A Python module to access the function of the LIKWID library
Project description
pylikwid
Python interface for the C API of LIKWID (https://github.com/RRZE-HPC/likwid)
Installation
I added a setup.py script for the installation. It builds the C module and copies it to the proper destination.
$ git clone https://github.com/RRZE-HPC/pylikwid.git $ cd pylikwid # Build C interface $ python setup.py build_ext -I <include path for likwid> -L <library path for likwid> -R <library path for likwid> # Install module to the proper location $ python setup.py install (--prefix=<where to install>) # Testing $ python -c "import pylikwid" $ ./testlib.py
Functions
After import pylikwid you can call the following functions:
Marker API
pylikwid.init(): Initialize the Marker API of the LIKWID library. Must be called previous to all other functions.
pylikwid.threadinit(): Add the current thread to the Marker API. Since Python is commonly single-threaded simply call it directly after pylikwid.init()
rr = pylikwid.registerregion(regiontag): Register a region to the Marker API. This is an optional function to reduce the overhead of region registration at pylikwid.startregion. If you don’t call pylikwid.registerregion(regiontag), the registration is done at pylikwid.startregion(regiontag). On success, 0 is return. If you havn’t called pylikwid.init(), a negative number is returned.
err = pylikwid.startregion(regiontag): Start measurements under the name regiontag. On success, 0 is return. If you havn’t called pylikwid.init(), a negative number is returned.
err = pylikwid.stopregion(regiontag): Stop measurements under the name regiontag again. On success, 0 is return. If you havn’t called pylikwid.init(), a negative number is returned.
num_events, events[], time, count = pylikwid.getregion(regiontag): Get the intermediate results of the region identified by regiontag. On success, it returns the number of events in the current group, a list with all the aggregated event results, the measurement time for the region and the number of calls.
pylikwid.nextgroup(): Switch to the next event set in a round-robin fashion. If you have set only one event set on the command line, this function performs no operation.
pylikwid.close(): Close the connection to the LIKWID Marker API and write out measurement data to file. This file will be evaluated by likwid-perfctr.
pylikwid.getprocessorid(): Returns the ID of the currently executing CPU
pylikwid.pinprocess(cpuid): Pins the current process to the CPU given as cpuid.
pylikwid.pinthread(cpuid): Pins the current thread to the CPU given as cpuid.
Topology
pylikwid.inittopology(): Initialize the topology module (reads in system topology)
infodict = pylikwid.getcpuinfo(): Return a dict with general information about the system (CPU model, CPU family, …)
osname: Name of the CPU retrieved from the CPUID leafs
name: Name of the micro architecture
short_name: Short name of the micro architecture
family: ID of the CPU family
model: Vendor-specific model number of the CPU
stepping: Stepping (Revision) of the CPU
perf_version: Version number of the hardware performance monitoring capabilities
perf_num_ctr: Amount of general-purpose counter registers per hardware thread
perf_num_fixed_ctr: Amount of fixed-purpose counter registers per hardware thread
perf_width_ctr: Bit length of the counter registers
clock: CPU clock (only unequal to 0 if timer module is initialized)
turbo: Is turbo mode supported?
isIntel: Is it an Intel CPU?
supportUncore: Does the system have performance monitoring counters in the Uncore?
