| ======================== |
| LLVM Programmer's Manual |
| ======================== |
| |
| .. contents:: |
| :local: |
| |
| .. warning:: |
| This is always a work in progress. |
| |
| .. _introduction: |
| |
| Introduction |
| ============ |
| |
| This document is meant to highlight some of the important classes and interfaces |
| available in the LLVM source-base. This manual is not intended to explain what |
| LLVM is, how it works, and what LLVM code looks like. It assumes that you know |
| the basics of LLVM and are interested in writing transformations or otherwise |
| analyzing or manipulating the code. |
| |
| This document should get you oriented so that you can find your way in the |
| continuously growing source code that makes up the LLVM infrastructure. Note |
| that this manual is not intended to serve as a replacement for reading the |
| source code, so if you think there should be a method in one of these classes to |
| do something, but it's not listed, check the source. Links to the `doxygen |
| <http://llvm.org/doxygen/>`__ sources are provided to make this as easy as |
| possible. |
| |
| The first section of this document describes general information that is useful |
| to know when working in the LLVM infrastructure, and the second describes the |
| Core LLVM classes. In the future this manual will be extended with information |
| describing how to use extension libraries, such as dominator information, CFG |
| traversal routines, and useful utilities like the ``InstVisitor`` (`doxygen |
| <http://llvm.org/doxygen/InstVisitor_8h-source.html>`__) template. |
| |
| .. _general: |
| |
| General Information |
| =================== |
| |
| This section contains general information that is useful if you are working in |
| the LLVM source-base, but that isn't specific to any particular API. |
| |
| .. _stl: |
| |
| The C++ Standard Template Library |
| --------------------------------- |
| |
| LLVM makes heavy use of the C++ Standard Template Library (STL), perhaps much |
| more than you are used to, or have seen before. Because of this, you might want |
| to do a little background reading in the techniques used and capabilities of the |
| library. There are many good pages that discuss the STL, and several books on |
| the subject that you can get, so it will not be discussed in this document. |
| |
| Here are some useful links: |
| |
| #. `cppreference.com |
| <http://en.cppreference.com/w/>`_ - an excellent |
| reference for the STL and other parts of the standard C++ library. |
| |
| #. `C++ In a Nutshell <http://www.tempest-sw.com/cpp/>`_ - This is an O'Reilly |
| book in the making. It has a decent Standard Library Reference that rivals |
| Dinkumware's, and is unfortunately no longer free since the book has been |
| published. |
| |
| #. `C++ Frequently Asked Questions <http://www.parashift.com/c++-faq-lite/>`_. |
| |
| #. `SGI's STL Programmer's Guide <http://www.sgi.com/tech/stl/>`_ - Contains a |
| useful `Introduction to the STL |
| <http://www.sgi.com/tech/stl/stl_introduction.html>`_. |
| |
| #. `Bjarne Stroustrup's C++ Page |
| <http://www.research.att.com/%7Ebs/C++.html>`_. |
| |
| #. `Bruce Eckel's Thinking in C++, 2nd ed. Volume 2 Revision 4.0 |
| (even better, get the book) |
| <http://www.mindview.net/Books/TICPP/ThinkingInCPP2e.html>`_. |
| |
| You are also encouraged to take a look at the :doc:`LLVM Coding Standards |
| <CodingStandards>` guide which focuses on how to write maintainable code more |
| than where to put your curly braces. |
| |
| .. _resources: |
| |
| Other useful references |
| ----------------------- |
| |
| #. `Using static and shared libraries across platforms |
| <http://www.fortran-2000.com/ArnaudRecipes/sharedlib.html>`_ |
| |
| .. _apis: |
| |
| Important and useful LLVM APIs |
| ============================== |
| |
| Here we highlight some LLVM APIs that are generally useful and good to know |
| about when writing transformations. |
| |
| .. _isa: |
| |
| The ``isa<>``, ``cast<>`` and ``dyn_cast<>`` templates |
| ------------------------------------------------------ |
| |
| The LLVM source-base makes extensive use of a custom form of RTTI. These |
| templates have many similarities to the C++ ``dynamic_cast<>`` operator, but |
| they don't have some drawbacks (primarily stemming from the fact that |
| ``dynamic_cast<>`` only works on classes that have a v-table). Because they are |
| used so often, you must know what they do and how they work. All of these |
| templates are defined in the ``llvm/Support/Casting.h`` (`doxygen |
| <http://llvm.org/doxygen/Casting_8h-source.html>`__) file (note that you very |
| rarely have to include this file directly). |
| |
| ``isa<>``: |
| The ``isa<>`` operator works exactly like the Java "``instanceof``" operator. |
| It returns true or false depending on whether a reference or pointer points to |
| an instance of the specified class. This can be very useful for constraint |
| checking of various sorts (example below). |
| |
| ``cast<>``: |
| The ``cast<>`` operator is a "checked cast" operation. It converts a pointer |
| or reference from a base class to a derived class, causing an assertion |
| failure if it is not really an instance of the right type. This should be |
| used in cases where you have some information that makes you believe that |
| something is of the right type. An example of the ``isa<>`` and ``cast<>`` |
| template is: |
| |
| .. code-block:: c++ |
| |
| static bool isLoopInvariant(const Value *V, const Loop *L) { |
| if (isa<Constant>(V) || isa<Argument>(V) || isa<GlobalValue>(V)) |
| return true; |
| |
| // Otherwise, it must be an instruction... |
| return !L->contains(cast<Instruction>(V)->getParent()); |
| } |
| |
| Note that you should **not** use an ``isa<>`` test followed by a ``cast<>``, |
| for that use the ``dyn_cast<>`` operator. |
| |
| ``dyn_cast<>``: |
| The ``dyn_cast<>`` operator is a "checking cast" operation. It checks to see |
| if the operand is of the specified type, and if so, returns a pointer to it |
| (this operator does not work with references). If the operand is not of the |
| correct type, a null pointer is returned. Thus, this works very much like |
| the ``dynamic_cast<>`` operator in C++, and should be used in the same |
| circumstances. Typically, the ``dyn_cast<>`` operator is used in an ``if`` |
| statement or some other flow control statement like this: |
| |
| .. code-block:: c++ |
| |
| if (AllocationInst *AI = dyn_cast<AllocationInst>(Val)) { |
| // ... |
| } |
| |
| This form of the ``if`` statement effectively combines together a call to |
| ``isa<>`` and a call to ``cast<>`` into one statement, which is very |
| convenient. |
| |
| Note that the ``dyn_cast<>`` operator, like C++'s ``dynamic_cast<>`` or Java's |
| ``instanceof`` operator, can be abused. In particular, you should not use big |
| chained ``if/then/else`` blocks to check for lots of different variants of |
| classes. If you find yourself wanting to do this, it is much cleaner and more |
| efficient to use the ``InstVisitor`` class to dispatch over the instruction |
| type directly. |
| |
| ``cast_or_null<>``: |
| The ``cast_or_null<>`` operator works just like the ``cast<>`` operator, |
| except that it allows for a null pointer as an argument (which it then |
| propagates). This can sometimes be useful, allowing you to combine several |
| null checks into one. |
| |
| ``dyn_cast_or_null<>``: |
| The ``dyn_cast_or_null<>`` operator works just like the ``dyn_cast<>`` |
| operator, except that it allows for a null pointer as an argument (which it |
| then propagates). This can sometimes be useful, allowing you to combine |
| several null checks into one. |
| |
| These five templates can be used with any classes, whether they have a v-table |
| or not. If you want to add support for these templates, see the document |
| :doc:`How to set up LLVM-style RTTI for your class hierarchy |
| <HowToSetUpLLVMStyleRTTI>` |
| |
| .. _string_apis: |
| |
| Passing strings (the ``StringRef`` and ``Twine`` classes) |
| --------------------------------------------------------- |
| |
| Although LLVM generally does not do much string manipulation, we do have several |
| important APIs which take strings. Two important examples are the Value class |
| -- which has names for instructions, functions, etc. -- and the ``StringMap`` |
| class which is used extensively in LLVM and Clang. |
| |
| These are generic classes, and they need to be able to accept strings which may |
| have embedded null characters. Therefore, they cannot simply take a ``const |
| char *``, and taking a ``const std::string&`` requires clients to perform a heap |
| allocation which is usually unnecessary. Instead, many LLVM APIs use a |
| ``StringRef`` or a ``const Twine&`` for passing strings efficiently. |
| |
| .. _StringRef: |
| |
| The ``StringRef`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The ``StringRef`` data type represents a reference to a constant string (a |
| character array and a length) and supports the common operations available on |
| ``std::string``, but does not require heap allocation. |
| |
| It can be implicitly constructed using a C style null-terminated string, an |
| ``std::string``, or explicitly with a character pointer and length. For |
| example, the ``StringRef`` find function is declared as: |
| |
| .. code-block:: c++ |
| |
| iterator find(StringRef Key); |
| |
| and clients can call it using any one of: |
| |
| .. code-block:: c++ |
| |
| Map.find("foo"); // Lookup "foo" |
| Map.find(std::string("bar")); // Lookup "bar" |
| Map.find(StringRef("\0baz", 4)); // Lookup "\0baz" |
| |
| Similarly, APIs which need to return a string may return a ``StringRef`` |
| instance, which can be used directly or converted to an ``std::string`` using |
| the ``str`` member function. See ``llvm/ADT/StringRef.h`` (`doxygen |
| <http://llvm.org/doxygen/classllvm_1_1StringRef_8h-source.html>`__) for more |
| information. |
| |
| You should rarely use the ``StringRef`` class directly, because it contains |
| pointers to external memory it is not generally safe to store an instance of the |
| class (unless you know that the external storage will not be freed). |
| ``StringRef`` is small and pervasive enough in LLVM that it should always be |
| passed by value. |
| |
| The ``Twine`` class |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| The ``Twine`` (`doxygen <http://llvm.org/doxygen/classllvm_1_1Twine.html>`__) |
| class is an efficient way for APIs to accept concatenated strings. For example, |
| a common LLVM paradigm is to name one instruction based on the name of another |
| instruction with a suffix, for example: |
| |
| .. code-block:: c++ |
| |
| New = CmpInst::Create(..., SO->getName() + ".cmp"); |
| |
| The ``Twine`` class is effectively a lightweight `rope |
| <http://en.wikipedia.org/wiki/Rope_(computer_science)>`_ which points to |
| temporary (stack allocated) objects. Twines can be implicitly constructed as |
| the result of the plus operator applied to strings (i.e., a C strings, an |
| ``std::string``, or a ``StringRef``). The twine delays the actual concatenation |
| of strings until it is actually required, at which point it can be efficiently |
| rendered directly into a character array. This avoids unnecessary heap |
| allocation involved in constructing the temporary results of string |
| concatenation. See ``llvm/ADT/Twine.h`` (`doxygen |
| <http://llvm.org/doxygen/Twine_8h_source.html>`__) and :ref:`here <dss_twine>` |
| for more information. |
| |
| As with a ``StringRef``, ``Twine`` objects point to external memory and should |
| almost never be stored or mentioned directly. They are intended solely for use |
| when defining a function which should be able to efficiently accept concatenated |
| strings. |
| |
| .. _DEBUG: |
| |
| The ``DEBUG()`` macro and ``-debug`` option |
| ------------------------------------------- |
| |
| Often when working on your pass you will put a bunch of debugging printouts and |
| other code into your pass. After you get it working, you want to remove it, but |
| you may need it again in the future (to work out new bugs that you run across). |
| |
| Naturally, because of this, you don't want to delete the debug printouts, but |
| you don't want them to always be noisy. A standard compromise is to comment |
| them out, allowing you to enable them if you need them in the future. |
| |
| The ``llvm/Support/Debug.h`` (`doxygen |
| <http://llvm.org/doxygen/Debug_8h-source.html>`__) file provides a macro named |
| ``DEBUG()`` that is a much nicer solution to this problem. Basically, you can |
| put arbitrary code into the argument of the ``DEBUG`` macro, and it is only |
| executed if '``opt``' (or any other tool) is run with the '``-debug``' command |
| line argument: |
| |
| .. code-block:: c++ |
| |
| DEBUG(errs() << "I am here!\n"); |
| |
| Then you can run your pass like this: |
| |
| .. code-block:: none |
| |
| $ opt < a.bc > /dev/null -mypass |
| <no output> |
| $ opt < a.bc > /dev/null -mypass -debug |
| I am here! |
| |
| Using the ``DEBUG()`` macro instead of a home-brewed solution allows you to not |
| have to create "yet another" command line option for the debug output for your |
| pass. Note that ``DEBUG()`` macros are disabled for optimized builds, so they |
| do not cause a performance impact at all (for the same reason, they should also |
| not contain side-effects!). |
| |
| One additional nice thing about the ``DEBUG()`` macro is that you can enable or |
| disable it directly in gdb. Just use "``set DebugFlag=0``" or "``set |
| DebugFlag=1``" from the gdb if the program is running. If the program hasn't |
| been started yet, you can always just run it with ``-debug``. |
| |
| .. _DEBUG_TYPE: |
| |
| Fine grained debug info with ``DEBUG_TYPE`` and the ``-debug-only`` option |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Sometimes you may find yourself in a situation where enabling ``-debug`` just |
| turns on **too much** information (such as when working on the code generator). |
| If you want to enable debug information with more fine-grained control, you |
| define the ``DEBUG_TYPE`` macro and the ``-debug`` only option as follows: |
| |
| .. code-block:: c++ |
| |
| #undef DEBUG_TYPE |
| DEBUG(errs() << "No debug type\n"); |
| #define DEBUG_TYPE "foo" |
| DEBUG(errs() << "'foo' debug type\n"); |
| #undef DEBUG_TYPE |
| #define DEBUG_TYPE "bar" |
| DEBUG(errs() << "'bar' debug type\n")); |
| #undef DEBUG_TYPE |
| #define DEBUG_TYPE "" |
| DEBUG(errs() << "No debug type (2)\n"); |
| |
| Then you can run your pass like this: |
| |
| .. code-block:: none |
| |
| $ opt < a.bc > /dev/null -mypass |
| <no output> |
| $ opt < a.bc > /dev/null -mypass -debug |
| No debug type |
| 'foo' debug type |
| 'bar' debug type |
| No debug type (2) |
| $ opt < a.bc > /dev/null -mypass -debug-only=foo |
| 'foo' debug type |
| $ opt < a.bc > /dev/null -mypass -debug-only=bar |
| 'bar' debug type |
| |
| Of course, in practice, you should only set ``DEBUG_TYPE`` at the top of a file, |
| to specify the debug type for the entire module (if you do this before you |
| ``#include "llvm/Support/Debug.h"``, you don't have to insert the ugly |
| ``#undef``'s). Also, you should use names more meaningful than "foo" and "bar", |
| because there is no system in place to ensure that names do not conflict. If |
| two different modules use the same string, they will all be turned on when the |
| name is specified. This allows, for example, all debug information for |
| instruction scheduling to be enabled with ``-debug-type=InstrSched``, even if |
| the source lives in multiple files. |
| |
| The ``DEBUG_WITH_TYPE`` macro is also available for situations where you would |
| like to set ``DEBUG_TYPE``, but only for one specific ``DEBUG`` statement. It |
| takes an additional first parameter, which is the type to use. For example, the |
| preceding example could be written as: |
| |
| .. code-block:: c++ |
| |
| DEBUG_WITH_TYPE("", errs() << "No debug type\n"); |
| DEBUG_WITH_TYPE("foo", errs() << "'foo' debug type\n"); |
| DEBUG_WITH_TYPE("bar", errs() << "'bar' debug type\n")); |
| DEBUG_WITH_TYPE("", errs() << "No debug type (2)\n"); |
| |
| .. _Statistic: |
| |
| The ``Statistic`` class & ``-stats`` option |
| ------------------------------------------- |
| |
| The ``llvm/ADT/Statistic.h`` (`doxygen |
| <http://llvm.org/doxygen/Statistic_8h-source.html>`__) file provides a class |
| named ``Statistic`` that is used as a unified way to keep track of what the LLVM |
| compiler is doing and how effective various optimizations are. It is useful to |
| see what optimizations are contributing to making a particular program run |
| faster. |
| |
| Often you may run your pass on some big program, and you're interested to see |
| how many times it makes a certain transformation. Although you can do this with |
| hand inspection, or some ad-hoc method, this is a real pain and not very useful |
| for big programs. Using the ``Statistic`` class makes it very easy to keep |
| track of this information, and the calculated information is presented in a |
| uniform manner with the rest of the passes being executed. |
| |
