Provided by: llvm-16_16.0.6-27_amd64 bug

NAME

       llvm-mca - LLVM Machine Code Analyzer

SYNOPSIS

       llvm-mca [options] [input]

DESCRIPTION

       llvm-mca  is  a  performance  analysis  tool that uses information available in LLVM (e.g.
       scheduling models) to statically measure the performance of machine  code  in  a  specific
       CPU.

       Performance  is measured in terms of throughput as well as processor resource consumption.
       The tool currently works for processors with a backend for which  there  is  a  scheduling
       model available in LLVM.

       The  main goal of this tool is not just to predict the performance of the code when run on
       the target, but also help with diagnosing potential performance issues.

       Given an assembly code sequence, llvm-mca estimates the Instructions Per Cycle  (IPC),  as
       well  as hardware resource pressure. The analysis and reporting style were inspired by the
       IACA tool from Intel.

       For example, you can compile code with clang, output assembly, and pipe it  directly  into
       llvm-mca for analysis:

          $ clang foo.c -O2 -target x86_64-unknown-unknown -S -o - | llvm-mca -mcpu=btver2

       Or for Intel syntax:

          $ clang foo.c -O2 -target x86_64-unknown-unknown -mllvm -x86-asm-syntax=intel -S -o - | llvm-mca -mcpu=btver2

       (llvm-mca  detects  Intel  syntax  by  the  presence  of an .intel_syntax directive at the
       beginning of the input.  By default its output syntax matches that of its input.)

       Scheduling models are not just used to compute instruction latencies and  throughput,  but
       also to understand what processor resources are available and how to simulate them.

       By design, the quality of the analysis conducted by llvm-mca is inevitably affected by the
       quality of the scheduling models in LLVM.

       If you see that the performance report is not accurate for a processor, please file a  bug
       against the appropriate backend.

OPTIONS

       If  input  is  “-” or omitted, llvm-mca reads from standard input. Otherwise, it will read
       from the specified filename.

       If the -o option is omitted, then llvm-mca will send its output to standard output if  the
       input  is  from standard input.  If the -o option specifies “-”, then the output will also
       be sent to standard output.

       -help  Print a summary of command line options.

       -o <filename>
              Use <filename> as the output filename. See the summary above for more details.

       -mtriple=<target triple>
              Specify a target triple string.

       -march=<arch>
              Specify the architecture for which to analyze the code. It  defaults  to  the  host
              default target.

       -mcpu=<cpuname>
              Specify  the  processor for which to analyze the code.  By default, the cpu name is
              autodetected from the host.

       -output-asm-variant=<variant id>
              Specify the output assembly variant for the report generated by the tool.  On  x86,
              possible  values  are  [0, 1]. A value of 0 (vic. 1) for this flag enables the AT&T
              (vic. Intel) assembly format for the code printed out by the tool in  the  analysis
              report.

       -print-imm-hex
              Prefer  hex  format  for numeric literals in the output assembly printed as part of
              the report.

       -dispatch=<width>
              Specify a different dispatch width for the processor. The dispatch  width  defaults
              to  field  ‘IssueWidth’  in the processor scheduling model.  If width is zero, then
              the default dispatch width is used.

       -register-file-size=<size>
              Specify the size of the register file. When specified, this flag  limits  how  many
              physical  registers  are  available for register renaming purposes. A value of zero
              for this flag means “unlimited number of physical registers”.

       -iterations=<number of iterations>
              Specify the number of iterations to run. If this flag is set to 0,  then  the  tool
              sets the number of iterations to a default value (i.e. 100).

       -noalias=<bool>
              If  set,  the  tool  assumes that loads and stores don’t alias. This is the default
              behavior.

       -lqueue=<load queue size>
              Specify the size of the load queue in the load/store unit emulated by the tool.  By
              default,  the tool assumes an unbound number of entries in the load queue.  A value
              of zero for this flag is ignored, and the default load queue size is used instead.

       -squeue=<store queue size>
              Specify the size of the store queue in the load/store unit emulated by the tool. By
              default,  the tool assumes an unbound number of entries in the store queue. A value
              of zero for this flag is ignored, and the default store queue size is used instead.

       -timeline
              Enable the timeline view.

       -timeline-max-iterations=<iterations>
              Limit the number of iterations to print in  the  timeline  view.  By  default,  the
              timeline view prints information for up to 10 iterations.

       -timeline-max-cycles=<cycles>
              Limit the number of cycles in the timeline view, or use 0 for no limit. By default,
              the number of cycles is set to 80.

       -resource-pressure
              Enable the resource pressure view. This is enabled by default.

       -register-file-stats
              Enable register file usage statistics.

       -dispatch-stats
              Enable extra dispatch statistics.  This  view  collects  and  analyzes  instruction
              dispatch  events,  as  well  as  static/dynamic dispatch stall events. This view is
              disabled by default.

       -scheduler-stats
              Enable extra scheduler statistics. This  view  collects  and  analyzes  instruction
              issue events. This view is disabled by default.

       -retire-stats
              Enable extra retire control unit statistics. This view is disabled by default.

       -instruction-info
              Enable the instruction info view. This is enabled by default.

       -show-encoding
              Enable the printing of instruction encodings within the instruction info view.

       -show-barriers
              Enable  the  printing  of LoadBarrier and StoreBarrier flags within the instruction
              info view.

       -all-stats
              Print all hardware  statistics.  This  enables  extra  statistics  related  to  the
              dispatch  logic,  the  hardware  schedulers,  the  register file(s), and the retire
              control unit. This option is disabled by default.

       -all-views
              Enable all the view.

       -instruction-tables
              Prints resource pressure information based on the static information available from
              the  processor  model.  This  differs  from  the  resource pressure view because it
              doesn’t require that the code is  simulated.  It  instead  prints  the  theoretical
              uniform distribution of resource pressure for every instruction in sequence.

