } return rel } func (t *Table) hasOneRelation(field *Field) *Relation { if err := t.CheckPKs(); err != nil { panic(err) } joinTable := t.dialect.Tables().InProgress(field.IndirectType) rel := &Relation{ Type: HasOneRelation, Field: field, JoinTable: joinTable, } if field.Tag.HasOption("join_on") { rel.Condition = field.Tag.Options["join_on"] } if join, ok := field.Tag.Options["join"]; ok { baseColumns, joinColumns := parseRelationJoin(join) for i, baseColumn := range baseColumns { if f := t.FieldMap[baseColumn]; f != nil { rel.BaseFields = append(rel.BaseFields, f) } else { panic(fmt.Errorf( "bun: %s has-one %s: %s must have column %s", field.GoName, t.TypeName, t.TypeName, baseColumn, )) } joinColumn := joinColumns[i] if f := joinTable.FieldMap[joinColumn]; f != nil { rel.JoinFields = append(rel.JoinFields, f) } else { panic(fmt.Errorf( "bun: %s has-one %s: %s must have column %s", field.GoName, t.TypeName, joinTable.TypeName, joinColumn, )) } } return rel } rel.BaseFields = t.PKs fkPrefix := internal.Underscore(t.ModelName) + "_" for _, pk := range t.PKs { fkName := fkPrefix + pk.Name if f := joinTable.FieldMap[fkName]; f != nil { rel.JoinFields = append(rel.JoinFields, f) continue } if f := joinTable.FieldMap[pk.Name]; f != nil { rel.JoinFields = append(rel.JoinFields, f) continue } panic(fmt.Errorf( "bun: %s has-one %s: %s must have column %s "+ "(to override, use join:base_column=join_column tag on %s field)", field.GoName, t.TypeName, joinTable.TypeName, fkName, field.GoName, )) } return rel } func (t *Table) hasManyRelation(field *Field) *Relation { if err := t.CheckPKs(); err != nil { panic(err) } if field.IndirectType.Kind() != reflect.Slice { panic(fmt.Errorf( "bun: %s.%s has-many relation requires slice, got %q", t.TypeName, field.GoName, field.IndirectType.Kind(), )) } joinTable := t.dialect.Tables().InProgress(indirectType(field.IndirectType.Elem())) polymorphicValue, isPolymorphic := field.Tag.Option("polymorphic") rel := &Relation{ Type: HasManyRelation, Field: field, JoinTable: joinTable, } if field.Tag.HasOption("join_on") { rel.Condition = field.Tag.Options["join_on"] } var polymorphicColumn string if join, ok := field.Tag.Options["join"]; ok { baseColumns, joinColumns := parseRelationJoin(join) for i, baseColumn := range baseColumns { joinColumn := joinColumns[i] if isPolymorphic && baseColumn == "type" { polymorphicColumn = joinColumn continue } if f := t.FieldMap[baseColumn]; f != nil { rel.BaseFields = append(rel.BaseFields, f) } else { panic(fmt.Errorf( "bun: %s has-many %s: %s must have column %s", t.TypeName, field.GoName, t.TypeName, baseColumn, )) } if f := joinTable.FieldMap[joinColumn]; f != nil { rel.JoinFields = append(rel.JoinFields, f) } else { panic(fmt.Errorf( "bun: %s has-many %s: %s must have column %s", t.TypeName, field.GoName, joinTable.TypeName, joinColumn, )) } } } else { rel.BaseFields = t.PKs fkPrefix := internal.Underscore(t.ModelName) + "_" if isPolymorphic { polymorphicColumn = fkPrefix + "type" } for _, pk := range t.PKs { joinColumn := fkPrefix + pk.Name if fk := joinTable.FieldMap[joinColumn]; fk != nil { rel.JoinFields = append(rel.JoinFields, fk) continue } if fk := joinTable.FieldMap[pk.Name]; fk != nil { rel.JoinFields = append(rel.JoinFields, fk) continue } panic(fmt.Errorf( "bun: %s has-many %s: %s must have column %s "+ "(to override, use join:base_column=join_column tag on the field %s)", t.TypeName, field.GoName, joinTable.TypeName, joinColumn, field.GoName, )) } } if isPolymorphic { rel.PolymorphicField = joinTable.FieldMap[polymorphicColumn] if rel.PolymorphicField == nil { panic(fmt.Errorf( "bun: %s has-many %s: %s must have polymorphic column %s", t.TypeName, field.GoName, joinTable.TypeName, polymorphicColumn, )) } if polymorphicValue == "" { polymorphicValue = t.ModelName } rel.PolymorphicValue = polymorphicValue } return rel } func (t *Table) m2mRelation(field *Field) *Relation { if field.IndirectType.Kind() != reflect.Slice { panic(fmt.Errorf( "bun: %s.%s m2m relation requires slice, got %q", t.TypeName, field.GoName, field.IndirectType.Kind(), )) } joinTable := t.dialect.Tables().InProgress(indirectType(field.IndirectType.Elem())) if err := t.CheckPKs(); err != nil { panic(err) } if err := joinTable.CheckPKs(); err != nil { panic(err) } m2mTableName, ok := field.Tag.Option("m2m") if !ok { panic(fmt.Errorf("bun: %s must have m2m tag option", field.GoName)) } m2mTable := t.dialect.Tables().ByName(m2mTableName) if m2mTable == nil { panic(fmt.Errorf( "bun: can't find m2m %s table (use db.RegisterModel)", m2mTableName, )) } rel := &Relation{ Type: ManyToManyRelation, Field: field, JoinTable: joinTable, M2MTable: m2mTable, } if field.Tag.HasOption("join_on") { rel.Condition = field.Tag.Options["join_on"] } var leftColumn, rightColumn string if join, ok := field.Tag.Options["join"]; ok { left, right := parseRelationJoin(join) leftColumn = left[0] rightColumn = right[0] } else { leftColumn = t.TypeName rightColumn = joinTable.TypeName } leftField := m2mTable.fieldByGoName(leftColumn) if leftField == nil { panic(fmt.Errorf( "bun: %s many-to-many %s: %s must have field %s "+ "(to override, use tag join:LeftField=RightField on field %s.