| There are many examples of ``Statistic`` uses, but the basics of using it are as |
| follows: |
| |
| #. Define your statistic like this: |
| |
| .. code-block:: c++ |
| |
| #define DEBUG_TYPE "mypassname" // This goes before any #includes. |
| STATISTIC(NumXForms, "The # of times I did stuff"); |
| |
| The ``STATISTIC`` macro defines a static variable, whose name is specified by |
| the first argument. The pass name is taken from the ``DEBUG_TYPE`` macro, and |
| the description is taken from the second argument. The variable defined |
| ("NumXForms" in this case) acts like an unsigned integer. |
| |
| #. Whenever you make a transformation, bump the counter: |
| |
| .. code-block:: c++ |
| |
| ++NumXForms; // I did stuff! |
| |
| That's all you have to do. To get '``opt``' to print out the statistics |
| gathered, use the '``-stats``' option: |
| |
| .. code-block:: none |
| |
| $ opt -stats -mypassname < program.bc > /dev/null |
| ... statistics output ... |
| |
| When running ``opt`` on a C file from the SPEC benchmark suite, it gives a |
| report that looks like this: |
| |
| .. code-block:: none |
| |
| 7646 bitcodewriter - Number of normal instructions |
| 725 bitcodewriter - Number of oversized instructions |
| 129996 bitcodewriter - Number of bitcode bytes written |
| 2817 raise - Number of insts DCEd or constprop'd |
| 3213 raise - Number of cast-of-self removed |
| 5046 raise - Number of expression trees converted |
| 75 raise - Number of other getelementptr's formed |
| 138 raise - Number of load/store peepholes |
| 42 deadtypeelim - Number of unused typenames removed from symtab |
| 392 funcresolve - Number of varargs functions resolved |
| 27 globaldce - Number of global variables removed |
| 2 adce - Number of basic blocks removed |
| 134 cee - Number of branches revectored |
| 49 cee - Number of setcc instruction eliminated |
| 532 gcse - Number of loads removed |
| 2919 gcse - Number of instructions removed |
| 86 indvars - Number of canonical indvars added |
| 87 indvars - Number of aux indvars removed |
| 25 instcombine - Number of dead inst eliminate |
| 434 instcombine - Number of insts combined |
| 248 licm - Number of load insts hoisted |
| 1298 licm - Number of insts hoisted to a loop pre-header |
| 3 licm - Number of insts hoisted to multiple loop preds (bad, no loop pre-header) |
| 75 mem2reg - Number of alloca's promoted |
| 1444 cfgsimplify - Number of blocks simplified |
| |
| Obviously, with so many optimizations, having a unified framework for this stuff |
| is very nice. Making your pass fit well into the framework makes it more |
| maintainable and useful. |
| |
| .. _ViewGraph: |
| |
| Viewing graphs while debugging code |
| ----------------------------------- |
| |
| Several of the important data structures in LLVM are graphs: for example CFGs |
| made out of LLVM :ref:`BasicBlocks <BasicBlock>`, CFGs made out of LLVM |
| :ref:`MachineBasicBlocks <MachineBasicBlock>`, and :ref:`Instruction Selection |
| DAGs <SelectionDAG>`. In many cases, while debugging various parts of the |
| compiler, it is nice to instantly visualize these graphs. |
| |
| LLVM provides several callbacks that are available in a debug build to do |
| exactly that. If you call the ``Function::viewCFG()`` method, for example, the |
| current LLVM tool will pop up a window containing the CFG for the function where |
| each basic block is a node in the graph, and each node contains the instructions |
| in the block. Similarly, there also exists ``Function::viewCFGOnly()`` (does |
| not include the instructions), the ``MachineFunction::viewCFG()`` and |
| ``MachineFunction::viewCFGOnly()``, and the ``SelectionDAG::viewGraph()`` |
| methods. Within GDB, for example, you can usually use something like ``call |
| DAG.viewGraph()`` to pop up a window. Alternatively, you can sprinkle calls to |
| these functions in your code in places you want to debug. |
| |
| Getting this to work requires a small amount of configuration. On Unix systems |
| with X11, install the `graphviz <http://www.graphviz.org>`_ toolkit, and make |
| sure 'dot' and 'gv' are in your path. If you are running on Mac OS/X, download |
| and install the Mac OS/X `Graphviz program |
| <http://www.pixelglow.com/graphviz/>`_ and add |
| ``/Applications/Graphviz.app/Contents/MacOS/`` (or wherever you install it) to |
| your path. Once in your system and path are set up, rerun the LLVM configure |
| script and rebuild LLVM to enable this functionality. |
| |
| ``SelectionDAG`` has been extended to make it easier to locate *interesting* |
| nodes in large complex graphs. From gdb, if you ``call DAG.setGraphColor(node, |
| "color")``, then the next ``call DAG.viewGraph()`` would highlight the node in |
| the specified color (choices of colors can be found at `colors |
| <http://www.graphviz.org/doc/info/colors.html>`_.) More complex node attributes |
| can be provided with ``call DAG.setGraphAttrs(node, "attributes")`` (choices can |
| be found at `Graph attributes <http://www.graphviz.org/doc/info/attrs.html>`_.) |
| If you want to restart and clear all the current graph attributes, then you can |
| ``call DAG.clearGraphAttrs()``. |
| |
| Note that graph visualization features are compiled out of Release builds to |
| reduce file size. This means that you need a Debug+Asserts or Release+Asserts |
| build to use these features. |
| |
| .. _datastructure: |
| |
| Picking the Right Data Structure for a Task |
| =========================================== |
| |
| LLVM has a plethora of data structures in the ``llvm/ADT/`` directory, and we |
| commonly use STL data structures. This section describes the trade-offs you |
| should consider when you pick one. |
| |
| The first step is a choose your own adventure: do you want a sequential |
| container, a set-like container, or a map-like container? The most important |
| thing when choosing a container is the algorithmic properties of how you plan to |
| access the container. Based on that, you should use: |
| |
| |
| * a :ref:`map-like <ds_map>` container if you need efficient look-up of a |
| value based on another value. Map-like containers also support efficient |
| queries for containment (whether a key is in the map). Map-like containers |
| generally do not support efficient reverse mapping (values to keys). If you |
| need that, use two maps. Some map-like containers also support efficient |
| iteration through the keys in sorted order. Map-like containers are the most |
| expensive sort, only use them if you need one of these capabilities. |
| |
| * a :ref:`set-like <ds_set>` container if you need to put a bunch of stuff into |
| a container that automatically eliminates duplicates. Some set-like |
| containers support efficient iteration through the elements in sorted order. |
| Set-like containers are more expensive than sequential containers. |
| |
| * a :ref:`sequential <ds_sequential>` container provides the most efficient way |
| to add elements and keeps track of the order they are added to the collection. |
| They permit duplicates and support efficient iteration, but do not support |
| efficient look-up based on a key. |
| |
| * a :ref:`string <ds_string>` container is a specialized sequential container or |
| reference structure that is used for character or byte arrays. |
| |
| * a :ref:`bit <ds_bit>` container provides an efficient way to store and |
| perform set operations on sets of numeric id's, while automatically |
| eliminating duplicates. Bit containers require a maximum of 1 bit for each |
| identifier you want to store. |
| |
| Once the proper category of container is determined, you can fine tune the |
| memory use, constant factors, and cache behaviors of access by intelligently |
| picking a member of the category. Note that constant factors and cache behavior |
| can be a big deal. If you have a vector that usually only contains a few |
| elements (but could contain many), for example, it's much better to use |
| :ref:`SmallVector <dss_smallvector>` than :ref:`vector <dss_vector>`. Doing so |
| avoids (relatively) expensive malloc/free calls, which dwarf the cost of adding |
| the elements to the container. |
| |
| .. _ds_sequential: |
| |
| Sequential Containers (std::vector, std::list, etc) |
| --------------------------------------------------- |
| |
| There are a variety of sequential containers available for you, based on your |
| needs. Pick the first in this section that will do what you want. |
| |
| .. _dss_arrayref: |
| |
| llvm/ADT/ArrayRef.h |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| The ``llvm::ArrayRef`` class is the preferred class to use in an interface that |
| accepts a sequential list of elements in memory and just reads from them. By |
| taking an ``ArrayRef``, the API can be passed a fixed size array, an |
| ``std::vector``, an ``llvm::SmallVector`` and anything else that is contiguous |
| in memory. |
| |
| .. _dss_fixedarrays: |
| |
| Fixed Size Arrays |
| ^^^^^^^^^^^^^^^^^ |
| |
| Fixed size arrays are very simple and very fast. They are good if you know |
| exactly how many elements you have, or you have a (low) upper bound on how many |
| you have. |
| |
| .. _dss_heaparrays: |
| |
| Heap Allocated Arrays |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| Heap allocated arrays (``new[]`` + ``delete[]``) are also simple. They are good |
| if the number of elements is variable, if you know how many elements you will |
| need before the array is allocated, and if the array is usually large (if not, |
| consider a :ref:`SmallVector <dss_smallvector>`). The cost of a heap allocated |
| array is the cost of the new/delete (aka malloc/free). Also note that if you |
| are allocating an array of a type with a constructor, the constructor and |
| destructors will be run for every element in the array (re-sizable vectors only |
| construct those elements actually used). |
| |
| .. _dss_tinyptrvector: |
| |
| llvm/ADT/TinyPtrVector.h |
| ^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| ``TinyPtrVector<Type>`` is a highly specialized collection class that is |
| optimized to avoid allocation in the case when a vector has zero or one |
| elements. It has two major restrictions: 1) it can only hold values of pointer |
| type, and 2) it cannot hold a null pointer. |
| |
| Since this container is highly specialized, it is rarely used. |
| |
| .. _dss_smallvector: |
| |
| llvm/ADT/SmallVector.h |
| ^^^^^^^^^^^^^^^^^^^^^^ |
| |
| ``SmallVector<Type, N>`` is a simple class that looks and smells just like |
| ``vector<Type>``: it supports efficient iteration, lays out elements in memory |
| order (so you can do pointer arithmetic between elements), supports efficient |
| push_back/pop_back operations, supports efficient random access to its elements, |
| etc. |
| |
| The advantage of SmallVector is that it allocates space for some number of |
| elements (N) **in the object itself**. Because of this, if the SmallVector is |
| dynamically smaller than N, no malloc is performed. This can be a big win in |
| cases where the malloc/free call is far more expensive than the code that |
| fiddles around with the elements. |
| |
| This is good for vectors that are "usually small" (e.g. the number of |
| predecessors/successors of a block is usually less than 8). On the other hand, |
| this makes the size of the SmallVector itself large, so you don't want to |
| allocate lots of them (doing so will waste a lot of space). As such, |
| SmallVectors are most useful when on the stack. |
| |
| SmallVector also provides a nice portable and efficient replacement for |
| ``alloca``. |
| |
| .. note:: |
| |
| Prefer to use ``SmallVectorImpl<T>`` as a parameter type. |
| |
| In APIs that don't care about the "small size" (most?), prefer to use |
| the ``SmallVectorImpl<T>`` class, which is basically just the "vector |
| header" (and methods) without the elements allocated after it. Note that |
| ``SmallVector<T, N>`` inherits from ``SmallVectorImpl<T>`` so the |
| conversion is implicit and costs nothing. E.g. |
| |
| .. code-block:: c++ |
| |
| // BAD: Clients cannot pass e.g. SmallVector<Foo, 4>. |
| hardcodedSmallSize(SmallVector<Foo, 2> &Out); |
| // GOOD: Clients can pass any SmallVector<Foo, N>. |
| allowsAnySmallSize(SmallVectorImpl<Foo> &Out); |
| |
| void someFunc() { |
| SmallVector<Foo, 8> Vec; |
| hardcodedSmallSize(Vec); // Error. |
| allowsAnySmallSize(Vec); // Works. |
| } |
| |
| Even though it has "``Impl``" in the name, this is so widely used that |
| it really isn't "private to the implementation" anymore. A name like |
| ``SmallVectorHeader`` would be more appropriate. |
| |
| .. _dss_vector: |
| |
| <vector> |
| ^^^^^^^^ |
| |
| ``std::vector`` is well loved and respected. It is useful when SmallVector |
| isn't: when the size of the vector is often large (thus the small optimization |
| will rarely be a benefit) or if you will be allocating many instances of the |
| vector itself (which would waste space for elements that aren't in the |
| container). vector is also useful when interfacing with code that expects |
| vectors :). |
| |
| One worthwhile note about std::vector: avoid code like this: |
| |
| .. code-block:: c++ |
| |
| for ( ... ) { |
| std::vector<foo> V; |
| // make use of V. |
| } |
| |
| Instead, write this as: |
| |
| .. code-block:: c++ |
| |
| std::vector<foo> V; |
| for ( ... ) { |
| // make use of V. |
| V.clear(); |
| } |
| |
| Doing so will save (at least) one heap allocation and free per iteration of the |
| loop. |
| |
| .. _dss_deque: |
| |
| <deque> |
| ^^^^^^^ |
| |
| ``std::deque`` is, in some senses, a generalized version of ``std::vector``. |
| Like ``std::vector``, it provides constant time random access and other similar |
| properties, but it also provides efficient access to the front of the list. It |
| does not guarantee continuity of elements within memory. |
| |
| In exchange for this extra flexibility, ``std::deque`` has significantly higher |
| constant factor costs than ``std::vector``. If possible, use ``std::vector`` or |
| something cheaper. |
| |
| .. _dss_list: |
| |
| <list> |
| ^^^^^^ |
| |
| ``std::list`` is an extremely inefficient class that is rarely useful. It |
| performs a heap allocation for every element inserted into it, thus having an |
| extremely high constant factor, particularly for small data types. |
| ``std::list`` also only supports bidirectional iteration, not random access |
| iteration. |
| |
| In exchange for this high cost, std::list supports efficient access to both ends |
| of the list (like ``std::deque``, but unlike ``std::vector`` or |
| ``SmallVector``). In addition, the iterator invalidation characteristics of |
| std::list are stronger than that of a vector class: inserting or removing an |
| element into the list does not invalidate iterator or pointers to other elements |
| in the list. |
| |
| .. _dss_ilist: |
| |
| llvm/ADT/ilist.h |
| ^^^^^^^^^^^^^^^^ |
| |
| ``ilist<T>`` implements an 'intrusive' doubly-linked list. It is intrusive, |
| because it requires the element to store and provide access to the prev/next |
| pointers for the list. |
| |
| ``ilist`` has the same drawbacks as ``std::list``, and additionally requires an |
| ``ilist_traits`` implementation for the element type, but it provides some novel |
| characteristics. In particular, it can efficiently store polymorphic objects, |
| the traits class is informed when an element is inserted or removed from the |
| list, and ``ilist``\ s are guaranteed to support a constant-time splice |
| operation. |
| |
| These properties are exactly what we want for things like ``Instruction``\ s and |
| basic blocks, which is why these are implemented with ``ilist``\ s. |
| |
| Related classes of interest are explained in the following subsections: |
| |
| * :ref:`ilist_traits <dss_ilist_traits>` |
| |
| * :ref:`iplist <dss_iplist>` |
| |
| * :ref:`llvm/ADT/ilist_node.h <dss_ilist_node>` |
| |
| * :ref:`Sentinels <dss_ilist_sentinel>` |
| |
| .. _dss_packedvector: |
| |
| llvm/ADT/PackedVector.h |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Useful for storing a vector of values using only a few number of bits for each |
| value. Apart from the standard operations of a vector-like container, it can |
| also perform an 'or' set operation. |
| |
| For example: |
| |
| .. code-block:: c++ |
| |
| enum State { |
| None = 0x0, |
| FirstCondition = 0x1, |
| SecondCondition = 0x2, |
| Both = 0x3 |
| }; |
| |
| State get() { |
| PackedVector<State, 2> Vec1; |
| Vec1.push_back(FirstCondition); |
| |
| PackedVector<State, 2> Vec2; |
| Vec2.push_back(SecondCondition); |
| |
| Vec1 |= Vec2; |
| return Vec1[0]; // returns 'Both'. |
| } |
| |
| .. _dss_ilist_traits: |
| |
| ilist_traits |
| ^^^^^^^^^^^^ |
| |
| ``ilist_traits<T>`` is ``ilist<T>``'s customization mechanism. ``iplist<T>`` |
| (and consequently ``ilist<T>``) publicly derive from this traits class. |
| |
| .. _dss_iplist: |
| |
| iplist |
| ^^^^^^ |
| |
| ``iplist<T>`` is ``ilist<T>``'s base and as such supports a slightly narrower |
| interface. Notably, inserters from ``T&`` are absent. |
| |
| ``ilist_traits<T>`` is a public base of this class and can be used for a wide |
| variety of customizations. |
| |
| .. _dss_ilist_node: |
| |
