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Understanding CPU Microarchitecture for Perform...

alblue
April 07, 2020

Understanding CPU Microarchitecture for Performance (LJC)

Microprocessors have evolved over decades to eke out performance from existing code. But the microarchitecture of the CPU leaks into the assumptions of a flat memory model, with the result that equivalent code can run significantly faster by working with, rather than fighting against, the microarchitecture of the CPU.

This talk, given for the London Java Community in 2020, presents the microarchitecture of modern CPUs, showing how misaligned data can cause cache line false sharing, how branch prediction works and when it fails, how to read CPU specific performance monitoring counters and use that in conjunction with tools like perf and toplev to discover where bottlenecks in CPU heavy code live. We’ll use these facts to revisit performance advice on general code patterns and the things to look out for in executing systems. The talk will be language agnostic, although it will be based on the Linux/x86_64 architecture.

The presentation was recorded at the London Java Community meeting in April 2020, and a recording is available here: https://youtu.be/C4HEoBYL0yk

alblue

April 07, 2020
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  1. @alblue ©2020 Alex Blewitt Overview • What happens inside a

    CPU? • Where do CPU intensive programs get delayed? • What tools are there to help measure performance bottlenecks? • How can we make programs run faster?
  2. @alblue ©2020 Alex Blewitt distributed architecture system architecture algorithm hardware

    cpu memory inst Performance Pyramid This talk Other QCon talks https://www.infoq.com/qconlondon2020/
  3. @alblue ©2020 Alex Blewitt DMI x4 ** Platform Topologies 8S

    Configuration SKL SKL LBG LBG LBG DMI LBG SKL SKL SKL SKL SKL SKL 3x16 PCIe* 4S Configurations SKL SKL SKL SKL 2S Configurations SKL SKL (4S-2UPI & 4S-3UPI shown) (2S-2UPI & 2S-3UPI shown) Intel® UPI LBG 3x16 PCIe* 1x100G Intel® OP Fabric 3x16 PCIe* 1x100G Intel® OP Fabric LBG LBG LBG DMI 3x16 PCIe* This slide under embargo until 9:15 AM PDT July 11, 2017 Intel® Xeon® Scalable Processor supports configurations ranging from 2S-2UPI to 8S Non Uniform Memory Architecture (NUMA) https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf
  4. @alblue ©2020 Alex Blewitt DMI x4 ** Platform Topologies 8S

    Configuration SKL SKL LBG LBG LBG DMI LBG SKL SKL SKL SKL SKL SKL 3x16 PCIe* 4S Configurations SKL SKL SKL SKL 2S Configurations SKL SKL (4S-2UPI & 4S-3UPI shown) (2S-2UPI & 2S-3UPI shown) Intel® UPI LBG 3x16 PCIe* 1x100G Intel® OP Fabric 3x16 PCIe* 1x100G Intel® OP Fabric LBG LBG LBG DMI 3x16 PCIe* This slide under embargo until 9:15 AM PDT July 11, 2017 Intel® Xeon® Scalable Processor supports configurations ranging from 2S-2UPI to 8S Non Uniform Memory Architecture (NUMA) https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf
  5. @alblue ©2020 Alex Blewitt DMI x4 ** Platform Topologies 8S

    Configuration SKL SKL LBG LBG LBG DMI LBG SKL SKL SKL SKL SKL SKL 3x16 PCIe* 4S Configurations SKL SKL SKL SKL 2S Configurations SKL SKL (4S-2UPI & 4S-3UPI shown) (2S-2UPI & 2S-3UPI shown) Intel® UPI LBG 3x16 PCIe* 1x100G Intel® OP Fabric 3x16 PCIe* 1x100G Intel® OP Fabric LBG LBG LBG DMI 3x16 PCIe* This slide under embargo until 9:15 AM PDT July 11, 2017 Intel® Xeon® Scalable Processor supports configurations ranging from 2S-2UPI to 8S Non Uniform Memory Architecture (NUMA) https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf
  6. @alblue ©2020 Alex Blewitt DMI x4 ** Platform Topologies 8S

