// file : doc/testscript.cli // copyright : Copyright (c) 2014-2016 Code Synthesis Ltd // license : MIT; see accompanying LICENSE file "\name=build2-testscript-language" "\subject=Testscript language" "\title=Testscript Language" // NOTES // // - Maximum
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// @@ Testscript vs testscript
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\h0#preface|Preface|

This document describes the \c{build2} Testscript language. It begins with an
introduction that first discusses the motivation behind having a separate
domain-specific language and then continues to introduce a number of
Testscript concept with examples. The remainder of the document provides a
more formal description of the language, including its integration into the
build system, lexical structure, compilation and execution model, as well as
grammar and semantics.

In this document we use the term \"Testscript\" (capitalized) to refer to the
Testscript language. Just \"testscript\" means some code written in this
language. For example: \"We can pass addition information to testscripts using
target-specific variables.\" Finally, \c{testscript} refers to the specific
file name.

We also use the equivalent distinction between \"Buildfile\" (language),
\"buildfile\" (code), and \c{buildfile} (file).

\h1#intro|Introduction|

Testscript is a domain-specific language for running tests. Traditionally, if
your testing requires varying input or analyzing output, you would use a
scripting language, for instance Bash. This has a number of drawbacks.
Firstly, this approach is usually not portable (there is no Bash on
Windows \i{out of the box}). It is also hard to write concise tests in a
general-purpose scripting language. The result is often a test suite that has
grown incomprehensible which is a major problem since now everyone dreads
adding new tests. Finally, it is hard to run such tests in parallel without a
major effort (for example, having a separate script for each test).

Testscript vaguely resembles Bash and is optimized for concise test
description by focusing on the following functionality:

\ul|

\li|Supplying input via command line and \c{stdin}.|

\li|Comparing to expected exit status.|

\li|Comparing to expected output for both \c{stdout} and \c{stderr}.|

\li|Setup/teardown commands and automatic file/directory cleanup.|

\li|Simple (single-command) and compound (multi-command) tests.|

\li|Test groups with common setup/teardown.|

\li|Test isolation for parallel execution.|

\li|Test documentation.||

Note that Testscript is a \i{test runner}, not a testing framework for a
particular programming language. It does not concern itself with how the test
executables themselves are implemented. As a result, it is mostly geared
towards functional testing but can also be used for unit testing if external
input/output is required. Testscript is an extension of the \c{build2} build
system and is implemented by its \c{test} module.

As an illustration, let's test a \"Hello, World\" program. For a simple
implementation the corresponding \c{buildfile} might look like this:

\
exe{hello}: cxx{hello}
\

We also assume that the project's \c{bootstrap.build} loads the \c{test}
module which implements the execution of the testscripts.

To start, we create an empty file called \c{testscript}. To indicate that a
testscript file tests a specific target we simply list it as a target's
prerequisite, for example:

\
exe{hello}: cxx{hello} test{testscript}
\

Let's assume our \c{hello} program expects us to pass the name to greet as
a command line argument. And if we don't pass anything, it prints usage and
terminates with a non-zero exit status. Let's test this by adding the
following line to the \c{testscript} file:

\
$* != 0
\

While it sure is concise, it may look cryptic without some explanation. When
the \c{test} module runs tests, it passes to each testscript the target path
of which this testscript is a prerequisite. So in our case the testscript will
receive the path to our \c{hello} executable. Also, the buildfile can pass
along additional options and arguments. And inside the testscript, all of this
(target path, options, and arguments) are bound to the \c{$*} variable. So in
our case, if we expand the above line, it will be something like this:

\
/tmp/hello/hello != 0
\

Or, if we are on Windows, something like this:

\
C:\projects\hello\hello.exe != 0
\

The remainder of the command (\c{!= 0}) is the exit status check. If we don't
specify it, then the test is expected to exit with zero status (which is
equivalent to specifying \c{== 0}).