| llvm/ADT/ilist_node.h |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| ``ilist_node<T>`` implements a the forward and backward links that are expected |
| by the ``ilist<T>`` (and analogous containers) in the default manner. |
| |
| ``ilist_node<T>``\ s are meant to be embedded in the node type ``T``, usually |
| ``T`` publicly derives from ``ilist_node<T>``. |
| |
| .. _dss_ilist_sentinel: |
| |
| Sentinels |
| ^^^^^^^^^ |
| |
| ``ilist``\ s have another specialty that must be considered. To be a good |
| citizen in the C++ ecosystem, it needs to support the standard container |
| operations, such as ``begin`` and ``end`` iterators, etc. Also, the |
| ``operator--`` must work correctly on the ``end`` iterator in the case of |
| non-empty ``ilist``\ s. |
| |
| The only sensible solution to this problem is to allocate a so-called *sentinel* |
| along with the intrusive list, which serves as the ``end`` iterator, providing |
| the back-link to the last element. However conforming to the C++ convention it |
| is illegal to ``operator++`` beyond the sentinel and it also must not be |
| dereferenced. |
| |
| These constraints allow for some implementation freedom to the ``ilist`` how to |
| allocate and store the sentinel. The corresponding policy is dictated by |
| ``ilist_traits<T>``. By default a ``T`` gets heap-allocated whenever the need |
| for a sentinel arises. |
| |
| While the default policy is sufficient in most cases, it may break down when |
| ``T`` does not provide a default constructor. Also, in the case of many |
| instances of ``ilist``\ s, the memory overhead of the associated sentinels is |
| wasted. To alleviate the situation with numerous and voluminous |
| ``T``-sentinels, sometimes a trick is employed, leading to *ghostly sentinels*. |
| |
| Ghostly sentinels are obtained by specially-crafted ``ilist_traits<T>`` which |
| superpose the sentinel with the ``ilist`` instance in memory. Pointer |
| arithmetic is used to obtain the sentinel, which is relative to the ``ilist``'s |
| ``this`` pointer. The ``ilist`` is augmented by an extra pointer, which serves |
| as the back-link of the sentinel. This is the only field in the ghostly |
| sentinel which can be legally accessed. |
| |
| .. _dss_other: |
| |
| Other Sequential Container options |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Other STL containers are available, such as ``std::string``. |
| |
| There are also various STL adapter classes such as ``std::queue``, |
| ``std::priority_queue``, ``std::stack``, etc. These provide simplified access |
| to an underlying container but don't affect the cost of the container itself. |
| |
| .. _ds_string: |
| |
| String-like containers |
| ---------------------- |
| |
| There are a variety of ways to pass around and use strings in C and C++, and |
| LLVM adds a few new options to choose from. Pick the first option on this list |
| that will do what you need, they are ordered according to their relative cost. |
| |
| Note that is is generally preferred to *not* pass strings around as ``const |
| char*``'s. These have a number of problems, including the fact that they |
| cannot represent embedded nul ("\0") characters, and do not have a length |
| available efficiently. The general replacement for '``const char*``' is |
| StringRef. |
| |
| For more information on choosing string containers for APIs, please see |
| :ref:`Passing Strings <string_apis>`. |
| |
| .. _dss_stringref: |
| |
| llvm/ADT/StringRef.h |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| The StringRef class is a simple value class that contains a pointer to a |
| character and a length, and is quite related to the :ref:`ArrayRef |
| <dss_arrayref>` class (but specialized for arrays of characters). Because |
| StringRef carries a length with it, it safely handles strings with embedded nul |
| characters in it, getting the length does not require a strlen call, and it even |
| has very convenient APIs for slicing and dicing the character range that it |
| represents. |
| |
| StringRef is ideal for passing simple strings around that are known to be live, |
| either because they are C string literals, std::string, a C array, or a |
| SmallVector. Each of these cases has an efficient implicit conversion to |
| StringRef, which doesn't result in a dynamic strlen being executed. |
| |
| StringRef has a few major limitations which make more powerful string containers |
| useful: |
| |
| #. You cannot directly convert a StringRef to a 'const char*' because there is |
| no way to add a trailing nul (unlike the .c_str() method on various stronger |
| classes). |
| |
| #. StringRef doesn't own or keep alive the underlying string bytes. |
| As such it can easily lead to dangling pointers, and is not suitable for |
| embedding in datastructures in most cases (instead, use an std::string or |
| something like that). |
| |
| #. For the same reason, StringRef cannot be used as the return value of a |
| method if the method "computes" the result string. Instead, use std::string. |
| |
| #. StringRef's do not allow you to mutate the pointed-to string bytes and it |
| doesn't allow you to insert or remove bytes from the range. For editing |
| operations like this, it interoperates with the :ref:`Twine <dss_twine>` |
| class. |
| |
| Because of its strengths and limitations, it is very common for a function to |
| take a StringRef and for a method on an object to return a StringRef that points |
| into some string that it owns. |
| |
| .. _dss_twine: |
| |
| llvm/ADT/Twine.h |
| ^^^^^^^^^^^^^^^^ |
| |
| The Twine class is used as an intermediary datatype for APIs that want to take a |
| string that can be constructed inline with a series of concatenations. Twine |
| works by forming recursive instances of the Twine datatype (a simple value |
| object) on the stack as temporary objects, linking them together into a tree |
| which is then linearized when the Twine is consumed. Twine is only safe to use |
| as the argument to a function, and should always be a const reference, e.g.: |
| |
| .. code-block:: c++ |
| |
| void foo(const Twine &T); |
| ... |
| StringRef X = ... |
| unsigned i = ... |
| foo(X + "." + Twine(i)); |
| |
| This example forms a string like "blarg.42" by concatenating the values |
| together, and does not form intermediate strings containing "blarg" or "blarg.". |
| |
| Because Twine is constructed with temporary objects on the stack, and because |
| these instances are destroyed at the end of the current statement, it is an |
| inherently dangerous API. For example, this simple variant contains undefined |
| behavior and will probably crash: |
| |
| .. code-block:: c++ |
| |
| void foo(const Twine &T); |
| ... |
| StringRef X = ... |
| unsigned i = ... |
| const Twine &Tmp = X + "." + Twine(i); |
| foo(Tmp); |
| |
| ... because the temporaries are destroyed before the call. That said, Twine's |
| are much more efficient than intermediate std::string temporaries, and they work |
| really well with StringRef. Just be aware of their limitations. |
| |
| .. _dss_smallstring: |
| |
| llvm/ADT/SmallString.h |
| ^^^^^^^^^^^^^^^^^^^^^^ |
| |
| SmallString is a subclass of :ref:`SmallVector <dss_smallvector>` that adds some |
| convenience APIs like += that takes StringRef's. SmallString avoids allocating |
| memory in the case when the preallocated space is enough to hold its data, and |
| it calls back to general heap allocation when required. Since it owns its data, |
| it is very safe to use and supports full mutation of the string. |
| |
| Like SmallVector's, the big downside to SmallString is their sizeof. While they |
| are optimized for small strings, they themselves are not particularly small. |
| This means that they work great for temporary scratch buffers on the stack, but |
| should not generally be put into the heap: it is very rare to see a SmallString |
| as the member of a frequently-allocated heap data structure or returned |
| by-value. |
| |
| .. _dss_stdstring: |
| |
| std::string |
| ^^^^^^^^^^^ |
| |
| The standard C++ std::string class is a very general class that (like |
| SmallString) owns its underlying data. sizeof(std::string) is very reasonable |
| so it can be embedded into heap data structures and returned by-value. On the |
| other hand, std::string is highly inefficient for inline editing (e.g. |
| concatenating a bunch of stuff together) and because it is provided by the |
| standard library, its performance characteristics depend a lot of the host |
| standard library (e.g. libc++ and MSVC provide a highly optimized string class, |
| GCC contains a really slow implementation). |
| |
| The major disadvantage of std::string is that almost every operation that makes |
| them larger can allocate memory, which is slow. As such, it is better to use |
| SmallVector or Twine as a scratch buffer, but then use std::string to persist |
| the result. |
| |
| .. _ds_set: |
| |
| Set-Like Containers (std::set, SmallSet, SetVector, etc) |
| -------------------------------------------------------- |
| |
| Set-like containers are useful when you need to canonicalize multiple values |
| into a single representation. There are several different choices for how to do |
| this, providing various trade-offs. |
| |
| .. _dss_sortedvectorset: |
| |
| A sorted 'vector' |
| ^^^^^^^^^^^^^^^^^ |
| |
| If you intend to insert a lot of elements, then do a lot of queries, a great |
| approach is to use a vector (or other sequential container) with |
| std::sort+std::unique to remove duplicates. This approach works really well if |
| your usage pattern has these two distinct phases (insert then query), and can be |
| coupled with a good choice of :ref:`sequential container <ds_sequential>`. |
| |
| This combination provides the several nice properties: the result data is |
| contiguous in memory (good for cache locality), has few allocations, is easy to |
| address (iterators in the final vector are just indices or pointers), and can be |
| efficiently queried with a standard binary search (e.g. |
| ``std::lower_bound``; if you want the whole range of elements comparing |
| equal, use ``std::equal_range``). |
| |
| .. _dss_smallset: |
| |
| llvm/ADT/SmallSet.h |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| If you have a set-like data structure that is usually small and whose elements |
| are reasonably small, a ``SmallSet<Type, N>`` is a good choice. This set has |
| space for N elements in place (thus, if the set is dynamically smaller than N, |
| no malloc traffic is required) and accesses them with a simple linear search. |
| When the set grows beyond 'N' elements, it allocates a more expensive |
| representation that guarantees efficient access (for most types, it falls back |
| to std::set, but for pointers it uses something far better, :ref:`SmallPtrSet |
| <dss_smallptrset>`. |
| |
| The magic of this class is that it handles small sets extremely efficiently, but |
| gracefully handles extremely large sets without loss of efficiency. The |
| drawback is that the interface is quite small: it supports insertion, queries |
| and erasing, but does not support iteration. |
| |
| .. _dss_smallptrset: |
| |
| llvm/ADT/SmallPtrSet.h |
| ^^^^^^^^^^^^^^^^^^^^^^ |
| |
| SmallPtrSet has all the advantages of ``SmallSet`` (and a ``SmallSet`` of |
| pointers is transparently implemented with a ``SmallPtrSet``), but also supports |
| iterators. If more than 'N' insertions are performed, a single quadratically |
| probed hash table is allocated and grows as needed, providing extremely |
| efficient access (constant time insertion/deleting/queries with low constant |
| factors) and is very stingy with malloc traffic. |
| |
| Note that, unlike ``std::set``, the iterators of ``SmallPtrSet`` are invalidated |
| whenever an insertion occurs. Also, the values visited by the iterators are not |
| visited in sorted order. |
| |
| .. _dss_denseset: |
| |
| llvm/ADT/DenseSet.h |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| DenseSet is a simple quadratically probed hash table. It excels at supporting |
| small values: it uses a single allocation to hold all of the pairs that are |
| currently inserted in the set. DenseSet is a great way to unique small values |
| that are not simple pointers (use :ref:`SmallPtrSet <dss_smallptrset>` for |
| pointers). Note that DenseSet has the same requirements for the value type that |
| :ref:`DenseMap <dss_densemap>` has. |
| |
| .. _dss_sparseset: |
| |
| llvm/ADT/SparseSet.h |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| SparseSet holds a small number of objects identified by unsigned keys of |
| moderate size. It uses a lot of memory, but provides operations that are almost |
| as fast as a vector. Typical keys are physical registers, virtual registers, or |
| numbered basic blocks. |
| |
| SparseSet is useful for algorithms that need very fast clear/find/insert/erase |
| and fast iteration over small sets. It is not intended for building composite |
| data structures. |
| |
| .. _dss_sparsemultiset: |
| |
| llvm/ADT/SparseMultiSet.h |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| SparseMultiSet adds multiset behavior to SparseSet, while retaining SparseSet's |
| desirable attributes. Like SparseSet, it typically uses a lot of memory, but |
| provides operations that are almost as fast as a vector. Typical keys are |
| physical registers, virtual registers, or numbered basic blocks. |
| |
| SparseMultiSet is useful for algorithms that need very fast |
| clear/find/insert/erase of the entire collection, and iteration over sets of |
| elements sharing a key. It is often a more efficient choice than using composite |
| data structures (e.g. vector-of-vectors, map-of-vectors). It is not intended for |
| building composite data structures. |
| |
| .. _dss_FoldingSet: |
| |
| llvm/ADT/FoldingSet.h |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| FoldingSet is an aggregate class that is really good at uniquing |
| expensive-to-create or polymorphic objects. It is a combination of a chained |
| hash table with intrusive links (uniqued objects are required to inherit from |
| FoldingSetNode) that uses :ref:`SmallVector <dss_smallvector>` as part of its ID |
| process. |
| |
| Consider a case where you want to implement a "getOrCreateFoo" method for a |
| complex object (for example, a node in the code generator). The client has a |
| description of **what** it wants to generate (it knows the opcode and all the |
| operands), but we don't want to 'new' a node, then try inserting it into a set |
| only to find out it already exists, at which point we would have to delete it |
| and return the node that already exists. |
| |
| To support this style of client, FoldingSet perform a query with a |
| FoldingSetNodeID (which wraps SmallVector) that can be used to describe the |
| element that we want to query for. The query either returns the element |
| matching the ID or it returns an opaque ID that indicates where insertion should |
| take place. Construction of the ID usually does not require heap traffic. |
| |
| Because FoldingSet uses intrusive links, it can support polymorphic objects in |
| the set (for example, you can have SDNode instances mixed with LoadSDNodes). |
| Because the elements are individually allocated, pointers to the elements are |
| stable: inserting or removing elements does not invalidate any pointers to other |
| elements. |
| |
| .. _dss_set: |
| |
| <set> |
| ^^^^^ |
| |
| ``std::set`` is a reasonable all-around set class, which is decent at many |
| things but great at nothing. std::set allocates memory for each element |
| inserted (thus it is very malloc intensive) and typically stores three pointers |
| per element in the set (thus adding a large amount of per-element space |
| overhead). It offers guaranteed log(n) performance, which is not particularly |
| fast from a complexity standpoint (particularly if the elements of the set are |
| expensive to compare, like strings), and has extremely high constant factors for |
| lookup, insertion and removal. |
| |
| The advantages of std::set are that its iterators are stable (deleting or |
| inserting an element from the set does not affect iterators or pointers to other |
| elements) and that iteration over the set is guaranteed to be in sorted order. |
| If the elements in the set are large, then the relative overhead of the pointers |
| and malloc traffic is not a big deal, but if the elements of the set are small, |
| std::set is almost never a good choice. |
| |
| .. _dss_setvector: |
| |
| llvm/ADT/SetVector.h |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| LLVM's ``SetVector<Type>`` is an adapter class that combines your choice of a |
| set-like container along with a :ref:`Sequential Container <ds_sequential>` The |
| important property that this provides is efficient insertion with uniquing |
| (duplicate elements are ignored) with iteration support. It implements this by |
| inserting elements into both a set-like container and the sequential container, |
| using the set-like container for uniquing and the sequential container for |
| iteration. |
| |
| The difference between SetVector and other sets is that the order of iteration |
