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refactor: db代码review

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This commit is contained in:
meilin.huang
2022-10-16 14:22:19 +08:00
parent c35e91b7b6
commit 6c197edddd
5 changed files with 733 additions and 120 deletions
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205
server/internal/db/application/db.go
View File

@@ -165,7 +165,7 @@ func (d *dbAppImpl) GetDatabases(ed *entity.Db) []string {
biz.ErrIsNilAppendErr(err, "数据库连接失败: %s") biz.ErrIsNilAppendErr(err, "数据库连接失败: %s")
defer dbConn.Close() defer dbConn.Close()
_, res, err := SelectDataByDb(dbConn, getDatabasesSql) _, res, err := SelectDataByDb(dbConn, getDatabasesSql, true)
biz.ErrIsNilAppendErr(err, "获取数据库列表失败") biz.ErrIsNilAppendErr(err, "获取数据库列表失败")
for _, re := range res { for _, re := range res {
databases = append(databases, re["dbname"].(string)) databases = append(databases, re["dbname"].(string))
@@ -218,6 +218,67 @@ func (da *dbAppImpl) GetDbInstance(id uint64, db string) *DbInstance {
return dbi return dbi
} }
//---------------------------------------- db instance ------------------------------------
// db实例
type DbInstance struct {
Id string
Type string
ProjectId uint64
db *sql.DB
sshTunnelMachineId uint64
}
// 执行查询语句
// 依次返回 列名数组结果map错误
func (d *DbInstance) SelectData(execSql string) ([]string, []map[string]interface{}, error) {
return SelectDataByDb(d.db, execSql, false)
}
// 将查询结果映射至struct可具体参考sqlx库
func (d *DbInstance) SelectData2Struct(execSql string, dest interface{}) error {
return Select2StructByDb(d.db, execSql, dest)
}
// 执行内部查询语句,不返回列名以及不限制行数
// 依次返回 结果map错误
func (d *DbInstance) innerSelect(execSql string) ([]map[string]interface{}, error) {
_, res, err := SelectDataByDb(d.db, execSql, true)
return res, err
}
// 执行 update, insert, delete建表等sql
// 返回影响条数和错误
func (d *DbInstance) Exec(sql string) (int64, error) {
res, err := d.db.Exec(sql)
if err != nil {
return 0, err
}
return res.RowsAffected()
}
// 获取数据库元信息实现接口
func (di *DbInstance) GetMeta() DbMetadata {
dbType := di.Type
if dbType == entity.DbTypeMysql {
return &MysqlMetadata{di: di}
}
if dbType == entity.DbTypePostgres {
return &PgsqlMetadata{di: di}
}
return nil
}
// 关闭连接
func (d *DbInstance) Close() {
if d.db != nil {
if err := d.db.Close(); err != nil {
global.Log.Errorf("关闭数据库实例[%s]连接失败: %s", d.Id, err.Error())
}
d.db = nil
}
}
//------------------------------------------------------------------------------ //------------------------------------------------------------------------------
// 单次最大查询数据集 // 单次最大查询数据集
@@ -292,7 +353,28 @@ func GetDbConn(d *entity.Db, db string) (*sql.DB, error) {
