<li><a href="#whatsnew">What's New in LLVM?</a></li>
<li><a href="GettingStarted.html">Installation Instructions</a></li>
<li><a href="#portability">Portability and Supported Platforms</a></li>
- <li><a href="#knownproblems">Known Problems</a>
+ <li><a href="#knownproblems">Known Problems</a></li>
<li><a href="#additionalinfo">Additional Information</a></li>
</ol>
<div class="doc_author">
- <p>Written by the <a href="http://llvm.org">LLVM Team</a><p>
+ <p>Written by the <a href="http://llvm.org">LLVM Team</a></p>
</div>
<!-- *********************************************************************** -->
<p>Note that if you are reading this file from a Subversion checkout or the
main LLVM web page, this document applies to the <i>next</i> release, not the
-current one. To see the release notes for a specific releases, please see the
+current one. To see the release notes for a specific release, please see the
<a href="http://llvm.org/releases/">releases page</a>.</p>
</div>
supporting tools) and the llvm-gcc repository. In addition to this code, the
LLVM Project includes other sub-projects that are in development. The two which
are the most actively developed are the <a href="#clang">Clang Project</a> and
-the <a href="#vmkit">vmkit Project</a>.
+the <a href="#vmkit">VMKit Project</a>.
</p>
</div>
yet production quality, it is progressing very nicely. In addition, C++
front-end work has started to make significant progress.</p>
-<p>Codegen progress/state
-</p>
+<p>Clang, in conjunction with the <tt>ccc</tt> driver, is now usable as a
+replacement for gcc for building some small- to medium-sized C applications.
+Additionally, Clang now has code generation support for Objective-C on Mac OS X
+platform. Major highlights include:</p>
+
+<ul>
+ <li> Clang/ccc pass almost all of the LLVM test suite on Mac OS X and Linux
+on the 32-bit x86 architecture. This includes significant C
+applications such as <a href="http://www.sqlite.org">sqlite3</a>,
+<a href="http://www.lua.org">lua</a>, and
+<a href="http://www.clamav.net">Clam AntiVirus</a>. </li>
+
+ <li> Clang can build the majority of Objective-C examples shipped with the
+Mac OS X Developer Tools. </li>
+</ul>
+
+<p>Clang code generation still needs considerable testing and development,
+however. Some areas under active development include:</p>
+
+<ul>
+ <li> Improved support for C and Objective-C features, for example
+ variable-length arrays, va_arg, exception handling (Obj-C), and garbage
+ collection (Obj-C). </li>
+ <li> ABI compatibility, especially for platforms other than 32-bit
+ x86. </li>
+</ul>
</div>
<div class="doc_text">
-<p>The
-<a href="http://clang.llvm.org/StaticAnalysis.html">static analysis tool</a>
-.</p>
+<p>The Clang project also includes an early stage static source code analysis
+tool for <a href="http://clang.llvm.org/StaticAnalysis.html">automatically
+finding bugs</a> in C and Objective-C programs. The tool performs a growing set
+of checks to find bugs that occur on a specific path within a program. Examples
+of bugs the tool finds include logic errors such as null dereferences,
+violations of various API rules, dead code, and potential memory leaks in
+Objective-C programs. Since its inception, public feedback on the tool has been
+extremely positive, and conservative estimates put the number of real bugs it
+has found in industrial-quality software on the order of thousands.</p>
+
+<p>The tool also provides a simple web GUI to inspect potential bugs found by
+the tool. While still early in development, the GUI illustrates some of the key
+features of Clang: accurate source location information, which is used by the
+GUI to highlight specific code expressions that relate to a bug (including those
+that span multiple lines); and built-in knowledge of macros, which is used to
+perform inline expansion of macros within the GUI itself.</p>
+
+<p>The set of checks performed by the static analyzer is gradually expanding,
+and future plans for the tool include full source-level inter-procedural
+analysis and deeper checks such as buffer overrun detection. There are many
+opportunities to extend and enhance the static analyzer, and anyone interested
+in working on this project is encouraged to get involved!</p>
</div>
<!--=========================================================================-->
<div class="doc_subsection">
-<a name="vmkit">vmkit: JVM/CLI Virtual Machine Implementation</a>
