Version 1.32
Postmodern is a Common Lisp library for interacting with PostgreSQL databases. It is under active development. Features are:
- Efficient communication with the database server without need for foreign libraries.
- Support for UTF-8 on Unicode-aware Lisp implementations
- A syntax for mixing SQL and Lisp code
- Convenient support for prepared statements and stored procedures
- A metaclass for simple database-access objects
The biggest differences between this library and CLSQL/CommonSQL or cl-dbi are that Postmodern has no intention of being portable across different SQL implementations (it embraces non-standard PostgreSQL features), and approaches extensions like lispy SQL and database access objects in a quite different way. This library was written because the CLSQL approach did not really work for me. Your mileage may vary.
- Dependencies
- License
- Download and installation
- Quickstart
- Running tests
- Reference
- Caveats and to-dos
- Resources
The library depends on usocket (except on SBCL and ACL, where the built-in socket library is used), md5, closer-mop, bordeaux-threads if you want thread-safe connection pools, and CL+SSL when SSL connections are needed. As of version 1.3 it also depends on ironclad, base64 and uax-15 because of the requirement to support scram-sha-256 authentication.
Postmodern itself is split into four different packages, some of which can be used independently.
Simple-date is a very basic implementation of date and time objects, used to support storing and retrieving time-related SQL types. It is not loaded by default and you can use local-time (which has support for timezones) instead.
CL-postgres is the low-level library used for interfacing with a PostgreSQL server over a socket.
S-SQL is used to compile s-expressions to strings of SQL code, escaping any Lisp values inside, and doing as much as possible of the work at compile time.
Finally, Postmodern itself is a wrapper around these packages and provides higher level functions, a very simple data access object that can be mapped directly to database tables and some convient utilities. It then tries to put all these things together into a convenient programming interface.
Postmodern is released under a zlib-style license. Which approximately means you can use the code in whatever way you like, except for passing it off as your own or releasing a modified version without indication that it is not the original.
The functions execute-file.lisp were ported from [[https://github.com/dimitri/pgloader][pgloader]] with grateful thanks to Dimitri Fontaine and are released under a BSD-3 license.
We suggest using quicklisp for installation.
A git repository with the most recent changes can be viewed or checked out at https://github.com/marijnh/Postmodern
This quickstart is intended to give you a feel of the way coding with Postmodern works. Further details about the workings of the library can be found in the reference manual.
Assuming you have already installed it, first load and use the system:
(ql:quickload :postmodern)
(use-package :postmodern)
If you have a PostgreSQL server running on localhost, with a database called 'testdb' on it, which is accessible for user 'foucault' with password 'surveiller', there are two basic ways to connect to a database. If your role/application/database(s) looks like a 1:1 relationship, you can connect like this:
(connect-toplevel "testdb" "foucault" "surveiller" "localhost")
Which will establish a connection to be used by all code, except for that wrapped in a with-connection form, which takes the same arguments but only establishes the connection within that lexical scope.
Connect-toplevel will maintain a single connection for the life of the session.
If the Postgresql server is running on a port other than 5432, you would also pass the appropriate keyword port parameter. E.g.:
(connect-toplevel "testdb" "foucault" "surveiller" "localhost" :port 5434)
Ssl connections would similarly use the keyword parameter :use-ssl and pass :yes, :no or :try
If you have multiple roles connecting to one or more databases, i.e. 1:many or many:1, (in other words, changing connections) then with-connection form which establishes a connection with a lexical scope is more appropriate.
(with-connection '("testdb" "foucault" "surveiller" "localhost")
...)
For example, if you are creating a database, you need to have established a connection to a currently existing database (typically "postgres"). Assuming the foucault role is a superuser and you want to stay in a development connection with your new database afterwards, you would first use with-connection to connect to postgres, create the database and then switch to connect-toplevel for development ease.
