-.. raw:: html
-
- <style> .red {color:red} </style>
-
-.. role:: red
-
======================
-LLVM 3.2 Release Notes
+LLVM 3.8 Release Notes
======================
.. contents::
:local:
-Written by the `LLVM Team <http://llvm.org/>`_
+.. warning::
+ These are in-progress notes for the upcoming LLVM 3.8 release. You may
+ prefer the `LLVM 3.7 Release Notes <http://llvm.org/releases/3.7.0/docs
+ /ReleaseNotes.html>`_.
-:red:`These are in-progress notes for the upcoming LLVM 3.2 release. You may
-prefer the` `LLVM 3.1 Release Notes <http://llvm.org/releases/3.1/docs
-/ReleaseNotes.html>`_.
Introduction
============
This document contains the release notes for the LLVM Compiler Infrastructure,
-release 3.2. Here we describe the status of LLVM, including major improvements
+release 3.8. Here we describe the status of LLVM, including major improvements
from the previous release, improvements in various subprojects of LLVM, and
some of the current users of the code. All LLVM releases may be downloaded
from the `LLVM releases web site <http://llvm.org/releases/>`_.
For more information about LLVM, including information about the latest
release, please check out the `main LLVM web site <http://llvm.org/>`_. If you
have questions or comments, the `LLVM Developer's Mailing List
-<http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev>`_ is a good place to send
+<http://lists.llvm.org/mailman/listinfo/llvm-dev>`_ is a good place to send
them.
Note that if you are reading this file from a Subversion checkout or the main
one. To see the release notes for a specific release, please see the `releases
page <http://llvm.org/releases/>`_.
-Sub-project Status Update
-=========================
-
-The LLVM 3.2 distribution currently consists of code from the core LLVM
-repository, which roughly includes the LLVM optimizers, code generators and
-supporting tools, and the Clang repository. In addition to this code, the LLVM
-Project includes other sub-projects that are in development. Here we include
-updates on these subprojects.
-
-Clang: C/C++/Objective-C Frontend Toolkit
------------------------------------------
-
-`Clang <http://clang.llvm.org/>`_ is an LLVM front end for the C, C++, and
-Objective-C languages. Clang aims to provide a better user experience through
-expressive diagnostics, a high level of conformance to language standards, fast
-compilation, and low memory use. Like LLVM, Clang provides a 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, Objective-C, C++ and Objective-C++ on x86 (32- and 64-bit), and
-for Darwin/ARM targets.
-
-In the LLVM 3.2 time-frame, the Clang team has made many improvements.
-Highlights include:
-
-#. ...
-
-For more details about the changes to Clang since the 3.1 release, see the
-`Clang release notes. <http://clang.llvm.org/docs/ReleaseNotes.html>`_
-
-If Clang rejects your code but another compiler accepts it, please take a look
-at the `language compatibility <http://clang.llvm.org/compatibility.html>`_
-guide to make sure this is not intentional or a known issue.
-
-DragonEgg: GCC front-ends, LLVM back-end
-----------------------------------------
-
-`DragonEgg <http://dragonegg.llvm.org/>`_ is a `gcc plugin
-<http://gcc.gnu.org/wiki/plugins>`_ that replaces GCC's optimizers and code
-generators with LLVM's. It works with gcc-4.5 and gcc-4.6 (and partially with
-gcc-4.7), can target the x86-32/x86-64 and ARM processor families, and has been
-successfully used on the Darwin, FreeBSD, KFreeBSD, Linux and OpenBSD
-platforms. It fully supports Ada, C, C++ and Fortran. It has partial support
-for Go, Java, Obj-C and Obj-C++.
-
-The 3.2 release has the following notable changes:
-
-#. ...
-
-compiler-rt: Compiler Runtime Library
--------------------------------------
-
-The new LLVM `compiler-rt project <http://compiler-rt.llvm.org/>`_ is a simple
-library that provides an implementation of the low-level target-specific hooks
-required by code generation and other runtime components. For example, when
-compiling for a 32-bit target, converting a double to a 64-bit unsigned integer
-is compiled into a runtime call to the ``__fixunsdfdi`` function. The
-``compiler-rt`` library provides highly optimized implementations of this and
-other low-level routines (some are 3x faster than the equivalent libgcc
-routines).