+<a name="vmkit">VMKit: JVM/CLI Virtual Machine Implementation</a>
</div>
<div class="doc_text">
<p>
-The <a href="http://vmkit.llvm.org/">vmkit project</a> is an implementation of
+The <a href="http://vmkit.llvm.org/">VMKit project</a> is an implementation of
a JVM and a CLI Virtual Machines (Microsoft .NET is an
implementation of the CLI) using the Just-In-Time compiler of LLVM.</p>
-<p>...</p>
+<p>Following LLVM 2.4, VMKit has its first release 0.24 that you can find on its
+<a href="http://vmkit.llvm.org/releases/">webpage</a>. The release includes
+bug fixes, cleanup and new features. The major changes are:</p>
+<ul>
+
+<li> Support for generics in the .Net virtual machine.</li>
+<li> Initial support for the Mono class libraries. </li>
+<li> Support for MacOSX/x86, following LLVM's support for exceptions in
+JIT on MacOSX/x86. </li>
+<li> A new vmkit driver: a program to run java or .net applications. The driver
+supports llvm command line arguments including the new "-fast" option. </li>
+<li> A new memory allocation scheme in the JVM that makes unloading a
+class loader very fast. </li>
+<li> VMKit now follows the LLVM Makefile machinery. </li>
+
+</ul>
</div>
<div class="doc_text">
-<p>This release includes a huge number of bug fixes, performance tweaks and
+<p>This release includes a huge number of bug fixes, performance tweaks, and
minor improvements. Some of the major improvements and new features are listed
in this section.
</p>
<p>LLVM 2.4 includes several major new capabilities:</p>
<ul>
-<li>
- <p>MRVs got generalized to FCAs. getresult is gone, ret with multiple values
- is gone.</p>
- </li>
-
-<li><p>-O0 compile times overall much faster</p></li>
-
-<li><p>Attrs changes?</p></li>
-
-
-<li><p>Initial PIC16 port</p></li>
-
-<li><p> Support the rest of the atomic __sync builtins</p></li>
-
-<li><p>...</p></li>
+<li><p>The most visible end-user change in LLVM 2.4 is that it includes many
+optimizations and changes to make -O0 compile times much faster. You should see
+improvements in speed on the order of 30% (or more) than in LLVM 2.3. There are
+many pieces to this change described in more detail below. The speedups and new
+components can also be used for JIT compilers that want fast
+compilation.</p></li>
+
+<li><p>The biggest change to the LLVM IR is that Multiple Return Values (which
+were introduced in LLVM 2.3) have been generalized to full support for "First
+Class Aggregate" values in LLVM 2.4. This means that LLVM IR supports using
+structs and arrays as values in a function. This capability is mostly useful
+for front-end authors, who prefer to treat things like complex numbers, simple
+tuples, dope vectors, etc., as Value*'s instead of as a tuple of Value*'s or as
+memory values. Bitcode files from LLVM 2.3 will automatically migrate to the
+general representation.</p></li>
+
+<li><p>LLVM 2.4 also includes an initial port for the PIC16 microprocessor. This
+target only has support for 8 bit registers, and a number of other crazy
+constraints. While the port is still in early development stages, it shows some
+interesting things you can do with LLVM.</p></li>
</ul>
<div class="doc_text">
-<p>LLVM 2.4 fully supports the llvm-gcc 4.2 front-end, and includes support
-for the C, C++, Objective-C, Ada, and Fortran front-ends.</p>
+<p>LLVM fully supports the llvm-gcc 4.2 front-end, which marries the GCC
+front-ends and driver with the LLVM optimizer and code generator. It currently
+includes support for the C, C++, Objective-C, Ada, and Fortran front-ends.</p>
-<p>
<ul>
-<li>block-pointers<li>
-<li>alpha?<li>
-<li>-flimited-precision</li>
-<li>-flto</li>
-
+<li>LLVM 2.4 supports the full set of atomic <tt>__sync_*</tt> builtins. LLVM
+2.3 only supported those used by OpenMP, but 2.4 supports them all. Note that
+while llvm-gcc supports all of these builtins, not all targets do. X86 support
+them all in both 32-bit and 64-bit mode and PowerPC supports them all except for
+the 64-bit operations when in 32-bit mode.</li>
+
+<li>llvm-gcc now supports an <tt>-flimited-precision</tt> option, which tells
+the compiler that it is okay to use low-precision approximations of certain libm
+functions (like <tt>exp</tt>, <tt>log</tt>, etc). This allows you to get high
+performance if you only need (say) 12-bits of precision.</li>
+
+<li>llvm-gcc now supports a C language extension known as "<a
+href="http://lists.cs.uiuc.edu/pipermail/cfe-dev/2008-August/002670.html">Blocks</a>".
