README.rst - platform/frameworks/compile/libbcc - Gitiles

 ===============================================================
 libbcc: A Versatile Bitcode Execution Engine for Mobile Devices
 ===============================================================


 Introduction
 ------------

 libbcc is an LLVM bitcode execution engine that compiles the bitcode
 to an in-memory executable. libbcc is versatile because:

 * it implements both AOT (Ahead-of-Time) and JIT (Just-in-Time)
   compilation.

 * Android devices demand fast start-up time, small size, and high
   performance *at the same time*. libbcc attempts to address these
   design constraints.

 * it supports on-device linking. Each device vendor can supply his or
   her own runtime bitcode library (lib*.bc) that differentiates his or
   her system. Specialization becomes ecosystem-friendly.

 libbcc provides:

 * a *just-in-time bitcode compiler*, which translates the LLVM bitcode
   into machine code

 * a *caching mechanism*, which can:

   * after each compilation, serialize the in-memory executable into a
     cache file.  Note that the compilation is triggered by a cache
     miss.
   * load from the cache file upon cache-hit.

 Highlights of libbcc are:

 * libbcc supports bitcode from various language frontends, such as
   Renderscript, GLSL (pixelflinger2).

 * libbcc strives to balance between library size, launch time and
   steady-state performance:

   * The size of libbcc is aggressively reduced for mobile devices. We
     customize and improve upon the default Execution Engine from
     upstream. Otherwise, libbcc's execution engine can easily become
     at least 2 times bigger.

   * To reduce launch time, we support caching of
     binaries. Just-in-Time compilation are oftentimes Just-too-Late,
     if the given apps are performance-sensitive. Thus, we implemented
     AOT to get the best of both worlds: Fast launch time and high
     steady-state performance.

     AOT is also important for projects such as NDK on LLVM with
     portability enhancement. Launch time reduction after we
     implemented AOT is signficant::


      Apps          libbcc without AOT       libbcc with AOT
                    launch time in libbcc    launch time in libbcc
      App_1            1218ms                   9ms
      App_2            842ms                    4ms
      Wallpaper:
        MagicSmoke     182ms                    3ms
        Halo           127ms                    3ms
      Balls            149ms                    3ms
      SceneGraph       146ms                    90ms
      Model            104ms                    4ms
      Fountain         57ms                     3ms

     AOT also masks the launching time overhead of on-device linking
     and helps it become reality.

   * For steady-state performance, we enable VFP3 and aggressive
     optimizations.

 * Currently we disable Lazy JITting.


 API
 ---

 **Basic:**

 * **bccCreateScript** - Create new bcc script

 * **bccRegisterSymbolCallback** - Register the callback function for external
   symbol lookup

 * **bccReadBC** - Set the source bitcode for compilation

 * **bccReadModule** - Set the llvm::Module for compilation

 * **bccLinkBC** - Set the library bitcode for linking

 * **bccPrepareExecutable** - *deprecated* - Use bccPrepareExecutableEx instead

 * **bccPrepareExecutableEx** - Create the in-memory executable by either
   just-in-time compilation or cache loading

 * **bccGetFuncAddr** - Get the entry address of the function

 * **bccDisposeScript** - Destroy bcc script and release the resources

 * **bccGetError** - *deprecated* - Don't use this


 **Reflection:**

 * **bccGetExportVarCount** - Get the count of exported variables

 * **bccGetExportVarList** - Get the addresses of exported variables

 * **bccGetExportFuncCount** - Get the count of exported functions

 * **bccGetExportFuncList** - Get the addresses of exported functions

 * **bccGetPragmaCount** - Get the count of pragmas

 * **bccGetPragmaList** - Get the pragmas


 **Debug:**

 * **bccGetFuncCount** - Get the count of functions (including non-exported)

 * **bccGetFuncInfoList** - Get the function information (name, base, size)


 Cache File Format
 -----------------

 A cache file (denoted as \*.oBCC) for libbcc consists of several sections:
 header, string pool, dependencies table, relocation table, exported
 variable list, exported function list, pragma list, function information
 table, and bcc context.  Every section should be aligned to a word size.
 Here is the brief description of each sections:

 * **Header** (MCO_Header) - The header of a cache file. It contains the
   magic word, version, machine integer type information (the endianness,
   the size of off_t, size_t, and ptr_t), and the size
   and offset of other sections.  The header section is guaranteed
   to be at the beginning of the cache file.