| is guaranteed to match the order of insertion into the SetVector. This property |
| is really important for things like sets of pointers. Because pointer values |
| are non-deterministic (e.g. vary across runs of the program on different |
| machines), iterating over the pointers in the set will not be in a well-defined |
| order. |
| |
| The drawback of SetVector is that it requires twice as much space as a normal |
| set and has the sum of constant factors from the set-like container and the |
| sequential container that it uses. Use it **only** if you need to iterate over |
| the elements in a deterministic order. SetVector is also expensive to delete |
| elements out of (linear time), unless you use it's "pop_back" method, which is |
| faster. |
| |
| ``SetVector`` is an adapter class that defaults to using ``std::vector`` and a |
| size 16 ``SmallSet`` for the underlying containers, so it is quite expensive. |
| However, ``"llvm/ADT/SetVector.h"`` also provides a ``SmallSetVector`` class, |
| which defaults to using a ``SmallVector`` and ``SmallSet`` of a specified size. |
| If you use this, and if your sets are dynamically smaller than ``N``, you will |
| save a lot of heap traffic. |
| |
| .. _dss_uniquevector: |
| |
| llvm/ADT/UniqueVector.h |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| UniqueVector is similar to :ref:`SetVector <dss_setvector>` but it retains a |
| unique ID for each element inserted into the set. It internally contains a map |
| and a vector, and it assigns a unique ID for each value inserted into the set. |
| |
| UniqueVector is very expensive: its cost is the sum of the cost of maintaining |
| both the map and vector, it has high complexity, high constant factors, and |
| produces a lot of malloc traffic. It should be avoided. |
| |
| .. _dss_immutableset: |
| |
| llvm/ADT/ImmutableSet.h |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| ImmutableSet is an immutable (functional) set implementation based on an AVL |
| tree. Adding or removing elements is done through a Factory object and results |
| in the creation of a new ImmutableSet object. If an ImmutableSet already exists |
| with the given contents, then the existing one is returned; equality is compared |
| with a FoldingSetNodeID. The time and space complexity of add or remove |
| operations is logarithmic in the size of the original set. |
| |
| There is no method for returning an element of the set, you can only check for |
| membership. |
| |
| .. _dss_otherset: |
| |
| Other Set-Like Container Options |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The STL provides several other options, such as std::multiset and the various |
| "hash_set" like containers (whether from C++ TR1 or from the SGI library). We |
| never use hash_set and unordered_set because they are generally very expensive |
| (each insertion requires a malloc) and very non-portable. |
| |
| std::multiset is useful if you're not interested in elimination of duplicates, |
| but has all the drawbacks of std::set. A sorted vector (where you don't delete |
| duplicate entries) or some other approach is almost always better. |
| |
| .. _ds_map: |
| |
| Map-Like Containers (std::map, DenseMap, etc) |
| --------------------------------------------- |
| |
| Map-like containers are useful when you want to associate data to a key. As |
| usual, there are a lot of different ways to do this. :) |
| |
| .. _dss_sortedvectormap: |
| |
| A sorted 'vector' |
| ^^^^^^^^^^^^^^^^^ |
| |
| If your usage pattern follows a strict insert-then-query approach, you can |
| trivially use the same approach as :ref:`sorted vectors for set-like containers |
| <dss_sortedvectorset>`. The only difference is that your query function (which |
| uses std::lower_bound to get efficient log(n) lookup) should only compare the |
| key, not both the key and value. This yields the same advantages as sorted |
| vectors for sets. |
| |
| .. _dss_stringmap: |
| |
| llvm/ADT/StringMap.h |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| Strings are commonly used as keys in maps, and they are difficult to support |
| efficiently: they are variable length, inefficient to hash and compare when |
| long, expensive to copy, etc. StringMap is a specialized container designed to |
| cope with these issues. It supports mapping an arbitrary range of bytes to an |
| arbitrary other object. |
| |
| The StringMap implementation uses a quadratically-probed hash table, where the |
| buckets store a pointer to the heap allocated entries (and some other stuff). |
| The entries in the map must be heap allocated because the strings are variable |
| length. The string data (key) and the element object (value) are stored in the |
| same allocation with the string data immediately after the element object. |
| This container guarantees the "``(char*)(&Value+1)``" points to the key string |
| for a value. |
| |
| The StringMap is very fast for several reasons: quadratic probing is very cache |
| efficient for lookups, the hash value of strings in buckets is not recomputed |
| when looking up an element, StringMap rarely has to touch the memory for |
| unrelated objects when looking up a value (even when hash collisions happen), |
| hash table growth does not recompute the hash values for strings already in the |
| table, and each pair in the map is store in a single allocation (the string data |
| is stored in the same allocation as the Value of a pair). |
| |
| StringMap also provides query methods that take byte ranges, so it only ever |
| copies a string if a value is inserted into the table. |
| |
| StringMap iteratation order, however, is not guaranteed to be deterministic, so |
| any uses which require that should instead use a std::map. |
| |
| .. _dss_indexmap: |
| |
| llvm/ADT/IndexedMap.h |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| IndexedMap is a specialized container for mapping small dense integers (or |
| values that can be mapped to small dense integers) to some other type. It is |
| internally implemented as a vector with a mapping function that maps the keys |
| to the dense integer range. |
| |
| This is useful for cases like virtual registers in the LLVM code generator: they |
| have a dense mapping that is offset by a compile-time constant (the first |
| virtual register ID). |
| |
| .. _dss_densemap: |
| |
| llvm/ADT/DenseMap.h |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| DenseMap is a simple quadratically probed hash table. It excels at supporting |
| small keys and values: it uses a single allocation to hold all of the pairs |
| that are currently inserted in the map. DenseMap is a great way to map |
| pointers to pointers, or map other small types to each other. |
| |
| There are several aspects of DenseMap that you should be aware of, however. |
| The iterators in a DenseMap are invalidated whenever an insertion occurs, |
| unlike map. Also, because DenseMap allocates space for a large number of |
| key/value pairs (it starts with 64 by default), it will waste a lot of space if |
| your keys or values are large. Finally, you must implement a partial |
| specialization of DenseMapInfo for the key that you want, if it isn't already |
| supported. This is required to tell DenseMap about two special marker values |
| (which can never be inserted into the map) that it needs internally. |
| |
| DenseMap's find_as() method supports lookup operations using an alternate key |
| type. This is useful in cases where the normal key type is expensive to |
| construct, but cheap to compare against. The DenseMapInfo is responsible for |
| defining the appropriate comparison and hashing methods for each alternate key |
| type used. |
| |
| .. _dss_valuemap: |
| |
| llvm/ADT/ValueMap.h |
| ^^^^^^^^^^^^^^^^^^^ |
| |
| ValueMap is a wrapper around a :ref:`DenseMap <dss_densemap>` mapping |
| ``Value*``\ s (or subclasses) to another type. When a Value is deleted or |
| RAUW'ed, ValueMap will update itself so the new version of the key is mapped to |
| the same value, just as if the key were a WeakVH. You can configure exactly how |
| this happens, and what else happens on these two events, by passing a ``Config`` |
| parameter to the ValueMap template. |
| |
| .. _dss_intervalmap: |
| |
| llvm/ADT/IntervalMap.h |
| ^^^^^^^^^^^^^^^^^^^^^^ |
| |
| IntervalMap is a compact map for small keys and values. It maps key intervals |
| instead of single keys, and it will automatically coalesce adjacent intervals. |
| When then map only contains a few intervals, they are stored in the map object |
| itself to avoid allocations. |
| |
| The IntervalMap iterators are quite big, so they should not be passed around as |
| STL iterators. The heavyweight iterators allow a smaller data structure. |
| |
| .. _dss_map: |
| |
| <map> |
| ^^^^^ |
| |
| std::map has similar characteristics to :ref:`std::set <dss_set>`: it uses a |
| single allocation per pair inserted into the map, it offers log(n) lookup with |
| an extremely large constant factor, imposes a space penalty of 3 pointers per |
| pair in the map, etc. |
| |
| std::map is most useful when your keys or values are very large, if you need to |
| iterate over the collection in sorted order, or if you need stable iterators |
| into the map (i.e. they don't get invalidated if an insertion or deletion of |
| another element takes place). |
| |
| .. _dss_mapvector: |
| |
| llvm/ADT/MapVector.h |
| ^^^^^^^^^^^^^^^^^^^^ |
| |
| ``MapVector<KeyT,ValueT>`` provides a subset of the DenseMap interface. The |
| main difference is that the iteration order is guaranteed to be the insertion |
| order, making it an easy (but somewhat expensive) solution for non-deterministic |
| iteration over maps of pointers. |
| |
| It is implemented by mapping from key to an index in a vector of key,value |
| pairs. This provides fast lookup and iteration, but has two main drawbacks: The |
| key is stored twice and it doesn't support removing elements. |
| |
| .. _dss_inteqclasses: |
| |
| llvm/ADT/IntEqClasses.h |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| IntEqClasses provides a compact representation of equivalence classes of small |
| integers. Initially, each integer in the range 0..n-1 has its own equivalence |
| class. Classes can be joined by passing two class representatives to the |
| join(a, b) method. Two integers are in the same class when findLeader() returns |
| the same representative. |
| |
| Once all equivalence classes are formed, the map can be compressed so each |
| integer 0..n-1 maps to an equivalence class number in the range 0..m-1, where m |
| is the total number of equivalence classes. The map must be uncompressed before |
| it can be edited again. |
| |
| .. _dss_immutablemap: |
| |
| llvm/ADT/ImmutableMap.h |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| ImmutableMap is an immutable (functional) map implementation based on an AVL |
| tree. Adding or removing elements is done through a Factory object and results |
| in the creation of a new ImmutableMap object. If an ImmutableMap already exists |
| with the given key set, then the existing one is returned; equality is compared |
| with a FoldingSetNodeID. The time and space complexity of add or remove |
| operations is logarithmic in the size of the original map. |
| |
| .. _dss_othermap: |
| |
| Other Map-Like Container Options |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The STL provides several other options, such as std::multimap and the various |
| "hash_map" like containers (whether from C++ TR1 or from the SGI library). We |
| never use hash_set and unordered_set because they are generally very expensive |
| (each insertion requires a malloc) and very non-portable. |
| |
| std::multimap is useful if you want to map a key to multiple values, but has all |
| the drawbacks of std::map. A sorted vector or some other approach is almost |
| always better. |
| |
| .. _ds_bit: |
| |
| Bit storage containers (BitVector, SparseBitVector) |
| --------------------------------------------------- |
| |
| Unlike the other containers, there are only two bit storage containers, and |
| choosing when to use each is relatively straightforward. |
| |
| One additional option is ``std::vector<bool>``: we discourage its use for two |
| reasons 1) the implementation in many common compilers (e.g. commonly |
| available versions of GCC) is extremely inefficient and 2) the C++ standards |
| committee is likely to deprecate this container and/or change it significantly |
| somehow. In any case, please don't use it. |
| |
| .. _dss_bitvector: |
| |
| BitVector |
| ^^^^^^^^^ |
| |
| The BitVector container provides a dynamic size set of bits for manipulation. |
| It supports individual bit setting/testing, as well as set operations. The set |
| operations take time O(size of bitvector), but operations are performed one word |
| at a time, instead of one bit at a time. This makes the BitVector very fast for |
| set operations compared to other containers. Use the BitVector when you expect |
| the number of set bits to be high (i.e. a dense set). |
| |
| .. _dss_smallbitvector: |
| |
| SmallBitVector |
| ^^^^^^^^^^^^^^ |
| |
| The SmallBitVector container provides the same interface as BitVector, but it is |
| optimized for the case where only a small number of bits, less than 25 or so, |
| are needed. It also transparently supports larger bit counts, but slightly less |
| efficiently than a plain BitVector, so SmallBitVector should only be used when |
| larger counts are rare. |
| |
| At this time, SmallBitVector does not support set operations (and, or, xor), and |
| its operator[] does not provide an assignable lvalue. |
| |
| .. _dss_sparsebitvector: |
| |
| SparseBitVector |
| ^^^^^^^^^^^^^^^ |
| |
| The SparseBitVector container is much like BitVector, with one major difference: |
| Only the bits that are set, are stored. This makes the SparseBitVector much |
| more space efficient than BitVector when the set is sparse, as well as making |
| set operations O(number of set bits) instead of O(size of universe). The |
| downside to the SparseBitVector is that setting and testing of random bits is |
| O(N), and on large SparseBitVectors, this can be slower than BitVector. In our |
| implementation, setting or testing bits in sorted order (either forwards or |
| reverse) is O(1) worst case. Testing and setting bits within 128 bits (depends |
| on size) of the current bit is also O(1). As a general statement, |
| testing/setting bits in a SparseBitVector is O(distance away from last set bit). |
| |
| .. _common: |
| |
| Helpful Hints for Common Operations |
| =================================== |
| |
| This section describes how to perform some very simple transformations of LLVM |
| code. This is meant to give examples of common idioms used, showing the |
| practical side of LLVM transformations. |
| |
| Because this is a "how-to" section, you should also read about the main classes |
| that you will be working with. The :ref:`Core LLVM Class Hierarchy Reference |
| <coreclasses>` contains details and descriptions of the main classes that you |
| should know about. |
| |
| .. _inspection: |
| |
| Basic Inspection and Traversal Routines |
| --------------------------------------- |
| |
| The LLVM compiler infrastructure have many different data structures that may be |
| traversed. Following the example of the C++ standard template library, the |
| techniques used to traverse these various data structures are all basically the |
| same. For a enumerable sequence of values, the ``XXXbegin()`` function (or |
| method) returns an iterator to the start of the sequence, the ``XXXend()`` |
| function returns an iterator pointing to one past the last valid element of the |
| sequence, and there is some ``XXXiterator`` data type that is common between the |
| two operations. |
| |
| Because the pattern for iteration is common across many different aspects of the |
| program representation, the standard template library algorithms may be used on |
| them, and it is easier to remember how to iterate. First we show a few common |
| examples of the data structures that need to be traversed. Other data |
| structures are traversed in very similar ways. |
| |
| .. _iterate_function: |
| |
| Iterating over the ``BasicBlock`` in a ``Function`` |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| It's quite common to have a ``Function`` instance that you'd like to transform |
| in some way; in particular, you'd like to manipulate its ``BasicBlock``\ s. To |
| facilitate this, you'll need to iterate over all of the ``BasicBlock``\ s that |
| constitute the ``Function``. The following is an example that prints the name |
| of a ``BasicBlock`` and the number of ``Instruction``\ s it contains: |
| |
| .. code-block:: c++ |
| |
| // func is a pointer to a Function instance |
| for (Function::iterator i = func->begin(), e = func->end(); i != e; ++i) |
| // Print out the name of the basic block if it has one, and then the |
| // number of instructions that it contains |
| errs() << "Basic block (name=" << i->getName() << ") has " |
| << i->size() << " instructions.\n"; |
| |
| Note that i can be used as if it were a pointer for the purposes of invoking |
| member functions of the ``Instruction`` class. This is because the indirection |
