gorm/migrator/migrator.go

857 lines
24 KiB
Go

package migrator
import (
"context"
"database/sql"
"fmt"
"reflect"
"regexp"
"strings"
"gorm.io/gorm"
"gorm.io/gorm/clause"
"gorm.io/gorm/schema"
)
var (
regRealDataType = regexp.MustCompile(`[^\d](\d+)[^\d]?`)
regFullDataType = regexp.MustCompile(`[^\d]*(\d+)[^\d]?`)
)
// Migrator m struct
type Migrator struct {
Config
}
// Config schema config
type Config struct {
CreateIndexAfterCreateTable bool
DB *gorm.DB
gorm.Dialector
}
// GormDataTypeInterface gorm data type interface
type GormDataTypeInterface interface {
GormDBDataType(*gorm.DB, *schema.Field) string
}
// RunWithValue run migration with statement value
func (m Migrator) RunWithValue(value interface{}, fc func(*gorm.Statement) error) error {
stmt := &gorm.Statement{DB: m.DB}
if m.DB.Statement != nil {
stmt.Table = m.DB.Statement.Table
stmt.TableExpr = m.DB.Statement.TableExpr
}
if table, ok := value.(string); ok {
stmt.Table = table
} else if err := stmt.ParseWithSpecialTableName(value, stmt.Table); err != nil {
return err
}
return fc(stmt)
}
// DataTypeOf return field's db data type
func (m Migrator) DataTypeOf(field *schema.Field) string {
fieldValue := reflect.New(field.IndirectFieldType)
if dataTyper, ok := fieldValue.Interface().(GormDataTypeInterface); ok {
if dataType := dataTyper.GormDBDataType(m.DB, field); dataType != "" {
return dataType
}
}
return m.Dialector.DataTypeOf(field)
}
// FullDataTypeOf returns field's db full data type
func (m Migrator) FullDataTypeOf(field *schema.Field) (expr clause.Expr) {
expr.SQL = m.DataTypeOf(field)
if field.NotNull {
expr.SQL += " NOT NULL"
}
if field.Unique {
expr.SQL += " UNIQUE"
}
if field.HasDefaultValue && (field.DefaultValueInterface != nil || field.DefaultValue != "") {
if field.DefaultValueInterface != nil {
defaultStmt := &gorm.Statement{Vars: []interface{}{field.DefaultValueInterface}}
m.Dialector.BindVarTo(defaultStmt, defaultStmt, field.DefaultValueInterface)
expr.SQL += " DEFAULT " + m.Dialector.Explain(defaultStmt.SQL.String(), field.DefaultValueInterface)
} else if field.DefaultValue != "(-)" {
expr.SQL += " DEFAULT " + field.DefaultValue
}
}
return
}
// AutoMigrate auto migrate values
func (m Migrator) AutoMigrate(values ...interface{}) error {
for _, value := range m.ReorderModels(values, true) {
tx := m.DB.Session(&gorm.Session{})
if !tx.Migrator().HasTable(value) {
if err := tx.Migrator().CreateTable(value); err != nil {
return err
}
} else {
if err := m.RunWithValue(value, func(stmt *gorm.Statement) (errr error) {
columnTypes, err := m.DB.Migrator().ColumnTypes(value)
if err != nil {
return err
}
for _, dbName := range stmt.Schema.DBNames {
field := stmt.Schema.FieldsByDBName[dbName]
var foundColumn gorm.ColumnType
for _, columnType := range columnTypes {
if columnType.Name() == dbName {
foundColumn = columnType
break
}
}
if foundColumn == nil {
// not found, add column
if err := tx.Migrator().AddColumn(value, dbName); err != nil {
return err
}
} else if err := m.DB.Migrator().MigrateColumn(value, field, foundColumn); err != nil {
// found, smart migrate
return err
}
}
for _, rel := range stmt.Schema.Relationships.Relations {
if !m.DB.Config.DisableForeignKeyConstraintWhenMigrating {
if constraint := rel.ParseConstraint(); constraint != nil &&
constraint.Schema == stmt.Schema && !tx.Migrator().HasConstraint(value, constraint.Name) {
if err := tx.Migrator().CreateConstraint(value, constraint.Name); err != nil {
return err
}
}
}
for _, chk := range stmt.Schema.ParseCheckConstraints() {
if !tx.Migrator().HasConstraint(value, chk.Name) {
if err := tx.Migrator().CreateConstraint(value, chk.Name); err != nil {
return err
}
}
}
}
for _, idx := range stmt.Schema.ParseIndexes() {
if !tx.Migrator().HasIndex(value, idx.Name) {
if err := tx.Migrator().CreateIndex(value, idx.Name); err != nil {
return err
}
}
}
return nil
}); err != nil {
return err
}
}
}
return nil
}
// GetTables returns tables
func (m Migrator) GetTables() (tableList []string, err error) {
err = m.DB.Raw("SELECT TABLE_NAME FROM information_schema.tables where TABLE_SCHEMA=?", m.CurrentDatabase()).
