githaven/vendor/github.com/go-xorm/xorm/engine.go

1642 lines
45 KiB
Go

// Copyright 2015 The Xorm Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package xorm
import (
"bufio"
"bytes"
"database/sql"
"encoding/gob"
"errors"
"fmt"
"io"
"os"
"reflect"
"strconv"
"strings"
"sync"
"time"
"github.com/go-xorm/core"
)
// Engine is the major struct of xorm, it means a database manager.
// Commonly, an application only need one engine
type Engine struct {
db *core.DB
dialect core.Dialect
ColumnMapper core.IMapper
TableMapper core.IMapper
TagIdentifier string
Tables map[reflect.Type]*core.Table
mutex *sync.RWMutex
Cacher core.Cacher
showSQL bool
showExecTime bool
logger core.ILogger
TZLocation *time.Location
DatabaseTZ *time.Location // The timezone of the database
disableGlobalCache bool
}
// ShowSQL show SQL statement or not on logger if log level is great than INFO
func (engine *Engine) ShowSQL(show ...bool) {
engine.logger.ShowSQL(show...)
if len(show) == 0 {
engine.showSQL = true
} else {
engine.showSQL = show[0]
}
}
// ShowExecTime show SQL statement and execute time or not on logger if log level is great than INFO
func (engine *Engine) ShowExecTime(show ...bool) {
if len(show) == 0 {
engine.showExecTime = true
} else {
engine.showExecTime = show[0]
}
}
// Logger return the logger interface
func (engine *Engine) Logger() core.ILogger {
return engine.logger
}
// SetLogger set the new logger
func (engine *Engine) SetLogger(logger core.ILogger) {
engine.logger = logger
engine.dialect.SetLogger(logger)
}
// SetDisableGlobalCache disable global cache or not
func (engine *Engine) SetDisableGlobalCache(disable bool) {
if engine.disableGlobalCache != disable {
engine.disableGlobalCache = disable
}
}
// DriverName return the current sql driver's name
func (engine *Engine) DriverName() string {
return engine.dialect.DriverName()
}
// DataSourceName return the current connection string
func (engine *Engine) DataSourceName() string {
return engine.dialect.DataSourceName()
}
// SetMapper set the name mapping rules
func (engine *Engine) SetMapper(mapper core.IMapper) {
engine.SetTableMapper(mapper)
engine.SetColumnMapper(mapper)
}
// SetTableMapper set the table name mapping rule
func (engine *Engine) SetTableMapper(mapper core.IMapper) {
engine.TableMapper = mapper
}
// SetColumnMapper set the column name mapping rule
func (engine *Engine) SetColumnMapper(mapper core.IMapper) {
engine.ColumnMapper = mapper
}
// SupportInsertMany If engine's database support batch insert records like
// "insert into user values (name, age), (name, age)".
// When the return is ture, then engine.Insert(&users) will
// generate batch sql and exeute.
func (engine *Engine) SupportInsertMany() bool {
return engine.dialect.SupportInsertMany()
}
// QuoteStr Engine's database use which character as quote.
// mysql, sqlite use ` and postgres use "
func (engine *Engine) QuoteStr() string {
return engine.dialect.QuoteStr()
}
// Quote Use QuoteStr quote the string sql
func (engine *Engine) Quote(value string) string {
value = strings.TrimSpace(value)
if len(value) == 0 {
return value
}
if string(value[0]) == engine.dialect.QuoteStr() || value[0] == '`' {
return value
}
value = strings.Replace(value, ".", engine.dialect.QuoteStr()+"."+engine.dialect.QuoteStr(), -1)
return engine.dialect.QuoteStr() + value + engine.dialect.QuoteStr()
}
// QuoteTo quotes string and writes into the buffer
func (engine *Engine) QuoteTo(buf *bytes.Buffer, value string) {
if buf == nil {
return
}
value = strings.TrimSpace(value)
if value == "" {
return
}
if string(value[0]) == engine.dialect.QuoteStr() || value[0] == '`' {
buf.WriteString(value)
return
}
value = strings.Replace(value, ".", engine.dialect.QuoteStr()+"."+engine.dialect.QuoteStr(), -1)
buf.WriteString(engine.dialect.QuoteStr())
buf.WriteString(value)
buf.WriteString(engine.dialect.QuoteStr())
}
func (engine *Engine) quote(sql string) string {
return engine.dialect.QuoteStr() + sql + engine.dialect.QuoteStr()
}
// SqlType will be depracated, please use SQLType instead
//
// Deprecated: use SQLType instead
func (engine *Engine) SqlType(c *core.Column) string {
return engine.SQLType(c)
}
// SQLType A simple wrapper to dialect's core.SqlType method
func (engine *Engine) SQLType(c *core.Column) string {
return engine.dialect.SqlType(c)
}
// AutoIncrStr Database's autoincrement statement
func (engine *Engine) AutoIncrStr() string {
return engine.dialect.AutoIncrStr()
}
// SetMaxOpenConns is only available for go 1.2+
func (engine *Engine) SetMaxOpenConns(conns int) {
engine.db.SetMaxOpenConns(conns)
}
// SetMaxIdleConns set the max idle connections on pool, default is 2
func (engine *Engine) SetMaxIdleConns(conns int) {
engine.db.SetMaxIdleConns(conns)
}
// SetDefaultCacher set the default cacher. Xorm's default not enable cacher.
