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249 lines
8.0 KiB
Markdown
249 lines
8.0 KiB
Markdown
# Compilation Artifacts
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In this tutorial, we are going to go over the artifact system, which is designed to inspect/debug the compilation process easily.
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## Automatic export
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In case of compilation failures, artifacts are exported automatically to `.artifacts` directory under the working directory. Let's intentionally create a compilation failure and show what kinds of things are exported.
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<!--python-test:skip-->
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```python
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def f(x):
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return np.sin(x)
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```
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This function fails to compile because **Concrete Framework** doesn't support floating point outputs. When you try to compile it (you might want to check [this](../basics/compiling_and_executing.md) to see how you can do that), an exception will be raised and the artifacts will be exported automatically.
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### environment.txt
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This file contains information about your setup (i.e., your operating system and python version).
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```
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Linux-5.12.13-arch1-2-x86_64-with-glibc2.29 #1 SMP PREEMPT Fri, 25 Jun 2021 22:56:51 +0000
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Python 3.8.10
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```
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### requirements.txt
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This file contains information about python packages and their versions installed on your system.
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```
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alabaster==0.7.12
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appdirs==1.4.4
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argon2-cffi==21.1.0
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...
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wheel==0.37.0
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widgetsnbextension==3.5.1
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wrapt==1.12.1
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```
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### function.txt
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This file contains information about the function you are trying to compile.
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```
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def f(x):
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return np.sin(x)
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```
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### parameters.txt
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This file contains information about the parameters of the function you are trying to compile.
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```
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x :: EncryptedScalar<Integer<unsigned, 3 bits>>
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```
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### 1.initial.graph.txt
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This file contains textual representation of the initial computation graph right after tracing.
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```
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%0 = x # EncryptedScalar<uint3>
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%1 = sin(%0) # EncryptedScalar<float64>
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return %1
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```
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### 1.initial.graph.png
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This file contains the visual representation of the initial computation graph right after tracing.
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### 2.final.graph.txt
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This file contains textual representation of the final computation graph right before MLIR conversion.
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```
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%0 = x # EncryptedScalar<uint3>
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%1 = sin(%0) # EncryptedScalar<float64>
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return %1
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```
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### 2.final.graph.png
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This file contains the visual representation of the final computation graph right before MLIR conversion.
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### traceback.txt
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This file contains information about the error you got.
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```
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Traceback (most recent call last):
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File "/home/default/Documents/Projects/Zama/hdk/concrete/numpy/compile.py", line 141, in run_compilation_function_with_error_management
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return compilation_function()
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File "/home/default/Documents/Projects/Zama/hdk/concrete/numpy/compile.py", line 769, in compilation_function
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return _compile_numpy_function_internal(
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File "/home/default/Documents/Projects/Zama/hdk/concrete/numpy/compile.py", line 722, in _compile_numpy_function_internal
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fhe_circuit = _compile_op_graph_to_fhe_circuit_internal(
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File "/home/default/Documents/Projects/Zama/hdk/concrete/numpy/compile.py", line 626, in _compile_op_graph_to_fhe_circuit_internal
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prepare_op_graph_for_mlir(op_graph)
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File "/home/default/Documents/Projects/Zama/hdk/concrete/numpy/compile.py", line 597, in prepare_op_graph_for_mlir
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raise RuntimeError(
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RuntimeError: function you are trying to compile isn't supported for MLIR lowering
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%0 = x # EncryptedScalar<uint3>
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%1 = sin(%0) # EncryptedScalar<float64>
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ only integer outputs are supported
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return %1
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```
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## Manual export
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Manual exports are mostly used for visualization. Nonetheless, they can be very useful for demonstrations. Here is how to do it:
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```python
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import concrete.numpy as hnp
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import numpy as np
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import pathlib
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def f(x):
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return 127 - (50 * (np.sin(x) + 1)).astype(np.uint32)
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artifacts = hnp.CompilationArtifacts(pathlib.Path("/tmp/custom/export/path"))
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compiler = hnp.NPFHECompiler(f, {"x": "encrypted"}, compilation_artifacts=artifacts)
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compiler.compile_on_inputset(range(2 ** 3))
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artifacts.export()
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```
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### 1.initial.graph.txt
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This file contains textual representation of the initial computation graph right after tracing.