If we run our test, it will pass provided our program behaves as expected.
One thing our test doesn't verify, however, is the usage that gets
printed. Let's fix that assuming this is the code that prints it:

\
cerr << \"usage: \" << argv[0] << \" \" << endl;
\

In testscripts you can compare output to the expected result for both
\c{stdout} and \c{stderr}. We can supply the expected result as either
\i{here-string} or \i{here-document}. The here-string approach works
best for short, single-line output and we will use it for another test
in a minute. For this test let's use here-document since the usage
line is somewhat long (not really, but play along):

\
$* 2>>EOE != 0
usage: $0 
EOE
\

Let's decrypt this: the \c{2>>EOE} is a here-document redirect with \c{2}
being the \c{stderr} file descriptor and \c{EOE} is the string we chose to
mark the end of here-document (stands for End-Of-Error). Next comes the
here-document fragment. In our case it has only one line but it could have
several. Note also that we can expand variables in here-document fragments.
You probably have guessed that \c{$0} expands to the target path. Finally,
we have the here-document end marker.

Now when executing this test the \c{test} module will check two things: it
will compare the \c{stderr} output to the expected result using the \c{diff}
tool and it will make sure the test exits with a non-zero status.

Now that we have tested the failure case, let's test the normal functionality.
While we could have used here-document, in this case here-string will be more
concise:

\
$* World >\"Hello, World!\"
\

It's also a good idea to document our tests. Testscript has a formalized test
description that can capture the test id, summary, and details. All three
components are optional and how thoroughly you document your tests is up to
you.

Description lines precede the test command, start with a colon (\c{:}), and
have the following layout:

