package gorm import ( "context" "database/sql" "database/sql/driver" "fmt" "reflect" "sort" "strconv" "strings" "sync" "gorm.io/gorm/clause" "gorm.io/gorm/logger" "gorm.io/gorm/schema" "gorm.io/gorm/utils" ) // Statement statement type Statement struct { *DB TableExpr *clause.Expr Table string Model interface{} Unscoped bool Dest interface{} ReflectValue reflect.Value Clauses map[string]clause.Clause Distinct bool Selects []string // selected columns Omits []string // omit columns Joins []join Preloads map[string][]interface{} Settings sync.Map ConnPool ConnPool Schema *schema.Schema Context context.Context RaiseErrorOnNotFound bool SkipHooks bool SQL strings.Builder Vars []interface{} CurDestIndex int attrs []interface{} assigns []interface{} } type join struct { Name string Conds []interface{} } // StatementModifier statement modifier interface type StatementModifier interface { ModifyStatement(*Statement) } // Write write string func (stmt *Statement) WriteString(str string) (int, error) { return stmt.SQL.WriteString(str) } // Write write string func (stmt *Statement) WriteByte(c byte) error { return stmt.SQL.WriteByte(c) } // WriteQuoted write quoted value func (stmt *Statement) WriteQuoted(value interface{}) { stmt.QuoteTo(&stmt.SQL, value) } // QuoteTo write quoted value to writer func (stmt *Statement) QuoteTo(writer clause.Writer, field interface{}) { switch v := field.(type) { case clause.Table: if v.Name == clause.CurrentTable { if stmt.TableExpr != nil { stmt.TableExpr.Build(stmt) } else { stmt.DB.Dialector.QuoteTo(writer, stmt.Table) } } else if v.Raw { writer.WriteString(v.Name) } else { stmt.DB.Dialector.QuoteTo(writer, v.Name) } if v.Alias != "" { writer.WriteByte(' ') stmt.DB.Dialector.QuoteTo(writer, v.Alias) } case clause.Column: if v.Table != "" { if v.Table == clause.CurrentTable { stmt.DB.Dialector.QuoteTo(writer, stmt.Table) } else { stmt.DB.Dialector.QuoteTo(writer, v.Table) } writer.WriteByte('.') } if v.Name == clause.PrimaryKey { if stmt.Schema == nil { stmt.DB.AddError(ErrModelValueRequired) } else if stmt.Schema.PrioritizedPrimaryField != nil { stmt.DB.Dialector.QuoteTo(writer, stmt.Schema.PrioritizedPrimaryField.DBName) } else if len(stmt.Schema.DBNames) > 0 { stmt.DB.Dialector.QuoteTo(writer, stmt.Schema.DBNames[0]) } } else if v.Raw { writer.WriteString(v.Name) } else { stmt.DB.Dialector.QuoteTo(writer, v.Name) } if v.Alias != "" { writer.WriteString(" AS ") stmt.DB.Dialector.QuoteTo(writer, v.Alias) } case []clause.Column: writer.WriteByte('(') for idx, d := range v { if idx > 0 { writer.WriteString(",") } stmt.QuoteTo(writer, d) } writer.WriteByte(')') case string: stmt.DB.Dialector.QuoteTo(writer, v) case []string: writer.WriteByte('(') for idx, d := range v { if idx > 0 { writer.WriteString(",") } stmt.DB.Dialector.QuoteTo(writer, d) } writer.WriteByte(')') default: stmt.DB.Dialector.QuoteTo(writer, fmt.Sprint(field)) } } // Quote returns quoted value func (stmt *Statement) Quote(field interface{}) string { var builder strings.Builder stmt.QuoteTo(&builder, field) return builder.String() } // Write write string func (stmt *Statement) AddVar(writer clause.Writer, vars ...interface{}) { for idx, v := range vars { if idx > 0 { writer.WriteByte(',') } switch v := v.(type) { case sql.NamedArg: stmt.Vars = append(stmt.Vars, v.Value) case clause.Column, clause.Table: stmt.QuoteTo(writer, v) case Valuer: stmt.AddVar(writer, v.GormValue(stmt.Context, stmt.DB)) case clause.Expr: v.Build(stmt) case driver.Valuer: stmt.Vars = append(stmt.Vars, v) stmt.DB.Dialector.BindVarTo(writer, stmt, v) case []byte: stmt.Vars = append(stmt.Vars, v) stmt.DB.Dialector.BindVarTo(writer, stmt, v) case []interface{}: if len(v) > 0 { writer.WriteByte('(') stmt.AddVar(writer, v...) writer.WriteByte(')') } else { writer.WriteString("(NULL)") } case *DB: subdb := v.Session(&Session{Logger: logger.Discard, DryRun: true}).getInstance() if v.Statement.SQL.Len() > 0 { var ( vars = subdb.Statement.Vars sql = v.Statement.SQL.String() ) subdb.Statement.Vars = make([]interface{}, 0, len(vars)) for _, vv := range vars { subdb.Statement.Vars = append(subdb.Statement.Vars, vv) bindvar := strings.Builder{} v.Dialector.BindVarTo(&bindvar, subdb.Statement, vv) sql = strings.Replace(sql, bindvar.String(), "?", 1) } subdb.Statement.SQL.Reset() subdb.Statement.Vars = stmt.Vars if strings.Contains(sql, "@") { clause.NamedExpr{SQL: sql, Vars: vars}.Build(subdb.Statement) } else { clause.Expr{SQL: sql, Vars: vars}.Build(subdb.Statement) } } else { subdb.Statement.Vars = append(stmt.Vars, subdb.Statement.Vars...) subdb.callbacks.Query().Execute(subdb) } writer.WriteString(subdb.Statement.SQL.String()) stmt.Vars = subdb.Statement.Vars default: switch rv := reflect.ValueOf(v); rv.Kind() { case reflect.Slice, reflect.Array: if rv.Len() == 0 { writer.WriteString("(NULL)") } else { writer.WriteByte('(') for i := 0; i < rv.Len(); i++ { if i > 0 { writer.WriteByte(',') } stmt.AddVar(writer, rv.Index(i).Interface()) } writer.WriteByte(')') } default: stmt.Vars = append(stmt.Vars, v) stmt.DB.Dialector.BindVarTo(writer, stmt, v) } } } } // AddClause add clause func (stmt *Statement) AddClause(v clause.Interface) { if optimizer, ok := v.(StatementModifier); ok { optimizer.ModifyStatement(stmt) } else { name := v.Name() c := stmt.Clauses[name] c.Name = name v.MergeClause(&c) stmt.Clauses[name] = c } } // AddClauseIfNotExists add clause if not exists func (stmt *Statement) AddClauseIfNotExists(v clause.Interface) { if c, ok := stmt.Clauses[v.Name()]; !ok || c.Expression == nil { stmt.AddClause(v) } } // BuildCondition build condition func (stmt *Statement) BuildCondition(query interface{}, args ...interface{}) []clause.Expression { if s, ok := query.(string); ok { // if it is a number, then treats it as primary key if _, err := strconv.Atoi(s); err != nil { if s == "" && len(args) == 0 { return nil } else if len(args) == 0 || (len(args) > 0 && strings.Contains(s, "?")) { // looks like a where condition return []clause.Expression{clause.Expr{SQL: s, Vars: args}} } else if len(args) > 0 && strings.Contains(s, "@") { // looks like a named query return []clause.Expression{clause.NamedExpr{SQL: s, Vars: args}} } else if len(args) == 1 { return []clause.Expression{clause.Eq{Column: s, Value: args[0]}} } } } conds := make([]clause.Expression, 0, 4) args = append([]interface{}{query}, args...) for idx, arg := range args { if valuer, ok := arg.(driver.Valuer); ok { arg, _ = valuer.Value() } switch v := arg.(type) { case clause.Expression: conds = append(conds, v) case *DB: if cs, ok := v.Statement.Clauses["WHERE"]; ok { if where, ok := cs.Expression.(clause.Where); ok { if len(where.Exprs) == 1 { if orConds, ok := where.Exprs[0].(clause.OrConditions); ok { where.Exprs[0] = clause.AndConditions{Exprs: orConds.Exprs} } } conds = append(conds, clause.And(where.Exprs...)) } else if cs.Expression != nil { conds = append(conds, cs.Expression) } } case map[interface{}]interface{}: for i, j := range v { conds = append(conds, clause.Eq{Column: i, Value: j}) } case map[string]string: var keys = make([]string, 0, len(v)) for i := range v { keys = append(keys, i) } sort.Strings(keys) for _, key := range keys { conds = append(conds, clause.Eq{Column: key, Value: v[key]}) } case map[string]interface{}: var keys = make([]string, 0, len(v)) for i := range v { keys = append(keys, i) } sort.Strings(keys) for _, key := range keys { reflectValue := reflect.Indirect(reflect.ValueOf(v[key])) switch reflectValue.Kind() { case reflect.Slice, reflect.Array: if _, ok := v[key].(driver.Valuer); ok { conds = append(conds, clause.Eq{Column: key, Value: v[key]}) } else if _, ok := v[key].