func (engine *Engine) SetDefaultCacher(cacher core.Cacher) {
engine.Cacher = cacher
}
// NoCache If you has set default cacher, and you want temporilly stop use cache,
// you can use NoCache()
func (engine *Engine) NoCache() *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.NoCache()
}
// NoCascade If you do not want to auto cascade load object
func (engine *Engine) NoCascade() *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.NoCascade()
}
// MapCacher Set a table use a special cacher
func (engine *Engine) MapCacher(bean interface{}, cacher core.Cacher) {
v := rValue(bean)
tb := engine.autoMapType(v)
tb.Cacher = cacher
}
// NewDB provides an interface to operate database directly
func (engine *Engine) NewDB() (*core.DB, error) {
return core.OpenDialect(engine.dialect)
}
// DB return the wrapper of sql.DB
func (engine *Engine) DB() *core.DB {
return engine.db
}
// Dialect return database dialect
func (engine *Engine) Dialect() core.Dialect {
return engine.dialect
}
// NewSession New a session
func (engine *Engine) NewSession() *Session {
session := &Session{Engine: engine}
session.Init()
return session
}
// Close the engine
func (engine *Engine) Close() error {
return engine.db.Close()
}
// Ping tests if database is alive
func (engine *Engine) Ping() error {
session := engine.NewSession()
defer session.Close()
engine.logger.Infof("PING DATABASE %v", engine.DriverName())
return session.Ping()
}
// logging sql
func (engine *Engine) logSQL(sqlStr string, sqlArgs ...interface{}) {
if engine.showSQL && !engine.showExecTime {
if len(sqlArgs) > 0 {
engine.logger.Infof("[sql] %v [args] %v", sqlStr, sqlArgs)
} else {
engine.logger.Infof("[sql] %v", sqlStr)
}
}
}
func (engine *Engine) logSQLQueryTime(sqlStr string, args []interface{}, executionBlock func() (*core.Stmt, *core.Rows, error)) (*core.Stmt, *core.Rows, error) {
if engine.showSQL && engine.showExecTime {
b4ExecTime := time.Now()
stmt, res, err := executionBlock()
execDuration := time.Since(b4ExecTime)
if len(args) > 0 {
engine.logger.Infof("[sql] %s [args] %v - took: %v", sqlStr, args, execDuration)
} else {
engine.logger.Infof("[sql] %s - took: %v", sqlStr, execDuration)
}
return stmt, res, err
}
return executionBlock()
}
func (engine *Engine) logSQLExecutionTime(sqlStr string, args []interface{}, executionBlock func() (sql.Result, error)) (sql.Result, error) {
if engine.showSQL && engine.showExecTime {
b4ExecTime := time.Now()
res, err := executionBlock()
execDuration := time.Since(b4ExecTime)
if len(args) > 0 {
engine.logger.Infof("[sql] %s [args] %v - took: %v", sqlStr, args, execDuration)
} else {
engine.logger.Infof("[sql] %s - took: %v", sqlStr, execDuration)
}
return res, err
}
return executionBlock()
}
// Sql provides raw sql input parameter. When you have a complex SQL statement
// and cannot use Where, Id, In and etc. Methods to describe, you can use SQL.
//
// Deprecated: use SQL instead.
func (engine *Engine) Sql(querystring string, args ...interface{}) *Session {
return engine.SQL(querystring, args...)
}
// SQL method let's you manually write raw SQL and operate
// For example:
//
// engine.SQL("select * from user").Find(&users)
//
// This code will execute "select * from user" and set the records to users
func (engine *Engine) SQL(query interface{}, args ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.SQL(query, args...)
}
// NoAutoTime Default if your struct has "created" or "updated" filed tag, the fields
// will automatically be filled with current time when Insert or Update
// invoked. Call NoAutoTime if you dont' want to fill automatically.
func (engine *Engine) NoAutoTime() *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.NoAutoTime()
}
// NoAutoCondition disable auto generate Where condition from bean or not
func (engine *Engine) NoAutoCondition(no ...bool) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.NoAutoCondition(no...)
}
// DBMetas Retrieve all tables, columns, indexes' informations from database.
func (engine *Engine) DBMetas() ([]*core.Table, error) {
tables, err := engine.dialect.GetTables()
if err != nil {
return nil, err
}
for _, table := range tables {
colSeq, cols, err := engine.dialect.GetColumns(table.Name)
if err != nil {
return nil, err
}
for _, name := range colSeq {
table.AddColumn(cols[name])
}
indexes, err := engine.dialect.GetIndexes(table.Name)
if err != nil {
return nil, err
}
table.Indexes = indexes
for _, index := range indexes {
for _, name := range index.Cols {
if col := table.GetColumn(name); col != nil {
col.Indexes[index.Name] = index.Type
} else {
return nil, fmt.Errorf("Unknown col %s in index %v of table %v, columns %v", name, index.Name, table.Name, table.ColumnsSeq())
}
}
}
}
return tables, nil
}
// DumpAllToFile dump database all table structs and data to a file
func (engine *Engine) DumpAllToFile(fp string, tp ...core.DbType) error {
f, err := os.Create(fp)
if err != nil {
return err
}
defer f.Close()
return engine.DumpAll(f, tp...)
}
// DumpAll dump database all table structs and data to w
func (engine *Engine) DumpAll(w io.Writer, tp ...core.DbType) error {
tables, err := engine.DBMetas()
if err != nil {
return err
}
return engine.DumpTables(tables, w, tp...)
}
// DumpTablesToFile dump specified tables to SQL file.
func (engine *Engine) DumpTablesToFile(tables []*core.Table, fp string, tp ...core.DbType) error {
f, err := os.Create(fp)
if err != nil {
return err
}
defer f.Close()
return engine.DumpTables(tables, f, tp...)
}
// DumpTables dump specify tables to io.Writer
func (engine *Engine) DumpTables(tables []*core.Table, w io.Writer, tp ...core.DbType) error {
return engine.dumpTables(tables, w, tp...)
