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2222 2223 2224 2225 2226 2227 2228 2229 2230 2231 2232 2233 2234 2235 2236 2237 2238 2239 2240 2241 2242 2243 2244 2245 2246 2247 2248 2249 2250 2251 2252 2253 2254 2255 2256 2257 2258 2259 2260 2261 2262 2263 2264 2265 2266 2267 2268 2269 2270 2271 2272 2273 2274 2275 2276 2277 2278 2279 2280 2281 2282 2283 2284 2285 2286 2287 2288 2289 2290 2291 2292 2293 2294 2295 2296 2297 2298 2299 2300 2301 2302 2303 2304 2305 2306 2307 2308 2309 2310 2311 2312 2313 2314 2315 2316 2317 2318 2319 2320 2321 2322 2323 2324 2325 2326 2327 2328 2329 2330 2331 2332 2333 2334 2335 2336 2337 2338 2339 2340 2341 2342 2343 2344 2345 2346 2347 2348 2349 2350 2351 2352 2353 2354 2355 2356 2357 2358 2359 2360 2361 2362 2363 2364 2365 2366 2367 2368 | /* SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note * * Copyright 2016-2023 HabanaLabs, Ltd. * All Rights Reserved. * */ #ifndef HABANALABS_H_ #define HABANALABS_H_ #include <drm/drm.h> /* * Defines that are asic-specific but constitutes as ABI between kernel driver * and userspace */ #define GOYA_KMD_SRAM_RESERVED_SIZE_FROM_START 0x8000 /* 32KB */ #define GAUDI_DRIVER_SRAM_RESERVED_SIZE_FROM_START 0x80 /* 128 bytes */ /* * 128 SOBs reserved for collective wait * 16 SOBs reserved for sync stream */ #define GAUDI_FIRST_AVAILABLE_W_S_SYNC_OBJECT 144 /* * 64 monitors reserved for collective wait * 8 monitors reserved for sync stream */ #define GAUDI_FIRST_AVAILABLE_W_S_MONITOR 72 /* Max number of elements in timestamps registration buffers */ #define TS_MAX_ELEMENTS_NUM (1 << 20) /* 1MB */ /* * Goya queue Numbering * * The external queues (PCI DMA channels) MUST be before the internal queues * and each group (PCI DMA channels and internal) must be contiguous inside * itself but there can be a gap between the two groups (although not * recommended) */ enum goya_queue_id { GOYA_QUEUE_ID_DMA_0 = 0, GOYA_QUEUE_ID_DMA_1 = 1, GOYA_QUEUE_ID_DMA_2 = 2, GOYA_QUEUE_ID_DMA_3 = 3, GOYA_QUEUE_ID_DMA_4 = 4, GOYA_QUEUE_ID_CPU_PQ = 5, GOYA_QUEUE_ID_MME = 6, /* Internal queues start here */ GOYA_QUEUE_ID_TPC0 = 7, GOYA_QUEUE_ID_TPC1 = 8, GOYA_QUEUE_ID_TPC2 = 9, GOYA_QUEUE_ID_TPC3 = 10, GOYA_QUEUE_ID_TPC4 = 11, GOYA_QUEUE_ID_TPC5 = 12, GOYA_QUEUE_ID_TPC6 = 13, GOYA_QUEUE_ID_TPC7 = 14, GOYA_QUEUE_ID_SIZE }; /* * Gaudi queue Numbering * External queues (PCI DMA channels) are DMA_0_*, DMA_1_* and DMA_5_*. * Except one CPU queue, all the rest are internal queues. */ enum gaudi_queue_id { GAUDI_QUEUE_ID_DMA_0_0 = 0, /* external */ GAUDI_QUEUE_ID_DMA_0_1 = 1, /* external */ GAUDI_QUEUE_ID_DMA_0_2 = 2, /* external */ GAUDI_QUEUE_ID_DMA_0_3 = 3, /* external */ GAUDI_QUEUE_ID_DMA_1_0 = 4, /* external */ GAUDI_QUEUE_ID_DMA_1_1 = 5, /* external */ GAUDI_QUEUE_ID_DMA_1_2 = 6, /* external */ GAUDI_QUEUE_ID_DMA_1_3 = 7, /* external */ GAUDI_QUEUE_ID_CPU_PQ = 8, /* CPU */ GAUDI_QUEUE_ID_DMA_2_0 = 9, /* internal */ GAUDI_QUEUE_ID_DMA_2_1 = 10, /* internal */ GAUDI_QUEUE_ID_DMA_2_2 = 11, /* internal */ GAUDI_QUEUE_ID_DMA_2_3 = 12, /* internal */ GAUDI_QUEUE_ID_DMA_3_0 = 13, /* internal */ GAUDI_QUEUE_ID_DMA_3_1 = 14, /* internal */ GAUDI_QUEUE_ID_DMA_3_2 = 15, /* internal */ GAUDI_QUEUE_ID_DMA_3_3 = 16, /* internal */ GAUDI_QUEUE_ID_DMA_4_0 = 17, /* internal */ GAUDI_QUEUE_ID_DMA_4_1 = 18, /* internal */ GAUDI_QUEUE_ID_DMA_4_2 = 19, /* internal */ GAUDI_QUEUE_ID_DMA_4_3 = 20, /* internal */ GAUDI_QUEUE_ID_DMA_5_0 = 21, /* internal */ GAUDI_QUEUE_ID_DMA_5_1 = 22, /* internal */ GAUDI_QUEUE_ID_DMA_5_2 = 23, /* internal */ GAUDI_QUEUE_ID_DMA_5_3 = 24, /* internal */ GAUDI_QUEUE_ID_DMA_6_0 = 25, /* internal */ GAUDI_QUEUE_ID_DMA_6_1 = 26, /* internal */ GAUDI_QUEUE_ID_DMA_6_2 = 27, /* internal */ GAUDI_QUEUE_ID_DMA_6_3 = 28, /* internal */ GAUDI_QUEUE_ID_DMA_7_0 = 29, /* internal */ GAUDI_QUEUE_ID_DMA_7_1 = 30, /* internal */ GAUDI_QUEUE_ID_DMA_7_2 = 31, /* internal */ GAUDI_QUEUE_ID_DMA_7_3 = 32, /* internal */ GAUDI_QUEUE_ID_MME_0_0 = 33, /* internal */ GAUDI_QUEUE_ID_MME_0_1 = 34, /* internal */ GAUDI_QUEUE_ID_MME_0_2 = 35, /* internal */ GAUDI_QUEUE_ID_MME_0_3 = 36, /* internal */ GAUDI_QUEUE_ID_MME_1_0 = 37, /* internal */ GAUDI_QUEUE_ID_MME_1_1 = 38, /* internal */ GAUDI_QUEUE_ID_MME_1_2 = 39, /* internal */ GAUDI_QUEUE_ID_MME_1_3 = 40, /* internal */ GAUDI_QUEUE_ID_TPC_0_0 = 41, /* internal */ GAUDI_QUEUE_ID_TPC_0_1 = 42, /* internal */ GAUDI_QUEUE_ID_TPC_0_2 = 43, /* internal */ GAUDI_QUEUE_ID_TPC_0_3 = 44, /* internal */ GAUDI_QUEUE_ID_TPC_1_0 = 45, /* internal */ GAUDI_QUEUE_ID_TPC_1_1 = 46, /* internal */ GAUDI_QUEUE_ID_TPC_1_2 = 47, /* internal */ GAUDI_QUEUE_ID_TPC_1_3 = 48, /* internal */ GAUDI_QUEUE_ID_TPC_2_0 = 49, /* internal */ GAUDI_QUEUE_ID_TPC_2_1 = 50, /* internal */ GAUDI_QUEUE_ID_TPC_2_2 = 51, /* internal */ GAUDI_QUEUE_ID_TPC_2_3 = 52, /* internal */ GAUDI_QUEUE_ID_TPC_3_0 = 53, /* internal */ GAUDI_QUEUE_ID_TPC_3_1 = 54, /* internal */ GAUDI_QUEUE_ID_TPC_3_2 = 55, /* internal */ GAUDI_QUEUE_ID_TPC_3_3 = 56, /* internal */ GAUDI_QUEUE_ID_TPC_4_0 = 57, /* internal */ GAUDI_QUEUE_ID_TPC_4_1 = 58, /* internal */ GAUDI_QUEUE_ID_TPC_4_2 = 59, /* internal */ GAUDI_QUEUE_ID_TPC_4_3 = 60, /* internal */ GAUDI_QUEUE_ID_TPC_5_0 = 61, /* internal */ GAUDI_QUEUE_ID_TPC_5_1 = 62, /* internal */ GAUDI_QUEUE_ID_TPC_5_2 = 63, /* internal */ GAUDI_QUEUE_ID_TPC_5_3 = 64, /* internal */ GAUDI_QUEUE_ID_TPC_6_0 = 65, /* internal */ GAUDI_QUEUE_ID_TPC_6_1 = 66, /* internal */ GAUDI_QUEUE_ID_TPC_6_2 = 67, /* internal */ GAUDI_QUEUE_ID_TPC_6_3 = 68, /* internal */ GAUDI_QUEUE_ID_TPC_7_0 = 69, /* internal */ GAUDI_QUEUE_ID_TPC_7_1 = 70, /* internal */ GAUDI_QUEUE_ID_TPC_7_2 = 71, /* internal */ GAUDI_QUEUE_ID_TPC_7_3 = 72, /* internal */ GAUDI_QUEUE_ID_NIC_0_0 = 73, /* internal */ GAUDI_QUEUE_ID_NIC_0_1 = 74, /* internal */ GAUDI_QUEUE_ID_NIC_0_2 = 75, /* internal */ GAUDI_QUEUE_ID_NIC_0_3 = 76, /* internal */ GAUDI_QUEUE_ID_NIC_1_0 = 77, /* internal */ GAUDI_QUEUE_ID_NIC_1_1 = 78, /* internal */ GAUDI_QUEUE_ID_NIC_1_2 = 79, /* internal */ GAUDI_QUEUE_ID_NIC_1_3 = 80, /* internal */ GAUDI_QUEUE_ID_NIC_2_0 = 81, /* internal */ GAUDI_QUEUE_ID_NIC_2_1 = 82, /* internal */ GAUDI_QUEUE_ID_NIC_2_2 = 83, /* internal */ GAUDI_QUEUE_ID_NIC_2_3 = 84, /* internal */ GAUDI_QUEUE_ID_NIC_3_0 = 85, /* internal */ GAUDI_QUEUE_ID_NIC_3_1 = 86, /* internal */ GAUDI_QUEUE_ID_NIC_3_2 = 87, /* internal */ GAUDI_QUEUE_ID_NIC_3_3 = 88, /* internal */ GAUDI_QUEUE_ID_NIC_4_0 = 89, /* internal */ GAUDI_QUEUE_ID_NIC_4_1 = 90, /* internal */ GAUDI_QUEUE_ID_NIC_4_2 = 91, /* internal */ GAUDI_QUEUE_ID_NIC_4_3 = 92, /* internal */ GAUDI_QUEUE_ID_NIC_5_0 = 93, /* internal */ GAUDI_QUEUE_ID_NIC_5_1 = 94, /* internal */ GAUDI_QUEUE_ID_NIC_5_2 = 95, /* internal */ GAUDI_QUEUE_ID_NIC_5_3 = 96, /* internal */ GAUDI_QUEUE_ID_NIC_6_0 = 97, /* internal */ GAUDI_QUEUE_ID_NIC_6_1 = 98, /* internal */ GAUDI_QUEUE_ID_NIC_6_2 = 99, /* internal */ GAUDI_QUEUE_ID_NIC_6_3 = 100, /* internal */ GAUDI_QUEUE_ID_NIC_7_0 = 101, /* internal */ GAUDI_QUEUE_ID_NIC_7_1 = 102, /* internal */ GAUDI_QUEUE_ID_NIC_7_2 = 103, /* internal */ GAUDI_QUEUE_ID_NIC_7_3 = 104, /* internal */ GAUDI_QUEUE_ID_NIC_8_0 = 105, /* internal */ GAUDI_QUEUE_ID_NIC_8_1 = 106, /* internal */ GAUDI_QUEUE_ID_NIC_8_2 = 107, /* internal */ GAUDI_QUEUE_ID_NIC_8_3 = 108, /* internal */ GAUDI_QUEUE_ID_NIC_9_0 = 109, /* internal */ GAUDI_QUEUE_ID_NIC_9_1 = 110, /* internal */ GAUDI_QUEUE_ID_NIC_9_2 = 111, /* internal */ GAUDI_QUEUE_ID_NIC_9_3 = 112, /* internal */ GAUDI_QUEUE_ID_SIZE }; /* * In GAUDI2 we have two modes of operation in regard to queues: * 1. Legacy mode, where each QMAN exposes 4 streams to the user * 2. F/W mode, where we use F/W to schedule the JOBS to the different queues. * * When in legacy mode, the user sends the queue id per JOB according to * enum gaudi2_queue_id below. * * When in F/W mode, the user sends a stream id per Command Submission. The * stream id is a running number from 0 up to (N-1), where N is the number * of streams the F/W exposes and is passed to the user in * struct hl_info_hw_ip_info */ enum gaudi2_queue_id { GAUDI2_QUEUE_ID_PDMA_0_0 = 0, GAUDI2_QUEUE_ID_PDMA_0_1 = 1, GAUDI2_QUEUE_ID_PDMA_0_2 = 2, GAUDI2_QUEUE_ID_PDMA_0_3 = 3, GAUDI2_QUEUE_ID_PDMA_1_0 = 4, GAUDI2_QUEUE_ID_PDMA_1_1 = 5, GAUDI2_QUEUE_ID_PDMA_1_2 = 6, GAUDI2_QUEUE_ID_PDMA_1_3 = 7, GAUDI2_QUEUE_ID_DCORE0_EDMA_0_0 = 8, GAUDI2_QUEUE_ID_DCORE0_EDMA_0_1 = 9, GAUDI2_QUEUE_ID_DCORE0_EDMA_0_2 = 10, GAUDI2_QUEUE_ID_DCORE0_EDMA_0_3 = 11, GAUDI2_QUEUE_ID_DCORE0_EDMA_1_0 = 12, GAUDI2_QUEUE_ID_DCORE0_EDMA_1_1 = 13, GAUDI2_QUEUE_ID_DCORE0_EDMA_1_2 = 14, GAUDI2_QUEUE_ID_DCORE0_EDMA_1_3 = 15, GAUDI2_QUEUE_ID_DCORE0_MME_0_0 = 16, GAUDI2_QUEUE_ID_DCORE0_MME_0_1 = 17, GAUDI2_QUEUE_ID_DCORE0_MME_0_2 = 18, GAUDI2_QUEUE_ID_DCORE0_MME_0_3 = 19, GAUDI2_QUEUE_ID_DCORE0_TPC_0_0 = 20, GAUDI2_QUEUE_ID_DCORE0_TPC_0_1 = 21, GAUDI2_QUEUE_ID_DCORE0_TPC_0_2 = 22, GAUDI2_QUEUE_ID_DCORE0_TPC_0_3 = 23, GAUDI2_QUEUE_ID_DCORE0_TPC_1_0 = 24, GAUDI2_QUEUE_ID_DCORE0_TPC_1_1 = 25, GAUDI2_QUEUE_ID_DCORE0_TPC_1_2 = 26, GAUDI2_QUEUE_ID_DCORE0_TPC_1_3 = 27, GAUDI2_QUEUE_ID_DCORE0_TPC_2_0 = 28, GAUDI2_QUEUE_ID_DCORE0_TPC_2_1 = 29, GAUDI2_QUEUE_ID_DCORE0_TPC_2_2 = 30, GAUDI2_QUEUE_ID_DCORE0_TPC_2_3 = 31, GAUDI2_QUEUE_ID_DCORE0_TPC_3_0 = 32, GAUDI2_QUEUE_ID_DCORE0_TPC_3_1 = 33, GAUDI2_QUEUE_ID_DCORE0_TPC_3_2 = 34, GAUDI2_QUEUE_ID_DCORE0_TPC_3_3 = 35, GAUDI2_QUEUE_ID_DCORE0_TPC_4_0 = 36, GAUDI2_QUEUE_ID_DCORE0_TPC_4_1 = 37, GAUDI2_QUEUE_ID_DCORE0_TPC_4_2 = 38, GAUDI2_QUEUE_ID_DCORE0_TPC_4_3 = 39, GAUDI2_QUEUE_ID_DCORE0_TPC_5_0 = 40, GAUDI2_QUEUE_ID_DCORE0_TPC_5_1 = 41, GAUDI2_QUEUE_ID_DCORE0_TPC_5_2 = 42, GAUDI2_QUEUE_ID_DCORE0_TPC_5_3 = 43, GAUDI2_QUEUE_ID_DCORE0_TPC_6_0 = 44, GAUDI2_QUEUE_ID_DCORE0_TPC_6_1 = 45, GAUDI2_QUEUE_ID_DCORE0_TPC_6_2 = 46, GAUDI2_QUEUE_ID_DCORE0_TPC_6_3 = 47, GAUDI2_QUEUE_ID_DCORE1_EDMA_0_0 = 48, GAUDI2_QUEUE_ID_DCORE1_EDMA_0_1 = 49, GAUDI2_QUEUE_ID_DCORE1_EDMA_0_2 = 50, GAUDI2_QUEUE_ID_DCORE1_EDMA_0_3 = 51, GAUDI2_QUEUE_ID_DCORE1_EDMA_1_0 = 52, GAUDI2_QUEUE_ID_DCORE1_EDMA_1_1 = 53, GAUDI2_QUEUE_ID_DCORE1_EDMA_1_2 = 54, GAUDI2_QUEUE_ID_DCORE1_EDMA_1_3 = 55, GAUDI2_QUEUE_ID_DCORE1_MME_0_0 = 56, GAUDI2_QUEUE_ID_DCORE1_MME_0_1 = 57, GAUDI2_QUEUE_ID_DCORE1_MME_0_2 = 58, GAUDI2_QUEUE_ID_DCORE1_MME_0_3 = 59, GAUDI2_QUEUE_ID_DCORE1_TPC_0_0 = 60, GAUDI2_QUEUE_ID_DCORE1_TPC_0_1 = 61, GAUDI2_QUEUE_ID_DCORE1_TPC_0_2 = 62, GAUDI2_QUEUE_ID_DCORE1_TPC_0_3 = 63, GAUDI2_QUEUE_ID_DCORE1_TPC_1_0 = 64, GAUDI2_QUEUE_ID_DCORE1_TPC_1_1 = 65, GAUDI2_QUEUE_ID_DCORE1_TPC_1_2 = 66, GAUDI2_QUEUE_ID_DCORE1_TPC_1_3 = 67, GAUDI2_QUEUE_ID_DCORE1_TPC_2_0 = 68, GAUDI2_QUEUE_ID_DCORE1_TPC_2_1 = 69, GAUDI2_QUEUE_ID_DCORE1_TPC_2_2 = 70, GAUDI2_QUEUE_ID_DCORE1_TPC_2_3 = 71, GAUDI2_QUEUE_ID_DCORE1_TPC_3_0 = 72, GAUDI2_QUEUE_ID_DCORE1_TPC_3_1 = 73, GAUDI2_QUEUE_ID_DCORE1_TPC_3_2 = 74, GAUDI2_QUEUE_ID_DCORE1_TPC_3_3 = 75, GAUDI2_QUEUE_ID_DCORE1_TPC_4_0 = 76, GAUDI2_QUEUE_ID_DCORE1_TPC_4_1 = 77, GAUDI2_QUEUE_ID_DCORE1_TPC_4_2 = 78, GAUDI2_QUEUE_ID_DCORE1_TPC_4_3 = 79, GAUDI2_QUEUE_ID_DCORE1_TPC_5_0 = 80, GAUDI2_QUEUE_ID_DCORE1_TPC_5_1 = 81, GAUDI2_QUEUE_ID_DCORE1_TPC_5_2 = 82, GAUDI2_QUEUE_ID_DCORE1_TPC_5_3 = 83, GAUDI2_QUEUE_ID_DCORE2_EDMA_0_0 = 84, GAUDI2_QUEUE_ID_DCORE2_EDMA_0_1 = 85, GAUDI2_QUEUE_ID_DCORE2_EDMA_0_2 = 86, GAUDI2_QUEUE_ID_DCORE2_EDMA_0_3 = 87, GAUDI2_QUEUE_ID_DCORE2_EDMA_1_0 = 88, GAUDI2_QUEUE_ID_DCORE2_EDMA_1_1 = 89, GAUDI2_QUEUE_ID_DCORE2_EDMA_1_2 = 90, GAUDI2_QUEUE_ID_DCORE2_EDMA_1_3 = 91, GAUDI2_QUEUE_ID_DCORE2_MME_0_0 = 92, GAUDI2_QUEUE_ID_DCORE2_MME_0_1 = 93, GAUDI2_QUEUE_ID_DCORE2_MME_0_2 = 94, GAUDI2_QUEUE_ID_DCORE2_MME_0_3 = 95, GAUDI2_QUEUE_ID_DCORE2_TPC_0_0 = 96, GAUDI2_QUEUE_ID_DCORE2_TPC_0_1 = 97, GAUDI2_QUEUE_ID_DCORE2_TPC_0_2 = 98, GAUDI2_QUEUE_ID_DCORE2_TPC_0_3 = 99, GAUDI2_QUEUE_ID_DCORE2_TPC_1_0 = 100, GAUDI2_QUEUE_ID_DCORE2_TPC_1_1 = 101, GAUDI2_QUEUE_ID_DCORE2_TPC_1_2 = 102, GAUDI2_QUEUE_ID_DCORE2_TPC_1_3 = 103, GAUDI2_QUEUE_ID_DCORE2_TPC_2_0 = 104, GAUDI2_QUEUE_ID_DCORE2_TPC_2_1 = 105, GAUDI2_QUEUE_ID_DCORE2_TPC_2_2 = 106, GAUDI2_QUEUE_ID_DCORE2_TPC_2_3 = 107, GAUDI2_QUEUE_ID_DCORE2_TPC_3_0 = 108, GAUDI2_QUEUE_ID_DCORE2_TPC_3_1 = 109, GAUDI2_QUEUE_ID_DCORE2_TPC_3_2 = 110, GAUDI2_QUEUE_ID_DCORE2_TPC_3_3 = 111, GAUDI2_QUEUE_ID_DCORE2_TPC_4_0 = 112, GAUDI2_QUEUE_ID_DCORE2_TPC_4_1 = 113, GAUDI2_QUEUE_ID_DCORE2_TPC_4_2 = 114, GAUDI2_QUEUE_ID_DCORE2_TPC_4_3 = 115, GAUDI2_QUEUE_ID_DCORE2_TPC_5_0 = 116, GAUDI2_QUEUE_ID_DCORE2_TPC_5_1 = 117, GAUDI2_QUEUE_ID_DCORE2_TPC_5_2 = 118, GAUDI2_QUEUE_ID_DCORE2_TPC_5_3 = 119, GAUDI2_QUEUE_ID_DCORE3_EDMA_0_0 = 120, GAUDI2_QUEUE_ID_DCORE3_EDMA_0_1 = 121, GAUDI2_QUEUE_ID_DCORE3_EDMA_0_2 = 122, GAUDI2_QUEUE_ID_DCORE3_EDMA_0_3 = 123, GAUDI2_QUEUE_ID_DCORE3_EDMA_1_0 = 124, GAUDI2_QUEUE_ID_DCORE3_EDMA_1_1 = 125, GAUDI2_QUEUE_ID_DCORE3_EDMA_1_2 = 126, GAUDI2_QUEUE_ID_DCORE3_EDMA_1_3 = 127, GAUDI2_QUEUE_ID_DCORE3_MME_0_0 = 128, GAUDI2_QUEUE_ID_DCORE3_MME_0_1 = 129, GAUDI2_QUEUE_ID_DCORE3_MME_0_2 = 130, GAUDI2_QUEUE_ID_DCORE3_MME_0_3 = 131, GAUDI2_QUEUE_ID_DCORE3_TPC_0_0 = 132, GAUDI2_QUEUE_ID_DCORE3_TPC_0_1 = 133, GAUDI2_QUEUE_ID_DCORE3_TPC_0_2 = 134, GAUDI2_QUEUE_ID_DCORE3_TPC_0_3 = 135, GAUDI2_QUEUE_ID_DCORE3_TPC_1_0 = 136, GAUDI2_QUEUE_ID_DCORE3_TPC_1_1 = 137, GAUDI2_QUEUE_ID_DCORE3_TPC_1_2 = 138, GAUDI2_QUEUE_ID_DCORE3_TPC_1_3 = 139, GAUDI2_QUEUE_ID_DCORE3_TPC_2_0 = 140, GAUDI2_QUEUE_ID_DCORE3_TPC_2_1 = 141, GAUDI2_QUEUE_ID_DCORE3_TPC_2_2 = 142, GAUDI2_QUEUE_ID_DCORE3_TPC_2_3 = 143, GAUDI2_QUEUE_ID_DCORE3_TPC_3_0 = 144, GAUDI2_QUEUE_ID_DCORE3_TPC_3_1 = 145, GAUDI2_QUEUE_ID_DCORE3_TPC_3_2 = 146, GAUDI2_QUEUE_ID_DCORE3_TPC_3_3 = 147, GAUDI2_QUEUE_ID_DCORE3_TPC_4_0 = 148, GAUDI2_QUEUE_ID_DCORE3_TPC_4_1 = 149, GAUDI2_QUEUE_ID_DCORE3_TPC_4_2 = 150, GAUDI2_QUEUE_ID_DCORE3_TPC_4_3 = 151, GAUDI2_QUEUE_ID_DCORE3_TPC_5_0 = 152, GAUDI2_QUEUE_ID_DCORE3_TPC_5_1 = 153, GAUDI2_QUEUE_ID_DCORE3_TPC_5_2 = 154, GAUDI2_QUEUE_ID_DCORE3_TPC_5_3 = 155, GAUDI2_QUEUE_ID_NIC_0_0 = 156, GAUDI2_QUEUE_ID_NIC_0_1 = 157, GAUDI2_QUEUE_ID_NIC_0_2 = 158, GAUDI2_QUEUE_ID_NIC_0_3 = 159, GAUDI2_QUEUE_ID_NIC_1_0 = 160, GAUDI2_QUEUE_ID_NIC_1_1 = 161, GAUDI2_QUEUE_ID_NIC_1_2 = 162, GAUDI2_QUEUE_ID_NIC_1_3 = 163, GAUDI2_QUEUE_ID_NIC_2_0 = 164, GAUDI2_QUEUE_ID_NIC_2_1 = 165, GAUDI2_QUEUE_ID_NIC_2_2 = 166, GAUDI2_QUEUE_ID_NIC_2_3 = 167, GAUDI2_QUEUE_ID_NIC_3_0 = 168, GAUDI2_QUEUE_ID_NIC_3_1 = 169, GAUDI2_QUEUE_ID_NIC_3_2 = 170, GAUDI2_QUEUE_ID_NIC_3_3 = 171, GAUDI2_QUEUE_ID_NIC_4_0 = 172, GAUDI2_QUEUE_ID_NIC_4_1 = 173, GAUDI2_QUEUE_ID_NIC_4_2 = 174, GAUDI2_QUEUE_ID_NIC_4_3 = 175, GAUDI2_QUEUE_ID_NIC_5_0 = 176, GAUDI2_QUEUE_ID_NIC_5_1 = 177, GAUDI2_QUEUE_ID_NIC_5_2 = 178, GAUDI2_QUEUE_ID_NIC_5_3 = 179, GAUDI2_QUEUE_ID_NIC_6_0 = 180, GAUDI2_QUEUE_ID_NIC_6_1 = 181, GAUDI2_QUEUE_ID_NIC_6_2 = 182, GAUDI2_QUEUE_ID_NIC_6_3 = 183, GAUDI2_QUEUE_ID_NIC_7_0 = 184, GAUDI2_QUEUE_ID_NIC_7_1 = 185, GAUDI2_QUEUE_ID_NIC_7_2 = 186, GAUDI2_QUEUE_ID_NIC_7_3 = 187, GAUDI2_QUEUE_ID_NIC_8_0 = 188, GAUDI2_QUEUE_ID_NIC_8_1 = 189, GAUDI2_QUEUE_ID_NIC_8_2 = 190, GAUDI2_QUEUE_ID_NIC_8_3 = 191, GAUDI2_QUEUE_ID_NIC_9_0 = 192, GAUDI2_QUEUE_ID_NIC_9_1 = 193, GAUDI2_QUEUE_ID_NIC_9_2 = 194, GAUDI2_QUEUE_ID_NIC_9_3 = 195, GAUDI2_QUEUE_ID_NIC_10_0 = 196, GAUDI2_QUEUE_ID_NIC_10_1 = 197, GAUDI2_QUEUE_ID_NIC_10_2 = 198, GAUDI2_QUEUE_ID_NIC_10_3 = 199, GAUDI2_QUEUE_ID_NIC_11_0 = 200, GAUDI2_QUEUE_ID_NIC_11_1 = 201, GAUDI2_QUEUE_ID_NIC_11_2 = 202, GAUDI2_QUEUE_ID_NIC_11_3 = 203, GAUDI2_QUEUE_ID_NIC_12_0 = 204, GAUDI2_QUEUE_ID_NIC_12_1 = 205, GAUDI2_QUEUE_ID_NIC_12_2 = 206, GAUDI2_QUEUE_ID_NIC_12_3 = 207, GAUDI2_QUEUE_ID_NIC_13_0 = 208, GAUDI2_QUEUE_ID_NIC_13_1 = 209, GAUDI2_QUEUE_ID_NIC_13_2 = 210, GAUDI2_QUEUE_ID_NIC_13_3 = 211, GAUDI2_QUEUE_ID_NIC_14_0 = 212, GAUDI2_QUEUE_ID_NIC_14_1 = 213, GAUDI2_QUEUE_ID_NIC_14_2 = 214, GAUDI2_QUEUE_ID_NIC_14_3 = 215, GAUDI2_QUEUE_ID_NIC_15_0 = 216, GAUDI2_QUEUE_ID_NIC_15_1 = 217, GAUDI2_QUEUE_ID_NIC_15_2 = 218, GAUDI2_QUEUE_ID_NIC_15_3 = 219, GAUDI2_QUEUE_ID_NIC_16_0 = 220, GAUDI2_QUEUE_ID_NIC_16_1 = 221, GAUDI2_QUEUE_ID_NIC_16_2 = 222, GAUDI2_QUEUE_ID_NIC_16_3 = 223, GAUDI2_QUEUE_ID_NIC_17_0 = 224, GAUDI2_QUEUE_ID_NIC_17_1 = 225, GAUDI2_QUEUE_ID_NIC_17_2 = 226, GAUDI2_QUEUE_ID_NIC_17_3 = 227, GAUDI2_QUEUE_ID_NIC_18_0 = 228, GAUDI2_QUEUE_ID_NIC_18_1 = 229, GAUDI2_QUEUE_ID_NIC_18_2 = 230, GAUDI2_QUEUE_ID_NIC_18_3 = 231, GAUDI2_QUEUE_ID_NIC_19_0 = 232, GAUDI2_QUEUE_ID_NIC_19_1 = 233, GAUDI2_QUEUE_ID_NIC_19_2 = 234, GAUDI2_QUEUE_ID_NIC_19_3 = 235, GAUDI2_QUEUE_ID_NIC_20_0 = 236, GAUDI2_QUEUE_ID_NIC_20_1 = 237, GAUDI2_QUEUE_ID_NIC_20_2 = 238, GAUDI2_QUEUE_ID_NIC_20_3 = 239, GAUDI2_QUEUE_ID_NIC_21_0 = 240, GAUDI2_QUEUE_ID_NIC_21_1 = 241, GAUDI2_QUEUE_ID_NIC_21_2 = 242, GAUDI2_QUEUE_ID_NIC_21_3 = 243, GAUDI2_QUEUE_ID_NIC_22_0 = 244, GAUDI2_QUEUE_ID_NIC_22_1 = 245, GAUDI2_QUEUE_ID_NIC_22_2 = 246, GAUDI2_QUEUE_ID_NIC_22_3 = 247, GAUDI2_QUEUE_ID_NIC_23_0 = 248, GAUDI2_QUEUE_ID_NIC_23_1 = 249, GAUDI2_QUEUE_ID_NIC_23_2 = 250, GAUDI2_QUEUE_ID_NIC_23_3 = 251, GAUDI2_QUEUE_ID_ROT_0_0 = 252, GAUDI2_QUEUE_ID_ROT_0_1 = 253, GAUDI2_QUEUE_ID_ROT_0_2 = 254, GAUDI2_QUEUE_ID_ROT_0_3 = 255, GAUDI2_QUEUE_ID_ROT_1_0 = 256, GAUDI2_QUEUE_ID_ROT_1_1 = 257, GAUDI2_QUEUE_ID_ROT_1_2 = 258, GAUDI2_QUEUE_ID_ROT_1_3 = 259, GAUDI2_QUEUE_ID_CPU_PQ = 260, GAUDI2_QUEUE_ID_SIZE }; /* * Engine Numbering * * Used in the "busy_engines_mask" field in `struct hl_info_hw_idle' */ enum goya_engine_id { GOYA_ENGINE_ID_DMA_0 = 0, GOYA_ENGINE_ID_DMA_1, GOYA_ENGINE_ID_DMA_2, GOYA_ENGINE_ID_DMA_3, GOYA_ENGINE_ID_DMA_4, GOYA_ENGINE_ID_MME_0, GOYA_ENGINE_ID_TPC_0, GOYA_ENGINE_ID_TPC_1, GOYA_ENGINE_ID_TPC_2, GOYA_ENGINE_ID_TPC_3, GOYA_ENGINE_ID_TPC_4, GOYA_ENGINE_ID_TPC_5, GOYA_ENGINE_ID_TPC_6, GOYA_ENGINE_ID_TPC_7, GOYA_ENGINE_ID_SIZE }; enum gaudi_engine_id { GAUDI_ENGINE_ID_DMA_0 = 0, GAUDI_ENGINE_ID_DMA_1, GAUDI_ENGINE_ID_DMA_2, GAUDI_ENGINE_ID_DMA_3, GAUDI_ENGINE_ID_DMA_4, GAUDI_ENGINE_ID_DMA_5, GAUDI_ENGINE_ID_DMA_6, GAUDI_ENGINE_ID_DMA_7, GAUDI_ENGINE_ID_MME_0, GAUDI_ENGINE_ID_MME_1, GAUDI_ENGINE_ID_MME_2, GAUDI_ENGINE_ID_MME_3, GAUDI_ENGINE_ID_TPC_0, GAUDI_ENGINE_ID_TPC_1, GAUDI_ENGINE_ID_TPC_2, GAUDI_ENGINE_ID_TPC_3, GAUDI_ENGINE_ID_TPC_4, GAUDI_ENGINE_ID_TPC_5, GAUDI_ENGINE_ID_TPC_6, GAUDI_ENGINE_ID_TPC_7, GAUDI_ENGINE_ID_NIC_0, GAUDI_ENGINE_ID_NIC_1, GAUDI_ENGINE_ID_NIC_2, GAUDI_ENGINE_ID_NIC_3, GAUDI_ENGINE_ID_NIC_4, GAUDI_ENGINE_ID_NIC_5, GAUDI_ENGINE_ID_NIC_6, GAUDI_ENGINE_ID_NIC_7, GAUDI_ENGINE_ID_NIC_8, GAUDI_ENGINE_ID_NIC_9, GAUDI_ENGINE_ID_SIZE }; enum gaudi2_engine_id { GAUDI2_DCORE0_ENGINE_ID_EDMA_0 = 