/* automatically generated by rust-bindgen 0.70.1 */
pub type faiss_idx_t = i64;
pub type idx_t = faiss_idx_t;
#[repr(i32)]
#[non_exhaustive]
#[doc = " An error code which depends on the exception thrown from the previous\n operation. See `faiss_get_last_error` to retrieve the error message."]
#[derive(Debug, Copy, Clone, Hash, PartialEq, Eq)]
pub enum FaissErrorCode {
#[doc = " No error"]
OK = 0,
#[doc = " Any exception other than Faiss or standard C++ library exceptions"]
UNKNOWN_EXCEPT = -1,
#[doc = " Faiss library exception"]
FAISS_EXCEPT = -2,
#[doc = " Standard C++ library exception"]
STD_EXCEPT = -4,
}
extern "C" {
#[doc = " Get the error message of the last failed operation performed by Faiss.\n The given pointer is only invalid until another Faiss function is\n called."]
pub fn faiss_get_last_error() -> *const ::std::os::raw::c_char;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissRangeSearchResult_H {
_unused: [u8; 0],
}
pub type FaissRangeSearchResult = FaissRangeSearchResult_H;
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelector_H {
_unused: [u8; 0],
}
#[doc = " Encapsulates a set of ids to remove."]
pub type FaissIDSelector = FaissIDSelector_H;
#[repr(i32)]
#[non_exhaustive]
#[doc = " Some algorithms support both an inner product version and a L2 search\n version."]
#[derive(Debug, Copy, Clone, Hash, PartialEq, Eq)]
pub enum FaissMetricType {
#[doc = "< maximum inner product search"]
METRIC_INNER_PRODUCT = 0,
#[doc = "< squared L2 search"]
METRIC_L2 = 1,
#[doc = "< L1 (aka cityblock)"]
METRIC_L1 = 2,
#[doc = "< infinity distance"]
METRIC_Linf = 3,
#[doc = "< L_p distance, p is given by metric_arg"]
METRIC_Lp = 4,
#[doc = " some additional metrics defined in scipy.spatial.distance"]
METRIC_Canberra = 20,
#[doc = " some additional metrics defined in scipy.spatial.distance"]
METRIC_BrayCurtis = 21,
#[doc = " some additional metrics defined in scipy.spatial.distance"]
METRIC_JensenShannon = 22,
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissSearchParameters_H {
_unused: [u8; 0],
}
pub type FaissSearchParameters = FaissSearchParameters_H;
extern "C" {
pub fn faiss_SearchParameters_free(obj: *mut FaissSearchParameters);
}
extern "C" {
pub fn faiss_SearchParameters_new(
p_sp: *mut *mut FaissSearchParameters,
sel: *mut FaissIDSelector,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIndex_H {
_unused: [u8; 0],
}
#[doc = " Opaque type for referencing to an index object"]
pub type FaissIndex = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for referencing to an index object"]
pub fn faiss_Index_free(obj: *mut FaissIndex);
}
extern "C" {
#[doc = " Getter for d"]
pub fn faiss_Index_d(arg1: *const FaissIndex) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for is_trained"]
pub fn faiss_Index_is_trained(arg1: *const FaissIndex) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for ntotal"]
pub fn faiss_Index_ntotal(arg1: *const FaissIndex) -> idx_t;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_Index_metric_type(arg1: *const FaissIndex) -> FaissMetricType;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_Index_verbose(arg1: *const FaissIndex) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_Index_set_verbose(arg1: *mut FaissIndex, arg2: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Perform training on a representative set of vectors\n\n @param index opaque pointer to index object\n @param n nb of training vectors\n @param x training vectors, size n * d"]
pub fn faiss_Index_train(
index: *mut FaissIndex,
n: idx_t,
x: *const f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Add n vectors of dimension d to the index.\n\n Vectors are implicitly assigned labels ntotal .. ntotal + n - 1\n This function slices the input vectors in chunks smaller than\n blocksize_add and calls add_core.\n @param index opaque pointer to index object\n @param x input matrix, size n * d"]
pub fn faiss_Index_add(
index: *mut FaissIndex,
n: idx_t,
x: *const f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Same as add, but stores xids instead of sequential ids.\n\n The default implementation fails with an assertion, as it is\n not supported by all indexes.\n\n @param index opaque pointer to index object\n @param xids if non-null, ids to store for the vectors (size n)"]
pub fn faiss_Index_add_with_ids(
index: *mut FaissIndex,
n: idx_t,
x: *const f32,
xids: *const idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d to the index.\n\n return at most k vectors. If there are not enough results for a\n query, the result array is padded with -1s.\n\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param labels output labels of the NNs, size n*k\n @param distances output pairwise distances, size n*k"]
pub fn faiss_Index_search(
index: *const FaissIndex,
n: idx_t,
x: *const f32,
k: idx_t,
distances: *mut f32,
labels: *mut idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d with search parameters to the index.\n\n return at most k vectors. If there are not enough results for a query,\n the result is padded with -1s.\n\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param params input params to modify how search is done\n @param labels output labels of the NNs, size n*k\n @param distances output pairwise distances, size n*k"]
pub fn faiss_Index_search_with_params(
index: *const FaissIndex,
n: idx_t,
x: *const f32,
k: idx_t,
params: *const FaissSearchParameters,
distances: *mut f32,
labels: *mut idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d to the index.\n\n return all vectors with distance < radius. Note that many\n indexes do not implement the range_search (only the k-NN search\n is mandatory).\n\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param radius search radius\n @param result result table"]
pub fn faiss_Index_range_search(
index: *const FaissIndex,
n: idx_t,
x: *const f32,
radius: f32,
result: *mut FaissRangeSearchResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " return the indexes of the k vectors closest to the query x.\n\n This function is identical as search but only return labels of neighbors.\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param labels output labels of the NNs, size n*k"]
pub fn faiss_Index_assign(
index: *mut FaissIndex,
n: idx_t,
x: *const f32,
labels: *mut idx_t,
k: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " removes all elements from the database.\n @param index opaque pointer to index object"]
pub fn faiss_Index_reset(index: *mut FaissIndex) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " removes IDs from the index. Not supported by all indexes\n @param index opaque pointer to index object\n @param nremove output for the number of IDs removed"]
pub fn faiss_Index_remove_ids(
index: *mut FaissIndex,
sel: *const FaissIDSelector,
n_removed: *mut usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Reconstruct a stored vector (or an approximation if lossy coding)\n\n this function may not be defined for some indexes\n @param index opaque pointer to index object\n @param key id of the vector to reconstruct\n @param recons reconstructed vector (size d)"]
pub fn faiss_Index_reconstruct(
index: *const FaissIndex,
key: idx_t,
recons: *mut f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Reconstruct vectors i0 to i0 + ni - 1\n\n this function may not be defined for some indexes\n @param index opaque pointer to index object\n @param recons reconstructed vector (size ni * d)"]
pub fn faiss_Index_reconstruct_n(
index: *const FaissIndex,
i0: idx_t,
ni: idx_t,
recons: *mut f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Computes a residual vector after indexing encoding.\n\n The residual vector is the difference between a vector and the\n reconstruction that can be decoded from its representation in\n the index. The residual can be used for multiple-stage indexing\n methods, like IndexIVF's methods.\n\n @param index opaque pointer to index object\n @param x input vector, size d\n @param residual output residual vector, size d\n @param key encoded index, as returned by search and assign"]
pub fn faiss_Index_compute_residual(
index: *const FaissIndex,
x: *const f32,
residual: *mut f32,
key: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Computes a residual vector after indexing encoding.\n\n The residual vector is the difference between a vector and the\n reconstruction that can be decoded from its representation in\n the index. The residual can be used for multiple-stage indexing\n methods, like IndexIVF's methods.\n\n @param index opaque pointer to index object\n @param n number of vectors\n @param x input vector, size (n x d)\n @param residuals output residual vectors, size (n x d)\n @param keys encoded index, as returned by search and assign"]
pub fn faiss_Index_compute_residual_n(
index: *const FaissIndex,
n: idx_t,
x: *const f32,
residuals: *mut f32,
keys: *const idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " The size of the produced codes in bytes.\n\n @param index opaque pointer to index object\n @param size the returned size in bytes"]
pub fn faiss_Index_sa_code_size(
index: *const FaissIndex,
size: *mut usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " encode a set of vectors\n\n @param index opaque pointer to index object\n @param n number of vectors\n @param x input vectors, size n * d\n @param bytes output encoded vectors, size n * sa_code_size()"]
pub fn faiss_Index_sa_encode(
index: *const FaissIndex,
n: idx_t,
x: *const f32,
bytes: *mut u8,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " decode a set of vectors\n\n @param index opaque pointer to index object\n @param n number of vectors\n @param bytes input encoded vectors, size n * sa_code_size()\n @param x output vectors, size n * d"]
pub fn faiss_Index_sa_decode(
index: *const FaissIndex,
n: idx_t,
bytes: *const u8,
x: *mut f32,
) -> ::std::os::raw::c_int;
}
#[doc = " Opaque type for IndexFlat"]
pub type FaissIndexFlat = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexFlat"]
pub fn faiss_IndexFlat_new(p_index: *mut *mut FaissIndexFlat) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexFlat_new_with(
p_index: *mut *mut FaissIndexFlat,
d: idx_t,
metric: FaissMetricType,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " get a pointer to the index's internal data (the `xb` field). The outputs\n become invalid after any data addition or removal operation.\n\n @param index opaque pointer to index object\n @param p_xb output, the pointer to the beginning of `xb`.\n @param p_size output, the current size of `xb` in number of float values."]