}
// dumpTables dump database all table structs and data to w with specify db type
func (engine *Engine) dumpTables(tables []*core.Table, w io.Writer, tp ...core.DbType) error {
var dialect core.Dialect
var distDBName string
if len(tp) == 0 {
dialect = engine.dialect
distDBName = string(engine.dialect.DBType())
} else {
dialect = core.QueryDialect(tp[0])
if dialect == nil {
return errors.New("Unsupported database type")
}
dialect.Init(nil, engine.dialect.URI(), "", "")
distDBName = string(tp[0])
}
_, err := io.WriteString(w, fmt.Sprintf("/*Generated by xorm v%s %s, from %s to %s*/\n\n",
Version, time.Now().In(engine.TZLocation).Format("2006-01-02 15:04:05"), engine.dialect.DBType(), strings.ToUpper(distDBName)))
if err != nil {
return err
}
for i, table := range tables {
if i > 0 {
_, err = io.WriteString(w, "\n")
if err != nil {
return err
}
}
_, err = io.WriteString(w, dialect.CreateTableSql(table, "", table.StoreEngine, "")+";\n")
if err != nil {
return err
}
for _, index := range table.Indexes {
_, err = io.WriteString(w, dialect.CreateIndexSql(table.Name, index)+";\n")
if err != nil {
return err
}
}
cols := table.ColumnsSeq()
colNames := dialect.Quote(strings.Join(cols, dialect.Quote(", ")))
rows, err := engine.DB().Query("SELECT " + colNames + " FROM " + engine.Quote(table.Name))
if err != nil {
return err
}
defer rows.Close()
for rows.Next() {
dest := make([]interface{}, len(cols))
err = rows.ScanSlice(&dest)
if err != nil {
return err
}
_, err = io.WriteString(w, "INSERT INTO "+dialect.Quote(table.Name)+" ("+colNames+") VALUES (")
if err != nil {
return err
}
var temp string
for i, d := range dest {
col := table.GetColumn(cols[i])
if col == nil {
return errors.New("unknow column error")
}
if d == nil {
temp += ", NULL"
} else if col.SQLType.IsText() || col.SQLType.IsTime() {
var v = fmt.Sprintf("%s", d)
if strings.HasSuffix(v, " +0000 UTC") {
temp += fmt.Sprintf(", '%s'", v[0:len(v)-len(" +0000 UTC")])
} else {
temp += ", '" + strings.Replace(v, "'", "''", -1) + "'"
}
} else if col.SQLType.IsBlob() {
if reflect.TypeOf(d).Kind() == reflect.Slice {
temp += fmt.Sprintf(", %s", dialect.FormatBytes(d.([]byte)))
} else if reflect.TypeOf(d).Kind() == reflect.String {
temp += fmt.Sprintf(", '%s'", d.(string))
}
} else if col.SQLType.IsNumeric() {
switch reflect.TypeOf(d).Kind() {
case reflect.Slice:
temp += fmt.Sprintf(", %s", string(d.([]byte)))
case reflect.Int16, reflect.Int8, reflect.Int32, reflect.Int64, reflect.Int:
if col.SQLType.Name == core.Bool {
temp += fmt.Sprintf(", %v", strconv.FormatBool(reflect.ValueOf(d).Int() > 0))
} else {
temp += fmt.Sprintf(", %v", d)
}
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
if col.SQLType.Name == core.Bool {
temp += fmt.Sprintf(", %v", strconv.FormatBool(reflect.ValueOf(d).Uint() > 0))
} else {
temp += fmt.Sprintf(", %v", d)
}
default:
temp += fmt.Sprintf(", %v", d)
}
} else {
s := fmt.Sprintf("%v", d)
if strings.Contains(s, ":") || strings.Contains(s, "-") {
if strings.HasSuffix(s, " +0000 UTC") {
temp += fmt.Sprintf(", '%s'", s[0:len(s)-len(" +0000 UTC")])
} else {
temp += fmt.Sprintf(", '%s'", s)
}
} else {
temp += fmt.Sprintf(", %s", s)
}
}
}
_, err = io.WriteString(w, temp[2:]+");\n")
if err != nil {
return err
}
}
}
return nil
}
func (engine *Engine) tableName(beanOrTableName interface{}) (string, error) {
v := rValue(beanOrTableName)
if v.Type().Kind() == reflect.String {
return beanOrTableName.(string), nil
} else if v.Type().Kind() == reflect.Struct {
return engine.tbName(v), nil
}
return "", errors.New("bean should be a struct or struct's point")
}
func (engine *Engine) tbName(v reflect.Value) string {
if tb, ok := v.Interface().(TableName); ok {
return tb.TableName()
}
if v.Type().Kind() == reflect.Ptr {
if tb, ok := reflect.Indirect(v).Interface().(TableName); ok {
return tb.TableName()
}
} else if v.CanAddr() {
if tb, ok := v.Addr().Interface().(TableName); ok {
return tb.TableName()
}
}
return engine.TableMapper.Obj2Table(reflect.Indirect(v).Type().Name())
}
// Cascade use cascade or not
func (engine *Engine) Cascade(trueOrFalse ...bool) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Cascade(trueOrFalse...)
}
// Where method provide a condition query
func (engine *Engine) Where(query interface{}, args ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Where(query, args...)