-
-The 3.2 release has the following notable changes:
-
-#. ...
-
-LLDB: Low Level Debugger
-------------------------
-
-`LLDB <http://lldb.llvm.org>`_ is a ground-up implementation of a command line
-debugger, as well as a debugger API that can be used from other applications.
-LLDB makes use of the Clang parser to provide high-fidelity expression parsing
-(particularly for C++) and uses the LLVM JIT for target support.
-
-The 3.2 release has the following notable changes:
-
-#. ...
-
-libc++: C++ Standard Library
-----------------------------
+Non-comprehensive list of changes in this release
+=================================================
+* With this release, the minimum Windows version required for running LLVM is
+ Windows 7. Earlier versions, including Windows Vista and XP are no longer
+ supported.
-Like compiler_rt, libc++ is now :ref:`dual licensed
-<copyright-license-patents>` under the MIT and UIUC license, allowing it to be
-used more permissively.
+* With this release, the autoconf build system is deprecated. It will be removed
+ in the 3.9 release. Please migrate to using CMake. For more information see:
+ `Building LLVM with CMake <CMake.html>`_
-Within the LLVM 3.2 time-frame there were the following highlights:
+* The C API function LLVMLinkModules is deprecated. It will be removed in the
+ 3.9 release. Please migrate to LLVMLinkModules2. Unlike the old function the
+ new one
-#. ...
-
-VMKit
------
-
-The `VMKit project <http://vmkit.llvm.org/>`_ is an implementation of a Java
-Virtual Machine (Java VM or JVM) that uses LLVM for static and just-in-time
-compilation.
-
-The 3.2 release has the following notable changes:
-
-#. ...
-
-Polly: Polyhedral Optimizer
----------------------------
-
-`Polly <http://polly.llvm.org/>`_ is an *experimental* optimizer for data
-locality and parallelism. It provides high-level loop optimizations and
-automatic parallelisation.
-
-Within the LLVM 3.2 time-frame there were the following highlights:
-
-#. isl, the integer set library used by Polly, was relicensed to the MIT license
-#. isl based code generation
-#. MIT licensed replacement for CLooG (LGPLv2)
-#. Fine grained option handling (separation of core and border computations,
- control overhead vs. code size)
-#. Support for FORTRAN and dragonegg
-#. OpenMP code generation fixes
-
-External Open Source Projects Using LLVM 3.2
-============================================
-
-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 3.2.
-
-Crack
------
-
-`Crack <http://code.google.com/p/crack-language/>`_ aims to provide the ease of
-development of a scripting language with the performance of a compiled
-language. The language derives concepts from C++, Java and Python,
-incorporating object-oriented programming, operator overloading and strong
-typing.
-
-FAUST
------
-
-`FAUST <http://faust.grame.fr/>`_ is a compiled language for real-time audio
-signal processing. The name FAUST stands for Functional AUdio STream. Its
-programming model combines two approaches: functional programming and block
-diagram composition. In addition with the C, C++, Java, JavaScript output
-formats, the Faust compiler can generate LLVM bitcode, and works with LLVM
-2.7-3.1.
-
-Glasgow Haskell Compiler (GHC)
-------------------------------
-
-`GHC <http://www.haskell.org/ghc/>`_ is an open source compiler and programming
-suite for Haskell, a 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.
-
-GHC 7.0 and onwards include an LLVM code generator, supporting LLVM 2.8 and
-later.
-
-Julia
------
-
-`Julia <https://github.com/JuliaLang/julia>`_ is a high-level, high-performance
-dynamic language for technical computing. It provides a sophisticated
-compiler, distributed parallel execution, numerical accuracy, and an extensive
-mathematical function library. The compiler uses type inference to generate
-fast code without any type declarations, and uses LLVM's optimization passes
-and JIT compiler. The `Julia Language <http://julialang.org/>`_ is designed
-around multiple dispatch, giving programs a large degree of flexibility. It is
-ready for use on many kinds of problems.
-
-LLVM D Compiler
----------------
-
-`LLVM D Compiler <https://github.com/ldc-developers/ldc>`_ (LDC) is a compiler
-for the D programming Language. It is based on the DMD frontend and uses LLVM
-as backend.