    Configuration SKL SKL LBG LBG LBG DMI LBG SKL SKL SKL SKL SKL SKL 3x16 PCIe* 4S Configurations SKL SKL SKL SKL 2S Configurations SKL SKL (4S-2UPI & 4S-3UPI shown) (2S-2UPI & 2S-3UPI shown) Intel® UPI LBG 3x16 PCIe* 1x100G Intel® OP Fabric 3x16 PCIe* 1x100G Intel® OP Fabric LBG LBG LBG DMI 3x16 PCIe* This slide under embargo until 9:15 AM PDT July 11, 2017 Intel® Xeon® Scalable Processor supports configurations ranging from 2S-2UPI to 8S Non Uniform Memory Architecture (NUMA) https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf
  7. @alblue ©2020 Alex Blewitt Sub NUMA cluster 1 Sub NUMA

    cluster 0 https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf Cascade/Skylake 28-core die
  8. @alblue ©2020 Alex Blewitt L3$ (LLC) 1.375 MiB 11-way Non-inclusive

    L3$ (LLC) 1.375 MiB 11-way Non-inclusive L3$ (LLC) 1.375 MiB 11-way Non-inclusive Memory and Cache ($) Register file 180 Integer 168 Floating Point L1 Data (L1D$) 32 KiB 8-way L1 Instruction (L1I$) 32 KiB 8-way L2$ 1 MiB 16-way Inclusive L3$ (LLC) 1.375 MiB 11-way Non-inclusive Information for Cascade/Skylake systems RAM RAM RAM RAM 1 4 4 40 12 50 150 300 Clock Cycles
  9. @alblue ©2020 Alex Blewitt lstopo --no-io Machine (16GB) Package P#0

    L4 (128MB) L3 (6144KB) L2 (256KB) L1d (32KB) L1i (32KB) Core P#0 PU P#0 PU P#4 L2 (256KB) L1d (32KB) L1i (32KB) Core P#1 PU P#1 PU P#5 L2 (256KB) L1d (32KB) L1i (32KB) Core P#2 PU P#2 PU P#6 L2 (256KB) L1d (32KB) L1i (32KB) Core P#3 PU P#3 PU P#7 Shared memory between CPU and GPU HyperThreads Single socket system Cache levels Four core processor
  10. @alblue ©2020 Alex Blewitt L3$ (LLC) 1.375 MiB 11-way Non-inclusive

    L3$ (LLC) 1.375 MiB 11-way Non-inclusive L3$ (LLC) 1.375 MiB 11-way Non-inclusive Memory and Cache ($) Register file 180 Integer 168 Floating Point L1 Data (L1D$) 32 KiB 8-way L1 Instruction (L1I$) 32 KiB 8-way L2$ 1 MiB 16-way Inclusive L3$ (LLC) 1.375 MiB 11-way Non-inclusive Data TLB 4K: 128 8-way 2M/4M: 8/T assoc Instruction TLB 4: 64 4-way 2M/4M: 32 4-way 1G: 4 4-way STLB 4K/2M: 1536 12-way 1G: 16 4-way RAM RAM RAM RAM Virtual Physical PCID 00008000(1234) 5e38450c(1234) 10 00008000(1234) 48656c6f(1234) 20 fffffffffffb(8080) 2345ffffffb(8080) 0 1 4 4 40 12 50 150 300 Clock Cycles Information for Cascade/Skylake systems grep /proc/cpuinfo for pcid ↑
  11. @alblue ©2020 Alex Blewitt Memory Pages 8000 ffaa ffbb f000

    0000 CR3 0000 ffff 7fff CR3 0000 ffff 7fff 8000 f000 Two layer page table structure shown x86_64 has 4 level paging (48 bits, 256TiB virtual, 64TiB real) Ice Lake processors support 5 level paging (57 bits, 128Pb virtual, 4PiB real) 0x000080001234 0x000080001234 Pages can be 4k, 2M or 1G
  12. @alblue ©2020 Alex Blewitt Huge Pages 0000 Pages can be