       -bottleneck-analysis
              Print  information  about bottlenecks that affect the throughput. This analysis can
              be expensive, and it is disabled by default. Bottlenecks  are  highlighted  in  the
              summary view. Bottleneck analysis is currently not supported for processors with an
              in-order backend.

       -json  Print the requested views in valid JSON format. The instructions and the  processor
              resources are printed as members of special top level JSON objects.  The individual
              views refer to them by index. However, not all views are currently  supported.  For
              example,  the  report  from the bottleneck analysis is not printed out in JSON. All
              the default views are currently supported.

       -disable-cb
              Force usage of the generic CustomBehaviour and InstrPostProcess classes rather than
              using  the  target  specific  implementation.  The generic classes never detect any
              custom hazards or make any post processing modifications to instructions.

       -disable-im
              Force usage of the generic InstrumentManager rather than using the target  specific
              implementation.  The  generic  class  creates  Instruments  that  provide  no extra
              information, and InstrumentManager never overrides the default schedule class for a
              given instruction.

EXIT STATUS

       llvm-mca  returns  0 on success. Otherwise, an error message is printed to standard error,
       and the tool returns 1.

USING MARKERS TO ANALYZE SPECIFIC CODE BLOCKS

       llvm-mca allows for the optional usage of special code comments to  mark  regions  of  the
       assembly  code to be analyzed.  A comment starting with substring LLVM-MCA-BEGIN marks the
       beginning of an analysis region. A comment starting with substring LLVM-MCA-END marks  the
       end of a region.  For example:

          # LLVM-MCA-BEGIN
            ...
          # LLVM-MCA-END

       If  no  user-defined  region  is  specified,  then llvm-mca assumes a default region which
       contains every instruction in the input file.  Every region is analyzed in isolation,  and
       the  final performance report is the union of all the reports generated for every analysis
       region.

       Analysis regions can have names. For example:

          # LLVM-MCA-BEGIN A simple example
            add %eax, %eax
          # LLVM-MCA-END

       The code from the example above defines a region named “A simple example”  with  a  single
       instruction  in  it.  Note  how  the  region  name  doesn’t  have  to  be  repeated in the
       LLVM-MCA-END directive. In the absence of overlapping regions, an  anonymous  LLVM-MCA-END
       directive always ends the currently active user defined region.

       Example of nesting regions:

          # LLVM-MCA-BEGIN foo
            add %eax, %edx
          # LLVM-MCA-BEGIN bar
            sub %eax, %edx
          # LLVM-MCA-END bar
          # LLVM-MCA-END foo

       Example of overlapping regions:

          # LLVM-MCA-BEGIN foo
            add %eax, %edx
          # LLVM-MCA-BEGIN bar
            sub %eax, %edx
          # LLVM-MCA-END foo
            add %eax, %edx
          # LLVM-MCA-END bar

       Note that multiple anonymous regions cannot overlap. Also, overlapping regions cannot have
       the same name.

       There is no support for marking regions from high-level source code, like C or C++.  As  a
       workaround, inline assembly directives may be used:

          int foo(int a, int b) {
            __asm volatile("# LLVM-MCA-BEGIN foo":::"memory");
            a += 42;
            __asm volatile("# LLVM-MCA-END":::"memory");
            a *= b;
            return a;
          }

       However, this interferes with optimizations like loop vectorization and may have an impact
       on the code generated. This is because the __asm statements are seen as real  code  having
       important side effects, which limits how the code around them can be transformed. If users
       want to make use of inline assembly to emit markers, then the recommendation is to  always
       verify  that the output assembly is equivalent to the assembly generated in the absence of
       markers.  The Clang options to emit optimization reports can also help in detecting missed
       optimizations.

INSTRUMENT REGIONS

       An  InstrumentRegion  describes  a  region  of  assembly  code guarded by special LLVM-MCA
       comment directives.

          # LLVM-MCA-<INSTRUMENT_TYPE> <data>
            ...  ## asm

       where INSTRUMENT_TYPE is a type defined by the target and expects to use data.

       A comment starting with substring LLVM-MCA-<INSTRUMENT_TYPE> brings data  into  scope  for
       llvm-mca to use in its analysis for all following instructions.

       If  a  comment  with the same INSTRUMENT_TYPE is found later in the instruction list, then
       the original InstrumentRegion will be automatically ended, and a new InstrumentRegion will
       begin.

       If there are comments containing the different INSTRUMENT_TYPE, then both data sets remain
       available. In contrast with an AnalysisRegion, an InstrumentRegion does not need a comment
       to end the region.

       Comments that are prefixed with LLVM-MCA- but do not correspond to a valid INSTRUMENT_TYPE
       for the target cause an error, except  for  BEGIN  and  END,  since  those  correspond  to
       AnalysisRegions.  Comments  that  do  not  start  with  LLVM-MCA-  are ignored by :program
       llvm-mca.

       An instruction (a MCInst) is added to an InstrumentRegion R only if  its  location  is  in
       range [R.RangeStart, R.RangeEnd].

       On RISCV targets, vector instructions have different behaviour depending on the LMUL. Code
       can be instrumented with a comment that takes the following form:

          # LLVM-MCA-RISCV-LMUL <M1|M2|M4|M8|MF2|MF4|MF8>

       The RISCV InstrumentManager will override the schedule class for  vector  instructions  to
       use  the  scheduling behaviour of its pseudo-instruction which is LMUL dependent. It makes
       sense to  place  RISCV  instrument  comments  directly  after  vset{i}vl{i}  instructions,
       although they can be placed anywhere in the program.