| operator is overloaded for the iterator classes. In the above code, the |
| expression ``i->size()`` is exactly equivalent to ``(*i).size()`` just like |
| you'd expect. |
| |
| .. _iterate_basicblock: |
| |
| Iterating over the ``Instruction`` in a ``BasicBlock`` |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Just like when dealing with ``BasicBlock``\ s in ``Function``\ s, it's easy to |
| iterate over the individual instructions that make up ``BasicBlock``\ s. Here's |
| a code snippet that prints out each instruction in a ``BasicBlock``: |
| |
| .. code-block:: c++ |
| |
| // blk is a pointer to a BasicBlock instance |
| for (BasicBlock::iterator i = blk->begin(), e = blk->end(); i != e; ++i) |
| // The next statement works since operator<<(ostream&,...) |
| // is overloaded for Instruction& |
| errs() << *i << "\n"; |
| |
| |
| However, this isn't really the best way to print out the contents of a |
| ``BasicBlock``! Since the ostream operators are overloaded for virtually |
| anything you'll care about, you could have just invoked the print routine on the |
| basic block itself: ``errs() << *blk << "\n";``. |
| |
| .. _iterate_insiter: |
| |
| Iterating over the ``Instruction`` in a ``Function`` |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| If you're finding that you commonly iterate over a ``Function``'s |
| ``BasicBlock``\ s and then that ``BasicBlock``'s ``Instruction``\ s, |
| ``InstIterator`` should be used instead. You'll need to include |
| ``llvm/Support/InstIterator.h`` (`doxygen |
| <http://llvm.org/doxygen/InstIterator_8h-source.html>`__) and then instantiate |
| ``InstIterator``\ s explicitly in your code. Here's a small example that shows |
| how to dump all instructions in a function to the standard error stream: |
| |
| .. code-block:: c++ |
| |
| #include "llvm/Support/InstIterator.h" |
| |
| // F is a pointer to a Function instance |
| for (inst_iterator I = inst_begin(F), E = inst_end(F); I != E; ++I) |
| errs() << *I << "\n"; |
| |
| Easy, isn't it? You can also use ``InstIterator``\ s to fill a work list with |
| its initial contents. For example, if you wanted to initialize a work list to |
| contain all instructions in a ``Function`` F, all you would need to do is |
| something like: |
| |
| .. code-block:: c++ |
| |
| std::set<Instruction*> worklist; |
| // or better yet, SmallPtrSet<Instruction*, 64> worklist; |
| |
| for (inst_iterator I = inst_begin(F), E = inst_end(F); I != E; ++I) |
| worklist.insert(&*I); |
| |
| The STL set ``worklist`` would now contain all instructions in the ``Function`` |
| pointed to by F. |
| |
| .. _iterate_convert: |
| |
| Turning an iterator into a class pointer (and vice-versa) |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Sometimes, it'll be useful to grab a reference (or pointer) to a class instance |
| when all you've got at hand is an iterator. Well, extracting a reference or a |
| pointer from an iterator is very straight-forward. Assuming that ``i`` is a |
| ``BasicBlock::iterator`` and ``j`` is a ``BasicBlock::const_iterator``: |
| |
| .. code-block:: c++ |
| |
| Instruction& inst = *i; // Grab reference to instruction reference |
| Instruction* pinst = &*i; // Grab pointer to instruction reference |
| const Instruction& inst = *j; |
| |
| However, the iterators you'll be working with in the LLVM framework are special: |
| they will automatically convert to a ptr-to-instance type whenever they need to. |
| Instead of derferencing the iterator and then taking the address of the result, |
| you can simply assign the iterator to the proper pointer type and you get the |
| dereference and address-of operation as a result of the assignment (behind the |
| scenes, this is a result of overloading casting mechanisms). Thus the last line |
| of the last example, |
| |
| .. code-block:: c++ |
| |
| Instruction *pinst = &*i; |
| |
| is semantically equivalent to |
| |
| .. code-block:: c++ |
| |
| Instruction *pinst = i; |
| |
| It's also possible to turn a class pointer into the corresponding iterator, and |
| this is a constant time operation (very efficient). The following code snippet |
| illustrates use of the conversion constructors provided by LLVM iterators. By |
| using these, you can explicitly grab the iterator of something without actually |
| obtaining it via iteration over some structure: |
| |
| .. code-block:: c++ |
| |
| void printNextInstruction(Instruction* inst) { |
| BasicBlock::iterator it(inst); |
| ++it; // After this line, it refers to the instruction after *inst |
| if (it != inst->getParent()->end()) errs() << *it << "\n"; |
| } |
| |
| Unfortunately, these implicit conversions come at a cost; they prevent these |
| iterators from conforming to standard iterator conventions, and thus from being |
| usable with standard algorithms and containers. For example, they prevent the |
| following code, where ``B`` is a ``BasicBlock``, from compiling: |
| |
| .. code-block:: c++ |
| |
| llvm::SmallVector<llvm::Instruction *, 16>(B->begin(), B->end()); |
| |
| Because of this, these implicit conversions may be removed some day, and |
| ``operator*`` changed to return a pointer instead of a reference. |
| |
| .. _iterate_complex: |
| |
| Finding call sites: a slightly more complex example |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Say that you're writing a FunctionPass and would like to count all the locations |
| in the entire module (that is, across every ``Function``) where a certain |
| function (i.e., some ``Function *``) is already in scope. As you'll learn |
| later, you may want to use an ``InstVisitor`` to accomplish this in a much more |
| straight-forward manner, but this example will allow us to explore how you'd do |
| it if you didn't have ``InstVisitor`` around. In pseudo-code, this is what we |
| want to do: |
| |
| .. code-block:: none |
| |
| initialize callCounter to zero |
| for each Function f in the Module |
| for each BasicBlock b in f |
| for each Instruction i in b |
| if (i is a CallInst and calls the given function) |
| increment callCounter |
| |
| And the actual code is (remember, because we're writing a ``FunctionPass``, our |
| ``FunctionPass``-derived class simply has to override the ``runOnFunction`` |
| method): |
| |
| .. code-block:: c++ |
| |
| Function* targetFunc = ...; |
| |
| class OurFunctionPass : public FunctionPass { |
| public: |
| OurFunctionPass(): callCounter(0) { } |
| |
| virtual runOnFunction(Function& F) { |
| for (Function::iterator b = F.begin(), be = F.end(); b != be; ++b) { |
| for (BasicBlock::iterator i = b->begin(), ie = b->end(); i != ie; ++i) { |
| if (CallInst* callInst = dyn_cast<CallInst>(&*i)) { |
| // We know we've encountered a call instruction, so we |
| // need to determine if it's a call to the |
| // function pointed to by m_func or not. |
| if (callInst->getCalledFunction() == targetFunc) |
| ++callCounter; |
| } |
| } |
| } |
| } |
| |
| private: |
| unsigned callCounter; |
| }; |
| |
| .. _calls_and_invokes: |
| |
| Treating calls and invokes the same way |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| You may have noticed that the previous example was a bit oversimplified in that |
| it did not deal with call sites generated by 'invoke' instructions. In this, |
| and in other situations, you may find that you want to treat ``CallInst``\ s and |
| ``InvokeInst``\ s the same way, even though their most-specific common base |
| class is ``Instruction``, which includes lots of less closely-related things. |
| For these cases, LLVM provides a handy wrapper class called ``CallSite`` |
| (`doxygen <http://llvm.org/doxygen/classllvm_1_1CallSite.html>`__) It is |
| essentially a wrapper around an ``Instruction`` pointer, with some methods that |
| provide functionality common to ``CallInst``\ s and ``InvokeInst``\ s. |
| |
| This class has "value semantics": it should be passed by value, not by reference |
| and it should not be dynamically allocated or deallocated using ``operator new`` |
| or ``operator delete``. It is efficiently copyable, assignable and |
| constructable, with costs equivalents to that of a bare pointer. If you look at |
| its definition, it has only a single pointer member. |
| |
| .. _iterate_chains: |
| |
| Iterating over def-use & use-def chains |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Frequently, we might have an instance of the ``Value`` class (`doxygen |
| <http://llvm.org/doxygen/classllvm_1_1Value.html>`__) and we want to determine |
| which ``User`` s use the ``Value``. The list of all ``User``\ s of a particular |
| ``Value`` is called a *def-use* chain. For example, let's say we have a |
| ``Function*`` named ``F`` to a particular function ``foo``. Finding all of the |
| instructions that *use* ``foo`` is as simple as iterating over the *def-use* |
| chain of ``F``: |
| |
| .. code-block:: c++ |
| |
| Function *F = ...; |
| |
| for (Value::use_iterator i = F->use_begin(), e = F->use_end(); i != e; ++i) |
| if (Instruction *Inst = dyn_cast<Instruction>(*i)) { |
| errs() << "F is used in instruction:\n"; |
| errs() << *Inst << "\n"; |
| } |
| |
| Note that dereferencing a ``Value::use_iterator`` is not a very cheap operation. |
| Instead of performing ``*i`` above several times, consider doing it only once in |
| the loop body and reusing its result. |
| |
| Alternatively, it's common to have an instance of the ``User`` Class (`doxygen |
| <http://llvm.org/doxygen/classllvm_1_1User.html>`__) and need to know what |
| ``Value``\ s are used by it. The list of all ``Value``\ s used by a ``User`` is |
| known as a *use-def* chain. Instances of class ``Instruction`` are common |
| ``User`` s, so we might want to iterate over all of the values that a particular |
| instruction uses (that is, the operands of the particular ``Instruction``): |
| |
| .. code-block:: c++ |
| |
| Instruction *pi = ...; |
| |
| for (User::op_iterator i = pi->op_begin(), e = pi->op_end(); i != e; ++i) { |
| Value *v = *i; |
| // ... |
| } |
| |
| Declaring objects as ``const`` is an important tool of enforcing mutation free |
| algorithms (such as analyses, etc.). For this purpose above iterators come in |
| constant flavors as ``Value::const_use_iterator`` and |
| ``Value::const_op_iterator``. They automatically arise when calling |
| ``use/op_begin()`` on ``const Value*``\ s or ``const User*``\ s respectively. |
| Upon dereferencing, they return ``const Use*``\ s. Otherwise the above patterns |
| remain unchanged. |
| |
| .. _iterate_preds: |
| |
| Iterating over predecessors & successors of blocks |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Iterating over the predecessors and successors of a block is quite easy with the |
| routines defined in ``"llvm/Support/CFG.h"``. Just use code like this to |
| iterate over all predecessors of BB: |
| |
| .. code-block:: c++ |
| |
| #include "llvm/Support/CFG.h" |
| BasicBlock *BB = ...; |
| |
| for (pred_iterator PI = pred_begin(BB), E = pred_end(BB); PI != E; ++PI) { |
| BasicBlock *Pred = *PI; |
| // ... |
| } |
| |
| Similarly, to iterate over successors use ``succ_iterator/succ_begin/succ_end``. |
| |
| .. _simplechanges: |
| |
| Making simple changes |
| --------------------- |
| |
| There are some primitive transformation operations present in the LLVM |
| infrastructure that are worth knowing about. When performing transformations, |
| it's fairly common to manipulate the contents of basic blocks. This section |
| describes some of the common methods for doing so and gives example code. |
| |
| .. _schanges_creating: |
| |
| Creating and inserting new ``Instruction``\ s |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| *Instantiating Instructions* |
| |
| Creation of ``Instruction``\ s is straight-forward: simply call the constructor |
| for the kind of instruction to instantiate and provide the necessary parameters. |
| For example, an ``AllocaInst`` only *requires* a (const-ptr-to) ``Type``. Thus: |
| |
| .. code-block:: c++ |
| |
| AllocaInst* ai = new AllocaInst(Type::Int32Ty); |
| |
| will create an ``AllocaInst`` instance that represents the allocation of one |
| integer in the current stack frame, at run time. Each ``Instruction`` subclass |
| is likely to have varying default parameters which change the semantics of the |
| instruction, so refer to the `doxygen documentation for the subclass of |
| Instruction <http://llvm.org/doxygen/classllvm_1_1Instruction.html>`_ that |
| you're interested in instantiating. |
| |
| *Naming values* |
| |
| It is very useful to name the values of instructions when you're able to, as |
| this facilitates the debugging of your transformations. If you end up looking |
| at generated LLVM machine code, you definitely want to have logical names |
| associated with the results of instructions! By supplying a value for the |
| ``Name`` (default) parameter of the ``Instruction`` constructor, you associate a |
| logical name with the result of the instruction's execution at run time. For |
| example, say that I'm writing a transformation that dynamically allocates space |
| for an integer on the stack, and that integer is going to be used as some kind |
| of index by some other code. To accomplish this, I place an ``AllocaInst`` at |
| the first point in the first ``BasicBlock`` of some ``Function``, and I'm |
| intending to use it within the same ``Function``. I might do: |
| |
| .. code-block:: c++ |
| |
| AllocaInst* pa = new AllocaInst(Type::Int32Ty, 0, "indexLoc"); |
| |
| where ``indexLoc`` is now the logical name of the instruction's execution value, |
| which is a pointer to an integer on the run time stack. |
| |
| *Inserting instructions* |
| |
| There are essentially two ways to insert an ``Instruction`` into an existing |
| sequence of instructions that form a ``BasicBlock``: |
| |
| * Insertion into an explicit instruction list |
| |
| Given a ``BasicBlock* pb``, an ``Instruction* pi`` within that ``BasicBlock``, |
| and a newly-created instruction we wish to insert before ``*pi``, we do the |
| following: |
| |
| .. code-block:: c++ |
| |
| BasicBlock *pb = ...; |
| Instruction *pi = ...; |
| Instruction *newInst = new Instruction(...); |
| |
| pb->getInstList().insert(pi, newInst); // Inserts newInst before pi in pb |
| |
| Appending to the end of a ``BasicBlock`` is so common that the ``Instruction`` |
| class and ``Instruction``-derived classes provide constructors which take a |
| pointer to a ``BasicBlock`` to be appended to. For example code that looked |
| like: |
| |
| .. code-block:: c++ |
| |
| BasicBlock *pb = ...; |
| Instruction *newInst = new Instruction(...); |
| |
| pb->getInstList().push_back(newInst); // Appends newInst to pb |
| |
| becomes: |
| |
| .. code-block:: c++ |
| |
| BasicBlock *pb = ...; |
| Instruction *newInst = new Instruction(..., pb); |
| |
| which is much cleaner, especially if you are creating long instruction |
| streams. |
| |
| * Insertion into an implicit instruction list |
| |
| ``Instruction`` instances that are already in ``BasicBlock``\ s are implicitly |
| associated with an existing instruction list: the instruction list of the |
| enclosing basic block. Thus, we could have accomplished the same thing as the |
| above code without being given a ``BasicBlock`` by doing: |
| |
| .. code-block:: c++ |
| |
| Instruction *pi = ...; |
| Instruction *newInst = new Instruction(...); |
| |
| pi->getParent()->getInstList().insert(pi, newInst); |
| |
| In fact, this sequence of steps occurs so frequently that the ``Instruction`` |
| class and ``Instruction``-derived classes provide constructors which take (as |
| a default parameter) a pointer to an ``Instruction`` which the newly-created |
| ``Instruction`` should precede. That is, ``Instruction`` constructors are |
| capable of inserting the newly-created instance into the ``BasicBlock`` of a |
| provided instruction, immediately before that instruction. Using an |
| ``Instruction`` constructor with a ``insertBefore`` (default) parameter, the |
| above code becomes: |
| |
| .. code-block:: c++ |
| |
| Instruction* pi = ...; |
| Instruction* newInst = new Instruction(..., pi); |
| |
| which is much cleaner, especially if you're creating a lot of instructions and |
| adding them to ``BasicBlock``\ s. |
| |
| .. _schanges_deleting: |
| |
| Deleting Instructions |
| ^^^^^^^^^^^^^^^^^^^^^ |
| |
| Deleting an instruction from an existing sequence of instructions that form a |
| BasicBlock_ is very straight-forward: just call the instruction's |
| ``eraseFromParent()`` method. For example: |
| |
| .. code-block:: c++ |
| |
| Instruction *I = .. ; |
| I->eraseFromParent(); |
| |
| This unlinks the instruction from its containing basic block and deletes it. If |
| you'd just like to unlink the instruction from its containing basic block but |
| not delete it, you can use the ``removeFromParent()`` method. |
| |
| .. _schanges_replacing: |
| |
| Replacing an Instruction with another Value |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Replacing individual instructions |
| """"""""""""""""""""""""""""""""" |
| |
| Including "`llvm/Transforms/Utils/BasicBlockUtils.h |
| <http://llvm.org/doxygen/BasicBlockUtils_8h-source.html>`_" permits use of two |