return DB, nil return DB, nil
} }
func SelectDataByDb(db *sql.DB, selectSql string) ([]string, []map[string]interface{}, error) { // 获取dataSourceName
func getDsn(d *entity.Db, db string) string {
var dsn string
if d.Type == entity.DbTypeMysql {
dsn = fmt.Sprintf("%s:%s@%s(%s:%d)/%s?timeout=8s", d.Username, d.Password, d.Network, d.Host, d.Port, db)
if d.Params != "" {
dsn = fmt.Sprintf("%s&%s", dsn, d.Params)
}
return dsn
}
if d.Type == entity.DbTypePostgres {
dsn = fmt.Sprintf("host=%s port=%d user=%s password=%s dbname=%s sslmode=disable", d.Host, d.Port, d.Username, d.Password, db)
if d.Params != "" {
dsn = fmt.Sprintf("%s %s", dsn, strings.Join(strings.Split(d.Params, "&"), " "))
}
return dsn
}
return ""
}
func SelectDataByDb(db *sql.DB, selectSql string, isInner bool) ([]string, []map[string]interface{}, error) {
rows, err := db.Query(selectSql) rows, err := db.Query(selectSql)
if err != nil { if err != nil {
return nil, nil, err return nil, nil, err
@@ -322,7 +404,10 @@ func SelectDataByDb(db *sql.DB, selectSql string) ([]string, []map[string]interf
rowNum := 0 rowNum := 0
for rows.Next() { for rows.Next() {
rowNum++ rowNum++
// 非内部sql则校验返回结果数量
if !isInner {
biz.IsTrue(rowNum <= Max_Rows, "结果集 > 2000, 请完善条件或分页信息") biz.IsTrue(rowNum <= Max_Rows, "结果集 > 2000, 请完善条件或分页信息")
}
// 不Scan也会导致等待该链接实际处于未工作的状态然后也会导致连接数迅速达到最大 // 不Scan也会导致等待该链接实际处于未工作的状态然后也会导致连接数迅速达到最大
err := rows.Scan(scans...) err := rows.Scan(scans...)
@@ -397,10 +482,11 @@ func valueConvert(data []byte, colType *sql.ColumnType) interface{} {
return stringV return stringV
} }
func innerSelectByDb(db *sql.DB, selectSql string) ([]map[string]interface{}, error) { // 查询数据结果映射至struct。可参考sqlx库
func Select2StructByDb(db *sql.DB, selectSql string, dest interface{}) error {
rows, err := db.Query(selectSql) rows, err := db.Query(selectSql)
if err != nil { if err != nil {
return nil, err return err
} }
// rows对象一定要close掉如果出错不关掉则会很迅速的达到设置最大连接数 // rows对象一定要close掉如果出错不关掉则会很迅速的达到设置最大连接数
// 后面的链接过来直接报错或拒绝,实际上也没有起效果 // 后面的链接过来直接报错或拒绝,实际上也没有起效果
@@ -409,35 +495,12 @@ func innerSelectByDb(db *sql.DB, selectSql string) ([]map[string]interface{}, er
rows.Close() rows.Close()
} }
}() }()
colTypes, _ := rows.ColumnTypes() return scanAll(rows, dest, false)
// 这里表示一行填充数据
scans := make([]interface{}, len(colTypes))
// 这里表示一行所有列的值,用[]byte表示
vals := make([][]byte, len(colTypes))
// 这里scans引用vals把数据填充到[]byte里
for k := range vals {
scans[k] = &vals[k]
} }
result := make([]map[string]interface{}, 0) // 删除db缓存并关闭该数据库所有连接
for rows.Next() { func CloseDb(dbId uint64, db string) {
// 不Scan也会导致等待该链接实际处于未工作的状态然后也会导致连接数迅速达到最大 dbCache.Delete(GetDbCacheKey(dbId, db))
err := rows.Scan(scans...)