(Valuer); ok { conds = append(conds, clause.Eq{Column: key, Value: v[key]}) } else { values := make([]interface{}, reflectValue.Len()) for i := 0; i < reflectValue.Len(); i++ { values[i] = reflectValue.Index(i).Interface() } conds = append(conds, clause.IN{Column: key, Values: values}) } default: conds = append(conds, clause.Eq{Column: key, Value: v[key]}) } } default: reflectValue := reflect.Indirect(reflect.ValueOf(arg)) if s, err := schema.Parse(arg, stmt.DB.cacheStore, stmt.DB.NamingStrategy); err == nil { selectedColumns := map[string]bool{} if idx == 0 { for _, v := range args[1:] { if vs, ok := v.(string); ok { selectedColumns[vs] = true } } } restricted := len(selectedColumns) != 0 switch reflectValue.Kind() { case reflect.Struct: for _, field := range s.Fields { selected := selectedColumns[field.DBName] || selectedColumns[field.Name] if selected || (!restricted && field.Readable) { if v, isZero := field.ValueOf(reflectValue); !isZero || selected { if field.DBName != "" { conds = append(conds, clause.Eq{Column: clause.Column{Table: clause.CurrentTable, Name: field.DBName}, Value: v}) } else if field.DataType != "" { conds = append(conds, clause.Eq{Column: clause.Column{Table: clause.CurrentTable, Name: field.Name}, Value: v}) } } } } case reflect.Slice, reflect.Array: for i := 0; i < reflectValue.Len(); i++ { for _, field := range s.Fields { selected := selectedColumns[field.DBName] || selectedColumns[field.Name] if selected || (!restricted && field.Readable) { if v, isZero := field.ValueOf(reflectValue.Index(i)); !isZero || selected { if field.DBName != "" { conds = append(conds, clause.Eq{Column: clause.Column{Table: clause.CurrentTable, Name: field.DBName}, Value: v}) } else if field.DataType != "" { conds = append(conds, clause.Eq{Column: clause.Column{Table: clause.CurrentTable, Name: field.Name}, Value: v}) } } } } } } if restricted { break } } else if !reflectValue.IsValid() { stmt.AddError(ErrInvalidData) } else if len(conds) == 0 { if len(args) == 1 { switch reflectValue.Kind() { case reflect.Slice, reflect.Array: values := make([]interface{}, reflectValue.Len()) for i := 0; i < reflectValue.Len(); i++ { values[i] = reflectValue.Index(i).Interface() } if len(values) > 0 { conds = append(conds, clause.IN{Column: clause.PrimaryColumn, Values: values}) } return conds } } conds = append(conds, clause.IN{Column: clause.PrimaryColumn, Values: args}) } } } return conds } // Build build sql with clauses names func (stmt *Statement) Build(clauses ...string) { var firstClauseWritten bool for _, name := range clauses { if c, ok := stmt.Clauses[name]; ok { if firstClauseWritten { stmt.WriteByte(' ') } firstClauseWritten = true if b, ok := stmt.DB.ClauseBuilders[name]; ok { b(c, stmt) } else { c.Build(stmt) } } } } func (stmt *Statement) Parse(value interface{}) (err error) { if stmt.Schema, err = schema.Parse(value, stmt.DB.cacheStore, stmt.DB.NamingStrategy); err == nil && stmt.Table == "" { if tables := strings.Split(stmt.Schema.Table, "."); len(tables) == 2 { stmt.TableExpr = &clause.Expr{SQL: stmt.Quote(stmt.Schema.Table)} stmt.Table = tables[1] return } stmt.Table = stmt.Schema.Table } return err } func (stmt *Statement) clone() *Statement { newStmt := &Statement{ TableExpr: stmt.TableExpr, Table: stmt.Table, Model: stmt.Model, Unscoped: stmt.Unscoped, Dest: stmt.Dest, ReflectValue: stmt.ReflectValue, Clauses: map[string]clause.Clause{}, Distinct: stmt.Distinct, Selects: stmt.Selects, Omits: stmt.Omits, Preloads: map[string][]interface{}{}, ConnPool: stmt.ConnPool, Schema: stmt.Schema, Context: stmt.Context, RaiseErrorOnNotFound: stmt.RaiseErrorOnNotFound, SkipHooks: stmt.SkipHooks, } if stmt.SQL.Len() > 0 { newStmt.SQL.WriteString(stmt.SQL.String()) newStmt.Vars = make([]interface{}, 0, len(stmt.Vars)) newStmt.Vars = append(newStmt.Vars, stmt.Vars...) } for k, c := range stmt.Clauses { newStmt.Clauses[k] = c } for k, p := range stmt.Preloads { newStmt.Preloads[k] = p } if len(stmt.Joins) > 0 { newStmt.Joins = make([]join, len(stmt.Joins)) copy(newStmt.Joins, stmt.Joins) } stmt.Settings.Range(func(k, v interface{}) bool { newStmt.Settings.Store(k, v) return true }) return newStmt } // Helpers // SetColumn set column's value // stmt.SetColumn("Name", "jinzhu") // Hooks Method // stmt.SetColumn("Name", "jinzhu", true) // Callbacks Method func (stmt *Statement) SetColumn(name string, value interface{}, fromCallbacks ...bool) { if v, ok := stmt.Dest.