Richard Levitte f5a46ed7fe Modify the ERR init functions to use the internal ERR string loaders | 4 лет назад | |
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The unified scheme takes all its data from the build.info
files seen
throughout the source tree. These files hold the minimum information
needed to build end product files from diverse sources. See the
section on build.info
files below.
From the information in build.info
files, Configure
builds up an
information database as a hash table called %unified_info
, which is
stored in configdata.pm, found at the top of the build tree (which may
or may not be the same as the source tree).
Configurations/common.tmpl
uses the data from %unified_info
to
generate the rules for building end product files as well as
intermediary files with the help of a few functions found in the
build-file templates. See the section on build-file templates further
down for more information.
As mentioned earlier, build.info
files are meant to hold the minimum
information needed to build output files, and therefore only (with a
few possible exceptions [1]) have information about end products (such
as scripts, library files and programs) and source files (such as C
files, C header files, assembler files, etc). Intermediate files such
as object files are rarely directly referred to in build.info
files (and
when they are, it's always with the file name extension .o
), they are
inferred by Configure
. By the same rule of minimalism, end product
file name extensions (such as .so
, .a
, .exe
, etc) are never mentioned
in build.info
. Their file name extensions will be inferred by the
build-file templates, adapted for the platform they are meant for (see
sections on %unified_info
and build-file templates further down).
The variables PROGRAMS
, LIBS
, MODULES
and SCRIPTS
are used to declare
end products. There are variants for them with _NO_INST
as suffix
(PROGRAM_NO_INST
etc) to specify end products that shouldn't get installed.
The variables SOURCE
, DEPEND
, INCLUDE
and DEFINE
are indexed by a
produced file, and their values are the source used to produce that
particular produced file, extra dependencies, include directories
needed, or C macros to be defined.
All their values in all the build.info
throughout the source tree are
collected together and form a set of programs, libraries, modules and
scripts to be produced, source files, dependencies, etc etc etc.
Let's have a pretend example, a very limited contraption of OpenSSL,
composed of the program apps/openssl
, the libraries libssl
and
libcrypto
, an module engines/ossltest
and their sources and
dependencies.
# build.info
LIBS=libcrypto libssl
INCLUDE[libcrypto]=include
INCLUDE[libssl]=include
DEPEND[libssl]=libcrypto
This is the top directory build.info
file, and it tells us that two
libraries are to be built, the include directory include/
shall be
used throughout when building anything that will end up in each
library, and that the library libssl
depend on the library
libcrypto
to function properly.
# apps/build.info
PROGRAMS=openssl
SOURCE[openssl]=openssl.c
INCLUDE[openssl]=.. ../include
DEPEND[openssl]=../libssl
This is the build.info
file in apps/
, one may notice that all file
paths mentioned are relative to the directory the build.info
file is
located in. This one tells us that there's a program to be built
called apps/openss
(the file name extension will depend on the
platform and is therefore not mentioned in the build.info
file). It's
built from one source file, apps/openssl.c
, and building it requires
the use of .
and include/
include directories (both are declared
from the point of view of the apps/
directory), and that the program
depends on the library libssl
to function properly.
# crypto/build.info
LIBS=../libcrypto
SOURCE[../libcrypto]=aes.c evp.c cversion.c
DEPEND[cversion.o]=buildinf.h
GENERATE[buildinf.h]=../util/mkbuildinf.pl "$(CC) $(CFLAGS)" "$(PLATFORM)"
DEPEND[buildinf.h]=../Makefile
DEPEND[../util/mkbuildinf.pl]=../util/Foo.pm
This is the build.info
file in crypto/
, and it tells us a little more
about what's needed to produce libcrypto
. LIBS is used again to
declare that libcrypto
is to be produced. This declaration is
really unnecessary as it's already mentioned in the top build.info
file, but can make the info file easier to understand. This is to
show that duplicate information isn't an issue.
This build.info
file informs us that libcrypto
is built from a few
source files, crypto/aes.c
, crypto/evp.c
and crypto/cversion.c
.
It also shows us that building the object file inferred from
crypto/cversion.c
depends on crypto/buildinf.h
. Finally, it
also shows the possibility to declare how some files are generated
using some script, in this case a perl script, and how such scripts
can be declared to depend on other files, in this case a perl module.
Two things are worth an extra note:
DEPEND[cversion.o]
mentions an object file. DEPEND indexes is the
only location where it's valid to mention them
# ssl/build.info
LIBS=../libssl
SOURCE[../libssl]=tls.c
This is the build.info file in ssl/
, and it tells us that the
library libssl
is built from the source file ssl/tls.c
.