-
-Open Shading Language
----------------------
-
-`Open Shading Language (OSL)
-<https://github.com/imageworks/OpenShadingLanguage/>`_ is a small but rich
-language for programmable shading in advanced global illumination renderers and
-other applications, ideal for describing materials, lights, displacement, and
-pattern generation. It uses LLVM to JIT complex shader networks to x86 code at
-runtime.
-
-OSL was developed by Sony Pictures Imageworks for use in its in-house renderer
-used for feature film animation and visual effects, and is distributed as open
-source software with the "New BSD" license.
-
-Portable OpenCL (pocl)
-----------------------
-
-In addition to producing an easily portable open source OpenCL implementation,
-another major goal of `pocl <http://pocl.sourceforge.net/>`_ is improving
-performance portability of OpenCL programs with compiler optimizations,
-reducing the need for target-dependent manual optimizations. An important part
-of pocl is a set of LLVM passes used to statically parallelize multiple
-work-items with the kernel compiler, even in the presence of work-group
-barriers. This enables static parallelization of the fine-grained static
-concurrency in the work groups in multiple ways (SIMD, VLIW, superscalar, ...).
-
-Pure
-----
-
-`Pure <http://pure-lang.googlecode.com/>`_ 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. The
-interpreter uses LLVM as a backend to JIT-compile Pure programs to fast native
-code. 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
-interface to C and other programming languages (including the ability to load
-LLVM bitcode modules, and inline C, C++, Fortran and Faust code in Pure
-programs if the corresponding LLVM-enabled compilers are installed).
-
-Pure version 0.54 has been tested and is known to work with LLVM 3.1 (and
-continues to work with older LLVM releases >= 2.5).
-
-TTA-based Co-design Environment (TCE)
--------------------------------------
-
-`TCE <http://tce.cs.tut.fi/>`_ 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/Verilog and parallel program binaries. Processor
-customization points include the register files, function units, supported
-operations, and the interconnection network.
-
-TCE uses 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.
-
-Installation Instructions
-=========================
-
-See :doc:`GettingStarted`.
-
-What's New in LLVM 3.2?
-=======================
-
-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.
-
-Major New Features
-------------------
-
-..
-
- Features that need text if they're finished for 3.2:
- ARM EHABI
- combiner-aa?
- strong phi elim
- loop dependence analysis
- CorrelatedValuePropagation
- lib/Transforms/IPO/MergeFunctions.cpp => consider for 3.2.
- Integrated assembler on by default for arm/thumb?
-
- Near dead:
- Analysis/RegionInfo.h + Dom Frontiers
- SparseBitVector: used in LiveVar.
- llvm/lib/Archive - replace with lib object?
-
-
-LLVM 3.2 includes several major changes and big features:
-
-#. New NVPTX back-end (replacing existing PTX back-end) based on NVIDIA sources
-#. ...
-
-LLVM IR and Core Improvements
+ * Doesn't take an unused parameter.
+ * Destroys the source instead of only damaging it.
+ * Does not record a message. Use the diagnostic handler instead.
+
+* The C API functions LLVMParseBitcode, LLVMParseBitcodeInContext,
+ LLVMGetBitcodeModuleInContext and LLVMGetBitcodeModule have been deprecated.
+ They will be removed in 3.9. Please migrate to the versions with a 2 suffix.
+ Unlike the old ones the new ones do not record a diagnostic message. Use
+ the diagnostic handler instead.
+
+* The deprecated C APIs LLVMGetBitcodeModuleProviderInContext and
+ LLVMGetBitcodeModuleProvider have been removed.
+
+* The deprecated C APIs LLVMCreateExecutionEngine, LLVMCreateInterpreter,
+ LLVMCreateJITCompiler, LLVMAddModuleProvider and LLVMRemoveModuleProvider
+ have been removed.
+
+* With this release, the C API headers have been reorganized to improve build
+ time. Type specific declarations have been moved to Type.h, and error
+ handling routines have been moved to ErrorHandling.h. Both are included in
+ Core.h so nothing should change for projects directly including the headers,
+ but transitive dependencies may be affected.
+
+* llvm-ar now suports thin archives.