    4K, 2M or 1G grep /proc/cpuinfo pse: 2M support pdpe1g: 1G support Better use of TLB More complex to set up Fewer memory cache misses May waste memory Hugetblfs needs to be configured
  13. @alblue ©2020 Alex Blewitt Hugetblfs • Requires kernel configuration to

    reserve memory ahead of time • Boot parameter hugepages=N puts aside memory for huge page use • Boot parameter hugepagesz={2M,1G} specifies huge page size • Requires a hugetblfs mount to be provided • Requires root (or suitably permissioned app) to use hugepages
  14. @alblue ©2020 Alex Blewitt Transparent Huge Pages • Does not

    require boot time configuration or special permissions • khugepaged assembles contiguous physical memory for large pages • Default page size is still 4k, but processes can madvise() use of large pages • Allows specific apps to opt-in on demand • Benefits of smaller TLB with less wasted memory # echo madvise > /sys/kernel/mm/transparent_hugepages/enabled # echo defer > /sys/kernel/mm/transparent_hugepage/defrag Defer instead of blocking large page request Enable opt-in through use of madvise
  15. @alblue ©2020 Alex Blewitt Cache lines, loads and stores •

    Unit of granularity of a cache entry is 64 bytes (512 bits) • Even if you only read/write 1 byte you're writing 64 bytes • Cache lines can generally be in different states: ➡ M – exclusively owned by that core, and modified (dirty) ➡ E – exclusively owned by that core, but not modified ➡ S – shared read-only with other cores ➡ I – invalid, cache line not used
  16. @alblue ©2020 Alex Blewitt Memory prefetching (CPU) CPU issues automatic

    prefetch for streamed data Also notices striding by certain amounts as well Can also use __builtin_prefetch to explicitly suggest prefetching memory elsewhere but needs to be a measured improvement
  17. @alblue ©2020 Alex Blewitt False sharing • Two cores trying

    to write to bytes in the same cache-line will thrash • First thread will try to acquire exclusive ownership of cache line • Second thread (on different core) will try to do the same • Performance will suffer when cache line repeatedly moved • Avoid by padding to at least cacheline size * 2 (128 bytes) for writes Thread 1 data[0] = 'A' Thread 2 data[7] = 'C'
  18. @alblue ©2020 Alex Blewitt Memory performance strategies • Ensure data

    fits in L1/L2/L3 cache where possible • Stream or stride through data in a single pass if possible • Consider pivoting data (array-of-structs or structs-of-arrays) • Add padding for multi-threaded contended writes • Prefer thread-local or cpu-local accumulators with final merge step • Compress data where practical (compressed pointers)
  19. @alblue ©2020 Alex Blewitt Pinning memory/threads • Pinning memory or

    threads to a particular core can improve performance • Reduces intra-core memory ownership traffic • Less likely to have cache invalidations • isolcpu allows reservation of CPUs for non-kernel use with cpusets • taskset allows binding of a process to specific cores • numactl allows cores/memory to be clamped for a process • libnuma has additional affinity settings for programmatic use
  20. @alblue ©2020 Alex Blewitt Frontend Core L1 Data 32 KiB

    8-way L1 Instruction 32 KiB 8-way Backend x86_64 µop
  21. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way
  22. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way 55 48 89 e5 fe 04 25 d2 04 00 00 41 6c 42 6c 75
  23. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way 55|48 89 e5|fe 04 25 d2 04 00 00|41 6c 42 6c 75
  24. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way push %rbp mov %rsp, %rbp ? incb 0x4d2
  25. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way incb 0x4d2 incb 0x4d2 incb 0x4d2
  26. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way TMP = [0x4d2] INC TMP [0x4d2] = TMP
  27. @alblue ©2020 Alex Blewitt Core x86_64 Pre-decode Instructions µop decoders

    µop cache loop decode branch prediction Backend µop L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way TMP = [0x4d2] INC TMP [0x4d2] = TMP
  28. @alblue ©2020 Alex Blewitt Branch Prediction ⤵ • Correct 95%

    of the time • Queues up instructions assuming the branch has been taken • Learns patterns in code based on existing behaviour • Iterating through predictable (sorted) data may be more efficient • Throws away inaccurate work if incorrect • May cause observable side channel behaviour e.g. cache invalidation cmp eax,42; jne
  29. @alblue ©2020 Alex Blewitt Branch Target Predictor • Predicts where

    the target is going if taken • Hard coded addresses/offsets always predictable • Jump to location of register may be more difficult • Often seen when jumping through object oriented code • Inlining is the master optimisation because it avoids unknowable branches jmp [eax]
  30. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way
  31. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way TMP = [0x4d2] INC TMP [0x4d2] = TMP
  32. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way R99 = [0x4d2] INC R99 [0x4d2] = R99
  33. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way R99 = [0x4d2] INC R99 [0x4d2] = R99
  34. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way R99 = 2A INC R99 [0x4d2] = R99
  35. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way R99 = 2A INC R99 [0x4d2] = R99
  36. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way INC R99 [0x4d2] = R99 R99 = 2B
  37. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way INC R99 R99 = 2B [0x4d2] = 2B
  38. @alblue ©2020 Alex Blewitt Core Allocate Rename Retire load buffer

