strip out the 2.7 release notes, this really is the 2.8 release notes

now. Add a few items like the fpstackifier improvements. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@109013 91177308-0d34-0410-b5e6-96231b3b80d8
2025-08-09 11:25:55 +00:00 · 2010-07-21 15:57:40 +00:00
parent bc56501435
commit 922d00f5f5
1 changed files with 27 additions and 507 deletions
--- a/docs/ReleaseNotes.html
+++ b/docs/ReleaseNotes.html
@@ -118,40 +118,9 @@ modular, library-based architecture that makes it suitable for creating or
 integrating with other development tools. Clang is considered a
 production-quality compiler for C and Objective-C on x86 (32- and 64-bit).</p>
-<p>In the LLVM 2.7 time-frame, the Clang team has made many improvements:</p>
+<p>In the LLVM 2.8 time-frame, the Clang team has made many improvements:</p>
 <ul>
 <li>C++ Support: Clang is now capable of self-hosting! While still
 alpha-quality, Clang's C++ support has matured enough to build LLVM and Clang,
 and C++ is now enabled by default. See the <a
 href="http://clang.llvm.org/cxx_compatibility.html">Clang C++ compatibility
 page</a> for common C++ migration issues.</li>
 <li>Objective-C: Clang now includes experimental support for an updated
 Objective-C ABI on non-Darwin platforms.  This includes support for non-fragile
 instance variables and accelerated proxies, as well as greater potential for
 future optimisations.  The new ABI is used when compiling with the
 -fobjc-nonfragile-abi and -fgnu-runtime options.  Code compiled with these
 options may be mixed with code compiled with GCC or clang using the old GNU ABI,
 but requires the libobjc2 runtime from the GNUstep project.</li>
 <li>New warnings: Clang contains a number of new warnings, including
 control-flow warnings (unreachable code, missing return statements in a
 non-<code>void</code> function, etc.), sign-comparison warnings, and improved
 format-string warnings.</li>
 <li>CIndex API and Python bindings: Clang now includes a C API as part of the
 CIndex library. Although we may make some changes to the API in the future, it
 is intended to be stable and has been designed for use by external projects. See
 the Clang
 doxygen <a href="http://clang.llvm.org/doxygen/group__CINDEX.html">CIndex</a>
 documentation for more details. The CIndex API also includes a preliminary
 set of Python bindings.</li>
 <li>ARM Support: Clang now has ABI support for both the Darwin and Linux ARM
 ABIs. Coupled with many improvements to the LLVM ARM backend, Clang is now
 suitable for use as a beta quality ARM compiler.</li>
 </ul>
 </div>
@@ -170,10 +139,7 @@ suitable for use as a beta quality ARM compiler.</li>
   future</a>!).  The tool is very good at finding bugs that occur on specific
   paths through code, such as on error conditions.</p>
-<p>In the LLVM 2.7 time-frame, the analyzer core has made several major and 
+<p>In the LLVM 2.8 time-frame, 
   minor improvements, including better support for tracking the fields of
   structures, initial support (not enabled by default yet) for doing
   interprocedural (cross-function) analysis, and new checks have been added.
 </p>
 </div>
@@ -190,26 +156,8 @@ a JVM and a CLI Virtual Machine (Microsoft .NET is an
 implementation of the CLI) using LLVM for static and just-in-time
 compilation.</p>
-<p>
+<p>With the release of LLVM 2.8, ...</p>
 With the release of LLVM 2.7, VMKit has shifted to a great framework for writing
 virtual machines. VMKit now offers precise and efficient garbage collection with
 multi-threading support, thanks to the MMTk memory management toolkit, as well
 as just in time and ahead of time compilation with LLVM.  The major changes in
 VMKit 0.27 are:</p>
 <ul>
 <li>Garbage collection: VMKit now uses the MMTk toolkit for garbage collectors.
  The first collector to be ported is the MarkSweep collector, which is precise,
  and drastically improves the performance of VMKit.</li>
 <li>Line number information in the JVM: by using the debug metadata of LLVM, the
 JVM now supports precise line number information, useful when printing a stack
 trace.</li>
 <li>Interface calls in the JVM: we implemented a variant of the Interface Method
  Table technique for interface calls in the JVM.