if err != nil {
return nil, err
}
// 每行数据
rowData := make(map[string]interface{})
// 把vals中的数据复制到row中
for i, v := range vals {
colType := colTypes[i]
colName := colType.Name()
rowData[colName] = valueConvert(v, colType)
}
// 放入结果集
result = append(result, rowData)
}
return result, nil
} }
type PqSqlDialer struct { type PqSqlDialer struct {
@@ -452,85 +515,7 @@ func (pd *PqSqlDialer) Dial(network, address string) (net.Conn, error) {
return nil, err return nil, err
} }
} }
func (pd *PqSqlDialer) DialTimeout(network, address string, timeout time.Duration) (net.Conn, error) { func (pd *PqSqlDialer) DialTimeout(network, address string, timeout time.Duration) (net.Conn, error) {
return pd.Dial(network, address) return pd.Dial(network, address)
} }
// db实例
type DbInstance struct {
Id string
Type string
ProjectId uint64
db *sql.DB
sshTunnelMachineId uint64
}
// 执行查询语句
// 依次返回 列名数组结果map错误
func (d *DbInstance) SelectData(execSql string) ([]string, []map[string]interface{}, error) {
return SelectDataByDb(d.db, execSql)
}
// 执行内部查询语句,不返回列名以及不限制行数
// 依次返回 结果map错误
func (d *DbInstance) innerSelect(execSql string) ([]map[string]interface{}, error) {
return innerSelectByDb(d.db, execSql)
}
// 执行 update, insert, delete建表等sql
// 返回影响条数和错误
func (d *DbInstance) Exec(sql string) (int64, error) {
res, err := d.db.Exec(sql)
if err != nil {
return 0, err
}
return res.RowsAffected()
}
// 获取数据库元信息实现接口
func (di *DbInstance) GetMeta() DbMetadata {
dbType := di.Type
if dbType == entity.DbTypeMysql {
return &MysqlMetadata{di: di}
}
if dbType == entity.DbTypePostgres {
return &PgsqlMetadata{di: di}
}
return nil
}
// 关闭连接
func (d *DbInstance) Close() {
if d.db != nil {
if err := d.db.Close(); err != nil {
global.Log.Errorf("关闭数据库实例[%s]连接失败: %s", d.Id, err.Error())
}
d.db = nil
}
}
// 获取dataSourceName
func getDsn(d *entity.Db, db string) string {
var dsn string
if d.Type == entity.DbTypeMysql {
dsn = fmt.Sprintf("%s:%s@%s(%s:%d)/%s?timeout=8s", d.Username, d.Password, d.Network, d.Host, d.Port, db)
if d.Params != "" {
dsn = fmt.Sprintf("%s&%s", dsn, d.Params)
}
return dsn
}
if d.Type == entity.DbTypePostgres {
dsn = fmt.Sprintf("host=%s port=%d user=%s password=%s dbname=%s sslmode=disable", d.Host, d.Port, d.Username, d.Password, db)
if d.Params != "" {
dsn = fmt.Sprintf("%s %s", dsn, strings.Join(strings.Split(d.Params, "&"), " "))
}
return dsn
}
return ""
}
// 删除db缓存并关闭该数据库所有连接
func CloseDb(dbId uint64, db string) {
dbCache.Delete(GetDbCacheKey(dbId, db))
}

9
server/internal/db/application/meta.go
View File

@@ -1,9 +1,11 @@
package application package application
// -----------------------------------元数据------------------------------------------- // -----------------------------------元数据接口定义------------------------------------------
// 数据库元信息接口(表、列等元信息) // 数据库元信息接口(表、列等元信息)
// 所有数据查出来直接用map接收注意map的key需要统一 // 所有数据查出来直接用map接收注意不同数据库实现该接口返回的map的key需要统一.