}
// Id will be depracated, please use ID instead
func (engine *Engine) Id(id interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Id(id)
}
// ID method provoide a condition as (id) = ?
func (engine *Engine) ID(id interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.ID(id)
}
// Before apply before Processor, affected bean is passed to closure arg
func (engine *Engine) Before(closures func(interface{})) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Before(closures)
}
// After apply after insert Processor, affected bean is passed to closure arg
func (engine *Engine) After(closures func(interface{})) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.After(closures)
}
// Charset set charset when create table, only support mysql now
func (engine *Engine) Charset(charset string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Charset(charset)
}
// StoreEngine set store engine when create table, only support mysql now
func (engine *Engine) StoreEngine(storeEngine string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.StoreEngine(storeEngine)
}
// Distinct use for distinct columns. Caution: when you are using cache,
// distinct will not be cached because cache system need id,
// but distinct will not provide id
func (engine *Engine) Distinct(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Distinct(columns...)
}
// Select customerize your select columns or contents
func (engine *Engine) Select(str string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Select(str)
}
// Cols only use the parameters as select or update columns
func (engine *Engine) Cols(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Cols(columns...)
}
// AllCols indicates that all columns should be use
func (engine *Engine) AllCols() *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.AllCols()
}
// MustCols specify some columns must use even if they are empty
func (engine *Engine) MustCols(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.MustCols(columns...)
}
// UseBool xorm automatically retrieve condition according struct, but
// if struct has bool field, it will ignore them. So use UseBool
// to tell system to do not ignore them.
// If no parameters, it will use all the bool field of struct, or
// it will use parameters's columns
func (engine *Engine) UseBool(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.UseBool(columns...)
}
// Omit only not use the parameters as select or update columns
func (engine *Engine) Omit(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Omit(columns...)
}
// Nullable set null when column is zero-value and nullable for update
func (engine *Engine) Nullable(columns ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Nullable(columns...)
}
// In will generate "column IN (?, ?)"
func (engine *Engine) In(column string, args ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.In(column, args...)
}
// Incr provides a update string like "column = column + ?"
func (engine *Engine) Incr(column string, arg ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Incr(column, arg...)
}
// Decr provides a update string like "column = column - ?"
func (engine *Engine) Decr(column string, arg ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Decr(column, arg...)
}
// SetExpr provides a update string like "column = {expression}"
func (engine *Engine) SetExpr(column string, expression string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.SetExpr(column, expression)
}
// Table temporarily change the Get, Find, Update's table
func (engine *Engine) Table(tableNameOrBean interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Table(tableNameOrBean)
}
// Alias set the table alias
func (engine *Engine) Alias(alias string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Alias(alias)
}
// Limit will generate "LIMIT start, limit"
func (engine *Engine) Limit(limit int, start ...int) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Limit(limit, start...)
}
// Desc will generate "ORDER BY column1 DESC, column2 DESC"
func (engine *Engine) Desc(colNames ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Desc(colNames...)
}
// Asc will generate "ORDER BY column1,column2 Asc"
// This method can chainable use.
//
// engine.Desc("name").Asc("age").Find(&users)
// // SELECT * FROM user ORDER BY name DESC, age ASC
//
func (engine *Engine) Asc(colNames ...string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Asc(colNames...)
}
// OrderBy will generate "ORDER BY order"
func (engine *Engine) OrderBy(order string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.OrderBy(order)
}
// Join the join_operator should be one of INNER, LEFT OUTER, CROSS etc - this will be prepended to JOIN
func (engine *Engine) Join(joinOperator string, tablename interface{}, condition string, args ...interface{}) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Join(joinOperator, tablename, condition, args...)
}
// GroupBy generate group by statement
func (engine *Engine) GroupBy(keys string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.GroupBy(keys)
}
// Having generate having statement
func (engine *Engine) Having(conditions string) *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Having(conditions)
}
func (engine *Engine) autoMapType(v reflect.Value) *core.Table {
t := v.Type()
engine.mutex.Lock()
defer engine.mutex.Unlock()
table, ok := engine.Tables[t]
if !ok {
table = engine.mapType(v)
engine.Tables[t] = table
if engine.Cacher != nil {