       Example of program with no call to vset{i}vl{i}:

          # LLVM-MCA-RISCV-LMUL M2
          vadd.vv v2, v2, v2

       Example of program with call to vset{i}vl{i}:

          vsetvli zero, a0, e8, m1, tu, mu
          # LLVM-MCA-RISCV-LMUL M1
          vadd.vv v2, v2, v2

       Example of program with multiple calls to vset{i}vl{i}:

          vsetvli zero, a0, e8, m1, tu, mu
          # LLVM-MCA-RISCV-LMUL M1
          vadd.vv v2, v2, v2
          vsetvli zero, a0, e8, m8, tu, mu
          # LLVM-MCA-RISCV-LMUL M8
          vadd.vv v2, v2, v2

       Example of program with call to vsetvl:

          vsetvl rd, rs1, rs2
          # LLVM-MCA-RISCV-LMUL M1
          vadd.vv v12, v12, v12
          vsetvl rd, rs1, rs2
          # LLVM-MCA-RISCV-LMUL M4
          vadd.vv v12, v12, v12

HOW LLVM-MCA WORKS

       llvm-mca  takes  assembly  code  as  input. The assembly code is parsed into a sequence of
       MCInst with the help of the existing LLVM target assembly parsers. The parsed sequence  of
       MCInst is then analyzed by a Pipeline module to generate a performance report.

       The  Pipeline  module  simulates  the  execution of the machine code sequence in a loop of
       iterations (default is 100). During this  process,  the  pipeline  collects  a  number  of
       execution  related  statistics.  At  the  end  of this process, the pipeline generates and
       prints a report from the collected statistics.

       Here is an example of a performance report generated by the tool for a dot-product of  two
       packed  float  vectors  of  four  elements.  The analysis is conducted for target x86, cpu
       btver2.  The following result can be produced via the following command using the  example
       located at test/tools/llvm-mca/X86/BtVer2/dot-product.s:

          $ llvm-mca -mtriple=x86_64-unknown-unknown -mcpu=btver2 -iterations=300 dot-product.s

          Iterations:        300
          Instructions:      900
          Total Cycles:      610
          Total uOps:        900

          Dispatch Width:    2
          uOps Per Cycle:    1.48
          IPC:               1.48
          Block RThroughput: 2.0

          Instruction Info:
          [1]: #uOps
          [2]: Latency
          [3]: RThroughput
          [4]: MayLoad
          [5]: MayStore
          [6]: HasSideEffects (U)

          [1]    [2]    [3]    [4]    [5]    [6]    Instructions:
           1      2     1.00                        vmulps      %xmm0, %xmm1, %xmm2
           1      3     1.00                        vhaddps     %xmm2, %xmm2, %xmm3
           1      3     1.00                        vhaddps     %xmm3, %xmm3, %xmm4

          Resources:
          [0]   - JALU0
          [1]   - JALU1
          [2]   - JDiv
          [3]   - JFPA
          [4]   - JFPM
          [5]   - JFPU0
          [6]   - JFPU1
          [7]   - JLAGU
          [8]   - JMul
          [9]   - JSAGU
          [10]  - JSTC
          [11]  - JVALU0
          [12]  - JVALU1
          [13]  - JVIMUL

          Resource pressure per iteration:
          [0]    [1]    [2]    [3]    [4]    [5]    [6]    [7]    [8]    [9]    [10]   [11]   [12]   [13]
           -      -      -     2.00   1.00   2.00   1.00    -      -      -      -      -      -      -

          Resource pressure by instruction:
          [0]    [1]    [2]    [3]    [4]    [5]    [6]    [7]    [8]    [9]    [10]   [11]   [12]   [13]   Instructions:
           -      -      -      -     1.00    -     1.00    -      -      -      -      -      -      -     vmulps      %xmm0, %xmm1, %xmm2
           -      -      -     1.00    -     1.00    -      -      -      -      -      -      -      -     vhaddps     %xmm2, %xmm2, %xmm3
           -      -      -     1.00    -     1.00    -      -      -      -      -      -      -      -     vhaddps     %xmm3, %xmm3, %xmm4

       According  to this report, the dot-product kernel has been executed 300 times, for a total
       of 900 simulated instructions. The total number of simulated micro opcodes (uOps) is  also
       900.

       The  report  is  structured  in  three  main  sections.   The first section collects a few
       performance numbers; the goal of this section is to give a  very  quick  overview  of  the
       performance  throughput.  Important  performance  indicators  are IPC, uOps Per Cycle, and
       Block RThroughput (Block Reciprocal Throughput).

       Field DispatchWidth is the maximum number of micro opcodes  that  are  dispatched  to  the
       out-of-order  backend  every  simulated  cycle.  For  processors with an in-order backend,
       DispatchWidth is the maximum number of micro opcodes issued to the backend every simulated
       cycle.

       IPC is computed dividing the total number of simulated instructions by the total number of
       cycles.

       Field Block RThroughput is the reciprocal of the block throughput. Block throughput  is  a
       theoretical  quantity  computed as the maximum number of blocks (i.e. iterations) that can
       be executed per simulated clock cycle in the absence of loop carried  dependencies.  Block
       throughput  is  superiorly  limited by the dispatch rate, and the availability of hardware
       resources.

       In the absence of loop-carried data dependencies, the observed IPC tends to a  theoretical
       maximum which can be computed by dividing the number of instructions of a single iteration
       by the Block RThroughput.

       Field ‘uOps Per Cycle’ is computed dividing the total number of simulated micro opcodes by
       the  total number of cycles. A delta between Dispatch Width and this field is an indicator
       of a performance issue. In the absence of loop-carried  data  dependencies,  the  observed
       ‘uOps  Per Cycle’ should tend to a theoretical maximum throughput which can be computed by
       dividing the number of uOps of a single iteration by the Block RThroughput.

       Field uOps Per Cycle is bounded from above by the dispatch  width.  That  is  because  the
       dispatch  width limits the maximum size of a dispatch group. Both IPC and ‘uOps Per Cycle’
       are limited by the amount of hardware parallelism. The availability of hardware  resources
       affects  the resource pressure distribution, and it limits the number of instructions that
       can be executed in  parallel  every  cycle.   A  delta  between  Dispatch  Width  and  the
       theoretical  maximum  uOps  per Cycle (computed by dividing the number of uOps of a single
       iteration by the Block RThroughput) is an indicator of a performance bottleneck caused  by
       the lack of hardware resources.  In general, the lower the Block RThroughput, the better.