features: String with performance relevant CPU features (AVX, SSE, …)
featureFlags: Bitmask for all available CPU features
topodict = pylikwid.getcputopology(): Return a dict with the topology of the system. Here is a list of fields in the dict:
numSockets: Number of CPU sockets
numHWThreads: Number of hardware threads (physical + hyperthreading cores)
activeHWThreads: Number of active/usable hardware threads
numCoresPerSocket: Amount of hardware threads per CPU socket
numThreadsPerCore: Amount of hardware threads assembled in every physical CPU core
numCacheLevels: Amount of levels in cacheing hierarchy
cacheLevels: Dict with information about the cache levels, keys are the levels (1, 2, 3,…)
level: Level of the cache in the hierarchy
lineSize: Size of a cache line
sets: Amount of sets
inclusive: Is the cache inclusive or exclusive?`
threads: Amount of threads attached to the cache
associativity: Associativity of the cache
type: data (= data cache), unified = (data + instruction cache)
size: Size of the cache in bytes
threadPool: Dict with information about the hardware threads. Keys are the os-generated ID of the hardware thread
coreId: ID of the corresponding physical core
apicId: ID set by the operating system
threadId: ID of the hardware thread in the physical core
packageId: ID of the CPU socket hosting the hardware thread
pylikwid.printsupportedcpus(): Prints all supported micro architecture names to stdout
pylikwid.finalizetopology(): Delete all information in the topology module
NUMA
numadict = pylikwid.initnuma(): Initialize the NUMA module and return the gathered values
numberOfNodes: Amount of NUMA nodes in the system
nodes: Dict holding the information about the NUMA domains. Keys are the NUMA domain IDs
id: ID of the NUMA domain (should be equal to dict key)
numberOfProcessors: Number of hardware threads attached to the NUMA domain
processors: List of all CPU IDs attached to the NUMA domain
freeMemory: Amount of free memory in the NUMA domain (in Kbytes)
totalMemory: Amount of total memory in the NUMA domain (in Kbytes)
numberOfDistances: How many distances to self/other NUMA domains
distances: List with distances, NUMA domain IDs are the destination indexes in the list
pylikwid.finalizenuma(): Delete all information in the NUMA module
Affinity
affdict = pylikwid.initaffinity(): Initialize the affinity domain module and return the gathered values
numberOfAffinityDomains: Amount of affinity domains
numberOfSocketDomains: Amount of CPU socket related affinity domains
numberOfNumaDomains: Amount of NUMA related affinity domains
numberOfCacheDomains: Amount of last level cache related affinity domains
numberOfProcessorsPerSocket: Amount of hardware threads per CPU socket
numberOfCoresPerCache: Amount of physical CPU cores per last level cache
numberOfProcessorsPerCache: Amount of hardware threads per last level cache
domains: Dict holding the information about the affinity domains
tag: Name of the affinity domain (N = node, SX = socket X, CY = cache Y, MZ = memory domain Z)
numberOfProcessors: Amount of hardware threads in the domain
numberOfCores: Amount of physical CPU cores in the domain
processorList: List holding the CPU IDs in the domain
pylikwid.finalizeaffinity(): Delete all information in the affinity domain module
pylikwid.cpustr_to_cpulist(): Transform a valid cpu string in LIKWID syntax into a list of CPU IDs
Timer
pylikwid.getcpuclock(): Return the CPU clock
t_start = pylikwid.startclock(): Start the clock and return the current timestamp
t_end = pylikwid.stopclock(): Stop the clock and return the current timestamp
t = pylikwid.getclock(t_start, t_end): Return the time in seconds between t_start and t_end
c = pylikwid.getclockcycles(t_start, t_end): Return the amount of CPU cycles between t_start and t_end
Temperature
pylikwid.inittemp(cpu): Initialize the temperature module for CPU cpu
pylikwid.readtemp(cpu): Read the current temperature of CPU cpu
Energy
pinfo = pylikwid.getpowerinfo(): Initializes the energy module and returns gathered information. If it returns None, there is no energy support
minFrequency: Minimal possible frequency of a CPU core
baseFrequency: Base frequency of a CPU core
hasRAPL: Are energy reading supported?
timeUnit: Time unit
powerUnit: Power unit
domains: Dict holding the information about the energy domains. Keys are PKG, PP0, PP1, DRAM
ID: ID of the energy domain
energyUnit: Unit to derive raw register counts to uJ
supportInfo: Is the information register available?