if v.CanAddr() {
engine.GobRegister(v.Addr().Interface())
} else {
engine.GobRegister(v.Interface())
}
}
}
return table
}
// GobRegister register one struct to gob for cache use
func (engine *Engine) GobRegister(v interface{}) *Engine {
//fmt.Printf("Type: %[1]T => Data: %[1]#v\n", v)
gob.Register(v)
return engine
}
// Table table struct
type Table struct {
*core.Table
Name string
}
// TableInfo get table info according to bean's content
func (engine *Engine) TableInfo(bean interface{}) *Table {
v := rValue(bean)
return &Table{engine.autoMapType(v), engine.tbName(v)}
}
func addIndex(indexName string, table *core.Table, col *core.Column, indexType int) {
if index, ok := table.Indexes[indexName]; ok {
index.AddColumn(col.Name)
col.Indexes[index.Name] = indexType
} else {
index := core.NewIndex(indexName, indexType)
index.AddColumn(col.Name)
table.AddIndex(index)
col.Indexes[index.Name] = indexType
}
}
func (engine *Engine) newTable() *core.Table {
table := core.NewEmptyTable()
if !engine.disableGlobalCache {
table.Cacher = engine.Cacher
}
return table
}
// TableName table name interface to define customerize table name
type TableName interface {
TableName() string
}
var (
tpTableName = reflect.TypeOf((*TableName)(nil)).Elem()
)
func (engine *Engine) mapType(v reflect.Value) *core.Table {
t := v.Type()
table := engine.newTable()
if tb, ok := v.Interface().(TableName); ok {
table.Name = tb.TableName()
} else {
if v.CanAddr() {
if tb, ok = v.Addr().Interface().(TableName); ok {
table.Name = tb.TableName()
}
}
if table.Name == "" {
table.Name = engine.TableMapper.Obj2Table(t.Name())
}
}
table.Type = t
var idFieldColName string
var err error
var hasCacheTag, hasNoCacheTag bool
for i := 0; i < t.NumField(); i++ {
tag := t.Field(i).Tag
ormTagStr := tag.Get(engine.TagIdentifier)
var col *core.Column
fieldValue := v.Field(i)
fieldType := fieldValue.Type()
if ormTagStr != "" {
col = &core.Column{FieldName: t.Field(i).Name, Nullable: true, IsPrimaryKey: false,
IsAutoIncrement: false, MapType: core.TWOSIDES, Indexes: make(map[string]int)}
tags := splitTag(ormTagStr)
if len(tags) > 0 {
if tags[0] == "-" {
continue
}
if strings.ToUpper(tags[0]) == "EXTENDS" {
switch fieldValue.Kind() {
case reflect.Ptr:
f := fieldValue.Type().Elem()
if f.Kind() == reflect.Struct {
fieldPtr := fieldValue
fieldValue = fieldValue.Elem()
if !fieldValue.IsValid() || fieldPtr.IsNil() {
fieldValue = reflect.New(f).Elem()
}
}
fallthrough
case reflect.Struct:
parentTable := engine.mapType(fieldValue)
for _, col := range parentTable.Columns() {
col.FieldName = fmt.Sprintf("%v.%v", t.Field(i).Name, col.FieldName)
table.AddColumn(col)
for indexName, indexType := range col.Indexes {
addIndex(indexName, table, col, indexType)
}
}
continue
default:
//TODO: warning
}
}
indexNames := make(map[string]int)
var isIndex, isUnique bool
var preKey string
for j, key := range tags {
k := strings.ToUpper(key)
switch {
case k == "<-":
col.MapType = core.ONLYFROMDB
case k == "->":
col.MapType = core.ONLYTODB
case k == "PK":
col.IsPrimaryKey = true
col.Nullable = false
case k == "NULL":
if j == 0 {
col.Nullable = true
} else {
col.Nullable = (strings.ToUpper(tags[j-1]) != "NOT")
}
// TODO: for postgres how add autoincr?
/*case strings.HasPrefix(k, "AUTOINCR(") && strings.HasSuffix(k, ")"):
col.IsAutoIncrement = true
autoStart := k[len("AUTOINCR")+1 : len(k)-1]
autoStartInt, err := strconv.Atoi(autoStart)
if err != nil {
engine.LogError(err)
}
col.AutoIncrStart = autoStartInt*/
case k == "AUTOINCR":
col.IsAutoIncrement = true
//col.AutoIncrStart = 1
case k == "DEFAULT":
col.Default = tags[j+1]
case k == "CREATED":
col.IsCreated = true
case k == "VERSION":
col.IsVersion = true
col.Default = "1"
case k == "UTC":
col.TimeZone = time.UTC
case k == "LOCAL":
col.TimeZone = time.Local
case strings.HasPrefix(k, "LOCALE(") && strings.HasSuffix(k, ")"):
location := k[len("LOCALE")+1 : len(k)-1]
col.TimeZone, err = time.LoadLocation(location)
if err != nil {
engine.logger.Error(err)
}
case k == "UPDATED":
col.IsUpdated = true
case k == "DELETED":
col.IsDeleted = true
case strings.HasPrefix(k, "INDEX(") && strings.HasSuffix(k, ")"):
indexName := k[len("INDEX")+1 : len(k)-1]
indexNames[indexName] = core.IndexType
case k == "INDEX":
isIndex = true
case strings.HasPrefix(k, "UNIQUE(") && strings.HasSuffix(k, ")"):
indexName := k[len("UNIQUE")+1 : len(k)-1]
indexNames[indexName] = core.UniqueType
case k == "UNIQUE":
isUnique = true
case k == "NOTNULL":
col.Nullable = false
case k == "CACHE":
if !hasCacheTag {
hasCacheTag = true
}
case k == "NOCACHE":
if !hasNoCacheTag {
hasNoCacheTag = true
}
case k == "NOT":
default:
if strings.HasPrefix(k, "'") && strings.HasSuffix(k, "'") {
if preKey != "DEFAULT" {
col.Name = key[1 : len(key)-1]
}
} else if strings.Contains(k, "(") && strings.HasSuffix(k, ")") {
fs := strings.Split(k, "(")
if _, ok := core.SqlTypes[fs[0]]; !ok {
preKey = k
continue
}
col.SQLType = core.SQLType{Name: fs[0]}
if fs[0] == core.Enum && fs[1][0] == '\'' { //enum
options := strings.Split(fs[1][0:len(fs[1])-1], ",")
col.EnumOptions = make(map[string]int)
for k, v := range options {
v = strings.TrimSpace(v)
v = strings.Trim(v, "'")
col.EnumOptions[v] = k
}
} else if fs[0] == core.Set && fs[1][0] == '\'' { //set
options := strings.Split(fs[1][0:len(fs[1])-1], ",")
col.SetOptions = make(map[string]int)
for k, v := range options {
v = strings.TrimSpace(v)
v = strings.Trim(v, "'")
col.SetOptions[v] = k
}
} else {
fs2 := strings.Split(fs[1][0:len(fs[1])-1], ",")