    store buffer register files 2 3 4 7 8 9 0 1 5 6 Scheduler Integer Unit Floating Unit ALU LEA Shift Branch ALU FMA Shift Divide ALU LEA Multiply Divide ALU FMA Shift Shuffle ALU LEA Multiply ALU FMA Shuffle ALU LEA Shift Branch Execution units added in Ice Lake Port 0 and 1 can be fused for a 512 bit operation Port 5 is a 512 bit wide operation All others handle 256 bits Port 8 and 9 added in Ice Lake Address generation reorder buffer Frontend L1 Data 32 KiB 8-way L1 Instruction 32 KiB 8-way INC R99 R99 = 2B [0x4d2] = 2B
  39. @alblue ©2020 Alex Blewitt perf • Linux perf (compiled from

    linux/tools/perf, or from linux-tools/linux-perf) • Running in Docker requires compilation from source • Commands available • record – record execution performance for process/pid • report – generate a report from prior recording • annotate – annotate a report from a prior recording • stat – record performance counters for process/pid https://perf.wiki.kernel.org https://github.com/alblue/scripts/blob/master/perf-Dockerfile
  40. @alblue ©2020 Alex Blewitt perf record • Perf record will

    sample the process(es) and generate stack traces • Events may be skewed from their location • Improve accuracy with :p, :pp or :ppp suffix to event • Can capture branches, last branch records or use processor tracing • perf record -b program • perf record --call-graph lbr -j any_call,any_ret program • perf record -e intel_pt//u program https://lwn.net/Articles/680985/ https://lwn.net/Articles/680996/
  41. @alblue ©2020 Alex Blewitt perf stat $ perf stat base64

    <(echo hello) d29ybGQK Performance counter stats for 'base64 /dev/fd/63': 0.341382 task-clock (msec) # 0.649 CPUs utilized 0 context-switches # 0.000 K/sec 0 cpu-migrations # 0.000 K/sec 65 page-faults # 0.190 M/sec 1,218,176 cycles # 3.568 GHz 811,468 stalled-cycles-frontend # 66.61% frontend cycles idle 855,999 instructions # 0.70 insn per cycle # 0.95 stalled cycles per insn 169,032 branches # 495.140 M/sec 8,883 branch-misses # 5.26% of all branches 0.000526160 seconds time elapsed https://perf.wiki.kernel.org IPC > 4 < 1
  42. @alblue ©2020 Alex Blewitt Performance counters • Intel cores have

    a few dedicated and programmable counters • Instruction cycles, branches, branch misses … • Counters can be multiplexed (read X for 1µs, read Y for 1µs) • Programmable counters can be set to specific measurements • iTLB-load-misses, LLC-load-misses, uops_dispatched_port.port_5 ... • Undocumented performance counters can be specified with events • cpu/event=0x3c,umask=0x0,any=1/
  43. @alblue ©2020 Alex Blewitt 19 Locating Issues Have Precise events

    for sampling Precise events added in Skylake Top-down Microarchitecture Analysis https://www.researchgate.net/publication/269302126_A_Top-Down_method_for_performance_analysis_and_counters_architecture Ahmed Yasin
  44. @alblue ©2020 Alex Blewitt Top-down Analysis Method USING PERFORMANCE MONITORING