       In  this  example,  uOps  per  iteration/Block  RThroughput  is  1.50.  Since there are no
       loop-carried dependencies, the observed uOps Per Cycle is expected to approach  1.50  when
       the  number  of iterations tends to infinity. The delta between the Dispatch Width (2.00),
       and the theoretical maximum uOp  throughput  (1.50)  is  an  indicator  of  a  performance
       bottleneck  caused  by  the lack of hardware resources, and the Resource pressure view can
       help to identify the problematic resource usage.

       The second section of the report is the instruction info view. It shows  the  latency  and
       reciprocal  throughput  of  every  instruction  in  the  sequence.  It  also reports extra
       information related  to  the  number  of  micro  opcodes,  and  opcode  properties  (i.e.,
       ‘MayLoad’, ‘MayStore’, and ‘HasSideEffects’).

       Field  RThroughput is the reciprocal of the instruction throughput. Throughput is computed
       as the maximum number of instructions of a same type that can be executed per clock  cycle
       in  the  absence  of operand dependencies. In this example, the reciprocal throughput of a
       vector float multiply is 1 cycles/instruction.  That is because the FP multiplier JFPM  is
       only available from pipeline JFPU1.

       Instruction   encodings   are  displayed  within  the  instruction  info  view  when  flag
       -show-encoding is specified.

       Below is an example of -show-encoding output for the dot-product kernel:

          Instruction Info:
          [1]: #uOps
          [2]: Latency
          [3]: RThroughput
          [4]: MayLoad
          [5]: MayStore
          [6]: HasSideEffects (U)
          [7]: Encoding Size

          [1]    [2]    [3]    [4]    [5]    [6]    [7]    Encodings:                    Instructions:
           1      2     1.00                         4     c5 f0 59 d0                   vmulps %xmm0, %xmm1, %xmm2
           1      4     1.00                         4     c5 eb 7c da                   vhaddps        %xmm2, %xmm2, %xmm3
           1      4     1.00                         4     c5 e3 7c e3                   vhaddps        %xmm3, %xmm3, %xmm4

       The Encoding Size column shows the size in bytes of instructions.   The  Encodings  column
       shows the actual instruction encodings (byte sequences in hex).

       The  third section is the Resource pressure view.  This view reports the average number of
       resource cycles consumed every iteration by instructions for every processor resource unit
       available on the target.  Information is structured in two tables. The first table reports
       the number of  resource  cycles  spent  on  average  every  iteration.  The  second  table
       correlates  the  resource  cycles to the machine instruction in the sequence. For example,
       every iteration of the instruction vmulps always executes on resource unit  [6]  (JFPU1  -
       floating point pipeline #1), consuming an average of 1 resource cycle per iteration.  Note
       that on AMD Jaguar, vector floating-point multiply can only be issued to  pipeline  JFPU1,
       while horizontal floating-point additions can only be issued to pipeline JFPU0.

       The  resource  pressure  view  helps  with identifying bottlenecks caused by high usage of
       specific hardware resources.  Situations with resource pressure mainly concentrated  on  a
       few  resources  should,  in  general,  be  avoided.  Ideally, pressure should be uniformly
       distributed between multiple resources.

   Timeline View
       The timeline view produces a detailed  report  of  each  instruction’s  state  transitions
       through  an  instruction  pipeline.   This  view  is  enabled  by  the command line option
       -timeline.  As instructions transition through the various stages of the  pipeline,  their
       states  are  depicted  in  the view report.  These states are represented by the following
       characters:

       • D : Instruction dispatched.

       • e : Instruction executing.

       • E : Instruction executed.

       • R : Instruction retired.

       • = : Instruction already dispatched, waiting to be executed.

       • - : Instruction executed, waiting to be retired.

       Below  is  the  timeline  view  for  a  subset  of  the  dot-product  example  located  in
       test/tools/llvm-mca/X86/BtVer2/dot-product.s and processed by llvm-mca using the following
       command:

          $ llvm-mca -mtriple=x86_64-unknown-unknown -mcpu=btver2 -iterations=3 -timeline dot-product.s

          Timeline view:
                              012345
          Index     0123456789

          [0,0]     DeeER.    .    .   vmulps   %xmm0, %xmm1, %xmm2
          [0,1]     D==eeeER  .    .   vhaddps  %xmm2, %xmm2, %xmm3
          [0,2]     .D====eeeER    .   vhaddps  %xmm3, %xmm3, %xmm4
          [1,0]     .DeeE-----R    .   vmulps   %xmm0, %xmm1, %xmm2
          [1,1]     . D=eeeE---R   .   vhaddps  %xmm2, %xmm2, %xmm3
          [1,2]     . D====eeeER   .   vhaddps  %xmm3, %xmm3, %xmm4
          [2,0]     .  DeeE-----R  .   vmulps   %xmm0, %xmm1, %xmm2
          [2,1]     .  D====eeeER  .   vhaddps  %xmm2, %xmm2, %xmm3
          [2,2]     .   D======eeeER   vhaddps  %xmm3, %xmm3, %xmm4

          Average Wait times (based on the timeline view):
          [0]: Executions
          [1]: Average time spent waiting in a scheduler's queue
          [2]: Average time spent waiting in a scheduler's queue while ready
          [3]: Average time elapsed from WB until retire stage

                [0]    [1]    [2]    [3]
          0.     3     1.0    1.0    3.3       vmulps   %xmm0, %xmm1, %xmm2
          1.     3     3.3    0.7    1.0       vhaddps  %xmm2, %xmm2, %xmm3
          2.     3     5.7    0.0    0.0       vhaddps  %xmm3, %xmm3, %xmm4
                 3     3.3    0.5    1.4       <total>

       The timeline view is  interesting  because  it  shows  instruction  state  changes  during
       execution.   It  also gives an idea of how the tool processes instructions executed on the
       target, and how their timing information might be calculated.

