continue decoding chris scribble.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@83719 91177308-0d34-0410-b5e6-96231b3b80d8
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Chris Lattner 2009-10-10 19:00:55 +00:00
parent 60f034097e
commit cfb92fe54e

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@ -77,7 +77,7 @@ Almost dead code.
Logo web page.
llvm devmtg
compiler_rt
klee web page at klee.llvm.org
KLEE web page at klee.llvm.org
Many new papers added to /pubs/
Mention gcc plugin.
@ -216,19 +216,19 @@ License, a "BSD-style" license.</p>
<!--=========================================================================-->
<div class="doc_subsection">
<a name="klee">klee: Symbolic Execution and Automatic Test Case Generator</a>
<a name="klee">KLEE: Symbolic Execution and Automatic Test Case Generator</a>
</div>
<div class="doc_text">
<p>
The new LLVM <a href="http://klee.llvm.org/">klee project</a> is a symbolic
execution framework for programs in LLVM bitcode form. Klee tries to
The new LLVM <a href="http://klee.llvm.org/">KLEE project</a> is a symbolic
execution framework for programs in LLVM bitcode form. KLEE tries to
symbolically evaluate "all" paths through the application and records state
transitions that lead to fault states. This allows it to construct testcases
that lead to faults and can even be used to verify algorithms. For more
details, please see the <a
href="http://llvm.org/pubs/2008-12-OSDI-KLEE.html">OSDI 2008 paper</a> about
Klee.</p>
KLEE.</p>
</div>
@ -441,7 +441,7 @@ in this section.
<p>LLVM 2.6 includes several major new capabilities:</p>
<ul>
<li>New <a href="#compiler-rt">compiler-rt</a>, <A href="#klee">klee</a>,
<li>New <a href="#compiler-rt">compiler-rt</a>, <A href="#klee">KLEE</a>,
and <a href="#mc">machine code toolkit</a> sub-projects.</li>
<li>Debug information now includes line numbers when optimizations are enabled.
This allows statistical sampling tools like oprofile and Shark to map
@ -529,17 +529,28 @@ expose new optimization opportunities:</p>
<div class="doc_text">
<p>In addition to a large array of bug fixes and minor performance tweaks, this
<p>In addition to a large array of minor performance tweaks and bug fixes, this
release includes a few major enhancements and additions to the optimizers:</p>
<ul>
<li>SRoA improvements for vector unions, memset, arbitrary weird bitfield accesses etc. It now produces "strange" sized integers.</li>
<li>Inliner reuse stack space when inlining arrays?</li>
<li>Enabled GVN Load PRE.</li>
<li>New Static Single Information (SSI) construction pass (not used by anything yet, experimental).</li>
<li>LSR promotes int induction variables to 64-bit on 64-bit targets, major perf boost for numerical code.</li>
<li>LSR now analyzes pointer expressions (e.g. getelementptrs), not just integers.</li>
<li>The <a href="Passes.html#scalarrepl">Scalar Replacement of Aggregates</a>
pass has many improvements that allow it to better promote vector unions,
variables which are memset, and much more strange code that can happen do
to bitfield accesses to register operations. An interesting change is that
it now produces "unusual" integer sizes (like i1704) in some cases and lets
other optimizers clean things up.</li>
<li>The <a href="Passes.html#loop-reduce">Loop Strength Reduction</a> pass now
promotes small integer induction variables to 64-bit on 64-bit targets,
which provides a major performance boost many for numerical code. It also
promotes shorts to int on 32-bit hosts, etc. LSR now also analyzes pointer
expressions (e.g. getelementptrs), as well as integers.</li>
<li>The <a href="Passes.html#gvn">GVN</a> pass now eliminates partial
redundancies of loads in simple cases.</li>
<li>The <a href="Passes.html#inline">Inliner</a> now reuses stack space when
inlining similiar arrays from multiple callees into one caller.</li>
<li>LLVM includes a new experimental Static Single Information (SSI)
construction pass.</li>
</li>
</ul>
@ -559,34 +570,43 @@ it run faster:</p>
<ul>
<li> -asm-verbose now prints location info (with -g) and loop nest info.</li>
<li>The <tt>llc -asm-verbose</tt> option (exposed from llvm-gcc and clang as
<tt>-fverbose-asm</tt>) now adds a lot of useful information in comments to
the generated .s file. This information includes location information (if
built with <tt>-g</tt>) and loop nest information.</li>
<li>The code generator now supports a new MachineVerifier pass which is useful
for finding bugs in targets and ccodegen passes.</li>
<li>The Machine LICM is now enabled by default. It hoists instructions out of
loops (such as constant pool loads, loads from readonly stubs, vector
constant synthesization code, etc) and is currently configured to only do so
when the hoisted operation can be rematerialized.</li>
<li>The Machine Sinking pass is now enabled by default. This pass moves
side-effect free operations down the CFG so that they are executed on fewer
paths through a function.</li>
<li>Tblgen now supports multiclass inheritance and a number of new string and
list operations like !(subst), !(foreach), !car, !cdr, !null, !if, !cast.
These make the .td files more expressive and allow more aggressive factoring
of duplication across instruction patterns.</li>
<li>New MachineVerifier pass.</li>
<li>Machine LICM, hoists things like constant pool loads, loads from readonly stubs, vector constant synthesization code, etc.</li>
<li>Machine Sinking</li>
<li>target-specific intrinsics (r63765)</li>
<li>Target-specific intrinsics can now be added without having to hack VMCore to
add them. This makes it easier to maintain out-of-tree targets.</li>
<li>Regalloc improvements for commuting, various spiller peephole optimizations, cross-class coalescing.</li>
<li><tt>llc -enable-value-prop</tt>, propagation of value info (sign/zero ext info) from one MBB to another</li>
<li>Regalloc hints for allocation stuff: Evan r73381/r73671. Finished/enabled?</li>
<li>Stack slot coloring for register spills (denser stack frames)</li>
<li>SelectionDAGS: New BuildVectorSDNode (r65296), and ISD::VECTOR_SHUFFLE (r69952 / PR2957)</li>
<li>Experimental support for shrink wrapping support in PEI.</li>
<li>Experimental support for writing ELF .o files directly from the compiler,
it works well for many simple C testcases, but doesn't support exception
handling, debug info, inline assembly, etc.</li>
<li>The Prolog/Epilog Insertion Pass now has experimental support for performing
the "shrink wrapping" optimization, which moves spills and reloads around in
the CFG to avoid doing saves on paths that don't need them.</li>
<li>LLVM includes new experimental support for writing ELF .o files directly
from the compiler. It works well for many simple C testcases, but doesn't
support exception handling, debug info, inline assembly, etc.</li>
<li>Targets can now specify register allocation hints through
MachineRegisterInfo:: setRegAllocationHint. A regalloc hint consists 1) hint
type, 2) physical register number. A hint type of zero specifies a register
allocation preference. Other hint type values are target specific which are
resolved by TargetRegisterInfo::ResolveRegAllocHint. An example of which is
the ARM target can uses register hint to request that the register allocator
provide an even / odd register pair to two virtual registers. It is
important to note the register allocation hints are just hints. There is no
guarantee the register allocators will be able to satisfy the hints.</li>
MachineRegisterInfo:: setRegAllocationHint. A regalloc hint consists of hint
type and physical register number. A hint type of zero specifies a register
allocation preference. Other hint type values are target specific which are
resolved by TargetRegisterInfo::ResolveRegAllocHint. An example of which is
the ARM target can uses register hint to request that the register allocator
provide an even / odd register pair to two virtual registers.</li>
</ul>
</div>