 </li>
 </ul>
 </div>
@@ -231,8 +179,10 @@ libgcc routines).</p>
 <p>
 All of the code in the compiler-rt project is available under the standard LLVM
-License, a "BSD-style" license.  New in LLVM 2.7: compiler_rt now
+License, a "BSD-style" license.  New in LLVM 2.8: 
-supports ARM targets.</p>
+
 Soft float support
 </p>
 </div>
@@ -265,7 +215,7 @@ supported, and only on linux and darwin (darwin needs an additional gcc patch).
 </p>
 <p>
-DragonEgg is a new project which is seeing its first release with llvm-2.7.
+2.8 status here.
 </p>
 </div>
@@ -288,23 +238,13 @@ href="http://blog.llvm.org/2010/04/intro-to-llvm-mc-project.html">Intro to the
 LLVM MC Project Blog Post</a>.
 </p>
-<p>2.7 includes major parts of the work required by the new MC Project.  A few
+<p>2.8 status here</p>
   targets have been refactored to support it, and work is underway to support a
   native assembler in LLVM.  This work is not complete in LLVM 2.7, but it has
   made substantially more progress on LLVM mainline.</p>
 <p>One minor example of what MC can do is to transcode an AT&amp;T syntax
   X86 .s file into intel syntax.  You can do this with something like:</p>
 <pre>
  llvm-mc foo.s -output-asm-variant=1 -o foo-intel.s
 </pre>
 </div>	
 <!-- *********************************************************************** -->
 <div class="doc_section">
-  <a name="externalproj">External Open Source Projects Using LLVM 2.7</a>
+  <a name="externalproj">External Open Source Projects Using LLVM 2.8</a>
 </div>
 <!-- *********************************************************************** -->
@@ -312,171 +252,13 @@ LLVM MC Project Blog Post</a>.
 <p>An exciting aspect of LLVM is that it is used as an enabling technology for
   a lot of other language and tools projects.  This section lists some of the
-   projects that have already been updated to work with LLVM 2.7.</p>
+   projects that have already been updated to work with LLVM 2.8.</p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="pure">Pure</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://pure-lang.googlecode.com/">Pure</a>
 is an algebraic/functional programming language based on term rewriting.
 Programs are collections of equations which are used to evaluate expressions in
 a symbolic fashion. Pure offers dynamic typing, eager and lazy evaluation,
 lexical closures, a hygienic macro system (also based on term rewriting),
 built-in list and matrix support (including list and matrix comprehensions) and
 an easy-to-use C interface. The interpreter uses LLVM as a backend to
 JIT-compile Pure programs to fast native code.</p>
 <p>Pure versions 0.43 and later have been tested and are known to work with
 LLVM 2.7 (and continue to work with older LLVM releases >= 2.5).</p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="RoadsendPHP">Roadsend PHP</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://code.roadsend.com/rphp">Roadsend PHP</a> (rphp) is an open
 source implementation of the PHP programming 
 language that uses LLVM for its optimizer, JIT and static compiler. This is a 
 reimplementation of an earlier project that is now based on LLVM.
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="UnladenSwallow">Unladen Swallow</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://code.google.com/p/unladen-swallow/">Unladen Swallow</a> is a
 branch of <a href="http://python.org/">Python</a> intended to be fully
 compatible and significantly faster.  It uses LLVM's optimization passes and JIT
 compiler.
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="tce">TTA-based Codesign Environment (TCE)</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://tce.cs.tut.fi/">TCE</a> is a toolset for designing
 application-specific processors (ASP) based on the Transport triggered
 architecture (TTA). The toolset provides a complete co-design flow from C/C++
 programs down to synthesizable VHDL and parallel program binaries. Processor
 customization points include the register files, function units, supported
 operations, and the interconnection network.</p>
 <p>TCE uses llvm-gcc/Clang and LLVM for C/C++ language support, target
 independent optimizations and also for parts of code generation. It generates
 new LLVM-based code generators "on the fly" for the designed TTA processors and
 loads them in to the compiler backend as runtime libraries to avoid per-target
 recompilation of larger parts of the compiler chain.</p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="safecode">SAFECode Compiler</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://safecode.cs.illinois.edu">SAFECode</a> is a memory safe C
 compiler built using LLVM.  It takes standard, unannotated C code, analyzes the
 code to ensure that memory accesses and array indexing operations are safe, and
 instruments the code with run-time checks when safety cannot be proven
 statically.