    EVENTS Additionally, the metric uses the UOPS_ISSUED.ANY, which is common in recent Intel microarchitec- tures, as the denominator. The UOPS_ISSUED.ANY event counts the total number of Uops that the RAT issues to RS. The VectorMixRate metric gives the percentage of injected blend uops out of all uops issued. Usually a VectorMixRate over 5% is worth investigating. VectorMixRate[%] = 100 * UOPS_ISSUED.VECTOR_WIDTH_MISMATCH / UOPS_ISSUED.ANY Note the actual penalty may vary as it stems from the additional data-dependency on the destination register the injected blend operations add. B.2 PERFORMANCE MONITORING AND MICROARCHITECTURE This section provides information of performance monitoring hardware and terminology related to the Silvermont, Airmont and Goldmont microarchitectures. The features described here may be specific to individual microarchitecture, as indicated in Table B-1. Figure B-3. TMAM Hierarchy Supported by Skylake Microarchitecture WŝƉĞůŝŶĞ^ůŽƚƐ ZĞƚŝƌŝŶŐ ĂĚ^ƉĞĐƵůĂƚŝŽŶ &ƌŽŶƚŶĚŽƵŶĚ ĂĐŬŶĚŽƵŶĚ EŽƚ^ƚĂůůĞĚ ^ƚĂůůĞĚ ĂƐĞ ƌĂŶĐŚ D ŝƐƉƌĞĚŝĐƚ &ĞƚĐŚ >ĂƚĞŶĐLJ D Ğŵ ŽƌLJŽƵŶĚ ŽƌĞŽƵŶĚ &ĞƚĐŚ ĂŶĚǁ ŝĚƚŚ D ĂĐŚŝŶĞ ůĞĂƌ D ^Ͳ ZKD džƚ͘ D Ğŵ ŽƌLJ ŽƵŶĚ >ϯŽƵŶĚ >ϮŽƵŶĚ >ϭŽƵŶĚ ^ƚŽƌĞƐŽƵŶĚ ŝǀŝĚĞƌ džĞĐƵƚŝŽŶ ƉŽƌƚƐ hƚŝůŝnjĂƚŝŽŶ >^ D/d ƌĂŶĐŚ ZĞƐƚĞĞƌƐ /ĐĂĐŚĞDŝƐƐ /d>DŝƐƐ KƚŚĞƌ &WͲƌŝƚŚ ^ ^^ǁŝƚĐŚĞƐ D^^ǁŝƚĐŚĞƐ ^ĐĂůĂƌ sĞĐƚŽƌ ϯнƉŽƌƚƐ ϭŽƌϮƉŽƌƚƐ ϬƉŽƌƚƐ DĞŵĂŶĚǁŝĚƚŚ DĞŵ>ĂƚĞŶĐLJ yϴϳ ^ƚŽƌĞDŝƐƐ ^d>,ŝƚ ^d>DŝƐƐ >Ϯ,ŝƚ >ϮDŝƐƐ &ĂůƐĞƐŚĂƌŝŶŐ d>^ƚŽƌĞ ^ƚŽƌĞĨǁĚďůŬ ϰ<ĂůŝĂƐŝŶŐ ŽŶƚĞƐƚĞĚĂĐĐĞƐƐ ĂƚĂƐŚĂƌŝŶŐ >ϯůĂƚĞŶĐLJ USING PERFORMANCE MONITORING EVENTS The single entry point of division at a pipeline’s issue-stage (allocation-stage) makes the four categories additive to the total possible slots. The classification at slots granularity (sub-cycle) makes the break- down very accurate and robust for superscalar cores, which is a necessity at the top-level. Figure B-2. TMAM’s Top Level Drill Down Flowchart hŽƉ ůůŽĐĂƚĞ͍ hŽƉǀĞƌ ZĞƚŝƌĞƐ͍ ĂĐŬŶĚ ^ƚĂůůƐ͍ &ƌŽŶƚŶĚ ŽƵŶĚ ĂĐŬŶĚ ŽƵŶĚ ZĞƚŝƌŝŶŐ ĂĚ ^ƉĞĐƵůĂƚŝŽŶ zĞƐ zĞƐ EŽ zĞƐ EŽ EŽ https://software.intel.com/en-us/download/intel-64-and-ia-32-architectures-optimization-reference-manual Ahmed Yasin
  45. @alblue ©2020 Alex Blewitt perf stat --topdown $ perf stat

    -a --topdown sleep 1 nmi_watchdog enabled with topdown. May give wrong results. Disable with echo 0 > /proc/sys/kernel/nmi_watchdog Performance counter stats for 'system wide': retiring bad speculation frontend bound backend bound S0-C0 2 15.3% 2.8% 32.1% 49.9% S0-C1 2 23.3% 4.0% 27.3% 45.4% S0-C2 2 15.2% 2.9% 29.8% 52.1% S0-C3 2 16.7% 0.0% 31.8% 51.5% S0-C4 2 35.7% 10.7% 26.2% 27.4% S0-C5 2 14.9% 2.5% 34.1% 48.5% 1.000889285 seconds time elapsed
  46. @alblue ©2020 Alex Blewitt Toplev PMU tools • Andi Kleen

