xref: /linux/Documentation/accel/qaic/aic100.rst (revision 4b132aacb0768ac1e652cf517097ea6f237214b9)
1.. SPDX-License-Identifier: GPL-2.0-only
2
3===============================
4 Qualcomm Cloud AI 100 (AIC100)
5===============================
6
7Overview
8========
9
10The Qualcomm Cloud AI 100/AIC100 family of products (including SA9000P - part of
11Snapdragon Ride) are PCIe adapter cards which contain a dedicated SoC ASIC for
12the purpose of efficiently running Artificial Intelligence (AI) Deep Learning
13inference workloads. They are AI accelerators.
14
15The PCIe interface of AIC100 is capable of PCIe Gen4 speeds over eight lanes
16(x8). An individual SoC on a card can have up to 16 NSPs for running workloads.
17Each SoC has an A53 management CPU. On card, there can be up to 32 GB of DDR.
18
19Multiple AIC100 cards can be hosted in a single system to scale overall
20performance. AIC100 cards are multi-user capable and able to execute workloads
21from multiple users in a concurrent manner.
22
23Hardware Description
24====================
25
26An AIC100 card consists of an AIC100 SoC, on-card DDR, and a set of misc
27peripherals (PMICs, etc).
28
29An AIC100 card can either be a PCIe HHHL form factor (a traditional PCIe card),
30or a Dual M.2 card. Both use PCIe to connect to the host system.
31
32As a PCIe endpoint/adapter, AIC100 uses the standard VendorID(VID)/
33DeviceID(DID) combination to uniquely identify itself to the host. AIC100
34uses the standard Qualcomm VID (0x17cb). All AIC100 SKUs use the same
35AIC100 DID (0xa100).
36
37AIC100 does not implement FLR (function level reset).
38
39AIC100 implements MSI but does not implement MSI-X. AIC100 prefers 17 MSIs to
40operate (1 for MHI, 16 for the DMA Bridge). Falling back to 1 MSI is possible in
41scenarios where reserving 32 MSIs isn't feasible.
42
43As a PCIe device, AIC100 utilizes BARs to provide host interfaces to the device
44hardware. AIC100 provides 3, 64-bit BARs.
45
46* The first BAR is 4K in size, and exposes the MHI interface to the host.
47
48* The second BAR is 2M in size, and exposes the DMA Bridge interface to the
49  host.
50
51* The third BAR is variable in size based on an individual AIC100's
52  configuration, but defaults to 64K. This BAR currently has no purpose.
53
54From the host perspective, AIC100 has several key hardware components -
55
56* MHI (Modem Host Interface)
57* QSM (QAIC Service Manager)
58* NSPs (Neural Signal Processor)
59* DMA Bridge
60* DDR
61
62MHI
63---
64
65AIC100 has one MHI interface over PCIe. MHI itself is documented at
66Documentation/mhi/index.rst MHI is the mechanism the host uses to communicate
67with the QSM. Except for workload data via the DMA Bridge, all interaction with
68the device occurs via MHI.
69
70QSM
71---
72
73QAIC Service Manager. This is an ARM A53 CPU that runs the primary
74firmware of the card and performs on-card management tasks. It also
75communicates with the host via MHI. Each AIC100 has one of
76these.
77
78NSP
79---
80
81Neural Signal Processor. Each AIC100 has up to 16 of these. These are
82the processors that run the workloads on AIC100. Each NSP is a Qualcomm Hexagon
83(Q6) DSP with HVX and HMX. Each NSP can only run one workload at a time, but
84multiple NSPs may be assigned to a single workload. Since each NSP can only run
85one workload, AIC100 is limited to 16 concurrent workloads. Workload
86"scheduling" is under the purview of the host. AIC100 does not automatically
87timeslice.
88
89DMA Bridge
90----------
91
92The DMA Bridge is custom DMA engine that manages the flow of data
93in and out of workloads. AIC100 has one of these. The DMA Bridge has 16
94channels, each consisting of a set of request/response FIFOs. Each active
95workload is assigned a single DMA Bridge channel. The DMA Bridge exposes
96hardware registers to manage the FIFOs (head/tail pointers), but requires host
97memory to store the FIFOs.
98
99DDR
100---
101
102AIC100 has on-card DDR. In total, an AIC100 can have up to 32 GB of DDR.