0, GAUDI2_DCORE0_ENGINE_ID_EDMA_1, GAUDI2_DCORE0_ENGINE_ID_MME, GAUDI2_DCORE0_ENGINE_ID_TPC_0, GAUDI2_DCORE0_ENGINE_ID_TPC_1, GAUDI2_DCORE0_ENGINE_ID_TPC_2, GAUDI2_DCORE0_ENGINE_ID_TPC_3, GAUDI2_DCORE0_ENGINE_ID_TPC_4, GAUDI2_DCORE0_ENGINE_ID_TPC_5, GAUDI2_DCORE0_ENGINE_ID_DEC_0, GAUDI2_DCORE0_ENGINE_ID_DEC_1, GAUDI2_DCORE1_ENGINE_ID_EDMA_0, GAUDI2_DCORE1_ENGINE_ID_EDMA_1, GAUDI2_DCORE1_ENGINE_ID_MME, GAUDI2_DCORE1_ENGINE_ID_TPC_0, GAUDI2_DCORE1_ENGINE_ID_TPC_1, GAUDI2_DCORE1_ENGINE_ID_TPC_2, GAUDI2_DCORE1_ENGINE_ID_TPC_3, GAUDI2_DCORE1_ENGINE_ID_TPC_4, GAUDI2_DCORE1_ENGINE_ID_TPC_5, GAUDI2_DCORE1_ENGINE_ID_DEC_0, GAUDI2_DCORE1_ENGINE_ID_DEC_1, GAUDI2_DCORE2_ENGINE_ID_EDMA_0, GAUDI2_DCORE2_ENGINE_ID_EDMA_1, GAUDI2_DCORE2_ENGINE_ID_MME, GAUDI2_DCORE2_ENGINE_ID_TPC_0, GAUDI2_DCORE2_ENGINE_ID_TPC_1, GAUDI2_DCORE2_ENGINE_ID_TPC_2, GAUDI2_DCORE2_ENGINE_ID_TPC_3, GAUDI2_DCORE2_ENGINE_ID_TPC_4, GAUDI2_DCORE2_ENGINE_ID_TPC_5, GAUDI2_DCORE2_ENGINE_ID_DEC_0, GAUDI2_DCORE2_ENGINE_ID_DEC_1, GAUDI2_DCORE3_ENGINE_ID_EDMA_0, GAUDI2_DCORE3_ENGINE_ID_EDMA_1, GAUDI2_DCORE3_ENGINE_ID_MME, GAUDI2_DCORE3_ENGINE_ID_TPC_0, GAUDI2_DCORE3_ENGINE_ID_TPC_1, GAUDI2_DCORE3_ENGINE_ID_TPC_2, GAUDI2_DCORE3_ENGINE_ID_TPC_3, GAUDI2_DCORE3_ENGINE_ID_TPC_4, GAUDI2_DCORE3_ENGINE_ID_TPC_5, GAUDI2_DCORE3_ENGINE_ID_DEC_0, GAUDI2_DCORE3_ENGINE_ID_DEC_1, GAUDI2_DCORE0_ENGINE_ID_TPC_6, GAUDI2_ENGINE_ID_PDMA_0, GAUDI2_ENGINE_ID_PDMA_1, GAUDI2_ENGINE_ID_ROT_0, GAUDI2_ENGINE_ID_ROT_1, GAUDI2_PCIE_ENGINE_ID_DEC_0, GAUDI2_PCIE_ENGINE_ID_DEC_1, GAUDI2_ENGINE_ID_NIC0_0, GAUDI2_ENGINE_ID_NIC0_1, GAUDI2_ENGINE_ID_NIC1_0, GAUDI2_ENGINE_ID_NIC1_1, GAUDI2_ENGINE_ID_NIC2_0, GAUDI2_ENGINE_ID_NIC2_1, GAUDI2_ENGINE_ID_NIC3_0, GAUDI2_ENGINE_ID_NIC3_1, GAUDI2_ENGINE_ID_NIC4_0, GAUDI2_ENGINE_ID_NIC4_1, GAUDI2_ENGINE_ID_NIC5_0, GAUDI2_ENGINE_ID_NIC5_1, GAUDI2_ENGINE_ID_NIC6_0, GAUDI2_ENGINE_ID_NIC6_1, GAUDI2_ENGINE_ID_NIC7_0, GAUDI2_ENGINE_ID_NIC7_1, GAUDI2_ENGINE_ID_NIC8_0, GAUDI2_ENGINE_ID_NIC8_1, GAUDI2_ENGINE_ID_NIC9_0, GAUDI2_ENGINE_ID_NIC9_1, GAUDI2_ENGINE_ID_NIC10_0, GAUDI2_ENGINE_ID_NIC10_1, GAUDI2_ENGINE_ID_NIC11_0, GAUDI2_ENGINE_ID_NIC11_1, GAUDI2_ENGINE_ID_PCIE, GAUDI2_ENGINE_ID_PSOC, GAUDI2_ENGINE_ID_ARC_FARM, GAUDI2_ENGINE_ID_KDMA, GAUDI2_ENGINE_ID_SIZE }; /* * ASIC specific PLL index * * Used to retrieve in frequency info of different IPs via HL_INFO_PLL_FREQUENCY under * DRM_IOCTL_HL_INFO IOCTL. * The enums need to be used as an index in struct hl_pll_frequency_info. */ enum hl_goya_pll_index { HL_GOYA_CPU_PLL = 0, HL_GOYA_IC_PLL, HL_GOYA_MC_PLL, HL_GOYA_MME_PLL, HL_GOYA_PCI_PLL, HL_GOYA_EMMC_PLL, HL_GOYA_TPC_PLL, HL_GOYA_PLL_MAX }; enum hl_gaudi_pll_index { HL_GAUDI_CPU_PLL = 0, HL_GAUDI_PCI_PLL, HL_GAUDI_SRAM_PLL, HL_GAUDI_HBM_PLL, HL_GAUDI_NIC_PLL, HL_GAUDI_DMA_PLL, HL_GAUDI_MESH_PLL, HL_GAUDI_MME_PLL, HL_GAUDI_TPC_PLL, HL_GAUDI_IF_PLL, HL_GAUDI_PLL_MAX }; enum hl_gaudi2_pll_index { HL_GAUDI2_CPU_PLL = 0, HL_GAUDI2_PCI_PLL, HL_GAUDI2_SRAM_PLL, HL_GAUDI2_HBM_PLL, HL_GAUDI2_NIC_PLL, HL_GAUDI2_DMA_PLL, HL_GAUDI2_MESH_PLL, HL_GAUDI2_MME_PLL, HL_GAUDI2_TPC_PLL, HL_GAUDI2_IF_PLL, HL_GAUDI2_VID_PLL, HL_GAUDI2_MSS_PLL, HL_GAUDI2_PLL_MAX }; /** * enum hl_goya_dma_direction - Direction of DMA operation inside a LIN_DMA packet that is * submitted to the GOYA's DMA QMAN. This attribute is not relevant * to the H/W but the kernel driver use it to parse the packet's * addresses and patch/validate them. * @HL_DMA_HOST_TO_DRAM: DMA operation from Host memory to GOYA's DDR. * @HL_DMA_HOST_TO_SRAM: DMA operation from Host memory to GOYA's SRAM. * @HL_DMA_DRAM_TO_SRAM: DMA operation from GOYA's DDR to GOYA's SRAM. * @HL_DMA_SRAM_TO_DRAM: DMA operation from GOYA's SRAM to GOYA's DDR. * @HL_DMA_SRAM_TO_HOST: DMA operation from GOYA's SRAM to Host memory. * @HL_DMA_DRAM_TO_HOST: DMA operation from GOYA's DDR to Host memory. * @HL_DMA_DRAM_TO_DRAM: DMA operation from GOYA's DDR to GOYA's DDR. * @HL_DMA_SRAM_TO_SRAM: DMA operation from GOYA's SRAM to GOYA's SRAM. * @HL_DMA_ENUM_MAX: number of values in enum */ enum hl_goya_dma_direction { HL_DMA_HOST_TO_DRAM, HL_DMA_HOST_TO_SRAM, HL_DMA_DRAM_TO_SRAM, HL_DMA_SRAM_TO_DRAM, HL_DMA_SRAM_TO_HOST, HL_DMA_DRAM_TO_HOST, HL_DMA_DRAM_TO_DRAM, HL_DMA_SRAM_TO_SRAM, HL_DMA_ENUM_MAX }; /** * enum hl_device_status - Device status information. * @HL_DEVICE_STATUS_OPERATIONAL: Device is operational. * @HL_DEVICE_STATUS_IN_RESET: Device is currently during reset. * @HL_DEVICE_STATUS_MALFUNCTION: Device is unusable. * @HL_DEVICE_STATUS_NEEDS_RESET: Device needs reset because auto reset was disabled. * @HL_DEVICE_STATUS_IN_DEVICE_CREATION: Device is operational but its creation is still in * progress. * @HL_DEVICE_STATUS_IN_RESET_AFTER_DEVICE_RELEASE: Device is currently during reset that was * triggered because the user released the device * @HL_DEVICE_STATUS_LAST: Last status. */ enum hl_device_status { HL_DEVICE_STATUS_OPERATIONAL, HL_DEVICE_STATUS_IN_RESET, HL_DEVICE_STATUS_MALFUNCTION, HL_DEVICE_STATUS_NEEDS_RESET, HL_DEVICE_STATUS_IN_DEVICE_CREATION, HL_DEVICE_STATUS_IN_RESET_AFTER_DEVICE_RELEASE, HL_DEVICE_STATUS_LAST = HL_DEVICE_STATUS_IN_RESET_AFTER_DEVICE_RELEASE }; enum hl_server_type { HL_SERVER_TYPE_UNKNOWN = 0, HL_SERVER_GAUDI_HLS1 = 1, HL_SERVER_GAUDI_HLS1H = 2, HL_SERVER_GAUDI_TYPE1 = 3, HL_SERVER_GAUDI_TYPE2 = 4, HL_SERVER_GAUDI2_HLS2 = 5, HL_SERVER_GAUDI2_TYPE1 = 7 }; /* * Notifier event values - for the notification mechanism and the HL_INFO_GET_EVENTS command * * HL_NOTIFIER_EVENT_TPC_ASSERT - Indicates TPC assert event * HL_NOTIFIER_EVENT_UNDEFINED_OPCODE - Indicates undefined operation code * HL_NOTIFIER_EVENT_DEVICE_RESET - Indicates device requires a reset * HL_NOTIFIER_EVENT_CS_TIMEOUT - Indicates CS timeout error * HL_NOTIFIER_EVENT_DEVICE_UNAVAILABLE - Indicates device is unavailable * HL_NOTIFIER_EVENT_USER_ENGINE_ERR - Indicates device engine in error state * HL_NOTIFIER_EVENT_GENERAL_HW_ERR - Indicates device HW error * HL_NOTIFIER_EVENT_RAZWI - Indicates razwi happened * HL_NOTIFIER_EVENT_PAGE_FAULT - Indicates page fault happened * HL_NOTIFIER_EVENT_CRITICAL_HW_ERR - Indicates a HW error that requires SW abort and * HW reset * HL_NOTIFIER_EVENT_CRITICAL_FW_ERR - Indicates a FW error that requires SW abort and * HW reset */ #define HL_NOTIFIER_EVENT_TPC_ASSERT (1ULL << 0) #define HL_NOTIFIER_EVENT_UNDEFINED_OPCODE (1ULL << 1) #define HL_NOTIFIER_EVENT_DEVICE_RESET (1ULL << 2) #define HL_NOTIFIER_EVENT_CS_TIMEOUT (1ULL << 3) #define HL_NOTIFIER_EVENT_DEVICE_UNAVAILABLE (1ULL << 4) #define HL_NOTIFIER_EVENT_USER_ENGINE_ERR (1ULL << 5) #define HL_NOTIFIER_EVENT_GENERAL_HW_ERR (1ULL << 6) #define HL_NOTIFIER_EVENT_RAZWI (1ULL << 7) #define HL_NOTIFIER_EVENT_PAGE_FAULT (1ULL << 8) #define HL_NOTIFIER_EVENT_CRITICL_HW_ERR (1ULL << 9) #define HL_NOTIFIER_EVENT_CRITICL_FW_ERR (1ULL << 10) /* Opcode for management ioctl * * HW_IP_INFO - Receive information about different IP blocks in the * device. * HL_INFO_HW_EVENTS - Receive an array describing how many times each event * occurred since the last hard reset. * HL_INFO_DRAM_USAGE - Retrieve the dram usage inside the device and of the * specific context. This is relevant only for devices * where the dram is managed by the kernel driver * HL_INFO_HW_IDLE - Retrieve information about the idle status of each * internal engine. * HL_INFO_DEVICE_STATUS - Retrieve the device's status. This opcode doesn't * require an open context. * HL_INFO_DEVICE_UTILIZATION - Retrieve the total utilization of the device * over the last period specified by the user. * The period can be between 100ms to 1s, in * resolution of 100ms. The return value is a * percentage of the utilization rate. * HL_INFO_HW_EVENTS_AGGREGATE - Receive an array describing how many times each * event occurred since the driver was loaded. * HL_INFO_CLK_RATE - Retrieve the current and maximum clock rate * of the device in MHz. The maximum clock rate is * configurable via sysfs parameter * HL_INFO_RESET_COUNT - Retrieve the counts of the soft and hard reset * operations performed on the device since the last * time the driver was loaded. * HL_INFO_TIME_SYNC - Retrieve the device's time alongside the host's time * for synchronization. * HL_INFO_CS_COUNTERS - Retrieve command submission counters * HL_INFO_PCI_COUNTERS - Retrieve PCI counters * HL_INFO_CLK_THROTTLE_REASON - Retrieve clock throttling reason * HL_INFO_SYNC_MANAGER - Retrieve sync manager info per dcore * HL_INFO_TOTAL_ENERGY - Retrieve total energy consumption * HL_INFO_PLL_FREQUENCY - Retrieve PLL frequency * HL_INFO_POWER - Retrieve power information * HL_INFO_OPEN_STATS - Retrieve info regarding recent device open calls * HL_INFO_DRAM_REPLACED_ROWS - Retrieve DRAM replaced rows info * HL_INFO_DRAM_PENDING_ROWS - Retrieve DRAM pending rows num * HL_INFO_LAST_ERR_OPEN_DEV_TIME - Retrieve timestamp of the last time the device was opened * and CS timeout or razwi error occurred. * HL_INFO_CS_TIMEOUT_EVENT - Retrieve CS timeout timestamp and its related CS sequence number. * HL_INFO_RAZWI_EVENT - Retrieve parameters of razwi: * Timestamp of razwi. * The address which accessing it caused the razwi. * Razwi initiator. * Razwi cause, was it a page fault or MMU access error. * May return 0 even though no new data is available, in that case * timestamp will be 0. * HL_INFO_DEV_MEM_ALLOC_PAGE_SIZES - Retrieve valid page sizes for device memory allocation * HL_INFO_SECURED_ATTESTATION - Retrieve attestation report of the boot. * HL_INFO_REGISTER_EVENTFD - Register eventfd for event notifications. * HL_INFO_UNREGISTER_EVENTFD - Unregister eventfd * HL_INFO_GET_EVENTS - Retrieve the last occurred events * HL_INFO_UNDEFINED_OPCODE_EVENT - Retrieve last undefined opcode error information. * May return 0 even though no new data is available, in that case * timestamp will be 0. * HL_INFO_ENGINE_STATUS - Retrieve the status of all the h/w engines in the asic. * HL_INFO_PAGE_FAULT_EVENT - Retrieve parameters of captured page fault. * May return 0 even though no new data is available, in that case * timestamp will be 0. * HL_INFO_USER_MAPPINGS - Retrieve user mappings, captured after page fault event. * HL_INFO_FW_GENERIC_REQ - Send generic request to FW. * HL_INFO_HW_ERR_EVENT - Retrieve information on the reported HW error. * May return 0 even though no new data is available, in that case * timestamp will be 0. * HL_INFO_FW_ERR_EVENT - Retrieve information on the reported FW error. * May