## 2. Schema #### 2.1 Collection Schema ```go type CollectionSchema struct { Name string Description string AutoId bool Fields []*FieldSchema } ``` #### 2.2 Field Schema ```go type FieldSchema struct { FieldID int64 Name string IsPrimaryKey bool Description string DataType DataType TypeParams []*commonpb.KeyValuePair IndexParams []*commonpb.KeyValuePair AutoID bool } ``` ###### 2.2.1 Data Types **DataType** ```protobuf enum DataType { NONE = 0; BOOL = 1; INT8 = 2; INT16 = 3; INT32 = 4; INT64 = 5; FLOAT = 10; DOUBLE = 11; STRING = 20; VECTOR_BINARY = 100; VECTOR_FLOAT = 101; } ``` ###### 2.2.2 Type Params ###### 2.2.3 Index Params # Intro to Index For more detailed information about indexes, please refer to [Milvus documentation index chapter.](https://milvus.io/docs/index.md) To learn how to choose an appropriate index for your application scenarios, please read [How to Select an Index in Milvus](https://medium.com/@milvusio/how-to-choose-an-index-in-milvus-4f3d15259212). To learn how to choose an appropriate index for a metric, see [Similarity Metrics](https://milvus.io/docs/metric.md). Different index types use different index params in construction and query. All index params are represented by the structure of the map. This doc shows the map code in python. [IVF_FLAT](#IVF_FLAT) [BIN_IVF_FLAT](#BIN_IVF_FLAT) [IVF_PQ](#IVF_PQ) [IVF_SQ8](#IVF_SQ8) [IVF_SQ8_HYBRID](#IVF_SQ8_HYBRID) [ANNOY](#ANNOY) [HNSW](#HNSW) [RHNSW_PQ](#RHNSW_PQ) [RHNSW_SQ](#RHNSW_SQ) [NSG](#NSG) ## IVF_FLAT **IVF** (_Inverted File_) is an index type based on quantization. It divides the points in space into `nlist` units by the clustering method. During searching vectors, it compares the distance between the target vector and the center of all units, and then selects the `nprobe` nearest unit. Afterwards, it compares all the vectors in these selected cells to get the final result. IVF_FLAT is the most basic IVF index, and the encoded data stored in each unit is consistent with the original data. - building parameters: **nlist**: Number of cluster units. ```python # IVF_FLAT { "index_type": "IVF_FLAT", "metric_type": "L2", # one of L2, IP #Special for IVF_FLAT "nlist": 100 # int. 1~65536 } ``` - search parameters: **nprobe**: Number of inverted file cells to probe. ```python # IVF_FLAT { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for IVF_FLAT "nprobe": 8 # int. 1~nlist(cpu), 1~min[2048, nlist](gpu) } ``` ## BIN_IVF_FLAT **BIN_IVF_FLAT** is a binary variant of IVF_FLAT. - building parameters: **nlist**: Number of cluster units. ```python # BIN_IVF_FLAT { "index_type": "BIN_IVF_FLAT", "metric_type": "jaccard", # one of jaccard, hamming, tanimoto #Special for BIN_IVF_FLAT "nlist": 100 # int. 1~65536 } ``` - search parameters: **nprobe**: Number of inverted file cells to probe. ```python # BIN_IVF_FLAT { "topk": top_k, "query": queries, #Special for BIN_IVF_FLAT "metric_type": "jaccard", # one of jaccard, hamming, tanimoto "nprobe": 8 # int. 1~nlist(cpu), 1~min[2048, nlist](gpu) } ``` ## IVF_PQ **PQ** (_Product Quantization_) uniformly decomposes the original high-dimensional vector space into Cartesian products of `m` low-dimensional vector spaces and then quantizes the decomposed low-dimensional vector spaces. Instead of calculating the distances between the target vector and the center of all the units, product quantization enables the calculation of distances between the target vector and the clustering center of each low-dimensional space and greatly reduces the time complexity and space complexity of the algorithm. IVF_PQ performs IVF index clustering, and then quantizes the product of vectors. Its index file is even smaller than IVF_SQ8, but it also causes a loss of accuracy during searching. - building parameters: **nlist**: Number of cluster units. **m**: Number of factors of product quantization. **CPU-only** Milvus: `m ≡ dim (mod m)`; **GPU-enabled** Milvus: `m` ∈ {1, 2, 3, 4, 8, 12, 16, 20, 24, 28, 32, 40, 48, 56, 64, 96}, and (dim / m) ∈ {1, 2, 3, 4, 6, 8, 10, 12, 16, 20, 24, 28, 32}. (`m` x 1024) ≥ `MaxSharedMemPerBlock` of your graphics card. ```python # IVF_PQ { "index_type": "IVF_PQ", "metric_type": "L2", # one of L2, IP #Special for IVF_PQ "nlist": 100, # int. 1~65536 "m": 8 } ``` - search parameters: **nprobe**: Number of inverted file cells to probe. ```python # IVF_PQ { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for IVF_PQ "nprobe": 8 # int. 1~nlist(cpu), 1~min[2048, nlist](gpu) } ``` ## IVF_SQ8 **IVF_SQ8** does scalar quantization for each vector placed in the unit based on IVF. Scalar quantization converts each dimension of the original vector from a 4-byte floating-point number to a 1-byte unsigned integer, so the IVF_SQ8 index file occupies much less space than the IVF_FLAT index file. However, scalar quantization results in a loss of accuracy during searching vectors. - building parameters: **nlist**: Number of cluster units. ```python # IVF_SQ8 { "index_type": "IVF_SQ8", "metric_type": "L2", # one of L2, IP #Special for IVF_SQ8 "nlist": 100 # int. 1~65536 } ``` - search parameters: **nprobe**: Number of inverted file cells to probe. ```python # IVF_SQ8 { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for IVF_SQ8 "nprobe": 8 # int. 1~nlist(cpu), 1~min[2048, nlist](gpu) } ``` ## IVF_SQ8_HYBRID An optimized version of IVF_SQ8 that requires both CPU and GPU to work. Unlike IVF_SQ8, IVF_SQ8H uses a GPU-based coarse quantizer, which greatly reduces the time to quantize. IVF_SQ8H is an IVF_SQ8 index that optimizes query execution. The query method is as follows: - If `nq` ≥ `gpu_search_threshold`, GPU handles the entire query task. - If `nq` < `gpu_search_threshold`, GPU handles the task of retrieving the `nprobe` nearest unit in the IVF index file, and CPU handles the rest. - building parameters: **nlist**: Number of cluster units. ```python # IVF_SQ8_HYBRID { "index_type": "IVF_SQ8_HYBRID", "metric_type": "L2", # one of L2, IP #Special for IVF_SQ8_HYBRID "nlist": 100 # int. 1~65536 } ``` - search parameters: **nprobe**: Number of inverted file cells to probe. ```python # IVF_SQ8_HYBRID { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for IVF_SQ8_HYBRID "nprobe": 8 # int. 1~nlist(cpu), 1~min[2048, nlist](gpu) } ``` ## ANNOY **ANNOY** (_Approximate Nearest Neighbors Oh Yeah_) is an index that uses a hyperplane to divide a high-dimensional space into multiple subspaces, and then stores them in a tree structure. When searching for vectors, ANNOY follows the tree structure to find subspaces closer to the target vector, and then compares all the vectors in these subspaces (The number of vectors being compared should not be less than `search_k`) to obtain the final result. Obviously, when the target vector is close to the edge of a certain subspace, sometimes it is necessary to greatly increase the number of searched subspaces to obtain a high recall rate. Therefore, ANNOY uses `n_trees` different methods to divide the whole space, and searches all the dividing methods simultaneously to reduce the probability that the target vector is always at the edge of the subspace. - building parameters: **n_trees**: The number of methods of space division. ```python # ANNOY { "index_type": "ANNOY", "metric_type": "L2", # one of L2, IP #Special for ANNOY "n_trees": 8 # int. 1~1024 } ``` - search parameters: **search_k**: The number of nodes to search. -1 means 5% of the whole data. ```python # ANNOY { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for ANNOY "search_k": -1 # int. {-1} U [top_k, n*n_trees], n represents vectors count. } ``` ## HNSW **HNSW** (_Hierarchical Navigable Small World Graph_) is a graph-based indexing algorithm. It builds a multi-layer navigation structure for an image according to certain rules. In this structure, the upper layers are more sparse and the distances between nodes are farther; the lower layers are denser and the distances between nodes are closer. The search starts from the uppermost