Scan(&tableList).Error
return
}
// CreateTable create table in database for values
func (m Migrator) CreateTable(values ...interface{}) error {
for _, value := range m.ReorderModels(values, false) {
tx := m.DB.Session(&gorm.Session{})
if err := m.RunWithValue(value, func(stmt *gorm.Statement) (errr error) {
var (
createTableSQL = "CREATE TABLE ? ("
values = []interface{}{m.CurrentTable(stmt)}
hasPrimaryKeyInDataType bool
)
for _, dbName := range stmt.Schema.DBNames {
field := stmt.Schema.FieldsByDBName[dbName]
if !field.IgnoreMigration {
createTableSQL += "? ?"
hasPrimaryKeyInDataType = hasPrimaryKeyInDataType || strings.Contains(strings.ToUpper(string(field.DataType)), "PRIMARY KEY")
values = append(values, clause.Column{Name: dbName}, m.DB.Migrator().FullDataTypeOf(field))
createTableSQL += ","
}
}
if !hasPrimaryKeyInDataType && len(stmt.Schema.PrimaryFields) > 0 {
createTableSQL += "PRIMARY KEY ?,"
primaryKeys := []interface{}{}
for _, field := range stmt.Schema.PrimaryFields {
primaryKeys = append(primaryKeys, clause.Column{Name: field.DBName})
}
values = append(values, primaryKeys)
}
for _, idx := range stmt.Schema.ParseIndexes() {
if m.CreateIndexAfterCreateTable {
defer func(value interface{}, name string) {
if errr == nil {
errr = tx.Migrator().CreateIndex(value, name)
}
}(value, idx.Name)
} else {
if idx.Class != "" {
createTableSQL += idx.Class + " "
}
createTableSQL += "INDEX ? ?"
if idx.Comment != "" {
createTableSQL += fmt.Sprintf(" COMMENT '%s'", idx.Comment)
}
if idx.Option != "" {
createTableSQL += " " + idx.Option
}
createTableSQL += ","
values = append(values, clause.Column{Name: idx.Name}, tx.Migrator().(BuildIndexOptionsInterface).BuildIndexOptions(idx.Fields, stmt))
}
}
for _, rel := range stmt.Schema.Relationships.Relations {
if !m.DB.DisableForeignKeyConstraintWhenMigrating {
if constraint := rel.ParseConstraint(); constraint != nil {
if constraint.Schema == stmt.Schema {
sql, vars := buildConstraint(constraint)
createTableSQL += sql + ","
values = append(values, vars...)
}
}
}
}
for _, chk := range stmt.Schema.ParseCheckConstraints() {
createTableSQL += "CONSTRAINT ? CHECK (?),"
values = append(values, clause.Column{Name: chk.Name}, clause.Expr{SQL: chk.Constraint})
}
createTableSQL = strings.TrimSuffix(createTableSQL, ",")
createTableSQL += ")"
if tableOption, ok := m.DB.Get("gorm:table_options"); ok {
createTableSQL += fmt.Sprint(tableOption)
}
errr = tx.Exec(createTableSQL, values...).Error
return errr
}); err != nil {
return err
}
}
return nil
}
// DropTable drop table for values
func (m Migrator) DropTable(values ...interface{}) error {
values = m.ReorderModels(values, false)
for i := len(values) - 1; i >= 0; i-- {
tx := m.DB.Session(&gorm.Session{})
if err := m.RunWithValue(values[i], func(stmt *gorm.Statement) error {
return tx.Exec("DROP TABLE IF EXISTS ?", m.CurrentTable(stmt)).Error
}); err != nil {
return err
}
}
return nil
}
// HasTable returns table exists or not for value, value could be a struct or string
func (m Migrator) HasTable(value interface{}) bool {
var count int64
m.RunWithValue(value, func(stmt *gorm.Statement) error {
currentDatabase := m.DB.Migrator().CurrentDatabase()
return m.DB.Raw("SELECT count(*) FROM information_schema.tables WHERE table_schema = ? AND table_name = ? AND table_type = ?", currentDatabase, stmt.Table, "BASE TABLE").Row().Scan(&count)
})
return count > 0
}
// RenameTable rename table from oldName to newName
func (m Migrator) RenameTable(oldName, newName interface{}) error {
var oldTable, newTable interface{}