\
: 
: 
:
: 
\ The recommended format for \c{} is \c{-...} with at least two keywords. The id is used in diagnostics as well as to run individual tests. The recommended style for \c{} is that of the \c{git(1)} commit summary. The detailed description is free-form. Here are some examples: \ # Only id. # : missing-name # Only summary. # : Test handling of missing name # Both id and summary. # : missing-name : Test handling of missing name # All three: id, summary, and a detailed description. # : missing-name : Test handling of missing name : : This test makes sure the program detects that the name to greet : was not specified on the command line and both prints usage and : exits with non-zero status. \ The recommended way to come up with an id is to distill the summary to its essential keywords by removing generic words like \"test\", \"handle\", and so on. If you do this, then both the id and summary will convey essentially the same information. As a result, to keep things concise, you may choose to drop the summary and only have the id. Either the id or summary (but not both) can alternatively be specified inline in the test command after a colon (\c{:}), for example: \ $* != 0 : missing-name \ Similar to handling output, Testscript provides a convenient way to supply input to test's \c{stdin}. Let's say our \c{hello} program recognizes the special \c{-} name as an instruction to read the names from \c{stdin}. This is how we could test this functionality: \ $* - <>EOO : stdin-names Jane John EOI Hello, Jane! Hello, John! EOO \ As you might have suspected, we can also use here-string to supply \c{stdin}, for example: \ $* - \"Hello, World!\" : stdin-name \ Let's say our \c{hello} program has a configuration file that captures custom name to greeting mappings. A path to this file can be passed as a second command line argument. To test this functionality we first need to create a sample configuration file. We do these kind of not-test actions with \i{setup} and \i{teardown} commands, for example: \ +cat <>>hello.conf; John = Howdy Jane = Good day EOI $* Jane hello.conf >\"Good day, Jane!\" : config-greet \ The setup commands start with the plus sign (\c{+}) while teardown \- with minus (\c{-}). Notice also the semicolon (\c{;}) at the end of the setup command: it indicates that the following command is part of the same test \- what we call a multi-command or \i{compound} test. Other than that it should all look familiar. You may be wondering why we don't have a teardown command that removes \c{hello.conf}? It is not necessary because this file will be automatically registered for automatic cleanup that will happen at the end of the test. We can also register our own files and directories for automatic cleanup. For example, if the \c{hello} program created the \c{hello.log} file on unsuccessful runs, then here is how we could have cleaned it up: \ $* &hello.log != 0 \ What if we wanted to run two tests for this configuration file functionality? For example, we may want to test the custom greeting as above but also make sure the default greeting is not affected. One way to do this would be to repeat the setup command in each test. But, as you can probably guess, there is a better way to do it: testscripts can define test groups. For example: \ : config { conf = hello.conf +cat <>>$conf John = Howdy Jane = Good day EOI $* John ../$conf >\"Howdy, John!\" : custom-greet $* Jack ../$conf >\"Hello, Jack!\" : default-greet } \ @@ Need to explain why ../ A test group is a scope that contains several test/setup/teardown commands. Variables set inside a scope (like our \c{conf}) are only in effect until the end of the scope. Plus, setup and teardown commands that are not part of any test (notice the lack of \c{;} after \c{+ cat}) are associated with the scope; their automatic cleanup only happens at the end of the scope (so our \c{hello.conf} will only be removed after all the tests in the group have completed). Note also that a scope can have a description. In particular, assigning a test group an id allows us to run tests only from this specific group. We can also use scopes for individual tests. For example, if we need to set a test-local variable: \ : config-greet { conf = hello.conf +cat <\"Jane = Good day\" >>>$conf; $* Jane $conf >\"Good day, Jane!\" } \ We can exclude sections of a testscript from execution using the \c{.if}, \c{.elif}, and \c{.else} directives. For example, we may need to omit a test if we are running on Windows (notice the last line with just the dot \- it marks the end of the \c{.if} body): \ .if ($cxx.target.class != windows) $* Jane /dev/null >\"Hello, Jane!