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```
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%0 = 127 # ClearScalar<uint7>
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%1 = 50 # ClearScalar<uint6>
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%2 = 1 # ClearScalar<uint1>
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%3 = x # EncryptedScalar<uint3>
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%4 = sin(%3) # EncryptedScalar<float64>
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%5 = add(%4, %2) # EncryptedScalar<float64>
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%6 = mul(%5, %1) # EncryptedScalar<float64>
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%7 = astype(%6, dtype=uint32) # EncryptedScalar<uint32>
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%8 = sub(%0, %7) # EncryptedScalar<uint32>
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return %8
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```
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### 1.initial.graph.png
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This file contains the visual representation of the initial computation graph right after tracing.
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### 2.after-float-fuse-0.graph.txt
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This file contains textual representation of the intermediate computation graph after fusing.
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```
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%0 = 127 # ClearScalar<uint7>
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%1 = x # EncryptedScalar<uint3>
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%2 = subgraph(%1) # EncryptedScalar<uint32>
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%3 = sub(%0, %2) # EncryptedScalar<uint32>
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return %3
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Subgraphs:
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%2 = subgraph(%1):
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%0 = 50 # ClearScalar<uint6>
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%1 = 1 # ClearScalar<uint1>
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%2 = float_subgraph_input # EncryptedScalar<uint3>
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%3 = sin(%2) # EncryptedScalar<float64>
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%4 = add(%3, %1) # EncryptedScalar<float64>
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%5 = mul(%4, %0) # EncryptedScalar<float64>
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%6 = astype(%5, dtype=uint32) # EncryptedScalar<uint32>
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return %6
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```
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### 2.after-float-fuse-0.graph.png
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This file contains the visual representation of the intermediate computation graph after fusing.
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### 3.final.graph.txt
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This file contains textual representation of the final computation graph right before MLIR conversion.
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```
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%0 = 127 # ClearScalar<uint7>
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%1 = x # EncryptedScalar<uint3>
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%2 = subgraph(%1) # EncryptedScalar<uint7>
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%3 = sub(%0, %2) # EncryptedScalar<uint7>
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return %3
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Subgraphs:
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%2 = subgraph(%1):
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%0 = 50 # ClearScalar<uint6>
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%1 = 1 # ClearScalar<uint1>
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%2 = float_subgraph_input # EncryptedScalar<uint3>
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%3 = sin(%2) # EncryptedScalar<float64>
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%4 = add(%3, %1) # EncryptedScalar<float64>
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%5 = mul(%4, %0) # EncryptedScalar<float64>
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%6 = astype(%5, dtype=uint32) # EncryptedScalar<uint7>
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return %6
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```
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### 3.final.graph.png
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This file contains the visual representation of the final computation graph right before MLIR conversion.
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### bounds.txt
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This file contains information about the bounds of the final computation graph of the function you are trying to compile using the input set you provide.
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```
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%0 :: [127, 127]
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%1 :: [0, 7]
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%2 :: [2, 95]
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%3 :: [32, 125]
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```
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You can learn what bounds are [here](../../dev/explanation/terminology_and_structure.md).
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### mlir.txt
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This file contains information about the MLIR of the function you are trying to compile using the input set you provide.
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```
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module {
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func @main(%arg0: !HLFHE.eint<7>) -> !HLFHE.eint<7> {
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%c127_i8 = arith.constant 127 : i8
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%cst = arith.constant dense<"..."> : tensor<128xi64>
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%0 = "HLFHE.apply_lookup_table"(%arg0, %cst) : (!HLFHE.eint<7>, tensor<128xi64>) -> !HLFHE.eint<7>
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%1 = "HLFHE.sub_int_eint"(%c127_i8, %0) : (i8, !HLFHE.eint<7>) -> !HLFHE.eint<7>
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return %1 : !HLFHE.eint<7>
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}
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}
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```
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You can learn more about MLIR [here](../../dev/explanation/mlir.md).
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