 * **String Pool** (MCO_StringPool) - A collection of serialized variable
   length strings.  The strp_index in the other part of the cache file
   represents the index of such string in this string pool.

 * **Dependencies Table** (MCO_DependencyTable) - The dependencies table.
   This table stores the resource name (or file path), the resource
   type (rather in APK or on the file system), and the SHA1 checksum.

 * **Relocation Table** (MCO_RelocationTable) - *not enabled*

 * **Exported Variable List** (MCO_ExportVarList) -
   The list of the addresses of exported variables.

 * **Exported Function List** (MCO_ExportFuncList) -
   The list of the addresses of exported functions.

 * **Pragma List** (MCO_PragmaList) - The list of pragma key-value pair.

 * **Function Information Table** (MCO_FuncTable) - This is a table of
   function information, such as function name, function entry address,
   and function binary size.  Besides, the table should be ordered by
   function name.

 * **Context** - The context of the in-memory executable, including
   the code and the data.  The offset of context should aligned to
   a page size, so that we can mmap the context directly into memory.

 For furthur information, you may read `bcc_cache.h <include/bcc/bcc_cache.h>`_,
 `CacheReader.cpp <lib/bcc/CacheReader.cpp>`_, and
 `CacheWriter.cpp <lib/bcc/CacheWriter.cpp>`_ for details.


 JIT'ed Code Calling Conventions
 -------------------------------

 1. Calls from Execution Environment or from/to within script:

    On ARM, the first 4 arguments will go into r0, r1, r2, and r3, in that order.
    The remaining (if any) will go through stack.

    For ext_vec_types such as float2, a set of registers will be used. In the case
    of float2, a register pair will be used. Specifically, if float2 is the first
    argument in the function prototype, float2.x will go into r0, and float2.y,
    r1.

    Note: stack will be aligned to the coarsest-grained argument. In the case of
    float2 above as an argument, parameter stack will be aligned to an 8-byte
    boundary (if the sizes of other arguments are no greater than 8.)

 2. Calls from/to a separate compilation unit: (E.g., calls to Execution
    Environment if those runtime library callees are not compiled using LLVM.)

    On ARM, we use hardfp.  Note that double will be placed in a register pair.
	===============================================================
	libbcc: A Versatile Bitcode Execution Engine for Mobile Devices
	===============================================================


	Introduction
	------------

	libbcc is an LLVM bitcode execution engine that compiles the bitcode
	to an in-memory executable. libbcc is versatile because:

	* it implements both AOT (Ahead-of-Time) and JIT (Just-in-Time)
	compilation.

	* Android devices demand fast start-up time, small size, and high
	performance at the same time. libbcc attempts to address these
	design constraints.

	* it supports on-device linking. Each device vendor can supply his or
	her own runtime bitcode library (lib*.bc) that differentiates his or
	her system. Specialization becomes ecosystem-friendly.

	libbcc provides:

	* a just-in-time bitcode compiler, which translates the LLVM bitcode
	into machine code

	* a caching mechanism, which can:

	* after each compilation, serialize the in-memory executable into a
	cache file. Note that the compilation is triggered by a cache
	miss.
	* load from the cache file upon cache-hit.

	Highlights of libbcc are:

	* libbcc supports bitcode from various language frontends, such as
	Renderscript, GLSL (pixelflinger2).

	* libbcc strives to balance between library size, launch time and
	steady-state performance:

	* The size of libbcc is aggressively reduced for mobile devices. We
	customize and improve upon the default Execution Engine from
	upstream. Otherwise, libbcc's execution engine can easily become
	at least 2 times bigger.

	* To reduce launch time, we support caching of
	binaries. Just-in-Time compilation are oftentimes Just-too-Late,
	if the given apps are performance-sensitive. Thus, we implemented
	AOT to get the best of both worlds: Fast launch time and high
	steady-state performance.

	AOT is also important for projects such as NDK on LLVM with
	portability enhancement. Launch time reduction after we
	implemented AOT is signficant::


	Apps libbcc without AOT libbcc with AOT
	launch time in libbcc launch time in libbcc
	App_1 1218ms 9ms
	App_2 842ms 4ms
	Wallpaper:
	MagicSmoke 182ms 3ms
	Halo 127ms 3ms
	Balls 149ms 3ms
	SceneGraph 146ms 90ms
	Model 104ms 4ms
	Fountain 57ms 3ms

	AOT also masks the launching time overhead of on-device linking
	and helps it become reality.