\" : config-empty .end \ You may have noticed that in the above example we referenced the \c{cxx.target.class} variable as if we were in a buildfile. We could do that because the testscript variable lookup continues in the buildfile starting from the testscript target and continuing with the standard buildfile variable lookup. In particular, this means we can pass arbitrary information to testscripts using target-specific variables. For example, this how we can move the above platform test to \c{buildfile}: \ # buildfile exe{hello}: cxx{hello} test{testscript} test{*}: windows = ($cxx.target.class == windows) \ \ # testscript .if! $windows $* Jane /dev/null >\"Hello, Jane!\" : config-empty .end \ To conclude, let's put all our tests together so that we can have a complete picure: \ $* != 0 : missing-name $* World >\"Hello, World!\" : command-name $* - <>EOO : stdin-names Jane John EOI Hello, Jane! Hello, John! EOO : config { conf = hello.conf +cat <>>$conf John = Howdy Jane = Good day EOI $* John ../$conf >\"Howdy, John!\" : custom-greet $* Jack ../$conf >\"Hello, Jack!\" : default-greet .if! $windows $* Jane /dev/null >\"Hello, Jane!\" : config-empty .end } \ @@ Add test.redirects? @@ Maybe allow variables in-between test lines (;)? Will have to recognize semicolon in variable value. @@ Maybe $~ for test temp directory. @@ temp directory structure (why ../)? @@ how to run individual tests/groups? @@ how to preserve test output @@ term: 'test working directory' \h1#integration|Build System Integration| The \c{build2} \c{test} module provides the ability to run an executable target as a test, optionally passing options and arguments, providing \c{stdin} input, as well as comparing the \c{stdout} output to the expected result. For example: \ exe{xml-parser}: test.options = --strict exe{xml-parser}: test.input = test.xml exe{xml-parser}: test.output = test.out \ This works well for simple, single-run tests. In contrast the testscript approach allows you to perform multiple test runs of potentially multi-command (compound) tests that can perform setup/teardown actions. It also provides concise mechanisms for commonly used test steps such as supplying input as well as comparing output and exit status. The integration of testscripts into buildfiles is done using the standard \i{target-prerequisite} mechanism. In this sense, a testscript is a prerequisite that describes how to test the target similar to how, for example, the \c{INSTALL} file describes how to install it. For example: \ exe{xml-parser}: test{testscript} doc{INSTALL README} \ By convention the testscript file should be either called \c{testscript} if you only have one or have the \c{.test} extension, for example, \c{basics.test}. The \c{test} modules registers the \c{test{\}} target type for testscript files. A testscript prerequisite can be specified for any target. For example, if our directory contains a bunch of shell scripts that we want to test together, then it makes sense to specify the testscript prerequisite for the directory target: \ ./: test{basics} \ During variable lookup if a variable is not found in a testscript, then its search continues in the buildfile starting from the testscript target. This means a testscript can \"see\" all the existing buildfile variables and we can use target-specific variables to pass additional information, for example: \ # testscript .if ($cxx.target.class == windows) foo = $bar \ \ # buildfile test{testscript}@./: bar = baz \ Additionally, a number of \c{test.*} variables are reused to pass specific information to testscripts. Unless set manually as a testscript target-specific variable, the \c{test} variable is automatically set to the target path being tested. For example, given this \c{buildfile}: \ exe{xml-parser}: test{testscript} \ The value of \c{test} inside the testscript will be the absolute path to the \c{xml-parser} executable. The other two special variables are \c{test.options} and \c{test.arguments}. You can use them to pass additional options/arguments to your test scripts and together with \c{test} they form the test target command line which is bound to a number of read-only variable aliases: \ $* - the complete {$test $test.options $test.arguments} command line $0 - $test $N - (N-1)-th element in the {$test.options $test.arguments} array \ Note that these aliases are read-only; if you need to modify any of the values then you should use the original variable names, for example: \ test.options += --strict $* <\"not xml\" != 0 \ A testscript would normally contain multiple tests and sometimes it is desirable to only run a specific test or a group of tests. For example, you may be debugging a failing tests and would like to re-run it. Each test and test group in a testscript has an id. As a result each test has an \i{id path} that uniquely identifies it. The id path starts with the testscript file name (corresponds to the id of the implied outermost test group, as described below), may include a number of intermediate test group ids, and ends with the test id. The ids in a path are separated with a forward