xo
is a command-line tool to generate Go
code based on a database schema or a custom query.
xo
works by using database metadata and SQL introspection queries to discover
the types and relationships contained within a schema, and applying a standard
set of base (or customized) Go templates against the discovered relationships.
Currently, xo
can generate types for tables, enums, stored procedures, and
custom SQL queries for PostgreSQL, MySQL, Oracle, Microsoft SQL Server, and
SQLite3 databases.
NOTE: While the code generated by xo is production quality, it is not the goal, nor the intention for xo to be a "silver bullet," nor to completely eliminate the manual authoring of SQL / Go code.
The following is a matrix of the feature support for each database:
PostgreSQL | MySQL | Oracle | Microsoft SQL Server | SQLite | |
---|---|---|---|---|---|
Models | ✅ | ✅ | ✅ | ✅ | ✅ |
Primary Keys | ✅ | ✅ | ✅ | ✅ | ✅ |
Foreign Keys | ✅ | ✅ | ✅ | ✅ | ✅ |
Indexes | ✅ | ✅ | ✅ | ✅ | ✅ |
Stored Procs | ✅ | ✅ | |||
ENUM types | ✅ | ✅ | |||
Custom types | ✅ |
Install goimports
dependency (if not already installed):
$ go get -u golang.org/x/tools/cmd/goimports
Then, install in the usual Go way:
$ go get -u github.com/xo/xo
# install with oracle support (see notes below)
$ go get -tags oracle -u github.com/xo/xo
NOTE: Go 1.6+ is needed for installing xo
from source, as it makes use
of the trim template syntax in Go templates, which is not compatible with
previous versions of Go. However, code generated by xo
should compile with Go
1.3+.
The following is a quick overview of using xo
on the command-line:
# change to project directory
$ cd $GOPATH/src/path/to/project
# make an output directory
$ mkdir -p models
# generate code for a postgres schema
$ xo pgsql://user:pass@host/dbname -o models
# generate code for a Microsoft SQL schema using a custom template directory (see notes below)
$ mkdir -p mssqlmodels
$ xo mysql://user:pass@host/dbname -o mssqlmodels --template-path /path/to/custom/templates
# generate code for a custom SQL query for postgres
$ xo pgsql://user:pass@host/dbname -N -M -B -T AuthorResult -o models/ << ENDSQL
SELECT
a.name::varchar AS name,
b.type::integer AS my_type
FROM authors a
INNER JOIN authortypes b ON a.id = b.author_id
WHERE
a.id = %%authorID int%%
LIMIT %%limit int%%
ENDSQL
# build generated code
$ go build ./models/
$ go build ./mssqlmodels/
# do standard go install
$ go install ./models/
$ go install ./mssqlmodels/
The following are xo
's command-line arguments and options:
$ xo --help
usage: xo [--verbose] [--schema SCHEMA] [--out OUT] [--append] [--suffix SUFFIX] [--single-file] [--package PACKAGE] [--custom-type-package CUSTOM-TYPE-PACKAGE] [--int32-type INT32-TYPE] [--uint32-type UINT32-TYPE] [--ignore-fields IGNORE-FIELDS] [--fk-mode FK-MODE] [--use-index-names] [--use-reversed-enum-const-names] [--query-mode] [--query QUERY] [--query-type QUERY-TYPE] [--query-func QUERY-FUNC] [--query-only-one] [--query-trim] [--query-strip] [--query-interpolate] [--query-type-comment QUERY-TYPE-COMMENT] [--query-func-comment QUERY-FUNC-COMMENT] [--query-delimiter QUERY-DELIMITER] [--query-fields QUERY-FIELDS] [--escape-all] [--escape-schema] [--escape-table] [--escape-column] [--enable-postgres-oids] [--name-conflict-suffix NAME-CONFLICT-SUFFIX] [--template-path TEMPLATE-PATH] DSN
positional arguments:
dsn data source name
options:
--verbose, -v toggle verbose
--schema SCHEMA, -s SCHEMA
schema name to generate Go types for
--out OUT, -o OUT output path or file name
--append, -a append to existing files
--suffix SUFFIX, -f SUFFIX
output file suffix [default: .xo.go]
--single-file toggle single file output
--package PACKAGE, -p PACKAGE
package name used in generated Go code
--custom-type-package CUSTOM-TYPE-PACKAGE, -C CUSTOM-TYPE-PACKAGE
Go package name to use for custom or unknown types
--int32-type INT32-TYPE, -i INT32-TYPE
Go type to assign to integers [default: int]
--uint32-type UINT32-TYPE, -u UINT32-TYPE
Go type to assign to unsigned integers [default: uint]
--ignore-fields IGNORE-FIELDS
fields to exclude from the generated Go code types