if len(fs2) == 2 {
col.Length, err = strconv.Atoi(fs2[0])
if err != nil {
engine.logger.Error(err)
}
col.Length2, err = strconv.Atoi(fs2[1])
if err != nil {
engine.logger.Error(err)
}
} else if len(fs2) == 1 {
col.Length, err = strconv.Atoi(fs2[0])
if err != nil {
engine.logger.Error(err)
}
}
}
} else {
if _, ok := core.SqlTypes[k]; ok {
col.SQLType = core.SQLType{Name: k}
} else if key != col.Default {
col.Name = key
}
}
engine.dialect.SqlType(col)
}
preKey = k
}
if col.SQLType.Name == "" {
col.SQLType = core.Type2SQLType(fieldType)
}
if col.Length == 0 {
col.Length = col.SQLType.DefaultLength
}
if col.Length2 == 0 {
col.Length2 = col.SQLType.DefaultLength2
}
if col.Name == "" {
col.Name = engine.ColumnMapper.Obj2Table(t.Field(i).Name)
}
if isUnique {
indexNames[col.Name] = core.UniqueType
} else if isIndex {
indexNames[col.Name] = core.IndexType
}
for indexName, indexType := range indexNames {
addIndex(indexName, table, col, indexType)
}
}
} else {
var sqlType core.SQLType
if fieldValue.CanAddr() {
if _, ok := fieldValue.Addr().Interface().(core.Conversion); ok {
sqlType = core.SQLType{Name: core.Text}
}
}
if _, ok := fieldValue.Interface().(core.Conversion); ok {
sqlType = core.SQLType{Name: core.Text}
} else {
sqlType = core.Type2SQLType(fieldType)
}
col = core.NewColumn(engine.ColumnMapper.Obj2Table(t.Field(i).Name),
t.Field(i).Name, sqlType, sqlType.DefaultLength,
sqlType.DefaultLength2, true)
}
if col.IsAutoIncrement {
col.Nullable = false
}
table.AddColumn(col)
if fieldType.Kind() == reflect.Int64 && (strings.ToUpper(col.FieldName) == "ID" || strings.HasSuffix(strings.ToUpper(col.FieldName), ".ID")) {
idFieldColName = col.Name
}
} // end for
if idFieldColName != "" && len(table.PrimaryKeys) == 0 {
col := table.GetColumn(idFieldColName)
col.IsPrimaryKey = true
col.IsAutoIncrement = true
col.Nullable = false
table.PrimaryKeys = append(table.PrimaryKeys, col.Name)
table.AutoIncrement = col.Name
}
if hasCacheTag {
if engine.Cacher != nil { // !nash! use engine's cacher if provided
engine.logger.Info("enable cache on table:", table.Name)
table.Cacher = engine.Cacher
} else {
engine.logger.Info("enable LRU cache on table:", table.Name)
table.Cacher = NewLRUCacher2(NewMemoryStore(), time.Hour, 10000) // !nashtsai! HACK use LRU cacher for now
}
}
if hasNoCacheTag {
engine.logger.Info("no cache on table:", table.Name)
table.Cacher = nil
}
return table
}
// IsTableEmpty if a table has any reocrd
func (engine *Engine) IsTableEmpty(bean interface{}) (bool, error) {
session := engine.NewSession()
defer session.Close()
return session.IsTableEmpty(bean)
}
// IsTableExist if a table is exist
func (engine *Engine) IsTableExist(beanOrTableName interface{}) (bool, error) {
session := engine.NewSession()
defer session.Close()
return session.IsTableExist(beanOrTableName)
}
// IdOf get id from one struct
//
// Deprecated: use IDOf instead.
func (engine *Engine) IdOf(bean interface{}) core.PK {
return engine.IDOf(bean)
}
// IDOf get id from one struct
func (engine *Engine) IDOf(bean interface{}) core.PK {
return engine.IdOfV(reflect.ValueOf(bean))
}
// IdOfV get id from one value of struct
//
// Deprecated: use IDOfV instead.
func (engine *Engine) IdOfV(rv reflect.Value) core.PK {
return engine.IDOfV(rv)
}
// IDOfV get id from one value of struct
func (engine *Engine) IDOfV(rv reflect.Value) core.PK {
v := reflect.Indirect(rv)
table := engine.autoMapType(v)
pk := make([]interface{}, len(table.PrimaryKeys))
for i, col := range table.PKColumns() {
pkField := v.FieldByName(col.FieldName)
switch pkField.Kind() {
case reflect.String:
pk[i] = pkField.String()
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
pk[i] = pkField.Int()
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
pk[i] = pkField.Uint()
}
}
return core.PK(pk)
}
// CreateIndexes create indexes
func (engine *Engine) CreateIndexes(bean interface{}) error {
session := engine.NewSession()
defer session.Close()
return session.CreateIndexes(bean)
}
// CreateUniques create uniques
func (engine *Engine) CreateUniques(bean interface{}) error {
session := engine.NewSession()
defer session.Close()
return session.CreateUniques(bean)
}
func (engine *Engine) getCacher2(table *core.Table) core.Cacher {
return table.Cacher
}
func (engine *Engine) getCacher(v reflect.Value) core.Cacher {
if table := engine.autoMapType(v); table != nil {
return table.Cacher
}
return engine.Cacher
}
// ClearCacheBean if enabled cache, clear the cache bean
func (engine *Engine) ClearCacheBean(bean interface{}, id string) error {
v := rValue(bean)
t := v.Type()
if t.Kind() != reflect.Struct {
return errors.New("error params")
}
tableName := engine.tbName(v)
table := engine.autoMapType(v)
cacher := table.Cacher
if cacher == nil {
cacher = engine.Cacher
}
if cacher != nil {
cacher.ClearIds(tableName)
cacher.DelBean(tableName, id)
}
return nil
}
// ClearCache if enabled cache, clear some tables' cache
func (engine *Engine) ClearCache(beans ...interface{}) error {
for _, bean := range beans {
v := rValue(bean)
t := v.Type()
if t.Kind() != reflect.Struct {
return errors.New("error params")
}
tableName := engine.tbName(v)
table := engine.autoMapType(v)
cacher := table.Cacher
if cacher == nil {
cacher = engine.Cacher
}
if cacher != nil {
cacher.ClearIds(tableName)
cacher.ClearBeans(tableName)
}
}
return nil
}
// Sync the new struct changes to database, this method will automatically add
// table, column, index, unique. but will not delete or change anything.
