This package is deprecated. Use the excellent sqlc package instead.
Package sqlr is designed to reduce the effort required to work with SQL databases. It is intended for programmers who are comfortable with writing SQL, but would like assistance with the sometimes tedious process of preparing SQL queries for tables that have a large number of columns, or have a variable number of input parameters.
This package is designed to work seamlessly with the standard library "database/sql" package. It does not provide any layer on top of *sql.DB or *sql.Tx. If the calling program has a need to execute queries independently of this package, it can use "database/sql" directly, or make use of any other third party package that uses "database/sql".
This README provides an overview of how to use this package. For more detailed documentation, see https://jjeffery.github.io/sqlr, or consult the GoDoc documentation.
- Obtaining the package
- Prepare SQL queries based on row structures
- Autoincrement Column Values
- Null Columns
- JSON Columns
- WHERE IN Clauses with Multiple Values
- Type-Safe Query Functions
- Performance and Caching
go get github.com/jjeffery/sqlrNote that if you are interested in running the tests, you will need to get additional database driver packages and setup a test database. See the detailed documentation for more information.
Preparing SQL queries with many placeholder arguments is tedious and error-prone. The following insert query has a dozen placeholders, and it is difficult to match up the columns with the placeholders. It is not uncommon to have tables with many more columns than this example, and the level of difficulty increases with the number of columns in the table.
insert into users(id,given_name,family_name,dob,ssn,street,locality,postcode,country,phone,mobile,fax)
values(?,?,?,?,?,?,?,?,?,?,?,?)This package uses reflection to simplify the construction of SQL queries. Supplementary information about each database column is stored in the structure tag of the associated field.
type User struct {
ID int `sql:"primary key"`
GivenName string
FamilyName string
DOB time.Time
SSN string
Street string
Locality string
Postcode string
Country string
Phone string
Mobile string
Facsimile string `sql:"fax"` // "fax" overrides the column name
}The calling program creates a schema, which describes rules for generating SQL statements. These rules include specifying the SQL dialect (eg MySQL, Postgres, SQLite) and the naming convention used to convert Go struct field names into column names (eg "GivenName" => "given_name"). The schema is usually created during program initialization. Once created, a schema is immutable and can be called concurrently from multiple goroutines.
schema := NewSchema(
WithDialect(MySQL),
WithNamingConvention(SnakeCase),
)A session is created using a context, a database connection (eg *sql.DB, *sql.Tx, *sql.Conn),
and a schema. A session is inexpensive to create, and is intended to last no longer than a single
request (which might be a HTTP request, in the case of a HTTP server). A session is bounded by the
lifetime of its context. The most common pattern is to create a new session for each database transaction.
sess := NewSession(ctx, tx, schema)With a session, it is possible to create simple CRUD statements with minimal effort.
var row User
// ... populate row with data here and then ...
// generates the correct SQL to insert a row into the users table
result, err := sess.InsertRow(row)
// ... and then later on ...
// generates the correct SQL to update a the matching row in the users table
result, err := sess.UpdateRow(row)In the example above, the generated insert and update statements would look like:
insert into users(`id`,`given_name`,`family_name`,`dob`,`ssn`,`street`,`locality`,`postcode`,
`country`,`phone`,`mobile`,`fax`) values(?,?,?,?,?,?,?,?,?,?,?,?)
update users set `given_name`=?,`family_name`=?,`dob`=?,`ssn`=?,`street`=?,`locality`=?,
`postcode`=?,`country`=?,`phone`=?,`mobile`=?,`fax`=? where `id`=?If the schema is created with a different dialect then the generated SQL will be different. For example if the Postgres dialect was used the insert and update queries would look more like:
insert into users("id","given_name","family_name","dob","ssn","street","locality","postcode",
"country","phone","mobile","fax") values($1,$2,$3,$4,$5,$6,$7,$8,$9,$10,$11,$12)
update users set "given_name"=$1,"family_name"=$2,"dob"=$3,"ssn"=$4,"street"=$5,"locality"=$6,
"postcode"=$7,"country"=$8,"phone"=$9,"mobile"=$10,"fax"=$11 where "id"=$12More complex update queries are handled by the Session.Exec method.