// 即: 使用别名统一即可。如table_name AS tableName
type DbMetadata interface { type DbMetadata interface {
// 获取表基础元信息 // 获取表基础元信息
// 表名: tableName, 备注: tableComment // 表名: tableName, 备注: tableComment
GetTables() []map[string]interface{} GetTables() []map[string]interface{}
@@ -24,6 +26,3 @@ type DbMetadata interface {
// 获取建表ddl // 获取建表ddl
GetCreateTableDdl(tableName string) []map[string]interface{} GetCreateTableDdl(tableName string) []map[string]interface{}
} }
// 默认每次查询列元信息数量
const DEFAULT_COLUMN_SIZE = 2000

4
server/internal/db/application/mysql_meta.go
View File

@@ -8,9 +8,7 @@ import (
// ---------------------------------- mysql元数据 ----------------------------------- // ---------------------------------- mysql元数据 -----------------------------------
const ( const (
// mysql 表信息元数据 // mysql 表信息元数据
MYSQL_TABLE_MA = `SELECT table_name tableName, engine, table_comment tableComment, MYSQL_TABLE_MA = `SELECT table_name tableName, table_comment tableComment from information_schema.tables WHERE table_schema = (SELECT database())`
create_time createTime from information_schema.tables
WHERE table_schema = (SELECT database())`
// mysql 表信息 // mysql 表信息
MYSQL_TABLE_INFO = `SELECT table_name tableName, table_comment tableComment, table_rows tableRows, MYSQL_TABLE_INFO = `SELECT table_name tableName, table_comment tableComment, table_rows tableRows,

1
server/internal/db/application/pgsql_meta.go
View File

@@ -88,5 +88,6 @@ func (pm *PgsqlMetadata) GetTableIndex(tableName string) []map[string]interface{
// 获取建表ddl // 获取建表ddl
func (mm *PgsqlMetadata) GetCreateTableDdl(tableName string) []map[string]interface{} { func (mm *PgsqlMetadata) GetCreateTableDdl(tableName string) []map[string]interface{} {
biz.IsTrue(tableName == "", "暂不支持获取pgsql建表DDL")
return nil return nil
} }

630
server/internal/db/application/sqlx.go Normal file
View File

@@ -0,0 +1,630 @@
package application
import (
"database/sql"
"errors"
"fmt"
"reflect"
"runtime"
"strings"
"sync"
)
// 将结果scan至结构体copy至 sqlx库: https://github.com/jmoiron/sqlx
func scanAll(rows *sql.Rows, dest interface{}, structOnly bool) error {
var v, vp reflect.Value
value := reflect.ValueOf(dest)
// json.Unmarshal returns errors for these
if value.Kind() != reflect.Ptr {
return errors.New("must pass a pointer, not a value, to StructScan destination")
}
if value.IsNil() {
return errors.New("nil pointer passed to StructScan destination")
}
direct := reflect.Indirect(value)
slice, err := baseType(value.Type(), reflect.Slice)
if err != nil {
return err
}
direct.SetLen(0)
isPtr := slice.Elem().Kind() == reflect.Ptr
base := Deref(slice.Elem())
scannable := isScannable(base)
if structOnly && scannable {
return structOnlyError(base)
}
columns, err := rows.Columns()
if err != nil {
return err
}
// if it's a base type make sure it only has 1 column; if not return an error
if scannable && len(columns) > 1 {
return fmt.Errorf("non-struct dest type %s with >1 columns (%d)", base.Kind(), len(columns))
}
if !scannable {
var values []interface{}
var m *Mapper = mapper()
fields := m.TraversalsByName(base, columns)
// if we are not unsafe and are missing fields, return an error
if f, err := missingFields(fields); err != nil {
return fmt.Errorf("missing destination name %s in %T", columns[f], dest)
}
values = make([]interface{}, len(columns))
for rows.Next() {
// create a new struct type (which returns PtrTo) and indirect it
vp = reflect.New(base)
v = reflect.Indirect(vp)
err = fieldsByTraversal(v, fields, values, true)
if err != nil {
return err
}
// scan into the struct field pointers and append to our results
err = rows.Scan(values...)