if v, ok := oldName.(string); ok {
oldTable = clause.Table{Name: v}
} else {
stmt := &gorm.Statement{DB: m.DB}
if err := stmt.Parse(oldName); err == nil {
oldTable = m.CurrentTable(stmt)
} else {
return err
}
}
if v, ok := newName.(string); ok {
newTable = clause.Table{Name: v}
} else {
stmt := &gorm.Statement{DB: m.DB}
if err := stmt.Parse(newName); err == nil {
newTable = m.CurrentTable(stmt)
} else {
return err
}
}
return m.DB.Exec("ALTER TABLE ? RENAME TO ?", oldTable, newTable).Error
}
// AddColumn create `name` column for value
func (m Migrator) AddColumn(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
// avoid using the same name field
f := stmt.Schema.LookUpField(name)
if f == nil {
return fmt.Errorf("failed to look up field with name: %s", name)
}
if !f.IgnoreMigration {
return m.DB.Exec(
"ALTER TABLE ? ADD ? ?",
m.CurrentTable(stmt), clause.Column{Name: f.DBName}, m.DB.Migrator().FullDataTypeOf(f),
).Error
}
return nil
})
}
// DropColumn drop value's `name` column
func (m Migrator) DropColumn(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
if field := stmt.Schema.LookUpField(name); field != nil {
name = field.DBName
}
return m.DB.Exec(
"ALTER TABLE ? DROP COLUMN ?", m.CurrentTable(stmt), clause.Column{Name: name},
).Error
})
}
// AlterColumn alter value's `field` column' type based on schema definition
func (m Migrator) AlterColumn(value interface{}, field string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
if field := stmt.Schema.LookUpField(field); field != nil {
fileType := m.FullDataTypeOf(field)
return m.DB.Exec(
"ALTER TABLE ? ALTER COLUMN ? TYPE ?",
m.CurrentTable(stmt), clause.Column{Name: field.DBName}, fileType,
).Error
}
return fmt.Errorf("failed to look up field with name: %s", field)
})
}
// HasColumn check has column `field` for value or not
func (m Migrator) HasColumn(value interface{}, field string) bool {
var count int64
m.RunWithValue(value, func(stmt *gorm.Statement) error {
currentDatabase := m.DB.Migrator().CurrentDatabase()
name := field
if field := stmt.Schema.LookUpField(field); field != nil {
name = field.DBName
}
return m.DB.Raw(
"SELECT count(*) FROM INFORMATION_SCHEMA.columns WHERE table_schema = ? AND table_name = ? AND column_name = ?",
currentDatabase, stmt.Table, name,
).Row().Scan(&count)
})
return count > 0
}
// RenameColumn rename value's field name from oldName to newName
func (m Migrator) RenameColumn(value interface{}, oldName, newName string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
if field := stmt.Schema.LookUpField(oldName); field != nil {
oldName = field.DBName
}
if field := stmt.Schema.LookUpField(newName); field != nil {
newName = field.DBName
}
return m.DB.Exec(
"ALTER TABLE ? RENAME COLUMN ? TO ?",
m.CurrentTable(stmt), clause.Column{Name: oldName}, clause.Column{Name: newName},
).Error
})
}
// MigrateColumn migrate column
func (m Migrator) MigrateColumn(value interface{}, field *schema.Field, columnType gorm.ColumnType) error {
// found, smart migrate
fullDataType := strings.ToLower(m.DB.Migrator().FullDataTypeOf(field).SQL)
realDataType := strings.ToLower(columnType.DatabaseTypeName())
alterColumn := false
// check size
if length, ok := columnType.Length(); length != int64(field.Size) {
if length > 0 && field.Size > 0 {
alterColumn = true
} else {
// has size in data type and not equal
// Since the following code is frequently called in the for loop, reg optimization is needed here
matches := regRealDataType.FindAllStringSubmatch(realDataType, -1)
matches2 := regFullDataType.FindAllStringSubmatch(fullDataType, -1)