| very useful replace functions: ``ReplaceInstWithValue`` and |
| ``ReplaceInstWithInst``. |
| |
| .. _schanges_deleting_sub: |
| |
| Deleting Instructions |
| """"""""""""""""""""" |
| |
| * ``ReplaceInstWithValue`` |
| |
| This function replaces all uses of a given instruction with a value, and then |
| removes the original instruction. The following example illustrates the |
| replacement of the result of a particular ``AllocaInst`` that allocates memory |
| for a single integer with a null pointer to an integer. |
| |
| .. code-block:: c++ |
| |
| AllocaInst* instToReplace = ...; |
| BasicBlock::iterator ii(instToReplace); |
| |
| ReplaceInstWithValue(instToReplace->getParent()->getInstList(), ii, |
| Constant::getNullValue(PointerType::getUnqual(Type::Int32Ty))); |
| |
| * ``ReplaceInstWithInst`` |
| |
| This function replaces a particular instruction with another instruction, |
| inserting the new instruction into the basic block at the location where the |
| old instruction was, and replacing any uses of the old instruction with the |
| new instruction. The following example illustrates the replacement of one |
| ``AllocaInst`` with another. |
| |
| .. code-block:: c++ |
| |
| AllocaInst* instToReplace = ...; |
| BasicBlock::iterator ii(instToReplace); |
| |
| ReplaceInstWithInst(instToReplace->getParent()->getInstList(), ii, |
| new AllocaInst(Type::Int32Ty, 0, "ptrToReplacedInt")); |
| |
| |
| Replacing multiple uses of Users and Values |
| """"""""""""""""""""""""""""""""""""""""""" |
| |
| You can use ``Value::replaceAllUsesWith`` and ``User::replaceUsesOfWith`` to |
| change more than one use at a time. See the doxygen documentation for the |
| `Value Class <http://llvm.org/doxygen/classllvm_1_1Value.html>`_ and `User Class |
| <http://llvm.org/doxygen/classllvm_1_1User.html>`_, respectively, for more |
| information. |
| |
| .. _schanges_deletingGV: |
| |
| Deleting GlobalVariables |
| ^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Deleting a global variable from a module is just as easy as deleting an |
| Instruction. First, you must have a pointer to the global variable that you |
| wish to delete. You use this pointer to erase it from its parent, the module. |
| For example: |
| |
| .. code-block:: c++ |
| |
| GlobalVariable *GV = .. ; |
| |
| GV->eraseFromParent(); |
| |
| |
| .. _create_types: |
| |
| How to Create Types |
| ------------------- |
| |
| In generating IR, you may need some complex types. If you know these types |
| statically, you can use ``TypeBuilder<...>::get()``, defined in |
| ``llvm/Support/TypeBuilder.h``, to retrieve them. ``TypeBuilder`` has two forms |
| depending on whether you're building types for cross-compilation or native |
| library use. ``TypeBuilder<T, true>`` requires that ``T`` be independent of the |
| host environment, meaning that it's built out of types from the ``llvm::types`` |
| (`doxygen <http://llvm.org/doxygen/namespacellvm_1_1types.html>`__) namespace |
| and pointers, functions, arrays, etc. built of those. ``TypeBuilder<T, false>`` |
| additionally allows native C types whose size may depend on the host compiler. |
| For example, |
| |
| .. code-block:: c++ |
| |
| FunctionType *ft = TypeBuilder<types::i<8>(types::i<32>*), true>::get(); |
| |
| is easier to read and write than the equivalent |
| |
| .. code-block:: c++ |
| |
| std::vector<const Type*> params; |
| params.push_back(PointerType::getUnqual(Type::Int32Ty)); |
| FunctionType *ft = FunctionType::get(Type::Int8Ty, params, false); |
| |
| See the `class comment |
| <http://llvm.org/doxygen/TypeBuilder_8h-source.html#l00001>`_ for more details. |
| |
| .. _threading: |
| |
| Threads and LLVM |
| ================ |
| |
| This section describes the interaction of the LLVM APIs with multithreading, |
| both on the part of client applications, and in the JIT, in the hosted |
| application. |
| |
| Note that LLVM's support for multithreading is still relatively young. Up |
| through version 2.5, the execution of threaded hosted applications was |
| supported, but not threaded client access to the APIs. While this use case is |
| now supported, clients *must* adhere to the guidelines specified below to ensure |
| proper operation in multithreaded mode. |
| |
| Note that, on Unix-like platforms, LLVM requires the presence of GCC's atomic |
| intrinsics in order to support threaded operation. If you need a |
| multhreading-capable LLVM on a platform without a suitably modern system |
| compiler, consider compiling LLVM and LLVM-GCC in single-threaded mode, and |
| using the resultant compiler to build a copy of LLVM with multithreading |
| support. |
| |
| .. _startmultithreaded: |
| |
| Entering and Exiting Multithreaded Mode |
| --------------------------------------- |
| |
| In order to properly protect its internal data structures while avoiding |
| excessive locking overhead in the single-threaded case, the LLVM must intialize |
| certain data structures necessary to provide guards around its internals. To do |
| so, the client program must invoke ``llvm_start_multithreaded()`` before making |
| any concurrent LLVM API calls. To subsequently tear down these structures, use |
| the ``llvm_stop_multithreaded()`` call. You can also use the |
| ``llvm_is_multithreaded()`` call to check the status of multithreaded mode. |
| |
| Note that both of these calls must be made *in isolation*. That is to say that |
| no other LLVM API calls may be executing at any time during the execution of |
| ``llvm_start_multithreaded()`` or ``llvm_stop_multithreaded``. It's is the |
| client's responsibility to enforce this isolation. |
| |
| The return value of ``llvm_start_multithreaded()`` indicates the success or |
| failure of the initialization. Failure typically indicates that your copy of |
| LLVM was built without multithreading support, typically because GCC atomic |
| intrinsics were not found in your system compiler. In this case, the LLVM API |
| will not be safe for concurrent calls. However, it *will* be safe for hosting |
| threaded applications in the JIT, though :ref:`care must be taken |
| <jitthreading>` to ensure that side exits and the like do not accidentally |
| result in concurrent LLVM API calls. |
| |
| .. _shutdown: |
| |
| Ending Execution with ``llvm_shutdown()`` |
| ----------------------------------------- |
| |
| When you are done using the LLVM APIs, you should call ``llvm_shutdown()`` to |
| deallocate memory used for internal structures. This will also invoke |
| ``llvm_stop_multithreaded()`` if LLVM is operating in multithreaded mode. As |
| such, ``llvm_shutdown()`` requires the same isolation guarantees as |
| ``llvm_stop_multithreaded()``. |
| |
| Note that, if you use scope-based shutdown, you can use the |
| ``llvm_shutdown_obj`` class, which calls ``llvm_shutdown()`` in its destructor. |
| |
| .. _managedstatic: |
| |
| Lazy Initialization with ``ManagedStatic`` |
| ------------------------------------------ |
| |
| ``ManagedStatic`` is a utility class in LLVM used to implement static |
| initialization of static resources, such as the global type tables. Before the |
| invocation of ``llvm_shutdown()``, it implements a simple lazy initialization |
| scheme. Once ``llvm_start_multithreaded()`` returns, however, it uses |
| double-checked locking to implement thread-safe lazy initialization. |
| |
| Note that, because no other threads are allowed to issue LLVM API calls before |
| ``llvm_start_multithreaded()`` returns, it is possible to have |
| ``ManagedStatic``\ s of ``llvm::sys::Mutex``\ s. |
| |
| The ``llvm_acquire_global_lock()`` and ``llvm_release_global_lock`` APIs provide |
| access to the global lock used to implement the double-checked locking for lazy |
| initialization. These should only be used internally to LLVM, and only if you |
| know what you're doing! |
| |
| .. _llvmcontext: |
| |
| Achieving Isolation with ``LLVMContext`` |
| ---------------------------------------- |
| |
| ``LLVMContext`` is an opaque class in the LLVM API which clients can use to |
| operate multiple, isolated instances of LLVM concurrently within the same |
| address space. For instance, in a hypothetical compile-server, the compilation |
| of an individual translation unit is conceptually independent from all the |
| others, and it would be desirable to be able to compile incoming translation |
| units concurrently on independent server threads. Fortunately, ``LLVMContext`` |
| exists to enable just this kind of scenario! |
| |
| Conceptually, ``LLVMContext`` provides isolation. Every LLVM entity |
| (``Module``\ s, ``Value``\ s, ``Type``\ s, ``Constant``\ s, etc.) in LLVM's |
| in-memory IR belongs to an ``LLVMContext``. Entities in different contexts |
| *cannot* interact with each other: ``Module``\ s in different contexts cannot be |
| linked together, ``Function``\ s cannot be added to ``Module``\ s in different |
| contexts, etc. What this means is that is is safe to compile on multiple |
| threads simultaneously, as long as no two threads operate on entities within the |
| same context. |
| |
| In practice, very few places in the API require the explicit specification of a |
| ``LLVMContext``, other than the ``Type`` creation/lookup APIs. Because every |
| ``Type`` carries a reference to its owning context, most other entities can |
| determine what context they belong to by looking at their own ``Type``. If you |
| are adding new entities to LLVM IR, please try to maintain this interface |
| design. |
| |
| For clients that do *not* require the benefits of isolation, LLVM provides a |
| convenience API ``getGlobalContext()``. This returns a global, lazily |
| initialized ``LLVMContext`` that may be used in situations where isolation is |
| not a concern. |
| |
| .. _jitthreading: |
| |
| Threads and the JIT |
| ------------------- |
| |
| LLVM's "eager" JIT compiler is safe to use in threaded programs. Multiple |
| threads can call ``ExecutionEngine::getPointerToFunction()`` or |
| ``ExecutionEngine::runFunction()`` concurrently, and multiple threads can run |
| code output by the JIT concurrently. The user must still ensure that only one |
| thread accesses IR in a given ``LLVMContext`` while another thread might be |
| modifying it. One way to do that is to always hold the JIT lock while accessing |
| IR outside the JIT (the JIT *modifies* the IR by adding ``CallbackVH``\ s). |
| Another way is to only call ``getPointerToFunction()`` from the |
| ``LLVMContext``'s thread. |
| |
| When the JIT is configured to compile lazily (using |
| ``ExecutionEngine::DisableLazyCompilation(false)``), there is currently a `race |
| condition <http://llvm.org/bugs/show_bug.cgi?id=5184>`_ in updating call sites |
| after a function is lazily-jitted. It's still possible to use the lazy JIT in a |
| threaded program if you ensure that only one thread at a time can call any |
| particular lazy stub and that the JIT lock guards any IR access, but we suggest |
| using only the eager JIT in threaded programs. |
| |
| .. _advanced: |
| |
| Advanced Topics |
| =============== |
| |
| This section describes some of the advanced or obscure API's that most clients |
| do not need to be aware of. These API's tend manage the inner workings of the |
| LLVM system, and only need to be accessed in unusual circumstances. |
| |
| .. _SymbolTable: |
| |
| The ``ValueSymbolTable`` class |
| ------------------------------ |
| |
| The ``ValueSymbolTable`` (`doxygen |
| <http://llvm.org/doxygen/classllvm_1_1ValueSymbolTable.html>`__) class provides |
| a symbol table that the :ref:`Function <c_Function>` and Module_ classes use for |
| naming value definitions. The symbol table can provide a name for any Value_. |
| |
| Note that the ``SymbolTable`` class should not be directly accessed by most |
| clients. It should only be used when iteration over the symbol table names |
| themselves are required, which is very special purpose. Note that not all LLVM |
| Value_\ s have names, and those without names (i.e. they have an empty name) do |
| not exist in the symbol table. |
| |
| Symbol tables support iteration over the values in the symbol table with |
| ``begin/end/iterator`` and supports querying to see if a specific name is in the |
| symbol table (with ``lookup``). The ``ValueSymbolTable`` class exposes no |
| public mutator methods, instead, simply call ``setName`` on a value, which will |
| autoinsert it into the appropriate symbol table. |
| |
| .. _UserLayout: |
| |
| The ``User`` and owned ``Use`` classes' memory layout |
| ----------------------------------------------------- |
| |
| The ``User`` (`doxygen <http://llvm.org/doxygen/classllvm_1_1User.html>`__) |
| class provides a basis for expressing the ownership of ``User`` towards other |
| `Value instance <http://llvm.org/doxygen/classllvm_1_1Value.html>`_\ s. The |
| ``Use`` (`doxygen <http://llvm.org/doxygen/classllvm_1_1Use.html>`__) helper |
| class is employed to do the bookkeeping and to facilitate *O(1)* addition and |
| removal. |
| |
| .. _Use2User: |
| |
| Interaction and relationship between ``User`` and ``Use`` objects |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| A subclass of ``User`` can choose between incorporating its ``Use`` objects or |
| refer to them out-of-line by means of a pointer. A mixed variant (some ``Use`` |
| s inline others hung off) is impractical and breaks the invariant that the |
| ``Use`` objects belonging to the same ``User`` form a contiguous array. |
| |
| We have 2 different layouts in the ``User`` (sub)classes: |
| |
| * Layout a) |
| |
| The ``Use`` object(s) are inside (resp. at fixed offset) of the ``User`` |
| object and there are a fixed number of them. |
| |
| * Layout b) |
| |
| The ``Use`` object(s) are referenced by a pointer to an array from the |
| ``User`` object and there may be a variable number of them. |
| |
| As of v2.4 each layout still possesses a direct pointer to the start of the |
| array of ``Use``\ s. Though not mandatory for layout a), we stick to this |
| redundancy for the sake of simplicity. The ``User`` object also stores the |
| number of ``Use`` objects it has. (Theoretically this information can also be |
| calculated given the scheme presented below.) |
| |
| Special forms of allocation operators (``operator new``) enforce the following |
| memory layouts: |
| |
| * Layout a) is modelled by prepending the ``User`` object by the ``Use[]`` |
| array. |
| |
| .. code-block:: none |
| |
| ...---.---.---.---.-------... |
| | P | P | P | P | User |
| '''---'---'---'---'-------''' |
| |
| * Layout b) is modelled by pointing at the ``Use[]`` array. |
| |
| .. code-block:: none |
| |
| .-------... |
| | User |
| '-------''' |
| | |
| v |
| .---.---.---.---... |
| | P | P | P | P | |
| '---'---'---'---''' |
| |
| *(In the above figures* '``P``' *stands for the* ``Use**`` *that is stored in |
| each* ``Use`` *object in the member* ``Use::Prev`` *)* |
| |
| .. _Waymarking: |
| |
| The waymarking algorithm |
| ^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Since the ``Use`` objects are deprived of the direct (back)pointer to their |
| ``User`` objects, there must be a fast and exact method to recover it. This is |
| accomplished by the following scheme: |
| |
| A bit-encoding in the 2 LSBits (least significant bits) of the ``Use::Prev`` |
| allows to find the start of the ``User`` object: |
| |
| * ``00`` --- binary digit 0 |
| |
| * ``01`` --- binary digit 1 |
| |
| * ``10`` --- stop and calculate (``s``) |
| |
| * ``11`` --- full stop (``S``) |
| |
| Given a ``Use*``, all we have to do is to walk till we get a stop and we either |
| have a ``User`` immediately behind or we have to walk to the next stop picking |
| up digits and calculating the offset: |
| |
| .. code-block:: none |
| |
| .---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---------------- |
| | 1 | s | 1 | 0 | 1 | 0 | s | 1 | 1 | 0 | s | 1 | 1 | s | 1 | S | User (or User*) |
| '---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---------------- |
| |+15 |+10 |+6 |+3 |+1 |
| | | | | | __> |
| | | | | __________> |
| | | | ______________________> |
| | | ______________________________________> |
| | __________________________________________________________> |
| |
| Only the significant number of bits need to be stored between the stops, so that |
| the *worst case is 20 memory accesses* when there are 1000 ``Use`` objects |
| associated with a ``User``. |
| |
| .. _ReferenceImpl: |
| |
| Reference implementation |
| ^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The following literate Haskell fragment demonstrates the concept: |
| |
| .. code-block:: haskell |
| |
| > import Test.QuickCheck |
| > |
| > digits :: Int -> [Char] -> [Char] |
| > digits 0 acc = '0' : acc |
| > digits 1 acc = '1' : acc |
| > digits n acc = digits (n `div` 2) $ digits (n `mod` 2) acc |
| > |
| > dist :: Int -> [Char] -> [Char] |
| > dist 0 [] = ['S'] |
| > dist 0 acc = acc |
| > dist 1 acc = let r = dist 0 acc in 's' : digits (length r) r |
| > dist n acc = dist (n - 1) $ dist 1 acc |
| > |
| > takeLast n ss = reverse $ take n $ reverse ss |
| > |
| > test = takeLast 40 $ dist 20 [] |
| > |
| |
| Printing <test> gives: ``"1s100000s11010s10100s1111s1010s110s11s1S"`` |
| |