if err != nil {
return err
}
if isPtr {
direct.Set(reflect.Append(direct, vp))
} else {
direct.Set(reflect.Append(direct, v))
}
}
} else {
for rows.Next() {
vp = reflect.New(base)
err = rows.Scan(vp.Interface())
if err != nil {
return err
}
// append
if isPtr {
direct.Set(reflect.Append(direct, vp))
} else {
direct.Set(reflect.Append(direct, reflect.Indirect(vp)))
}
}
}
return rows.Err()
}
func baseType(t reflect.Type, expected reflect.Kind) (reflect.Type, error) {
t = Deref(t)
if t.Kind() != expected {
return nil, fmt.Errorf("expected %s but got %s", expected, t.Kind())
}
return t, nil
}
// structOnlyError returns an error appropriate for type when a non-scannable
// struct is expected but something else is given
func structOnlyError(t reflect.Type) error {
isStruct := t.Kind() == reflect.Struct
isScanner := reflect.PtrTo(t).Implements(_scannerInterface)
if !isStruct {
return fmt.Errorf("expected %s but got %s", reflect.Struct, t.Kind())
}
if isScanner {
return fmt.Errorf("structscan expects a struct dest but the provided struct type %s implements scanner", t.Name())
}
return fmt.Errorf("expected a struct, but struct %s has no exported fields", t.Name())
}
var _scannerInterface = reflect.TypeOf((*sql.Scanner)(nil)).Elem()
func isScannable(t reflect.Type) bool {
if reflect.PtrTo(t).Implements(_scannerInterface) {
return true
}
if t.Kind() != reflect.Struct {
return true
}
// it's not important that we use the right mapper for this particular object,
// we're only concerned on how many exported fields this struct has
return len(mapper().TypeMap(t).Index) == 0
}
var NameMapper = strings.ToLower
var origMapper = reflect.ValueOf(NameMapper)
// Rather than creating on init, this is created when necessary so that
// importers have time to customize the NameMapper.
var mpr *Mapper
// mprMu protects mpr.
var mprMu sync.Mutex
// mapper returns a valid mapper using the configured NameMapper func.
func mapper() *Mapper {
mprMu.Lock()
defer mprMu.Unlock()
if mpr == nil {
mpr = NewMapperFunc("db", NameMapper)
} else if origMapper != reflect.ValueOf(NameMapper) {
// if NameMapper has changed, create a new mapper
mpr = NewMapperFunc("db", NameMapper)
origMapper = reflect.ValueOf(NameMapper)
}
return mpr
}
func missingFields(transversals [][]int) (field int, err error) {
for i, t := range transversals {
if len(t) == 0 {
return i, errors.New("missing field")
}
}
return 0, nil
}
// fieldsByName fills a values interface with fields from the passed value based
// on the traversals in int. If ptrs is true, return addresses instead of values.
// We write this instead of using FieldsByName to save allocations and map lookups
// when iterating over many rows. Empty traversals will get an interface pointer.
// Because of the necessity of requesting ptrs or values, it's considered a bit too
// specialized for inclusion in reflectx itself.
func fieldsByTraversal(v reflect.Value, traversals [][]int, values []interface{}, ptrs bool) error {
v = reflect.Indirect(v)
if v.Kind() != reflect.Struct {
return errors.New("argument not a struct")
}
for i, traversal := range traversals {
if len(traversal) == 0 {
values[i] = new(interface{})
continue
}
f := FieldByIndexes(v, traversal)
if ptrs {
values[i] = f.Addr().Interface()
} else {
values[i] = f.Interface()
}
}
return nil
}
// A FieldInfo is metadata for a struct field.
type FieldInfo struct {
Index []int
Path string
Field reflect.StructField
Zero reflect.Value
Name string
Options map[string]string
Embedded bool
Children []*FieldInfo
Parent *FieldInfo
}
// A StructMap is an index of field metadata for a struct.
type StructMap struct {
Tree *FieldInfo
Index []*FieldInfo
Paths map[string]*FieldInfo
Names map[string]*FieldInfo
}
// GetByPath returns a *FieldInfo for a given string path.
func (f StructMap) GetByPath(path string) *FieldInfo {
return f.Paths[path]
}
// GetByTraversal returns a *FieldInfo for a given integer path. It is
// analogous to reflect.FieldByIndex, but using the cached traversal
// rather than re-executing the reflect machinery each time.
func (f StructMap) GetByTraversal(index []int) *FieldInfo {
if len(index) == 0 {
return nil
}
tree := f.Tree
for _, i := range index {
if i >= len(tree.Children) || tree.Children[i] == nil {
return nil
}
tree = tree.Children[i]
}
return tree
}
// Mapper is a general purpose mapper of names to struct fields. A Mapper
// behaves like most marshallers in the standard library, obeying a field tag
// for name mapping but also providing a basic transform function.
type Mapper struct {
cache map[reflect.Type]*StructMap
tagName string
tagMapFunc func(string) string
mapFunc func(string) string
mutex sync.Mutex
}
// NewMapper returns a new mapper using the tagName as its struct field tag.
