The appcert utility examines an application's conformance to the Solaris Application Binary Interface (ABI). The Solaris ABI defines the runtime library interfaces in Solaris that are safe and stable for application use. More specifically, appcert identifies any dependencies on unstable runtime interfaces, as well as certain other risks that could cause the product to fail to work on a subsequent release of Solaris.
appcert checks for:
Private symbol usage in Solaris libraries. These are private symbols, that is, functions or data, that are not intended for developer consumption. They are interfaces that Solaris libraries use to call one another. These symbols might change their semantic behavior or even disappear altogether (so-called "demoted" symbols), so it is a good practice to make sure your application does not depend upon any of them.
Static linking. In particular, this refers to static linking of archives libc.a, libsocket.a, and libnsl.a, that is, instead of dynamically linking the corresponding shared object .so's. Because the semantics of private symbol calls from one Solaris library to another can change from one release to another, it is not a good practice to "hardwire" library code into your binary objects.
Unbound symbols. These are library symbols (that is, functions or data) that the dynamic linker could not resolve when appcert was run. This might be an environment problem (for example, LD_LIBRARY_PATH) or a build problem (for example, not specifying -llib and/or -z defs with compiling). They are flagged to point these problems out and in case a more serious problem is indicated.
An entire product can be readily examined by appcert (that is, if the product is a collection of many programs and supporting shared objects) by referring appcert to the directories where the product is installed.
To perform its task, appcert constructs a profile of interface dependencies for each object file within the product (whether an executable object or shared object), to determine all the Solaris system interfaces that are depended upon. (Notice that appcert uses the Solaris runtime linker to make this determination.) These dependency profiles are then compared to a definition of the Solaris ABI to identify any interfaces that are Private (unsafe and unstable for application-level use).
appcert generates a simple roll-up report that indicates which of the product's components, if any, had liabilities and what those liabilities were. The report aids developers who are examining their product's release-to-release stability.
Notice that appcert produces complete interface dependency information, both the Public (safe and stable) Solaris interfaces and the Private (non-ABI) interfaces. This information can also be examined for each product component, if you want.
IMPORTANT: appcert must run in the same environment in which the application being checked runs. See NOTES.
The following options are supported:
If appcert is run in "batch" mode, the output report will contain one line per binary, beginning with PASS if no problems were detected for the binary, FAIL if any problems were found, or INC if the binary could not be completely checked. Do not interpret these labels too literally. For example, PASS just means that none of the appcert warnings were triggered. These strings are flush left and so can be selected via grep ‸FAIL ..., and so forth.
Specifies the file infile that contains a list of files (one per line) to check. This list is appended to the list determined from the command line operands (see OPERANDS below).
Prints out the usage information.
appcert examines your product for the presence of shared objects. If it finds some, it appends the directories they reside in to LD_LIBRARY_PATH. Use this flag to prevent appcert from doing this.
When searching directories for binaries to check, this option does not follow symbolic links. See find(1).
Appends Solaris library directories (that is, /usr/openwin/lib:/usr/dt/lib) to LD_LIBRARY_PATH.
Identifies the directory in which to run the library components and create temporary files (default is /tmp).
The following operands are supported:
A complete list of objects and/or directories that contain the objects constituting the product to be checked. appcert recursively searches directories looking for object files; non-object files are ignored.
The following exit values are returned:
appcert ran successfully and found no potential binary stability problems.
appcert failed to run successfully.
Some of the objects checked have potential binary stability problems.
No binary objects were located that could be checked.
If the object file to be examined depends on libraries, those dependencies must be recorded in it (by using the compiler's -l switch).
If the object file to be examined depends on other shared libraries, those libraries must be accessible via LD_LIBRARY_PATH or RPATH when appcert is run.
To check 64-bit applications, the machine must be running the 64-bit Solaris kernel. See isalist(1). Also, the checks for static linking are currently not done on 64-bit applications.
appcert cannot examine:
Non-ELF file executables such as shell scripts.
A mapping between checked binaries and the subdirectory in the working directory in which the output specific to that binary can be found.