+This feature is similar to nested functions and closures, but does not
+require stack trampolines (with most ABIs), and supports returning closures
+from functions that define them. Note that actually <em>using</em> Blocks
+requires a small runtime that is not included with llvm-gcc.</li>
+
+<li>llvm-gcc now supports a new <tt>-flto</tt> option. On systems that support
+transparent Link Time Optimization (currently Darwin systems with Xcode 3.1 and
+later) this allows the use of LTO with other optimization levels like -Os.
+Previously, LTO could only be used with -O4, which implied optimizations in
+-O3 that can increase code size.</li>
</ul>
</div>
</div>
<div class="doc_text">
-<p>New features include:
-</p>
+<p>New features include:</p>
<ul>
-<li>vector shifts in the IR: no codegen support yet</li>
-<li>use diet patch landed: saved 15% IR memory footprint</li>
+<li>A major change to the <tt>Use</tt> class landed, which shrank it by 25%. Since
+this is a pervasive part of the LLVM, it ended up reducing the memory use of
+LLVM IR in general by 15% for most programs.</li>
+
+<li>Values with no names are now pretty printed by <tt>llvm-dis</tt> more
+nicely. They now print as "<tt>%3 = add i32 %A, 4</tt>" instead of
+"<tt>add i32 %A, 4 ; <i32>:3</tt>", which makes it much easier to read.
+</li>
+
+<li>LLVM 2.4 includes some changes for better vector support. First, the shift
+operations (<tt>shl</tt>, <tt>ashr</tt>, and <tt>lshr</tt>) now all support
+vectors and do an element-by-element shift (shifts of the whole vector can be
+accomplished by bitcasting the vector to <tt><1 x i128></tt>, for example). Second,
+there is initial support in development for vector comparisons with the
+<tt><a href="LangRef.html#i_fcmp">fcmp</a>/<a href="LangRef.html#i_icmp">icmp</a></tt>
+instructions. These instructions compare two vectors and return a vector of
+<tt>i1</tt>'s for each result. Note that there is very little codegen support
+available for any of these IR features though.</li>
+
+<li>A new <tt>DebugInfoBuilder</tt> class is available, which makes it much
+easier for front-ends to create debug info descriptors, similar to the way that
+<tt>IRBuilder</tt> makes it easier to create LLVM IR.</li>
+
+<li>The <tt>IRBuilder</tt> class is now parameterized by a class responsible
+for constant folding. The default <tt>ConstantFolder</tt> class does target independent
+constant folding. The <tt>NoFolder</tt> class does no constant folding at all, which is
+useful when learning how LLVM works. The <tt>TargetFolder</tt> class folds the most,
+doing target dependent constant folding.</li>
+
+<li>LLVM now supports "function attributes", which allow us to separate return
+value attributes from function attributes. LLVM now supports attributes on a
+function itself, a return value, and its parameters. New supported function
+attributes include <tt>noinline/alwaysinline</tt> and the <tt>opt-size</tt> flag,
+which says the function should be optimized for code size.</li>
+
<li>LLVM IR now directly represents "common" linkage, instead of
representing it as a form of weak linkage.</li>
-<li>DebugInfoBuilder</li>
-<li>.ll printing format change: %3 = add i32 4, 2</li>
-<li>opt-size, noinline, alwaysinline function attributes</li>
-<li>...</li>
+
</ul>
</div>
<div class="doc_text">
-<p>In addition to a huge array of bug fixes and minor performance tweaks, the
-LLVM 2.4 optimizers support a few major enhancements:</p>
+<p>In addition to a huge array of bug fixes and minor performance tweaks, this
+release includes a few major enhancements and additions to the optimizers:</p>
<ul>
-<li>GVN now does local PRE?</li>
+<li>The Global Value Numbering (GVN) pass now does local Partial Redundancy
+Elimination (PRE) to eliminate some partially redundant expressions in cases
+where doing so won't grow code size.</li>
-<li>Matthijs' Dead argument elimination rewrite</li>
+<li>LLVM 2.4 includes a new loop deletion pass (which removes output-free
+provably-finite loops) and a rewritten Aggressive Dead Code Elimination (ADCE)
+pass that no longer uses control dependence information. These changes speed up
+the optimizer and also prevent it from deleting output-free infinite
+loops.</li>
-<li>Old-ADCE used control dependence and deleted output-free infinite loops.