(map[string]interface{}); ok { v[name] = value } else if v, ok := stmt.Dest.([]map[string]interface{}); ok { for _, m := range v { m[name] = value } } else if stmt.Schema != nil { if field := stmt.Schema.LookUpField(name); field != nil { destValue := reflect.ValueOf(stmt.Dest) for destValue.Kind() == reflect.Ptr { destValue = destValue.Elem() } if stmt.ReflectValue != destValue { if !destValue.CanAddr() { destValueCanAddr := reflect.New(destValue.Type()) destValueCanAddr.Elem().Set(destValue) stmt.Dest = destValueCanAddr.Interface() destValue = destValueCanAddr.Elem() } switch destValue.Kind() { case reflect.Struct: field.Set(destValue, value) default: stmt.AddError(ErrInvalidData) } } switch stmt.ReflectValue.Kind() { case reflect.Slice, reflect.Array: if len(fromCallbacks) > 0 { for i := 0; i < stmt.ReflectValue.Len(); i++ { field.Set(stmt.ReflectValue.Index(i), value) } } else { field.Set(stmt.ReflectValue.Index(stmt.CurDestIndex), value) } case reflect.Struct: field.Set(stmt.ReflectValue, value) } } else { stmt.AddError(ErrInvalidField) } } else { stmt.AddError(ErrInvalidField) } } // Changed check model changed or not when updating func (stmt *Statement) Changed(fields ...string) bool { modelValue := stmt.ReflectValue switch modelValue.Kind() { case reflect.Slice, reflect.Array: modelValue = stmt.ReflectValue.Index(stmt.CurDestIndex) } selectColumns, restricted := stmt.SelectAndOmitColumns(false, true) changed := func(field *schema.Field) bool { fieldValue, _ := field.ValueOf(modelValue) if v, ok := selectColumns[field.DBName]; (ok && v) || (!ok && !restricted) { if v, ok := stmt.Dest.(map[string]interface{}); ok { if fv, ok := v[field.Name]; ok { return !utils.AssertEqual(fv, fieldValue) } else if fv, ok := v[field.DBName]; ok { return !utils.AssertEqual(fv, fieldValue) } } else { destValue := reflect.ValueOf(stmt.Dest) for destValue.Kind() == reflect.Ptr { destValue = destValue.Elem() } changedValue, zero := field.ValueOf(destValue) return !zero && !utils.AssertEqual(changedValue, fieldValue) } } return false } if len(fields) == 0 { for _, field := range stmt.Schema.FieldsByDBName { if changed(field) { return true } } } else { for _, name := range fields { if field := stmt.Schema.LookUpField(name); field != nil { if changed(field) { return true } } } } return false } // SelectAndOmitColumns get select and omit columns, select -> true, omit -> false func (stmt *Statement) SelectAndOmitColumns(requireCreate, requireUpdate bool) (map[string]bool, bool) { results := map[string]bool{} notRestricted := false // select columns for _, column := range stmt.Selects { if column == "*" { notRestricted = true for _, dbName := range stmt.Schema.DBNames { results[dbName] = true } } else if column == clause.Associations && stmt.Schema != nil { for _, rel := range stmt.Schema.Relationships.Relations { results[rel.Name] = true } } else if field := stmt.Schema.LookUpField(column); field != nil && field.DBName != "" { results[field.DBName] = true } else { results[column] = true } } // omit columns for _, omit := range stmt.Omits { if omit == clause.Associations { if stmt.Schema != nil { for _, rel := range stmt.Schema.Relationships.Relations { results[rel.Name] = false } } } else if field := stmt.Schema.LookUpField(omit); field != nil && field.DBName != "" { results[field.DBName] = false } else { results[omit] = false } } if stmt.Schema != nil { for _, field := range stmt.Schema.FieldsByName { name := field.DBName if name == "" { name = field.Name } if requireCreate && !field.Creatable { results[name] = false } else if requireUpdate && !field.Updatable { results[name] = false } } } return results, !notRestricted && len(stmt.Selects) > 0 }