A copy of the rollup report that was displayed on stdout when appcert was run.
A list of binaries that appcert was asked to check but had to skip, along with a brief reason why each was skipped.
A list of symbols suspected to be demoted Solaris symbols.
A list of private Solaris symbols to which the object makes direct bindings.
A list of public Solaris symbols to which the object makes direct bindings.
A list of symbols not bound by the dynamic linker when ldd -r was run. For convenience, ldd output lines containing "file not found" are also included.
A pretty-printed summary of dynamic bindings for the objects examined, including tables of Public and Private symbols used from each Solaris library.
Other files are temporary files used internally by appcert.
Private symbols are functions or data variables in a Solaris library that are not intended for developer or external use. These symbols are interfaces that the Solaris libraries use to call and communicate with one another. They are marked in pvs(1) output with the symbol version name "SUNWprivate".
Private symbols can change their semantic behavior or even disappear altogether ("demoted" or "deprecated" symbols), so your application should not depend upon any of them.
Demoted symbols are functions or data variables in a Solaris library that were once private to that library and have been removed (or possibly scoped local to the library) in a later Solaris release. If your application directly calls one of these demoted symbols, it will fail to run (relocation error) on the release in which the symbol was removed and releases thereafter.
In some rare cases, a demoted symbol will return in a later release, but nevertheless there are still some releases on which the application will not run.
Sun Microsystems Inc. performed most of the library scoping in the transition from Solaris 2.5.1 to 2.6. This action was done to increase binary stability. By making these completely internal interfaces invisible (that is, they cannot be dynamically linked against), a developer cannot accidentally or intentionally call these interfaces. For more information, see the Linker and Libraries Guide, in particular the chapter on versioning. This document may be found online at http://docs.sun.com.
Unbound symbols are library symbols (that is, functions or data) referenced by the application that the dynamic linker could not resolve when appcert was run. Note: appcert does not actually run your application, so some aspect of the environment that affects dynamic linking might not be set properly.
Unbound symbols do not necessarily indicate a potential binary stability problem. They only mean that when appcert was run, the runtime dynamic linker could not resolve these symbols.
Unbound symbols might be due to LD_LIBRARY_PATH not being correctly set. Make sure it is set, so that all of your binary objects can find all of the libraries they depend on (either your product's own libraries, Solaris libraries, or those of a third party). Then re-run appcert.
You might find it useful to write a shell script that sets up the environment correctly and then runs appcert on the binaries you want to check.
Another common cause for unbound symbols is when a shared object under test has not recorded its dynamic dependencies, that is, at build time the -l switch was not supplied to the compiler and ld(1). So the shared object requires that the executables that link against it have the correct dependencies recorded.
Notice that such a shared object can either be linked in the standard way (that is, specified at an executable's build time) or dynamically opened (for example, an executable calls dlopen(3DL) on the shared object sometimes when running). Either case can give rise to unbound symbols when appcert is run. The former can usually be resolved by setting LD_LIBRARY_PATH appropriately before running appcert. The latter (dlopen) is usually difficult to resolve. Under some circumstances, you might be able to set LD_PRELOAD appropriately to preload the needed libraries, but this procedure does not always work.
How do you know if the environment has been set up correctly so that there will be no unbound symbols? It must be set up so that running ldd -r on the binary yields no “file not found” or “symbol not found” errors. See ld.so.1(1) and ldd(1) for more information on dynamic linking.
In any event, appcert flags unbound symbols as a warning in case they might indicate a more serious problem. Unbound symbols can be an indicator of dependencies on demoted symbols (symbols that have been removed from a library or scoped local to it). Dependencies on demoted symbols will lead to serious binary stability problems.
However, setting up the environment properly should remove most unbound symbols. In general, it is good practice to record library dependencies at build time whenever possible because it helps make the binary object better defined and self-contained. Also recommended is using the -z defs flag when building shared objects, to force the resolution of all symbols during compilation. See ld(1) for more information.
appcert runs /bin/ldd -r on each binary object to be tested. It sets the environment variable LD_DEBUG=“files,bindings”. (See ldd(1) and ld.so.1(1) for more information). If that command fails for some reason, appcert will have no dynamic symbol binding information and will find “no bindings”.