-Added a new Loop deletion pass (for deleting output free provably-finite loops)
-and rewrote ADCE to be simpler faster, and not need control dependence.</li>
+<li>The new AddReadAttrs pass works out which functions are read-only or
+read-none (these correspond to 'pure' and 'const' in GCC) and marks them
+with the appropriate attribute.</li>
-<li>SparsePropagation framework for lattice-based dataflow solvers.</li>
+<li>LLVM 2.4 now includes a new SparsePropagation framework, which makes it
+trivial to build lattice-based dataflow solvers that operate over LLVM IR. Using
+this interface means that you just define objects to represent your lattice
+values and the transfer functions that operate on them. It handles the
+mechanics of worklist processing, liveness tracking, handling PHI nodes,
+etc.</li>
-<li>Tail duplication was removed from the standard optimizer sequence.</li>
+<li>The Loop Strength Reduction and induction variable optimization passes have
+several improvements to avoid inserting MAX expressions, to optimize simple
+floating point induction variables and to analyze trip counts of more
+loops.</li>
<li>Various helper functions (ComputeMaskedBits, ComputeNumSignBits, etc) were
-pulled out of instcombine and put into a new ValueTracking.h file, where they
-can be reused by other passes.</li>
+pulled out of the Instruction Combining pass and put into a new
+<tt>ValueTracking.h</tt> header, where they can be reused by other passes.</li>
+
+<li>The tail duplication pass has been removed from the standard optimizer
+sequence used by llvm-gcc. This pass still exists, but the benefits it once
+provided are now achieved by other passes.</li>
-<li>MarkModRef etc</li>
</ul>
</div>
<div class="doc_text">
-<p>We put a significant amount of work into the code generator infrastructure,
+<p>We have put a significant amount of work into the code generator infrastructure,
which allows us to implement more aggressive algorithms and make it run
faster:</p>
<ul>
-<li>asm writers split out to their own library to avoid JITs having to link
- them in.</li>
-<li>Big asm writer refactoring + TargetAsmInfo</li>
-<li>2-addr pass and coalescer can now remat trivial insts to avoid a copy.</li>
-<li>spiller to commute instructions in order to fold a reload</li>
-<li>Stack slot coloring?</li>
-<li>Live intervals renumbering? Is this useful to external people?</li>
-<li>'is as cheap as a move' instruction flag</li>
-<li>Improvements to selection dag viewing</li>
-<li>fast isel</li>
-<li>Selection dag speedups</li>
-<li>asmwriter + raw_ostream -> fastah</li>
-<li>Partitioned Boolean Quadratic Programming (PBQP) based register
-allocator.</li>
-<li>...</li>
+<li>The target-independent code generator supports (and the X86 backend
+ currently implements) a new interface for "fast" instruction selection. This
+ interface is optimized to produce code as quickly as possible, sacrificing
+ code quality to do it. This is used by default at -O0 or when using
+ "llc -fast" on X86. It is straight-forward to add support for
+ other targets if faster -O0 compilation is desired.</li>
+
+<li>In addition to the new 'fast' instruction selection path, many existing
+ pieces of the code generator have been optimized in significant ways.