return 0 even though no new data is available, in that case * timestamp will be 0. * HL_INFO_USER_ENGINE_ERR_EVENT - Retrieve the last engine id that reported an error. */ #define HL_INFO_HW_IP_INFO 0 #define HL_INFO_HW_EVENTS 1 #define HL_INFO_DRAM_USAGE 2 #define HL_INFO_HW_IDLE 3 #define HL_INFO_DEVICE_STATUS 4 #define HL_INFO_DEVICE_UTILIZATION 6 #define HL_INFO_HW_EVENTS_AGGREGATE 7 #define HL_INFO_CLK_RATE 8 #define HL_INFO_RESET_COUNT 9 #define HL_INFO_TIME_SYNC 10 #define HL_INFO_CS_COUNTERS 11 #define HL_INFO_PCI_COUNTERS 12 #define HL_INFO_CLK_THROTTLE_REASON 13 #define HL_INFO_SYNC_MANAGER 14 #define HL_INFO_TOTAL_ENERGY 15 #define HL_INFO_PLL_FREQUENCY 16 #define HL_INFO_POWER 17 #define HL_INFO_OPEN_STATS 18 #define HL_INFO_DRAM_REPLACED_ROWS 21 #define HL_INFO_DRAM_PENDING_ROWS 22 #define HL_INFO_LAST_ERR_OPEN_DEV_TIME 23 #define HL_INFO_CS_TIMEOUT_EVENT 24 #define HL_INFO_RAZWI_EVENT 25 #define HL_INFO_DEV_MEM_ALLOC_PAGE_SIZES 26 #define HL_INFO_SECURED_ATTESTATION 27 #define HL_INFO_REGISTER_EVENTFD 28 #define HL_INFO_UNREGISTER_EVENTFD 29 #define HL_INFO_GET_EVENTS 30 #define HL_INFO_UNDEFINED_OPCODE_EVENT 31 #define HL_INFO_ENGINE_STATUS 32 #define HL_INFO_PAGE_FAULT_EVENT 33 #define HL_INFO_USER_MAPPINGS 34 #define HL_INFO_FW_GENERIC_REQ 35 #define HL_INFO_HW_ERR_EVENT 36 #define HL_INFO_FW_ERR_EVENT 37 #define HL_INFO_USER_ENGINE_ERR_EVENT 38 #define HL_INFO_DEV_SIGNED 40 #define HL_INFO_VERSION_MAX_LEN 128 #define HL_INFO_CARD_NAME_MAX_LEN 16 /* Maximum buffer size for retrieving engines status */ #define HL_ENGINES_DATA_MAX_SIZE SZ_1M /** * struct hl_info_hw_ip_info - hardware information on various IPs in the ASIC * @sram_base_address: The first SRAM physical base address that is free to be * used by the user. * @dram_base_address: The first DRAM virtual or physical base address that is * free to be used by the user. * @dram_size: The DRAM size that is available to the user. * @sram_size: The SRAM size that is available to the user. * @num_of_events: The number of events that can be received from the f/w. This * is needed so the user can what is the size of the h/w events * array he needs to pass to the kernel when he wants to fetch * the event counters. * @device_id: PCI device ID of the ASIC. * @module_id: Module ID of the ASIC for mezzanine cards in servers * (From OCP spec). * @decoder_enabled_mask: Bit-mask that represents which decoders are enabled. * @first_available_interrupt_id: The first available interrupt ID for the user * to be used when it works with user interrupts. * Relevant for Gaudi2 and later. * @server_type: Server type that the Gaudi ASIC is currently installed in. * The value is according to enum hl_server_type * @cpld_version: CPLD version on the board. * @psoc_pci_pll_nr: PCI PLL NR value. Needed by the profiler in some ASICs. * @psoc_pci_pll_nf: PCI PLL NF value. Needed by the profiler in some ASICs. * @psoc_pci_pll_od: PCI PLL OD value. Needed by the profiler in some ASICs. * @psoc_pci_pll_div_factor: PCI PLL DIV factor value. Needed by the profiler * in some ASICs. * @tpc_enabled_mask: Bit-mask that represents which TPCs are enabled. Relevant * for Goya/Gaudi only. * @dram_enabled: Whether the DRAM is enabled. * @security_enabled: Whether security is enabled on device. * @mme_master_slave_mode: Indicate whether the MME is working in master/slave * configuration. Relevant for Gaudi2 and later. * @cpucp_version: The CPUCP f/w version. * @card_name: The card name as passed by the f/w. * @tpc_enabled_mask_ext: Bit-mask that represents which TPCs are enabled. * Relevant for Gaudi2 and later. * @dram_page_size: The DRAM physical page size. * @edma_enabled_mask: Bit-mask that represents which EDMAs are enabled. * Relevant for Gaudi2 and later. * @number_of_user_interrupts: The number of interrupts that are available to the userspace * application to use. Relevant for Gaudi2 and later. * @device_mem_alloc_default_page_size: default page size used in device memory allocation. * @revision_id: PCI revision ID of the ASIC. * @tpc_interrupt_id: interrupt id for TPC to use in order to raise events towards the host. * @rotator_enabled_mask: Bit-mask that represents which rotators are enabled. * Relevant for Gaudi3 and later. * @engine_core_interrupt_reg_addr: interrupt register address for engine core to use * in order to raise events toward FW. * @reserved_dram_size: DRAM size reserved for driver and firmware. */ struct hl_info_hw_ip_info { __u64 sram_base_address; __u64 dram_base_address; __u64 dram_size; __u32 sram_size; __u32 num_of_events; __u32 device_id; __u32 module_id; __u32 decoder_enabled_mask; __u16 first_available_interrupt_id; __u16 server_type; __u32 cpld_version; __u32 psoc_pci_pll_nr; __u32 psoc_pci_pll_nf; __u32 psoc_pci_pll_od; __u32 psoc_pci_pll_div_factor; __u8 tpc_enabled_mask; __u8 dram_enabled; __u8 security_enabled; __u8 mme_master_slave_mode; __u8 cpucp_version[HL_INFO_VERSION_MAX_LEN]; __u8 card_name[HL_INFO_CARD_NAME_MAX_LEN]; __u64 tpc_enabled_mask_ext; __u64 dram_page_size; __u32 edma_enabled_mask; __u16 number_of_user_interrupts; __u8 reserved1; __u8 reserved2; __u64 reserved3; __u64 device_mem_alloc_default_page_size; __u64 reserved4; __u64 reserved5; __u32 reserved6; __u8 reserved7; __u8 revision_id; __u16 tpc_interrupt_id; __u32 rotator_enabled_mask; __u32 reserved9; __u64 engine_core_interrupt_reg_addr; __u64 reserved_dram_size; }; struct hl_info_dram_usage { __u64 dram_free_mem; __u64 ctx_dram_mem; }; #define HL_BUSY_ENGINES_MASK_EXT_SIZE 4 struct hl_info_hw_idle { __u32 is_idle; /* * Bitmask of busy engines. * Bits definition is according to `enum <chip>_engine_id'. */ __u32 busy_engines_mask; /* * Extended Bitmask of busy engines. * Bits definition is according to `enum <chip>_engine_id'. */ __u64 busy_engines_mask_ext[HL_BUSY_ENGINES_MASK_EXT_SIZE]; }; struct hl_info_device_status { __u32 status; __u32 pad; }; struct hl_info_device_utilization { __u32 utilization; __u32 pad; }; struct hl_info_clk_rate { __u32 cur_clk_rate_mhz; __u32 max_clk_rate_mhz; }; struct hl_info_reset_count { __u32 hard_reset_cnt; __u32 soft_reset_cnt; }; struct hl_info_time_sync { __u64 device_time; __u64 host_time; __u64 tsc_time; }; /** * struct hl_info_pci_counters - pci counters * @rx_throughput: PCI rx throughput KBps * @tx_throughput: PCI tx throughput KBps * @replay_cnt: PCI replay counter */ struct hl_info_pci_counters { __u64 rx_throughput; __u64 tx_throughput; __u64 replay_cnt; }; enum hl_clk_throttling_type { HL_CLK_THROTTLE_TYPE_POWER, HL_CLK_THROTTLE_TYPE_THERMAL, HL_CLK_THROTTLE_TYPE_MAX }; /* clk_throttling_reason masks */ #define HL_CLK_THROTTLE_POWER (1 << HL_CLK_THROTTLE_TYPE_POWER) #define HL_CLK_THROTTLE_THERMAL (1 << HL_CLK_THROTTLE_TYPE_THERMAL) /** * struct hl_info_clk_throttle - clock throttling reason * @clk_throttling_reason: each bit represents a clk throttling reason * @clk_throttling_timestamp_us: represents CPU timestamp in microseconds of the start-event * @clk_throttling_duration_ns: the clock throttle time in nanosec */ struct hl_info_clk_throttle { __u32 clk_throttling_reason; __u32 pad; __u64 clk_throttling_timestamp_us[HL_CLK_THROTTLE_TYPE_MAX]; __u64 clk_throttling_duration_ns[HL_CLK_THROTTLE_TYPE_MAX]; }; /** * struct hl_info_energy - device energy information * @total_energy_consumption: total device energy consumption */ struct hl_info_energy { __u64 total_energy_consumption; }; #define HL_PLL_NUM_OUTPUTS 4 struct hl_pll_frequency_info { __u16 output[HL_PLL_NUM_OUTPUTS]; }; /** * struct hl_open_stats_info - device open statistics information * @open_counter: ever growing counter, increased on each successful dev open * @last_open_period_ms: duration (ms) device was open last time * @is_compute_ctx_active: Whether there is an active compute context executing * @compute_ctx_in_release: true if the current compute context is being released */ struct hl_open_stats_info { __u64 open_counter; __u64 last_open_period_ms; __u8 is_compute_ctx_active; __u8 compute_ctx_in_release; __u8 pad[6]; }; /** * struct hl_power_info - power information * @power: power consumption */ struct hl_power_info { __u64 power; }; /** * struct hl_info_sync_manager - sync manager information * @first_available_sync_object: first available sob * @first_available_monitor: first available monitor * @first_available_cq: first available cq */ struct hl_info_sync_manager { __u32 first_available_sync_object; __u32 first_available_monitor; __u32 first_available_cq; __u32 reserved; }; /** * struct hl_info_cs_counters - command submission counters * @total_out_of_mem_drop_cnt: total dropped due to memory allocation issue * @ctx_out_of_mem_drop_cnt: context dropped due to memory allocation issue * @total_parsing_drop_cnt: total dropped due to error in packet parsing * @ctx_parsing_drop_cnt: context dropped due to error in packet parsing * @total_queue_full_drop_cnt: total dropped due to queue full * @ctx_queue_full_drop_cnt: context dropped due to queue full * @total_device_in_reset_drop_cnt: total dropped due to device in reset * @ctx_device_in_reset_drop_cnt: context dropped due to device in reset * @total_max_cs_in_flight_drop_cnt: total dropped due to maximum CS in-flight * @ctx_max_cs_in_flight_drop_cnt: context dropped due to maximum CS in-flight * @total_validation_drop_cnt: total dropped due to validation error * @ctx_validation_drop_cnt: context dropped due to validation error */ struct hl_info_cs_counters { __u64 total_out_of_mem_drop_cnt; __u64 ctx_out_of_mem_drop_cnt; __u64 total_parsing_drop_cnt; __u64 ctx_parsing_drop_cnt; __u64 total_queue_full_drop_cnt; __u64 ctx_queue_full_drop_cnt; __u64 