# engines/build.info
MODULES=dasync
SOURCE[dasync]=e_dasync.c
DEPEND[dasync]=../libcrypto
INCLUDE[dasync]=../include
MODULES_NO_INST=ossltest
SOURCE[ossltest]=e_ossltest.c
DEPEND[ossltest]=../libcrypto.a
INCLUDE[ossltest]=../include
This is the build.info
file in engines/
, telling us that two modules
called engines/dasync
and engines/ossltest
shall be built, that
dasync
's source is engines/e_dasync.c
and ossltest
's source is
engines/e_ossltest.c
and that the include directory include/
may
be used when building anything that will be part of these modules.
Also, both modules depend on the library libcrypto
to function
properly. ossltest
is explicitly linked with the static variant of
the library libcrypto
. Finally, only dasync
is being installed, as
ossltest
is only for internal testing.
When Configure
digests these build.info
files, the accumulated
information comes down to this:
LIBS=libcrypto libssl
SOURCE[libcrypto]=crypto/aes.c crypto/evp.c crypto/cversion.c
DEPEND[crypto/cversion.o]=crypto/buildinf.h
INCLUDE[libcrypto]=include
SOURCE[libssl]=ssl/tls.c
INCLUDE[libssl]=include
DEPEND[libssl]=libcrypto
PROGRAMS=apps/openssl
SOURCE[apps/openssl]=apps/openssl.c
INCLUDE[apps/openssl]=. include
DEPEND[apps/openssl]=libssl
MODULES=engines/dasync
SOURCE[engines/dasync]=engines/e_dasync.c
DEPEND[engines/dasync]=libcrypto
INCLUDE[engines/dasync]=include
MODULES_NO_INST=engines/ossltest
SOURCE[engines/ossltest]=engines/e_ossltest.c
DEPEND[engines/ossltest]=libcrypto.a
INCLUDE[engines/ossltest]=include
GENERATE[crypto/buildinf.h]=util/mkbuildinf.pl "$(CC) $(CFLAGS)" "$(PLATFORM)"
DEPEND[crypto/buildinf.h]=Makefile
DEPEND[util/mkbuildinf.pl]=util/Foo.pm
A few notes worth mentioning:
LIBS
may be used to declare routine libraries only.
PROGRAMS
may be used to declare programs only.
MODULES
may be used to declare modules only.
The indexes for SOURCE
must only be end product files, such as
libraries, programs or modules. The values of SOURCE
variables must
only be source files (possibly generated).
INCLUDE
and DEPEND
shows a relationship between different files
(usually produced files) or between files and directories, such as a
program depending on a library, or between an object file and some
extra source file.
When Configure
processes the build.info
files, it will take it as
truth without question, and will therefore perform very few checks.
If the build tree is separate from the source tree, it will assume
that all built files and up in the build directory and that all source
files are to be found in the source tree, if they can be found there.
Configure
will assume that source files that can't be found in the
source tree (such as crypto/bildinf.h
in the example above) are
generated and will be found in the build tree.
%unified_info
databaseThe information in all the build.info
get digested by Configure
and
collected into the %unified_info
database, divided into the following
indexes:
depends => a hash table containing 'file' => [ 'dependency' ... ]
pairs. These are directly inferred from the DEPEND
variables in build.info files.
modules => a list of modules. These are directly inferred from
the MODULES variable in build.info files.
generate => a hash table containing 'file' => [ 'generator' ... ]
pairs. These are directly inferred from the GENERATE
variables in build.info files.
includes => a hash table containing 'file' => [ 'include' ... ]
pairs. These are directly inferred from the INCLUDE
variables in build.info files.
install => a hash table containing 'type' => [ 'file' ... ] pairs.
The types are 'programs', 'libraries', 'modules' and
'scripts', and the array of files list the files of
that type that should be installed.
libraries => a list of libraries. These are directly inferred from
the LIBS variable in build.info files.
programs => a list of programs. These are directly inferred from
the PROGRAMS variable in build.info files.
scripts => a list of scripts. There are directly inferred from
the SCRIPTS variable in build.info files.
sources => a hash table containing 'file' => [ 'sourcefile' ... ]
pairs. These are indirectly inferred from the SOURCE
variables in build.info files. Object files are
mentioned in this hash table, with source files from
SOURCE variables, and AS source files for programs and
libraries.
shared_sources =>
a hash table just like 'sources', but only as source
files (object files) for building shared libraries.