--fk-mode FK-MODE, -k FK-MODE
sets mode for naming foreign key funcs in generated Go code [values: <smart|parent|field|key>] [default: smart]
--use-index-names, -j
use index names as defined in schema for generated Go code
--use-reversed-enum-const-names, -R
use reversed enum names for generated consts in Go code
--query-mode, -N enable query mode
--query QUERY, -Q QUERY
query to generate Go type and func from
--query-type QUERY-TYPE, -T QUERY-TYPE
query's generated Go type
--query-func QUERY-FUNC, -F QUERY-FUNC
query's generated Go func name
--query-only-one, -1 toggle query's generated Go func to return only one result
--query-trim, -M toggle trimming of query whitespace in generated Go code
--query-strip, -B toggle stripping type casts from query in generated Go code
--query-interpolate, -I
toggle query interpolation in generated Go code
--query-type-comment QUERY-TYPE-COMMENT
comment for query's generated Go type
--query-func-comment QUERY-FUNC-COMMENT
comment for query's generated Go func
--query-delimiter QUERY-DELIMITER, -D QUERY-DELIMITER
delimiter for query's embedded Go parameters [default: %%]
--query-fields QUERY-FIELDS, -Z QUERY-FIELDS
comma separated list of field names to scan query's results to the query's associated Go type
--escape-all, -X escape all names in SQL queries
--escape-schema, -z escape schema name in SQL queries
--escape-table, -y escape table names in SQL queries
--escape-column, -x escape column names in SQL queries
--enable-postgres-oids
enable postgres oids
--name-conflict-suffix NAME-CONFLICT-SUFFIX, -w NAME-CONFLICT-SUFFIX
suffix to append when a name conflicts with a Go variable [default: Val]
--template-path TEMPLATE-PATH
user supplied template path
--help, -h display this help and exit
xo
provides a set of generic "base" templates for each of the
supported databases, but it is understood these templates are not suitable for
every organization or every schema out there. As such, you can author your own
custom templates, or modify the base templates available in the xo
source
tree, and use those with xo
by a passing a directory path via the --template-path
flag.
For non-trivial schemas, custom templates are the most practical, common, and
best way to use xo
(see below quickstart and related example).
The following is a quick overview of copying the base templates contained in
the xo
project's templates/
directory, editing to suit, and
using with xo
:
# change to working project directory
$ cd $GOPATH/src/path/to/my/project
# create a template directory
$ mkdir -p templates
# copy xo templates for postgres
$ cp "$GOPATH/src/github.com/xo/xo/templates/*" templates/
# remove xo binary data
$ rm templates/*.go
# edit base postgres templates
$ vi templates/postgres.*.tpl.go
# use with xo
$ xo pgsql://user:pass@host/db -o models --template-path templates
See the Custom Template example below for more information on adapting the base
templates in the xo
source tree for use within your own project.
Ideally, the custom templates for your project/schema should be stored
within your project, and used in conjunction with a build pipeline such as
go generate
:
# add to custom xo command to go generate:
$ tee -a gen.go << ENDGO
package mypackage
//go:generate xo pgsql://user:pass@host/db -o models --template-path templates
ENDGO
# run go generate
$ go generate
# add custom templates and gen.go to project
$ git add templates gen.go && git commit -m 'Adding custom xo templates for models'
Note that xo
only needs the templates for your specific database. You can
safely delete the templates for the other databases -- make sure, however, that
your templates are not symlinks to another database's templates before
deleting.
xo
templates are standard Go text templates. Please see the documentation
for Go's standard text/template
package
for information concerning the syntax, logic, and variable use within Go
templates.
The contexts (ie, the .
identifier in templates) made available to custom
templates are instances of xo/internal/$TYPE
(see below table on $TYPE
available $TYPE
s), and are defined in internal/types.go
.