total_device_in_reset_drop_cnt; __u64 ctx_device_in_reset_drop_cnt; __u64 total_max_cs_in_flight_drop_cnt; __u64 ctx_max_cs_in_flight_drop_cnt; __u64 total_validation_drop_cnt; __u64 ctx_validation_drop_cnt; }; /** * struct hl_info_last_err_open_dev_time - last error boot information. * @timestamp: timestamp of last time the device was opened and error occurred. */ struct hl_info_last_err_open_dev_time { __s64 timestamp; }; /** * struct hl_info_cs_timeout_event - last CS timeout information. * @timestamp: timestamp when last CS timeout event occurred. * @seq: sequence number of last CS timeout event. */ struct hl_info_cs_timeout_event { __s64 timestamp; __u64 seq; }; #define HL_RAZWI_NA_ENG_ID U16_MAX #define HL_RAZWI_MAX_NUM_OF_ENGINES_PER_RTR 128 #define HL_RAZWI_READ BIT(0) #define HL_RAZWI_WRITE BIT(1) #define HL_RAZWI_LBW BIT(2) #define HL_RAZWI_HBW BIT(3) #define HL_RAZWI_RR BIT(4) #define HL_RAZWI_ADDR_DEC BIT(5) /** * struct hl_info_razwi_event - razwi information. * @timestamp: timestamp of razwi. * @addr: address which accessing it caused razwi. * @engine_id: engine id of the razwi initiator, if it was initiated by engine that does not * have engine id it will be set to HL_RAZWI_NA_ENG_ID. If there are several possible * engines which caused the razwi, it will hold all of them. * @num_of_possible_engines: contains number of possible engine ids. In some asics, razwi indication * might be common for several engines and there is no way to get the * exact engine. In this way, engine_id array will be filled with all * possible engines caused this razwi. Also, there might be possibility * in gaudi, where we don't indication on specific engine, in that case * the value of this parameter will be zero. * @flags: bitmask for additional data: HL_RAZWI_READ - razwi caused by read operation * HL_RAZWI_WRITE - razwi caused by write operation * HL_RAZWI_LBW - razwi caused by lbw fabric transaction * HL_RAZWI_HBW - razwi caused by hbw fabric transaction * HL_RAZWI_RR - razwi caused by range register * HL_RAZWI_ADDR_DEC - razwi caused by address decode error * Note: this data is not supported by all asics, in that case the relevant bits will not * be set. */ struct hl_info_razwi_event { __s64 timestamp; __u64 addr; __u16 engine_id[HL_RAZWI_MAX_NUM_OF_ENGINES_PER_RTR]; __u16 num_of_possible_engines; __u8 flags; __u8 pad[5]; }; #define MAX_QMAN_STREAMS_INFO 4 #define OPCODE_INFO_MAX_ADDR_SIZE 8 /** * struct hl_info_undefined_opcode_event - info about last undefined opcode error * @timestamp: timestamp of the undefined opcode error * @cb_addr_streams: CB addresses (per stream) that are currently exists in the PQ * entries. In case all streams array entries are * filled with values, it means the execution was in Lower-CP. * @cq_addr: the address of the current handled command buffer * @cq_size: the size of the current handled command buffer * @cb_addr_streams_len: num of streams - actual len of cb_addr_streams array. * should be equal to 1 in case of undefined opcode * in Upper-CP (specific stream) and equal to 4 incase * of undefined opcode in Lower-CP. * @engine_id: engine-id that the error occurred on * @stream_id: the stream id the error occurred on. In case the stream equals to * MAX_QMAN_STREAMS_INFO it means the error occurred on a Lower-CP. */ struct hl_info_undefined_opcode_event { __s64 timestamp; __u64 cb_addr_streams[MAX_QMAN_STREAMS_INFO][OPCODE_INFO_MAX_ADDR_SIZE]; __u64 cq_addr; __u32 cq_size; __u32 cb_addr_streams_len; __u32 engine_id; __u32 stream_id; }; /** * struct hl_info_hw_err_event - info about HW error * @timestamp: timestamp of error occurrence * @event_id: The async event ID (specific to each device type). * @pad: size padding for u64 granularity. */ struct hl_info_hw_err_event { __s64 timestamp; __u16 event_id; __u16 pad[3]; }; /* FW error definition for event_type in struct hl_info_fw_err_event */ enum hl_info_fw_err_type { HL_INFO_FW_HEARTBEAT_ERR, HL_INFO_FW_REPORTED_ERR, }; /** * struct hl_info_fw_err_event - info about FW error * @timestamp: time-stamp of error occurrence * @err_type: The type of event as defined in hl_info_fw_err_type. * @event_id: The async event ID (specific to each device type, applicable only when event type is * HL_INFO_FW_REPORTED_ERR). * @pad: size padding for u64 granularity. */ struct hl_info_fw_err_event { __s64 timestamp; __u16 err_type; __u16 event_id; __u32 pad; }; /** * struct hl_info_engine_err_event - engine error info * @timestamp: time-stamp of error occurrence * @engine_id: engine id who reported the error. * @error_count: Amount of errors reported. * @pad: size padding for u64 granularity. */ struct hl_info_engine_err_event { __s64 timestamp; __u16 engine_id; __u16 error_count; __u32 pad; }; /** * struct hl_info_dev_memalloc_page_sizes - valid page sizes in device mem alloc information. * @page_order_bitmask: bitmap in which a set bit represents the order of the supported page size * (e.g. 0x2100000 means that 1MB and 32MB pages are supported). */ struct hl_info_dev_memalloc_page_sizes { __u64 page_order_bitmask; }; #define SEC_PCR_DATA_BUF_SZ 256 #define SEC_PCR_QUOTE_BUF_SZ 510 /* (512 - 2) 2 bytes used for size */ #define SEC_SIGNATURE_BUF_SZ 255 /* (256 - 1) 1 byte used for size */ #define SEC_PUB_DATA_BUF_SZ 510 /* (512 - 2) 2 bytes used for size */ #define SEC_CERTIFICATE_BUF_SZ 2046 /* (2048 - 2) 2 bytes used for size */ #define SEC_DEV_INFO_BUF_SZ 5120 /* * struct hl_info_sec_attest - attestation report of the boot * @nonce: number only used once. random number provided by host. this also passed to the quote * command as a qualifying data. * @pcr_quote_len: length of the attestation quote data (bytes) * @pub_data_len: length of the public data (bytes) * @certificate_len: length of the certificate (bytes) * @pcr_num_reg: number of PCR registers in the pcr_data array * @pcr_reg_len: length of each PCR register in the pcr_data array (bytes) * @quote_sig_len: length of the attestation report signature (bytes) * @pcr_data: raw values of the PCR registers * @pcr_quote: attestation report data structure * @quote_sig: signature structure of the attestation report * @public_data: public key for the signed attestation * (outPublic + name + qualifiedName) * @certificate: certificate for the attestation signing key */ struct hl_info_sec_attest { __u32 nonce; __u16 pcr_quote_len; __u16 pub_data_len; __u16 certificate_len; __u8 pcr_num_reg; __u8 pcr_reg_len; __u8 quote_sig_len; __u8 pcr_data[SEC_PCR_DATA_BUF_SZ]; __u8 pcr_quote[SEC_PCR_QUOTE_BUF_SZ]; __u8 quote_sig[SEC_SIGNATURE_BUF_SZ]; __u8 public_data[SEC_PUB_DATA_BUF_SZ]; __u8 certificate[SEC_CERTIFICATE_BUF_SZ]; __u8 pad0[2]; }; /* * struct hl_info_signed - device information signed by a secured device. * @nonce: number only used once. random number provided by host. this also passed to the quote * command as a qualifying data. * @pub_data_len: length of the public data (bytes) * @certificate_len: length of the certificate (bytes) * @info_sig_len: length of the attestation signature (bytes) * @public_data: public key info signed info data (outPublic + name + qualifiedName) * @certificate: certificate for the signing key * @info_sig: signature of the info + nonce data. * @dev_info_len: length of device info (bytes) * @dev_info: device info as byte array. */ struct hl_info_signed { __u32 nonce; __u16 pub_data_len; __u16 certificate_len; __u8 info_sig_len; __u8 public_data[SEC_PUB_DATA_BUF_SZ]; __u8 certificate[SEC_CERTIFICATE_BUF_SZ]; __u8 info_sig[SEC_SIGNATURE_BUF_SZ]; __u16 dev_info_len; __u8 dev_info[SEC_DEV_INFO_BUF_SZ]; __u8 pad[2]; }; /** * struct hl_page_fault_info - page fault information. * @timestamp: timestamp of page fault. * @addr: address which accessing it caused page fault. * @engine_id: engine id which caused the page fault, supported only in gaudi3. */ struct hl_page_fault_info { __s64 timestamp; __u64 addr; __u16 engine_id; __u8 pad[6]; }; /** * struct hl_user_mapping - user mapping information. * @dev_va: device virtual address. * @size: virtual address mapping size. */ struct hl_user_mapping { __u64 dev_va; __u64 size; }; enum gaudi_dcores { HL_GAUDI_WS_DCORE, HL_GAUDI_WN_DCORE, HL_GAUDI_EN_DCORE, HL_GAUDI_ES_DCORE }; /** * struct hl_info_args - Main structure to retrieve device related information. * @return_pointer: User space address of the relevant structure related to HL_INFO_* operation * mentioned in @op. * @return_size: Size of the structure used in @return_pointer, just like "size" in "snprintf", it * limits how many bytes the kernel can write. For hw_events array, the size should be * hl_info_hw_ip_info.num_of_events * sizeof(__u32). * @op: Defines which type of information to be retrieved. Refer HL_INFO_* for details. * @dcore_id: DCORE id for which the information is relevant (for Gaudi refer to enum gaudi_dcores). * @ctx_id: Context ID of the user. Currently not in use. * @period_ms: Period value, in milliseconds, for utilization rate in range 100ms - 1000ms in 100 ms * resolution. Currently not in use. * @pll_index: Index as defined in hl_<asic type>_pll_index enumeration. * @eventfd: event file descriptor for event notifications. * @user_buffer_actual_size: Actual data size which was copied to user allocated buffer by the * driver. It is possible for the user to allocate buffer larger than * needed, hence updating this variable so user will know the exact amount * of bytes copied by the kernel to the buffer. * @sec_attest_nonce: Nonce number used for attestation report. * @array_size: Number of array members copied to user buffer. * Relevant for HL_INFO_USER_MAPPINGS info ioctl. * @fw_sub_opcode: generic requests sub opcodes. * @pad: Padding to 64 bit. */ struct hl_info_args { __u64 return_pointer; __u32 return_size; __u32 op; union { __u32 dcore_id; __u32 ctx_id; __u32 period_ms; __u32 pll_index; __u32 eventfd; __u32 user_buffer_actual_size; __u32 sec_attest_nonce; __u32 array_size; __u32 fw_sub_opcode; }; __u32 pad; }; /* Opcode to create a new command buffer */ #define HL_CB_OP_CREATE 0 /* Opcode to destroy previously created command buffer */ #define HL_CB_OP_DESTROY 1 /* Opcode to retrieve information about a command buffer */ #define HL_CB_OP_INFO 2 /* 2MB minus 32 bytes for 2xMSG_PROT */ #define HL_MAX_CB_SIZE (0x200000 - 32) /* Indicates whether the command buffer should be mapped to the device's MMU */ #define HL_CB_FLAGS_MAP 0x1 /* Used with HL_CB_OP_INFO opcode to get the device va address for kernel mapped CB */ #define HL_CB_FLAGS_GET_DEVICE_VA 0x2 struct hl_cb_in { /* Handle of CB or 0 if we want to create one */ __u64 cb_handle; /* HL_CB_OP_* */ __u32 op; /* Size of CB. Maximum size is HL_MAX_CB_SIZE. The minimum size that * will be allocated, regardless of this parameter's value, is PAGE_SIZE */ __u32 cb_size; /* Context ID - Currently not in use */ __u32 ctx_id; /* HL_CB_FLAGS_* */ __u32 flags; }; struct hl_cb_out { union { /* Handle of CB */ __u64 cb_handle; union { /* Information about CB */ struct { /* Usage count of CB */ __u32 usage_cnt; __u32 pad; }; /* CB mapped address to device MMU */ __u64 device_va; }; }; }; union hl_cb_args { struct hl_cb_in in; struct hl_cb_out out; }; /* HL_CS_CHUNK_FLAGS_ values * * HL_CS_CHUNK_FLAGS_USER_ALLOC_CB: * Indicates if the CB was allocated and mapped by userspace * (relevant to Gaudi2 and later). User allocated CB is a command buffer, * allocated by the user, via malloc (or similar). After allocating the * CB, the user invokes - “memory ioctl” to map the user memory into a * device virtual address. The user provides this address via the * cb_handle field. The interface provides the ability to create a * large CBs, Which aren’t limited to “HL_MAX_CB_SIZE”. Therefore, it * increases the PCI-DMA queues throughput. This CB allocation method * also reduces the use of Linux DMA-able memory pool. Which are limited * and used by other Linux sub-systems. */ #define HL_CS_CHUNK_FLAGS_USER_ALLOC_CB 0x1 /* * This structure size must always be fixed to 64-bytes for backward * compatibility */ struct hl_cs_chunk { union { /* Goya/Gaudi: * For external queue, this represents a Handle of CB on the * Host. * For internal queue in Goya, this represents an SRAM or * a DRAM address of the internal CB. In Gaudi, this might also * represent a mapped host address of the CB. * * Gaudi2 onwards: * For H/W queue, this represents either a Handle of CB on the * Host, or an SRAM, a DRAM, or a mapped host address of the CB. * * A mapped host address is in the device address space, after * a host address was mapped by the device MMU. */ __u64 cb_handle; /* Relevant only when HL_CS_FLAGS_WAIT or * HL_CS_FLAGS_COLLECTIVE_WAIT is set * This holds address of array of u64 values that contain * signal CS sequence numbers. The wait described by * this job will listen on all those signals * (wait event per signal) */ __u64 signal_seq_arr; /* * Relevant only when HL_CS_FLAGS_WAIT or * HL_CS_FLAGS_COLLECTIVE_WAIT is set * along with HL_CS_FLAGS_ENCAP_SIGNALS. * This is the CS sequence which has the encapsulated signals. */ __u64 encaps_signal_seq; }; /* Index of queue to put the CB on */ __u32 queue_index; union { /* * Size of command buffer with valid packets * Can be smaller then actual CB size */ __u32 cb_size; /* Relevant only when HL_CS_FLAGS_WAIT or * HL_CS_FLAGS_COLLECTIVE_WAIT is set. * Number of entries in signal_seq_arr */ __u32 num_signal_seq_arr; /* Relevant only when HL_CS_FLAGS_WAIT or * HL_CS_FLAGS_COLLECTIVE_WAIT is set along * with HL_CS_FLAGS_ENCAP_SIGNALS * This set the signals range that the user want to wait for * out of the whole reserved signals range. * e.g if the signals range is 20, and user don't want * to wait for signal 8, so he set this offset to 7, then * he call the API again with 9 and so on till 20. */ __u32 encaps_signal_offset; }; /* HL_CS_CHUNK_FLAGS_* */ __u32 cs_chunk_flags; /* Relevant only when HL_CS_FLAGS_COLLECTIVE_WAIT is set. * This holds the collective engine ID. The wait described by this job * will sync with this engine and with all NICs before completion. */ __u32 collective_engine_id; /* Align structure to 64 bytes */ __u32 pad[10]; }; /* SIGNAL/WAIT/COLLECTIVE_WAIT flags are mutually exclusive */ #define HL_CS_FLAGS_FORCE_RESTORE 0x1 #define HL_CS_FLAGS_SIGNAL 0x2 #define HL_CS_FLAGS_WAIT 0x4 #define HL_CS_FLAGS_COLLECTIVE_WAIT 0x8 #define HL_CS_FLAGS_TIMESTAMP 0x20 #define HL_CS_FLAGS_STAGED_SUBMISSION 0x40 #define HL_CS_FLAGS_STAGED_SUBMISSION_FIRST 0x80 #define HL_CS_FLAGS_STAGED_SUBMISSION_LAST 0x100 #define HL_CS_FLAGS_CUSTOM_TIMEOUT 0x200 #define HL_CS_FLAGS_SKIP_RESET_ON_TIMEOUT 0x400 /* * The encapsulated signals CS is merged into the existing CS ioctls. * In order to use this feature need to follow the below procedure: * 1. Reserve signals, set the CS type to HL_CS_FLAGS_RESERVE_SIGNALS_ONLY * the output of this API will be the SOB offset from CFG_BASE. * this address will be used to patch CB cmds to do the signaling for this * SOB by incrementing it's value. * for reverting the reservation use HL_CS_FLAGS_UNRESERVE_SIGNALS_ONLY * CS type, note that this might fail if out-of-sync happened to the SOB * value, in case other signaling request to the same SOB occurred between * reserve-unreserve calls. * 2. Use the staged CS to do the encapsulated signaling jobs. * use HL_CS_FLAGS_STAGED_SUBMISSION and HL_CS_FLAGS_STAGED_SUBMISSION_FIRST * along with HL_CS_FLAGS_ENCAP_SIGNALS flag, and set encaps_signal_offset * field. This offset allows app to wait on part of the reserved signals. * 3. Use WAIT/COLLECTIVE WAIT CS along with HL_CS_FLAGS_ENCAP_SIGNALS flag * to wait for the encapsulated signals. */ #define HL_CS_FLAGS_ENCAP_SIGNALS 0x800 #define HL_CS_FLAGS_RESERVE_SIGNALS_ONLY 0x1000 #define HL_CS_FLAGS_UNRESERVE_SIGNALS_ONLY 0x2000 /* * The engine cores CS is merged into the existing CS ioctls. * Use it to control the engine cores mode. */ #define HL_CS_FLAGS_ENGINE_CORE_COMMAND 0x4000 /* * The flush HBW PCI writes is merged into the existing CS ioctls. * Used to flush all HBW PCI writes. * This is a blocking operation and for this reason the user shall not use * the return sequence number (which will be invalid anyway) */ #define HL_CS_FLAGS_FLUSH_PCI_HBW_WRITES 0x8000 /* * The engines CS is merged into the existing CS ioctls. * Use it to control engines modes. */ #define HL_CS_FLAGS_ENGINES_COMMAND 0x10000 #define HL_CS_STATUS_SUCCESS 0 #define HL_MAX_JOBS_PER_CS 512 /* * enum hl_engine_command - engine command * * @HL_ENGINE_CORE_HALT: engine core halt * @HL_ENGINE_CORE_RUN: engine core run * @HL_ENGINE_STALL: user engine/s stall * @HL_ENGINE_RESUME: user engine/s resume */ enum hl_engine_command { HL_ENGINE_CORE_HALT = 1, HL_ENGINE_CORE_RUN = 2, HL_ENGINE_STALL = 3, HL_ENGINE_RESUME = 4, HL_ENGINE_COMMAND_MAX }; struct hl_cs_in { union { struct { /* this holds address of array of hl_cs_chunk for restore phase */ __u64 chunks_restore; /* holds address of array of hl_cs_chunk for execution phase */ __u64 chunks_execute; }; /* Valid only when HL_CS_FLAGS_ENGINE_CORE_COMMAND is set */ struct { /* this holds address of array of uint32 for engine_cores */ __u64 engine_cores; /* number of engine cores in engine_cores array */ __u32 num_engine_cores; /* the core command to be sent towards engine cores */ __u32 core_command; }; /* Valid only when HL_CS_FLAGS_ENGINES_COMMAND is set */ struct { /* this holds address of array of uint32 for engines */ __u64 engines; /* number of engines in engines array */ __u32 num_engines; /* the engine command to be sent towards engines */ __u32 engine_command; }; }; union { /* * Sequence number of a staged submission CS * valid only if HL_CS_FLAGS_STAGED_SUBMISSION is set and * HL_CS_FLAGS_STAGED_SUBMISSION_FIRST is unset. */ __u64 seq; /* * Encapsulated signals handle id * Valid for two flows: * 1. CS with encapsulated signals: * when HL_CS_FLAGS_STAGED_SUBMISSION and * HL_CS_FLAGS_STAGED_SUBMISSION_FIRST * and HL_CS_FLAGS_ENCAP_SIGNALS are set. * 2. unreserve signals: * valid when HL_CS_FLAGS_UNRESERVE_SIGNALS_ONLY is set. */ __u32 encaps_sig_handle_id; /* Valid only when HL_CS_FLAGS_RESERVE_SIGNALS_ONLY is set */ struct { /* Encapsulated signals number */ __u32 encaps_signals_count; /* Encapsulated signals queue index (stream) */ __u32 encaps_signals_q_idx; }; }; /* Number of chunks in restore phase array. Maximum number is * HL_MAX_JOBS_PER_CS */ __u32 num_chunks_restore; /* Number of chunks in execution array. Maximum number is * HL_MAX_JOBS_PER_CS */ __u32 num_chunks_execute; /* timeout in seconds - valid only if HL_CS_FLAGS_CUSTOM_TIMEOUT * is set */ __u32 timeout; /* HL_CS_FLAGS_* */ __u32 cs_flags; /* Context ID - Currently not in use */ __u32 ctx_id; __u8 pad[4]; }; struct hl_cs_out { union { /* * seq holds the sequence number of the CS to pass to wait * ioctl. All values are valid except for 0 and ULLONG_MAX */ __u64 seq; /* Valid only when HL_CS_FLAGS_RESERVE_SIGNALS_ONLY is set */ struct { /* This is the reserved signal handle id */ __u32 handle_id; /* This is the signals count */ __u32 count; }; }; /* HL_CS_STATUS */ __u32 status; /* * SOB base address offset * Valid only when HL_CS_FLAGS_RESERVE_SIGNALS_ONLY or HL_CS_FLAGS_SIGNAL is set */ __u32 sob_base_addr_offset; /* * Count of completed signals in