pub fn faiss_IndexFlat_xb(index: *mut FaissIndexFlat, p_xb: *mut *mut f32, p_size: *mut usize);
}
extern "C" {
#[doc = " attempt a dynamic cast to a flat index, thus checking\n check whether the underlying index type is `IndexFlat`.\n\n @param index opaque pointer to index object\n @return the same pointer if the index is a flat index, NULL otherwise"]
pub fn faiss_IndexFlat_cast(arg1: *mut FaissIndex) -> *mut FaissIndexFlat;
}
extern "C" {
#[doc = " attempt a dynamic cast to a flat index, thus checking\n check whether the underlying index type is `IndexFlat`.\n\n @param index opaque pointer to index object\n @return the same pointer if the index is a flat index, NULL otherwise"]
pub fn faiss_IndexFlat_free(obj: *mut FaissIndexFlat);
}
extern "C" {
#[doc = " compute distance with a subset of vectors\n\n @param index opaque pointer to index object\n @param x query vectors, size n * d\n @param labels indices of the vectors that should be compared\n for each query vector, size n * k\n @param distances\n corresponding output distances, size n * k"]
pub fn faiss_IndexFlat_compute_distance_subset(
index: *mut FaissIndex,
n: idx_t,
x: *const f32,
k: idx_t,
distances: *mut f32,
labels: *const idx_t,
) -> ::std::os::raw::c_int;
}
#[doc = " Opaque type for IndexFlatIP"]
pub type FaissIndexFlatIP = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexFlatIP"]
pub fn faiss_IndexFlatIP_cast(arg1: *mut FaissIndex) -> *mut FaissIndexFlatIP;
}
extern "C" {
#[doc = " Opaque type for IndexFlatIP"]
pub fn faiss_IndexFlatIP_free(obj: *mut FaissIndexFlatIP);
}
extern "C" {
#[doc = " Opaque type for IndexFlatIP"]
pub fn faiss_IndexFlatIP_new(p_index: *mut *mut FaissIndexFlatIP) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexFlatIP_new_with(
p_index: *mut *mut FaissIndexFlatIP,
d: idx_t,
) -> ::std::os::raw::c_int;
}
#[doc = " Opaque type for IndexFlatL2"]
pub type FaissIndexFlatL2 = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexFlatL2"]
pub fn faiss_IndexFlatL2_cast(arg1: *mut FaissIndex) -> *mut FaissIndexFlatL2;
}
extern "C" {
#[doc = " Opaque type for IndexFlatL2"]
pub fn faiss_IndexFlatL2_free(obj: *mut FaissIndexFlatL2);
}
extern "C" {
#[doc = " Opaque type for IndexFlatL2"]
pub fn faiss_IndexFlatL2_new(p_index: *mut *mut FaissIndexFlatL2) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexFlatL2_new_with(
p_index: *mut *mut FaissIndexFlatL2,
d: idx_t,
) -> ::std::os::raw::c_int;
}
#[doc = " Opaque type for IndexRefineFlat\n\n Index that queries in a base_index (a fast one) and refines the\n results with an exact search, hopefully improving the results."]
pub type FaissIndexRefineFlat = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexRefineFlat\n\n Index that queries in a base_index (a fast one) and refines the\n results with an exact search, hopefully improving the results."]
pub fn faiss_IndexRefineFlat_new(
p_index: *mut *mut FaissIndexRefineFlat,
base_index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexRefineFlat_free(obj: *mut FaissIndexRefineFlat);
}
extern "C" {
pub fn faiss_IndexRefineFlat_cast(arg1: *mut FaissIndex) -> *mut FaissIndexRefineFlat;
}
extern "C" {
pub fn faiss_IndexRefineFlat_own_fields(
arg1: *const FaissIndexRefineFlat,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexRefineFlat_set_own_fields(
arg1: *mut FaissIndexRefineFlat,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " factor between k requested in search and the k requested from\n the base_index (should be >= 1)"]
pub fn faiss_IndexRefineFlat_k_factor(arg1: *const FaissIndexRefineFlat) -> f32;
}
extern "C" {
#[doc = " factor between k requested in search and the k requested from\n the base_index (should be >= 1)"]
pub fn faiss_IndexRefineFlat_set_k_factor(arg1: *mut FaissIndexRefineFlat, arg2: f32);
}
#[doc = " Opaque type for IndexFlat1D\n\n optimized version for 1D \"vectors\""]
pub type FaissIndexFlat1D = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexFlat1D\n\n optimized version for 1D \"vectors\""]
pub fn faiss_IndexFlat1D_cast(arg1: *mut FaissIndex) -> *mut FaissIndexFlat1D;
}
extern "C" {
#[doc = " Opaque type for IndexFlat1D\n\n optimized version for 1D \"vectors\""]
pub fn faiss_IndexFlat1D_free(obj: *mut FaissIndexFlat1D);
}
extern "C" {
#[doc = " Opaque type for IndexFlat1D\n\n optimized version for 1D \"vectors\""]
pub fn faiss_IndexFlat1D_new(p_index: *mut *mut FaissIndexFlat1D) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexFlat1D_new_with(
p_index: *mut *mut FaissIndexFlat1D,
continuous_update: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexFlat1D_update_permutation(
index: *mut FaissIndexFlat1D,
) -> ::std::os::raw::c_int;
}
#[doc = " Class for the clustering parameters. Can be passed to the\n constructor of the Clustering object."]
#[repr(C)]
#[derive(Debug, Default, Copy, Clone)]
pub struct FaissClusteringParameters {
#[doc = "< clustering iterations"]
pub niter: ::std::os::raw::c_int,
#[doc = "< redo clustering this many times and keep best"]
pub nredo: ::std::os::raw::c_int,
#[doc = "< (bool)"]
pub verbose: ::std::os::raw::c_int,
#[doc = "< (bool) do we want normalized centroids?"]
pub spherical: ::std::os::raw::c_int,
#[doc = "< (bool) round centroids coordinates to integer"]
pub int_centroids: ::std::os::raw::c_int,
#[doc = "< (bool) update index after each iteration?"]
pub update_index: ::std::os::raw::c_int,
#[doc = "< (bool) use the centroids provided as input and do\n< not change them during iterations"]
pub frozen_centroids: ::std::os::raw::c_int,
#[doc = "< otherwise you get a warning"]
pub min_points_per_centroid: ::std::os::raw::c_int,
#[doc = "< to limit size of dataset"]
pub max_points_per_centroid: ::std::os::raw::c_int,
#[doc = "< seed for the random number generator"]
pub seed: ::std::os::raw::c_int,
#[doc = "< how many vectors at a time to decode"]
pub decode_block_size: usize,
}
extern "C" {
#[doc = " Sets the ClusteringParameters object with reasonable defaults"]
pub fn faiss_ClusteringParameters_init(params: *mut FaissClusteringParameters);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissClustering_H {
_unused: [u8; 0],
}
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub type FaissClustering = FaissClustering_H;
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_niter(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_nredo(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_verbose(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_spherical(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_int_centroids(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_update_index(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_frozen_centroids(arg1: *const FaissClustering)
-> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_min_points_per_centroid(
arg1: *const FaissClustering,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_max_points_per_centroid(
arg1: *const FaissClustering,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_seed(arg1: *const FaissClustering) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " clustering based on assignment - centroid update iterations\n\n The clustering is based on an Index object that assigns training\n points to the centroids. Therefore, at each iteration the centroids\n are added to the index.\n\n On output, the centroids table is set to the latest version\n of the centroids and they are also added to the index. If the\n centroids table it is not empty on input, it is also used for\n initialization.\n\n To do several clusterings, just call train() several times on\n different training sets, clearing the centroid table in between."]
pub fn faiss_Clustering_decode_block_size(arg1: *const FaissClustering) -> usize;
}
extern "C" {
#[doc = " getter for d"]
pub fn faiss_Clustering_d(arg1: *const FaissClustering) -> usize;
}
extern "C" {
#[doc = " getter for k"]
pub fn faiss_Clustering_k(arg1: *const FaissClustering) -> usize;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissClusteringIterationStats_H {
_unused: [u8; 0],
}
#[doc = " getter for k"]
pub type FaissClusteringIterationStats = FaissClusteringIterationStats_H;
extern "C" {
#[doc = " getter for k"]
pub fn faiss_ClusteringIterationStats_obj(arg1: *const FaissClusteringIterationStats) -> f32;
}
extern "C" {
#[doc = " getter for k"]
pub fn faiss_ClusteringIterationStats_time(arg1: *const FaissClusteringIterationStats) -> f64;
}
extern "C" {
#[doc = " getter for k"]
pub fn faiss_ClusteringIterationStats_time_search(
arg1: *const FaissClusteringIterationStats,
) -> f64;
}
extern "C" {
#[doc = " getter for k"]
pub fn faiss_ClusteringIterationStats_imbalance_factor(
arg1: *const FaissClusteringIterationStats,
) -> f64;
}
extern "C" {
#[doc = " getter for k"]
pub fn faiss_ClusteringIterationStats_nsplit(
arg1: *const FaissClusteringIterationStats,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " getter for centroids (size = k * d)"]
pub fn faiss_Clustering_centroids(
clustering: *mut FaissClustering,
centroids: *mut *mut f32,
size: *mut usize,
);
}
extern "C" {
#[doc = " getter for iteration stats"]
pub fn faiss_Clustering_iteration_stats(
clustering: *mut FaissClustering,
iteration_stats: *mut *mut FaissClusteringIterationStats,
size: *mut usize,
);
}
extern "C" {
#[doc = " the only mandatory parameters are k and d"]
pub fn faiss_Clustering_new(
p_clustering: *mut *mut FaissClustering,
d: ::std::os::raw::c_int,
k: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_Clustering_new_with_params(
p_clustering: *mut *mut FaissClustering,
d: ::std::os::raw::c_int,
k: ::std::os::raw::c_int,
cp: *const FaissClusteringParameters,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_Clustering_train(
clustering: *mut FaissClustering,
n: idx_t,
x: *const f32,
index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_Clustering_free(clustering: *mut FaissClustering);
}
extern "C" {
#[doc = " simplified interface\n\n @param d dimension of the data\n @param n nb of training vectors\n @param k nb of output centroids\n @param x training set (size n * d)\n @param centroids output centroids (size k * d)\n @param q_error final quantization error\n @return error code"]
pub fn faiss_kmeans_clustering(
d: usize,
n: usize,
k: usize,
x: *const f32,
centroids: *mut f32,
q_error: *mut f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchResult_nq(arg1: *const FaissRangeSearchResult) -> usize;
}
extern "C" {
pub fn faiss_RangeSearchResult_new(
p_rsr: *mut *mut FaissRangeSearchResult,
nq: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchResult_new_with(
p_rsr: *mut *mut FaissRangeSearchResult,
nq: idx_t,
alloc_lims: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " called when lims contains the nb of elements result entries\n for each query"]
pub fn faiss_RangeSearchResult_do_allocation(
rsr: *mut FaissRangeSearchResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchResult_free(obj: *mut FaissRangeSearchResult);
}
extern "C" {
#[doc = " getter for buffer_size"]
pub fn faiss_RangeSearchResult_buffer_size(arg1: *const FaissRangeSearchResult) -> usize;
}
extern "C" {
#[doc = " getter for lims: size (nq + 1)"]
pub fn faiss_RangeSearchResult_lims(rsr: *mut FaissRangeSearchResult, lims: *mut *mut usize);
}
extern "C" {
#[doc = " getter for labels and respective distances (not sorted):\n result for query i is labels[lims[i]:lims[i+1]]"]
pub fn faiss_RangeSearchResult_labels(
rsr: *mut FaissRangeSearchResult,
labels: *mut *mut idx_t,
distances: *mut *mut f32,
);
}
extern "C" {
#[doc = " Encapsulates a set of ids to remove."]