| The reverse algorithm computes the length of the string just by examining a |
| certain prefix: |
| |
| .. code-block:: haskell |
| |
| > pref :: [Char] -> Int |
| > pref "S" = 1 |
| > pref ('s':'1':rest) = decode 2 1 rest |
| > pref (_:rest) = 1 + pref rest |
| > |
| > decode walk acc ('0':rest) = decode (walk + 1) (acc * 2) rest |
| > decode walk acc ('1':rest) = decode (walk + 1) (acc * 2 + 1) rest |
| > decode walk acc _ = walk + acc |
| > |
| |
| Now, as expected, printing <pref test> gives ``40``. |
| |
| We can *quickCheck* this with following property: |
| |
| .. code-block:: haskell |
| |
| > testcase = dist 2000 [] |
| > testcaseLength = length testcase |
| > |
| > identityProp n = n > 0 && n <= testcaseLength ==> length arr == pref arr |
| > where arr = takeLast n testcase |
| > |
| |
| As expected <quickCheck identityProp> gives: |
| |
| :: |
| |
| *Main> quickCheck identityProp |
| OK, passed 100 tests. |
| |
| Let's be a bit more exhaustive: |
| |
| .. code-block:: haskell |
| |
| > |
| > deepCheck p = check (defaultConfig { configMaxTest = 500 }) p |
| > |
| |
| And here is the result of <deepCheck identityProp>: |
| |
| :: |
| |
| *Main> deepCheck identityProp |
| OK, passed 500 tests. |
| |
| .. _Tagging: |
| |
| Tagging considerations |
| ^^^^^^^^^^^^^^^^^^^^^^ |
| |
| To maintain the invariant that the 2 LSBits of each ``Use**`` in ``Use`` never |
| change after being set up, setters of ``Use::Prev`` must re-tag the new |
| ``Use**`` on every modification. Accordingly getters must strip the tag bits. |
| |
| For layout b) instead of the ``User`` we find a pointer (``User*`` with LSBit |
| set). Following this pointer brings us to the ``User``. A portable trick |
| ensures that the first bytes of ``User`` (if interpreted as a pointer) never has |
| the LSBit set. (Portability is relying on the fact that all known compilers |
| place the ``vptr`` in the first word of the instances.) |
| |
| .. _coreclasses: |
| |
| The Core LLVM Class Hierarchy Reference |
| ======================================= |
| |
| ``#include "llvm/Type.h"`` |
| |
| header source: `Type.h <http://llvm.org/doxygen/Type_8h-source.html>`_ |
| |
| doxygen info: `Type Clases <http://llvm.org/doxygen/classllvm_1_1Type.html>`_ |
| |
| The Core LLVM classes are the primary means of representing the program being |
| inspected or transformed. The core LLVM classes are defined in header files in |
| the ``include/llvm/`` directory, and implemented in the ``lib/VMCore`` |
| directory. |
| |
| .. _Type: |
| |
| The Type class and Derived Types |
| -------------------------------- |
| |
| ``Type`` is a superclass of all type classes. Every ``Value`` has a ``Type``. |
| ``Type`` cannot be instantiated directly but only through its subclasses. |
| Certain primitive types (``VoidType``, ``LabelType``, ``FloatType`` and |
| ``DoubleType``) have hidden subclasses. They are hidden because they offer no |
| useful functionality beyond what the ``Type`` class offers except to distinguish |
| themselves from other subclasses of ``Type``. |
| |
| All other types are subclasses of ``DerivedType``. Types can be named, but this |
| is not a requirement. There exists exactly one instance of a given shape at any |
| one time. This allows type equality to be performed with address equality of |
| the Type Instance. That is, given two ``Type*`` values, the types are identical |
| if the pointers are identical. |
| |
| .. _m_Type: |
| |
| Important Public Methods |
| ^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``bool isIntegerTy() const``: Returns true for any integer type. |
| |
| * ``bool isFloatingPointTy()``: Return true if this is one of the five |
| floating point types. |
| |
| * ``bool isSized()``: Return true if the type has known size. Things |
| that don't have a size are abstract types, labels and void. |
| |
| .. _derivedtypes: |
| |
| Important Derived Types |
| ^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| ``IntegerType`` |
| Subclass of DerivedType that represents integer types of any bit width. Any |
| bit width between ``IntegerType::MIN_INT_BITS`` (1) and |
| ``IntegerType::MAX_INT_BITS`` (~8 million) can be represented. |
| |
| * ``static const IntegerType* get(unsigned NumBits)``: get an integer |
| type of a specific bit width. |
| |
| * ``unsigned getBitWidth() const``: Get the bit width of an integer type. |
| |
| ``SequentialType`` |
| This is subclassed by ArrayType, PointerType and VectorType. |
| |
| * ``const Type * getElementType() const``: Returns the type of each |
| of the elements in the sequential type. |
| |
| ``ArrayType`` |
| This is a subclass of SequentialType and defines the interface for array |
| types. |
| |
| * ``unsigned getNumElements() const``: Returns the number of elements |
| in the array. |
| |
| ``PointerType`` |
| Subclass of SequentialType for pointer types. |
| |
| ``VectorType`` |
| Subclass of SequentialType for vector types. A vector type is similar to an |
| ArrayType but is distinguished because it is a first class type whereas |
| ArrayType is not. Vector types are used for vector operations and are usually |
| small vectors of of an integer or floating point type. |
| |
| ``StructType`` |
| Subclass of DerivedTypes for struct types. |
| |
| .. _FunctionType: |
| |
| ``FunctionType`` |
| Subclass of DerivedTypes for function types. |
| |
| * ``bool isVarArg() const``: Returns true if it's a vararg function. |
| |
| * ``const Type * getReturnType() const``: Returns the return type of the |
| function. |
| |
| * ``const Type * getParamType (unsigned i)``: Returns the type of the ith |
| parameter. |
| |
| * ``const unsigned getNumParams() const``: Returns the number of formal |
| parameters. |
| |
| .. _Module: |
| |
| The ``Module`` class |
| -------------------- |
| |
| ``#include "llvm/Module.h"`` |
| |
| header source: `Module.h <http://llvm.org/doxygen/Module_8h-source.html>`_ |
| |
| doxygen info: `Module Class <http://llvm.org/doxygen/classllvm_1_1Module.html>`_ |
| |
| The ``Module`` class represents the top level structure present in LLVM |
| programs. An LLVM module is effectively either a translation unit of the |
| original program or a combination of several translation units merged by the |
| linker. The ``Module`` class keeps track of a list of :ref:`Function |
| <c_Function>`\ s, a list of GlobalVariable_\ s, and a SymbolTable_. |
| Additionally, it contains a few helpful member functions that try to make common |
| operations easy. |
| |
| .. _m_Module: |
| |
| Important Public Members of the ``Module`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``Module::Module(std::string name = "")`` |
| |
| Constructing a Module_ is easy. You can optionally provide a name for it |
| (probably based on the name of the translation unit). |
| |
| * | ``Module::iterator`` - Typedef for function list iterator |
| | ``Module::const_iterator`` - Typedef for const_iterator. |
| | ``begin()``, ``end()``, ``size()``, ``empty()`` |
| |
| These are forwarding methods that make it easy to access the contents of a |
| ``Module`` object's :ref:`Function <c_Function>` list. |
| |
| * ``Module::FunctionListType &getFunctionList()`` |
| |
| Returns the list of :ref:`Function <c_Function>`\ s. This is necessary to use |
| when you need to update the list or perform a complex action that doesn't have |
| a forwarding method. |
| |
| ---------------- |
| |
| * | ``Module::global_iterator`` - Typedef for global variable list iterator |
| | ``Module::const_global_iterator`` - Typedef for const_iterator. |
| | ``global_begin()``, ``global_end()``, ``global_size()``, ``global_empty()`` |
| |
| These are forwarding methods that make it easy to access the contents of a |
| ``Module`` object's GlobalVariable_ list. |
| |
| * ``Module::GlobalListType &getGlobalList()`` |
| |
| Returns the list of GlobalVariable_\ s. This is necessary to use when you |
| need to update the list or perform a complex action that doesn't have a |
| forwarding method. |
| |
| ---------------- |
| |
| * ``SymbolTable *getSymbolTable()`` |
| |
| Return a reference to the SymbolTable_ for this ``Module``. |
| |
| ---------------- |
| |
| * ``Function *getFunction(StringRef Name) const`` |
| |
| Look up the specified function in the ``Module`` SymbolTable_. If it does not |
| exist, return ``null``. |
| |
| * ``Function *getOrInsertFunction(const std::string &Name, const FunctionType |
| *T)`` |
| |
| Look up the specified function in the ``Module`` SymbolTable_. If it does not |
| exist, add an external declaration for the function and return it. |
| |
| * ``std::string getTypeName(const Type *Ty)`` |
| |
| If there is at least one entry in the SymbolTable_ for the specified Type_, |
| return it. Otherwise return the empty string. |
| |
| * ``bool addTypeName(const std::string &Name, const Type *Ty)`` |
| |
| Insert an entry in the SymbolTable_ mapping ``Name`` to ``Ty``. If there is |
| already an entry for this name, true is returned and the SymbolTable_ is not |
| modified. |
| |
| .. _Value: |
| |
| The ``Value`` class |
| ------------------- |
| |
| ``#include "llvm/Value.h"`` |
| |
| header source: `Value.h <http://llvm.org/doxygen/Value_8h-source.html>`_ |
| |
| doxygen info: `Value Class <http://llvm.org/doxygen/classllvm_1_1Value.html>`_ |
| |
| The ``Value`` class is the most important class in the LLVM Source base. It |
| represents a typed value that may be used (among other things) as an operand to |
| an instruction. There are many different types of ``Value``\ s, such as |
| Constant_\ s, Argument_\ s. Even Instruction_\ s and :ref:`Function |
| <c_Function>`\ s are ``Value``\ s. |
| |
| A particular ``Value`` may be used many times in the LLVM representation for a |
| program. For example, an incoming argument to a function (represented with an |
| instance of the Argument_ class) is "used" by every instruction in the function |
| that references the argument. To keep track of this relationship, the ``Value`` |
| class keeps a list of all of the ``User``\ s that is using it (the User_ class |
| is a base class for all nodes in the LLVM graph that can refer to ``Value``\ s). |
| This use list is how LLVM represents def-use information in the program, and is |
| accessible through the ``use_*`` methods, shown below. |
| |
| Because LLVM is a typed representation, every LLVM ``Value`` is typed, and this |
| Type_ is available through the ``getType()`` method. In addition, all LLVM |
| values can be named. The "name" of the ``Value`` is a symbolic string printed |
| in the LLVM code: |
| |
| .. code-block:: llvm |
| |
| %foo = add i32 1, 2 |
| |
| .. _nameWarning: |
| |
| The name of this instruction is "foo". **NOTE** that the name of any value may |
| be missing (an empty string), so names should **ONLY** be used for debugging |
| (making the source code easier to read, debugging printouts), they should not be |
| used to keep track of values or map between them. For this purpose, use a |
| ``std::map`` of pointers to the ``Value`` itself instead. |
| |
| One important aspect of LLVM is that there is no distinction between an SSA |
| variable and the operation that produces it. Because of this, any reference to |
| the value produced by an instruction (or the value available as an incoming |
| argument, for example) is represented as a direct pointer to the instance of the |
| class that represents this value. Although this may take some getting used to, |
| it simplifies the representation and makes it easier to manipulate. |
| |
| .. _m_Value: |
| |
| Important Public Members of the ``Value`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * | ``Value::use_iterator`` - Typedef for iterator over the use-list |
| | ``Value::const_use_iterator`` - Typedef for const_iterator over the |
| use-list |
| | ``unsigned use_size()`` - Returns the number of users of the value. |
| | ``bool use_empty()`` - Returns true if there are no users. |
| | ``use_iterator use_begin()`` - Get an iterator to the start of the |
| use-list. |
| | ``use_iterator use_end()`` - Get an iterator to the end of the use-list. |
| | ``User *use_back()`` - Returns the last element in the list. |
| |
| These methods are the interface to access the def-use information in LLVM. |
| As with all other iterators in LLVM, the naming conventions follow the |
| conventions defined by the STL_. |
| |
| * ``Type *getType() const`` |
| This method returns the Type of the Value. |
| |
| * | ``bool hasName() const`` |
| | ``std::string getName() const`` |
| | ``void setName(const std::string &Name)`` |
| |
| This family of methods is used to access and assign a name to a ``Value``, be |
| aware of the :ref:`precaution above <nameWarning>`. |
| |
| * ``void replaceAllUsesWith(Value *V)`` |
| |
| This method traverses the use list of a ``Value`` changing all User_\ s of the |
| current value to refer to "``V``" instead. For example, if you detect that an |
| instruction always produces a constant value (for example through constant |
| folding), you can replace all uses of the instruction with the constant like |
| this: |
| |
| .. code-block:: c++ |
| |
| Inst->replaceAllUsesWith(ConstVal); |
| |
| .. _User: |
| |
| The ``User`` class |
| ------------------ |
| |
| ``#include "llvm/User.h"`` |
| |
| header source: `User.h <http://llvm.org/doxygen/User_8h-source.html>`_ |
| |
| doxygen info: `User Class <http://llvm.org/doxygen/classllvm_1_1User.html>`_ |
| |
| Superclass: Value_ |
| |
| The ``User`` class is the common base class of all LLVM nodes that may refer to |
| ``Value``\ s. It exposes a list of "Operands" that are all of the ``Value``\ s |
| that the User is referring to. The ``User`` class itself is a subclass of |
| ``Value``. |
| |
| The operands of a ``User`` point directly to the LLVM ``Value`` that it refers |
| to. Because LLVM uses Static Single Assignment (SSA) form, there can only be |
| one definition referred to, allowing this direct connection. This connection |
| provides the use-def information in LLVM. |
| |
| .. _m_User: |
| |
| Important Public Members of the ``User`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| The ``User`` class exposes the operand list in two ways: through an index access |
| interface and through an iterator based interface. |
| |
| * | ``Value *getOperand(unsigned i)`` |
| | ``unsigned getNumOperands()`` |
| |
| These two methods expose the operands of the ``User`` in a convenient form for |
| direct access. |
| |
| * | ``User::op_iterator`` - Typedef for iterator over the operand list |
| | ``op_iterator op_begin()`` - Get an iterator to the start of the operand |
| list. |
| | ``op_iterator op_end()`` - Get an iterator to the end of the operand list. |
| |
| Together, these methods make up the iterator based interface to the operands |
| of a ``User``. |
| |
| |
| .. _Instruction: |
| |
| The ``Instruction`` class |
| ------------------------- |
| |
| ``#include "llvm/Instruction.h"`` |
| |
| header source: `Instruction.h |
| <http://llvm.org/doxygen/Instruction_8h-source.html>`_ |
| |
| doxygen info: `Instruction Class |
| <http://llvm.org/doxygen/classllvm_1_1Instruction.html>`_ |
| |
| Superclasses: User_, Value_ |
| |
| The ``Instruction`` class is the common base class for all LLVM instructions. |
| It provides only a few methods, but is a very commonly used class. The primary |
| data tracked by the ``Instruction`` class itself is the opcode (instruction |
| type) and the parent BasicBlock_ the ``Instruction`` is embedded into. To |
| represent a specific type of instruction, one of many subclasses of |
| ``Instruction`` are used. |
| |
| Because the ``Instruction`` class subclasses the User_ class, its operands can |
| be accessed in the same way as for other ``User``\ s (with the |
| ``getOperand()``/``getNumOperands()`` and ``op_begin()``/``op_end()`` methods). |
| An important file for the ``Instruction`` class is the ``llvm/Instruction.def`` |
| file. This file contains some meta-data about the various different types of |
| instructions in LLVM. It describes the enum values that are used as opcodes |
| (for example ``Instruction::Add`` and ``Instruction::ICmp``), as well as the |
| concrete sub-classes of ``Instruction`` that implement the instruction (for |
| example BinaryOperator_ and CmpInst_). Unfortunately, the use of macros in this |
| file confuses doxygen, so these enum values don't show up correctly in the |
| `doxygen output <http://llvm.org/doxygen/classllvm_1_1Instruction.html>`_. |
| |
| .. _s_Instruction: |
| |
| Important Subclasses of the ``Instruction`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| .. _BinaryOperator: |
| |
| * ``BinaryOperator`` |
| |
| This subclasses represents all two operand instructions whose operands must be |
| the same type, except for the comparison instructions. |
| |
| .. _CastInst: |
| |
| * ``CastInst`` |
| This subclass is the parent of the 12 casting instructions. It provides |
| common operations on cast instructions. |
| |
| .. _CmpInst: |
| |
| * ``CmpInst`` |
| |
| This subclass respresents the two comparison instructions, |
| `ICmpInst <LangRef.html#i_icmp>`_ (integer opreands), and |
| `FCmpInst <LangRef.html#i_fcmp>`_ (floating point operands). |
| |
| .. _TerminatorInst: |
| |
| * ``TerminatorInst`` |
