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(check (+ 1 1) => 3)evaluates the expression
(+ 1 1)
and compares the result
with the expected result 3 provided after the syntactic
keyword =>
. Then the outcome of this comparison is reported
in human-readable form by printing a message of the form
(+ 1 1) => 2 ; *** failed *** ; expected result: 3Moreover, the outcome of any executed check is recorded in a global state counting the number of correct and failed checks and storing the first failed check. At the end of a file, or at any other point, the user can print a summary using
check-report
.
In addition to the simple test above, it is also possible to execute a parametric sequence of checks. Syntactically, this takes the form of an eager comprehension in the sense of SRFI 42 [5]. For example,
(check-ec (:range e 100) (:let x (expt 2.0 e)) (= (+ x 1) x) => #f (e x))This statement runs the variable
e
through {0..99} and
for each binding defines x
as (expt 2.0 e)
. Then it is
checked if (+ x 1)
is equal to x
, and it is expected that
this is not the case (i.e. expected value is #f
). The
trailing (e x)
tells the reporting mechanism to print
the values of both e
and x
in case of a failed check.
The output could look like this:
(let ((e 53) (x 9007199254740992.0)) (= (+ x 1) x)) => #t ; *** failed *** ; expected result: #fThe specification of bindings to report,
(e x)
in the
example, is optional but very informative.
Other features of this SRFI are:
equal?
).Although it is extremely straight-forward, the origin of the particular mechanism described here is the 'examples.scm' file accompanying the reference implementation of SRFI 42 [5]. The same mechanism has been reimplemented for the reference implementation of SRFI 67, and a simplified version is yet again found in the reference implementation of SRFI 77.
The mechanism in this SRFI does not replace more sophisticated approaches to unit testing, like SRFI 64 [1] or SchemeUnit [2]. These systems provide more control of the testing, separate the definition of a test, its execution, and its reports, and provide several other features.
Neil Van Dyke's Testeez library [3] is very close in spirit
to this SRFI. In Testeez, tests are disabled by (re-)defining a
macro. The advantage of this method is that the code for the
test cases can be removed entirely, and hence even the dependency
on the Testeez library. This SRFI on the other hand, uses a
Scheme conditional (COND
, IF
) to prevent execution of the
testing code. This method is more dynamic but retains dead
testing code, unless a compiler and a module system are used
to apply constant folding and dead code elimination. The only
major addition in SRFI over Testeez is the comprehension for
formulating parametric tests.
Design considerations for this SRFI include the following:
=>
" syntax is widely used and intuitive.
(check <expr> (=> <equal>) <expected>)
MACRO
(check <expr> => <expected>)
<expr>
and compares the value to the value
of <expected>
using the predicate <equal>
, which is
equal?
when omitted. Then a report is printed according
to the current mode setting (see below) and the outcome
is recorded in a global state to be used in check-report
.
The precise order of evaluation is that first <equal>
and <expected>
are evaluated (in unspecified order) and
then <expr>
is evaluated.(check (+ 1 1) => 2)
(check-ec <qualifier>
* <expr> (=> <equal>) <expected> (<argument>
*))
MACRO
(check-ec <qualifier>
* <expr> => <expected> (<argument>
*))
(check-ec <qualifier>
* <expr> (=> <equal>) <expected>)
(check-ec <qualifier>
* <expr> => <expected>)
Enumerates the sequence of bindings specified by <qualifier>
*.
For each binding evaluates <equal>
and <expected>
in unspecified
order. Then evalues <expr>
and compares the value obtained to the
value of <expected>
using the value of <equal>
as predicate, which
is equal?
when omitted.
The comprehension stops after the first failed check, if there
is any. Then a report is printed according to the current mode
setting (see below) and the outcome is recorded in a global state
to be used in check-report
. The entire check-ec
counts as a single
check.
In case the check fails <argument>
* is used for constructing an
informative message with the argument values. Use <argument>
* to
list the relevant free variables of <expr>
(see examples) that you
want to have printed.
A <qualifier>
is any qualifier of an eager comprehension as
specified in SRFI 42 [5].
Examples:
(check-ec (: e 100) (positive? (expt 2 e)) => #t (e)) ; fails on fixnums (check-ec (: e 100) (:let x (expt 2.0 e)) (= (+ x 1) x) => #f (x)) ; fails (check-ec (: x 10) (: y 10) (: z 10) (* x (+ y z)) => (+ (* x y) (* x z)) (x y z)) ; passes with 10^3 cases checked
(check-report)
PROCEDURE
(check-set-mode! mode)
PROCEDURE
'(off summary report-failed report)
, default is 'report
.
Note that you can change the mode at any time, and that check,
check-ec
and check-report
use the current value.
The mode symbols have the following meaning:
off
: do not execute any of the checks,
summary
: print only summary in (check-report)
and nothing else,
report-failed
: report failed checks when they happen, and in summary,
report
: report every example executed.
(check-reset!)
PROCEDURE
(check-passed? expected-total-count)
PROCEDURE
#t
if there were no failed checks and expected-total-count
correct checks, #f
otherwise.
Rationale: This procedure can be used in automatized
tests by terminating a test program with the statement
(exit (if (check-passed?
n) 0 1))
.
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The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
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