tdp: TDP of the domain (only if supportInfo == True)
minPower: Minimal power consumption by the domain (only if supportInfo == True)
maxPower: Maximal power consumption by the domain (only if supportInfo == True)
maxTimeWindow: Maximal time window between updates of the energy registers
supportStatus: Are energy readings from the domain are possible?
supportPerf: Is power capping etc. available?
supportPolicy: Can we set a power policy for the domain?
e_start = pylikwid.startpower(cpu, domainid): Return the start value for a cpu for the domain with domainid. The domainid can be found in pinfo["domains"][domainname]["ID"]
e_stop = pylikwid.stoppower(cpu, domainid): Return the stop value for a cpu for the domain with domainid. The domainid can be found in pinfo["domains"][domainname]["ID"]
e = pylikwid.getpower(e_start, e_stop, domainid): Calculate the uJ from the values retrieved by startpower and stoppower.
Configuration
pylikwid.initconfiguration(): Read in config file from different places. Default is /etc/likwid.cfg
config = pylikwid.getconfiguration(): Get the dict with the configuration options
configFileName: Path to the config file
topologyCfgFileName: If a topology file was created with likwid-genTopoCfg and found by initconfiguration()
daemonPath: Path to the access daemon executable
groupPath: Path to the base directory with the performance group files
daemonMode: Configured access mode (0=direct, 1=accessDaemon)
maxNumThreads: Maximal amount of hardware threads that can be handled by LIKWID
maxNumNodes: Maximal amount of CPU sockets that can be handled by LIKWID
pylikwid.destroyconfiguration(): Destroy all information about the configuration
Access module
pylikwid.hpmmode(mode): Set access mode. For x86 there are two modes:
mode = 0: Access the MSR and PCI devices directly. May require root access
mode = 1: Access the MSR and PCI devices through access daemon instances
pylikwid.hpminit(): Initialize the access functions according to the access mode
pylikwid.hpmaddthread(cpu): Add CPU cpu to the access layer (opens devices files or connection to an access daemon)
pylikwid.hpmfinalize(): Unregister all CPUs from the access layer and close files/connections
Performance Monitoring
pylikwid.init(cpus): Initialize the perfmon module for the CPUs given in list cpus
pylikwid.getnumberofthreads(): Return the number of threads initialized in the perfmon module
pylikwid.getnumberofgroups(): Return the number of groups currently registered in the perfmon module
pylikwid.getgroups(): Return a list of all available groups. Each list entry is a dict:
Name: Name of the performance group
Short: Short information about the performance group
Long: Long description of the performance group
gid = pylikwid.addeventset(estr): Add a performance group or a custom event set to the perfmon module. The gid is required to specify the event set later
pylikwid.getnameofgroup(gid): Return the name of the group identified by gid. If it is a custom event set, the name is set to Custom
pylikwid.getshortinfoofgroup(gid): Return the short information about a performance group
pylikwid.getlonginfoofgroup(gid): Return the description of a performance group
pylikwid.getnumberofevents(gid): Return the amount of events in the group
pylikwid.getnumberofmetrics(gid): Return the amount of derived metrics in the group. Always 0 for custom event sets.