(with-connection '("postgres" "foucault" "surveiller" "localhost")
(create-database 'testdb :limit-public-access t
:comment "This database is for testing silly theories"))
(connect-toplevel "testdb" "foucault" "surveiller" "localhost")
Note: (create-database) functionality is new to postmodern v. 1.32. Setting the :limit-public-access parameter to t will block connections to that database from anyone who you have not explicitly given permission (except other superusers).
A word about Postgresql connections. Postgresql connections are not lightweight threads. They actually consume about 10 MB of memory per connection and Postgresql can be tuned to limit the number of connections allowed at any one time. In addition, any connections which require security (ssl or scram authentication) will take additiona time and create more overhead.
If you have an application like a web app which will make many connections, you also generally do not want to create and drop connections for every query. The usual solution is to use connection pools so that the application is grabbing an already existing connection and returning it to the pool when finished, saving connection time and memory.
To use postmodern's simple connection pooler, the with-connection call would look like:
(with-connection '("testdb" "foucault" "surveiller" "localhost" :pooled-p t)
...)
The maximum number of connections in the pool is set in the special variable *max-pool-size*, which defaults to nil (no maximum).
Now for a basic sanity test which does not need a database connection at all:
(query "select 22, 'Folie et déraison', 4.5")
;; => ((22 "Folie et déraison" 9/2))
That should work. query is the basic way to send queries to the database. The same query can be expressed like this:
(query (:select 22 "Folie et déraison" 4.5))
;; => ((22 "Folie et déraison" 9/2))
In many contexts, query strings and lists starting with keywords can be used interchangeably. The lists will be compiled to SQL. The S-SQL manual describes the syntax used by these expressions. Lisp values occurring in them are automatically escaped. In the above query, only constant values are used, but it is possible to transparently use run-time values as well:
(defun database-powered-addition (a b)
(query (:select (:+ a b)) :single))
(database-powered-addition 1030 204)
;; => 1234
That last argument, :single, indicates that we want the result not as a list of lists (for the result rows), but as a single value, since we know that we are only selecting one value. Some other options are :rows, :row, :column, :alists, and :none. Their precise effect is documented in the reference manual.
You do not have to pull in the whole result of a query at once, you can also iterate over it with the doquery macro:
(doquery (:select 'x 'y :from 'some-imaginary-table) (x y)
(format t "On this row, x = ~A and y = ~A.~%" x y))
You can work directly with the database or you can use a simple database-access-class (aka dao) which would cover all the columns in a row. This is what a database-access class looks like:
(defclass country ()
((name :col-type string :initarg :name
:reader country-name)
(inhabitants :col-type integer :initarg :inhabitants
:accessor country-inhabitants)
(sovereign :col-type (or db-null string) :initarg :sovereign
:accessor country-sovereign))
(:metaclass dao-class)
(:keys name))
The above defines a class that can be used to handle records in a table with three columns: name, inhabitants and sovereign. The :keys parameter specifies which column(s) are used for the primary key. Once you have created the class, you can return an instance of the country class by calling
(get-dao 'country "Croatia")
You can also define classes that use multiple columns in the primary key:
(defclass points ()
((x :col-type integer :initarg :x
:reader point-x)
(y :col-type integer :initarg :y
:reader point-y)
(value :col-type integer :initarg :value
:accessor value))
(:metaclass dao-class)
(:keys x y))
In this case, retrieving a points record would look like the following where 12 and 34 would be the values you are looking to find in the x column and y column respectively.:
(get-dao 'points 12 34)
Consider a slightly more complicated version of country:
(defclass country ()
((id :col-type integer :col-identity t :accessor id)
(name :col-type string :col-unique t :check (:<> 'name "")
:initarg :name :reader country-name)
(inhabitants :col-type integer :initarg :inhabitants
:accessor country-inhabitants)
(sovereign :col-type (or db-null string) :initarg :sovereign
:accessor country-sovereign)
(region-id :col-type integer :col-references ((regions id))
:initarg :region-id :accessor region-id))
(:metaclass dao-class)
(:table-name countries))
In this example we have an id column which is specified to be an identity column. Postgresql will automatically generate a sequence of of integers and this will be the primary key.