pub fn faiss_IDSelector_free(obj: *mut FaissIDSelector);
}
extern "C" {
#[doc = " Encapsulates a set of ids to remove."]
pub fn faiss_IDSelector_is_member(
sel: *const FaissIDSelector,
id: idx_t,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorRange_H {
_unused: [u8; 0],
}
#[doc = " remove ids between [imni, imax)"]
pub type FaissIDSelectorRange = FaissIDSelectorRange_H;
extern "C" {
#[doc = " remove ids between [imni, imax)"]
pub fn faiss_IDSelectorRange_free(obj: *mut FaissIDSelectorRange);
}
extern "C" {
#[doc = " remove ids between [imni, imax)"]
pub fn faiss_IDSelectorRange_imin(arg1: *const FaissIDSelectorRange) -> idx_t;
}
extern "C" {
#[doc = " remove ids between [imni, imax)"]
pub fn faiss_IDSelectorRange_imax(arg1: *const FaissIDSelectorRange) -> idx_t;
}
extern "C" {
#[doc = " remove ids between [imni, imax)"]
pub fn faiss_IDSelectorRange_new(
p_sel: *mut *mut FaissIDSelectorRange,
imin: idx_t,
imax: idx_t,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorBatch_H {
_unused: [u8; 0],
}
#[doc = " Remove ids from a set. Repetitions of ids in the indices set\n passed to the constructor does not hurt performance. The hash\n function used for the bloom filter and GCC's implementation of\n unordered_set are just the least significant bits of the id. This\n works fine for random ids or ids in sequences but will produce many\n hash collisions if lsb's are always the same"]
pub type FaissIDSelectorBatch = FaissIDSelectorBatch_H;
extern "C" {
#[doc = " Remove ids from a set. Repetitions of ids in the indices set\n passed to the constructor does not hurt performance. The hash\n function used for the bloom filter and GCC's implementation of\n unordered_set are just the least significant bits of the id. This\n works fine for random ids or ids in sequences but will produce many\n hash collisions if lsb's are always the same"]
pub fn faiss_IDSelectorBatch_nbits(arg1: *const FaissIDSelectorBatch) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Remove ids from a set. Repetitions of ids in the indices set\n passed to the constructor does not hurt performance. The hash\n function used for the bloom filter and GCC's implementation of\n unordered_set are just the least significant bits of the id. This\n works fine for random ids or ids in sequences but will produce many\n hash collisions if lsb's are always the same"]
pub fn faiss_IDSelectorBatch_mask(arg1: *const FaissIDSelectorBatch) -> idx_t;
}
extern "C" {
#[doc = " Remove ids from a set. Repetitions of ids in the indices set\n passed to the constructor does not hurt performance. The hash\n function used for the bloom filter and GCC's implementation of\n unordered_set are just the least significant bits of the id. This\n works fine for random ids or ids in sequences but will produce many\n hash collisions if lsb's are always the same"]
pub fn faiss_IDSelectorBatch_new(
p_sel: *mut *mut FaissIDSelectorBatch,
n: usize,
indices: *const idx_t,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorBitmap_H {
_unused: [u8; 0],
}
pub type FaissIDSelectorBitmap = FaissIDSelectorBitmap_H;
extern "C" {
pub fn faiss_IDSelectorBitmap_free(obj: *mut FaissIDSelectorBitmap);
}
extern "C" {
pub fn faiss_IDSelectorBitmap_n(arg1: *const FaissIDSelectorBitmap) -> usize;
}
extern "C" {
pub fn faiss_IDSelectorBitmap_bitmap(arg1: *const FaissIDSelectorBitmap) -> *const u8;
}
extern "C" {
pub fn faiss_IDSelectorBitmap_new(
p_sel: *mut *mut FaissIDSelectorBitmap,
n: usize,
bitmap: *const u8,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorNot_H {
_unused: [u8; 0],
}
pub type FaissIDSelectorNot = FaissIDSelectorNot_H;
extern "C" {
pub fn faiss_IDSelectorNot_new(
p_sel: *mut *mut FaissIDSelectorNot,
sel: *const FaissIDSelector,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorAnd_H {
_unused: [u8; 0],
}
pub type FaissIDSelectorAnd = FaissIDSelectorAnd_H;
extern "C" {
pub fn faiss_IDSelectorAnd_new(
p_sel: *mut *mut FaissIDSelectorAnd,
lhs_sel: *const FaissIDSelector,
rhs_sel: *const FaissIDSelector,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorOr_H {
_unused: [u8; 0],
}
pub type FaissIDSelectorOr = FaissIDSelectorOr_H;
extern "C" {
pub fn faiss_IDSelectorOr_new(
p_sel: *mut *mut FaissIDSelectorOr,
lhs_sel: *const FaissIDSelector,
rhs_sel: *const FaissIDSelector,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIDSelectorXOr_H {
_unused: [u8; 0],
}
pub type FaissIDSelectorXOr = FaissIDSelectorXOr_H;
extern "C" {
pub fn faiss_IDSelectorXOr_new(
p_sel: *mut *mut FaissIDSelectorXOr,
lhs_sel: *const FaissIDSelector,
rhs_sel: *const FaissIDSelector,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissBufferList_H {
_unused: [u8; 0],
}
#[doc = " List of temporary buffers used to store results before they are\n copied to the RangeSearchResult object."]
pub type FaissBufferList = FaissBufferList_H;
extern "C" {
#[doc = " List of temporary buffers used to store results before they are\n copied to the RangeSearchResult object."]
pub fn faiss_BufferList_free(obj: *mut FaissBufferList);
}
extern "C" {
#[doc = " List of temporary buffers used to store results before they are\n copied to the RangeSearchResult object."]
pub fn faiss_BufferList_buffer_size(arg1: *const FaissBufferList) -> usize;
}
extern "C" {
#[doc = " List of temporary buffers used to store results before they are\n copied to the RangeSearchResult object."]
pub fn faiss_BufferList_wp(arg1: *const FaissBufferList) -> usize;
}
#[doc = " List of temporary buffers used to store results before they are\n copied to the RangeSearchResult object."]