+ SelectionDAG's are now pool allocated and use better algorithms in many
+ places, the ".s" file printers now use <tt>raw_ostream</tt> to emit text much faster,
+ etc. The end result of these improvements is that the compiler also takes
+ substantially less time to generate code that is just as good (and often
+ better) than before.</li>
+
+<li>Each target has been split to separate the ".s" file printing logic from the
+ rest of the target. This enables JIT compilers that don't link in the
+ (somewhat large) code and data tables used for printing a ".s" file.</li>
+
+<li>The code generator now includes a "stack slot coloring" pass, which packs
+ together individual spilled values into common stack slots. This reduces
+ the size of stack frames with many spills, which tends to increase L1 cache
+ effectiveness.</li>
+
+<li>Various pieces of the register allocator (e.g. the coalescer and two-address
+ operation elimination pass) now know how to rematerialize trivial operations
+ to avoid copies and include several other optimizations.</li>
+
+<li>The <a href="CodeGenerator.html#selectiondag_process">graphs</a> produced by
+ the <tt>llc -view-*-dags</tt> options are now significantly prettier and
+ easier to read.</li>
+
+<li>LLVM 2.4 includes a new register allocator based on Partitioned Boolean
+ Quadratic Programming (PBQP). This register allocator is still in
+ development, but is very simple and clean.</li>
</ul>
<!--=========================================================================-->
<div class="doc_subsection">
-<a name="x86specific">X86/X86-64 Specific Improvements</a>
+<a name="targetspecific">Target Specific Improvements</a>
</div>
<div class="doc_text">
<ul>
<li>Exception handling is supported by default on Linux/x86-64.</li>
<li>Position Independent Code (PIC) is now supported on Linux/x86-64.</li>
-<li>...</li>
-
-</ul>
-
-</div>
-
-<!--=========================================================================-->
-<div class="doc_subsection">
-<a name="targetspecific">Other Target Specific Improvements</a>
-</div>
-
-<div class="doc_text">
-<p>New target-specific features include:
-</p>
-
-<ul>
-<li>MIPS floating point support?</li>
-<li>PowerPC now supports trampolines.</li>
-<li>....</li>
+<li><tt>@llvm.frameaddress</tt> now supports getting the frame address of stack frames
+ > 0 on x86/x86-64.</li>
+<li>MIPS has improved a lot since last release, the most important changes
+ are: Little endian support, floating point support, allegrex core and
+ intrinsics support. O32 ABI is improved but isn't complete. The EABI
+ was implemented and is fully supported. We also have support for small
+ sections and gp_rel relocation for its access, a threshold in bytes can be
+ specified through command line.</li>
+<li>The PowerPC backend now supports trampolines.</li>
</ul>
</div>
<ul>
<li><tt>llvmc2</tt> (the generic compiler driver) gained plugin
- support. It is now easier to experiment with <tt>llvmc2</tt> and
- build your own tools based on it. </li>
-<li>raw_ostream + formatting</li>
-<li>Recycler + pool allocation stuff?</li>
-<li>...</li>
+ support. It is now easier to experiment with <tt>llvmc2</tt> and
+ build your own tools based on it.</li>
+
+<li>LLVM 2.4 includes a number of new generic algorithms and data structures,
+ including a scoped hash table, 'immutable' data structures, a simple
+ free-list manager, and a <tt>raw_ostream</tt> class.
+ The <tt>raw_ostream</tt> class and
+ <tt>format</tt> allow for efficient file output, and various pieces of LLVM
+ have switched over to use it. The eventual goal is to eliminate
+ use of <tt>std::ostream</tt> in favor of it.</li>
+
+<li>LLVM 2.4 includes an optional build system based on CMake. It
+ still is in its early stages but can be useful for Visual C++
+ users who can not use the Visual Studio IDE.</li>
+
</ul>
</div>
<div class="doc_text">
-<p>If you're already an LLVM user, this section lists some "gotchas" that you
-may run into upgrading from the previous release.</p>
+<p>If you're already an LLVM user or developer with out-of-tree changes based
+on LLVM 2.3, this section lists some "gotchas" that you may run into upgrading
+from the previous release.</p>
-<p>The LLVM IR generated by llvm-gcc no longer names all instructions.