We have a name column which is specified as unique and is not null and the check will ensure that the database refuses to accept an empty string as the name.
We have a region-id column which references the id column in the regions table. This is a foreign key constraint and Postgresql will not accept inserting a country into the database unless there is an existing region with an id that matches this number. Postgresql will also not allow deleting a region if there are countries that reference that region's id. If we wanted Postgresql to delete countries when regions are deleted, that column would be specified as:
(region-id :col-type integer :col-references ((regions id) :cascade)
:initarg :region-id :accessor region-id)
Now you can see why the double parens.
We also specify that the table name is not "country" but "countries". (Some style guides recommend that table names be plural and references to rows be singular.)
You can create tables directly without the need to define a class, and in more complicated cases, you may need to use the s-sql :create-table operator or plain vanilla sql. Staying with examples that will match our slightly more complicated dao-class above (but ignoring the fact that the references parameter would actually require us to create the regions table first) and using s-sql rather than plain vanilla sql would be the following:
(query (:create-table 'countries
((id :type integer :primary-key t :identity-always t)
(name :type string :unique t :check (:<> 'name ""))
(inhabitants :type integer)
(sovereign :type (or db-null string))
(region-id :type integer :references ((regions id))))))
Restated using vanilla sql:
(query "CREATE TABLE countries (
id INTEGER NOT NULL PRIMARY KEY GENERATED ALWAYS AS IDENTITY,
name TEXT NOT NULL UNIQUE CHECK (NAME <> E''),
inhabitants INTEGER NOT NULL,
sovereign TEXT,
region_id INTEGER NOT NULL REFERENCES regions(id)
MATCH SIMPLE ON DELETE RESTRICT ON UPDATE RESTRICT)")
Let's look at a slightly different example:
(query (:create-table so-items
((item-id :type integer)
(so-id :type (or integer db-null) :references ((so-headers id)))
(product-id :type (or integer db-null))
(qty :type (or integer db-null))
(net-price :type (or numeric db-null)))
(:primary-key item-id so-id)))
Restated using plain sql:
(query "CREATE TABLE so_items (
item_id INTEGER NOT NULL,
so_id INTEGER REFERENCES so_headers(id)
MATCH SIMPLE ON DELETE RESTRICT ON UPDATE RESTRICT,
product_id INTEGER,
qty INTEGER,
net_price NUMERIC,
PRIMARY KEY (item_id, so_id)
);"
)
In the above case, the new table's name will be so_items because sql does not allow hyphens and plain vanilla sql will require that. Postmodern will generally allow you to use the quoted symbol 'so-items. This is also true for all the column names. The column item-id is an integer and cannot be null. The column so-id is also an integer, but is allowed to be null and is a foreign key to the id field in the so-headers table so-headers. The primary key is actually a composite of item-id and so-id. (If we wanted the primary key to be just item-id, we could have specified that in the form defining item-id.)
You can also use a previously defined dao to create a table as well using the dao-table-definition function which generates the plain vanilla sql for creating plain vanilla sql for creating a table described above. Using the slightly more complicated version of the country dao above:
(dao-table-definition 'country)
;; => "CREATE TABLE countries (
;; id INTEGER NOT NULL PRIMARY KEY generated always as identity,
;; name TEXT NOT NULL UNIQUE,
;; inhabitants INTEGER NOT NULL,
;; sovereign TEXT DEFAULT NULL,
;; region_id INTEGER NOT NULL REFERENCES regions(id)
;; MATCH SIMPLE ON DELETE RESTRICT ON UPDATE RESTRICT)
(execute (dao-table-definition 'country))
This defines our table in the database. execute works like query, but does not expect any results back.
See Introduction to Multi-table dao class objects in the postmodern.org or postmodern.html manual for a further discussion of multi-table use of daos.
