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README.txt

      1 rt "mterp" README
      2 
      3 NOTE: Find rebuilding instructions at the bottom of this file.
      4 
      5 
      6 ==== Overview ====
      7 
      8 Every configuration has a "config-*" file that controls how the sources
      9 are generated.  The sources are written into the "out" directory, where
     10 they are picked up by the Android build system.
     11 
     12 The best way to become familiar with the interpreter is to look at the
     13 generated files in the "out" directory.
     14 
     15 
     16 ==== Config file format ====
     17 
     18 The config files are parsed from top to bottom.  Each line in the file
     19 may be blank, hold a comment (line starts with '#'), or be a command.
     20 
     21 The commands are:
     22 
     23   handler-style <computed-goto|jump-table>
     24 
     25     Specify which style of interpreter to generate.  In computed-goto,
     26     each handler is allocated a fixed region, allowing transitions to
     27     be done via table-start-address + (opcode * handler-size). With
     28     jump-table style, handlers may be of any length, and the generated
     29     table is an array of pointers to the handlers.  This command is required,
     30     and must be the first command in the config file.
     31 
     32   handler-size <bytes>
     33 
     34     Specify the size of the fixed region, in bytes.  On most platforms
     35     this will need to be a power of 2.  For jump-table implementations,
     36     this command is ignored.
     37 
     38   import <filename>
     39 
     40     The specified file is included immediately, in its entirety.  No
     41     substitutions are performed.  ".cpp" and ".h" files are copied to the
     42     C output, ".S" files are copied to the asm output.
     43 
     44   asm-alt-stub <filename>
     45 
     46     When present, this command will cause the generation of an alternate
     47     set of entry points (for computed-goto interpreters) or an alternate
     48     jump table (for jump-table interpreters).
     49 
     50   fallback-stub <filename>
     51 
     52     Specifies a file to be used for the special FALLBACK tag on the "op"
     53     command below.  Intended to be used to transfer control to an alternate
     54     interpreter to single-step a not-yet-implemented opcode.  Note: should
     55     note be used on RETURN-class instructions.
     56 
     57   op-start <directory>
     58 
     59     Indicates the start of the opcode list.  Must precede any "op"
     60     commands.  The specified directory is the default location to pull
     61     instruction files from.
     62 
     63   op <opcode> <directory>|FALLBACK
     64 
     65     Can only appear after "op-start" and before "op-end".  Overrides the
     66     default source file location of the specified opcode.  The opcode
     67     definition will come from the specified file, e.g. "op OP_NOP arm"
     68     will load from "arm/OP_NOP.S".  A substitution dictionary will be
     69     applied (see below).  If the special "FALLBACK" token is used instead of
     70     a directory name, the source file specified in fallback-stub will instead
     71     be used for this opcode.
     72 
     73   alt <opcode> <directory>
     74 
     75     Can only appear after "op-start" and before "op-end".  Similar to the
     76     "op" command above, but denotes a source file to override the entry
     77     in the alternate handler table.  The opcode definition will come from
     78     the specified file, e.g. "alt OP_NOP arm" will load from
     79     "arm/ALT_OP_NOP.S".  A substitution dictionary will be applied
     80     (see below).
     81 
     82   op-end
     83 
     84     Indicates the end of the opcode list.  All kNumPackedOpcodes
     85     opcodes are emitted when this is seen, followed by any code that
     86     didn't fit inside the fixed-size instruction handler space.
     87 
     88 The order of "op" and "alt" directives are not significant; the generation
     89 tool will extract ordering info from the VM sources.
     90 
     91 Typically the form in which most opcodes currently exist is used in
     92 the "op-start" directive.
     93 
     94 ==== Instruction file format ====
     95 
     96 The assembly instruction files are simply fragments of assembly sources.
     97 The starting label will be provided by the generation tool, as will
     98 declarations for the segment type and alignment.  The expected target
     99 assembler is GNU "as", but others will work (may require fiddling with
    100 some of the pseudo-ops emitted by the generation tool).