if (len(matches) == 1 && matches[0][1] != fmt.Sprint(field.Size) || !field.PrimaryKey) &&
(len(matches2) == 1 && matches2[0][1] != fmt.Sprint(length) && ok) {
alterColumn = true
}
}
}
// check precision
if precision, _, ok := columnType.DecimalSize(); ok && int64(field.Precision) != precision {
if regexp.MustCompile(fmt.Sprintf("[^0-9]%d[^0-9]", field.Precision)).MatchString(m.DataTypeOf(field)) {
alterColumn = true
}
}
// check nullable
if nullable, ok := columnType.Nullable(); ok && nullable == field.NotNull {
// not primary key & database is nullable
if !field.PrimaryKey && nullable {
alterColumn = true
}
}
// check unique
if unique, ok := columnType.Unique(); ok && unique != field.Unique {
// not primary key
if !field.PrimaryKey {
alterColumn = true
}
}
// check default value
if !field.PrimaryKey {
dv, dvNotNull := columnType.DefaultValue()
if dvNotNull && field.DefaultValueInterface == nil {
// defalut value -> null
alterColumn = true
} else if !dvNotNull && field.DefaultValueInterface != nil {
// null -> default value
alterColumn = true
} else if dv != field.DefaultValue {
// default value not equal
// not both null
if !(field.DefaultValueInterface == nil && !dvNotNull) {
alterColumn = true
}
}
}
// check comment
if comment, ok := columnType.Comment(); ok && comment != field.Comment {
// not primary key
if !field.PrimaryKey {
alterColumn = true
}
}
if alterColumn && !field.IgnoreMigration {
return m.DB.Migrator().AlterColumn(value, field.Name)
}
return nil
}
// ColumnTypes return columnTypes []gorm.ColumnType and execErr error
func (m Migrator) ColumnTypes(value interface{}) ([]gorm.ColumnType, error) {
columnTypes := make([]gorm.ColumnType, 0)
execErr := m.RunWithValue(value, func(stmt *gorm.Statement) (err error) {
rows, err := m.DB.Session(&gorm.Session{}).Table(stmt.Table).Limit(1).Rows()
if err != nil {
return err
}
defer func() {
err = rows.Close()
}()
var rawColumnTypes []*sql.ColumnType
rawColumnTypes, err = rows.ColumnTypes()
if err != nil {
return err
}
for _, c := range rawColumnTypes {
columnTypes = append(columnTypes, ColumnType{SQLColumnType: c})
}
return
})
return columnTypes, execErr
}
// CreateView create view
func (m Migrator) CreateView(name string, option gorm.ViewOption) error {
return gorm.ErrNotImplemented
}
// DropView drop view
func (m Migrator) DropView(name string) error {
return gorm.ErrNotImplemented
}
func buildConstraint(constraint *schema.Constraint) (sql string, results []interface{}) {
sql = "CONSTRAINT ? FOREIGN KEY ? REFERENCES ??"
if constraint.OnDelete != "" {
sql += " ON DELETE " + constraint.OnDelete
}
if constraint.OnUpdate != "" {
sql += " ON UPDATE " + constraint.OnUpdate
}
var foreignKeys, references []interface{}
for _, field := range constraint.ForeignKeys {
foreignKeys = append(foreignKeys, clause.Column{Name: field.DBName})
}
for _, field := range constraint.References {
references = append(references, clause.Column{Name: field.DBName})
}
results = append(results, clause.Table{Name: constraint.Name}, foreignKeys, clause.Table{Name: constraint.ReferenceSchema.Table}, references)
return
}
// GuessConstraintAndTable guess statement's constraint and it's table based on name
func (m Migrator) GuessConstraintAndTable(stmt *gorm.Statement, name string) (_ *schema.Constraint, _ *schema.Check, table string) {
if stmt.Schema == nil {
return nil, nil, stmt.Table
}
checkConstraints := stmt.Schema.ParseCheckConstraints()
if chk, ok := checkConstraints[name]; ok {
return nil, &chk, stmt.Table
}