Each database, $DBNAME
, has its own set of templates for $TYPE
and are
available in the templates/ directory as templates/$DBNAME.$TYPE.go.tpl
:
Template File | $TYPE |
Description |
---|---|---|
templates/$DBNAME.type.go.tpl |
Type |
Template for schema tables/views/queries |
templates/$DBNAME.enum.go.tpl |
Enum |
Template for schema enum definitions |
templates/$DBNAME.proc.go.tpl |
Proc |
Template for stored procedures/functions ("routines") |
templates/$DBNAME.foreignkey.go.tpl |
ForeignKey |
Template for foreign keys relationships |
templates/$DBNAME.index.go.tpl |
Index |
Template for schema indexes |
templates/$DBNAME.querytype.go.tpl |
QueryType |
Template for a custom query's generated type |
templates/$DBNAME.query.go.tpl |
Query |
Template for custom query execution |
templates/xo_db.go.tpl |
ArgType |
Package level template generated once per package |
templates/xo_package.go.tpl |
ArgType |
File header template generated once per file |
For example, PostgreSQL has templates/postgres.foreignkey.go.tpl
which defines the template used by xo
for PostgreSQL's foreign keys. This
template will be called once for every foreign key relationship that xo
finds
in a PostgreSQL schema, and each time the template will be passed a different
internal.ForeignKey
instance, populated fields for Name
, Schema
, etc.,
which are then available in the templates/postgres.foreignkey.go.tpl
as
template variables, and used similar to the following: {{ .Name }}
, {{ .Schema }}
,
etc.
Since some of the templates are identical for the supported databases, the
templates are not duplicated, but are instead symlinks in the xo
source tree.
For example, templates/oracle.querytype.go.tpl
is a symlink to templates/postgres.querytype.go.tpl
.
There is a set of well defined template helpers in internal/funcs.go
that can assist with writing templated Go code / SQL. Please review how the
base templates/
make use of helpers, and/or see the inline
documentation for the respective helper func definitions.
The base xo
templates are bin packed so that they are always available to the
built xo
binary using go-bindata
(via
the tpl.sh
script) and need to be regenerated/included in any
changeset when submitting any template changes to the xo
project.
If you would like to distribute your own binary version of xo
with the
included templates, simply modify the templates in the xo
source tree, run
tpl.sh
, and build as you normally would.
Alternatively, you can simply do the following:
$ go generate && go build
Please see the booktest example for a full end-to-end
example for each supported database, showcasing how to use a database schema
with xo
, and the resulting code generated by xo
.
Additionally, please see the pokedex example for a
demonstration of running xo
against a large schema. Please note that this
example is a work in progress, and does not yet work properly with Microsoft
SQL Server and Oracle databases, and has no documentation (for now) -- however
it works very similarly to the booktest end-to-end example.
Sometimes you may wish to have the database manage the values of columns
instead of having them managed by code generated by xo
. As such, when you
need xo
to ignore fields for a database schema, you can use the --ignore-fields
flag. For example, a common use case is to define a table with created_at
and/or modified_at
timestamps, where the database is responsible for setting
column values on INSERT
and UPDATE
, respectively.
Consider the following PostgreSQL schema where a users
table has a
created_at
and modified_at
field, where created_at
has a default value of
now()
and where modified_at
is updated by a trigger on UPDATE
:
CREATE TABLE users (
id SERIAL PRIMARY KEY,
name text NOT NULL DEFAULT '' UNIQUE,
created_at timestamptz default now(),
modified_at timestamptz default now(),
);
CREATE OR REPLACE FUNCTION update_modified_column() RETURNS TRIGGER AS $$
BEGIN
NEW.modfified_at = now();
RETURN NEW;
END;
$$ language 'plpgsql';
CREATE TRIGGER update_users_modtime BEFORE UPDATE ON users FROM EACH ROW EXECUTE PROCEDURE update_modified_column();
We can ensure that these columns are managed by PostgreSQL and not by the Go
code generated with xo
by passing the --ignore-fields
option:
# ignore special fields
$ xo pgsql://user:pass@host/db -o models --ignore-fields created_at modified_at
Often, a schema has a common layout/pattern, such as every table having a
created_at
and modified_at
field (as in the PostgreSQL schema in the
previous example). It is then a common use-case to have a GetMostRecent
lookup for each table type, retrieving the most recently modified rows for each
table (up to some limit, N).
To accomplish this with xo
, we will need to create our own set of custom
templates, and then add a GetMostRecent
lookup to the $DBTYPE.type.go.tpl
template.
First, we create a copy of the base xo
templates:
$ cd $GOPATH/src/path/to/project
$ mkdir -p templates
$ cp $GOPATH/src/github.com/xo/xo/templates/* templates/
We can now modify the templates to suit our specific schema, adding lookups, helpers, or anything else necessary for our schema.