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="icedtea">IcedTea Java Virtual Machine Implementation</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://icedtea.classpath.org/wiki/Main_Page">IcedTea</a> provides a
 harness to build OpenJDK using only free software build tools and to provide
 replacements for the not-yet free parts of OpenJDK.  One of the extensions that
 IcedTea provides is a new JIT compiler named <a
 href="http://icedtea.classpath.org/wiki/ZeroSharkFaq">Shark</a> which uses LLVM
 to provide native code generation without introducing processor-dependent
 code.
 </p>
 <p>Icedtea6 1.8 and later have been tested and are known to work with
 LLVM 2.7 (and continue to work with older LLVM releases >= 2.6 as well).
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="llvm-lua">LLVM-Lua</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://code.google.com/p/llvm-lua/">LLVM-Lua</a> uses LLVM
 to add JIT and static compiling support to the Lua VM. Lua 
 bytecode is analyzed to remove type checks, then LLVM is used to compile the 
 bytecode down to machine code.
 </p>
 <p>LLVM-Lua 1.2.0  have been tested and is known to work with LLVM 2.7.
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="MacRuby">MacRuby</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://macruby.org">MacRuby</a> is an implementation of Ruby based on
 core Mac OS technologies, sponsored by Apple Inc.  It uses LLVM at runtime for
 optimization passes, JIT compilation and exception handling. It also allows
 static (ahead-of-time) compilation of Ruby code straight to machine code. 
 </p>
 <p>The upcoming MacRuby 0.6 release works with LLVM 2.7.
 </p>
 </div>
 <!--=========================================================================-->
 <div class="doc_subsection">
 <a name="GHC">Glasgow Haskell Compiler (GHC)</a>
 </div>
 <div class="doc_text">
 <p>
 <a href="http://www.haskell.org/ghc/">GHC</a> is an open source,
 state-of-the-art programming suite for Haskell, a standard lazy
 functional programming language. It includes an optimizing static
 compiler generating good code for a variety of platforms, together
 with an interactive system for convenient, quick development.</p>
 <p>In addition to the existing C and native code generators, GHC now
 supports an <a
 href="http://hackage.haskell.org/trac/ghc/wiki/Commentary/Compiler/Backends/LLVM">LLVM
 code generator</a>. GHC supports LLVM 2.7.</p>
 </div>
 <!-- *********************************************************************** -->
 <div class="doc_section">
-  <a name="whatsnew">What's New in LLVM 2.7?</a>
+  <a name="whatsnew">What's New in LLVM 2.8?</a>
 </div>
 <!-- *********************************************************************** -->
@@ -496,29 +278,11 @@ in this section.
 <div class="doc_text">
-<p>In addition to changes to the code, between LLVM 2.6 and 2.7, a number of
+<p>In addition to changes to the code, between LLVM 2.7 and 2.8, a number of
 organization changes have happened:
 </p>
 <ul>
 <li>LLVM has a new <a href="http://llvm.org/Logo.html">official logo</a>!</li>
 <li>Ted Kremenek and Doug Gregor have stepped forward as <a
 href="http://llvm.org/docs/DeveloperPolicy.html#owners">Code Owners</a> of the
 Clang static analyzer and the Clang frontend, respectively.</li>
 <li>LLVM now has an <a href="http://blog.llvm.org">official Blog</a> at
    <a href="http://blog.llvm.org">http://blog.llvm.org</a>. This is a great way
    to learn about new LLVM-related features as they are implemented.  Several
    features in this release are already explained on the blog.</li>
 <li>The LLVM web pages are now checked into the SVN server, in the "www",
    "www-pubs" and "www-releases" SVN modules.  Previously they were hidden in a
    largely inaccessible old CVS server.</li>
 <li><a href="http://llvm.org">llvm.org</a> is now hosted on a new (and much
    faster) server.  It is still graciously hosted at the University of Illinois
    of Urbana Champaign.</li>
 </ul>
 </div>
@@ -529,43 +293,10 @@ organization changes have happened:
 <div class="doc_text">
-<p>LLVM 2.7 includes several major new capabilities:</p>
+<p>LLVM 2.8 includes several major new capabilities:</p>
 <ul>
-<li>2.7 includes initial support for the <a
+<li>.</li>
  href="http://en.wikipedia.org/wiki/MicroBlaze">MicroBlaze</a> target.