Similarly to table creation, you can insert data using the s-sql wrapper, plain vanilla sql or daos. Because we have not created a regions table, we are just going to use the simple version of country without the region-id.
The s-sql approach would be:
(query (:insert-into 'country :set 'name "The Netherlands"
'inhabitants 16800000
'sovereign "Willem-Alexander"))
(query (:insert-into 'country :set 'name "Croatia"
'inhabitants 4400000))
You could also insert multiple rows at a time but that requires the same columns for each row:
(query (:insert-rows-into 'country :columns 'name 'inhabitants 'sovereign
:values '(("The Netherlands" 16800000 "Willem-Alexander")
("Croatia" 4400000 :null))))
The sql approach would be:
(query "insert into country (name, inhabitants, sovereign)
values ('The Netherlands', 16800000, 'Willem-Alexander')")
(query "insert into country (name, inhabitants)
values ('Croatia', 4400000)")
The multiple row sql approach would be:
(query "insert into country (name, inhabitants, sovereign)
values
('The Netherlands', 16800000, 'Willem-Alexander'),
('Croatia', 4400000, NULL)")
Using dao classes would look like:
(insert-dao (make-instance 'country :name "The Netherlands"
:inhabitants 16800000
:sovereign "Willem-Alexander"))
(insert-dao (make-instance 'country :name "Croatia"
:inhabitants 4400000))
Postmodern does not yet have an insert-daos (plural) function.
Staying with the dao class approach, to update Croatia's population, we could do this:
(let ((croatia (get-dao 'country "Croatia")))
(setf (country-inhabitants croatia) 4500000)
(update-dao croatia))
(query (:select '* :from 'country))
;; => (("The Netherlands" 16800000 "Willem-Alexander")
;; ("Croatia" 4500000 :NULL))
Next, to demonstrate a bit more of the S-SQL syntax, here is the query the utility function list-tables uses to get a list of the tables in a database:
(sql (:select 'relname :from 'pg-catalog.pg-class
:inner-join 'pg-catalog.pg-namespace :on (:= 'relnamespace 'pg-namespace.oid)
:where (:and (:= 'relkind "r")
(:not-in 'nspname (:set "pg_catalog" "pg_toast"))
(:pg-catalog.pg-table-is-visible 'pg-class.oid))))
;; => "(SELECT relname FROM pg_catalog.pg_class
;; INNER JOIN pg_catalog.pg_namespace ON (relnamespace = pg_namespace.oid)
;; WHERE ((relkind = 'r') and (nspname NOT IN ('pg_catalog', 'pg_toast'))
;; and pg_catalog.pg_table_is_visible(pg_class.oid)))"
sql is a macro that will simply compile a query, it can be useful for seeing how your queries are expanded or if you want to do something unexpected with them.
As you can see, lists starting with keywords are used to express SQL commands and operators (lists starting with something else will be evaluated and then inserted into the query). Quoted symbols name columns or tables (keywords can also be used but might introduce ambiguities). The syntax supports subqueries, multiple joins, stored procedures, etc. See the S-SQL reference manual for a complete treatment.
Finally, here is an example of the use of prepared statements:
(defprepared sovereign-of
(:select 'sovereign :from 'country :where (:= 'name '$1))
:single!)
(sovereign-of "The Netherlands")
;; => "Willem-Alexander"
The defprepared macro creates a function that takes the same amount of arguments as there are $X placeholders in the given query. The query will only be parsed and planned once (per database connection), which can be faster, especially for complex queries.
(disconnect-toplevel)
Postmodern can use either md5 or scram-sha-256 authentication. Scram-sha-256 authentication is obviously more secure, but slower than md5, so take that into account if you are planning on opening and closing many connections without using a connection pooling setup..
Other authentication methods have not been tested. Please let us know if there is a authentication method that you believe should be considered.