SOB before current signal submission. * Valid only when (HL_CS_FLAGS_ENCAP_SIGNALS & HL_CS_FLAGS_STAGED_SUBMISSION) * or HL_CS_FLAGS_SIGNAL is set */ __u16 sob_count_before_submission; __u16 pad[3]; }; union hl_cs_args { struct hl_cs_in in; struct hl_cs_out out; }; #define HL_WAIT_CS_FLAGS_INTERRUPT 0x2 #define HL_WAIT_CS_FLAGS_INTERRUPT_MASK 0xFFF00000 #define HL_WAIT_CS_FLAGS_ANY_CQ_INTERRUPT 0xFFF00000 #define HL_WAIT_CS_FLAGS_ANY_DEC_INTERRUPT 0xFFE00000 #define HL_WAIT_CS_FLAGS_MULTI_CS 0x4 #define HL_WAIT_CS_FLAGS_INTERRUPT_KERNEL_CQ 0x10 #define HL_WAIT_CS_FLAGS_REGISTER_INTERRUPT 0x20 #define HL_WAIT_MULTI_CS_LIST_MAX_LEN 32 struct hl_wait_cs_in { union { struct { /* * In case of wait_cs holds the CS sequence number. * In case of wait for multi CS hold a user pointer to * an array of CS sequence numbers */ __u64 seq; /* Absolute timeout to wait for command submission * in microseconds */ __u64 timeout_us; }; struct { union { /* User address for completion comparison. * upon interrupt, driver will compare the value pointed * by this address with the supplied target value. * in order not to perform any comparison, set address * to all 1s. * Relevant only when HL_WAIT_CS_FLAGS_INTERRUPT is set */ __u64 addr; /* cq_counters_handle to a kernel mapped cb which contains * cq counters. * Relevant only when HL_WAIT_CS_FLAGS_INTERRUPT_KERNEL_CQ is set */ __u64 cq_counters_handle; }; /* Target value for completion comparison */ __u64 target; }; }; /* Context ID - Currently not in use */ __u32 ctx_id; /* HL_WAIT_CS_FLAGS_* * If HL_WAIT_CS_FLAGS_INTERRUPT is set, this field should include * interrupt id according to HL_WAIT_CS_FLAGS_INTERRUPT_MASK * * in order to wait for any CQ interrupt, set interrupt value to * HL_WAIT_CS_FLAGS_ANY_CQ_INTERRUPT. * * in order to wait for any decoder interrupt, set interrupt value to * HL_WAIT_CS_FLAGS_ANY_DEC_INTERRUPT. */ __u32 flags; union { struct { /* Multi CS API info- valid entries in multi-CS array */ __u8 seq_arr_len; __u8 pad[7]; }; /* Absolute timeout to wait for an interrupt in microseconds. * Relevant only when HL_WAIT_CS_FLAGS_INTERRUPT is set */ __u64 interrupt_timeout_us; }; /* * cq counter offset inside the counters cb pointed by cq_counters_handle above. * upon interrupt, driver will compare the value pointed * by this address (cq_counters_handle + cq_counters_offset) * with the supplied target value. * relevant only when HL_WAIT_CS_FLAGS_INTERRUPT_KERNEL_CQ is set */ __u64 cq_counters_offset; /* * Timestamp_handle timestamps buffer handle. * relevant only when HL_WAIT_CS_FLAGS_REGISTER_INTERRUPT is set */ __u64 timestamp_handle; /* * Timestamp_offset is offset inside the timestamp buffer pointed by timestamp_handle above. * upon interrupt, if the cq reached the target value then driver will write * timestamp to this offset. * relevant only when HL_WAIT_CS_FLAGS_REGISTER_INTERRUPT is set */ __u64 timestamp_offset; }; #define HL_WAIT_CS_STATUS_COMPLETED 0 #define HL_WAIT_CS_STATUS_BUSY 1 #define HL_WAIT_CS_STATUS_TIMEDOUT 2 #define HL_WAIT_CS_STATUS_ABORTED 3 #define HL_WAIT_CS_STATUS_FLAG_GONE 0x1 #define HL_WAIT_CS_STATUS_FLAG_TIMESTAMP_VLD 0x2 struct hl_wait_cs_out { /* HL_WAIT_CS_STATUS_* */ __u32 status; /* HL_WAIT_CS_STATUS_FLAG* */ __u32 flags; /* * valid only if HL_WAIT_CS_STATUS_FLAG_TIMESTAMP_VLD is set * for wait_cs: timestamp of CS completion * for wait_multi_cs: timestamp of FIRST CS completion */ __s64 timestamp_nsec; /* multi CS completion bitmap */ __u32 cs_completion_map; __u32 pad; }; union hl_wait_cs_args { struct hl_wait_cs_in in; struct hl_wait_cs_out out; }; /* Opcode to allocate device memory */ #define HL_MEM_OP_ALLOC 0 /* Opcode to free previously allocated device memory */ #define HL_MEM_OP_FREE 1 /* Opcode to map host and device memory */ #define HL_MEM_OP_MAP 2 /* Opcode to unmap previously mapped host and device memory */ #define HL_MEM_OP_UNMAP 3 /* Opcode to map a hw block */ #define HL_MEM_OP_MAP_BLOCK 4 /* Opcode to create DMA-BUF object for an existing device memory allocation * and to export an FD of that DMA-BUF back to the caller */ #define HL_MEM_OP_EXPORT_DMABUF_FD 5 /* Opcode to create timestamps pool for user interrupts registration support * The memory will be allocated by the kernel driver, A timestamp buffer which the user * will get handle to it for mmap, and another internal buffer used by the * driver for registration management * The memory will be freed when the user closes the file descriptor(ctx close) */ #define HL_MEM_OP_TS_ALLOC 6 /* Memory flags */ #define HL_MEM_CONTIGUOUS 0x1 #define HL_MEM_SHARED 0x2 #define HL_MEM_USERPTR 0x4 #define HL_MEM_FORCE_HINT 0x8 #define HL_MEM_PREFETCH 0x40 /** * structure hl_mem_in - structure that handle input args for memory IOCTL * @union arg: union of structures to be used based on the input operation * @op: specify the requested memory operation (one of the HL_MEM_OP_* definitions). * @flags: flags for the memory operation (one of the HL_MEM_* definitions). * For the HL_MEM_OP_EXPORT_DMABUF_FD opcode, this field holds the DMA-BUF file/FD flags. * @ctx_id: context ID - currently not in use. * @num_of_elements: number of timestamp elements used only with HL_MEM_OP_TS_ALLOC opcode. */ struct hl_mem_in { union { /** * structure for device memory allocation (used with the HL_MEM_OP_ALLOC op) * @mem_size: memory size to allocate * @page_size: page size to use on allocation. when the value is 0 the default page * size will be taken. */ struct { __u64 mem_size; __u64 page_size; } alloc; /** * structure for free-ing device memory (used with the HL_MEM_OP_FREE op) * @handle: handle returned from HL_MEM_OP_ALLOC */ struct { __u64 handle; } free; /** * structure for mapping device memory (used with the HL_MEM_OP_MAP op) * @hint_addr: requested virtual address of mapped memory. * the driver will try to map the requested region to this hint * address, as long as the address is valid and not already mapped. * the user should check the returned address of the IOCTL to make * sure he got the hint address. * passing 0 here means that the driver will choose the address itself. * @handle: handle returned from HL_MEM_OP_ALLOC. */ struct { __u64 hint_addr; __u64 handle; } map_device; /** * structure for mapping host memory (used with the HL_MEM_OP_MAP op) * @host_virt_addr: address of allocated host memory. * @hint_addr: requested virtual address of mapped memory. * the driver will try to map the requested region to this hint * address, as long as the address is valid and not already mapped. * the user should check the returned address of the IOCTL to make * sure he got the hint address. * passing 0 here means that the driver will choose the address itself. * @size: size of allocated host memory. */ struct { __u64 host_virt_addr; __u64 hint_addr; __u64 mem_size; } map_host; /** * structure for mapping hw block (used with the HL_MEM_OP_MAP_BLOCK op) * @block_addr:HW block address to map, a handle and size will be returned * to the user and will be used to mmap the relevant block. * only addresses from configuration space are allowed. */ struct { __u64 block_addr; } map_block; /** * structure for unmapping host memory (used with the HL_MEM_OP_UNMAP op) * @device_virt_addr: virtual address returned from HL_MEM_OP_MAP */ struct { __u64 device_virt_addr; } unmap; /** * structure for exporting DMABUF object (used with * the HL_MEM_OP_EXPORT_DMABUF_FD op) * @addr: for Gaudi1, the driver expects a physical address * inside the device's DRAM. this is because in Gaudi1 * we don't have MMU that covers the device's DRAM. * for all other ASICs, the driver expects a device * virtual address that represents the start address of * a mapped DRAM memory area inside the device. * the address must be the same as was received from the * driver during a previous HL_MEM_OP_MAP operation. * @mem_size: size of memory to export. * @offset: for Gaudi1, this value must be 0. For all other ASICs, * the driver expects an offset inside of the memory area * describe by addr. the offset represents the start * address of that the exported dma-buf object describes. */ struct { __u64 addr; __u64 mem_size; __u64 offset; } export_dmabuf_fd; }; __u32 op; __u32 flags; __u32 ctx_id; __u32 num_of_elements; }; struct hl_mem_out { union { /* * Used for HL_MEM_OP_MAP as the virtual address that was * assigned in the device VA space. * A value of 0 means the requested operation failed. */ __u64 device_virt_addr; /* * Used in HL_MEM_OP_ALLOC * This is the assigned handle for the allocated memory */ __u64 handle; struct { /* * Used in HL_MEM_OP_MAP_BLOCK. * This is the assigned handle for the mapped block */ __u64 block_handle; /* * Used in HL_MEM_OP_MAP_BLOCK * This is the size of the mapped block */ __u32 block_size; __u32 pad; }; /* Returned in HL_MEM_OP_EXPORT_DMABUF_FD. Represents the * DMA-BUF object that was created to describe a memory * allocation on the device's memory space. The FD should be * passed to the importer driver */ __s32 fd; }; }; union hl_mem_args { struct hl_mem_in in; struct hl_mem_out out; }; #define HL_DEBUG_MAX_AUX_VALUES 10 struct hl_debug_params_etr { /* Address in memory to allocate buffer */ __u64 buffer_address; /* Size of buffer to allocate */ __u64 buffer_size; /* Sink operation mode: SW fifo, HW fifo, Circular buffer */ __u32 sink_mode; __u32 pad; }; struct hl_debug_params_etf { /* Address in memory to allocate buffer */ __u64 buffer_address; /* Size of buffer to allocate */ __u64 buffer_size; /* Sink operation mode: SW fifo, HW fifo, Circular buffer */ __u32 sink_mode; __u32 pad; }; struct hl_debug_params_stm { /* Two bit masks for HW