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This can now be achieved with the new `recipe` directive:
recipe <language> <file>
Note that similar to the use of if-else and switch directives with recipes,
this directive requires explicit % recipe header. For example, instead of:
file{foo.output}:
{{
echo 'hello' >$path($>)
}}
We can now write:
file{foo.output}:
%
recipe buildscript hello.buildscript
With hello.buildscript containing:
echo 'hello' >$path($>)
Similarly, for C++ recipes (this time for a pattern), instead of:
[rule_name=hello] file{~'/(.+)\.output/'}:
% update clean
{{ c++ 1 --
--
...
}}
We can now write:
[rule_name=hello] file{~'/(.+)\.output/'}:
% update clean
recipe c++ hello.cxx
With hello.cxx containing:
// c++ 1 --
--
...
Relative <file> paths are resolved using the buildfile directory that contains
the `recipe` directive as a base.
Note also that this mechanism can be used in exported buildfiles with recipe
files placed into build/export/ together with buildfiles.
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Feels like this is an equivalent context to subscript/iteration.
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This in fact feels more natural in the "for consumption" model and also helps
with the nested subscript semantics.
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New types:
json
json_array
json_object
New functions:
$json.value_type(<json>)
$json.value_size(<json>)
$json.member_{name,value}(<json-member>)
$json.object_names(<json-object>)
$json.array_size(<json-array>)
$json.array_find(<json-array>, <json>)
$json.array_find_index(<json-array>, <json>)
$json.load(<path>)
$json.parse(<text>)
$json.serialize(<json>[, <indentation>])
For example, to load a JSON value from a file:
j = $json.load($src_base/board.json)
Or to construct it in a buildfile:
j = [json] one@1 two@([json] 2 3 4) three@([json] x@1 y@-1)
This can also be done incrementally with append/prepend:
j = [json_object]
j += one@1
j += two@([json] 2 3 4)
j += three@([json] x@1 y@-1)
Instead of using this JSON-like syntax, one can also specify valid JSON
input text:
j = [json] '{"one":1, "two":[2, 3, 4], "three":{"x":1, "y":-1}'
Besides the above set of functions, other handy ways to access components
in a JSON value are iteration and subscript. For example:
for m: $j
print $member_name($m) $member_value($m)
print ($j[three])
A subscript can be nested:
print ($j[two][1])
print ($j[three][x])
While a JSON value can be printed directly like any other value, the
representation will not be pretty-printed. As a result, for complex
JSON values, printing a serialized representation might be a more
readable option:
info $serialize($j)
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Several tests (other than the expected symexport) are still failing due to
what looks like Windows-specific bugs in the compiler.
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close stderr on exit
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Specifically:
1. In the double-quoted strings we now only do effective escaping of the
special `$("\` characters plus `)` for symmetry.
2. There is now support for "escape sequence expansion" in the form $\X where
\X can be any of the C/C++ simple escape sequences (\n, \t, etc) plus \0
(which in C/C++ is an octal escape sequence). For example:
info "foo$\n$\tbar$\n$\tbaz"
Will print:
buildfile:1:1: info: foo
bar
baz
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Specifically, do not reduce typed RHS empty simple values for prepend/append
and additionally for assignment provided LHS is typed and is a container.
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This is relied upon by the parser to provide conversion/concatenation
semantics consistent with untyped values. Note that we handle NULL values
only for types that have empty representation.
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There are three options here: we can "fall through" to an outer scope (there
is always the global scope backstop; this is the old semantics, sort of), we
can return NULL straight away, or we can fail. It feels like in most cases
unknown scope or target is a mistake and doing anything other than failing is
just making things harder to debug.
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Also fix simple test redirecting diff's stdout to stderr.
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In particular, we now always print error message on non-0 exit except
in cases where such exit is ignored.
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x [...], for x [...])
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in script
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Now unqualified variables are project-private and can be typified.
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The $find() function returns true if the sequence contains the specified
value. The $find_index() function returns the index of the first element
in the sequence that is equal to the specified value or $size(<sequence>)
if none is found. For string sequences, it's possible to request case-
insensitive comparison with a flag.
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functions
$is_a() returns true if the <name>'s target type is-a <target-type>. Note
that this is a dynamic type check that takes into account target type
inheritance.
$filter[_out]() return names with target types which are-a (filter) or
not are-a (filter_out) one of <target-types>.
In particular, these functions are useful for filtering prerequisite
targets ($<) in ad hoc recipes and rules.
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It returns the list of uint64 integers starting from <begin> (including)
to <end> (excluding) with the specified <step> or 1 if unspecified. For
example:
hdr = foo.hxx bar.hxx baz.hxx
src = foo.cxx bar.cxx baz.cxx
assert ($size($hdr) == $size($src)) "hdr and src expected to be parallel"
for i: $integer_sequence(0, $size($hdr))
{
h = ($hdr[$i])
s = ($src[$i])
...
}
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