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissBuffer {
pub ids: *mut idx_t,
pub dis: *mut f32,
}
impl Default for FaissBuffer {
fn default() -> Self {
let mut s = ::std::mem::MaybeUninit::<Self>::uninit();
unsafe {
::std::ptr::write_bytes(s.as_mut_ptr(), 0, 1);
s.assume_init()
}
}
}
extern "C" {
pub fn faiss_BufferList_append_buffer(bl: *mut FaissBufferList) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_BufferList_new(
p_bl: *mut *mut FaissBufferList,
buffer_size: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_BufferList_add(
bl: *mut FaissBufferList,
id: idx_t,
dis: f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " copy elements ofs:ofs+n-1 seen as linear data in the buffers to\n tables dest_ids, dest_dis"]
pub fn faiss_BufferList_copy_range(
bl: *mut FaissBufferList,
ofs: usize,
n: usize,
dest_ids: *mut idx_t,
dest_dis: *mut f32,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissRangeSearchPartialResult_H {
_unused: [u8; 0],
}
#[doc = " the entries in the buffers are split per query"]
pub type FaissRangeSearchPartialResult = FaissRangeSearchPartialResult_H;
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissRangeQueryResult_H {
_unused: [u8; 0],
}
#[doc = " result structure for a single query"]
pub type FaissRangeQueryResult = FaissRangeQueryResult_H;
extern "C" {
#[doc = " result structure for a single query"]
pub fn faiss_RangeQueryResult_qno(arg1: *const FaissRangeQueryResult) -> idx_t;
}
extern "C" {
#[doc = " result structure for a single query"]
pub fn faiss_RangeQueryResult_nres(arg1: *const FaissRangeQueryResult) -> usize;
}
extern "C" {
#[doc = " result structure for a single query"]
pub fn faiss_RangeQueryResult_pres(
arg1: *const FaissRangeQueryResult,
) -> *mut FaissRangeSearchPartialResult;
}
extern "C" {
#[doc = " result structure for a single query"]
pub fn faiss_RangeQueryResult_add(
qr: *mut FaissRangeQueryResult,
dis: f32,
id: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchPartialResult_res(
arg1: *const FaissRangeSearchPartialResult,
) -> *mut FaissRangeSearchResult;
}
extern "C" {
pub fn faiss_RangeSearchPartialResult_new(
p_res: *mut *mut FaissRangeSearchPartialResult,
res_in: *mut FaissRangeSearchResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchPartialResult_finalize(
res: *mut FaissRangeSearchPartialResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " called by range_search before do_allocation"]
pub fn faiss_RangeSearchPartialResult_set_lims(
res: *mut FaissRangeSearchPartialResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_RangeSearchPartialResult_new_result(
res: *mut FaissRangeSearchPartialResult,
qno: idx_t,
qr: *mut *mut FaissRangeQueryResult,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissDistanceComputer_H {
_unused: [u8; 0],
}
pub type FaissDistanceComputer = FaissDistanceComputer_H;
extern "C" {
#[doc = " called before computing distances"]
pub fn faiss_DistanceComputer_set_query(
dc: *mut FaissDistanceComputer,
x: *const f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Compute distance of vector i to current query.\n This function corresponds to the function call operator:\n DistanceComputer::operator()"]
pub fn faiss_DistanceComputer_vector_to_query_dis(
dc: *mut FaissDistanceComputer,
i: idx_t,
qd: *mut f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " compute distance between two stored vectors"]
pub fn faiss_DistanceComputer_symmetric_dis(
dc: *mut FaissDistanceComputer,
i: idx_t,
j: idx_t,
vd: *mut f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_DistanceComputer_free(obj: *mut FaissDistanceComputer);
}
pub type FaissSearchParametersIVF = FaissSearchParameters_H;
extern "C" {
pub fn faiss_SearchParametersIVF_free(obj: *mut FaissSearchParametersIVF);
}
extern "C" {
pub fn faiss_SearchParametersIVF_cast(
arg1: *mut FaissSearchParameters,
) -> *mut FaissSearchParametersIVF;
}
extern "C" {
pub fn faiss_SearchParametersIVF_new(
p_sp: *mut *mut FaissSearchParametersIVF,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_SearchParametersIVF_new_with(
p_sp: *mut *mut FaissSearchParametersIVF,
sel: *mut FaissIDSelector,
nprobe: usize,
max_codes: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_SearchParametersIVF_sel(
arg1: *const FaissSearchParametersIVF,
) -> *const FaissIDSelector;
}
extern "C" {
pub fn faiss_SearchParametersIVF_nprobe(arg1: *const FaissSearchParametersIVF) -> usize;
}
extern "C" {
pub fn faiss_SearchParametersIVF_set_nprobe(arg1: *mut FaissSearchParametersIVF, arg2: usize);
}
extern "C" {
pub fn faiss_SearchParametersIVF_max_codes(arg1: *const FaissSearchParametersIVF) -> usize;
}
extern "C" {
pub fn faiss_SearchParametersIVF_set_max_codes(
arg1: *mut FaissSearchParametersIVF,
arg2: usize,
);
}
#[doc = " Index based on a inverted file (IVF)\n\n In the inverted file, the quantizer (an Index instance) provides a\n quantization index for each vector to be added. The quantization\n index maps to a list (aka inverted list or posting list), where the\n id of the vector is then stored.\n\n At search time, the vector to be searched is also quantized, and\n only the list corresponding to the quantization index is\n searched. This speeds up the search by making it\n non-exhaustive. This can be relaxed using multi-probe search: a few\n (nprobe) quantization indices are selected and several inverted\n lists are visited.\n\n Sub-classes implement a post-filtering of the index that refines\n the distance estimation from the query to database vectors."]
pub type FaissIndexIVF = FaissIndex_H;
extern "C" {
#[doc = " Index based on a inverted file (IVF)\n\n In the inverted file, the quantizer (an Index instance) provides a\n quantization index for each vector to be added. The quantization\n index maps to a list (aka inverted list or posting list), where the\n id of the vector is then stored.\n\n At search time, the vector to be searched is also quantized, and\n only the list corresponding to the quantization index is\n searched. This speeds up the search by making it\n non-exhaustive. This can be relaxed using multi-probe search: a few\n (nprobe) quantization indices are selected and several inverted\n lists are visited.\n\n Sub-classes implement a post-filtering of the index that refines\n the distance estimation from the query to database vectors."]
pub fn faiss_IndexIVF_free(obj: *mut FaissIndexIVF);
}
extern "C" {
#[doc = " Index based on a inverted file (IVF)\n\n In the inverted file, the quantizer (an Index instance) provides a\n quantization index for each vector to be added. The quantization\n index maps to a list (aka inverted list or posting list), where the\n id of the vector is then stored.\n\n At search time, the vector to be searched is also quantized, and\n only the list corresponding to the quantization index is\n searched. This speeds up the search by making it\n non-exhaustive. This can be relaxed using multi-probe search: a few\n (nprobe) quantization indices are selected and several inverted\n lists are visited.\n\n Sub-classes implement a post-filtering of the index that refines\n the distance estimation from the query to database vectors."]
pub fn faiss_IndexIVF_cast(arg1: *mut FaissIndex) -> *mut FaissIndexIVF;
}
extern "C" {
#[doc = " number of possible key values"]
pub fn faiss_IndexIVF_nlist(arg1: *const FaissIndexIVF) -> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVF_nprobe(arg1: *const FaissIndexIVF) -> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVF_set_nprobe(arg1: *mut FaissIndexIVF, arg2: usize);
}
extern "C" {
#[doc = " quantizer that maps vectors to inverted lists"]
pub fn faiss_IndexIVF_quantizer(arg1: *const FaissIndexIVF) -> *mut FaissIndex;
}
extern "C" {
#[doc = " = 0: use the quantizer as index in a kmeans training\n = 1: just pass on the training set to the train() of the quantizer\n = 2: kmeans training on a flat index + add the centroids to the quantizer"]
pub fn faiss_IndexIVF_quantizer_trains_alone(
arg1: *const FaissIndexIVF,
) -> ::std::os::raw::c_char;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVF_own_fields(arg1: *const FaissIndexIVF) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVF_set_own_fields(arg1: *mut FaissIndexIVF, arg2: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " moves the entries from another dataset to self. On output,\n other is empty. add_id is added to all moved ids (for\n sequential ids, this would be this->ntotal"]
pub fn faiss_IndexIVF_merge_from(
index: *mut FaissIndexIVF,
other: *mut FaissIndexIVF,
add_id: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " copy a subset of the entries index to the other index\n\n if subset_type == 0: copies ids in [a1, a2)\n if subset_type == 1: copies ids if id % a1 == a2\n if subset_type == 2: copies inverted lists such that a1\n elements are left before and a2 elements are after"]
pub fn faiss_IndexIVF_copy_subset_to(
index: *const FaissIndexIVF,
other: *mut FaissIndexIVF,
subset_type: ::std::os::raw::c_int,
a1: idx_t,
a2: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " search a set of vectors, that are pre-quantized by the IVF\n quantizer. Fill in the corresponding heaps with the query\n results. search() calls this.\n\n @param n nb of vectors to query\n @param x query vectors, size nx * d\n @param assign coarse quantization indices, size nx * nprobe\n @param centroid_dis\n distances to coarse centroids, size nx * nprobe\n @param distance\n output distances, size n * k\n @param labels output labels, size n * k\n @param store_pairs store inv list index + inv list offset\n instead in upper/lower 32 bit of result,\n instead of ids (used for reranking)."]
pub fn faiss_IndexIVF_search_preassigned(
index: *const FaissIndexIVF,
n: idx_t,
x: *const f32,
k: idx_t,
assign: *const idx_t,
centroid_dis: *const f32,
distances: *mut f32,
labels: *mut idx_t,
store_pairs: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVF_get_list_size(index: *const FaissIndexIVF, list_no: usize) -> usize;
}
extern "C" {
#[doc = " initialize a direct map\n\n @param new_maintain_direct_map if true, create a direct map,\n else clear it"]
pub fn faiss_IndexIVF_make_direct_map(
index: *mut FaissIndexIVF,
new_maintain_direct_map: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Check the inverted lists' imbalance factor.\n\n 1= perfectly balanced, >1: imbalanced"]
pub fn faiss_IndexIVF_imbalance_factor(index: *const FaissIndexIVF) -> f64;
}
extern "C" {
#[doc = " display some stats about the inverted lists of the index"]
pub fn faiss_IndexIVF_print_stats(index: *const FaissIndexIVF);
}
extern "C" {
#[doc = " Get the IDs in an inverted list. IDs are written to `invlist`, which must be\n large enough\n to accommodate the full list.\n\n @param list_no the list ID\n @param invlist output pointer to a slice of memory, at least as long as the\n list's size\n @see faiss_IndexIVF_get_list_size(size_t)"]
pub fn faiss_IndexIVF_invlists_get_ids(
index: *const FaissIndexIVF,
list_no: usize,
invlist: *mut idx_t,
);
}
extern "C" {
pub fn faiss_IndexIVF_train_encoder(
index: *mut FaissIndexIVF,
n: idx_t,
x: *const f32,
assign: *const idx_t,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Default, Copy, Clone)]
pub struct FaissIndexIVFStats {
pub nq: usize,
pub nlist: usize,
pub ndis: usize,
pub nheap_updates: usize,
pub quantization_time: f64,
pub search_time: f64,
}
extern "C" {
pub fn faiss_IndexIVFStats_reset(stats: *mut FaissIndexIVFStats);
}
extern "C" {
#[doc = " global var that collects all statistics"]
pub fn faiss_get_indexIVF_stats() -> *mut FaissIndexIVFStats;
}
#[doc = " Inverted file with stored vectors. Here the inverted file\n pre-selects the vectors to be searched, but they are not otherwise\n encoded, the code array just contains the raw float entries."]
pub type FaissIndexIVFFlat = FaissIndex_H;
extern "C" {
#[doc = " Inverted file with stored vectors. Here the inverted file\n pre-selects the vectors to be searched, but they are not otherwise\n encoded, the code array just contains the raw float entries."]
