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sqlite-vec/tests/fuzz/diskann-deep-search.c
Alex Garcia 575371d751 Add DiskANN index for vec0 virtual table 
Add DiskANN graph-based index: builds a Vamana graph with configurable R
(max degree) and L (search list size, separate for insert/query), supports
int8 quantization with rescore, lazy reverse-edge replacement, pre-quantized
query optimization, and insert buffer reuse. Includes shadow table management,
delete support, KNN integration, compile flag (SQLITE_VEC_ENABLE_DISKANN),
release-demo workflow, fuzz targets, and tests. Fixes rescore int8
quantization bug.
2026-03-31 01:21:54 -07:00

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/**
* Fuzz target for DiskANN greedy beam search deep paths.
*
* Builds a graph with enough nodes to force multi-hop traversal, then
* uses fuzz data to control: query vector values, k, search_list_size
* overrides, and interleaved insert/delete/query sequences that stress
* the candidate list growth, visited set hash collisions, and the
* re-ranking logic.
*
* Key code paths targeted:
* - diskann_candidate_list_insert (sorted insert, dedup, eviction)
* - diskann_visited_set (hash collisions, capacity)
* - diskann_search (full beam search loop, re-ranking with exact dist)
* - diskann_distance_quantized_precomputed (both binary and int8)
* - Buffer merge in vec0Filter_knn_diskann
*/
#include <stdint.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "sqlite-vec.h"
#include "sqlite3.h"
#include <assert.h>
/* Consume one byte from fuzz input, or return default. */
static uint8_t fuzz_byte(const uint8_t **data, size_t *size, uint8_t def) {
if (*size == 0) return def;
uint8_t b = **data;
(*data)++;
(*size)--;
return b;
}
static uint16_t fuzz_u16(const uint8_t **data, size_t *size) {
uint8_t lo = fuzz_byte(data, size, 0);
uint8_t hi = fuzz_byte(data, size, 0);
return (uint16_t)hi << 8 | lo;
}
static float fuzz_float(const uint8_t **data, size_t *size) {
return (float)((int8_t)fuzz_byte(data, size, 0)) / 10.0f;
}
int LLVMFuzzerTestOneInput(const uint8_t *data, size_t size) {
if (size < 32) return 0;
/* Use first bytes to pick quantizer type and dimensions */
uint8_t quantizer_choice = fuzz_byte(&data, &size, 0) % 2;
const char *quantizer = quantizer_choice ? "int8" : "binary";
/* Dimensions must be divisible by 8. Pick from {8, 16, 32} */
int dim_choices[] = {8, 16, 32};
int dims = dim_choices[fuzz_byte(&data, &size, 0) % 3];
/* n_neighbors: 8 or 16 -- small to force full-neighbor scenarios quickly */
int n_neighbors = (fuzz_byte(&data, &size, 0) % 2) ? 16 : 8;
/* search_list_size: small so beam search terminates quickly but still exercises loops */
int search_list_size = 8 + (fuzz_byte(&data, &size, 0) % 24);
/* alpha: vary to test RobustPrune pruning logic */
float alpha_choices[] = {1.0f, 1.2f, 1.5f, 2.0f};
float alpha = alpha_choices[fuzz_byte(&data, &size, 0) % 4];
int rc;
sqlite3 *db;
rc = sqlite3_open(":memory:", &db);
assert(rc == SQLITE_OK);
rc = sqlite3_vec_init(db, NULL, NULL);
assert(rc == SQLITE_OK);
char sql[512];
snprintf(sql, sizeof(sql),
"CREATE VIRTUAL TABLE v USING vec0("
"emb float[%d] INDEXED BY diskann("
"neighbor_quantizer=%s, n_neighbors=%d, "
"search_list_size=%d"
"))", dims, quantizer, n_neighbors, search_list_size);
rc = sqlite3_exec(db, sql, NULL, NULL, NULL);
if (rc != SQLITE_OK) { sqlite3_close(db); return 0; }
sqlite3_stmt *stmtInsert = NULL, *stmtDelete = NULL, *stmtKnn = NULL;
sqlite3_prepare_v2(db,
"INSERT INTO v(rowid, emb) VALUES (?, ?)", -1, &stmtInsert, NULL);
sqlite3_prepare_v2(db,
"DELETE FROM v WHERE rowid = ?", -1, &stmtDelete, NULL);
char knn_sql[256];
snprintf(knn_sql, sizeof(knn_sql),
"SELECT rowid, distance FROM v WHERE emb MATCH ? AND k = ?");
sqlite3_prepare_v2(db, knn_sql, -1, &stmtKnn, NULL);
if (!stmtInsert || !stmtDelete || !stmtKnn) goto cleanup;
/* Phase 1: Seed the graph with enough nodes to create multi-hop structure.