  MicroBlaze is a soft processor core designed for Xilinx FPGAs.</li>
 <li>2.7 includes a new LLVM IR "extensible metadata" feature.  This feature
 supports many different use cases, including allowing front-end authors to
 encode source level information into LLVM IR, which is consumed by later
 language-specific passes.  This is a great way to do high-level optimizations
 like devirtualization, type-based alias analysis, etc.  See the <a 
 href="http://blog.llvm.org/2010/04/extensible-metadata-in-llvm-ir.html">
 Extensible Metadata Blog Post</a> for more information.</li>
 <li>2.7 encodes <a href="SourceLevelDebugging.html">debug information</a>
 in a completely new way, built on extensible metadata.  The new implementation
 is much more memory efficient and paves the way for improvements to optimized
 code debugging experience.</li>
 <li>2.7 now directly supports taking the address of a label and doing an
    indirect branch through a pointer.  This is particularly useful for
    interpreter loops, and is used to implement the GCC "address of label"
    extension.  For more information, see the <a 
 href="http://blog.llvm.org/2010/01/address-of-label-and-indirect-branches.html">
 Address of Label and Indirect Branches in LLVM IR Blog Post</a>.
 <li>2.7 is the first release to start supporting APIs for assembling and
    disassembling target machine code.  These APIs are useful for a variety of
    low level clients, and are surfaced in the new "enhanced disassembly" API.
    For more information see the <a 
    href="http://blog.llvm.org/2010/01/x86-disassembler.html">The X86
    Disassembler Blog Post</a> for more information.</li>
 <li>2.7 includes major parts of the work required by the new MC Project, 
    see the <a href="#mc">MC update above</a> for more information.</li>
 </ul>
 </div>
@@ -580,31 +311,6 @@ Address of Label and Indirect Branches in LLVM IR Blog Post</a>.
 expose new optimization opportunities:</p>
 <ul>
 <li>LLVM IR now supports a 16-bit "half float" data type through <a
   href="LangRef.html#int_fp16">two new intrinsics</a> and APFloat support.</li>
 <li>LLVM IR supports two new <a href="LangRef.html#fnattrs">function
    attributes</a>: inlinehint and alignstack(n).  The former is a hint to the
    optimizer that a function was declared 'inline' and thus the inliner should
    weight it higher when considering inlining it.  The later
    indicates to the code generator that the function diverges from the platform
    ABI on stack alignment.</li>
 <li>The new <a href="LangRef.html#int_objectsize">llvm.objectsize</a> intrinsic
    allows the optimizer to infer the sizes of memory objects in some cases.
    This intrinsic is used to implement the GCC <tt>__builtin_object_size</tt>
    extension.</li>
 <li>LLVM IR now supports marking load and store instructions with <a
    href="LangRef.html#i_load">"non-temporal" hints</a> (building on the new
    metadata feature).  This hint encourages the code
    generator to generate non-temporal accesses when possible, which are useful
    for code that is carefully managing cache behavior.  Currently, only the
    X86 backend provides target support for this feature.</li>
 <li>LLVM 2.7 has pre-alpha support for <a
  href="LangRef.html#t_union">unions in LLVM IR</a>.
  Unfortunately, this support is not really usable in 2.7, so if you're
 interested in pushing it forward, please help contribute to LLVM mainline.</li>
 <!-- BELOW COME ACTUAL 2.8 CHANGES -->
 <li>LLVM 2.8 changes the internal order of operands in <a
  href="http://llvm.org/doxygen/classllvm_1_1InvokeInst.html"><tt>InvokeInst</tt></a>
@@ -629,48 +335,7 @@ release includes a few major enhancements and additions to the optimizers:</p>
 <ul>
-<li>The inliner now merges arrays stack objects in different callees when
+<li></li>
    inlining multiple call sites into one function.  This reduces the stack size
    of the resultant function.</li>
 <li>The -basicaa alias analysis pass (which is the default) has been improved to
    be less dependent on "type safe" pointers.  It can now look through bitcasts
    and other constructs more aggressively, allowing better load/store
    optimization.</li>
 <li>The load elimination optimization in the GVN Pass [<a
 href="http://blog.llvm.org/2009/12/introduction-to-load-elimination-in-gvn.html">intro
 blog post</a>] has been substantially improved to be more aggressive about
 partial redundancy elimination and do more aggressive phi translation.  Please
 see the <a
 href="http://blog.llvm.org/2009/12/advanced-topics-in-redundant-load.html">
 Advanced Topics in Redundant Load Elimination with a Focus on PHI Translation
 Blog Post</a> for more details.</li>
 <li>The module <a href="LangRef.html#datalayout">target data string</a> now
    includes a notion of 'native' integer data types for the target. This
    helps mid-level optimizations avoid promoting complex sequences of
    operations to data types that are not natively supported (e.g. converting
    i32 operations to i64 on 32-bit chips).</li>
 <li>The mid-level optimizer is now conservative when operating on a module with
    no target data.  Previously, it would default to SparcV9 settings, which is
    not what most people expected.</li>
 <li>Jump threading is now much more aggressive at simplifying correlated
   conditionals and threading blocks with otherwise complex logic. It has
   subsumed the old "Conditional Propagation" pass, and -condprop has been
   removed from LLVM 2.7.</li>
 <li>The -instcombine pass has been refactored from being one huge file to being
    a library of its own.  Internally, it uses a customized IRBuilder to clean
    it up and simplify it.</li>
 <li>The optimal edge profiling pass is reliable and much more complete than in
    2.6.  It can be used with the llvm-prof tool but isn't wired up to the
    llvm-gcc and clang command line options yet.</li>
 <li>A new experimental alias analysis implementation, -scev-aa, has been added.