pub fn faiss_IndexIVFFlat_free(obj: *mut FaissIndexIVFFlat);
}
extern "C" {
#[doc = " Inverted file with stored vectors. Here the inverted file\n pre-selects the vectors to be searched, but they are not otherwise\n encoded, the code array just contains the raw float entries."]
pub fn faiss_IndexIVFFlat_cast(arg1: *mut FaissIndex) -> *mut FaissIndexIVFFlat;
}
extern "C" {
#[doc = " number of possible key values"]
pub fn faiss_IndexIVFFlat_nlist(arg1: *const FaissIndexIVFFlat) -> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVFFlat_nprobe(arg1: *const FaissIndexIVFFlat) -> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVFFlat_set_nprobe(arg1: *mut FaissIndexIVFFlat, arg2: usize);
}
extern "C" {
#[doc = " quantizer that maps vectors to inverted lists"]
pub fn faiss_IndexIVFFlat_quantizer(arg1: *const FaissIndexIVFFlat) -> *mut FaissIndex;
}
extern "C" {
#[doc = " = 0: use the quantizer as index in a kmeans training\n = 1: just pass on the training set to the train() of the quantizer\n = 2: kmeans training on a flat index + add the centroids to the quantizer"]
pub fn faiss_IndexIVFFlat_quantizer_trains_alone(
arg1: *const FaissIndexIVFFlat,
) -> ::std::os::raw::c_char;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFFlat_own_fields(arg1: *const FaissIndexIVFFlat) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFFlat_set_own_fields(
arg1: *mut FaissIndexIVFFlat,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFFlat_new(p_index: *mut *mut FaissIndexIVFFlat) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVFFlat_new_with(
p_index: *mut *mut FaissIndexIVFFlat,
quantizer: *mut FaissIndex,
d: usize,
nlist: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVFFlat_new_with_metric(
p_index: *mut *mut FaissIndexIVFFlat,
quantizer: *mut FaissIndex,
d: usize,
nlist: usize,
metric: FaissMetricType,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVFFlat_add_core(
index: *mut FaissIndexIVFFlat,
n: idx_t,
x: *const f32,
xids: *const idx_t,
precomputed_idx: *const i64,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Update a subset of vectors.\n\n The index must have a direct_map\n\n @param nv nb of vectors to update\n @param idx vector indices to update, size nv\n @param v vectors of new values, size nv*d"]
pub fn faiss_IndexIVFFlat_update_vectors(
index: *mut FaissIndexIVFFlat,
nv: ::std::os::raw::c_int,
idx: *mut idx_t,
v: *const f32,
) -> ::std::os::raw::c_int;
}
#[doc = " The sign of each vector component is put in a binary signature"]
pub type FaissIndexLSH = FaissIndex_H;
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_free(obj: *mut FaissIndexLSH);
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_cast(arg1: *mut FaissIndex) -> *mut FaissIndexLSH;
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_nbits(arg1: *const FaissIndexLSH) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_code_size(arg1: *const FaissIndexLSH) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_rotate_data(arg1: *const FaissIndexLSH) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_train_thresholds(arg1: *const FaissIndexLSH) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " The sign of each vector component is put in a binary signature"]
pub fn faiss_IndexLSH_new(
p_index: *mut *mut FaissIndexLSH,
d: idx_t,
nbits: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexLSH_new_with_options(
p_index: *mut *mut FaissIndexLSH,
d: idx_t,
nbits: ::std::os::raw::c_int,
rotate_data: ::std::os::raw::c_int,
train_thresholds: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIndexBinary_H {
_unused: [u8; 0],
}
#[doc = " Opaque type for referencing to a binary index object"]
pub type FaissIndexBinary = FaissIndexBinary_H;
extern "C" {
#[doc = " Opaque type for referencing to a binary index object"]
pub fn faiss_IndexBinary_free(obj: *mut FaissIndexBinary);
}
extern "C" {
#[doc = " Getter for d"]
pub fn faiss_IndexBinary_d(arg1: *const FaissIndexBinary) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for is_trained"]
pub fn faiss_IndexBinary_is_trained(arg1: *const FaissIndexBinary) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for ntotal"]
pub fn faiss_IndexBinary_ntotal(arg1: *const FaissIndexBinary) -> idx_t;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_IndexBinary_metric_type(arg1: *const FaissIndexBinary) -> FaissMetricType;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_IndexBinary_verbose(arg1: *const FaissIndexBinary) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for metric_type"]
pub fn faiss_IndexBinary_set_verbose(arg1: *mut FaissIndexBinary, arg2: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Perform training on a representative set of vectors\n\n @param index opaque pointer to index object\n @param n nb of training vectors\n @param x training vectors, size n * d"]
pub fn faiss_IndexBinary_train(
index: *mut FaissIndexBinary,
n: idx_t,
x: *const u8,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Add n vectors of dimension d to the index.\n\n Vectors are implicitly assigned labels ntotal .. ntotal + n - 1\n This function slices the input vectors in chunks smaller than\n blocksize_add and calls add_core.\n @param index opaque pointer to index object\n @param x input matrix, size n * d"]
pub fn faiss_IndexBinary_add(
index: *mut FaissIndexBinary,
n: idx_t,
x: *const u8,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Same as add, but stores xids instead of sequential ids.\n\n The default implementation fails with an assertion, as it is\n not supported by all indexes.\n\n @param index opaque pointer to index object\n @param xids if non-null, ids to store for the vectors (size n)"]
pub fn faiss_IndexBinary_add_with_ids(
index: *mut FaissIndexBinary,
n: idx_t,
x: *const u8,
xids: *const idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d to the index.\n\n return at most k vectors. If there are not enough results for a\n query, the result array is padded with -1s.\n\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param labels output labels of the NNs, size n*k\n @param distances output pairwise distances, size n*k"]
pub fn faiss_IndexBinary_search(
index: *const FaissIndexBinary,
n: idx_t,
x: *const u8,
k: idx_t,
distances: *mut i32,
labels: *mut idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d with search parameters to the index.\n\n return at most k vectors. If there are not enough results for a query,\n the result array is padded with -1s.\n\n @param index opaque pointer to index object\n @param n number of vectors\n @param x input vectors to search, size n * d\n @param k number of nearest neighbors\n @param params search parameters (can be NULL)\n @param distances output pairwise distances, size n*k\n @param labels output labels of the NNs, size n*k"]
pub fn faiss_IndexBinary_search_with_params(
index: *const FaissIndexBinary,
n: idx_t,
x: *const u8,
k: idx_t,
params: *const FaissSearchParameters,
distances: *mut i32,
labels: *mut idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " query n vectors of dimension d to the index.\n\n return all vectors with distance < radius. Note that many\n indexes do not implement the range_search (only the k-NN search\n is mandatory).\n\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param radius search radius\n @param result result table"]
pub fn faiss_IndexBinary_range_search(
index: *const FaissIndexBinary,
n: idx_t,
x: *const u8,
radius: ::std::os::raw::c_int,
result: *mut FaissRangeSearchResult,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " return the indexes of the k vectors closest to the query x.\n\n This function is identical as search but only return labels of neighbors.\n @param index opaque pointer to index object\n @param x input vectors to search, size n * d\n @param labels output labels of the NNs, size n*k"]
pub fn faiss_IndexBinary_assign(
index: *mut FaissIndexBinary,
n: idx_t,
x: *const u8,
labels: *mut idx_t,
k: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " removes all elements from the database.\n @param index opaque pointer to index object"]
pub fn faiss_IndexBinary_reset(index: *mut FaissIndexBinary) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " removes IDs from the index. Not supported by all indexes\n @param index opaque pointer to index object\n @param nremove output for the number of IDs removed"]
pub fn faiss_IndexBinary_remove_ids(
index: *mut FaissIndexBinary,
sel: *const FaissIDSelector,
n_removed: *mut usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Reconstruct a stored vector (or an approximation if lossy coding)\n\n this function may not be defined for some indexes\n @param index opaque pointer to index object\n @param key id of the vector to reconstruct\n @param recons reconstructed vector (size d)"]
pub fn faiss_IndexBinary_reconstruct(
index: *const FaissIndexBinary,
key: idx_t,
recons: *mut u8,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Reconstruct vectors i0 to i0 + ni - 1\n\n this function may not be defined for some indexes\n @param index opaque pointer to index object\n @param recons reconstructed vector (size ni * d)"]
pub fn faiss_IndexBinary_reconstruct_n(
index: *const FaissIndexBinary,
i0: idx_t,
ni: idx_t,
recons: *mut u8,
) -> ::std::os::raw::c_int;
}
#[repr(i32)]
#[non_exhaustive]
#[derive(Debug, Copy, Clone, Hash, PartialEq, Eq)]
pub enum FaissQuantizerType {
#[doc = "< 8 bits per component"]
QT_8bit = 0,
#[doc = "< 4 bits per component"]
QT_4bit = 1,
#[doc = "< same, shared range for all dimensions"]
QT_8bit_uniform = 2,
QT_4bit_uniform = 3,
QT_fp16 = 4,
#[doc = "< fast indexing of uint8s"]
QT_8bit_direct = 5,
#[doc = "< 6 bits per component"]
QT_6bit = 6,
QT_bf16 = 7,
#[doc = "< fast indexing of signed int8s ranging from [-128\n< to 127]"]
QT_8bit_direct_signed = 8,
}
#[doc = " Opaque type for IndexScalarQuantizer"]
pub type FaissIndexScalarQuantizer = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexScalarQuantizer"]
pub fn faiss_IndexScalarQuantizer_new(