The binary object does not have read permission.
The binary object is SUID or SGID and the user does not have sufficient privileges.
The binary object is an executable without the execute permission bit set.
The binary object is a 64-bit application, but the kernel running on the current machine supports only 32-bit applications.
The binary object is completely statically linked.
The binary object has no library dependency information recorded.
Other cases exist as well (for example, out of memory). In general, this flag means that appcert could not completely examine the object due to permissions or environment. Try to modify the permissions or environment so that the dynamic bindings can be recorded.
An obsolete library is one whose use is deprecated and that might, in some future release, be removed from Solaris altogether. appcert flags these because applications depending on them might not run in future releases of Solaris. All interfaces, including Private ones, in an obsolete library are frozen and will not change.
Direct use of the symbols sys_errlist or sys_nerr presents a risk in which reference might be made past the end of the sys_errlist array. These symbols are deprecated in 32-bit versions of Solaris and are absent altogether in 64-bit versions. Use strerror(3C) instead.
The “strong” symbols (for example, _socket) associated with “weak” symbols (for example, socket ) are reserved as private (their behavior could change in the future). Your application should only directly reference the weak symbol (usually the strong symbols begin with “_”).
Note: Under certain build environments, the strong/private symbol dependency gets recorded into your binary instead of the weak/public one, even though the source code doesn't appear to reference the private symbol. Nevertheless, steps should be taken to trace down why this is occurring and fix the dependency.
appcert needs to run in the same environment in which the application being checked runs. Otherwise it might not be able to resolve references correctly to interfaces in the Solaris libraries. Take the following steps:
Make sure that LD_LIBRARY_PATH and any other aspects of the environment are set to whatever settings are used when the application is run. Also make sure that it contains the directories containing any non-Solaris shared objects that are part of the product, so that they can be found when referenced.
Are dynamically linked ELF objects
Have execute permission set on executables (this is not necessary for shared objects)
Are not SUID root (otherwise you will have to be root to check them; make non-SUID copies and check those if necessary).
You might find it useful to write a shell script that sets up the environment correctly and then runs appcert.
Some potential problems that can be encountered are:
appcert reports unbound symbols that appear to be part of Solaris libraries.
This is probably caused when the application uses dlopen(3DL) to access a shared object that does not have its Solaris dependencies recorded. appcert cannot resolve symbol use in such cases, since the dynamic linker is never invoked on the shared object, and there is no other dependency information that could be used to resolve the Solaris symbol bindings. This can also occur with non-Solaris symbols.
To avoid this problem, make sure that when a shared object is built, its dependencies on Solaris libraries are explicitly recorded by using the -llib option on the compile line (see cc(1) and ld(1)).
appcert reports that the application uses a Solaris private symbol that is not referenced in the application's source code.
This problem is most likely due to static linking of a Solaris library that references that symbol. Since appcert uses the dynamic linker to resolve symbols, statically linked libraries appear to appcert to be part of the application code (which, in a sense, they are). This can also sometimes happen as a result of macro substitution in a Solaris header file.
To avoid this problem, whenever possible do not statically link Solaris library archives into your application.
appcert does not recognize a library as part of Solaris.
Some obsolete Solaris libraries are so old that they were obsoleted before their symbols could be versioned. Consequently, appcert cannot recognize them as being part of Solaris.
The use of the terms “public” and “private” as equivalent to “stable” and “unstable” is unfortunately somewhat confusing. In particular, experimental or evolving interfaces are public in the sense that they are documented and their use is encouraged. But they are unstable, because an application built with them might not run on subsequent releases. Thus, they are classified as private for appcert's purposes until they are no longer evolving. Conversely, obsolete interfaces will eventually disappear, and so are unstable, even though they have been public and stable in the past and are still treated as public by appcert. Fortunately, these two situations are rare.
See attributes(5) for descriptions of the following attributes:
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