       The timeline view is structured  in  two  tables.   The  first  table  shows  instructions
       changing state over time (measured in cycles); the second table (named Average Wait times)
       reports useful timing statistics,  which  should  help  diagnose  performance  bottlenecks
       caused by long data dependencies and sub-optimal usage of hardware resources.

       An  instruction  in  the timeline view is identified by a pair of indices, where the first
       index identifies an iteration, and the second index is the instruction index (i.e.,  where
       it  appears  in  the code sequence).  Since this example was generated using 3 iterations:
       -iterations=3, the iteration indices range from 0-2 inclusively.

       Excluding the first and last column, the remaining columns  are  in  cycles.   Cycles  are
       numbered sequentially starting from 0.

       From the example output above, we know the following:

       • Instruction [1,0] was dispatched at cycle 1.

       • Instruction [1,0] started executing at cycle 2.

       • Instruction [1,0] reached the write back stage at cycle 4.

       • Instruction [1,0] was retired at cycle 10.

       Instruction  [1,0]  (i.e.,  vmulps  from  iteration  #1)  does  not  have  to  wait in the
       scheduler’s queue for the operands to become available. By the time vmulps is  dispatched,
       operands  are already available, and pipeline JFPU1 is ready to serve another instruction.
       So the instruction can be immediately issued on the JFPU1 pipeline. That  is  demonstrated
       by the fact that the instruction only spent 1cy in the scheduler’s queue.

       There  is  a  gap  of 5 cycles between the write-back stage and the retire event.  That is
       because instructions must retire in program order, so [1,0] has to wait for  [0,2]  to  be
       retired first (i.e., it has to wait until cycle 10).

       In  the  example,  all  instructions  are  in  a  RAW (Read After Write) dependency chain.
       Register %xmm2 written by vmulps is immediately used by the first  vhaddps,  and  register
       %xmm3  written by the first vhaddps is used by the second vhaddps.  Long data dependencies
       negatively impact the ILP (Instruction Level Parallelism).

       In the dot-product example, there are anti-dependencies introduced  by  instructions  from
       different  iterations.   However,  those  dependencies can be removed at register renaming
       stage (at the cost of  allocating  register  aliases,  and  therefore  consuming  physical
       registers).

       Table Average Wait times helps diagnose performance issues that are caused by the presence
       of long latency instructions and potentially long data dependencies which  may  limit  the
       ILP.  Last  row, <total>, shows a global average over all instructions measured. Note that
       llvm-mca, by default, assumes at least 1cy between the dispatch event and the issue event.

       When the performance is limited by data dependencies and/or long latency instructions, the
       number of cycles spent while in the ready state is expected to be very small when compared
       with the total number of cycles spent in the scheduler’s queue.   The  difference  between
       the  two  counters  is a good indicator of how large of an impact data dependencies had on
       the execution of the instructions.  When performance is mostly  limited  by  the  lack  of
       hardware  resources,  the delta between the two counters is small.  However, the number of
       cycles spent in the queue tends to be larger (i.e.,  more  than  1-3cy),  especially  when
       compared to other low latency instructions.

   Bottleneck Analysis
       The   -bottleneck-analysis  command  line  option  enables  the  analysis  of  performance
       bottlenecks.

       This analysis is potentially expensive. It attempts  to  correlate  increases  in  backend
       pressure  (caused by pipeline resource pressure and data dependencies) to dynamic dispatch
       stalls.

       Below is  an  example  of  -bottleneck-analysis  output  generated  by  llvm-mca  for  500
       iterations of the dot-product example on btver2.

          Cycles with backend pressure increase [ 48.07% ]
          Throughput Bottlenecks:
            Resource Pressure       [ 47.77% ]
            - JFPA  [ 47.77% ]
            - JFPU0  [ 47.77% ]
            Data Dependencies:      [ 0.30% ]
            - Register Dependencies [ 0.30% ]
            - Memory Dependencies   [ 0.00% ]

          Critical sequence based on the simulation:

                        Instruction                         Dependency Information
           +----< 2.    vhaddps %xmm3, %xmm3, %xmm4
           |
           |    < loop carried >
           |
           |      0.    vmulps  %xmm0, %xmm1, %xmm2
           +----> 1.    vhaddps %xmm2, %xmm2, %xmm3         ## RESOURCE interference:  JFPA [ probability: 74% ]
           +----> 2.    vhaddps %xmm3, %xmm3, %xmm4         ## REGISTER dependency:  %xmm3
           |
           |    < loop carried >
           |
           +----> 1.    vhaddps %xmm2, %xmm2, %xmm3         ## RESOURCE interference:  JFPA [ probability: 74% ]

       According  to  the  analysis,  throughput  is limited by resource pressure and not by data
       dependencies.  The analysis observed increases in backend pressure during  48.07%  of  the
       simulated  run.  Almost  all  those  pressure increase events were caused by contention on
       processor resources JFPA/JFPU0.

       The critical sequence is the most expensive sequence  of  instructions  according  to  the
       simulation.  It  is  annotated  to  provide  extra  information  about  critical  register
       dependencies and resource interferences between instructions.

       Instructions from the critical sequence are expected to significantly impact  performance.
       By construction, the accuracy of this analysis is strongly dependent on the simulation and
       (as always) by the quality of the processor model in llvm.

       Bottleneck analysis is currently not supported for processors with an in-order backend.

   Extra Statistics to Further Diagnose Performance Issues
       The -all-stats command line option enables extra statistics and performance  counters  for
       the dispatch logic, the reorder buffer, the retire control unit, and the register file.

       Below  is an example of -all-stats output generated by  llvm-mca for 300 iterations of the
       dot-product example discussed in the previous sections.