// If you change some field, you should change the database manually.
func (engine *Engine) Sync(beans ...interface{}) error {
for _, bean := range beans {
v := rValue(bean)
tableName := engine.tbName(v)
table := engine.autoMapType(v)
s := engine.NewSession()
defer s.Close()
isExist, err := s.Table(bean).isTableExist(tableName)
if err != nil {
return err
}
if !isExist {
err = engine.CreateTables(bean)
if err != nil {
return err
}
}
/*isEmpty, err := engine.IsEmptyTable(bean)
if err != nil {
return err
}*/
var isEmpty bool
if isEmpty {
err = engine.DropTables(bean)
if err != nil {
return err
}
err = engine.CreateTables(bean)
if err != nil {
return err
}
} else {
for _, col := range table.Columns() {
isExist, err := engine.dialect.IsColumnExist(tableName, col.Name)
if err != nil {
return err
}
if !isExist {
session := engine.NewSession()
session.Statement.setRefValue(v)
defer session.Close()
err = session.addColumn(col.Name)
if err != nil {
return err
}
}
}
for name, index := range table.Indexes {
session := engine.NewSession()
session.Statement.setRefValue(v)
defer session.Close()
if index.Type == core.UniqueType {
//isExist, err := session.isIndexExist(table.Name, name, true)
isExist, err := session.isIndexExist2(tableName, index.Cols, true)
if err != nil {
return err
}
if !isExist {
session := engine.NewSession()
session.Statement.setRefValue(v)
defer session.Close()
err = session.addUnique(tableName, name)
if err != nil {
return err
}
}
} else if index.Type == core.IndexType {
isExist, err := session.isIndexExist2(tableName, index.Cols, false)
if err != nil {
return err
}
if !isExist {
session := engine.NewSession()
session.Statement.setRefValue(v)
defer session.Close()
err = session.addIndex(tableName, name)
if err != nil {
return err
}
}
} else {
return errors.New("unknow index type")
}
}
}
}
return nil
}
// Sync2 synchronize structs to database tables
func (engine *Engine) Sync2(beans ...interface{}) error {
s := engine.NewSession()
defer s.Close()
return s.Sync2(beans...)
}
func (engine *Engine) unMap(beans ...interface{}) (e error) {
engine.mutex.Lock()
defer engine.mutex.Unlock()
for _, bean := range beans {
t := rType(bean)
if _, ok := engine.Tables[t]; ok {
delete(engine.Tables, t)
}
}
return
}
// Drop all mapped table
func (engine *Engine) dropAll() error {
session := engine.NewSession()
defer session.Close()
err := session.Begin()
if err != nil {
return err
}
err = session.dropAll()
if err != nil {
session.Rollback()
return err
}
return session.Commit()
}
// CreateTables create tabls according bean
func (engine *Engine) CreateTables(beans ...interface{}) error {
session := engine.NewSession()
defer session.Close()
err := session.Begin()
if err != nil {
return err
}
for _, bean := range beans {
err = session.CreateTable(bean)
if err != nil {
session.Rollback()
return err
}
}
return session.Commit()
}
// DropTables drop specify tables
func (engine *Engine) DropTables(beans ...interface{}) error {
session := engine.NewSession()
defer session.Close()
err := session.Begin()
if err != nil {
return err
}
for _, bean := range beans {
err = session.DropTable(bean)
if err != nil {
session.Rollback()
return err
}
}
return session.Commit()
}
func (engine *Engine) createAll() error {
session := engine.NewSession()
defer session.Close()
return session.createAll()
}
// Exec raw sql
func (engine *Engine) Exec(sql string, args ...interface{}) (sql.Result, error) {
session := engine.NewSession()
defer session.Close()
return session.Exec(sql, args...)
}
// Query a raw sql and return records as []map[string][]byte
func (engine *Engine) Query(sql string, paramStr ...interface{}) (resultsSlice []map[string][]byte, err error) {
session := engine.NewSession()
defer session.Close()
return session.Query(sql, paramStr...)
}
// Insert one or more records
func (engine *Engine) Insert(beans ...interface{}) (int64, error) {
session := engine.NewSession()
defer session.Close()
return session.Insert(beans...)
}
// InsertOne insert only one record
func (engine *Engine) InsertOne(bean interface{}) (int64, error) {
session := engine.NewSession()
defer session.Close()
return session.InsertOne(bean)
}
// Update records, bean's non-empty fields are updated contents,
// condiBean' non-empty filds are conditions
// CAUTION:
// 1.bool will defaultly be updated content nor conditions
// You should call UseBool if you have bool to use.
// 2.float32 & float64 may be not inexact as conditions
func (engine *Engine) Update(bean interface{}, condiBeans ...interface{}) (int64, error) {
session := engine.NewSession()
defer session.Close()
return session.Update(bean, condiBeans...)