The reference manuals for the different components of Postmodern are kept in separate files. For using the library in the most straightforward way, you only really need to read the Postmodern reference and glance over the S-SQL reference. The simple-date reference explains the time-related data types included in Postmodern, and the CL-postgres reference might be useful if you just want a low-level library for talking to a PostgreSQL server.
For a short comparison of lisp and Postgresql data types (date and time datatypes are described in the next section)
Lisp type | SQL type | Description |
---|---|---|
integer | smallint | -32,768 to +32,768 2-byte storage |
integer | integer | -2147483648 to +2147483647 integer, 4-byte storage |
integer | bigint | -9223372036854775808 to 9223372036854775807 8-byte storage |
(numeric X Y) | numeric(X, Y) | user specified. See below |
float, real | real | float, 6 decimal digit precision 4-byte storage |
double-float | double-precision | double float 15 decimal digit precision 8-byte storage |
string, text | text | variable length string, no limit specified |
string | char(X) | char(length), blank-padded string, fixed storage length |
string | varchar(X) | varchar(length), non-blank-padded string, variable storage |
boolean | boolean | boolean, 'true'/'false', 1 byte |
bytea | bytea | binary strings allowing non-printable octets |
date | date | date range: 4713 BC to 5874897 AD |
interval | interval | time intervals |
array | array | See discussion at Array-Notes.html |
Numeric and decimal are variable storage size numbers with user specified precision. Up to 131072 digits before the decimal point; up to 16383 digits after the decimal point. The syntax is numeric(precision, scale). Numeric columns with a specified scale will coerce input values to that scale. For more detail, see https://www.postgresql.org/docs/current/datatype-numeric.html
PG Type | Sample Postmodern Return Value | Lisp Type (per sbcl) |
---|---|---|
boolean | T | BOOLEAN |
boolean | NIL (Note: within Postgresql this will show 'f') | BOOLEAN |
int2 | 273 | (INTEGER 0 4611686018427387903) |
int4 | 2 | (INTEGER 0 4611686018427387903) |
char | A | (VECTOR CHARACTER 64) |
varchar | id&wl;19 | (VECTOR CHARACTER 64) |
numeric | 78239/100 | RATIO |
json | { "customer": "John Doe", "items": {"product": "Beer","qty": 6}} | (VECTOR CHARACTER 64) |
jsonb | {"title": "Sleeping Beauties", "genres": ["Fiction", "Thriller", "Horror"]} | (VECTOR CHARACTER 128) |
float | 782.31 | SINGLE-FLOAT |
point | (0.0d0 0.0d0) | CONS |
lseg | ((-1.0d0 0.0d0) (2.0d0 4.0d0)) | CONS |
path | ((1,0),(2,4)) | (VECTOR CHARACTER 64) |
box | ((1.0d0 1.0d0) (0.0d0 0.0d0)) | CONS |
polygon | ((21,0),(2,4)) | (VECTOR CHARACTER 64) |
line | {2,-1,0} | (VECTOR CHARACTER 64) |
double_precision | 2.38921379231d8 | DOUBLE-FLOAT |
double_float | 2.3892137923231d8 | DOUBLE-FLOAT |
circle | <(0,0),2> | (VECTOR CHARACTER 64) |
cidr | 100.24.10.0/24 | (VECTOR CHARACTER 64) |
inet | 100.24.10.0/24 | (VECTOR CHARACTER 64) |
interval | # | INTERVAL |
bit | #*1 | (SIMPLE-BIT-VECTOR 1) |
int4range | [11,24) | (VECTOR CHARACTER 64) |
uuid | 40e6215d-b5c6-4896-987c-f30f3678f608 | (VECTOR CHARACTER 64) |
text_array | #(text one text two text three) | (SIMPLE-VECTOR 3) |
integer_array | #(3 5 7 8) | (SIMPLE-VECTOR 4) |
bytea | #(222 173 190 239) | (SIMPLE-ARRAY (UNSIGNED-BYTE 8) (4)) |
text | Lorem ipsum dolor sit amet, consectetur adipiscing elit | (VECTOR CHARACTER 64) |
enum_mood | happy (Note: enum_mood was defined as 'sad','ok' or 'happy') | (VECTOR CHARACTER 64) |
See array-notes.html
It is important to understand how postgresql (not postmodern) handles timestamps and timestamps with time zones. Postgresql keeps everything in UTC, it does not store a timezone even in a timezone aware column. If you use a timestamp with timezone column, postgresql will calculate the UTC time and will normalize the timestamp data to UTC. When you later select the record, postgresql will look at the timezone for the postgresql session, retrieve the data and then provide the data recalculated from UTC to the timezone for that postgresql session. There is a good writeup of timezones at http://blog.untrod.com/2016/08/actually-understanding-timezones-in-postgresql.html and http://phili.pe/posts/timestamps-and-time-zones-in-postgresql/.