// If tagName is the empty string, it is ignored.
func NewMapper(tagName string) *Mapper {
return &Mapper{
cache: make(map[reflect.Type]*StructMap),
tagName: tagName,
}
}
// NewMapperTagFunc returns a new mapper which contains a mapper for field names
// AND a mapper for tag values. This is useful for tags like json which can
// have values like "name,omitempty".
func NewMapperTagFunc(tagName string, mapFunc, tagMapFunc func(string) string) *Mapper {
return &Mapper{
cache: make(map[reflect.Type]*StructMap),
tagName: tagName,
mapFunc: mapFunc,
tagMapFunc: tagMapFunc,
}
}
// NewMapperFunc returns a new mapper which optionally obeys a field tag and
// a struct field name mapper func given by f. Tags will take precedence, but
// for any other field, the mapped name will be f(field.Name)
func NewMapperFunc(tagName string, f func(string) string) *Mapper {
return &Mapper{
cache: make(map[reflect.Type]*StructMap),
tagName: tagName,
mapFunc: f,
}
}
// TypeMap returns a mapping of field strings to int slices representing
// the traversal down the struct to reach the field.
func (m *Mapper) TypeMap(t reflect.Type) *StructMap {
m.mutex.Lock()
mapping, ok := m.cache[t]
if !ok {
mapping = getMapping(t, m.tagName, m.mapFunc, m.tagMapFunc)
m.cache[t] = mapping
}
m.mutex.Unlock()
return mapping
}
// FieldMap returns the mapper's mapping of field names to reflect values. Panics
// if v's Kind is not Struct, or v is not Indirectable to a struct kind.
func (m *Mapper) FieldMap(v reflect.Value) map[string]reflect.Value {
v = reflect.Indirect(v)
mustBe(v, reflect.Struct)
r := map[string]reflect.Value{}
tm := m.TypeMap(v.Type())
for tagName, fi := range tm.Names {
r[tagName] = FieldByIndexes(v, fi.Index)
}
return r
}
// FieldByName returns a field by its mapped name as a reflect.Value.
// Panics if v's Kind is not Struct or v is not Indirectable to a struct Kind.
// Returns zero Value if the name is not found.
func (m *Mapper) FieldByName(v reflect.Value, name string) reflect.Value {
v = reflect.Indirect(v)
mustBe(v, reflect.Struct)
tm := m.TypeMap(v.Type())
fi, ok := tm.Names[name]
if !ok {
return v
}
return FieldByIndexes(v, fi.Index)
}
// FieldsByName returns a slice of values corresponding to the slice of names
// for the value. Panics if v's Kind is not Struct or v is not Indirectable
// to a struct Kind. Returns zero Value for each name not found.
func (m *Mapper) FieldsByName(v reflect.Value, names []string) []reflect.Value {
v = reflect.Indirect(v)
mustBe(v, reflect.Struct)
tm := m.TypeMap(v.Type())
vals := make([]reflect.Value, 0, len(names))
for _, name := range names {
fi, ok := tm.Names[name]
if !ok {
vals = append(vals, *new(reflect.Value))
} else {
vals = append(vals, FieldByIndexes(v, fi.Index))
}
}
return vals
}
// TraversalsByName returns a slice of int slices which represent the struct
// traversals for each mapped name. Panics if t is not a struct or Indirectable
// to a struct. Returns empty int slice for each name not found.