103This DDR is used to store workloads, data for the workloads, and is used by the
104QSM for managing the device. NSPs are granted access to sections of the DDR by
105the QSM. The host does not have direct access to the DDR, and must make
106requests to the QSM to transfer data to the DDR.
107
108High-level Use Flow
109===================
110
111AIC100 is a multi-user, programmable accelerator typically used for running
112neural networks in inferencing mode to efficiently perform AI operations.
113AIC100 is not intended for training neural networks. AIC100 can be utilized
114for generic compute workloads.
115
116Assuming a user wants to utilize AIC100, they would follow these steps:
117
1181. Compile the workload into an ELF targeting the NSP(s)
1192. Make requests to the QSM to load the workload and related artifacts into the
120   device DDR
1213. Make a request to the QSM to activate the workload onto a set of idle NSPs
1224. Make requests to the DMA Bridge to send input data to the workload to be
123   processed, and other requests to receive processed output data from the
124   workload.
1255. Once the workload is no longer required, make a request to the QSM to
126   deactivate the workload, thus putting the NSPs back into an idle state.
1276. Once the workload and related artifacts are no longer needed for future
128   sessions, make requests to the QSM to unload the data from DDR. This frees
129   the DDR to be used by other users.
130
131
132Boot Flow
133=========
134
135AIC100 uses a flashless boot flow, derived from Qualcomm MSMs.
136
137When AIC100 is first powered on, it begins executing PBL (Primary Bootloader)
138from ROM. PBL enumerates the PCIe link, and initializes the BHI (Boot Host
139Interface) component of MHI.
140
141Using BHI, the host points PBL to the location of the SBL (Secondary Bootloader)
142image. The PBL pulls the image from the host, validates it, and begins
143execution of SBL.
144
145SBL initializes MHI, and uses MHI to notify the host that the device has entered
146the SBL stage. SBL performs a number of operations:
147
148* SBL initializes the majority of hardware (anything PBL left uninitialized),
149  including DDR.
150* SBL offloads the bootlog to the host.
151* SBL synchronizes timestamps with the host for future logging.
152* SBL uses the Sahara protocol to obtain the runtime firmware images from the
153  host.
154
155Once SBL has obtained and validated the runtime firmware, it brings the NSPs out
156of reset, and jumps into the QSM.
157
158The QSM uses MHI to notify the host that the device has entered the QSM stage
159(AMSS in MHI terms). At this point, the AIC100 device is fully functional, and
160ready to process workloads.
161
162Userspace components
163====================
164
165Compiler
166--------
167
168An open compiler for AIC100 based on upstream LLVM can be found at:
169https://github.com/quic/software-kit-for-qualcomm-cloud-ai-100-cc
170
171Usermode Driver (UMD)
172---------------------
173
174An open UMD that interfaces with the qaic kernel driver can be found at:
175https://github.com/quic/software-kit-for-qualcomm-cloud-ai-100
176
177Sahara loader
178-------------
179
180An open implementation of the Sahara protocol called kickstart can be found at:
181https://github.com/andersson/qdl
182
183MHI Channels
184============
185
186AIC100 defines a number of MHI channels for different purposes. This is a list
187of the defined channels, and their uses.