p_index: *mut *mut FaissIndexScalarQuantizer,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexScalarQuantizer_new_with(
p_index: *mut *mut FaissIndexScalarQuantizer,
d: idx_t,
qt: FaissQuantizerType,
metric: FaissMetricType,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexScalarQuantizer_cast(arg1: *mut FaissIndex)
-> *mut FaissIndexScalarQuantizer;
}
extern "C" {
pub fn faiss_IndexScalarQuantizer_free(obj: *mut FaissIndexScalarQuantizer);
}
#[doc = " Opaque type for IndexIVFScalarQuantizer"]
pub type FaissIndexIVFScalarQuantizer = FaissIndex_H;
extern "C" {
#[doc = " Opaque type for IndexIVFScalarQuantizer"]
pub fn faiss_IndexIVFScalarQuantizer_cast(
arg1: *mut FaissIndex,
) -> *mut FaissIndexIVFScalarQuantizer;
}
extern "C" {
#[doc = " Opaque type for IndexIVFScalarQuantizer"]
pub fn faiss_IndexIVFScalarQuantizer_free(obj: *mut FaissIndexIVFScalarQuantizer);
}
extern "C" {
#[doc = " Opaque type for IndexIVFScalarQuantizer"]
pub fn faiss_IndexIVFScalarQuantizer_new(
p_index: *mut *mut FaissIndexIVFScalarQuantizer,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVFScalarQuantizer_new_with(
p_index: *mut *mut FaissIndexIVFScalarQuantizer,
quantizer: *mut FaissIndex,
d: idx_t,
nlist: usize,
qt: FaissQuantizerType,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexIVFScalarQuantizer_new_with_metric(
p_index: *mut *mut FaissIndexIVFScalarQuantizer,
quantizer: *mut FaissIndex,
d: usize,
nlist: usize,
qt: FaissQuantizerType,
metric: FaissMetricType,
encode_residual: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " number of possible key values"]
pub fn faiss_IndexIVFScalarQuantizer_nlist(arg1: *const FaissIndexIVFScalarQuantizer) -> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVFScalarQuantizer_nprobe(arg1: *const FaissIndexIVFScalarQuantizer)
-> usize;
}
extern "C" {
#[doc = " number of probes at query time"]
pub fn faiss_IndexIVFScalarQuantizer_set_nprobe(
arg1: *mut FaissIndexIVFScalarQuantizer,
arg2: usize,
);
}
extern "C" {
#[doc = " quantizer that maps vectors to inverted lists"]
pub fn faiss_IndexIVFScalarQuantizer_quantizer(
arg1: *const FaissIndexIVFScalarQuantizer,
) -> *mut FaissIndex;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFScalarQuantizer_own_fields(
arg1: *const FaissIndexIVFScalarQuantizer,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFScalarQuantizer_set_own_fields(
arg1: *mut FaissIndexIVFScalarQuantizer,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " whether object owns the quantizer"]
pub fn faiss_IndexIVFScalarQuantizer_add_core(
index: *mut FaissIndexIVFScalarQuantizer,
n: idx_t,
x: *const f32,
xids: *const idx_t,
precomputed_idx: *const idx_t,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissVectorTransform_H {
_unused: [u8; 0],
}
#[doc = " Opaque type for referencing to a VectorTransform object"]
pub type FaissVectorTransform = FaissVectorTransform_H;
extern "C" {
#[doc = " Opaque type for referencing to a VectorTransform object"]
pub fn faiss_VectorTransform_free(obj: *mut FaissVectorTransform);
}
extern "C" {
#[doc = " Getter for is_trained"]
pub fn faiss_VectorTransform_is_trained(
arg1: *const FaissVectorTransform,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for input dimension"]
pub fn faiss_VectorTransform_d_in(arg1: *const FaissVectorTransform) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for output dimension"]
pub fn faiss_VectorTransform_d_out(arg1: *const FaissVectorTransform) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Perform training on a representative set of vectors\n\n @param vt opaque pointer to VectorTransform object\n @param n nb of training vectors\n @param x training vectors, size n * d"]
pub fn faiss_VectorTransform_train(
vt: *mut FaissVectorTransform,
n: idx_t,
x: *const f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " apply the random rotation, return new allocated matrix\n @param x size n * d_in\n @return size n * d_out"]
pub fn faiss_VectorTransform_apply(
vt: *const FaissVectorTransform,
n: idx_t,
x: *const f32,
) -> *mut f32;
}
extern "C" {
#[doc = " apply transformation and result is pre-allocated\n @param x size n * d_in\n @param xt size n * d_out"]
pub fn faiss_VectorTransform_apply_noalloc(
vt: *const FaissVectorTransform,
n: idx_t,
x: *const f32,
xt: *mut f32,
);
}
extern "C" {
#[doc = " reverse transformation. May not be implemented or may return\n approximate result"]
pub fn faiss_VectorTransform_reverse_transform(
vt: *const FaissVectorTransform,
n: idx_t,
xt: *const f32,
x: *mut f32,
);
}
#[doc = " Opaque type for referencing to a LinearTransform object"]
pub type FaissLinearTransform = FaissVectorTransform_H;
extern "C" {
#[doc = " Opaque type for referencing to a LinearTransform object"]
pub fn faiss_LinearTransform_free(obj: *mut FaissLinearTransform);
}
extern "C" {
#[doc = " compute x = A^T * (x - b)\n is reverse transform if A has orthonormal lines"]
pub fn faiss_LinearTransform_transform_transpose(
vt: *const FaissLinearTransform,
n: idx_t,
y: *const f32,
x: *mut f32,
);
}
extern "C" {
#[doc = " compute A^T * A to set the is_orthonormal flag"]
pub fn faiss_LinearTransform_set_is_orthonormal(vt: *mut FaissLinearTransform);
}
extern "C" {
#[doc = " Getter for have_bias"]
pub fn faiss_LinearTransform_have_bias(
arg1: *const FaissLinearTransform,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for is_orthonormal"]
pub fn faiss_LinearTransform_is_orthonormal(
arg1: *const FaissLinearTransform,
) -> ::std::os::raw::c_int;
}
#[doc = " Getter for is_orthonormal"]
pub type FaissRandomRotationMatrix = FaissVectorTransform_H;
extern "C" {
#[doc = " Getter for is_orthonormal"]
pub fn faiss_RandomRotationMatrix_free(obj: *mut FaissRandomRotationMatrix);
}
extern "C" {
#[doc = " Getter for is_orthonormal"]
pub fn faiss_RandomRotationMatrix_new_with(
p_vt: *mut *mut FaissRandomRotationMatrix,
d_in: ::std::os::raw::c_int,
d_out: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
pub type FaissPCAMatrix = FaissVectorTransform_H;
extern "C" {
pub fn faiss_PCAMatrix_free(obj: *mut FaissPCAMatrix);
}
extern "C" {
pub fn faiss_PCAMatrix_new_with(
p_vt: *mut *mut FaissPCAMatrix,
d_in: ::std::os::raw::c_int,
d_out: ::std::os::raw::c_int,
eigen_power: f32,
random_rotation: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for eigen_power"]
pub fn faiss_PCAMatrix_eigen_power(arg1: *const FaissPCAMatrix) -> f32;
}
extern "C" {
#[doc = " Getter for random_rotation"]
pub fn faiss_PCAMatrix_random_rotation(arg1: *const FaissPCAMatrix) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for balanced_bins"]
pub fn faiss_PCAMatrix_balanced_bins(arg1: *const FaissPCAMatrix) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Setter for balanced_bins"]
pub fn faiss_PCAMatrix_set_balanced_bins(
arg1: *mut FaissPCAMatrix,
arg2: ::std::os::raw::c_int,
);
}
#[doc = " Setter for balanced_bins"]
pub type FaissITQMatrix = FaissVectorTransform_H;
extern "C" {
#[doc = " Setter for balanced_bins"]
pub fn faiss_ITQMatrix_free(obj: *mut FaissITQMatrix);
}
extern "C" {
#[doc = " Setter for balanced_bins"]
pub fn faiss_ITQMatrix_new_with(
p_vt: *mut *mut FaissITQMatrix,
d: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
pub type FaissITQTransform = FaissVectorTransform_H;
extern "C" {
pub fn faiss_ITQTransform_free(obj: *mut FaissITQTransform);
}
extern "C" {
pub fn faiss_ITQTransform_new_with(
p_vt: *mut *mut FaissITQTransform,
d_in: ::std::os::raw::c_int,
d_out: ::std::os::raw::c_int,
do_pca: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Getter for do_pca"]
pub fn faiss_ITQTransform_do_pca(arg1: *const FaissITQTransform) -> ::std::os::raw::c_int;
}
#[doc = " Getter for do_pca"]
pub type FaissOPQMatrix = FaissVectorTransform_H;
extern "C" {
#[doc = " Getter for do_pca"]
pub fn faiss_OPQMatrix_free(obj: *mut FaissOPQMatrix);
}
extern "C" {
#[doc = " Getter for do_pca"]
pub fn faiss_OPQMatrix_new_with(
p_vt: *mut *mut FaissOPQMatrix,
d: ::std::os::raw::c_int,
M: ::std::os::raw::c_int,
d2: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_OPQMatrix_verbose(arg1: *const FaissOPQMatrix) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_OPQMatrix_set_verbose(arg1: *mut FaissOPQMatrix, arg2: ::std::os::raw::c_int);
}
extern "C" {
pub fn faiss_OPQMatrix_niter(arg1: *const FaissOPQMatrix) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_OPQMatrix_set_niter(arg1: *mut FaissOPQMatrix, arg2: ::std::os::raw::c_int);
}
extern "C" {
pub fn faiss_OPQMatrix_niter_pq(arg1: *const FaissOPQMatrix) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_OPQMatrix_set_niter_pq(arg1: *mut FaissOPQMatrix, arg2: ::std::os::raw::c_int);
}
pub type FaissRemapDimensionsTransform = FaissVectorTransform_H;
extern "C" {
pub fn faiss_RemapDimensionsTransform_free(obj: *mut FaissRemapDimensionsTransform);
}
extern "C" {
pub fn faiss_RemapDimensionsTransform_new_with(
p_vt: *mut *mut FaissRemapDimensionsTransform,
d_in: ::std::os::raw::c_int,
d_out: ::std::os::raw::c_int,
uniform: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
pub type FaissNormalizationTransform = FaissVectorTransform_H;
extern "C" {
pub fn faiss_NormalizationTransform_free(obj: *mut FaissNormalizationTransform);
}
extern "C" {
pub fn faiss_NormalizationTransform_new_with(
p_vt: *mut *mut FaissNormalizationTransform,
d: ::std::os::raw::c_int,
norm: f32,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_NormalizationTransform_norm(arg1: *const FaissNormalizationTransform) -> f32;
}
pub type FaissCenteringTransform = FaissVectorTransform_H;
extern "C" {
pub fn faiss_CenteringTransform_free(obj: *mut FaissCenteringTransform);
}
extern "C" {
pub fn faiss_CenteringTransform_new_with(
p_vt: *mut *mut FaissCenteringTransform,
d: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub type FaissIndexPreTransform = FaissIndex_H;
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_free(obj: *mut FaissIndexPreTransform);
}