          Dynamic Dispatch Stall Cycles:
          RAT     - Register unavailable:                      0
          RCU     - Retire tokens unavailable:                 0
          SCHEDQ  - Scheduler full:                            272  (44.6%)
          LQ      - Load queue full:                           0
          SQ      - Store queue full:                          0
          GROUP   - Static restrictions on the dispatch group: 0

          Dispatch Logic - number of cycles where we saw N micro opcodes dispatched:
          [# dispatched], [# cycles]
           0,              24  (3.9%)
           1,              272  (44.6%)
           2,              314  (51.5%)

          Schedulers - number of cycles where we saw N micro opcodes issued:
          [# issued], [# cycles]
           0,          7  (1.1%)
           1,          306  (50.2%)
           2,          297  (48.7%)

          Scheduler's queue usage:
          [1] Resource name.
          [2] Average number of used buffer entries.
          [3] Maximum number of used buffer entries.
          [4] Total number of buffer entries.

           [1]            [2]        [3]        [4]
          JALU01           0          0          20
          JFPU01           17         18         18
          JLSAGU           0          0          12

          Retire Control Unit - number of cycles where we saw N instructions retired:
          [# retired], [# cycles]
           0,           109  (17.9%)
           1,           102  (16.7%)
           2,           399  (65.4%)

          Total ROB Entries:                64
          Max Used ROB Entries:             35  ( 54.7% )
          Average Used ROB Entries per cy:  32  ( 50.0% )

          Register File statistics:
          Total number of mappings created:    900
          Max number of mappings used:         35

          *  Register File #1 -- JFpuPRF:
             Number of physical registers:     72
             Total number of mappings created: 900
             Max number of mappings used:      35

          *  Register File #2 -- JIntegerPRF:
             Number of physical registers:     64
             Total number of mappings created: 0
             Max number of mappings used:      0

       If we look at the Dynamic Dispatch Stall Cycles table,  we  see  the  counter  for  SCHEDQ
       reports  272  cycles.  This counter is incremented every time the dispatch logic is unable
       to dispatch a full group because the scheduler’s queue is full.

       Looking at the Dispatch Logic table, we see that the pipeline was only  able  to  dispatch
       two  micro  opcodes 51.5% of the time.  The dispatch group was limited to one micro opcode
       44.6% of the cycles, which  corresponds  to  272  cycles.   The  dispatch  statistics  are
       displayed by either using the command option -all-stats or -dispatch-stats.

       The  next  table,  Schedulers,  presents  a histogram displaying a count, representing the
       number of micro opcodes issued on some  number  of  cycles.  In  this  case,  of  the  610
       simulated  cycles,  single  opcodes  were issued 306 times (50.2%) and there were 7 cycles
       where no opcodes were issued.

       The Scheduler’s queue usage table shows that the average  and  maximum  number  of  buffer
       entries  (i.e.,  scheduler  queue  entries)  used at runtime.  Resource JFPU01 reached its
       maximum (18 of 18 queue entries). Note that AMD Jaguar implements three schedulers:

       • JALU01 - A scheduler for ALU instructions.

       • JFPU01 - A scheduler floating point operations.

       • JLSAGU - A scheduler for address generation.

       The dot-product is a kernel of  three  floating  point  instructions  (a  vector  multiply
       followed  by  two  horizontal  adds).  That explains why only the floating point scheduler
       appears to be used.

       A full scheduler queue is either caused by data dependency  chains  or  by  a  sub-optimal
       usage  of  hardware resources.  Sometimes, resource pressure can be mitigated by rewriting
       the kernel using  different  instructions  that  consume  different  scheduler  resources.
       Schedulers  with a small queue are less resilient to bottlenecks caused by the presence of
       long data dependencies.  The scheduler statistics  are  displayed  by  using  the  command
       option -all-stats or -scheduler-stats.

       The next table, Retire Control Unit, presents a histogram displaying a count, representing
       the number of instructions retired on some number of cycles.  In this  case,  of  the  610
       simulated  cycles,  two  instructions were retired during the same cycle 399 times (65.4%)
       and there were 109 cycles where no instructions were retired.  The retire  statistics  are
       displayed by using the command option -all-stats or -retire-stats.

       The  last  table presented is Register File statistics.  Each physical register file (PRF)
       used by the pipeline is presented in this table.  In the case of AMD Jaguar, there are two
       register  files,  one for floating-point registers (JFpuPRF) and one for integer registers
       (JIntegerPRF).  The table shows that of the 900 instructions  processed,  there  were  900
       mappings  created.  Since this dot-product example utilized only floating point registers,
       the JFPuPRF was responsible for creating the 900  mappings.   However,  we  see  that  the
       pipeline  only  used  a maximum of 35 of 72 available register slots at any given time. We
       can conclude that the floating point PRF was the only register file used for the  example,
       and that it was never resource constrained.  The register file statistics are displayed by
       using the command option -all-stats or -register-file-stats.

       In this example, we can conclude that the IPC is mostly limited by data dependencies,  and
       not by resource pressure.

   Instruction Flow
       This  section  describes the instruction flow through the default pipeline of llvm-mca, as
       well as the functional units involved in the process.

       The default  pipeline  implements  the  following  sequence  of  stages  used  to  process
       instructions.

       • Dispatch (Instruction is dispatched to the schedulers).

       • Issue (Instruction is issued to the processor pipelines).

       • Write Back (Instruction is executed, and results are written back).

       • Retire (Instruction is retired; writes are architecturally committed).

       The  in-order  pipeline  implements  the  following  sequence  of  stages:  * InOrderIssue
       (Instruction is issued to the processor pipelines).  *  Retire  (Instruction  is  retired;
       writes are architecturally committed).

       llvm-mca  assumes  that  instructions have all been decoded and placed into a queue before
       the simulation start. Therefore, the instruction fetch and decode stages are not  modeled.
       Performance  bottlenecks  in the frontend are not diagnosed. Also, llvm-mca does not model
       branch prediction.