func (m *Mapper) TraversalsByName(t reflect.Type, names []string) [][]int {
r := make([][]int, 0, len(names))
m.TraversalsByNameFunc(t, names, func(_ int, i []int) error {
if i == nil {
r = append(r, []int{})
} else {
r = append(r, i)
}
return nil
})
return r
}
// TraversalsByNameFunc traverses the mapped names and calls fn with the index of
// each name and the struct traversal represented by that name. Panics if t is not
// a struct or Indirectable to a struct. Returns the first error returned by fn or nil.
func (m *Mapper) TraversalsByNameFunc(t reflect.Type, names []string, fn func(int, []int) error) error {
t = Deref(t)
mustBe(t, reflect.Struct)
tm := m.TypeMap(t)
for i, name := range names {
fi, ok := tm.Names[name]
if !ok {
if err := fn(i, nil); err != nil {
return err
}
} else {
if err := fn(i, fi.Index); err != nil {
return err
}
}
}
return nil
}
// FieldByIndexes returns a value for the field given by the struct traversal
// for the given value.
func FieldByIndexes(v reflect.Value, indexes []int) reflect.Value {
for _, i := range indexes {
v = reflect.Indirect(v).Field(i)
// if this is a pointer and it's nil, allocate a new value and set it
if v.Kind() == reflect.Ptr && v.IsNil() {
alloc := reflect.New(Deref(v.Type()))
v.Set(alloc)
}
if v.Kind() == reflect.Map && v.IsNil() {
v.Set(reflect.MakeMap(v.Type()))
}
}
return v
}
// FieldByIndexesReadOnly returns a value for a particular struct traversal,
// but is not concerned with allocating nil pointers because the value is
// going to be used for reading and not setting.
func FieldByIndexesReadOnly(v reflect.Value, indexes []int) reflect.Value {
for _, i := range indexes {
v = reflect.Indirect(v).Field(i)
}
return v
}
// Deref is Indirect for reflect.Types
func Deref(t reflect.Type) reflect.Type {
if t.Kind() == reflect.Ptr {
t = t.Elem()
}
return t
}
// -- helpers & utilities --
type kinder interface {
Kind() reflect.Kind
}
// mustBe checks a value against a kind, panicing with a reflect.ValueError
// if the kind isn't that which is required.
func mustBe(v kinder, expected reflect.Kind) {
if k := v.Kind(); k != expected {
panic(&reflect.ValueError{Method: methodName(), Kind: k})
}
}
// methodName returns the caller of the function calling methodName
func methodName() string {
pc, _, _, _ := runtime.Caller(2)
f := runtime.FuncForPC(pc)
if f == nil {
return "unknown method"
}
return f.Name()
}
type typeQueue struct {
t reflect.Type
fi *FieldInfo
pp string // Parent path
}
// A copying append that creates a new slice each time.
func apnd(is []int, i int) []int {
x := make([]int, len(is)+1)
copy(x, is)
x[len(x)-1] = i
return x
}
type mapf func(string) string
// parseName parses the tag and the target name for the given field using
// the tagName (eg 'json' for `json:"foo"` tags), mapFunc for mapping the
// field's name to a target name, and tagMapFunc for mapping the tag to
// a target name.
func parseName(field reflect.StructField, tagName string, mapFunc, tagMapFunc mapf) (tag, fieldName string) {
// first, set the fieldName to the field's name
fieldName = field.Name
// if a mapFunc is set, use that to override the fieldName
if mapFunc != nil {
fieldName = mapFunc(fieldName)
}
// if there's no tag to look for, return the field name
if tagName == "" {
return "", fieldName
}
// if this tag is not set using the normal convention in the tag,
// then return the fieldname.. this check is done because according
// to the reflect documentation:
// If the tag does not have the conventional format,
// the value returned by Get is unspecified.