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_cast(arg1: *mut FaissIndex) -> *mut FaissIndexPreTransform;
}
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_index(arg1: *const FaissIndexPreTransform) -> *mut FaissIndex;
}
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_own_fields(
arg1: *const FaissIndexPreTransform,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_set_own_fields(
arg1: *mut FaissIndexPreTransform,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " Index that applies a LinearTransform transform on vectors before\n handing them over to a sub-index"]
pub fn faiss_IndexPreTransform_new(
p_index: *mut *mut FaissIndexPreTransform,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexPreTransform_new_with(
p_index: *mut *mut FaissIndexPreTransform,
index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexPreTransform_new_with_transform(
p_index: *mut *mut FaissIndexPreTransform,
ltrans: *mut FaissVectorTransform,
index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexPreTransform_prepend_transform(
index: *mut FaissIndexPreTransform,
ltrans: *mut FaissVectorTransform,
) -> ::std::os::raw::c_int;
}
#[doc = " Index that concatenates the results from several sub-indexes"]
pub type FaissIndexReplicas = FaissIndex_H;
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexReplicas_free(obj: *mut FaissIndexReplicas);
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexReplicas_own_fields(arg1: *const FaissIndexReplicas)
-> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexReplicas_set_own_fields(
arg1: *mut FaissIndexReplicas,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexReplicas_new(
p_index: *mut *mut FaissIndexReplicas,
d: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexReplicas_new_with_options(
p_index: *mut *mut FaissIndexReplicas,
d: idx_t,
threaded: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexReplicas_add_replica(
index: *mut FaissIndexReplicas,
replica: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexReplicas_remove_replica(
index: *mut FaissIndexReplicas,
replica: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexReplicas_at(
index: *mut FaissIndexReplicas,
i: ::std::os::raw::c_int,
) -> *mut FaissIndex;
}
#[doc = " Index that concatenates the results from several sub-indexes"]
pub type FaissIndexShards = FaissIndex_H;
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_free(obj: *mut FaissIndexShards);
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_own_fields(arg1: *const FaissIndexShards) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_set_own_fields(
arg1: *mut FaissIndexShards,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_successive_ids(arg1: *const FaissIndexShards)
-> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_set_successive_ids(
arg1: *mut FaissIndexShards,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " Index that concatenates the results from several sub-indexes"]
pub fn faiss_IndexShards_new(
p_index: *mut *mut FaissIndexShards,
d: idx_t,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexShards_new_with_options(
p_index: *mut *mut FaissIndexShards,
d: idx_t,
threaded: ::std::os::raw::c_int,
successive_ids: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexShards_add_shard(
index: *mut FaissIndexShards,
shard: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexShards_remove_shard(
index: *mut FaissIndexShards,
shard: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
pub fn faiss_IndexShards_at(
index: *mut FaissIndexShards,
i: ::std::os::raw::c_int,
) -> *mut FaissIndex;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissParameterRange_H {
_unused: [u8; 0],
}
#[doc = " possible values of a parameter, sorted from least to most expensive/accurate"]
pub type FaissParameterRange = FaissParameterRange_H;
extern "C" {
#[doc = " possible values of a parameter, sorted from least to most expensive/accurate"]
pub fn faiss_ParameterRange_name(
arg1: *const FaissParameterRange,
) -> *const ::std::os::raw::c_char;
}
extern "C" {
#[doc = " Getter for the values in the range. The output values are invalidated\n upon any other modification of the range."]
pub fn faiss_ParameterRange_values(
arg1: *mut FaissParameterRange,
arg2: *mut *mut f64,
arg3: *mut usize,
);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissParameterSpace_H {
_unused: [u8; 0],
}
#[doc = " Uses a-priori knowledge on the Faiss indexes to extract tunable parameters."]
pub type FaissParameterSpace = FaissParameterSpace_H;
extern "C" {
#[doc = " Uses a-priori knowledge on the Faiss indexes to extract tunable parameters."]
pub fn faiss_ParameterSpace_free(obj: *mut FaissParameterSpace);
}
extern "C" {
#[doc = " Parameter space default constructor"]
pub fn faiss_ParameterSpace_new(space: *mut *mut FaissParameterSpace) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " nb of combinations, = product of values sizes"]
pub fn faiss_ParameterSpace_n_combinations(arg1: *const FaissParameterSpace) -> usize;
}
extern "C" {
#[doc = " get string representation of the combination\n by writing it to the given character buffer.\n A buffer size of 1000 ensures that the full name is collected."]
pub fn faiss_ParameterSpace_combination_name(
arg1: *const FaissParameterSpace,
arg2: usize,
arg3: *mut ::std::os::raw::c_char,
arg4: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set a combination of parameters described by a string"]
pub fn faiss_ParameterSpace_set_index_parameters(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndex,
arg3: *const ::std::os::raw::c_char,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set a combination of parameters on an index"]
pub fn faiss_ParameterSpace_set_index_parameters_cno(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndex,
arg3: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set a combination of parameters described by a string on a binary index"]
pub fn faiss_ParameterSpace_set_index_parameters_binary(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndexBinary,
arg3: *const ::std::os::raw::c_char,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set a combination of parameters on a binary index"]
pub fn faiss_ParameterSpace_set_index_parameters_cno_binary(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndexBinary,
arg3: usize,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set one of the parameters"]
pub fn faiss_ParameterSpace_set_index_parameter(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndex,
arg3: *const ::std::os::raw::c_char,
arg4: f64,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " set one of the parameters for a binary index"]
pub fn faiss_ParameterSpace_set_index_parameter_binary(
arg1: *const FaissParameterSpace,
arg2: *mut FaissIndexBinary,
arg3: *const ::std::os::raw::c_char,
arg4: f64,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " print a description on stdout"]
pub fn faiss_ParameterSpace_display(arg1: *const FaissParameterSpace);
}
extern "C" {
#[doc = " add a new parameter (or return it if it exists)"]
pub fn faiss_ParameterSpace_add_range(
arg1: *mut FaissParameterSpace,
arg2: *const ::std::os::raw::c_char,
arg3: *mut *mut FaissParameterRange,
) -> ::std::os::raw::c_int;
}
pub type FILE = u64;
extern "C" {
#[doc = " Clone an index. This is equivalent to `faiss::clone_index`"]
pub fn faiss_clone_index(
arg1: *const FaissIndex,
p_out: *mut *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Clone a binary index. This is equivalent to `faiss::clone_index_binary`"]
pub fn faiss_clone_index_binary(
arg1: *const FaissIndexBinary,
p_out: *mut *mut FaissIndexBinary,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Build an index with the sequence of processing steps described in\n the string."]
pub fn faiss_index_factory(
p_index: *mut *mut FaissIndex,
d: ::std::os::raw::c_int,
description: *const ::std::os::raw::c_char,
metric: FaissMetricType,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Build a binary index with the sequence of processing steps described in\n the string."]
pub fn faiss_index_binary_factory(
p_index: *mut *mut FaissIndexBinary,
d: ::std::os::raw::c_int,
description: *const ::std::os::raw::c_char,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIOReader_H {
_unused: [u8; 0],
}
pub type FaissIOReader = FaissIOReader_H;
extern "C" {
pub fn faiss_IOReader_free(obj: *mut FaissIOReader);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissIOWriter_H {
_unused: [u8; 0],
}
pub type FaissIOWriter = FaissIOWriter_H;
extern "C" {
pub fn faiss_IOWriter_free(obj: *mut FaissIOWriter);
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissCustomIOReader_H {
_unused: [u8; 0],
}
#[doc = " Custom reader + writer\n\n Reader and writer which wraps a function pointer,\n primarily for FFI use."]
pub type FaissCustomIOReader = FaissCustomIOReader_H;
extern "C" {
#[doc = " Custom reader + writer\n\n Reader and writer which wraps a function pointer,\n primarily for FFI use."]
pub fn faiss_CustomIOReader_free(obj: *mut FaissCustomIOReader);
}
extern "C" {
#[doc = " Custom reader + writer\n\n Reader and writer which wraps a function pointer,\n primarily for FFI use."]
pub fn faiss_CustomIOReader_new(
p_out: *mut *mut FaissCustomIOReader,
func_in: ::std::option::Option<
unsafe extern "C" fn(
ptr: *mut ::std::os::raw::c_void,
size: usize,
nitems: usize,
) -> usize,
>,
) -> ::std::os::raw::c_int;
}
#[repr(C)]
#[derive(Debug, Copy, Clone)]
pub struct FaissCustomIOWriter_H {
_unused: [u8; 0],
}
pub type FaissCustomIOWriter = FaissCustomIOWriter_H;
extern "C" {
pub fn faiss_CustomIOWriter_free(obj: *mut FaissCustomIOWriter);
}
extern "C" {
pub fn faiss_CustomIOWriter_new(
p_out: *mut *mut FaissCustomIOWriter,
func_in: ::std::option::Option<
unsafe extern "C" fn(
ptr: *const ::std::os::raw::c_void,
size: usize,
nitems: usize,
) -> usize,
>,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write index to a file.\n This is equivalent to `faiss::write_index` when a file descriptor is\n provided."]