* Insert 2*n_neighbors nodes so the graph is dense enough for search
* to actually traverse multiple hops. */
int seed_count = n_neighbors * 2;
if (seed_count > 64) seed_count = 64; /* Bound for performance */
{
float *vec = malloc(dims * sizeof(float));
if (!vec) goto cleanup;
for (int i = 1; i <= seed_count; i++) {
for (int j = 0; j < dims; j++) {
vec[j] = fuzz_float(&data, &size);
}
sqlite3_reset(stmtInsert);
sqlite3_bind_int64(stmtInsert, 1, i);
sqlite3_bind_blob(stmtInsert, 2, vec, dims * sizeof(float), SQLITE_TRANSIENT);
sqlite3_step(stmtInsert);
}
free(vec);
}
/* Phase 2: Fuzz-driven operations on the seeded graph */
float *vec = malloc(dims * sizeof(float));
if (!vec) goto cleanup;
while (size >= 2) {
uint8_t op = fuzz_byte(&data, &size, 0) % 5;
uint8_t param = fuzz_byte(&data, &size, 0);
switch (op) {
case 0: { /* INSERT with fuzz-controlled vector and rowid */
int64_t rowid = (int64_t)(param % 128) + 1;
for (int j = 0; j < dims; j++) {
vec[j] = fuzz_float(&data, &size);
}
sqlite3_reset(stmtInsert);
sqlite3_bind_int64(stmtInsert, 1, rowid);
sqlite3_bind_blob(stmtInsert, 2, vec, dims * sizeof(float), SQLITE_TRANSIENT);
sqlite3_step(stmtInsert);
break;
}
case 1: { /* DELETE */
int64_t rowid = (int64_t)(param % 128) + 1;
sqlite3_reset(stmtDelete);
sqlite3_bind_int64(stmtDelete, 1, rowid);
sqlite3_step(stmtDelete);
break;
}
case 2: { /* KNN with fuzz query vector and variable k */
for (int j = 0; j < dims; j++) {
vec[j] = fuzz_float(&data, &size);
}
int k = (param % 20) + 1;
sqlite3_reset(stmtKnn);
sqlite3_bind_blob(stmtKnn, 1, vec, dims * sizeof(float), SQLITE_TRANSIENT);
sqlite3_bind_int(stmtKnn, 2, k);
while (sqlite3_step(stmtKnn) == SQLITE_ROW) {}
break;
}
case 3: { /* KNN with k > number of nodes (boundary) */
for (int j = 0; j < dims; j++) {
vec[j] = fuzz_float(&data, &size);
}
sqlite3_reset(stmtKnn);
sqlite3_bind_blob(stmtKnn, 1, vec, dims * sizeof(float), SQLITE_TRANSIENT);
sqlite3_bind_int(stmtKnn, 2, 1000); /* k >> graph size */
while (sqlite3_step(stmtKnn) == SQLITE_ROW) {}
break;
}
case 4: { /* INSERT duplicate rowid (triggers OR REPLACE path) */
int64_t rowid = (int64_t)(param % 32) + 1;
for (int j = 0; j < dims; j++) {
vec[j] = (float)(param + j) / 50.0f;
}
sqlite3_reset(stmtInsert);
sqlite3_bind_int64(stmtInsert, 1, rowid);
sqlite3_bind_blob(stmtInsert, 2, vec, dims * sizeof(float), SQLITE_TRANSIENT);
sqlite3_step(stmtInsert);
break;
}
}
}
free(vec);
cleanup:
sqlite3_finalize(stmtInsert);
sqlite3_finalize(stmtDelete);
sqlite3_finalize(stmtKnn);
sqlite3_close(db);
return 0;
}
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