188
189+----------------+---------+----------+----------------------------------------+
190| Channel name   | IDs     | EEs      | Purpose                                |
191+================+=========+==========+========================================+
192| QAIC_LOOPBACK  | 0 & 1   | AMSS     | Any data sent to the device on this    |
193|                |         |          | channel is sent back to the host.      |
194+----------------+---------+----------+----------------------------------------+
195| QAIC_SAHARA    | 2 & 3   | SBL      | Used by SBL to obtain the runtime      |
196|                |         |          | firmware from the host.                |
197+----------------+---------+----------+----------------------------------------+
198| QAIC_DIAG      | 4 & 5   | AMSS     | Used to communicate with QSM via the   |
199|                |         |          | DIAG protocol.                         |
200+----------------+---------+----------+----------------------------------------+
201| QAIC_SSR       | 6 & 7   | AMSS     | Used to notify the host of subsystem   |
202|                |         |          | restart events, and to offload SSR     |
203|                |         |          | crashdumps.                            |
204+----------------+---------+----------+----------------------------------------+
205| QAIC_QDSS      | 8 & 9   | AMSS     | Used for the Qualcomm Debug Subsystem. |
206+----------------+---------+----------+----------------------------------------+
207| QAIC_CONTROL   | 10 & 11 | AMSS     | Used for the Neural Network Control    |
208|                |         |          | (NNC) protocol. This is the primary    |
209|                |         |          | channel between host and QSM for       |
210|                |         |          | managing workloads.                    |
211+----------------+---------+----------+----------------------------------------+
212| QAIC_LOGGING   | 12 & 13 | SBL      | Used by the SBL to send the bootlog to |
213|                |         |          | the host.                              |
214+----------------+---------+----------+----------------------------------------+
215| QAIC_STATUS    | 14 & 15 | AMSS     | Used to notify the host of Reliability,|
216|                |         |          | Accessibility, Serviceability (RAS)    |
217|                |         |          | events.                                |
218+----------------+---------+----------+----------------------------------------+
219| QAIC_TELEMETRY | 16 & 17 | AMSS     | Used to get/set power/thermal/etc      |
220|                |         |          | attributes.                            |
221+----------------+---------+----------+----------------------------------------+
222| QAIC_DEBUG     | 18 & 19 | AMSS     | Not used.                              |
223+----------------+---------+----------+----------------------------------------+
224| QAIC_TIMESYNC  | 20 & 21 | SBL      | Used to synchronize timestamps in the  |
225|                |         |          | device side logs with the host time    |
226|                |         |          | source.                                |
227+----------------+---------+----------+----------------------------------------+
228| QAIC_TIMESYNC  | 22 & 23 | AMSS     | Used to periodically synchronize       |
229| _PERIODIC      |         |          | timestamps in the device side logs with|
230|                |         |          | the host time source.                  |
231+----------------+---------+----------+----------------------------------------+
232
233DMA Bridge
234==========
235
236Overview
237--------
238
239The DMA Bridge is one of the main interfaces to the host from the device
240(the other being MHI). As part of activating a workload to run on NSPs, the QSM
241assigns that network a DMA Bridge channel. A workload's DMA Bridge channel
242(DBC for short) is solely for the use of that workload and is not shared with
243other workloads.
244
245Each DBC is a pair of FIFOs that manage data in and out of the workload. One
246FIFO is the request FIFO. The other FIFO is the response FIFO.
247
248Each DBC contains 4 registers in hardware:
249
250* Request FIFO head pointer (offset 0x0). Read only by the host. Indicates the
251  latest item in the FIFO the device has consumed.
252* Request FIFO tail pointer (offset 0x4). Read/write by the host. Host
253  increments this register to add new items to the FIFO.
254* Response FIFO head pointer (offset 0x8). Read/write by the host. Indicates
255  the latest item in the FIFO the host has consumed.
256* Response FIFO tail pointer (offset 0xc). Read only by the host. Device
257  increments this register to add new items to the FIFO.
258
259The values in each register are indexes in the FIFO. To get the location of the
260FIFO element pointed to by the register: FIFO base address + register * element
261size.
262
263DBC registers are exposed to the host via the second BAR. Each DBC consumes
2644KB of space in the BAR.
265
266The actual FIFOs are backed by host memory. When sending a request to the QSM
267to activate a network, the host must donate memory to be used for the FIFOs.
268Due to internal mapping limitations of the device, a single contiguous chunk of
269memory must be provided per DBC, which hosts both FIFOs. The request FIFO will
270consume the beginning of the memory chunk, and the response FIFO will consume
271the end of the memory chunk.
272
273Request FIFO
274------------
275
276A request FIFO element has the following structure:
277
278.. code-block:: c
279
280  struct request_elem {
281	u16 req_id;
282	u8  seq_id;
283	u8  pcie_dma_cmd;
284	u32 reserved;
285	u64 pcie_dma_source_addr;
286	u64 pcie_dma_dest_addr;
287	u32 pcie_dma_len;
288	u32 reserved;
289	u64 doorbell_addr;
290	u8  doorbell_attr;
291	u8  reserved;
292	u16 reserved;
293	u32 doorbell_data;
294	u32 sem_cmd0;
295	u32 sem_cmd1;
296	u32 sem_cmd2;
297	u32 sem_cmd3;
298  };
299
300Request field descriptions:
301
302req_id
303	request ID. A request FIFO element and a response FIFO element with
304	the same request ID refer to the same command.
305
306seq_id
307	sequence ID within a request. Ignored by the DMA Bridge.
308
309pcie_dma_cmd
310	describes the DMA element of this request.