// which doesn't sound great.
if !strings.Contains(string(field.Tag), tagName+":") {
return "", fieldName
}
// at this point we're fairly sure that we have a tag, so lets pull it out
tag = field.Tag.Get(tagName)
// if we have a mapper function, call it on the whole tag
// XXX: this is a change from the old version, which pulled out the name
// before the tagMapFunc could be run, but I think this is the right way
if tagMapFunc != nil {
tag = tagMapFunc(tag)
}
// finally, split the options from the name
parts := strings.Split(tag, ",")
fieldName = parts[0]
return tag, fieldName
}
// parseOptions parses options out of a tag string, skipping the name
func parseOptions(tag string) map[string]string {
parts := strings.Split(tag, ",")
options := make(map[string]string, len(parts))
if len(parts) > 1 {
for _, opt := range parts[1:] {
// short circuit potentially expensive split op
if strings.Contains(opt, "=") {
kv := strings.Split(opt, "=")
options[kv[0]] = kv[1]
continue
}
options[opt] = ""
}
}
return options
}
// getMapping returns a mapping for the t type, using the tagName, mapFunc and
// tagMapFunc to determine the canonical names of fields.
func getMapping(t reflect.Type, tagName string, mapFunc, tagMapFunc mapf) *StructMap {
m := []*FieldInfo{}
root := &FieldInfo{}
queue := []typeQueue{}
queue = append(queue, typeQueue{Deref(t), root, ""})
QueueLoop:
for len(queue) != 0 {
// pop the first item off of the queue
tq := queue[0]
queue = queue[1:]
// ignore recursive field
for p := tq.fi.Parent; p != nil; p = p.Parent {
if tq.fi.Field.Type == p.Field.Type {
continue QueueLoop
}
}
nChildren := 0
if tq.t.Kind() == reflect.Struct {
nChildren = tq.t.NumField()
}
tq.fi.Children = make([]*FieldInfo, nChildren)
// iterate through all of its fields
for fieldPos := 0; fieldPos < nChildren; fieldPos++ {
f := tq.t.Field(fieldPos)
// parse the tag and the target name using the mapping options for this field
tag, name := parseName(f, tagName, mapFunc, tagMapFunc)
// if the name is "-", disabled via a tag, skip it
if name == "-" {
continue
}
fi := FieldInfo{
Field: f,
Name: name,
Zero: reflect.New(f.Type).Elem(),
Options: parseOptions(tag),
}
// if the path is empty this path is just the name
if tq.pp == "" {
fi.Path = fi.Name
} else {
fi.Path = tq.pp + "." + fi.Name
}
// skip unexported fields
if len(f.PkgPath) != 0 && !f.Anonymous {
continue
}
// bfs search of anonymous embedded structs
if f.Anonymous {
pp := tq.pp
if tag != "" {
pp = fi.Path
}
fi.Embedded = true
fi.Index = apnd(tq.fi.Index, fieldPos)
nChildren := 0
ft := Deref(f.Type)
if ft.Kind() == reflect.Struct {
nChildren = ft.NumField()
}
fi.Children = make([]*FieldInfo, nChildren)
queue = append(queue, typeQueue{Deref(f.Type), &fi, pp})
} else if fi.Zero.Kind() == reflect.Struct || (fi.Zero.Kind() == reflect.Ptr && fi.Zero.Type().Elem().Kind() == reflect.Struct) {
fi.Index = apnd(tq.fi.Index, fieldPos)
fi.Children = make([]*FieldInfo, Deref(f.Type).NumField())
queue = append(queue, typeQueue{Deref(f.Type), &fi, fi.Path})
}
fi.Index = apnd(tq.fi.Index, fieldPos)
fi.Parent = tq.fi
tq.fi.Children[fieldPos] = &fi
m = append(m, &fi)
}
}
flds := &StructMap{Index: m, Tree: root, Paths: map[string]*FieldInfo{}, Names: map[string]*FieldInfo{}}
for _, fi := range flds.Index {
// check if nothing has already been pushed with the same path
// sometimes you can choose to override a type using embedded struct
fld, ok := flds.Paths[fi.Path]
if !ok || fld.Embedded {
flds.Paths[fi.Path] = fi
if fi.Name != "" && !fi.Embedded {
flds.Names[fi.Path] = fi
}
}
}
return flds
}