Select queries are handled by the Session.Select method:
var rows []*User
// will populate rows slice with the results of the query
rowCount, err := sess.Select(&rows, "select {} from users where postcode = ?", postcode)
var row User
// will populate row with the first row returned by the query
rowCount, err = sess.Select(&row, "select {} from users where {}", userID)
// more complex query involving joins and aliases
rowCount, err = sess.Select(&rows, `
select {alias u}
from users u
inner join user_search_terms ust on ust.user_id = u.id
where ust.search_term like ?
order by {alias u}`, searchTermText)The SQL queries prepared in the above example would look like the following:
select `id`,`given_name`,`family_name`,`dob`,`ssn`,`street`,`locality`,`postcode`,
`country`,`phone`,`mobile`,`fax` from users where postcode=?
select `id`,`given_name`,`family_name`,`dob`,`ssn`,`street`,`locality`,`postcode`,`country`,
`phone`,`mobile`,`fax` from users where id=?
select u.`id`,u.`given_name`,u.`family_name`,u.`dob`,u.`ssn`,u.`street`,u.`locality`,
u.`postcode`,u.`country`,u.`phone`,u.`mobile`,u.`fax` from users u inner join
user_search_terms ust on ust.user_id = u.id where ust.search_term_like ? order by u.`id`The examples are using a MySQL dialect. If the schema had been setup for, say, a Postgres dialect, a generated query would look more like:
select "id","given_name","family_name","dob","ssn","street","locality","postcode","country",
"phone","mobile","fax" from users where postcode=$1It is an important point to note that this feature is not about writing the SQL for the programmer. Rather it is about "filling in the blanks": allowing the programmer to specify as much of the SQL query as they want without having to write the tiresome bits.
For more information on preparing queries, see the detailed documentation.
When inserting rows using InsertRow, if a column is defined as an autoincrement column, then the generated value will be retrieved from the database server, and the corresponding field in the row structure will be updated.
type Row {
ID int `sql:"primary key autoincrement"`
Name string
}
row := &Row{Name: "some name"}
_, err := sess.InsertRow(row)
if err != nil {
log.Fatal(err)
}
// row.ID will contain the auto-generated value
fmt.Println(row.ID)Most SQL database tables have columns that are nullable, and it can be tiresome to
always map to pointer types or special nullable types such as sql.NullString. In
many cases it is acceptable to map the zero value for the field a database NULL
in the corresponding database column.
Where it is acceptable to map a zero value to a NULL database column, the Go struct field can be marked with the "null" keyword in the field's struct tag.
type Employee struct {
ID int `sql:"primary key"`
Name string
ManagerID int `sql:"null"`
Phone string `sql:"null"`
}In the above example the manager_id column can be null, but if all valid IDs are
non-zero, it is unambiguous to map the zero value to a database NULL. Similarly, if
the phone column an empty string it will be stored as a NULL in the database.
Care should be taken, because there are cases where an empty value and a database NULL do not represent the same thing. There are many cases, however, where this feature can be applied, and the result is simpler code that is easier to read.
It is not uncommon to serialize complex objects as JSON text for storage in an SQL database. Native support for JSON is available in some database servers: in partcular Postgres has excellent support for JSON.
It is straightforward to use this package to serialize a structure field to JSON:
type SomethingComplex struct {
Name string
Values []int
MoreValues map[string]float64
// ... and more fields here ...
}
type Row struct {
ID int `sql:"primary key"`
Name string
Cmplx *SomethingComplex `sql:"json"`
}In the example above the Cmplx field will be marshaled as JSON text when
writing to the database, and unmarshaled into the struct when reading from
the database.
While most SQL queries accept a fixed number of parameters, if the SQL query
contains a WHERE IN clause, it requires additional string manipulation to match
the number of placeholders in the query with args.
This package simplifies queries with a variable number of arguments. When processing an SQL query, it detects if any of the arguments are slices:
// GetWidgets returns all the widgets associated with the supplied IDs.
func GetWidgets(sess *sqlr.Session, ids ...int) ([]*Widget, error) {
var rows []*Widget
_, err := sess.Select(&rows, `select {} from widgets where id in (?)`, ids)
if err != nil {
return nil, err
}
return widgets, nil
}In the above example, the number of placeholders ("?") in the query will be increased to
match the number of values in the ids slice. The expansion logic can handle any mix of
slice and scalar arguments.
A session can create type-safe query functions. This is a very powerful feature and makes it very easy to create type-safe data access objects.
var getWidget func(id int64) (*Widget, error)
// a session can make a typesafe function to retrieve an individual widget
sess.MakeQuery(&getWidget)
// now use the created function
widget, err := getWidget(42)
if err != nil {
return err
}
// ... now use the widget ...See Session.MakeQuery in the GoDoc for examples.