To add a GetMostRecent
lookup, we edit our copy of the postgres.type.go.tpl
template:
$ vi templates/postgres.type.go.tpl
And add the following templated GetMostRecent
func at the end of the file:
// GetMostRecent{{ .Name }} returns n most recent rows from '{{ .Schema }}.{{ .Table.TableName }}',
// ordered by "created_at" in descending order.
func GetMostRecent{{ .Name }}(db XODB, n int) ([]*{{ .Name }}, error) {
const sqlstr = `SELECT ` +
`{{ colnames .Fields "created_at" "modified_at" }}` +
`FROM {{ $table }} ` +
`ORDER BY created_at DESC LIMIT $1`
q, err := db.Query(sqlstr, n)
if err != nil {
return nil, err
}
defer q.Close()
// load results
var res []*{{ .Name }}
for q.Next() {
{{ $short }} := {{ .Name }}{}
// scan
err = q.Scan({{ fieldnames .Fields (print "&" $short) }})
if err != nil {
return nil, err
}
res = append(res, &{{ $short }})
}
return res, nil
}
We can then use the templates in conjunction with xo
to generate our "model"
code:
$ xo pgsql://user:pass@localhost/dbname -o models --template-path templates/
There will now be a GetMostRecentUsers
func defined in models/user.xo.go
,
which can be used as follows:
db, err := dburl.Open("pgsql//user:pass@localhost/dbname")
if err != nil { /* ... */ }
// retrieve 15 most recent items
mostRecentUsers, err := models.GetMostRecentUsers(db, 15)
if err != nil { /* ... */ }
for _, user := range users {
log.Printf("got user: %+v", user)
}
Please note that the base xo
templates do not import any SQL drivers. It is
left for the user of xo
's generated code to import the actual drivers. For
reference, these are the expected drivers to use with the code generated by
xo
:
Database (driver) | Package |
---|---|
Microsoft SQL Server (mssql) | github.com/denisenkom/go-mssqldb |
MySQL (mysql) | github.com/go-sql-driver/mysql |
Oracle (ora) | gopkg.in/rana/ora.v4 |
PostgreSQL (postgres) | github.com/lib/pq |
SQLite3 (sqlite3) | github.com/mattn/go-sqlite3 |
Additionally, please see below for usage notes on specific SQL database drivers.
If your schema or custom query contains table or column names that need to be
escaped using any of the --escape-*
options, you must pass the sql_mode=ansi
option to the MySQL driver:
$ xo --escape-all 'mysql://user:pass@host/?parseTime=true&sql_mode=ansi' -o models
And when opening a database connection:
db, err := dburl.Open("mysql://user:pass@host/?parseTime=true&sql_mode=ansi")
Additionally, when working with date/time column types in MySQL, one should
pass the parseTime=true
option to the MySQL driver:
$ xo 'mysql://user:pass@host/dbname?parseTime=true' -o models
And when opening a database connection:
db, err := dburl.Open("mysql://user:pass@host/dbname?parseTime=true")
Oracle support is disabled by default as the Go Oracle driver
used by xo
needs the Oracle instantclient
libs to be installed/known by
pkg-config
. If you have already installed rana's Oracle driver
according to the installation instructions, you can simply pass -tags oracle
to go get
, go install
or go build
to enable Oracle support:
$ go get -tags oracle -u github.com/xo/xo
On Ubuntu/Debian, you may download the instantclient RPMs here.
You should then be able to do the following:
# install alien, if not already installed
$ sudo aptitude install alien
# install the instantclient RPMs
$ sudo alien -i oracle-instantclient-12.1-basic-*.rpm
$ sudo alien -i oracle-instantclient-12.1-devel-*.rpm
$ sudo alien -i oracle-instantclient-12.1-sqlplus-*.rpm
# get xo
$ go get -u github.com/xo/xo
# copy oci8.pc from xo/contrib to system pkg-config directory
$ sudo cp $GOPATH/src/github.com/xo/xo/contrib/oci8.pc /usr/lib/pkgconfig/
# install rana's ora driver
$ go get -u gopkg.in/rana/ora.v4
# assuming the above succeeded, install xo with oracle support enabled
$ go install -tags oracle github.com/xo/xo
It's of note that there are additional scripts available in the
contrib directory that can help when working with Oracle databases
and xo
.
For reference, the xo
developers use the sath89/oracle-12c Docker image
for testing xo
's Oracle database support.
While not required, one should specify the loc=auto
option when using xo
with a SQLite3 database:
$ xo 'file:mydatabase.sqlite3?loc=auto' -o models
And when opening a database connection:
db, err := dburl.Open("file:mydatabase.sqlite3?loc=auto")
For row inserts xo
determines whether the primary key is
automatically generated by the DB or must be provided by the application for the table row being inserted.
For example a table that has a primary key that is also a foreign key to another table, or a
table that has multiple primary keys in a many-to-many link table, it is desired that
the application provide the primary key(s) for the insert rather than the DB.
xo
will query the schema to determine if the database provides an automatic primary key
and if the table does not provide one then it will require that the application provide the
primary key for the object passed to the the Insert method. Below is information on how
the logic works for each database type to determine if the DB automatically provides the PK.