event and Stimulus Port */ __u64 he_mask; __u64 sp_mask; /* Trace source ID */ __u32 id; /* Frequency for the timestamp register */ __u32 frequency; }; struct hl_debug_params_bmon { /* Two address ranges that the user can request to filter */ __u64 start_addr0; __u64 addr_mask0; __u64 start_addr1; __u64 addr_mask1; /* Capture window configuration */ __u32 bw_win; __u32 win_capture; /* Trace source ID */ __u32 id; /* Control register */ __u32 control; /* Two more address ranges that the user can request to filter */ __u64 start_addr2; __u64 end_addr2; __u64 start_addr3; __u64 end_addr3; }; struct hl_debug_params_spmu { /* Event types selection */ __u64 event_types[HL_DEBUG_MAX_AUX_VALUES]; /* Number of event types selection */ __u32 event_types_num; /* TRC configuration register values */ __u32 pmtrc_val; __u32 trc_ctrl_host_val; __u32 trc_en_host_val; }; /* Opcode for ETR component */ #define HL_DEBUG_OP_ETR 0 /* Opcode for ETF component */ #define HL_DEBUG_OP_ETF 1 /* Opcode for STM component */ #define HL_DEBUG_OP_STM 2 /* Opcode for FUNNEL component */ #define HL_DEBUG_OP_FUNNEL 3 /* Opcode for BMON component */ #define HL_DEBUG_OP_BMON 4 /* Opcode for SPMU component */ #define HL_DEBUG_OP_SPMU 5 /* Opcode for timestamp (deprecated) */ #define HL_DEBUG_OP_TIMESTAMP 6 /* Opcode for setting the device into or out of debug mode. The enable * variable should be 1 for enabling debug mode and 0 for disabling it */ #define HL_DEBUG_OP_SET_MODE 7 struct hl_debug_args { /* * Pointer to user input structure. * This field is relevant to specific opcodes. */ __u64 input_ptr; /* Pointer to user output structure */ __u64 output_ptr; /* Size of user input structure */ __u32 input_size; /* Size of user output structure */ __u32 output_size; /* HL_DEBUG_OP_* */ __u32 op; /* * Register index in the component, taken from the debug_regs_index enum * in the various ASIC header files */ __u32 reg_idx; /* Enable/disable */ __u32 enable; /* Context ID - Currently not in use */ __u32 ctx_id; }; #define HL_IOCTL_INFO 0x00 #define HL_IOCTL_CB 0x01 #define HL_IOCTL_CS 0x02 #define HL_IOCTL_WAIT_CS 0x03 #define HL_IOCTL_MEMORY 0x04 #define HL_IOCTL_DEBUG 0x05 /* * Various information operations such as: * - H/W IP information * - Current dram usage * * The user calls this IOCTL with an opcode that describes the required * information. The user should supply a pointer to a user-allocated memory * chunk, which will be filled by the driver with the requested information. * * The user supplies the maximum amount of size to copy into the user's memory, * in order to prevent data corruption in case of differences between the * definitions of structures in kernel and userspace, e.g. in case of old * userspace and new kernel driver */ #define DRM_IOCTL_HL_INFO DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_INFO, struct hl_info_args) /* * Command Buffer * - Request a Command Buffer * - Destroy a Command Buffer * * The command buffers are memory blocks that reside in DMA-able address * space and are physically contiguous so they can be accessed by the device * directly. They are allocated using the coherent DMA API. * * When creating a new CB, the IOCTL returns a handle of it, and the user-space * process needs to use that handle to mmap the buffer so it can access them. * * In some instances, the device must access the command buffer through the * device's MMU, and thus its memory should be mapped. In these cases, user can * indicate the driver that such a mapping is required. * The resulting device virtual address will be used internally by the driver, * and won't be returned to user. * */ #define DRM_IOCTL_HL_CB DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_CB, union hl_cb_args) /* * Command Submission * * To submit work to the device, the user need to call this IOCTL with a set * of JOBS. That set of JOBS constitutes a CS object. * Each JOB will be enqueued on a specific queue, according to the user's input. * There can be more then one JOB per queue. * * The CS IOCTL will receive two sets of JOBS. One set is for "restore" phase * and a second set is for "execution" phase. * The JOBS on the "restore" phase are enqueued only after context-switch * (or if its the first CS for this context). The user can also order the * driver to run the "restore" phase explicitly * * Goya/Gaudi: * There are two types of queues - external and internal. External queues * are DMA queues which transfer data from/to the Host. All other queues are * internal. The driver will get completion notifications from the device only * on JOBS which are enqueued in the external queues. * * Gaudi2 onwards: * There is a single type of queue for all types of engines, either DMA engines * for transfers from/to the host or inside the device, or compute engines. * The driver will get completion notifications from the device for all queues. * * For jobs on external queues, the user needs to create command buffers * through the CB ioctl and give the CB's handle to the CS ioctl. For jobs on * internal queues, the user needs to prepare a "command buffer" with packets * on either the device SRAM/DRAM or the host, and give the device address of * that buffer to the CS ioctl. * For jobs on H/W queues both options of command buffers are valid. * * This IOCTL is asynchronous in regard to the actual execution of the CS. This * means it returns immediately after ALL the JOBS were enqueued on their * relevant queues. Therefore, the user mustn't assume the CS has been completed * or has even started to execute. * * Upon successful enqueue, the IOCTL returns a sequence number which the user * can use with the "Wait for CS" IOCTL to check whether the handle's CS * non-internal JOBS have been completed. Note that if the CS has internal JOBS * which can execute AFTER the external JOBS have finished, the driver might * report that the CS has finished executing BEFORE the internal JOBS have * actually finished executing. * * Even though the sequence number increments per CS, the user can NOT * automatically assume that if CS with sequence number N finished, then CS * with sequence number N-1 also finished. The user can make this assumption if * and only if CS N and CS N-1 are exactly the same (same CBs for the same * queues). */ #define DRM_IOCTL_HL_CS DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_CS, union hl_cs_args) /* * Wait for Command Submission * * The user can call this IOCTL with a handle it received from the CS IOCTL * to wait until the handle's CS has finished executing. The user will wait * inside the kernel until the CS has finished or until the user-requested * timeout has expired. * * If the timeout value is 0, the driver won't sleep at all. It will check * the status of the CS and return immediately * * The return value of the IOCTL is a standard Linux error code. The possible * values are: * * EINTR - Kernel waiting has been interrupted, e.g. due to OS signal * that the user process received * ETIMEDOUT - The CS has caused a timeout on the device * EIO - The CS was aborted (usually because the device was reset) * ENODEV - The device wants to do hard-reset (so user need to close FD) * * The driver also returns a custom define in case the IOCTL call returned 0. * The define can be one of the following: * * HL_WAIT_CS_STATUS_COMPLETED - The CS has been completed successfully (0) * HL_WAIT_CS_STATUS_BUSY - The CS is still executing (0) * HL_WAIT_CS_STATUS_TIMEDOUT - The CS has caused a timeout on the device * (ETIMEDOUT) * HL_WAIT_CS_STATUS_ABORTED - The CS was aborted, usually because the * device was reset (EIO) */ #define DRM_IOCTL_HL_WAIT_CS DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_WAIT_CS, union hl_wait_cs_args) /* * Memory * - Map host memory to device MMU * - Unmap host memory from device MMU * * This IOCTL allows the user to map host memory to the device MMU * * For host memory, the IOCTL doesn't allocate memory. The user is supposed * to allocate the memory in user-space (malloc/new). The driver pins the * physical pages (up to the allowed limit by the OS), assigns a virtual * address in the device VA space and initializes the device MMU. * * There is an option for the user to specify the requested virtual address. * */ #define DRM_IOCTL_HL_MEMORY DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_MEMORY, union hl_mem_args) /* * Debug * - Enable/disable the ETR/ETF/FUNNEL/STM/BMON/SPMU debug traces * * This IOCTL allows the user to get debug traces from the chip. * * Before the user can send configuration requests of the various * debug/profile engines, it needs to set the device into debug mode. * This is because the debug/profile infrastructure is shared component in the * device and we can't allow multiple users to access it at the same time. * * Once a user set the device into debug mode, the driver won't allow other * users to "work" with the device, i.e. open a FD. If there are multiple users * opened on the device, the driver won't allow any user to debug the device. * * For each configuration request, the user needs to provide the register index * and essential data such as buffer address and size. * * Once the user has finished using the debug/profile engines, he should * set the device into non-debug mode, i.e. disable debug mode. * * The driver can decide to "kick out" the user if he abuses this interface. * */ #define DRM_IOCTL_HL_DEBUG DRM_IOWR(DRM_COMMAND_BASE + HL_IOCTL_DEBUG, struct hl_debug_args) #define HL_COMMAND_START (DRM_COMMAND_BASE + HL_IOCTL_INFO) #define HL_COMMAND_END (DRM_COMMAND_BASE + HL_IOCTL_DEBUG + 1) #endif /* HABANALABS_H_ */ |