slash (\c{/}). Note that this also happens to be the filesystem path to the temporary directory where the test is executed (again, as discussed below). As an example, consider the following testscript file called \c{basics.test}: \ $* foo ; foo : fox {{ $* fox bar ; bar $* fox baz ; baz }} \ The id paths for the three test will then be: \ basics/foo basics/fox/bar basics/fox/baz \ To only run individual tests, test groups, or testscript files we can specify their id paths in the \c{config.test} variable, for example: \ $ b test config.test=basics # Run all tests in basics.test. $ b test config.test=basics/fox # Run bar and baz. $ b test config.test=basics/foo # Run foo. $ b test \"config.test=basics/foo basics/fox/bar\" # Run fox and bar. \ \h1#lexical|Lexical Structure| Testscript is a line-oriented language with a context-dependent lexical structure. It \"borrows\" several building blocks (for example, variable expansion) from the Buildfile language. In a sense, testscripts are specialized (for testing) continuations of buildfiles. Except in here-document fragments, leading whitespaces and blank lines are ignored except for the line/column counts. A non-empty testscript must end with a newline. The backslash (\c{\\}) character followed by a newline signals the line continuation. Both this character and the newline are removed (note: not replaced with a whitespace) and the following line is read as if it was part of the first line. Note that \c{'\\'} followed by EOF is invalid. For example: \ $* foo | \ $* bar \ An unquoted and unescaped \c{'#'} character starts a comments; everything from this character until the end of line is ignored. For example: \ # Setup foo. $* foo $* bar # Setup bar. \ Note that there is no line continuation in comments; the trailing \c{'\\'} is ignored except in one case: if the comment is just \c{'#\\'} followed by the newline, then it starts a multi-line comment that spans until the closing \c{'#\\'} comment is encountered. For example: \ #\ $* foo $* bar #\ \ Similar to Buildfile, the Testscript language supports two types of quoting: single (\c{'}) and double (\c{\"}). Both can span multiple lines. The single-quoted string does not recognize any escape sequences (not even for the single quote itself or line continuations) with all the characters taken literally until the closing single quote is encountered. The double-quoted string recognizes escape sequences (including line continuations) as well as expansions of variables and evaluations of contexts. For example: \ foo = FOO bar = \"$foo ($foo == FOO)\" # 'FOO true' \ Characters that have special syntactic meaning (for example \c{'$'}) can be escaped with a backslash (\c{\\}) to preserve their literal meaning (to specify literal backslash you need to escape it as well). For example: \ foo = \$foo\\bar # '$foo\bar' \ Note that quoting could often be a more readable way to achieve the same result, for example: \ foo = '$foo\bar' \ Inside double-quoted strings only the \c{\"\\$(} character set needs to be escaped. A character is said to be \i{unquoted} and \i{unescaped} if it is not escaped and is not part of a quoted string. A token is said to be unquoted and unescaped if all its characters are unquoted and unescaped. The lexical structure of the remainder of a line (that is, the \i{context}) is determined by the leading (unquoted and unescaped) character after ignoring any (unquoted and unescaped) leading whitespaces. The following characters are context-introducing. \ ':' - description line '.' - directive line '{' - block start '}' - block end '+' - setup command line '-' - teardown command line \ For the here-document lines the context is implied by the preceding line. If none of the above determinants apply, then the line is either a variable assignment or a test command line. Distinguishing between the two is performed during parsing and is described below. \h1#grammar|Grammar and Semantics| \h#grammar-notation|Notation| The formal grammar of the Testscript language is specified using an EBNF-like notation with the following elements: \ foo: ... - production rule foo - non-terminal - terminal 'foo' - literal foo* - zero or more multiplier foo+ - one or more multiplier foo? - zero or one multiplier foo bar - concatenation (foo then bar) foo | bar - alternation (foo or bar) (foo bar) - grouping {foo bar} - concatenation in any order (foo then bar or bar then foo) foo \ bar - line continuation # foo - comment \ Rule right-hand-sides that start on a new line describe the line-level syntax and ones that start on the same line describes the syntax inside the line. If a multiplier appears in from on the line then it specifies the number of repetitions for the whole line. For example, from the following three rules, the first describes a single line of multiple literals (such as \c{'foofoofoo'}), the second \- multiple lines