pylikwid.getnameofevent(gid, eidx): Return the name of the event identified by gid and the index in the list of events
pylikwid.getnameofcounter(gid, eidx): Return the name of the counter register identified by gid and the index in the list of events
pylikwid.getnameofmetric(gid, midx): Return the name of a derived metric identified by gid and the index in the list of metrics
pylikwid.setup(gid): Program the counter registers to measure all events in group gid
pylikwid.start(): Start the counter registers
pylikwid.stop(): Stop the counter registers
pylikwid.read(): Read the counter registers (stop->read->start)
pylikwid.switch(gid): Switch to group gid (stop->setup(gid)->start)
pylikwid.getidofactivegroup() Return the gid of the currently configured group
pylikwid.getresult(gid, eidx, tidx): Return the raw counter register result of all measurements identified by group gid and the indices for event eidx and thread tidx
pylikwid.getlastresult(gid, eidx, tidx): Return the raw counter register result of the last measurement cycle identified by group gid and the indices for event eidx and thread tidx
pylikwid.getmetric(gid, midx, tidx): Return the derived metric result of all measurements identified by group gid and the indices for metric midx and thread tidx
pylikwid.getlastmetric(gid, midx, tidx): Return the derived metric result of the last measurement cycle identified by group gid and the indices for metric midx and thread tidx
pylikwid.gettimeofgroup(gid): Return the measurement time for group identified by gid
pylikwid.finalize(): Reset all used registers and delete internal measurement results
Marker API result file reader
pylikwid.markerreadfile(filename): Reads in the result file of an application run instrumented by the LIKWID Marker API
pylikwid.markernumregions(): Return the number of regions in an application run
pylikwid.markerregiontag(rid): Return the region tag for the region identified by rid
pylikwid.markerregiongroup(rid): Return the group name for the region identified by rid
pylikwid.markerregionevents(rid): Return the amount of events for the region identified by rid
pylikwid.markerregionthreads(rid): Return the amount of threads that executed the region identified by rid
pylikwid.markerregiontime(rid, tidx): Return the accumulated measurement time for the region identified by rid and the thread index tidx
pylikwid.markerregioncount(rid, tidx): Return the call count for the region identified by rid and the thread index tidx
pylikwid.markerregionresult(rid, eidx, tidx): Return the call count for the region identified by rid, the event index eidx and the thread index tidx
pylikwid.markerregionmetric(rid, midx, tidx): Return the call count for the region identified by rid, the metric index midx and the thread index tidx
Usage
Marker API
Code
Here is a small example Python script how to use the LIKWID Marker API in Python:
#!/usr/bin/env python import pylikwid pylikwid.init() pylikwid.threadinit() liste = [] pylikwid.startregion("listappend") for i in range(0,1000000): liste.append(i) pylikwid.stopregion("listappend") nr_events, eventlist, time, count = pylikwid.getregion("listappend") for i, e in enumerate(eventlist): print(i, e) pylikwid.close()
This code simply measures the hardware performance counters for appending 1000000 elements to a list. First the API is initialized with likwid.init() and likwid.threadinit(). Afterwards it creates an empty list, starts the measurements with likwid.startregion("listappend") and executes the appending loop. When the loop has finished, we stop the measurements again using likwid.stopregion("listappend"). Just for the example, we get the values inside our script using likwid.getregion("listappend") and print out the results. Finally, we close the connection to the LIKWID Marker API.
You always have to use likwid-perfctr to program the hardware performance counters and specify the CPUs that should be measured. Since Python is commonly single-threaded, the cpu set only contains one entry: likwid-perfctr -C 0 -g <EVENTSET> -m <PYTHONSCRIPT> This pins the Python interpreter to CPU 0 and measures <EVENTSET> for all regions in the Python script. You can set multiple event sets by adding multiple -g <EVENTSET> to the command line. Please see the LIKWID page for further information how to use likwid-perfctr. Link: https://github.com/rrze-likwid/likwid
Example
Using the above Python script we can measure the L2 to L3 cache data volume:
$ likwid-perfctr -C 0 -g L3 -m ./test.py -------------------------------------------------------------------------------- CPU name: Intel(R) Core(TM) i7-4770 CPU @ 3.40GHz CPU type: Intel Core Haswell processor CPU clock: 3.39 GHz -------------------------------------------------------------------------------- (0, 926208305.0) (1, 325539316.0) (2, 284626172.0) (3, 1219118.0) (4, 918368.0) Wrote LIKWID Marker API output to file /tmp/likwid_17275.txt -------------------------------------------------------------------------------- ================================================================================ Group 1 L3: Region listappend ================================================================================ +-------------------+----------+ | Region Info | Core 0 | +-------------------+----------+ | RDTSC Runtime [s] | 0.091028 | | call count | 1 | +-------------------+----------+ +-----------------------+---------+--------------+ | Event | Counter | Core 0 | +-----------------------+---------+--------------+ | INSTR_RETIRED_ANY | FIXC0 | 9.262083e+08 | | CPU_CLK_UNHALTED_CORE | FIXC1 | 3.255393e+08 | | CPU_CLK_UNHALTED_REF | FIXC2 | 2.846262e+08 | | L2_LINES_IN_ALL | PMC0 | 1.219118e+06 | | L2_TRANS_L2_WB | PMC1 | 9.183680e+05 | +-----------------------+---------+--------------+ +-------------------------------+--------------+ | Metric | Core 0 | +-------------------------------+--------------+ | Runtime (RDTSC) [s] | 0.09102752 | | Runtime unhalted [s] | 9.596737e-02 | | Clock [MHz] | 3.879792e+03 | | CPI | 3.514753e-01 | | L3 load bandwidth [MBytes/s] | 8.571425e+02 | | L3 load data volume [GBytes] | 0.078023552 | | L3 evict bandwidth [MBytes/s] | 6.456899e+02 | | L3 evict data volume [GBytes] | 0.058775552 | | L3 bandwidth [MBytes/s] | 1.502832e+03 | | L3 data volume [GBytes] | 0.136799104 | +-------------------------------+--------------+
At first a header with the current system type and clock is printed. Afterwards the output of the Python script lists the results of the measurements we got internally with likwid.getregion. The next output is the region results evaluated by likwid-perfctr and prints at first a headline stating the measured eventset, here L3 and the region name listappend. Afterwards 2 or 3 tables are printed. At first some basic information about the region like run time (or better measurement time) and the number of calls of the region. The next table contains the raw values for each event in the eventset. These numbers are similar to the ones we got internally with likwid.getregion. If you have set an performance group (here L3) instead of a custom event set, the raw results are derived to commonly used metrics, here the CPI (Cycles per instruction, lower is better) and different bandwidths and data volumes. You can see, that the load bandwidth for the small loop is 857 MByte/s and the evict (write) bandwidth is 645 MByte/s. In total we have a bandwidth of 1502 MByte/s.
Full API
Code
#!/usr/bin/env python import pylikwid liste = [] cpus = [0,1] pylikwid.init(cpus) group = pylikwid.addeventset("INSTR_RETIRED_ANY:FIXC0") pylikwid.setup(group) pylikwid.start() for i in range(0,1000000): liste.append(i) pylikwid.stop() for thread in range(0,len(cpus)): print("Result CPU %d : %f" % (cpus[thread], pylikwid.getresult(group,0,thread))) pylikwid.finalize()
Example
$ ./test.py Result CPU 0 : 87335.000000 Result CPU 1 : 5222188.000000
Further comments
Please be aware that Python is a high-level language and your simple code is translated to a lot of Assembly instructions. The CPI value is commonly low (=> good) for high-level languages because they have to perform type-checking and similar stuff that can be executed fast in comparison to the CPU clock. If you would compare the results to a lower level language like C or Fortran, the CPI will be worse for them but the performance will be higher as no type-checking and transformations need to be done.
Project details
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
File details
Details for the file pylikwid-0.2.7.tar.gz
.
File metadata
- Download URL: pylikwid-0.2.7.tar.gz
- Upload date:
- Size: 31.0 kB
- Tags: Source
- Uploaded using Trusted Publishing? No
File hashes
Algorithm | Hash digest | |
---|---|---|
SHA256 | ff3fd9af97320bff10da920b1330ed0a4c4b71d933878dcb75a0ea56fe726b7e |
|
MD5 | 8368a3061276e335fdbbd1623bd1b03e |
|
BLAKE2b-256 | c16f9b74caea82019cb569a3c14be2e0bb40e639a3532f210bded31e503f006c |