Without simple-date or local-time properly loaded, sample date and time data from postgresql will look like:
PG Type | Return Value | Lisp Type |
---|---|---|
date | #<DATE 16-05-2020> | DATE |
time_without_timezone | #<TIME-OF-DAY 09:47:09.926531> | TIME-OF-DAY |
time_with_timezone | 09:47:16.510459-04 | (VECTOR CHARACTER 64) |
timestamp_without_timezone | #<TIMESTAMP 16-05-2020T09:47:33,315> | TIMESTAMP |
timestamp_with_timezone | #<TIMESTAMP 16-05-2020T13:47:27,855> | TIMESTAMP |
The Simple-date add-on library (not enabled by default) provides types (CLOS classes) for dates, timestamps, and intervals similar to the ones SQL databases use, in order to be able to store and read these to and from a database in a straighforward way. A few obvious operations are defined on these types.
To use simple-date with cl-postgres or postmodern, load simple-date-cl-postgres-glue and register suitable SQL readers and writers for the associated database types.
(ql:quickload :simple-date/postgres-glue)
(setf cl-postgres:*sql-readtable*
(cl-postgres:copy-sql-readtable
simple-date-cl-postgres-glue:*simple-date-sql-readtable*))
With simple date loaded, the same data will look like this:
PG Type | Return Value | Lisp Type |
---|---|---|
date | #<DATE 16-05-2020> | DATE |
time_without_timezone | #<TIME-OF-DAY 09:47:09.926531> | TIME-OF-DAY |
time_with_timezone | 09:47:16.510459-04 | (VECTOR CHARACTER 64) |
timestamp_without_timezone | #<TIMESTAMP 16-05-2020T09:47:33,315> | TIMESTAMP |
timestamp_with_timezone | #<TIMESTAMP 16-05-2020T13:47:27,855> | TIMESTAMP |
To get back to the default cl-postgres reader:
(setf cl-postgres:*sql-readtable*
(cl-postgres:copy-sql-readtable
cl-postgres::*default-sql-readtable*))
However Simple-date has no concept of time zones. Many users use another library, local-time, which solves the same problem as simple-date, but does understand time zones.
For those who want to use local-time, to enable the local-time reader:
(ql:quickload :cl-postgres+local-time)
(local-time:set-local-time-cl-postgres-readers)
With that set postgresql time datatype returns look like: With local-time loaded and local-time:set-local-time-cl-postgres-readers run, the same sample data looks like:
PG Type | Return Value | Lisp Type |
---|---|---|
date | 2020-05-15T20:00:00.000000-04:00 | TIMESTAMP |
time_without_timezone | 2000-03-01T04:47:09.926531-05:00 | TIMESTAMP |
time_with_timezone | 09:47:16.510459-04 | (VECTOR CHARACTER 64) |
timestamp_without_timezone | 2020-05-16T05:47:33.315622-04:00 | TIMESTAMP |
timestamp_with_timezone | 2020-05-16T09:47:27.855146-04:00 | TIMESTAMP |
The Lisp code in Postmodern is theoretically portable across implementations, and seems to work on all major ones as well as some minor ones such as Genera. It is regularly tested on ccl, sbcl, ecl and cmucl. ABCL currently has issues with utf-8 and :null.