- Use the instnamer pass if you want everything named.</p>
+<ul>
-<li>The LoadVN and GCSE passes have been removed.</li>
+<li>The LLVM IR generated by llvm-gcc no longer names all instructions. This
+ makes it run faster, but may be more confusing to some people. If you
+ prefer to have names, the '<tt>opt -instnamer</tt>' pass will add names to
+ all instructions.</li>
+
+<li>The LoadVN and GCSE passes have been removed from the tree. They are
+ obsolete and have been replaced with the GVN and MemoryDependence passes.
+ </li>
+</ul>
-<p>LLVM API Changes:</p>
+<p>In addition, many APIs have changed in this release. Some of the major LLVM
+API changes are:</p>
<ul>
-<li>... Attributes changes ... </li>
+<li>Now, function attributes and return value attributes are managed
+separately. Interface exported by <tt>ParameterAttributes.h</tt> header is now
+exported by <tt>Attributes.h</tt> header. The new attributes interface changes are:
+<ul>
+<li><tt>getParamAttrs</tt> method is now replaced by
+<tt>getParamAttributes</tt>, <tt>getRetAttributes</tt> and
+<tt>getFnAttributes</tt> methods.</li>
+<li> Return value attributes are stored at index 0. Function attributes are
+stored at index ~0U. Parameter attributes are stored at index that matches
+parameter number.</li>
+<li> <tt>ParamAttr</tt> namespace is now renamed as <tt>Attribute</tt>.</li>
+<li> The name of the class that manages reference count of opaque
+attributes is changed from <tt>PAListPtr</tt> to <tt>AttrListPtr</tt>.</li>
+<li> <tt>ParamAttrsWithIndex</tt> is now renamed as <tt>AttributeWithIndex</tt>.
+</li>
+</ul>
+</li>
<li>The <tt>DbgStopPointInst</tt> methods <tt>getDirectory</tt> and
<tt>getFileName</tt> now return <tt>Value*</tt> instead of strings. These can be
converted to strings using <tt>llvm::GetConstantStringInfo</tt> defined via
-"llvm/Analysis/ValueTracking.h".</li>
-
-<li>API change: BinaryOperator::create -> Create (CmpInst, CastInst too)</li>
-<li>Various header files like "llvm/ADT/iterator" were given a .h suffix.
- Change your code to #include "llvm/ADT/iterator.h" instead.</li>
-
+"<tt>llvm/Analysis/ValueTracking.h</tt>".</li>
+
+<li>The APIs to create various instructions have changed from lower case
+ "create" methods to upper case "Create" methods (e.g.
+ <tt>BinaryOperator::create</tt>). LLVM 2.4 includes both cases, but the
+ lower case ones are removed in mainline (2.5 and later), please migrate.</li>
+
+<li>Various header files like "<tt>llvm/ADT/iterator</tt>" were given a ".h" suffix.