   Instruction Dispatch
       During the dispatch stage, instructions are picked  in  program  order  from  a  queue  of
       already  decoded  instructions,  and  dispatched  in  groups  to  the  simulated  hardware
       schedulers.

       The size of a dispatch group  depends  on  the  availability  of  the  simulated  hardware
       resources.  The processor dispatch width defaults to the value of the IssueWidth in LLVM’s
       scheduling model.

       An instruction can be dispatched if:

       • The size of the dispatch group is smaller than processor’s dispatch width.

       • There are enough entries in the reorder buffer.

       • There are enough physical registers to do register renaming.

       • The schedulers are not full.

       Scheduling models can optionally  specify  which  register  files  are  available  on  the
       processor.  llvm-mca uses that information to initialize register file descriptors.  Users
       can limit the number of physical  registers  that  are  globally  available  for  register
       renaming by using the command option -register-file-size.  A value of zero for this option
       means unbounded. By knowing how many registers are available for renaming,  the  tool  can
       predict dispatch stalls caused by the lack of physical registers.

       The  number  of reorder buffer entries consumed by an instruction depends on the number of
       micro-opcodes specified for that instruction by the target scheduling model.  The  reorder
       buffer  is responsible for tracking the progress of instructions that are “in-flight”, and
       retiring them in program order.  The number of entries in the reorder buffer  defaults  to
       the value specified by field MicroOpBufferSize in the target scheduling model.

       Instructions  that  are  dispatched  to  the  schedulers consume scheduler buffer entries.
       llvm-mca queries the scheduling model to determine the set of buffered resources  consumed
       by an instruction.  Buffered resources are treated like scheduler resources.

   Instruction Issue
       Each  processor scheduler implements a buffer of instructions.  An instruction has to wait
       in the scheduler’s buffer until input register operands become available.   Only  at  that
       point,  does the instruction becomes eligible for execution and may be issued (potentially
       out-of-order) for execution.  Instruction latencies are computed by llvm-mca with the help
       of the scheduling model.

       llvm-mca’s scheduler is designed to simulate multiple processor schedulers.  The scheduler
       is responsible for tracking data dependencies, and dynamically selecting  which  processor
       resources are consumed by instructions.  It delegates the management of processor resource
       units and resource groups to a resource manager.  The resource manager is responsible  for
       selecting  resource  units  that  are  consumed  by  instructions.   For  example,  if  an
       instruction consumes 1cy of a resource group, the resource  manager  selects  one  of  the
       available  units  from  the  group;  by  default,  the resource manager uses a round-robin
       selector to guarantee that resource usage is uniformly distributed between all units of  a
       group.

       llvm-mca’s scheduler internally groups instructions into three sets:

       • WaitSet: a set of instructions whose operands are not ready.

       • ReadySet: a set of instructions ready to execute.

       • IssuedSet: a set of instructions executing.

       Depending  on the operands availability, instructions that are dispatched to the scheduler
       are either placed into the WaitSet or into the ReadySet.

       Every cycle, the scheduler checks if instructions can be moved from  the  WaitSet  to  the
       ReadySet, and if instructions from the ReadySet can be issued to the underlying pipelines.
       The algorithm prioritizes older instructions over younger instructions.

   Write-Back and Retire Stage
       Issued instructions are moved from the ReadySet to  the  IssuedSet.   There,  instructions
       wait  until  they  reach  the  write-back stage.  At that point, they get removed from the
       queue and the retire control unit is notified.

       When instructions are executed, the retire control unit flags the instruction as “ready to
       retire.”

       Instructions  are  retired  in  program  order.   The  register  file  is  notified of the
       retirement so that it can  free  the  physical  registers  that  were  allocated  for  the
       instruction during the register renaming stage.

   Load/Store Unit and Memory Consistency Model
       To  simulate an out-of-order execution of memory operations, llvm-mca utilizes a simulated
       load/store unit (LSUnit) to simulate the speculative execution of loads and stores.

       Each load (or store) consumes an entry in the load (or store)  queue.  Users  can  specify
       flags  -lqueue  and  -squeue  to  limit the number of entries in the load and store queues
       respectively. The queues are unbounded by default.

       The LSUnit implements a relaxed consistency model for memory loads and stores.  The  rules
       are:

       1. A younger load is allowed to pass an older load only if there are no intervening stores
          or barriers between the two loads.

       2. A younger load is allowed to pass an older store provided that the load does not  alias
          with the store.

       3. A younger store is not allowed to pass an older store.

       4. A younger store is not allowed to pass an older load.

       By  default,  the  LSUnit  optimistically  assumes that loads do not alias (-noalias=true)
       store operations.  Under this assumption, younger loads are always allowed to  pass  older
       stores.   Essentially,  the  LSUnit  does not attempt to run any alias analysis to predict
       when loads and stores do not alias with each other.

       Note that, in the case of write-combining  memory,  rule  3  could  be  relaxed  to  allow
       reordering  of non-aliasing store operations.  That being said, at the moment, there is no
       way to further relax the memory model (-noalias is the only option).   Essentially,  there
       is  no  option  to  specify  a  different  memory type (e.g., write-back, write-combining,
       write-through; etc.) and consequently to weaken, or strengthen, the memory model.

       Other limitations are:

       • The LSUnit does not know when store-to-load forwarding may occur.

       • The LSUnit does not know anything about cache hierarchy and memory types.

       • The LSUnit does not know how to identify serializing operations and memory fences.