    It uses LLVM's Scalar Evolution implementation to do symbolic analysis of
    pointer offset expressions to disambiguate pointers.  It can catch a few
    cases that basicaa cannot, particularly in complex loop nests.</li>
 <li>The default pass ordering has been tweaked for improved optimization
    effectiveness.</li>
 </ul>
@@ -685,19 +350,7 @@ href="http://blog.llvm.org/2009/12/introduction-to-load-elimination-in-gvn.html"
 <div class="doc_text">
 <ul>
-<li>The JIT now supports generating debug information and is compatible with
+<li></li>
 the new GDB 7.0 (and later) interfaces for registering dynamically generated
 debug info.</li>
 <li>The JIT now <a href="http://llvm.org/PR5184">defaults
 to compiling eagerly</a> to avoid a race condition in the lazy JIT.
 Clients that still want the lazy JIT can switch it on by calling
 <tt>ExecutionEngine::DisableLazyCompilation(false)</tt>.</li>
 <li>It is now possible to create more than one JIT instance in the same process.
 These JITs can generate machine code in parallel,
 although <a href="http://llvm.org/docs/ProgrammersManual.html#jitthreading">you
 still have to obey the other threading restrictions</a>.</li>
 </ul>
@@ -715,49 +368,7 @@ infrastructure, which allows us to implement more aggressive algorithms and make
 it run faster:</p>
 <ul>
-<li>The 'llc -asm-verbose' option (which is now the default) has been enhanced
+<li>MachO writer works.</li>
    to emit many useful comments to .s files indicating information about spill
    slots and loop nest structure.  This should make it much easier to read and
    understand assembly files.  This is wired up in llvm-gcc and clang to
    the <tt>-fverbose-asm</tt> option.</li>
 <li>New LSR with "full strength reduction" mode, which can reduce address
    register pressure in loops where address generation is important.</li>
 <li>A new codegen level Common Subexpression Elimination pass (MachineCSE)
    is available and enabled by default.  It catches redundancies exposed by
    lowering.</li>
 <li>A new pre-register-allocation tail duplication pass is available and enabled
    by default, it can substantially improve branch prediction quality in some
    cases.</li>
 <li>A new sign and zero extension optimization pass (OptimizeExtsPass) 
    is available and enabled by default.  This pass can takes advantage
    architecture features like x86-64 implicit zero extension behavior and
    sub-registers.</li>
 <li>The code generator now supports a mode where it attempts to preserve the
    order of instructions in the input code.  This is important for source that
    is hand scheduled and extremely sensitive to scheduling.  It is compatible
    with the GCC <tt>-fno-schedule-insns</tt> option.</li>
 <li>The target-independent code generator now supports generating code with
    arbitrary numbers of result values.  Returning more values than was
    previously supported is handled by returning through a hidden pointer.  In
    2.7, only the X86 and XCore targets have adopted support for this
    though.</li>
 <li>The code generator now supports generating code that follows the
    <a href="LangRef.html#callingconv">Glasgow Haskell Compiler Calling
    Convention</a> and ABI.</li>
 <li>The "<a href="CodeGenerator.html#selectiondag_select">DAG instruction
    selection</a>" phase of the code generator has been largely rewritten for
    2.7.  Previously, tblgen spit out tons of C++ code which was compiled and
    linked into the target to do the pattern matching, now it emits a much
    smaller table which is read by the target-independent code.  The primary
    advantages of this approach is that the size and compile time of various
    targets is much improved.  The X86 code generator shrunk by 1.5MB of code,
