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GPUPluginDebugUtils
This document is a list of useful debug features / tricks that might be used to find root cause of performance / functional issues. Some of them are available by default, but some others might require plugin recompilation
For CPU dump, see Blob dumping
Debug_config
is an infra structure that contains number of easy-to-use debugging features. It has various control parameters. You can check list of parameters from the source code cldnn::debug_configuration
.
First, this feature should be enabled from cmake configuration ENABLE_DEBUG_CAPS
. When openvino is released, it is turned off by default.
The parameters should be set from environment variable when calling inference engine API.
$ OV_GPU_Verbose=1 ./benchmark_app ... # Run benchmark_app with OV_GPU_Verbose option
$ OV_GPU_DumpLayersPath="cldnn/" ./benchmark_app ... # Run benchmark_app and store intermediate buffers into cldnn/ directory.
For Windows OS, please use below syntax.
Windows Power Shell:
> $env:OV_GPU_Verbose=1
> .\benchmark_app.exe ... # Run benchmark_app with OV_GPU_Verbose option
Windows cmd.exe:
> set "OV_GPU_Verbose=1"
> benchmark_app.exe ... # Run benchmark_app with OV_GPU_Verbose option
Plugin is able to parse different naming styles for debug options:
OV_GPU_SOME_OPTION
OV_GPU_SomeOption
Behavior when both versions are specified is not defined.
Some options also allow multiple prefixes: OV
and OV_GPU
. OV
prefix is intended to be used for options common for all OpenVINO components. In case if an option is set twice with different prefixes, then OV_GPU
has higher priority.
-
OV_GPU_Help
: Show help message of debug config. -
OV_GPU_Verbose
: Verbose execution. Currently, Verbose=1 and 2 are supported. -
OV_GPU_PrintMultiKernelPerf
: Print kernel latency for multi-kernel primitives. This is turned on by setting 1. Execution time is printed. -
OV_GPU_DisableUsm
: Disable the usage of usm (unified shared memory). This is turned on by setting 1. -
OV_GPU_DumpGraphs
: Dump optimized graph into the path that this variable points. This is turned on by setting the destination path into this variable. -
OV_GPU_DumpLayersPath
: Enable intermediate buffer dump and store the tensors. This is turned on by setting the destination path into this variable. You can check the exact layer name fromOV_GPU_Verbose=1
. -
OV_GPU_DumpLayers
: Dump intermediate buffers only for the layers that this variable specifies. Multiple layers can be specified with space delimiter. Dump feature should be enabled throughOV_GPU_DumpLayersPath
-
OV_GPU_DumpLayersDstOnly
: When dumping intermediate buffer, dump destination buffer only. This is turned on by setting 1.
The execution graph (also known as runtime graph) is a device specific graph after all transformations applied by the plugin. It's a very useful
feature for performance analysis and it allows to find a source of performance regressions quickly. Execution graph can be retrieved from the plugin
using GetExecGraphInfo()
method of InferenceEngine::ExecutableNetwork
and then serialized as usual IR:
ExecutableNetwork exeNetwork;
// Load some model into the plugin
CNNNetwork execGraphInfo = exeNetwork.GetExecGraphInfo();
execGraphInfo.serialize("/path/to/serialized/exec/graph.xml");
The capability to retrieve execution graph and store it on the disk is integrated into benchmark_app
. The execution graph can be simply dumped
by setting additional parameter -exec_graph_path exec_graph.xml
for benchmark_app
. Output xml
file has a format similar to usual IR, but contains
execution nodes with some runtime info such as:
- Execution time of each node
- Mapping between nodes in final device specific graph and original input graph operations
- Output layout
- Output precision
- Primitive type
- Inference precision
Typical node in GPU execution graph looks as follows:
<layer id="0" name="convolution" type="Convolution">
<data execOrder="1" execTimeMcs="500" originalLayersNames="convolution,relu" outputLayouts="b_fs_yx_fsv16" outputPrecisions="FP16" primitiveType="convolution_gpu_bfyx_to_bfyx_f16" />
<input>
<port id="0">
<dim>1</dim>
<dim>3</dim>
<dim>224</dim>
<dim>224</dim>
</port>
</input>
<output>
<port id="1" precision="FP16">
<dim>1</dim>
<dim>64</dim>
<dim>112</dim>
<dim>112</dim>
</port>
</output>
</layer>
Most of the data here is very handy for the performance analysis. For example, for each node you can check that:
- Nodes fusion works as expected on given models (i.e. some node is missing in execution graph and it's name is a part of
originalLayersNames
list for some other node) - Input and output layouts of a node are optimal in each case
- Input and output precisions are valid in each case
- The node used expected kernel for execution
- And the most important: actual execution time of each operation
This graph can be visualized using Netron tool and all these properties can be analyzed there.