Please let us know if it does not work on the implementation that you normally use. Implementations that do not have meta-object protocol support will not have DAOs, but all other parts of the library should work (all widely used implementations do support this).
The library is not likely to work for PostgreSQL versions older than 8.4. Other features only work in newer Postgresql versions as the features were only introduced in those newer versions.
It is highly suggested that you do not use words that are reserved by Postgresql as identifiers (e.g. table names, columns). The reserved words are:
"all" "analyse" "analyze" "and" "any" "array" "as" "asc" "asymmetric" "authorization" "between" "binary" "both" "case" "cast" "check" "collate" "column" "concurrently" "constraint" "create" "cross" "current-catalog" "current-date" "current-role" "current-schema" "current-time" "current-timestamp" "current-user" "default" "deferrable" "desc" "distinct" "do" "else" "end" "except" "false" "fetch" "filter" "for" "foreign" "freeze" "from" "full" "grant" "group" "having" "ilike" "in" "initially" "inner" "intersect" "into" "is" "isnull" "join" "lateral" "leading" "left" "like" "limit" "localtime" "localtimestamp" "natural" "new" "not" "notnull" "nowait" "null" "off" "offset" "old" "on" "only" "or" "order" "outer" "overlaps" "placing" "primary" "references" "returning" "right" "select" "session-user" "share" "similar" "some" "symmetric" "table" "then" "to" "trailing" "true" "union" "unique" "user" "using" "variadic" "verbose" "when" "where" "window" "with"
Postmodern is under active development so issues and feature requests should be flagged on [[https://github.com/marijnh/Postmodern](Postmodern's site on github).
Some areas that are currently under consideration can be found in the ROADMAP.md file.
- Mailing List
- A collection of Postmodern examples
- The PostgreSQL manuals
- The wire protocol Postmodern uses
- Common Lisp Postgis library
- Local-time
Postmodern uses FiveAM for testing. The different component systems of Postmodern have tests defined in corresponding test systems, each defining a test suite. The test systems and corresponding top-level test suites are:
:postmodern
inpostmodern/tests
,:cl-postgres
incl-postgres/tests
,:s-sql
ins-sql/tests
, and:simple-date
insimple-date/tests
.
Before running the tests make sure PostgreSQL is running and a test database is created. By default tests use the following connection parameters to run the tests:
- Database name: test
- User: test
- Password:
- Hostname: localhost
- Port: 5432
- Use-SSL :NO
If connection with these parameters fails then you will be asked to
provide the connection parameters interactively. The parameters will
be stored in cl-postgres-tests:*test-connection*
variable and
automatically used on successive test runs. This variable can also be
set manually before running the tests.
To test a particular component one would first load the corresponding
test system, and then run the test suite. For example, to test the
postmodern
system in the REPL one would do the following:
(ql:quickload "postmodern/tests")
(5am:run! :postmodern)
;; ... test output ...
It is also possible to test multiple components at once by first loading test systems and then running all tests:
(ql:quickload '("cl-postgres/tests" "s-sql/tests"))
(5am:run-all-tests)
;; ... test output ...
To run the tests from command-line specify the same forms using your implementation's command-line syntax. For instance, to test all Postmodern components on SBCL, use the following command:
env DB_USER=$USER sbcl --noinform \
--eval '(ql:quickload "postmodern/tests")' \
--eval '(ql:quickload "cl-postgres/tests")' \
--eval '(ql:quickload "s-sql/tests")' \
--eval '(ql:quickload "simple-date/tests")' \
--eval '(progn (setq 5am:*print-names* nil) (5am:run-all-tests))' \
--eval '(sb-ext:exit)'
As you can see from above, database connection parameters can be provided using environment variables:
DB_NAME
: database name,DB_USER
: user,DB_PASS
: password,DB_HOST
: hostname.