| |
| This subclass is the parent of all terminator instructions (those which can |
| terminate a block). |
| |
| .. _m_Instruction: |
| |
| Important Public Members of the ``Instruction`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``BasicBlock *getParent()`` |
| |
| Returns the BasicBlock_ that this |
| ``Instruction`` is embedded into. |
| |
| * ``bool mayWriteToMemory()`` |
| |
| Returns true if the instruction writes to memory, i.e. it is a ``call``, |
| ``free``, ``invoke``, or ``store``. |
| |
| * ``unsigned getOpcode()`` |
| |
| Returns the opcode for the ``Instruction``. |
| |
| * ``Instruction *clone() const`` |
| |
| Returns another instance of the specified instruction, identical in all ways |
| to the original except that the instruction has no parent (i.e. it's not |
| embedded into a BasicBlock_), and it has no name. |
| |
| .. _Constant: |
| |
| The ``Constant`` class and subclasses |
| ------------------------------------- |
| |
| Constant represents a base class for different types of constants. It is |
| subclassed by ConstantInt, ConstantArray, etc. for representing the various |
| types of Constants. GlobalValue_ is also a subclass, which represents the |
| address of a global variable or function. |
| |
| .. _s_Constant: |
| |
| Important Subclasses of Constant |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ConstantInt : This subclass of Constant represents an integer constant of |
| any width. |
| |
| * ``const APInt& getValue() const``: Returns the underlying |
| value of this constant, an APInt value. |
| |
| * ``int64_t getSExtValue() const``: Converts the underlying APInt value to an |
| int64_t via sign extension. If the value (not the bit width) of the APInt |
| is too large to fit in an int64_t, an assertion will result. For this |
| reason, use of this method is discouraged. |
| |
| * ``uint64_t getZExtValue() const``: Converts the underlying APInt value |
| to a uint64_t via zero extension. IF the value (not the bit width) of the |
| APInt is too large to fit in a uint64_t, an assertion will result. For this |
| reason, use of this method is discouraged. |
| |
| * ``static ConstantInt* get(const APInt& Val)``: Returns the ConstantInt |
| object that represents the value provided by ``Val``. The type is implied |
| as the IntegerType that corresponds to the bit width of ``Val``. |
| |
| * ``static ConstantInt* get(const Type *Ty, uint64_t Val)``: Returns the |
| ConstantInt object that represents the value provided by ``Val`` for integer |
| type ``Ty``. |
| |
| * ConstantFP : This class represents a floating point constant. |
| |
| * ``double getValue() const``: Returns the underlying value of this constant. |
| |
| * ConstantArray : This represents a constant array. |
| |
| * ``const std::vector<Use> &getValues() const``: Returns a vector of |
| component constants that makeup this array. |
| |
| * ConstantStruct : This represents a constant struct. |
| |
| * ``const std::vector<Use> &getValues() const``: Returns a vector of |
| component constants that makeup this array. |
| |
| * GlobalValue : This represents either a global variable or a function. In |
| either case, the value is a constant fixed address (after linking). |
| |
| .. _GlobalValue: |
| |
| The ``GlobalValue`` class |
| ------------------------- |
| |
| ``#include "llvm/GlobalValue.h"`` |
| |
| header source: `GlobalValue.h |
| <http://llvm.org/doxygen/GlobalValue_8h-source.html>`_ |
| |
| doxygen info: `GlobalValue Class |
| <http://llvm.org/doxygen/classllvm_1_1GlobalValue.html>`_ |
| |
| Superclasses: Constant_, User_, Value_ |
| |
| Global values ( GlobalVariable_\ s or :ref:`Function <c_Function>`\ s) are the |
| only LLVM values that are visible in the bodies of all :ref:`Function |
| <c_Function>`\ s. Because they are visible at global scope, they are also |
| subject to linking with other globals defined in different translation units. |
| To control the linking process, ``GlobalValue``\ s know their linkage rules. |
| Specifically, ``GlobalValue``\ s know whether they have internal or external |
| linkage, as defined by the ``LinkageTypes`` enumeration. |
| |
| If a ``GlobalValue`` has internal linkage (equivalent to being ``static`` in C), |
| it is not visible to code outside the current translation unit, and does not |
| participate in linking. If it has external linkage, it is visible to external |
| code, and does participate in linking. In addition to linkage information, |
| ``GlobalValue``\ s keep track of which Module_ they are currently part of. |
| |
| Because ``GlobalValue``\ s are memory objects, they are always referred to by |
| their **address**. As such, the Type_ of a global is always a pointer to its |
| contents. It is important to remember this when using the ``GetElementPtrInst`` |
| instruction because this pointer must be dereferenced first. For example, if |
| you have a ``GlobalVariable`` (a subclass of ``GlobalValue)`` that is an array |
| of 24 ints, type ``[24 x i32]``, then the ``GlobalVariable`` is a pointer to |
| that array. Although the address of the first element of this array and the |
| value of the ``GlobalVariable`` are the same, they have different types. The |
| ``GlobalVariable``'s type is ``[24 x i32]``. The first element's type is |
| ``i32.`` Because of this, accessing a global value requires you to dereference |
| the pointer with ``GetElementPtrInst`` first, then its elements can be accessed. |
| This is explained in the `LLVM Language Reference Manual |
| <LangRef.html#globalvars>`_. |
| |
| .. _m_GlobalValue: |
| |
| Important Public Members of the ``GlobalValue`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * | ``bool hasInternalLinkage() const`` |
| | ``bool hasExternalLinkage() const`` |
| | ``void setInternalLinkage(bool HasInternalLinkage)`` |
| |
| These methods manipulate the linkage characteristics of the ``GlobalValue``. |
| |
| * ``Module *getParent()`` |
| |
| This returns the Module_ that the |
| GlobalValue is currently embedded into. |
| |
| .. _c_Function: |
| |
| The ``Function`` class |
| ---------------------- |
| |
| ``#include "llvm/Function.h"`` |
| |
| header source: `Function.h <http://llvm.org/doxygen/Function_8h-source.html>`_ |
| |
| doxygen info: `Function Class |
| <http://llvm.org/doxygen/classllvm_1_1Function.html>`_ |
| |
| Superclasses: GlobalValue_, Constant_, User_, Value_ |
| |
| The ``Function`` class represents a single procedure in LLVM. It is actually |
| one of the more complex classes in the LLVM hierarchy because it must keep track |
| of a large amount of data. The ``Function`` class keeps track of a list of |
| BasicBlock_\ s, a list of formal Argument_\ s, and a SymbolTable_. |
| |
| The list of BasicBlock_\ s is the most commonly used part of ``Function`` |
| objects. The list imposes an implicit ordering of the blocks in the function, |
| which indicate how the code will be laid out by the backend. Additionally, the |
| first BasicBlock_ is the implicit entry node for the ``Function``. It is not |
| legal in LLVM to explicitly branch to this initial block. There are no implicit |
| exit nodes, and in fact there may be multiple exit nodes from a single |
| ``Function``. If the BasicBlock_ list is empty, this indicates that the |
| ``Function`` is actually a function declaration: the actual body of the function |
| hasn't been linked in yet. |
| |
| In addition to a list of BasicBlock_\ s, the ``Function`` class also keeps track |
| of the list of formal Argument_\ s that the function receives. This container |
| manages the lifetime of the Argument_ nodes, just like the BasicBlock_ list does |
| for the BasicBlock_\ s. |
| |
| The SymbolTable_ is a very rarely used LLVM feature that is only used when you |
| have to look up a value by name. Aside from that, the SymbolTable_ is used |
| internally to make sure that there are not conflicts between the names of |
| Instruction_\ s, BasicBlock_\ s, or Argument_\ s in the function body. |
| |
| Note that ``Function`` is a GlobalValue_ and therefore also a Constant_. The |
| value of the function is its address (after linking) which is guaranteed to be |
| constant. |
| |
| .. _m_Function: |
| |
| Important Public Members of the ``Function`` |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``Function(const FunctionType *Ty, LinkageTypes Linkage, |
| const std::string &N = "", Module* Parent = 0)`` |
| |
| Constructor used when you need to create new ``Function``\ s to add the |
| program. The constructor must specify the type of the function to create and |
| what type of linkage the function should have. The FunctionType_ argument |
| specifies the formal arguments and return value for the function. The same |
| FunctionType_ value can be used to create multiple functions. The ``Parent`` |
| argument specifies the Module in which the function is defined. If this |
| argument is provided, the function will automatically be inserted into that |
| module's list of functions. |
| |
| * ``bool isDeclaration()`` |
| |
| Return whether or not the ``Function`` has a body defined. If the function is |
| "external", it does not have a body, and thus must be resolved by linking with |
| a function defined in a different translation unit. |
| |
| * | ``Function::iterator`` - Typedef for basic block list iterator |
| | ``Function::const_iterator`` - Typedef for const_iterator. |
| | ``begin()``, ``end()``, ``size()``, ``empty()`` |
| |
| These are forwarding methods that make it easy to access the contents of a |
| ``Function`` object's BasicBlock_ list. |
| |
| * ``Function::BasicBlockListType &getBasicBlockList()`` |
| |
| Returns the list of BasicBlock_\ s. This is necessary to use when you need to |
| update the list or perform a complex action that doesn't have a forwarding |
| method. |
| |
| * | ``Function::arg_iterator`` - Typedef for the argument list iterator |
| | ``Function::const_arg_iterator`` - Typedef for const_iterator. |
| | ``arg_begin()``, ``arg_end()``, ``arg_size()``, ``arg_empty()`` |
| |
| These are forwarding methods that make it easy to access the contents of a |
| ``Function`` object's Argument_ list. |
| |
| * ``Function::ArgumentListType &getArgumentList()`` |
| |
| Returns the list of Argument_. This is necessary to use when you need to |
| update the list or perform a complex action that doesn't have a forwarding |
| method. |
| |
| * ``BasicBlock &getEntryBlock()`` |
| |
| Returns the entry ``BasicBlock`` for the function. Because the entry block |
| for the function is always the first block, this returns the first block of |
| the ``Function``. |
| |
| * | ``Type *getReturnType()`` |
| | ``FunctionType *getFunctionType()`` |
| |
| This traverses the Type_ of the ``Function`` and returns the return type of |
| the function, or the FunctionType_ of the actual function. |
| |
| * ``SymbolTable *getSymbolTable()`` |
| |
| Return a pointer to the SymbolTable_ for this ``Function``. |
| |
| .. _GlobalVariable: |
| |
| The ``GlobalVariable`` class |
| ---------------------------- |
| |
| ``#include "llvm/GlobalVariable.h"`` |
| |
| header source: `GlobalVariable.h |
| <http://llvm.org/doxygen/GlobalVariable_8h-source.html>`_ |
| |
| doxygen info: `GlobalVariable Class |
| <http://llvm.org/doxygen/classllvm_1_1GlobalVariable.html>`_ |
| |
| Superclasses: GlobalValue_, Constant_, User_, Value_ |
| |
| Global variables are represented with the (surprise surprise) ``GlobalVariable`` |
| class. Like functions, ``GlobalVariable``\ s are also subclasses of |
| GlobalValue_, and as such are always referenced by their address (global values |
| must live in memory, so their "name" refers to their constant address). See |
| GlobalValue_ for more on this. Global variables may have an initial value |
| (which must be a Constant_), and if they have an initializer, they may be marked |
| as "constant" themselves (indicating that their contents never change at |
| runtime). |
| |
| .. _m_GlobalVariable: |
| |
| Important Public Members of the ``GlobalVariable`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``GlobalVariable(const Type *Ty, bool isConstant, LinkageTypes &Linkage, |
| Constant *Initializer = 0, const std::string &Name = "", Module* Parent = 0)`` |
| |
| Create a new global variable of the specified type. If ``isConstant`` is true |
| then the global variable will be marked as unchanging for the program. The |
| Linkage parameter specifies the type of linkage (internal, external, weak, |
| linkonce, appending) for the variable. If the linkage is InternalLinkage, |
| WeakAnyLinkage, WeakODRLinkage, LinkOnceAnyLinkage or LinkOnceODRLinkage, then |
| the resultant global variable will have internal linkage. AppendingLinkage |
| concatenates together all instances (in different translation units) of the |
| variable into a single variable but is only applicable to arrays. See the |
| `LLVM Language Reference <LangRef.html#modulestructure>`_ for further details |
| on linkage types. Optionally an initializer, a name, and the module to put |
| the variable into may be specified for the global variable as well. |
| |
| * ``bool isConstant() const`` |
| |
| Returns true if this is a global variable that is known not to be modified at |
| runtime. |
| |
| * ``bool hasInitializer()`` |
| |
| Returns true if this ``GlobalVariable`` has an intializer. |
| |
| * ``Constant *getInitializer()`` |
| |
| Returns the initial value for a ``GlobalVariable``. It is not legal to call |
| this method if there is no initializer. |
| |
| .. _BasicBlock: |
| |
| The ``BasicBlock`` class |
| ------------------------ |
| |
| ``#include "llvm/BasicBlock.h"`` |
| |
| header source: `BasicBlock.h |
| <http://llvm.org/doxygen/BasicBlock_8h-source.html>`_ |
| |
| doxygen info: `BasicBlock Class |
| <http://llvm.org/doxygen/classllvm_1_1BasicBlock.html>`_ |
| |
| Superclass: Value_ |
| |
| This class represents a single entry single exit section of the code, commonly |
| known as a basic block by the compiler community. The ``BasicBlock`` class |
| maintains a list of Instruction_\ s, which form the body of the block. Matching |
| the language definition, the last element of this list of instructions is always |
| a terminator instruction (a subclass of the TerminatorInst_ class). |
| |
| In addition to tracking the list of instructions that make up the block, the |
| ``BasicBlock`` class also keeps track of the :ref:`Function <c_Function>` that |
| it is embedded into. |
| |
| Note that ``BasicBlock``\ s themselves are Value_\ s, because they are |
| referenced by instructions like branches and can go in the switch tables. |
| ``BasicBlock``\ s have type ``label``. |
| |
| .. _m_BasicBlock: |
| |
| Important Public Members of the ``BasicBlock`` class |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| * ``BasicBlock(const std::string &Name = "", Function *Parent = 0)`` |
| |
| The ``BasicBlock`` constructor is used to create new basic blocks for |
| insertion into a function. The constructor optionally takes a name for the |
| new block, and a :ref:`Function <c_Function>` to insert it into. If the |
| ``Parent`` parameter is specified, the new ``BasicBlock`` is automatically |
| inserted at the end of the specified :ref:`Function <c_Function>`, if not |
| specified, the BasicBlock must be manually inserted into the :ref:`Function |
| <c_Function>`. |
| |
| * | ``BasicBlock::iterator`` - Typedef for instruction list iterator |
| | ``BasicBlock::const_iterator`` - Typedef for const_iterator. |
| | ``begin()``, ``end()``, ``front()``, ``back()``, |
| ``size()``, ``empty()`` |
| STL-style functions for accessing the instruction list. |
| |
| These methods and typedefs are forwarding functions that have the same |
| semantics as the standard library methods of the same names. These methods |
| expose the underlying instruction list of a basic block in a way that is easy |
| to manipulate. To get the full complement of container operations (including |
| operations to update the list), you must use the ``getInstList()`` method. |
| |
| * ``BasicBlock::InstListType &getInstList()`` |
| |
| This method is used to get access to the underlying container that actually |
| holds the Instructions. This method must be used when there isn't a |
| forwarding function in the ``BasicBlock`` class for the operation that you |
| would like to perform. Because there are no forwarding functions for |
| "updating" operations, you need to use this if you want to update the contents |
| of a ``BasicBlock``. |
| |
| * ``Function *getParent()`` |
| |
| Returns a pointer to :ref:`Function <c_Function>` the block is embedded into, |
| or a null pointer if it is homeless. |
| |
| * ``TerminatorInst *getTerminator()`` |
| |
| Returns a pointer to the terminator instruction that appears at the end of the |
| ``BasicBlock``. If there is no terminator instruction, or if the last |
| instruction in the block is not a terminator, then a null pointer is returned. |
| |
| .. _Argument: |
| |
| The ``Argument`` class |
| ---------------------- |
| |
| This subclass of Value defines the interface for incoming formal arguments to a |
| function. A Function maintains a list of its formal arguments. An argument has |
| a pointer to the parent Function. |
| |
| |