    for example.</li>
 <li>Almost the entire code generator has switched to emitting code through the
    MC interfaces instead of printing textually to the .s file.  This led to a
    number of cleanups and speedups.  In 2.7, debug an exception handling
    information does not go through MC yet.</li>
 </ul>
 </div>
@@ -771,11 +382,9 @@ it run faster:</p>
 </p>
 <ul>
-<li>The X86 backend now optimizes tails calls much more aggressively for
+<li>The X86 backend now supports holding X87 floating point stack values
-    functions that use the standard C calling convention.</li>
+    in registers across basic blocks, dramatically improving performance of code
-<li>The X86 backend now models scalar SSE registers as subregs of the SSE vector
+    that uses long double, and when targetting CPUs that don't support SSE.</li>
    registers, making the code generator more aggressive in cases where scalars
    and vector types are mixed.</li>
 </ul>
@@ -792,27 +401,7 @@ it run faster:</p>
 <ul>
-<li>The ARM backend now generates instructions in unified assembly syntax.</li>
+<li></li>
 <li>llvm-gcc now has complete support for the ARM v7 NEON instruction set.  This
   support differs slightly from the GCC implementation.  Please see the
   <a
 href="http://blog.llvm.org/2010/04/arm-advanced-simd-neon-intrinsics-and.html">
  ARM Advanced SIMD (NEON) Intrinsics and Types in LLVM Blog Post</a> for
  helpful information if migrating code from GCC to LLVM-GCC.</li>
 <li>The ARM and Thumb code generators now use register scavenging for stack
    object address materialization. This allows the use of R3 as a general
    purpose register in Thumb1 code, as it was previous reserved for use in
    stack address materialization. Secondly, sequential uses of the same
    value will now re-use the materialized constant.</li>
 <li>The ARM backend now has good support for ARMv4 targets and has been tested
    on StrongARM hardware.  Previously, LLVM only supported ARMv4T and
    newer chips.</li>
 <li>Atomic builtins are now supported for ARMv6 and ARMv7 (__sync_synchronize,
    __sync_fetch_and_add, etc.).</li>
 </ul>
@@ -831,34 +420,7 @@ href="http://blog.llvm.org/2010/04/arm-advanced-simd-neon-intrinsics-and.html">
 </p>
 <ul>
-<li>The optimizer uses the new CodeMetrics class to measure the size of code.
+<li></li>
    Various passes (like the inliner, loop unswitcher, etc) all use this to make
    more accurate estimates of the code size impact of various
    optimizations.</li>
 <li>A new <a href="http://llvm.org/doxygen/InstructionSimplify_8h-source.html">
    llvm/Analysis/InstructionSimplify.h</a> interface is available for doing
    symbolic simplification of instructions (e.g. <tt>a+0</tt> -&gt; <tt>a</tt>)
    without requiring the instruction to exist.  This centralizes a lot of
    ad-hoc symbolic manipulation code scattered in various passes.</li>
 <li>The optimizer now uses a new <a
    href="http://llvm.org/doxygen/SSAUpdater_8h-source.html">SSAUpdater</a>
    class which efficiently supports
    doing unstructured SSA update operations.  This centralized a bunch of code
    scattered throughout various passes (e.g. jump threading, lcssa,
    loop rotate, etc) for doing this sort of thing.  The code generator has a
    similar <a href="http://llvm.org/doxygen/MachineSSAUpdater_8h-source.html">
    MachineSSAUpdater</a> class.</li>
 <li>The <a href="http://llvm.org/doxygen/Regex_8h-source.html">
    llvm/Support/Regex.h</a> header exposes a platform independent regular
    expression API.  Building on this, the <a
    href="TestingGuide.html#FileCheck">FileCheck</a> utility now supports
    regular exressions.</li>
 <li>raw_ostream now supports a circular "debug stream" accessed with "dbgs()".