getTable := func(rel *schema.Relationship) string {
switch rel.Type {
case schema.HasOne, schema.HasMany:
return rel.FieldSchema.Table
case schema.Many2Many:
return rel.JoinTable.Table
}
return stmt.Table
}
for _, rel := range stmt.Schema.Relationships.Relations {
if constraint := rel.ParseConstraint(); constraint != nil && constraint.Name == name {
return constraint, nil, getTable(rel)
}
}
if field := stmt.Schema.LookUpField(name); field != nil {
for k := range checkConstraints {
if checkConstraints[k].Field == field {
v := checkConstraints[k]
return nil, &v, stmt.Table
}
}
for _, rel := range stmt.Schema.Relationships.Relations {
if constraint := rel.ParseConstraint(); constraint != nil && rel.Field == field {
return constraint, nil, getTable(rel)
}
}
}
return nil, nil, stmt.Schema.Table
}
// CreateConstraint create constraint
func (m Migrator) CreateConstraint(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
constraint, chk, table := m.GuessConstraintAndTable(stmt, name)
if chk != nil {
return m.DB.Exec(
"ALTER TABLE ? ADD CONSTRAINT ? CHECK (?)",
m.CurrentTable(stmt), clause.Column{Name: chk.Name}, clause.Expr{SQL: chk.Constraint},
).Error
}
if constraint != nil {
vars := []interface{}{clause.Table{Name: table}}
if stmt.TableExpr != nil {
vars[0] = stmt.TableExpr
}
sql, values := buildConstraint(constraint)
return m.DB.Exec("ALTER TABLE ? ADD "+sql, append(vars, values...)...).Error
}
return nil
})
}
// DropConstraint drop constraint
func (m Migrator) DropConstraint(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
constraint, chk, table := m.GuessConstraintAndTable(stmt, name)
if constraint != nil {
name = constraint.Name
} else if chk != nil {
name = chk.Name
}
return m.DB.Exec("ALTER TABLE ? DROP CONSTRAINT ?", clause.Table{Name: table}, clause.Column{Name: name}).Error
})
}
// HasConstraint check has constraint or not
func (m Migrator) HasConstraint(value interface{}, name string) bool {
var count int64
m.RunWithValue(value, func(stmt *gorm.Statement) error {
currentDatabase := m.DB.Migrator().CurrentDatabase()
constraint, chk, table := m.GuessConstraintAndTable(stmt, name)
if constraint != nil {
name = constraint.Name
} else if chk != nil {
name = chk.Name
}
return m.DB.Raw(
"SELECT count(*) FROM INFORMATION_SCHEMA.table_constraints WHERE constraint_schema = ? AND table_name = ? AND constraint_name = ?",
currentDatabase, table, name,
).Row().Scan(&count)
})
return count > 0
}
// BuildIndexOptions build index options
func (m Migrator) BuildIndexOptions(opts []schema.IndexOption, stmt *gorm.Statement) (results []interface{}) {
for _, opt := range opts {
str := stmt.Quote(opt.DBName)
if opt.Expression != "" {
str = opt.Expression
} else if opt.Length > 0 {
str += fmt.Sprintf("(%d)", opt.Length)
}
if opt.Collate != "" {
str += " COLLATE " + opt.Collate
}
if opt.Sort != "" {
str += " " + opt.Sort
}
results = append(results, clause.Expr{SQL: str})
}
return
}
// BuildIndexOptionsInterface build index options interface
type BuildIndexOptionsInterface interface {
BuildIndexOptions([]schema.IndexOption, *gorm.Statement) []interface{}
}
// CreateIndex create index `name`
func (m Migrator) CreateIndex(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
if idx := stmt.Schema.LookIndex(name); idx != nil {
opts := m.DB.Migrator().(BuildIndexOptionsInterface).BuildIndexOptions(idx.Fields, stmt)
values := []interface{}{clause.Column{Name: idx.Name}, m.CurrentTable(stmt), opts}
createIndexSQL := "CREATE "
if idx.Class != "" {
createIndexSQL += idx.Class + " "
}
createIndexSQL += "INDEX ? ON ??"