- Checks for an autoincrement row in the information_schema for the table in question.
- Checks for a sequence that is owned by the table in question.
- Checks the SQL that is used to generate the table contains the AUTOINCREMENT keyword.
- Checks that the table was created with the primary key type of INTEGER.
If either of the above conditions are satisfied then the PK is determined to be automatically provided by the DB. For the case of integer PK's when you want to override that the PK be manually provided then you can define the key type as INT instead of INTEGER, for example as in the following many-to-many link table:
CREATE TABLE "SiteContacts" (
"ContactId" INT NOT NULL,
"SiteId" INT NOT NULL,
PRIMARY KEY(ContactId,SiteId),
FOREIGN KEY("ContactId") REFERENCES "Contacts" ( "ContactId" ),
FOREIGN KEY("SiteId") REFERENCES "Sites" ( "SiteId" )
)
- Checks for an identity associated with one of the columns for the table in question.
There is currently no method provided for Oracle as there is no programmatic way to query for which sequences are associated with tables. All PK's will be assumed to be provided by the database.
xo
can likely get you 99% "of the way there" on medium or large database
schemas and 100% of the way there for small or trivial database schemas. In
short, xo is a great launching point for developing standardized packages for
standard database abstractions/relationships, and xo's most common use-case is
indeed in a code generation pipeline, ala stringer
.
xo
is NOT designed to be an ORM or to generate an ORM. Instead, xo
is
designed to vastly reduce the overhead/redundancy of (re-)writing types and
funcs for common database queries/relationships in Go -- it is not meant to be
a "silver bullet".
xo
was originally developed while migrating a large application written in
PHP to Go. The schema in use in the original app, while well designed, had
become inconsistent over multiple iterations/generations, mainly due to
different naming styles adopted by various developers/database admins over the
preceding years. Additionally, some components had been written in different
languages (Ruby, Java) and had also accumulated significant drift from the
original application and accompanying schema. Simultaneously, a large amount of
growth meant that the PHP/Ruby code could no longer efficiently serve the
traffic volumes.
In late 2014/early 2015, a decision was made to unify and strip out certain backend services and to fully isolate the API from the original application, allowing the various components to instead speak to a common API layer instead of directly to the database, and to build that service layer in Go.
However, unraveling the old PHP/Ruby/Java code became a large headache, as the code, the database, and the API, all had significant drift -- thus, underlying function names, fields, and API methods no longer coincided with the actual database schema, and were named differently in each language. As such, after a round of standardizing names, dropping cruft, and adding a small number of relationship changes to the schema, the various codebases were fixed to match the schema changes. After that was determined to be a success, the next target was to rewrite the backend services in Go.
In order to keep a similar and consistent workflow for the developers, the previous code generator (written in PHP and Twig templates) was modified to generate Go code. Additionally, at this time, but tangential to the story, the API definitions were ported from JSON to Protobuf to make use of its code generation abilities as well.
xo
is the open source version of that code generation tool, and is the fruits
of those development efforts. It is hoped that others will be able to use and
expand xo
to support other databases -- SQL or otherwise -- and that xo
can
become a common tool in any Go developer's toolbox.
Part of xo
's goals is to avoid writing an ORM, or an ORM-like in Go, and to
instead generate static, type-safe, fast, and idiomatic Go code across
languages and databases. Additionally, the xo
developers are of the opinion
that relational databases should have proper, well-designed relationships and
all the related definitions should reside within the database schema itself:
ie, a "self-documenting" schema. xo
is an end to that pursuit.
- dburl - a Go package providing a standard, URL style mechanism for parsing and opening database connection URLs
- usql - a universal command-line interface for SQL databases
The following projects work with similar concepts as xo:
- Completely refactor / fix code, templates, and other issues (PRIORITY #1)
- Add (finish) stored proc support for Oracle + Microsoft SQL Server
- Unit tests / code coverage / continuous builds for binary package releases
- Move database introspection to separate package for reuse by other Go packages
- Overhaul/standardize type parsing
- Finish support for --{incl, excl}[ude] types
- Write/publish template set for protobuf
- Add support for generating models for other languages
- Finish many-to-many and link table support
- Finish example and code for generated *Slice types (also, only generate for the databases its needed for)
- Add example for many-to-many relationships and link tables
- Add support for supplying a file (ie, *.sql) for query generation
- Add support for full text types (tsvector, tsquery on PostgreSQL)
- Finish COMMENT support for PostgreSQL/MySQL and update templates accordingly.
- Add support for JSON types (json, jsonb on PostgreSQL, json on MySQL)
- Add support for GIN index queries (PostgreSQL)