pub fn faiss_write_index(idx: *const FaissIndex, f: *mut FILE) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write index to a file.\n This is equivalent to `faiss::write_index` when a file path is provided."]
pub fn faiss_write_index_fname(
idx: *const FaissIndex,
fname: *const ::std::os::raw::c_char,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write index to a custom writer."]
pub fn faiss_write_index_custom(
idx: *const FaissIndex,
io_writer: *mut FaissIOWriter,
io_flags: ::std::os::raw::c_int,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read index from a file.\n This is equivalent to `faiss:read_index` when a file descriptor is given."]
pub fn faiss_read_index(
f: *mut FILE,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read index from a file.\n This is equivalent to `faiss:read_index` when a file path is given."]
pub fn faiss_read_index_fname(
fname: *const ::std::os::raw::c_char,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read index from a custom reader."]
pub fn faiss_read_index_custom(
io_reader: *mut FaissIOReader,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write index to a file.\n This is equivalent to `faiss::write_index_binary` when a file descriptor is\n provided."]
pub fn faiss_write_index_binary(
idx: *const FaissIndexBinary,
f: *mut FILE,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write index to a file.\n This is equivalent to `faiss::write_index_binary` when a file path is\n provided."]
pub fn faiss_write_index_binary_fname(
idx: *const FaissIndexBinary,
fname: *const ::std::os::raw::c_char,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Write binary index to a custom writer."]
pub fn faiss_write_index_binary_custom(
idx: *const FaissIndexBinary,
io_writer: *mut FaissIOWriter,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read index from a file.\n This is equivalent to `faiss:read_index_binary` when a file descriptor is\n given."]
pub fn faiss_read_index_binary(
f: *mut FILE,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndexBinary,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read index from a file.\n This is equivalent to `faiss:read_index_binary` when a file path is given."]
pub fn faiss_read_index_binary_fname(
fname: *const ::std::os::raw::c_char,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndexBinary,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read binary index from a custom reader."]
pub fn faiss_read_index_binary_custom(
io_reader: *mut FaissIOReader,
io_flags: ::std::os::raw::c_int,
p_out: *mut *mut FaissIndexBinary,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Read vector transform from a file.\n This is equivalent to `faiss:read_VectorTransform` when a file path is given."]
pub fn faiss_read_VectorTransform_fname(
fname: *const ::std::os::raw::c_char,
p_out: *mut *mut FaissVectorTransform,
) -> ::std::os::raw::c_int;
}
#[doc = " Index that translates search results to ids"]
pub type FaissIndexIDMap = FaissIndex_H;
extern "C" {
#[doc = " Index that translates search results to ids"]
pub fn faiss_IndexIDMap_own_fields(arg1: *const FaissIndexIDMap) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Index that translates search results to ids"]
pub fn faiss_IndexIDMap_set_own_fields(arg1: *mut FaissIndexIDMap, arg2: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Index that translates search results to ids"]
pub fn faiss_IndexIDMap_new(
p_index: *mut *mut FaissIndexIDMap,
index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " attempt a dynamic cast to a IDMap, thus checking\n check whether the underlying index type is `IndexIDMap`.\n\n @param index opaque pointer to index object\n @return the same pointer if the index is a IDMap index, NULL otherwise"]
pub fn faiss_IndexIDMap_cast(arg1: *mut FaissIndex) -> *mut FaissIndexIDMap;
}
extern "C" {
#[doc = " get a pointer to the index map's internal ID vector (the `id_map` field).\n The outputs of this function become invalid after any operation that can\n modify the index.\n\n @param index opaque pointer to index object\n @param p_id_map output, the pointer to the beginning of `id_map`.\n @param p_size output, the current length of `id_map`."]
pub fn faiss_IndexIDMap_id_map(
index: *mut FaissIndexIDMap,
p_id_map: *mut *mut idx_t,
p_size: *mut usize,
);
}
extern "C" {
#[doc = " get a pointer to the sub-index (the `index` field).\n The outputs of this function become invalid after any operation that can\n modify the index.\n\n @param index opaque pointer to index object"]
pub fn faiss_IndexIDMap_sub_index(index: *mut FaissIndexIDMap) -> *mut FaissIndex;
}
#[doc = " same as IndexIDMap but also provides an efficient reconstruction\nimplementation via a 2-way index"]
pub type FaissIndexIDMap2 = FaissIndex_H;
extern "C" {
#[doc = " same as IndexIDMap but also provides an efficient reconstruction\nimplementation via a 2-way index"]
pub fn faiss_IndexIDMap2_own_fields(arg1: *const FaissIndexIDMap2) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " same as IndexIDMap but also provides an efficient reconstruction\nimplementation via a 2-way index"]
pub fn faiss_IndexIDMap2_set_own_fields(
arg1: *mut FaissIndexIDMap2,
arg2: ::std::os::raw::c_int,
);
}
extern "C" {
#[doc = " same as IndexIDMap but also provides an efficient reconstruction\nimplementation via a 2-way index"]
pub fn faiss_IndexIDMap2_new(
p_index: *mut *mut FaissIndexIDMap2,
index: *mut FaissIndex,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " make the rev_map from scratch"]
pub fn faiss_IndexIDMap2_construct_rev_map(
index: *mut FaissIndexIDMap2,
) -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " attempt a dynamic cast to a IDMap2, thus checking\n check whether the underlying index type is `IndexIDMap`.\n\n @param index opaque pointer to index object\n @return the same pointer if the index is a IDMap2 index, NULL otherwise"]
pub fn faiss_IndexIDMap2_cast(arg1: *mut FaissIndex) -> *mut FaissIndexIDMap2;
}
extern "C" {
#[doc = " get a pointer to the index map's internal ID vector (the `id_map` field).\n The outputs of this function become invalid after any operation that can\n modify the index.\n\n @param index opaque pointer to index object\n @param p_id_map output, the pointer to the beginning of `id_map`.\n @param p_size output, the current length of `id_map`."]
pub fn faiss_IndexIDMap2_id_map(
index: *mut FaissIndexIDMap2,
p_id_map: *mut *mut idx_t,
p_size: *mut usize,
);
}
extern "C" {
#[doc = " get a pointer to the sub-index (the `index` field).\n The outputs of this function become invalid after any operation that can\n modify the index.\n\n @param index opaque pointer to index object"]
pub fn faiss_IndexIDMap2_sub_index(index: *mut FaissIndexIDMap2) -> *mut FaissIndex;
}
extern "C" {
#[doc = " Compute pairwise distances between sets of vectors"]
pub fn faiss_pairwise_L2sqr(
d: i64,
nq: i64,
xq: *const f32,
nb: i64,
xb: *const f32,
dis: *mut f32,
ldq: i64,
ldb: i64,
ldd: i64,
);
}
extern "C" {
#[doc = " Compute pairwise distances between sets of vectors\n arguments from \"faiss_pairwise_L2sqr\"\n ldq equal -1 by default\n ldb equal -1 by default\n ldd equal -1 by default"]
pub fn faiss_pairwise_L2sqr_with_defaults(
d: i64,
nq: i64,
xq: *const f32,
nb: i64,
xb: *const f32,
dis: *mut f32,
);
}
extern "C" {
#[doc = " compute the inner product between nx vectors x and one y"]
pub fn faiss_fvec_inner_products_ny(
ip: *mut f32,
x: *const f32,
y: *const f32,
d: usize,
ny: usize,
);
}
extern "C" {
#[doc = " compute ny square L2 distance between x and a set of contiguous y vectors"]
pub fn faiss_fvec_L2sqr_ny(dis: *mut f32, x: *const f32, y: *const f32, d: usize, ny: usize);
}
extern "C" {
#[doc = " squared norm of a vector"]
pub fn faiss_fvec_norm_L2sqr(x: *const f32, d: usize) -> f32;
}
extern "C" {
#[doc = " compute the L2 norms for a set of vectors"]
pub fn faiss_fvec_norms_L2(norms: *mut f32, x: *const f32, d: usize, nx: usize);
}
extern "C" {
#[doc = " same as fvec_norms_L2, but computes squared norms"]
pub fn faiss_fvec_norms_L2sqr(norms: *mut f32, x: *const f32, d: usize, nx: usize);
}
extern "C" {
#[doc = " L2-renormalize a set of vector. Nothing done if the vector is 0-normed"]
pub fn faiss_fvec_renorm_L2(d: usize, nx: usize, x: *mut f32);
}
extern "C" {
#[doc = " Setter of threshold value on nx above which we switch to BLAS to compute\n distances"]
pub fn faiss_set_distance_compute_blas_threshold(value: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Getter of threshold value on nx above which we switch to BLAS to compute\n distances"]
pub fn faiss_get_distance_compute_blas_threshold() -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Setter of block sizes value for BLAS distance computations"]
pub fn faiss_set_distance_compute_blas_query_bs(value: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Getter of block sizes value for BLAS distance computations"]
pub fn faiss_get_distance_compute_blas_query_bs() -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Setter of block sizes value for BLAS distance computations"]
pub fn faiss_set_distance_compute_blas_database_bs(value: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Getter of block sizes value for BLAS distance computations"]
pub fn faiss_get_distance_compute_blas_database_bs() -> ::std::os::raw::c_int;
}
extern "C" {
#[doc = " Setter of number of results we switch to a reservoir to collect results\n rather than a heap"]
pub fn faiss_set_distance_compute_min_k_reservoir(value: ::std::os::raw::c_int);
}
extern "C" {
#[doc = " Getter of number of results we switch to a reservoir to collect results\n rather than a heap"]
pub fn faiss_get_distance_compute_min_k_reservoir() -> ::std::os::raw::c_int;
}