layer, finds the node closest to the target in this layer, and then enters the next layer to begin another search. After multiple iterations, it can quickly approach the target position. To improve performance, HNSW limits the maximum degree of nodes on each layer of the graph to `M`. In addition, you can use `efConstruction` (when building index) or `ef` (when searching targets) to specify a search range. - building parameters: **M**: Maximum degree of the node. **efConstruction**: Take the effect in the stage of index construction. ```python # HNSW { "index_type": "HNSW", "metric_type": "L2", # one of L2, IP #Special for HNSW "M": 16, # int. 4~64 "efConstruction": 40 # int. 8~512 } ``` - search parameters: **ef**: Take the effect in the stage of search scope, should be larger than `top_k`. ```python # HNSW { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for HNSW "ef": 64 # int. top_k~32768 } ``` ## RHNSW_PQ **RHNSW_PQ** is a variant index type combining PQ and HNSW. It first uses PQ to quantize the vector, then uses HNSW to quantize the PQ quantization result to get the index. - building parameters: **M**: Maximum degree of the node. **efConstruction**: Take effect in the stage of index construction. **PQM**: m for PQ. ```python # RHNSW_PQ { "index_type": "RHNSW_PQ", "metric_type": "L2", #Special for RHNSW_PQ "M": 16, # int. 4~64 "efConstruction": 40, # int. 8~512 "PQM": 8, # int. CPU only. PQM = dim (mod m) } ``` - search parameters: **ef**: Take the effect in the stage of search scope, should be larger than `top_k`. ```python # RHNSW_PQ { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for RHNSW_PQ "ef": 64 # int. top_k~32768 } ``` ## RHNSW_SQ **RHNSW_SQ** is a variant index type combining SQ and HNSW. It uses SQ to quantize the vector, then uses HNSW to quantize the SQ quantization result to get the index. - building parameters: **M**: Maximum degree of the node. **efConstruction**: Take effect in the stage of index construction, search scope. ```python # RHNSW_SQ { "index_type": "RHNSW_SQ", "metric_type": "L2", # one of L2, IP #Special for RHNSW_SQ "M": 16, # int. 4~64 "efConstruction": 40 # int. 8~512 } ``` - search parameters: **ef**: Take the effect in the stage of search scope, should be larger than `top_k`. ```python # RHNSW_SQ { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for RHNSW_SQ "ef": 64 # int. top_k~32768 } ``` ## NSG **NSG** (_Refined Navigating Spreading-out Graph_) is a graph-based indexing algorithm. It sets the center position of the whole image as a navigation point, and then uses a specific edge selection strategy to control the out-degree of each point (less than or equal to `out_degree`). Therefore, it can reduce memory usage and quickly locate the target position nearby during searching vectors. The graph construction process of NSG is as follows: 1. Find `knng` nearest neighbors for each point. 2. Iterate at least `search_length` times based on `knng` nearest neighbor nodes to select `candidate_pool_size` possible nearest neighbor nodes. 3. Construct the out-edge of each point in the selected `candidate_pool_size` nodes according to the edge selection strategy. The query process is similar to the graph building process. It starts from the navigation point and iterates at least `search_length` times to get the final result. - building parameters: **search_length**: Number of query iterations. **out_degree**: Maximum out-degree of the node. **candidate_pool_size**: Candidate pool size of the node. **knng**: Number of nearest neighbors ```python # NSG { "index_type": "NSG", "metric_type": "L2", #Special for RHNSW_SQ "search_length": 60, # int. 10~300 "out_degree": 30, # int. 5~300 "candidate_pool_size": 300, # int. 50~1000 "knng": 50 # int. 5~300 } ``` - search parameters: **search_length**: Number of query iterations ```python # NSG { "topk": top_k, "query": queries, "metric_type": "L2", # one of L2, IP #Special for RHNSW_SQ "search_length": 100 # int. 10~300 } ```