of a single literal (such as \c{'foo\\nfoo\\nfoo'}), and the third \- multiple lines of multiple literals (such as \c{'foo\\nfoofoo\\nfoofoofoo'}). \ text-line: 'foo'+ text-lines: +'foo' text-lines: +('foo'+) \ A newline in the grammar matches any standard newline separator sequence (CR/LF combinations). An unquoted space in the grammar matches zero or more non-newline whitespaces (spaces and tabs). A quoted space matches exactly one non-newline whitespace. Note also that in some cases components within lines may not be whitespace-separated in which case they will be written without any spaces between them, for example: \ foo: 'foo' ';' # \"foo;\" or \"foo ;\" or \"foo ;\" bar: 'bar'';' # \"bar;\" baz: 'baz'' '+';' # \"baz ;\" or \"baz ;\" fox: bar''bar # \"bar;bar;\" \ You may also notice that several production rules below end with \c{-line} while potentially spanning several physical lines. In such cases they represent \i{logical lines}, for example, a test, its description, and its here-document fragments. \h#grammar-all|Grammar| @@ Move directives last? \ script: scope-body scope-body: *setup *(scope|test) *teardown setup: variable-line|setup-line teardown: variable-line|teardown-line scope: description? '{' scope-body '}' test: description? *((variable-line|test-line) ';') test-line (':' )? description: +(':' ) variable-line: ('='|'+='|'=+') value-attributes? value-attributes: '[' ']' setup-line: '+' command teardown-line: '-' command test-line: command command: (' '+(|redirect|cleanup))* command-exit? *here-document redirect: stdin|stdout|stderr stdin: '0'?(in-redirect) stdout: '1'?(out-redirect) stderr: '2'(out-redirect) in-redirect: '<-'|\ '<+'|\ ('<'|'<:') |\ ('<<'|'<<:') |\ '<<<' out-redirect: '>-'|\ '>+'|\ '>&' ('1'|'2')|\ ('>'|'>:') |\ ('>>'|'>>:') |\ ('>>>'|'>>>&') cleanup: ('&'|'&!'|'&?') (|) command-exit: ('=='|'!=') here-document: * \ Note that file descriptors must not be separated from the redirect operators with whitespaces. And if leading text is not separated from the redirect operators, then it is expected to be a file descriptor. As an example, the first command below has \c{2} as an argument and redirects \c{stdout}, not \c{stderr}. While the second is invalid since \c{a1} is not a valid file descriptor. \ $* 2 >! $* a1>! \ In merge redirects the left-hand-side descriptor (implied or explicit) must not be the same as the right-hand-side. Having both merge redirects at the same time is illegal. Here-line is like double-quoted string but recognizes newlines. It is an error to specify both normal (better term?) and inline descriptions for a test. \ script: (script-scope|script-line)* script-scope: description-line? '{' script '}' script-line: directive-line|variable-line|test-line|setup-line|teardown-line description-line: ':' (':' )* directive-line: include|if-else include: '.include'( )+ if-else: ('.if'|'.if!') script elif* else? '.end' elif: ('.elif'|'.elif!') script else: '.else' script variable-line: ('='|'+='|'=+') value-attributes? value-attributes: '[' ']' test-line: description-line? command-expr command-exit? (';'|(':' ))? here-document* command-exit: ('=='|'!=') setup-line: '+' command-expr ';'? here-document* teardown-line: '-' command-expr ';'? here-document* command-expr: command-pipe (('||'|'&&') command-pipe)* command-pipe: command ('|' command)* command: (' '+ )* {stdin? stdout? stderr? cleanup*} stdin: ('|\ '<<' |\ '<<<' ) stdout: ('>!'|\ '>?'|\ '>&' '2'|\ '>' |\ '>>' |\ ('>>>'|'>>>&') ) stderr: '2' ('>!'|\ '>?'|\ '>&' '1' |\ '>' |\ '>>' |\ ('>>>'|'>>>&') ) cleanup: '&' (|) here-document: * \ \h#grammar-script|Script| \ script: (script-scope | script-line)* \ A testscript file is a sequence of scopes and (logical) lines. \h#grammar-scope|Scope| \ script-scope: description-line? '{' script '}' \ A block establishes a nested variable scope and a cleanup context. Any variables set within the block will only have effect until the end of the block. All registered cleanups are triggered at the end of the block. Additionally, entering a block triggers the creation of a nested temporary directory with the test/group id (see below) as its name. This directory then becomes the current working directory (\c{CWD}). Unless instructed otherwise, this temporary directory is removed at the end of the block and the previous \c{CWD} value is restored. (@@ Should we expect it to be empty, i.e., no unexpected output from the test?). Test and test group blocks have the same semantics except that in a test block each test line is considered to be part of the same test while in the test group each test line is treated as an individual test. Individual test lines in a group are treated \i{as if} they were in a test block consisting of just that line. In particular, this means that a nested temporary directory is also created for such individual tests and cleanup happens immediately