As an example, here is how the build.info
files example from the
section above would be digested into a %unified_info
table:
our %unified_info = (
"depends" =>
{
"apps/openssl" =>
[
"libssl",
],
"crypto/buildinf.h" =>
[
"Makefile",
],
"crypto/cversion.o" =>
[
"crypto/buildinf.h",
],
"engines/dasync" =>
[
"libcrypto",
],
"engines/ossltest" =>
[
"libcrypto.a",
],
"libssl" =>
[
"libcrypto",
],
"util/mkbuildinf.pl" =>
[
"util/Foo.pm",
],
},
"modules" =>
[
"engines/dasync",
"engines/ossltest",
],
"generate" =>
{
"crypto/buildinf.h" =>
[
"util/mkbuildinf.pl",
"\"\$(CC)",
"\$(CFLAGS)\"",
"\"$(PLATFORM)\"",
],
},
"includes" =>
{
"apps/openssl" =>
[
".",
"include",
],
"engines/ossltest" =>
[
"include"
],
"libcrypto" =>
[
"include",
],
"libssl" =>
[
"include",
],
"util/mkbuildinf.pl" =>
[
"util",
],
}
"install" =>
{
"modules" =>
[
"engines/dasync",
],
"libraries" =>
[
"libcrypto",
"libssl",
],
"programs" =>
[
"apps/openssl",
],
},
"libraries" =>
[
"libcrypto",
"libssl",
],
"programs" =>
[
"apps/openssl",
],
"sources" =>
{
"apps/openssl" =>
[
"apps/openssl.o",
],
"apps/openssl.o" =>
[
"apps/openssl.c",
],
"crypto/aes.o" =>
[
"crypto/aes.c",
],
"crypto/cversion.o" =>
[
"crypto/cversion.c",
],
"crypto/evp.o" =>
[
"crypto/evp.c",
],
"engines/e_dasync.o" =>
[
"engines/e_dasync.c",
],
"engines/dasync" =>
[
"engines/e_dasync.o",
],
"engines/e_ossltest.o" =>
[
"engines/e_ossltest.c",
],
"engines/ossltest" =>
[
"engines/e_ossltest.o",
],
"libcrypto" =>
[
"crypto/aes.c",
"crypto/cversion.c",
"crypto/evp.c",
],
"libssl" =>
[
"ssl/tls.c",
],
"ssl/tls.o" =>
[
"ssl/tls.c",
],
},
);
As can be seen, everything in %unified_info
is fairly simple suggest
of information. Still, it tells us that to build all programs, we
must build apps/openssl
, and to build the latter, we will need to
build all its sources (apps/openssl.o
in this case) and all the
other things it depends on (such as libssl
). All those dependencies
need to be built as well, using the same logic, so to build libssl
,
we need to build ssl/tls.o
as well as libcrypto
, and to build the
latter...
Build-file templates are essentially build-files (such as Makefile
on
Unix) with perl code fragments mixed in. Those perl code fragment
will generate all the configuration dependent data, including all the
rules needed to build end product files and intermediary files alike.
At a minimum, there must be a perl code fragment that defines a set of
functions that are used to generates specific build-file rules, to
build static libraries from object files, to build shared libraries
from static libraries, to programs from object files and libraries,
etc.
generatesrc - function that produces build file lines to generate
a source file from some input.
It's called like this:
generatesrc(src => "PATH/TO/tobegenerated",
generator => [ "generatingfile", ... ]
generator_incs => [ "INCL/PATH", ... ]
generator_deps => [ "dep1", ... ]
incs => [ "INCL/PATH", ... ],
deps => [ "dep1", ... ],
intent => one of "libs", "dso", "bin" );
'src' has the name of the file to be generated.
'generator' is the command or part of command to
generate the file, of which the first item is
expected to be the file to generate from.
generatesrc() is expected to analyse and figure out
exactly how to apply that file and how to capture
the result. 'generator_incs' and 'generator_deps'
are include directories and files that the generator
file itself depends on. 'incs' and 'deps' are
include directories and files that are used if $(CC)
is used as an intermediary step when generating the
end product (the file indicated by 'src'). 'intent'
indicates what the generated file is going to be
used for.
src2obj - function that produces build file lines to build an
object file from source files and associated data.
It's called like this:
src2obj(obj => "PATH/TO/objectfile",
srcs => [ "PATH/TO/sourcefile", ... ],
deps => [ "dep1", ... ],
incs => [ "INCL/PATH", ... ]
intent => one of "lib", "dso", "bin" );
'obj' has the intended object file with `.o`
extension, src2obj() is expected to change it to
something more suitable for the platform.