+
+* llvm doesn't produce .data.rel.ro.local or .data.rel sections anymore.
+
+* aliases to available_externally globals are now rejected by the verifier.
+
+* the IR Linker has been split into IRMover that moves bits from one module to
+ another and Linker proper that decides what to link.
+
+* Support for dematerializing has been dropped.
+
+.. NOTE
+ For small 1-3 sentence descriptions, just add an entry at the end of
+ this list. If your description won't fit comfortably in one bullet
+ point (e.g. maybe you would like to give an example of the
+ functionality, or simply have a lot to talk about), see the `NOTE` below
+ for adding a new subsection.
+
+* ... next change ...
+
+.. NOTE
+ If you would like to document a larger change, then you can add a
+ subsection about it right here. You can copy the following boilerplate
+ and un-indent it (the indentation causes it to be inside this comment).
+
+ Special New Feature
+ -------------------
+
+ Makes programs 10x faster by doing Special New Thing.
+
+Changes to the ARM Backend
+--------------------------
+
+ During this release ...
+
+
+Changes to the MIPS Target
+--------------------------
+
+During this release the MIPS target has:
+
+* Significantly extended support for the Integrated Assembler. See below for
+ more information
+* Added support for the ``P5600`` processor.
+* Added support for the ``interrupt`` attribute for MIPS32R2 and later. This
+ attribute will generate a function which can be used as a interrupt handler
+ on bare metal MIPS targets using the static relocation model.
+* Added support for the ``ERETNC`` instruction found in MIPS32R5 and later.
+* Added support for OpenCL. See http://portablecl.org/.
+
+ * Address spaces 1 to 255 are now reserved for software use and conversions
+ between them are no-op casts.
+
+* Removed the ``mips16`` value for the -mcpu option since it is an :abbr:`ASE
+ (Application Specific Extension)` and not a processor. If you were using this,
+ please specify another CPU and use ``-mips16`` to enable MIPS16.
+* Removed ``copy_u.w`` from 32-bit MSA and ``copy_u.d`` from 64-bit MSA since
+ they have been removed from the MSA specification due to forward compatibility
+ issues. For example, 32-bit MSA code containing ``copy_u.w`` would behave
+ differently on a 64-bit processor supporting MSA. The corresponding intrinsics
+ are still available and may expand to ``copy_s.[wd]`` where this is
+ appropriate for forward compatibility purposes.
+* Relaxed the ``-mnan`` option to allow ``-mnan=2008`` on MIPS32R2/MIPS64R2 for
+ compatibility with GCC.
+* Made MIPS64R6 the default CPU for 64-bit Android triples.
+
+The MIPS target has also fixed various bugs including the following notable
+fixes:
+
+* Fixed reversed operands on ``mthi``/``mtlo`` in the DSP :abbr:`ASE
+ (Application Specific Extension)`.
+* The code generator no longer uses ``jal`` for calls to absolute immediate
+ addresses.
+* Disabled fast instruction selection on MIPS32R6 and MIPS64R6 since this is not
+ yet supported.
+* Corrected addend for ``R_MIPS_HI16`` and ``R_MIPS_PCHI16`` in MCJIT
+* The code generator no longer crashes when handling subregisters of an 64-bit
+ FPU register with undefined value.
+* The code generator no longer attempts to use ``$zero`` for operands that do
+ not permit ``$zero``.
+* Corrected the opcode used for ``ll``/``sc`` when using MIPS32R6/MIPS64R6 and
+ the Integrated Assembler.
+* Added support for atomic load and atomic store.
+* Corrected debug info when dynamically re-aligning the stack.
+
+Integrated Assembler
+^^^^^^^^^^^^^^^^^^^^
+We have made a large number of improvements to the integrated assembler for
+MIPS. In this release, the integrated assembler isn't quite production-ready
+since there are a few known issues related to bare-metal support, checking
+immediates on instructions, and the N32/N64 ABI's. However, the current support
+should be sufficient for many users of the O32 ABI, particularly those targeting
+MIPS32 on Linux or bare-metal MIPS32.
+
+If you would like to try the integrated assembler, please use
+``-fintegrated-as``.
