Summary:
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/2916
Overall better support for binary indexes:
- cloning (to CPU and GPU), only for BinaryFlat for now
- fix bug in reconstruct_n
- range_search_max_results
Reviewed By: algoriddle
Differential Revision: D46755778
fbshipit-source-id: 777ad90aff5c54a77f9685ed6512247a922c6ef5
Summary:
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/2860
Optimized range search function where the GPU computes by default and falls back on gpu for queries where there are too many results.
Parallelize the CPU to GPU cloning, it seems to work.
Support range_search_preassigned in Python
Fix long-standing issue with SWIG exposed functions that did not release the GIL (in particular the MapLong2Long).
Adds a MapInt64ToInt64 that is more efficient than MapLong2Long.
Reviewed By: algoriddle
Differential Revision: D45672301
fbshipit-source-id: 2e77397c40083818584dbafa5427149359a2abfd
Summary:
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/1972
This fixes a few issues that I ran into + adds tests:
- range_search_max_results with IP search
- a few missing downcasts for VectorTRansforms
- ResultHeap supports max IP search
Reviewed By: wickedfoo
Differential Revision: D29525093
fbshipit-source-id: d4ff0aff1d83af9717ff1aaa2fe3cda7b53019a3
Summary: For range search evaluation, this diff adds optimized functions for ground-truth generation (on GPU).
Reviewed By: beauby
Differential Revision: D25822716
fbshipit-source-id: c5278dfad0510d24c2a5c87c1f8c81161fa8c5d3
Summary:
Added a few functions in contrib to:
- run range searches by batches on the query or the database side
- emulate range search on GPU: search on GPU with k=1024, if the farthest neighbor is still within range, re-perform search on CPU
- as reference implementations for precision-recall on range search datasets
- optimized code to plot precision-recall plots (ie. sweep over thresholds)
The new functions are mainly in a new `evaluation.py`
Reviewed By: wickedfoo
Differential Revision: D25627619
fbshipit-source-id: 58f90654c32c925557d7bbf8083efbb710712e03
Summary:
IndexPQ and IndexIVFPQ implementations with AVX shuffle instructions.
The training and computing of the codes does not change wrt. the original PQ versions but the code layout is "packed" so that it can be used efficiently by the SIMD computation kernels.
The main changes are:
- new IndexPQFastScan and IndexIVFPQFastScan objects
- simdib.h for an abstraction above the AVX2 intrinsics
- BlockInvertedLists for invlists that are 32-byte aligned and where codes are not sequential
- pq4_fast_scan.h/.cpp: for packing codes and look-up tables + optmized distance comptuation kernels
- simd_result_hander.h: SIMD version of result collection in heaps / reservoirs
Misc changes:
- added contrib.inspect_tools to access fields in C++ objects
- moved .h and .cpp code for inverted lists to an invlists/ subdirectory, and made a .h/.cpp for InvertedListsIOHook
- added a new inverted lists type with 32-byte aligned codes (for consumption by SIMD)
- moved Windows-specific intrinsics to platfrom_macros.h
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/1542
Test Plan:
```
buck test mode/opt -j 4 //faiss/tests/:test_fast_scan_ivf //faiss/tests/:test_fast_scan
buck test mode/opt //faiss/manifold/...
```
Reviewed By: wickedfoo
Differential Revision: D25175439
Pulled By: mdouze
fbshipit-source-id: ad1a40c0df8c10f4b364bdec7172e43d71b56c34
Summary:
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/1484
This diff allows for native usage of PyTorch tensors for Faiss indexes on both CPU and GPU. It is currently only implemented in this diff for things that inherit from `faiss.Index`, which covers the non-binary indices, and it patches the same functions on `faiss.Index` that were also covered by `__init__.py` for numpy interoperability.
There must be uniformity among the inputs: if any array input is a Torch tensor, then all array inputs must be Torch tensors. Similarly, if any array input is a numpy ndarray, then all array inputs must be numpy ndarrays.