'srcs' has the list of source files to build the
object file, with the first item being the source
file that directly corresponds to the object file.
'deps' is a list of explicit dependencies. 'incs'
is a list of include file directories. Finally,
'intent' indicates what this object file is going
to be used for.
obj2lib - function that produces build file lines to build a
static library file ("libfoo.a" in Unix terms) from
object files.
called like this:
obj2lib(lib => "PATH/TO/libfile",
objs => [ "PATH/TO/objectfile", ... ]);
'lib' has the intended library file name *without*
extension, obj2lib is expected to add that. 'objs'
has the list of object files to build this library.
libobj2shlib - backward compatibility function that's used the
same way as obj2shlib (described next), and was
expected to build the shared library from the
corresponding static library when that was suitable.
NOTE: building a shared library from a static
library is now DEPRECATED, as they no longer share
object files. Attempting to do this will fail.
obj2shlib - function that produces build file lines to build a
shareable object library file ("libfoo.so" in Unix
terms) from the corresponding object files.
called like this:
obj2shlib(shlib => "PATH/TO/shlibfile",
lib => "PATH/TO/libfile",
objs => [ "PATH/TO/objectfile", ... ],
deps => [ "PATH/TO/otherlibfile", ... ]);
'lib' has the base (static) library file name
*without* extension. This is useful in case
supporting files are needed (such as import
libraries on Windows).
'shlib' has the corresponding shared library name
*without* extension. 'deps' has the list of other
libraries (also *without* extension) this library
needs to be linked with. 'objs' has the list of
object files to build this library.
obj2dso - function that produces build file lines to build a
dynamic shared object file from object files.
called like this:
obj2dso(lib => "PATH/TO/libfile",
objs => [ "PATH/TO/objectfile", ... ],
deps => [ "PATH/TO/otherlibfile",
... ]);
This is almost the same as obj2shlib, but the
intent is to build a shareable library that can be
loaded in runtime (a "plugin"...).
obj2bin - function that produces build file lines to build an
executable file from object files.
called like this:
obj2bin(bin => "PATH/TO/binfile",
objs => [ "PATH/TO/objectfile", ... ],
deps => [ "PATH/TO/libfile", ... ]);
'bin' has the intended executable file name
*without* extension, obj2bin is expected to add
that. 'objs' has the list of object files to build
this library. 'deps' has the list of library files
(also *without* extension) that the programs needs
to be linked with.
in2script - function that produces build file lines to build a
script file from some input.
called like this:
in2script(script => "PATH/TO/scriptfile",
sources => [ "PATH/TO/infile", ... ]);
'script' has the intended script file name.
'sources' has the list of source files to build the
resulting script from.
Along with the build-file templates is the driving template
Configurations/common.tmpl
, which looks through all the
information in %unified_info
and generates all the rulesets to build libraries,
programs and all intermediate files, using the rule generating
functions defined in the build-file template.
As an example with the smaller build.info
set we've seen as an
example, producing the rules to build libcrypto
would result in the
following calls:
# Note: obj2shlib will only be called if shared libraries are
# to be produced.
# Note 2: obj2shlib must convert the '.o' extension to whatever
# is suitable on the local platform.
obj2shlib(shlib => "libcrypto",
objs => [ "crypto/aes.o", "crypto/evp.o", "crypto/cversion.o" ],
deps => [ ]);
obj2lib(lib => "libcrypto"
objs => [ "crypto/aes.o", "crypto/evp.o", "crypto/cversion.o" ]);
src2obj(obj => "crypto/aes.o"
srcs => [ "crypto/aes.c" ],
deps => [ ],
incs => [ "include" ],
intent => "lib");
src2obj(obj => "crypto/evp.o"
srcs => [ "crypto/evp.c" ],
deps => [ ],
incs => [ "include" ],
intent => "lib");
src2obj(obj => "crypto/cversion.o"
srcs => [ "crypto/cversion.c" ],
deps => [ "crypto/buildinf.h" ],
incs => [ "include" ],
intent => "lib");
generatesrc(src => "crypto/buildinf.h",
generator => [ "util/mkbuildinf.pl", "\"$(CC)",
"$(CFLAGS)\"", "\"$(PLATFORM)\"" ],
generator_incs => [ "util" ],
generator_deps => [ "util/Foo.pm" ],
incs => [ ],
deps => [ ],
intent => "lib");
The returned strings from all those calls are then concatenated together and written to the resulting build-file.