+
+Changes to the PowerPC Target
-----------------------------
-LLVM IR has several new features for better support of new targets and that
-expose new optimization opportunities:
-
-#. Thread local variables may have a specified TLS model. See the :ref:`Language
- Reference Manual <globalvars>`.
-#. ...
-
-Optimizer Improvements
-----------------------
-
-In addition to many minor performance tweaks and bug fixes, this release
-includes a few major enhancements and additions to the optimizers:
-
-Loop Vectorizer - We've added a loop vectorizer and we are now able to
-vectorize small loops. The loop vectorizer is disabled by default and can be
-enabled using the ``-mllvm -vectorize-loops`` flag. The SIMD vector width can
-be specified using the flag ``-mllvm -force-vector-width=4``. The default
-value is ``0`` which means auto-select.
-
-We can now vectorize this function:
-
-.. code-block:: c++
-
- unsigned sum_arrays(int *A, int *B, int start, int end) {
- unsigned sum = 0;
- for (int i = start; i < end; ++i)
- sum += A[i] + B[i] + i;
- return sum;
- }
-
-We vectorize under the following loops:
-
-#. The inner most loops must have a single basic block.
-#. The number of iterations are known before the loop starts to execute.
-#. The loop counter needs to be incremented by one.
-#. The loop trip count **can** be a variable.
-#. Loops do **not** need to start at zero.
-#. The induction variable can be used inside the loop.
-#. Loop reductions are supported.
-#. Arrays with affine access pattern do **not** need to be marked as
- '``noalias``' and are checked at runtime.
-#. ...
-
-SROA - We've re-written SROA to be significantly more powerful.
-
-#. Branch weight metadata is preseved through more of the optimizer.
-#. ...
-
-MC Level Improvements
----------------------
+ During this release ...
-The LLVM Machine Code (aka MC) subsystem was created to solve a number of
-problems in the realm of assembly, disassembly, object file format handling,
-and a number of other related areas that CPU instruction-set level tools work
-in. For more information, please see the `Intro to the LLVM MC Project Blog
-Post <http://blog.llvm.org/2010/04/intro-to-llvm-mc-project.html>`_.
-#. ...
-
-.. _codegen:
-
-Target Independent Code Generator Improvements
-----------------------------------------------
-
-Stack Coloring - We have implemented a new optimization pass to merge stack
-objects which are used in disjoin areas of the code. This optimization reduces
-the required stack space significantly, in cases where it is clear to the
-optimizer that the stack slot is not shared. We use the lifetime markers to
-tell the codegen that a certain alloca is used within a region.
-
-We now merge consecutive loads and stores.
-
-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:
-
-#. ...
-
-We added new TableGen infrastructure to support bundling for Very Long
-Instruction Word (VLIW) architectures. TableGen can now automatically generate
-a deterministic finite automaton from a VLIW target's schedule description
-which can be queried to determine legal groupings of instructions in a bundle.
-
-We have added a new target independent VLIW packetizer based on the DFA
-infrastructure to group machine instructions into bundles.
-
-Basic Block Placement
-^^^^^^^^^^^^^^^^^^^^^
-
-A probability based block placement and code layout algorithm was added to
-LLVM's code generator. This layout pass supports probabilities derived from
-static heuristics as well as source code annotations such as
-``__builtin_expect``.
-
-X86-32 and X86-64 Target Improvements
--------------------------------------
-
-New features and major changes in the X86 target include:
-
-#. ...
-
-.. _ARM:
-
-ARM Target Improvements
------------------------
-
-New features of the ARM target include:
-
-#. ...
-
-.. _armintegratedassembler:
-
-ARM Integrated Assembler
-^^^^^^^^^^^^^^^^^^^^^^^^
-
-The ARM target now includes a full featured macro assembler, including
-direct-to-object module support for clang. The assembler is currently enabled
-by default for Darwin only pending testing and any additional necessary
-platform specific support for Linux.
-
-Full support is included for Thumb1, Thumb2 and ARM modes, along with subtarget
-and CPU specific extensions for VFP2, VFP3 and NEON.
-
-The assembler is Unified Syntax only (see ARM Architecural Reference Manual for
-details). While there is some, and growing, support for pre-unfied (divided)
-syntax, there are still significant gaps in that support.
-
-MIPS Target Improvements
-------------------------
-
-New features and major changes in the MIPS target include:
-
-#. ...