    has written toplev.py which allows top-down analysis • Initial download caches processor information from download.01.org • Uses perf to record stats, but with custom event filters • If workload is repeatable, can use --no-multiplex to repeat results • Run with -l1, see if issues are present, run with -l2 ... https://github.com/andikleen/pmu-tools/wiki/toplev-manual
  47. @alblue ©2020 Alex Blewitt toplev.py --single-thread $ dd if=/dev/urandom of=/tmp/rand

    bs=4096 count=4096 $ ./toplev.py --single-thread --no-multiplex -l1 -- base64 /tmp/rand > /dev/null # 3.6-full on Intel(R) Xeon(R) CPU E5-1650 v2 @ 3.50GHz BE Backend_Bound % Slots 24.07 <== $ ./toplev.py --single-thread --no-multiplex -l2 -- base64 /tmp/rand > /dev/null BE Backend_Bound % Slots 23.82 BE/Core Backend_Bound.Core_Bound % Slots 16.08 <== $ ./toplev.py --single-thread --no-multiplex -l3 -- base64 /tmp/rand > /dev/null BE Backend_Bound % Slots 23.96 BE/Core Backend_Bound.Core_Bound % Slots 16.35 BE/Core Backend_Bound.Core_Bound.Ports_Utilization % Clocks 24.51 <==
  48. @alblue ©2020 Alex Blewitt Cache line Instruction layout Before After

    Error Is Error? Before After Error Is Error? __builtin_expect(error,0) __builtin_expect(error,1)
  49. @alblue ©2020 Alex Blewitt Cache line Cache line Loop stream

    detector Good Loop Bad Loop 32 bit aliognment Align with 
 -mllvm -align-all-nofallthru-blocks=5
 -mllvm -align-all-functions=5
  50. @alblue ©2020 Alex Blewitt Facebook BOLT https://arxiv.org/abs/1807.06735 Figure 9: Heat

    maps for instruction memory accesses of the HHVM binary, without and with BOLT. Heat is a log scale. Executed instructions are distributed across icache space After sorting basic blocks guided by profiling data, the icache space is defragmented https://github.com/facebookincubator/BOLT
  51. @alblue ©2020 Alex Blewitt Google llvm-propeller https://github.com/google/llvm-propeller https://github.com/google/llvm-propeller/blob/plo-dev/Propeller_RFC.pdf Exe perf.data

    perf.propeller Optimised exe C C perf record clang -fpropeller-label create_llvm_prof clang -fpropeller-optimize func1() {…} func2() {…} func3() {…} … func1() {…} func2() {…} func3() {…} clang -ffunction-sections clang -fbasicblock-sections=perf.propeller lld + thinLTO + PGO
  52. @alblue ©2020 Alex Blewitt Summary: Memory • Use cacheline-aligned or

    cacheline-aware data structures • Compress data in memory and decompress on the fly • Avoid random memory access when possible • Configure huge pages and use madvise & defer • Partition memory with libnuma for data locality
  53. @alblue ©2020 Alex Blewitt Summary: CPU • Each CPU is

    its own networked mesh cluster • Branch speculation and memory/TLB misses are costly • Use branch free and lock free algorithms when possible • Analyse perf counters with top down architectural analysis • Use (auto)vectorisation and use XMM/YMM/ZMM when sensible
  54. @alblue ©2020 Alex Blewitt References https://alblue.bandlem.com/ https://arxiv.org/abs/1807.06735 → https://github.com/facebookincubator/BOLT https://arxiv.org/abs/1902.08318

    → https://github.com/lemire/simdjson/ https://github.com/andikleen/pmu-tools/wiki/toplev-manual https://github.com/google/llvm-propeller/ https://lwn.net/Articles/680985/ && https://lwn.net/Articles/680996/ https://perf.wiki.kernel.org https://simplecore-ger.intel.com/swdevcon-uk/wp-content/uploads/sites/5/2017/10/UK-Dev-Con_Toby-Smith-Track-A_1000.pdf https://software.intel.com/en-us/download/intel-64-and-ia-32-architectures-optimization-reference-manual https://www.researchgate.net/publication/269302126_A_Top- Down_method_for_performance_analysis_and_counters_architecture