after executing the test line. While test group blocks can contain other test group and test blocks, test blocks cannot contain nested blocks of any kind. A testscript execution starts in \c{out_base} as \c{CWD} and \i{as if} in an implicit test group block with the testscript file name (without the extension) as this group's id. For example, consider the following testscript file which we assume is called \c{basics.test}: \ : group1 {{ foo = bar + setup1 + setup2 &out-setup2 test1 &out-test1 ; test1 : test2 { bar = baz test2a $baz &out-test2 test2b (': ')* \ Description lines start with a colon (\c{:}) and are used to document tests (either single-line or compound) as well as test groups. In a sense, they are formalized comments. By convention the description has the following format with all three components being optional. \ : : : :
\ If the first line in the description does not contain any whitespaces, then it is assumed to be the test or test group id. If the next line is followed by a blank line, then it is assume to be the test or test group summary. After the blank line come optional details which are free-form. If an id is not specified then it is automatically derived from the test or test group location. If the test or test group is contained directly in the top-level testscript file, then just its start line number is used as an id. Otherwise, if the test or test group reside in an included file, then the start line number is prefixed with that file name (without the extension) in the form \c{-}. The start line for a block (either test or group) is the line containing opening curly brace (\c{{}) and for a simple test \- the test line itself. \h#grammar-directives|Directives| \ directive-line: include if-else \ All directive lines start with a leading dot (\c{.}). To specify a non-directive line that starts with a dot you can either escape or quote it, for example: \ \.include '.include' \ \h2#grammar-directives-include|\c{.include}| \ include: '.include' ( )+ \ The \c{include} directive includes one or more testscript files into another. If the specified path is not absolute, then it is interpreted as being relative to the including file. The semantics of inclusion is \i{as if} the contents of the included file appeared directly in the including file except for deriving test/group ids and displaying locations in diagnostics. The reminder of the line after the \c{'.include'} word is expanded as a Buildfile variable value. \h2#grammar-directives-if-else|\c{.if} \c{.else}| \ if-else: ('.if' | '.if!') script elif* else? '.end' elif: ('.elif' | '.elif!') script else: '.else' script \ The \c{if-else} directives allow for conditional exclusion of testscript fragments. The body of the \c{if-else} directive can be either a single (logical) line, a single block, or multiple lines/blocks. For example: \ .if ($foo == FOO) bar = BAR .if ($cxx.target.class != windows) $* foo .if ($cxx.target.class != windows) { $* foo $* bar } .if ($foo == FOO) .{ $* foo bar = BAR baz = BAZ { $* $bar $* $baz } .} \ Note that \c{if-else} operates on logical lines/blocks, for example: \ .if ($foo == FOO) : foo-bar : Test foo bar combination $* foo bar >>EOO foo bar EOO .if ($foo == FOO) : foo-bar : Test foo bar combination : foo-bar { $* foo $* bar } \ The reminder of the line after the \c{'.if'} and \c{'.elif'} words is expanded as a Buildfile variable value and should evaluate to either \c{'true'} or \c{'false'} text literals. \h#grammar-variable|Variable Assignment| \ variable-line: ('=' | '+=' | '=+') value-attributes? value-attributes: '[' ']' \ The Testscript variable assignment semantics is equivalent to Buildfile except that \c{} is expanded as \"strings\", not \"names\" (@@ clarify) and the default value type is \c{strings}. Note that unlike Buildfile no variable attributes are supported. \h#grammar-test|Test| \ test-line: description-line? command-expr command-exit? (';' | ':' )? here-document* command-exit: ('==' | '!=') \ The test command line can specify an optional exist status check. If omitted, then the test is expected to succeed (0 exit status). Variable expansion and context evaluation is performed (using chunked parsing) in \c{command-expr} and \c{command-exit} but not in the inline test description. \h#grammar-setup-teardown|Setup/Teardown| \ setup-line: '+' command-expr ';'? here-document* teardown-line: '-' command-expr ';'? here-document* \ The setup and teardown command lines are similar to the test command line except that they cannot have a test description or exit status check (they are always expected to succeed). The main motivation for distinguishing between test and setup/teardown commands is the ability to ignore the teardown commands in order to preserve the setup of test. For example, of a failed test that you are debugging. Also, the setup/teardown and test commands are shown at different