-
-PowerPC Target Improvements
----------------------------
-
-Many fixes and changes across LLVM (and Clang) for better compliance with the
-64-bit PowerPC ELF Application Binary Interface, interoperability with GCC, and
-overall 64-bit PowerPC support. Some highlights include:
-
-#. MCJIT support added.
-#. PPC64 relocation support and (small code model) TOC handling added.
-#. Parameter passing and return value fixes (alignment issues, padding, varargs
- support, proper register usage, odd-sized structure support, float support,
- extension of return values for i32 return values).
-#. Fixes in spill and reload code for vector registers.
-#. C++ exception handling enabled.
-#. Changes to remediate double-rounding compatibility issues with respect to
- GCC behavior.
-#. Refactoring to disentangle ``ppc64-elf-linux`` ABI from Darwin ppc64 ABI
- support.
-#. Assorted new test cases and test case fixes (endian and word size issues).
-#. Fixes for big-endian codegen bugs, instruction encodings, and instruction
- constraints.
-#. Implemented ``-integrated-as`` support.
-#. Additional support for Altivec compare operations.
-#. IBM long double support.
-
-There have also been code generation improvements for both 32- and 64-bit code.
-Instruction scheduling support for the Freescale e500mc and e5500 cores has
-been added.
-
-PTX/NVPTX Target Improvements
+Changes to the X86 Target
-----------------------------
-The PTX back-end has been replaced by the NVPTX back-end, which is based on the
-LLVM back-end used by NVIDIA in their CUDA (nvcc) and OpenCL compiler. Some
-highlights include:
-
-#. Compatibility with PTX 3.1 and SM 3.5.
-#. Support for NVVM intrinsics as defined in the NVIDIA Compiler SDK.
-#. Full compatibility with old PTX back-end, with much greater coverage of LLVM
- SIR.
-
-Please submit any back-end bugs to the LLVM Bugzilla site.
-
-Other Target Specific Improvements
-----------------------------------
-
-#. ...
+ During this release ...
-Major Changes and Removed Features
-----------------------------------
+* TLS is enabled for Cygwin as emutls.
-If you're already an LLVM user or developer with out-of-tree changes based on
-LLVM 3.2, this section lists some "gotchas" that you may run into upgrading
-from the previous release.
-#. The CellSPU port has been removed. It can still be found in older versions.
-#. ...
-
-Internal API Changes
---------------------
-
-In addition, many APIs have changed in this release. Some of the major LLVM
-API changes are:
-
-We've added a new interface for allowing IR-level passes to access
-target-specific information. A new IR-level pass, called
-``TargetTransformInfo`` provides a number of low-level interfaces. LSR and
-LowerInvoke already use the new interface.
-
-The ``TargetData`` structure has been renamed to ``DataLayout`` and moved to
-``VMCore`` to remove a dependency on ``Target``.
-
-#. ...
-
-Tools Changes
--------------
-
-In addition, some tools have changed in this release. Some of the changes are:
-
-#. ...
-
-Python Bindings
----------------
+Changes to the OCaml bindings
+-----------------------------
-Officially supported Python bindings have been added! Feature support is far
-from complete. The current bindings support interfaces to:
+ During this release ...
-#. ...
+* The ocaml function link_modules has been replaced with link_modules' which
+ uses LLVMLinkModules2.
-Known Problems
-==============
-LLVM is generally a production quality compiler, and is used by a broad range
-of applications and shipping in many products. That said, not every subsystem
-is as mature as the aggregate, particularly the more obscure1 targets. If you
-run into a problem, please check the `LLVM bug database
-<http://llvm.org/bugs/>`_ and submit a bug if there isn't already one or ask on
-the `LLVMdev list <http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev>`_.
+External Open Source Projects Using LLVM 3.8
+============================================
-Known problem areas include:
+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 3.8.
-#. The CellSPU, MSP430, and XCore backends are experimental.
+* A project
-#. The integrated assembler, disassembler, and JIT is not supported by several
- targets. If an integrated assembler is not supported, then a system
- assembler is required. For more details, see the
- :ref:`target-feature-matrix`.
Additional Information
======================
projects / oota-llvm.git / blobdiff