Note: execution time collection for each primitive requires CONFIG_KEY(PERF_COUNT)
to be enabled (benchmark_app
does it automatically), thus the overall
model execution time is usually much worse in such use cases.
This feature is a simplified version of execution graph as it provides much less information, but it might be more suitable for quick analysis and some kind of processing with scripts.
Performance counters can be retrieved from each InferenceEngine::InferRequest
object using getPerformanceCounts()
method. This feature is also integrated
into benchmark_app
and the counters can be printed to cout using -pc
parameter.
The format looks as follows:
${layer_name} ${exec_status} layerType: ${type} realTime: ${device_time} cpu: ${host_time} execType: ${kernel_name}
Total time: ${sum_of_device_times} microseconds
For example:
convolution EXECUTED layerType: Convolution realTime: 500 cpu: 3 execType: convolution_gpu_bfyx_os_iyx_osv16
relu OPTIMIZED_OUT layerType: ReLU realTime: 0 cpu: 0 execType: undef
Total time: 53877 microseconds
So it allows to quickly check execution time of some operation on the device and make sure that correct primitive is used. Also, the output can be easily converted into .csv format and then used to collect any kind of statistics (e.g. execution time distribution by layer types).
intel_gpu plugin allows to dump some info about intermediate stages in graph optimizer.
-
You can dump graphs with
OV_GPU_DumpGraphs
of debug config. For the usage of debug config, please see above section. -
Alternative, you can also enable the dumps from the application source code: clDNN plugin has the special internal config option
graph_dumps_dir
which can be set from the user app via plugin config:
Core ie;
std::map<std::string, std::string> device_config;
device_config[CLDNN_CONFIG_KEY(GRAPH_DUMPS_DIR)] = "/some/existing/path/";
ie.SetConfig(device_config, "GPU");
- or it can be specified inside the plugin with the following plugin recompilation:
// inference-engine/src/cldnn_engine/cldnn_engine.cpp
ExecutableNetworkInternal::Ptr clDNNEngine::LoadExeNetworkImpl(const InferenceEngine::ICNNNetwork &network,
const std::map<std::string, std::string> &config) {
CLDNNPlugin::Config conf = _impl->m_config;
conf.UpdateFromMap(config);
conf.graph_dumps_dir = "/some/existing/path/";
}
Note: if the app uses RemoteContext, then the second approach must be implemented in another LoadExeNetworkImpl
version.
For each stage it dumps:
- cldnn_program_${program_id}_${stage_id}_${stage_name}.graph - graph saved in dot format which can be visualized via graphviz tool
- cldnn_program_${program_id}_${stage_id}_${stage_name}.info - graph in text format
- cldnn_program_${program_id}_${stage_id}_${stage_name}.optimized - the list of nodes optimized out up to this stage
- cldnn_program_${program_id}_${stage_id}_${stage_name}.order - processing order in text format
- ${program_id}_${stage_id}_${stage_name}.xml - graph in a format of execution graph
Main graph usually has program_id = 0
, graphs with other program_id
values are usually created internally for constant propagation or some other purposes.