+ Change your code to #include "<tt>llvm/ADT/iterator.h</tt>" instead.</li>
+
+<li>The <tt>getresult</tt> instruction has been removed and replaced with the
+ <tt>extractvalue</tt> instruction. This is part of support for first class
+ aggregates.</li>
+
+<li>In the code generator, many <tt>MachineOperand</tt> predicates were renamed to be
+ shorter (e.g. <tt>isFrameIndex()</tt> -> <tt>isFI()</tt>),
+ <tt>SDOperand</tt> was renamed to <tt>SDValue</tt> (and the "<tt>Val</tt>"
+ member was changed to be the <tt>getNode()</tt> accessor), and the
+ <tt>MVT::ValueType</tt> enum has been replaced with an "<tt>MVT</tt>"
+ struct. The <tt>getSignExtended</tt> and <tt>getValue</tt> methods in the
+ ConstantSDNode class were renamed to <tt>getSExtValue</tt> and
+ <tt>getZExtValue</tt> respectively, to be more consistent with
+ the <tt>ConstantInt</tt> class.</li>
</ul>
</div>
<p>LLVM is known to work on the following platforms:</p>
<ul>
-<li>Intel and AMD machines (IA32) running Red Hat Linux, Fedora Core and FreeBSD
- (and probably other unix-like systems).</li>
-<li>PowerPC and X86-based Mac OS X systems, running 10.3 and above in 32-bit and
- 64-bit modes.</li>
+<li>Intel and AMD machines (IA32, X86-64, AMD64, EMT-64) running Red Hat
+Linux, Fedora Core and FreeBSD (and probably other unix-like systems).</li>
+<li>PowerPC and X86-based Mac OS X systems, running 10.3 and above in 32-bit
+and 64-bit modes.</li>
<li>Intel and AMD machines running on Win32 using MinGW libraries (native).</li>
<li>Intel and AMD machines running on Win32 with the Cygwin libraries (limited
support is available for native builds with Visual C++).</li>
<div class="doc_text">
-<p>This section contains all known problems with the LLVM system, listed by
-component. As new problems are discovered, they will be added to these
-sections. If you run into a problem, please check the <a
+<p>This section contains significant known problems with the LLVM system,
+listed by component. If you run into a problem, please check the <a
href="http://llvm.org/bugs/">LLVM bug database</a> and submit a bug if
there isn't already one.</p>
href="http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev">LLVMdev list</a>.</p>
<ul>
-<li>The MSIL, IA64, Alpha, SPU, and MIPS backends are experimental.</li>
+<li>The MSIL, IA64, Alpha, SPU, MIPS, and PIC16 backends are experimental.</li>
<li>The llc "<tt>-filetype=asm</tt>" (the default) is the only supported
value for this option.</li>
</ul>
</div>
+<!-- ======================================================================= -->
+<div class="doc_subsection">
+ <a name="mips-be">Known problems with the MIPS back-end</a>
+</div>
+
+<div class="doc_text">
+
+<ul>
+<li>The O32 ABI is not fully supported.</li>
+<li>64-bit MIPS targets are not supported yet.</li>
+</ul>
+
+</div>
+
<!-- ======================================================================= -->
<div class="doc_subsection">
<a name="alpha-be">Known problems with the Alpha back-end</a>
<ul>
<li>The Itanium backend is highly experimental, and has a number of known
issues. We are looking for a maintainer for the Itanium backend. If you
- are interested, please contact the llvmdev mailing list.</li>
+ are interested, please contact the LLVMdev mailing list.</li>
</ul>
</div>
<p>llvm-gcc does not currently support <a href="http://llvm.org/PR869">Link-Time
Optimization</a> on most platforms "out-of-the-box". Please inquire on the
-llvmdev mailing list if you are interested.</p>
+LLVMdev mailing list if you are interested.</p>
<p>The only major language feature of GCC not supported by llvm-gcc is
the <tt>__builtin_apply</tt> family of builtins. However, some extensions
<ul>
<li>Exception handling works well on the X86 and PowerPC targets. Currently
- only linux and darwin targets are supported (both 32 and 64 bit).</li>
+ only Linux and Darwin targets are supported (both 32 and 64 bit).</li>
</ul>
</div>
+<!-- ======================================================================= -->
+<div class="doc_subsection">
+ <a name="fortran-fe">Known problems with the llvm-gcc Fortran front-end</a>
+</div>
+
+<div class="doc_text">
+<ul>
+<li>Fortran support generally works, but there are still several unresolved bugs
+ in Bugzilla. Please see the tools/gfortran component for details.</li>
+
+<li>The Fortran front-end currently does not build on Darwin (without tweaks)
+ due to unresolved dependencies on the C front-end.</li>
+</ul>
+</div>
<!-- ======================================================================= -->
<div class="doc_subsection">
<hr>
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