If `faiss.contrib.torch_utils` is imported, it ensures that `import faiss` has already been performed to patch all of the functions using the base `__init__.py` numpy wrappers, and then patches the following functions again:
```
add
add_with_ids
assign
train
search
remove_ids
reconstruct
reconstruct_n
range_search
update_vectors
search_and_reconstruct
sa_encode
sa_decode
```
to allow usage of PyTorch CPU tensors, and additionally PyTorch GPU tensors if the index being used is on the GPU.
numpy functionality is still available when `faiss.contrib.torch_utils` is imported; we pass through to the original patched numpy function when we detect numpy inputs.
In addition, to allow for better (asynchronous) GPU usage without requiring the CPU to be involved, all of these functions which construct tensors/arrays for output now take optional arguments for storage (numpy or torch.Tensor) to be provided that will contain the output data. `range_search` is the only exception to this, as the size of the output data is indeterminate. The eventual GPU implementation will likely require the user to provide a maximum cap on the output size, and allow that to be passed instead. If the optional pre-allocated output values are presented by the user, they are used; otherwise, new return ndarray / Tensors are constructed as before and used for the return. If this feature were not provided on the GPU, then every execution would be completely serial as we would depend upon the CPU to allocate GPU memory before every operation. Instead, now this can function much like NN graph execution on the GPU, assuming that all of the data requirements are pre-allocated, so the execution will run at the full speed of the GPU and not be stalled sequentially launching kernels.
This diff also exposes the `GpuResources` shared_ptr object owned by a GPU index. This is required for pytorch GPU so that we can perform proper stream ordering in Faiss with respect to the current pytorch stream. So, Faiss indices now perform more or less as any NN operation in Torch does.
Note, however, that a Faiss index has its own setting on current device, and if the pytorch GPU tensor inputs are resident on a different device than what the Faiss index expects, a cross-device copy will be initiated. I may choose to make this an error in the future and require matching device to device.
This diff also found a bug when passing GPU data directly to `train()` for `GpuIndexIVFFlat` and `GpuIndexIVFScalarQuantizer`, as I guess we never tested passing GPU data directly to these functions before. `GpuIndexIVFPQ` was doing the right thing however.
The assign function is now also implemented on the GPU as well, and is now marked `const` to be in line with the `search` function.
Also added better checking of non-contiguous inputs for both Torch tensors and numpy ndarrays.
Updated the `knn_gpu` function with a base implementation always present that allows for usage of numpy arrays, which is overridden when `torch_utils` is imported to allow torch usage. This supports row/column major layout, float32/float16 data and int64/int32 indices for both numpy and torch.
Reviewed By: mdouze
Differential Revision: D24299400
fbshipit-source-id: b4f117b9c120bd1ad83e7702087051ab7b303b29
Summary:
Removed an unused function that caused compile errors in some configurations.
Added contrib function (exhaustive_search.knn) to compute the k nearest neighbors without constructing an index.
Renamed the equivalent GPU function as exhaustive_search.knn_gpu (it does not make much sense to mention numpy in the name as all functions take numpy arguments by default).
Reviewed By: beauby
Differential Revision: D24215427
fbshipit-source-id: 6d8e1eafa7c57593304b7b76f83b3015e4d2a2bb
Summary:
Pull Request resolved: https://github.com/facebookresearch/faiss/pull/1445
As requested in https://github.com/facebookresearch/faiss/issues/1304, `bfKnn` can now produce int32 indices for output.
The native kernels themselves for brute-force kNN only operate on int32 indices in any case, so this is faster.
Also added a SWIG definition for float16 numpy arrays. As there is not a native half type, the reverse definition is undefined, so this is only really used for taking float16 data (e.g., from numpy) as input when in Python.
Added a `knn_numpy_gpu` wrapper as well that handles calling the `bfKnn` GPU implementation using CPU numpy arrays. This handles transposition and f32/f16/i32 data types as needed.
Reviewed By: mdouze
Differential Revision: D24152296
fbshipit-source-id: caa7daea23438cf26aa248e380f0dab2b6b907fd
Matthijs Douze
Iurii Makarov
Matthijs Douze
Lucas Hosseini
Jeff Johnson