}
// Delete records, bean's non-empty fields are conditions
func (engine *Engine) Delete(bean interface{}) (int64, error) {
session := engine.NewSession()
defer session.Close()
return session.Delete(bean)
}
// Get retrieve one record from table, bean's non-empty fields
// are conditions
func (engine *Engine) Get(bean interface{}) (bool, error) {
session := engine.NewSession()
defer session.Close()
return session.Get(bean)
}
// Find retrieve records from table, condiBeans's non-empty fields
// are conditions. beans could be []Struct, []*Struct, map[int64]Struct
// map[int64]*Struct
func (engine *Engine) Find(beans interface{}, condiBeans ...interface{}) error {
session := engine.NewSession()
defer session.Close()
return session.Find(beans, condiBeans...)
}
// Iterate record by record handle records from table, bean's non-empty fields
// are conditions.
func (engine *Engine) Iterate(bean interface{}, fun IterFunc) error {
session := engine.NewSession()
defer session.Close()
return session.Iterate(bean, fun)
}
// Rows return sql.Rows compatible Rows obj, as a forward Iterator object for iterating record by record, bean's non-empty fields
// are conditions.
func (engine *Engine) Rows(bean interface{}) (*Rows, error) {
session := engine.NewSession()
return session.Rows(bean)
}
// Count counts the records. bean's non-empty fields are conditions.
func (engine *Engine) Count(bean interface{}) (int64, error) {
session := engine.NewSession()
defer session.Close()
return session.Count(bean)
}
// Sum sum the records by some column. bean's non-empty fields are conditions.
func (engine *Engine) Sum(bean interface{}, colName string) (float64, error) {
session := engine.NewSession()
defer session.Close()
return session.Sum(bean, colName)
}
// Sums sum the records by some columns. bean's non-empty fields are conditions.
func (engine *Engine) Sums(bean interface{}, colNames ...string) ([]float64, error) {
session := engine.NewSession()
defer session.Close()
return session.Sums(bean, colNames...)
}
// SumsInt like Sums but return slice of int64 instead of float64.
func (engine *Engine) SumsInt(bean interface{}, colNames ...string) ([]int64, error) {
session := engine.NewSession()
defer session.Close()
return session.SumsInt(bean, colNames...)
}
// ImportFile SQL DDL file
func (engine *Engine) ImportFile(ddlPath string) ([]sql.Result, error) {
file, err := os.Open(ddlPath)
if err != nil {
return nil, err
}
defer file.Close()
return engine.Import(file)
}
// Import SQL DDL from io.Reader
func (engine *Engine) Import(r io.Reader) ([]sql.Result, error) {
var results []sql.Result
var lastError error
scanner := bufio.NewScanner(r)
semiColSpliter := func(data []byte, atEOF bool) (advance int, token []byte, err error) {
if atEOF && len(data) == 0 {
return 0, nil, nil
}
if i := bytes.IndexByte(data, ';'); i >= 0 {
return i + 1, data[0:i], nil
}
// If we're at EOF, we have a final, non-terminated line. Return it.
if atEOF {
return len(data), data, nil
}
// Request more data.
return 0, nil, nil
}
scanner.Split(semiColSpliter)
for scanner.Scan() {
query := strings.Trim(scanner.Text(), " \t\n\r")
if len(query) > 0 {
engine.logSQL(query)
result, err := engine.DB().Exec(query)
results = append(results, result)
if err != nil {
return nil, err
//lastError = err
}
}
}
return results, lastError
}
// TZTime change one time to xorm time location
func (engine *Engine) TZTime(t time.Time) time.Time {
if !t.IsZero() { // if time is not initialized it's not suitable for Time.In()
return t.In(engine.TZLocation)
}
return t
}
// NowTime return current time
func (engine *Engine) NowTime(sqlTypeName string) interface{} {
t := time.Now()
return engine.FormatTime(sqlTypeName, t)
}
// NowTime2 return current time
func (engine *Engine) NowTime2(sqlTypeName string) (interface{}, time.Time) {
t := time.Now()
return engine.FormatTime(sqlTypeName, t), t
}
// FormatTime format time
func (engine *Engine) FormatTime(sqlTypeName string, t time.Time) (v interface{}) {
return engine.formatTime(engine.TZLocation, sqlTypeName, t)
}
func (engine *Engine) formatColTime(col *core.Column, t time.Time) (v interface{}) {
if col.DisableTimeZone {
return engine.formatTime(nil, col.SQLType.Name, t)
} else if col.TimeZone != nil {
return engine.formatTime(col.TimeZone, col.SQLType.Name, t)
}
return engine.formatTime(engine.TZLocation, col.SQLType.Name, t)
}
func (engine *Engine) formatTime(tz *time.Location, sqlTypeName string, t time.Time) (v interface{}) {
if engine.dialect.DBType() == core.ORACLE {
return t
}
if tz != nil {
t = t.In(tz)
} else {
t = engine.TZTime(t)
}
switch sqlTypeName {
case core.Time:
s := t.Format("2006-01-02 15:04:05") //time.RFC3339
v = s[11:19]
case core.Date:
v = t.Format("2006-01-02")
case core.DateTime, core.TimeStamp:
if engine.dialect.DBType() == "ql" {
v = t
} else if engine.dialect.DBType() == "sqlite3" {
v = t.UTC().Format("2006-01-02 15:04:05")
} else {
v = t.Format("2006-01-02 15:04:05")
}
case core.TimeStampz:
if engine.dialect.DBType() == core.MSSQL {
v = t.Format("2006-01-02T15:04:05.9999999Z07:00")
} else if engine.DriverName() == "mssql" {
v = t
} else {
v = t.Format(time.RFC3339Nano)
}
case core.BigInt, core.Int:
v = t.Unix()
default:
v = t
}
return
}
// Unscoped always disable struct tag "deleted"
func (engine *Engine) Unscoped() *Session {
session := engine.NewSession()
session.IsAutoClose = true
return session.Unscoped()
}