    101 
    102 A substitution dictionary is applied to all opcode fragments as they are
    103 appended to the output.  Substitutions can look like "$value" or "${value}".
    104 
    105 The dictionary always includes:
    106 
    107   $opcode - opcode name, e.g. "OP_NOP"
    108   $opnum - opcode number, e.g. 0 for OP_NOP
    109   $handler_size_bytes - max size of an instruction handler, in bytes
    110   $handler_size_bits - max size of an instruction handler, log 2
    111 
    112 Both C and assembly sources will be passed through the C pre-processor,
    113 so you can take advantage of C-style comments and preprocessor directives
    114 like "#define".
    115 
    116 Some generator operations are available.
    117 
    118   %include "filename" [subst-dict]
    119 
    120     Includes the file, which should look like "arm/OP_NOP.S".  You can
    121     specify values for the substitution dictionary, using standard Python
    122     syntax.  For example, this:
    123       %include "arm/unop.S" {"result":"r1"}
    124     would insert "arm/unop.S" at the current file position, replacing
    125     occurrences of "$result" with "r1".
    126 
    127   %default <subst-dict>
    128 
    129     Specify default substitution dictionary values, using standard Python
    130     syntax.  Useful if you want to have a "base" version and variants.
    131 
    132   %break
    133 
    134     Identifies the split between the main portion of the instruction
    135     handler (which must fit in "handler-size" bytes) and the "sister"
    136     code, which is appended to the end of the instruction handler block.
    137     In jump table implementations, %break is ignored.
    138 
    139 The generation tool does *not* print a warning if your instructions
    140 exceed "handler-size", but the VM will abort on startup if it detects an
    141 oversized handler.  On architectures with fixed-width instructions this
    142 is easy to work with, on others this you will need to count bytes.
    143 
    144 
    145 ==== Using C constants from assembly sources ====
    146 
    147 The file "art/runtime/asm_support.h" has some definitions for constant
    148 values, structure sizes, and struct member offsets.  The format is fairly
    149 restricted, as simple macros are used to massage it for use with both C
    150 (where it is verified) and assembly (where the definitions are used).
    151 
    152 If a constant in the file becomes out of sync, the VM will log an error
    153 message and abort during startup.
    154 
    155 
    156 ==== Development tips ====
    157 
    158 If you need to debug the initial piece of an opcode handler, and your
    159 debug code expands it beyond the handler size limit, you can insert a
    160 generic header at the top:
    161 
    162     b       ${opcode}_start
    163 %break
    164 ${opcode}_start:
    165 
    166 If you already have a %break, it's okay to leave it in place -- the second
    167 %break is ignored.
    168 
    169 
    170 ==== Rebuilding ====
    171 
    172 If you change any of the source file fragments, you need to rebuild the
    173 combined source files in the "out" directory.  Make sure the files in
    174 "out" are editable, then:
    175 
    176     $ cd mterp
    177     $ ./rebuild.sh
    178 
    179 The ultimate goal is to have the build system generate the necessary
    180 output files without requiring this separate step, but we're not yet
    181 ready to require Python in the build.
    182 
    183 ==== Interpreter Control ====
    184 
    185 The mterp fast interpreter achieves much of its performance advantage
    186 over the C++ interpreter through its efficient mechanism of
    187 transitioning from one Dalvik bytecode to the next.  Mterp for ARM targets
    188 uses a computed-goto mechanism, in which the handler entrypoints are
    189 located at the base of the handler table + (opcode * 128).
    190 
    191 In normal operation, the dedicated register rIBASE
    192 (r8 for ARM, edx for x86) holds a mainHandlerTable.  If we need to switch
    193 to a mode that requires inter-instruction checking, rIBASE is changed
    194 to altHandlerTable.  Note that this change is not immediate.  What is actually
    195 changed is the value of curHandlerTable - which is part of the interpBreak
    196 structure.  Rather than explicitly check for changes, each thread will
    197 blindly refresh rIBASE at backward branches, exception throws and returns.
    198