	* For steady-state performance, we enable VFP3 and aggressive
	optimizations.

	* Currently we disable Lazy JITting.



	API
	---

	Basic:

	* bccCreateScript - Create new bcc script

	* bccRegisterSymbolCallback - Register the callback function for external
	symbol lookup

	* bccReadBC - Set the source bitcode for compilation

	* bccReadModule - Set the llvm::Module for compilation

	* bccLinkBC - Set the library bitcode for linking

	* bccPrepareExecutable - deprecated - Use bccPrepareExecutableEx instead

	* bccPrepareExecutableEx - Create the in-memory executable by either
	just-in-time compilation or cache loading

	* bccGetFuncAddr - Get the entry address of the function

	* bccDisposeScript - Destroy bcc script and release the resources

	* bccGetError - deprecated - Don't use this


	Reflection:

	* bccGetExportVarCount - Get the count of exported variables

	* bccGetExportVarList - Get the addresses of exported variables

	* bccGetExportFuncCount - Get the count of exported functions

	* bccGetExportFuncList - Get the addresses of exported functions

	* bccGetPragmaCount - Get the count of pragmas

	* bccGetPragmaList - Get the pragmas


	Debug:

	* bccGetFuncCount - Get the count of functions (including non-exported)

	* bccGetFuncInfoList - Get the function information (name, base, size)



	Cache File Format
	-----------------

	A cache file (denoted as \*.oBCC) for libbcc consists of several sections:
	header, string pool, dependencies table, relocation table, exported
	variable list, exported function list, pragma list, function information
	table, and bcc context. Every section should be aligned to a word size.
	Here is the brief description of each sections:

	* Header (MCO_Header) - The header of a cache file. It contains the
	magic word, version, machine integer type information (the endianness,
	the size of off_t, size_t, and ptr_t), and the size
	and offset of other sections. The header section is guaranteed
	to be at the beginning of the cache file.

	* String Pool (MCO_StringPool) - A collection of serialized variable
	length strings. The strp_index in the other part of the cache file
	represents the index of such string in this string pool.

	* Dependencies Table (MCO_DependencyTable) - The dependencies table.
	This table stores the resource name (or file path), the resource
	type (rather in APK or on the file system), and the SHA1 checksum.

	* Relocation Table (MCO_RelocationTable) - not enabled

	* Exported Variable List (MCO_ExportVarList) -
	The list of the addresses of exported variables.

	* Exported Function List (MCO_ExportFuncList) -
	The list of the addresses of exported functions.

	* Pragma List (MCO_PragmaList) - The list of pragma key-value pair.

	* Function Information Table (MCO_FuncTable) - This is a table of
	function information, such as function name, function entry address,
	and function binary size. Besides, the table should be ordered by
	function name.

	* Context - The context of the in-memory executable, including
	the code and the data. The offset of context should aligned to
	a page size, so that we can mmap the context directly into memory.

	For furthur information, you may read `bcc_cache.h <include/bcc/bcc_cache.h>`_,
	`CacheReader.cpp <lib/bcc/CacheReader.cpp>`_, and
	`CacheWriter.cpp <lib/bcc/CacheWriter.cpp>`_ for details.



	JIT'ed Code Calling Conventions
	-------------------------------

	1. Calls from Execution Environment or from/to within script:

	On ARM, the first 4 arguments will go into r0, r1, r2, and r3, in that order.
	The remaining (if any) will go through stack.

	For ext_vec_types such as float2, a set of registers will be used. In the case
	of float2, a register pair will be used. Specifically, if float2 is the first
	argument in the function prototype, float2.x will go into r0, and float2.y,
	r1.

	Note: stack will be aligned to the coarsest-grained argument. In the case of
	float2 above as an argument, parameter stack will be aligned to an 8-byte
	boundary (if the sizes of other arguments are no greater than 8.)

	2. Calls from/to a separate compilation unit: (E.g., calls to Execution
	Environment if those runtime library callees are not compiled using LLVM.)

	On ARM, we use hardfp. Note that double will be placed in a register pair.