if idx.Type != "" {
createIndexSQL += " USING " + idx.Type
}
if idx.Comment != "" {
createIndexSQL += fmt.Sprintf(" COMMENT '%s'", idx.Comment)
}
if idx.Option != "" {
createIndexSQL += " " + idx.Option
}
return m.DB.Exec(createIndexSQL, values...).Error
}
return fmt.Errorf("failed to create index with name %s", name)
})
}
// DropIndex drop index `name`
func (m Migrator) DropIndex(value interface{}, name string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
if idx := stmt.Schema.LookIndex(name); idx != nil {
name = idx.Name
}
return m.DB.Exec("DROP INDEX ? ON ?", clause.Column{Name: name}, m.CurrentTable(stmt)).Error
})
}
// HasIndex check has index `name` or not
func (m Migrator) HasIndex(value interface{}, name string) bool {
var count int64
m.RunWithValue(value, func(stmt *gorm.Statement) error {
currentDatabase := m.DB.Migrator().CurrentDatabase()
if idx := stmt.Schema.LookIndex(name); idx != nil {
name = idx.Name
}
return m.DB.Raw(
"SELECT count(*) FROM information_schema.statistics WHERE table_schema = ? AND table_name = ? AND index_name = ?",
currentDatabase, stmt.Table, name,
).Row().Scan(&count)
})
return count > 0
}
// RenameIndex rename index from oldName to newName
func (m Migrator) RenameIndex(value interface{}, oldName, newName string) error {
return m.RunWithValue(value, func(stmt *gorm.Statement) error {
return m.DB.Exec(
"ALTER TABLE ? RENAME INDEX ? TO ?",
m.CurrentTable(stmt), clause.Column{Name: oldName}, clause.Column{Name: newName},
).Error
})
}
// CurrentDatabase returns current database name
func (m Migrator) CurrentDatabase() (name string) {
m.DB.Raw("SELECT DATABASE()").Row().Scan(&name)
return
}
// ReorderModels reorder models according to constraint dependencies
func (m Migrator) ReorderModels(values []interface{}, autoAdd bool) (results []interface{}) {
type Dependency struct {
*gorm.Statement
Depends []*schema.Schema
}
var (
modelNames, orderedModelNames []string
orderedModelNamesMap = map[string]bool{}
parsedSchemas = map[*schema.Schema]bool{}
valuesMap = map[string]Dependency{}
insertIntoOrderedList func(name string)
parseDependence func(value interface{}, addToList bool)
)
parseDependence = func(value interface{}, addToList bool) {
dep := Dependency{
Statement: &gorm.Statement{DB: m.DB, Dest: value},
}
beDependedOn := map[*schema.Schema]bool{}
// support for special table name
if err := dep.ParseWithSpecialTableName(value, m.DB.Statement.Table); err != nil {
m.DB.Logger.Error(context.Background(), "failed to parse value %#v, got error %v", value, err)
}
if _, ok := parsedSchemas[dep.Statement.Schema]; ok {
return
}
parsedSchemas[dep.Statement.Schema] = true
for _, rel := range dep.Schema.Relationships.Relations {
if c := rel.ParseConstraint(); c != nil && c.Schema == dep.Statement.Schema && c.Schema != c.ReferenceSchema {
dep.Depends = append(dep.Depends, c.ReferenceSchema)
}
if rel.Type == schema.HasOne || rel.Type == schema.HasMany {
beDependedOn[rel.FieldSchema] = true
}
if rel.JoinTable != nil {
// append join value
defer func(rel *schema.Relationship, joinValue interface{}) {
if !beDependedOn[rel.FieldSchema] {
dep.Depends = append(dep.Depends, rel.FieldSchema)
} else {
fieldValue := reflect.New(rel.FieldSchema.ModelType).Interface()
parseDependence(fieldValue, autoAdd)
}
parseDependence(joinValue, autoAdd)
}(rel, reflect.New(rel.JoinTable.ModelType).Interface())
}
}
valuesMap[dep.Schema.Table] = dep
if addToList {
modelNames = append(modelNames, dep.Schema.Table)
}
}
insertIntoOrderedList = func(name string) {
if _, ok := orderedModelNamesMap[name]; ok {
return // avoid loop
}
orderedModelNamesMap[name] = true
if autoAdd {
dep := valuesMap[name]
for _, d := range dep.Depends {
if _, ok := valuesMap[d.Table]; ok {
insertIntoOrderedList(d.Table)
} else {
parseDependence(reflect.New(d.ModelType).Interface(), autoAdd)
insertIntoOrderedList(d.Table)
}
}
}
orderedModelNames = append(orderedModelNames, name)
}
for _, value := range values {
if v, ok := value.(string); ok {
results = append(results, v)
} else {
parseDependence(value, true)
}
}
for _, name := range modelNames {
insertIntoOrderedList(name)
}
for _, name := range orderedModelNames {
results = append(results, valuesMap[name].Statement.Dest)
}
return
}
// CurrentTable returns current statement's table expression
func (m Migrator) CurrentTable(stmt *gorm.Statement) interface{} {
if stmt.TableExpr != nil {
return *stmt.TableExpr
}
return clause.Table{Name: stmt.Table}
}