verbosity levels (\c{3/-V} and \c{2/-v} respectively). Setup and teardown commands associeted with the test group are executed sequenctially in the order specified. \h#grammar-command-expr|Command Expression| \ command-expr: command-pipe (('||' | '&&') command-pipe)* \ Multiple commands can be combination with AND and OR operators. Note that the evaluation order is always from left to right (left-associative) and both operators have the same precedence and are short-circuiting. Note, however, that short-circuiting does not apply to variable expansion. The result of the expression is the exit status of the last \c{command-pipe} executed. \h#grammar-command-pipe|Command Pipe| \ command-pipe: command ('|' command)* \ Commands can also be combined with a pipe. All the piped commands except that last are expected to succeed with the last command's exit status being the result of \c{command-pipe}. \h#grammar-command|Command| \ command: * {stdin? stdout? stderr? merge? cleanup*} \ A command starts with a command path following by options and arguments, if any. We can also redirect/merge standard streams as well as register for automatic cleanup files and directories that may be created by the command. Note that redirects, merge, and cleanups can appear in any order but must come after the arguments. \h#grammar-redirect-merge-cleanup|Redirect, Merge, Cleanup| \ stdin: '0'?('<' | '<<' | '<<<' | '' | '>>' | '>>>''&'? | '>!' | '>?') stderr: '2'('>' | '>>' | '>>>''&'? | '>!' | '>?') merge: '1>&2' | '2>&1' cleanup: '&'( | ) \ The \c{stdin} stream data can come from a pipe, string, the here-document fragment, file, or \c{/dev/null} (\c{>>&}), or \c{/dev/null} (\c{>!}). It can also be compared to a string or the here-document fragment. For \c{stdout} specifying both pipe and redirect is an error. If no explicit \c{stderr} redirect is specified and the test is expected to fail (non-zero exit status), then an implicit \c{2>!} redirect is assumed. If no \c{stdout} or \c{stderr} redirect is specified and the test tries to write any data to either stream, it is considered to have failed. If you need to allow writing to the default \c{stdout} or \c{stderr}, specify \c{>?} and \c{2>?}, respectively. We can also merge \c{stderr} to \c{stdout} (\c{2>&1}) or vice versa (\c{1>&2}). If a command creates extra files or directories then we can register them for automatic cleanup at the end of the test. Files mentioned in redirects are registered automatically. Note that unlike shell no whitespaces around \c{<} and \c{>} redirects or after the \c{&} cleanups are allowed. A here-document redirect must be specified \i{literally} on test command line. Specifically, it must not be the result of a variable expansion or context evaluation, which rarely makes sense anyway since the following here-document fragment itself cannot be the result of the expansion/evaluation either; in a sense they both are part of the syntax. This requirement is imposed in order to be able to skip test lines and their associated here-document fragments in the \c{if-else} directives without performing any expansions/evaluations (which may not be valid). The skipping procedure for a line that is either a variable assignment or a test command is as follows: The line is lexed until the newline or EOF which checking each token either for one of the variable assignment operators or here-document redirects. If both kinds are present then this is an ambiguity error which can be resolved by quoting either of the token, depending on the desired semantics (variable assignment or test command). Otherwise, all the here-document redirects are noted and the corresponding number of here-document fragments is skipped (which \c{here-end} match/order validation). Note also that this procedure is applied even in case of \c{if-else} with \c{directive-block} since the block end (\c{.\}}) may appears literally in one of the here-document fragments. \h#grammar-here-document|Here-Document| \ here-document: * \ The here-document fragments can be used to supply data to \c{stdin} or to compare output to the expected result for \c{stdout} and \c{stderr}. Note that the order of here-document fragments must match the order of redirects, for example: \ : select-no-table-error $* --interactive >>EOO <>EOE enter query: EOO SELECT * FROM no_such_table EOI error: no such table 'no_such_table' EOE \ The lines in here-document are expanded as if they were double-quoted except that the double quote itself is not treated as special. This means we can use variables and evaluation contexts in here-documents but have to escape the \c{\\$(} character set. If the preceding command line starts with leading whitespaces, then the equivalent number is stripped (if present) from each here-document line (including the end marker). For example, the following two testscript fragments are equivalent: \ { $* <