       The LSUnit does not attempt to predict if a load or store hits or misses the L1 cache.  It
       only knows if an instruction “MayLoad” and/or “MayStore.”  For loads, the scheduling model
       provides an “optimistic”  load-to-use  latency  (which  usually  matches  the  load-to-use
       latency for when there is a hit in the L1D).

       llvm-mca  does  not  (on its own) know about serializing operations or memory-barrier like
       instructions.   The  LSUnit  used  to  conservatively  use  an  instruction’s   “MayLoad”,
       “MayStore”, and unmodeled side effects flags to determine whether an instruction should be
       treated as a memory-barrier. This was inaccurate in general and was changed  so  that  now
       each  instruction  has  an  IsAStoreBarrier  and  IsALoadBarrier flag. These flags are mca
       specific and default to false for every instruction. If any instruction should have either
       of  these flags set, it should be done within the target’s InstrPostProcess class.  For an
       example,   look   at   the   X86InstrPostProcess::postProcessInstruction   method   within
       llvm/lib/Target/X86/MCA/X86CustomBehaviour.cpp.

       A  load/store  barrier  consumes  one entry of the load/store queue.  A load/store barrier
       enforces ordering of loads/stores.  A younger load cannot pass a load  barrier.   Also,  a
       younger store cannot pass a store barrier.  A younger load has to wait for the memory/load
       barrier to execute.  A load/store barrier is “executed” when it becomes the  oldest  entry
       in  the  load/store  queue(s).  That  also  means,  by  construction,  all  of  the  older
       loads/stores have been executed.

       In conclusion, the full set of load/store consistency rules are:

       1. A store may not pass a previous store.

       2. A store may not pass a previous load (regardless of -noalias).

       3. A store has to wait until an older store barrier is fully executed.

       4. A load may pass a previous load.

       5. A load may not pass a previous store unless -noalias is set.

       6. A load has to wait until an older load barrier is fully executed.

   In-order Issue and Execute
       In-order processors  are  modelled  as  a  single  InOrderIssueStage  stage.  It  bypasses
       Dispatch,  Scheduler and Load/Store unit. Instructions are issued as soon as their operand
       registers are available and resource requirements are met. Multiple  instructions  can  be
       issued  in  one  cycle  according  to  the  value  of  the  IssueWidth parameter in LLVM’s
       scheduling model.

       Once issued, an instruction is moved to IssuedInst  set  until  it  is  ready  to  retire.
       llvm-mca ensures that writes are committed in-order. However, an instruction is allowed to
       commit writes and retire out-of-order if RetireOOO property is true for at  least  one  of
       its writes.

   Custom Behaviour
       Due  to  certain instructions not being expressed perfectly within their scheduling model,
       llvm-mca isn’t always able to simulate them  perfectly.  Modifying  the  scheduling  model
       isn’t  always a viable option though (maybe because the instruction is modeled incorrectly
       on purpose or the instruction’s behaviour is quite complex). The CustomBehaviour class can
       be  used  in these cases to enforce proper instruction modeling (often by customizing data
       dependencies and detecting hazards that llvm-mca has no way of knowing about).

       llvm-mca comes with one generic and multiple target specific CustomBehaviour classes.  The
       generic  class  will  be  used  if  the  -disable-cb  flag is used or if a target specific
       CustomBehaviour class doesn’t exist for that target. (The  generic  class  does  nothing.)
       Currently,  the  CustomBehaviour  class is only a part of the in-order pipeline, but there
       are plans to add it to the out-of-order pipeline in the future.

       CustomBehaviour’s main method is checkCustomHazard() which uses  the  current  instruction
       and  a  list  of  all instructions still executing within the pipeline to determine if the
       current instruction should be dispatched.   As  output,  the  method  returns  an  integer
       representing the number of cycles that the current instruction must stall for (this can be
       an underestimate if you don’t know the exact number and a value of 0 represents no stall).

       If you’d like to add a CustomBehaviour class for a target that doesn’t already  have  one,
       refer  to  an existing implementation to see how to set it up. The classes are implemented
       within the target specific backend (for example /llvm/lib/Target/AMDGPU/MCA/) so that they
       can access backend symbols.

   Instrument Manager
       On  certain  architectures, scheduling information for certain instructions do not contain
       all of the information required to identify the most precise schedule class. For  example,
       data that can have an impact on scheduling can be stored in CSR registers.

       One example of this is on RISCV, where values in registers such as vtype and vl change the
       scheduling behaviour of vector instructions. Since MCA does not keep track of  the  values
       in registers, instrument comments can be used to specify these values.

       InstrumentManager’s  main function is getSchedClassID() which has access to the MCInst and
       all of the instruments that are active  for  that  MCInst.   This  function  can  use  the
       instruments to override the schedule class of the MCInst.

       On RISCV, instrument comments containing LMUL information are used by getSchedClassID() to
       map  a  vector  instruction  and  the  active  LMUL  to  the  scheduling  class   of   the
       pseudo-instruction that describes that base instruction and the active LMUL.

   Custom Views
       llvm-mca  comes with several Views such as the Timeline View and Summary View. These Views
       are generic and can work with most (if not all) targets. If you wish to add a new View  to
       llvm-mca  and  it  does  not require any backend functionality that is not already exposed
       through MC layer classes (MCSubtargetInfo,  MCInstrInfo,  etc.),  please  add  it  to  the
       /tools/llvm-mca/View/ directory. However, if your new View is target specific AND requires
       unexposed   backend   symbols   or   functionality,   you   can   define   it    in    the
       /lib/Target/<TargetName>/MCA/ directory.

       To  enable  this  target specific View, you will have to use this target’s CustomBehaviour
       class to override the CustomBehaviour::getViews() methods.   There  are  3  variations  of
       these  methods based on where you want your View to appear in the output: getStartViews(),
       getPostInstrInfoViews(), and getEndViews(). These methods returns a vector of Views so you
       will want to return a vector containing all of the target specific Views for the target in
       question.

       Because   these   target   specific   (and   backend   dependent)   Views   require    the
       CustomBehaviour::getViews()  variants,  these Views will not be enabled if the -disable-cb
       flag is used.

       Enabling these custom Views does not affect the non-custom (generic) Views.   Continue  to
       use the usual command line arguments to enable / disable those Views.

AUTHOR

       Maintained by the LLVM Team (https://llvm.org/).

COPYRIGHT

       2003-2024, LLVM Project