%s", t.TypeName, field.GoName, m2mTable.TypeName, leftColumn, t.TypeName, field.GoName, )) } rightField := m2mTable.fieldByGoName(rightColumn) if rightField == nil { panic(fmt.Errorf( "bun: %s many-to-many %s: %s must have field %s "+ "(to override, use tag join:LeftField=RightField on field %s.%s", t.TypeName, field.GoName, m2mTable.TypeName, rightColumn, t.TypeName, field.GoName, )) } leftRel := m2mTable.belongsToRelation(leftField) rel.BaseFields = leftRel.JoinFields rel.M2MBaseFields = leftRel.BaseFields rightRel := m2mTable.belongsToRelation(rightField) rel.JoinFields = rightRel.JoinFields rel.M2MJoinFields = rightRel.BaseFields return rel } //------------------------------------------------------------------------------ func (t *Table) Dialect() Dialect { return t.dialect } func (t *Table) HasBeforeAppendModelHook() bool { return t.flags.Has(beforeAppendModelHookFlag) } // DEPRECATED. Use HasBeforeScanRowHook. func (t *Table) HasBeforeScanHook() bool { return t.flags.Has(beforeScanHookFlag) } // DEPRECATED. Use HasAfterScanRowHook. func (t *Table) HasAfterScanHook() bool { return t.flags.Has(afterScanHookFlag) } func (t *Table) HasBeforeScanRowHook() bool { return t.flags.Has(beforeScanRowHookFlag) } func (t *Table) HasAfterScanRowHook() bool { return t.flags.Has(afterScanRowHookFlag) } //------------------------------------------------------------------------------ func (t *Table) AppendNamedArg( fmter Formatter, b []byte, name string, strct reflect.Value, ) ([]byte, bool) { if field, ok := t.FieldMap[name]; ok { return field.AppendValue(fmter, b, strct), true } return b, false } func (t *Table) quoteTableName(s string) Safe { // Don't quote if table name contains placeholder (?) or parentheses. if strings.IndexByte(s, '?') >= 0 || strings.IndexByte(s, '(') >= 0 || strings.IndexByte(s, ')') >= 0 { return Safe(s) } return t.quoteIdent(s) } func (t *Table) quoteIdent(s string) Safe { return Safe(NewFormatter(t.dialect).AppendIdent(nil, s)) } func isKnownTableOption(name string) bool { switch name { case "table", "alias", "select": return true } return false } func isKnownFieldOption(name string) bool { switch name { case "column", "alt", "type", "array", "hstore", "composite", "json_use_number", "msgpack", "notnull", "nullzero", "default", "unique", "soft_delete", "scanonly", "skipupdate", "pk", "autoincrement", "rel", "join", "join_on", "on_update", "on_delete", "m2m", "polymorphic", "identity": return true } return false } func isKnownFKRule(name string) bool { switch name { case "CASCADE", "RESTRICT", "SET NULL", "SET DEFAULT": return true } return false } func parseRelationJoin(join []string) ([]string, []string) { var ss []string if len(join) == 1 { ss = strings.Split(join[0], ",") } else { ss = join } baseColumns := make([]string, len(ss)) joinColumns := make([]string, len(ss)) for i, s := range ss { ss := strings.Split(strings.TrimSpace(s), "=") if len(ss) != 2 { panic(fmt.Errorf("can't parse relation join: %q", join)) } baseColumns[i] = ss[0] joinColumns[i] = ss[1] } return baseColumns, joinColumns } //------------------------------------------------------------------------------ func softDeleteFieldUpdater(field *Field) func(fv reflect.Value, tm time.Time) error { typ := field.StructField.Type switch typ { case timeType: return func(fv reflect.Value, tm time.Time) error { ptr := fv.Addr().Interface().(*time.Time) *ptr = tm return nil } case nullTimeType: return func(fv reflect.Value, tm time.Time) error { ptr := fv.Addr().Interface().(*sql.NullTime) *ptr = sql.NullTime{Time: tm} return nil } case nullIntType: return func(fv reflect.Value, tm time.Time) error { ptr := fv.Addr().Interface().(*sql.NullInt64) *ptr = sql.NullInt64{Int64: tm.UnixNano()} return nil } } switch field.IndirectType.Kind() { case reflect.Int64: return func(fv reflect.Value, tm time.Time) error { ptr := fv.Addr().Interface().(*int64) *ptr = tm.UnixNano() return nil } case reflect.Ptr: typ = typ.Elem() default: return softDeleteFieldUpdaterFallback(field) } switch typ { //nolint:gocritic case timeType: return func(fv reflect.Value, tm time.Time) error { fv.Set(reflect.ValueOf(&tm)) return nil } } switch typ.Kind() { //nolint:gocritic case reflect.Int64: return func(fv reflect.Value, tm time.Time) error { utime := tm.UnixNano() fv.Set(reflect.ValueOf(&utime)) return nil } } return softDeleteFieldUpdaterFallback(field) } func softDeleteFieldUpdaterFallback(field *Field) func(fv reflect.Value, tm time.Time) error { return func(fv reflect.Value, tm time.Time) error { return field.ScanWithCheck(fv, tm) } } func makeIndex(a, b []int) []int { dest := make([]int, 0, len(a)+len(b)) dest = append(dest, a...) dest = append(dest, b...) return dest }