Since intel_gpu source tree contains only templates of the OpenCL™ kernels, it's quite important to get full kernels source code.
-
With debug_config, you can use
OV_GPU_DumpSources
option. -
How to enable the dumps from source code: clDNN plugin has the special internal config option
sources_dumps_dir
which can be set from the user app via plugin config:
Core ie;
std::map<std::string, std::string> device_config;
device_config[CLDNN_CONFIG_KEY(SOURCES_DUMPS_DIR)] = "/some/existing/path/";
ie.SetConfig(device_config, "GPU");
or it can be specified inside the plugin with the following plugin recompilation:
// inference-engine/src/cldnn_engine/cldnn_engine.cpp
ExecutableNetworkInternal::Ptr clDNNEngine::LoadExeNetworkImpl(const InferenceEngine::ICNNNetwork &network,
const std::map<std::string, std::string> &config) {
CLDNNPlugin::Config conf = _impl->m_config;
conf.UpdateFromMap(config);
conf.sources_dumps_dir = "/some/existing/path/";
}
Note: if the app uses RemoteContext, then the second approach must be implemented in another LoadExeNetworkImpl
version.
When this key is enabled, the plugin dumps multiple files with the following names:
clDNN_program_${program_id}_part_${bucket_id}.cl
Note: program_id
here might differ from program_id
for the graph dumps as it's just a static counter for enumerating incoming programs.
Each file contains a bucket of kernels that are compiled together. In case of any compilation errors, intel_gpu plugin will append compiler output in the end of corresponding source file.
If you want to find some specific layer, then you'll need to use Debug/RelWithDebInfo build or modify base jitter method to append LayerID
in release build:
// inference-engine/thirdparty/clDNN/kernel_selector/core/kernel_base.cpp
JitConstants KernelBase::MakeBaseParamsJitConstants(const base_params& params) const {
// ...
#ifndef NDEBUG <--- should be removed
jit.AddConstant(MakeJitConstant("LayerID", params.layerID));
#endif
}
When source is dumped, it actually contains huge amount of macros(#define
). For readability, you can run c preprocessor to apply the macros.
$ cpp dumped_source.cl > clean_source.cl
In some cases you might want to get actual values in each layer execution to compare it with some reference blob. In order to do that we have
OV_GPU_DumpLayersPath
option in debug config:
# As a prerequisite, enable ENABLE_DEBUG_CAPS from cmake configuration.
export OV_GPU_DumpLayersPath=path/to/dir
export OV_GPU_DumpLayers="layer_name_to_dump1 layer_name_to_dump2"
export OV_GPU_DumpLayersDstOnly=1 # Set as 1 when you want to dump dest buff only
Dump files have the following naming:
${layer_name_with_underscores}_${src/dst}_${port_id}.txt
Each file contains single buffer in common planar format (bfyx
, bfzyx
or bfwzyx
) where each value is stored on a separate line. The first line in the file constains buffer description, e.g:
shape: [b:1, f:1280, x:1, y:1, z:1, w:1, g:1] (count: 1280, original format: b_fs_yx_fsv16)
As gen9 hw doesn't have hardware acceleration, low precision transformations are disabled by default, thus quantized networks are executed in full precision (fp16 or fp32) with explicit execution of quantize operations. If you don't have gen12 HW, but want to debug network's accuracy or performance of simple operations (which doesn't require dp4a support), then you can enable low precision pipeline on gen9 using one of the following ways:
- Add
{PluginConfigInternalParams::KEY_LP_TRANSFORMS_MODE, PluginConfigParams::YES}
option to the plugin config - Enforce
supports_imad = true
here - Enforce
conf.enableInt8 = true
here
After that the plugin will run exactly the same scope of transformations as on gen12HW and generate similar kernels (small difference is possible due to different EUs count)
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