    By default, this stream works the same way as "errs()", but if you pass
    <tt>-debug-buffer-size=1000</tt> to opt, the debug stream is capped to a
    fixed sized circular buffer and the output is printed at the end of the
    program's execution.  This is helpful if you have a long lived compiler
    process and you're interested in seeing snapshots in time.</li>
 </ul>
@@ -873,16 +435,7 @@ href="http://blog.llvm.org/2010/04/arm-advanced-simd-neon-intrinsics-and.html">
 <p>Other miscellaneous features include:</p>
 <ul>
-<li>You can now build LLVM as a big dynamic library (e.g. "libllvm2.7.so"). To
+<li></li>
    get this, configure LLVM with the --enable-shared option.</li>
 <li>LLVM command line tools now overwrite their output by default. Previously,
    they would only do this with -f. This makes them more convenient to use, and
    behave more like standard unix tools.</li>
 <li>The opt and llc tools now autodetect whether their input is a .ll or .bc
    file, and automatically do the right thing.  This means you don't need to
    explicitly use the llvm-as tool for most things.</li>
 </ul>
 </div>
@@ -896,48 +449,18 @@ href="http://blog.llvm.org/2010/04/arm-advanced-simd-neon-intrinsics-and.html">
 <div class="doc_text">
 <p>If you're already an LLVM user or developer with out-of-tree changes based
-on LLVM 2.6, this section lists some "gotchas" that you may run into upgrading
+on LLVM 2.7, this section lists some "gotchas" that you may run into upgrading
 from the previous release.</p>
 <ul>
-<li>
+<li>.</li>
 The Andersen's alias analysis ("anders-aa") pass, the Predicate Simplifier
 ("predsimplify") pass, the LoopVR pass, the GVNPRE pass, and the random sampling
 profiling ("rsprofiling") passes have all been removed.  They were not being
 actively maintained and had substantial problems.  If you are interested in
 these components, you are welcome to ressurect them from SVN, fix the
 correctness problems, and resubmit them to mainline.</li>
 <li>LLVM now defaults to building most libraries with RTTI turned off, providing
 a code size reduction.  Packagers who are interested in building LLVM to support
 plugins that require RTTI information should build with "make REQUIRE_RTTI=1"
 and should read the new <a href="Packaging.html">Advice on Packaging LLVM</a>
 document.</li>
 <li>The LLVM interpreter now defaults to <em>not</em> using <tt>libffi</tt> even
 if you have it installed.  This makes it more likely that an LLVM built on one
 system will work when copied to a similar system.  To use <tt>libffi</tt>,
 configure with <tt>--enable-libffi</tt>.</li>
 <li>Debug information uses a completely different representation, an LLVM 2.6
 .bc file should work with LLVM 2.7, but debug info won't come forward.</li>
 <li>The LLVM 2.6 (and earlier) "malloc" and "free" instructions got removed,
    along with LowerAllocations pass.  Now you should just use a call to the
    malloc and free functions in libc.  These calls are optimized as well as
    the old instructions were.</li>
 </ul>
 <p>In addition, many APIs have changed in this release.  Some of the major LLVM
 API changes are:</p>
 <ul>
 <li>The <tt>add</tt>, <tt>sub</tt>, and <tt>mul</tt> instructions no longer
 support floating-point operands. The <tt>fadd</tt>, <tt>fsub</tt>, and
 <tt>fmul</tt> instructions should be used for this purpose instead.</li>
 </ul>
 </div>
@@ -1016,8 +539,7 @@ href="http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev">LLVMdev list</a>.</p>
 <li>The MSIL, Alpha, SPU, MIPS, PIC16, Blackfin, MSP430, SystemZ and MicroBlaze
    backends are experimental.</li>
 <li><tt>llc</tt> "<tt>-filetype=asm</tt>" (the default) is the only
-    supported value for this option.  The MachO writer is experimental, and
+    supported value for this option.  XXX Update me</li>
    works much better in mainline SVN.</li>
 </ul>
 </div>
@@ -1034,8 +556,6 @@ href="http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev">LLVMdev list</a>.</p>
    all <a href="http://llvm.org/PR879">inline assembly that uses the X86
    floating point stack</a>.  It supports the 'f' and 't' constraints, but not
    'u'.</li>
  <li>The X86 backend generates inefficient floating point code when configured
    to generate code for systems that don't have SSE2.</li>
  <li>Win64 code generation wasn't widely tested. Everything should work, but we
    expect small issues to happen. Also, llvm-gcc cannot build the mingw64
    runtime currently due to lack of support for the 'u' inline assembly