311
312	* Bit(7) is the force msi flag, which overrides the DMA Bridge MSI logic
313	  and generates a MSI when this request is complete, and QSM
314	  configures the DMA Bridge to look at this bit.
315	* Bits(6:5) are reserved.
316	* Bit(4) is the completion code flag, and indicates that the DMA Bridge
317	  shall generate a response FIFO element when this request is
318	  complete.
319	* Bit(3) indicates if this request is a linked list transfer(0) or a bulk
320	  transfer(1).
321	* Bit(2) is reserved.
322	* Bits(1:0) indicate the type of transfer. No transfer(0), to device(1),
323	  from device(2). Value 3 is illegal.
324
325pcie_dma_source_addr
326	source address for a bulk transfer, or the address of the linked list.
327
328pcie_dma_dest_addr
329	destination address for a bulk transfer.
330
331pcie_dma_len
332	length of the bulk transfer. Note that the size of this field
333	limits transfers to 4G in size.
334
335doorbell_addr
336	address of the doorbell to ring when this request is complete.
337
338doorbell_attr
339	doorbell attributes.
340
341	* Bit(7) indicates if a write to a doorbell is to occur.
342	* Bits(6:2) are reserved.
343	* Bits(1:0) contain the encoding of the doorbell length. 0 is 32-bit,
344	  1 is 16-bit, 2 is 8-bit, 3 is reserved. The doorbell address
345	  must be naturally aligned to the specified length.
346
347doorbell_data
348	data to write to the doorbell. Only the bits corresponding to
349	the doorbell length are valid.
350
351sem_cmdN
352	semaphore command.
353
354	* Bit(31) indicates this semaphore command is enabled.
355	* Bit(30) is the to-device DMA fence. Block this request until all
356	  to-device DMA transfers are complete.
357	* Bit(29) is the from-device DMA fence. Block this request until all
358	  from-device DMA transfers are complete.
359	* Bits(28:27) are reserved.
360	* Bits(26:24) are the semaphore command. 0 is NOP. 1 is init with the
361	  specified value. 2 is increment. 3 is decrement. 4 is wait
362	  until the semaphore is equal to the specified value. 5 is wait
363	  until the semaphore is greater or equal to the specified value.
364	  6 is "P", wait until semaphore is greater than 0, then
365	  decrement by 1. 7 is reserved.
366	* Bit(23) is reserved.
367	* Bit(22) is the semaphore sync. 0 is post sync, which means that the
368	  semaphore operation is done after the DMA transfer. 1 is
369	  presync, which gates the DMA transfer. Only one presync is
370	  allowed per request.
371	* Bit(21) is reserved.
372	* Bits(20:16) is the index of the semaphore to operate on.
373	* Bits(15:12) are reserved.
374	* Bits(11:0) are the semaphore value to use in operations.
375
376Overall, a request is processed in 4 steps:
377
3781. If specified, the presync semaphore condition must be true
3792. If enabled, the DMA transfer occurs
3803. If specified, the postsync semaphore conditions must be true
3814. If enabled, the doorbell is written
382
383By using the semaphores in conjunction with the workload running on the NSPs,
384the data pipeline can be synchronized such that the host can queue multiple
385requests of data for the workload to process, but the DMA Bridge will only copy
386the data into the memory of the workload when the workload is ready to process
387the next input.
388
389Response FIFO
390-------------
391
392Once a request is fully processed, a response FIFO element is generated if
393specified in pcie_dma_cmd. The structure of a response FIFO element:
394
395.. code-block:: c
396
397  struct response_elem {
398	u16 req_id;
399	u16 completion_code;
400  };
401
402req_id
403	matches the req_id of the request that generated this element.
404
405completion_code
406	status of this request. 0 is success. Non-zero is an error.
407
408The DMA Bridge will generate a MSI to the host as a reaction to activity in the
409response FIFO of a DBC. The DMA Bridge hardware has an IRQ storm mitigation
410algorithm, where it will only generate a MSI when the response FIFO transitions
411from empty to non-empty (unless force MSI is enabled and triggered). In
412response to this MSI, the host is expected to drain the response FIFO, and must
413take care to handle any race conditions between draining the FIFO, and the
414device inserting elements into the FIFO.
415
416Neural Network Control (NNC) Protocol
417=====================================
418
419The NNC protocol is how the host makes requests to the QSM to manage workloads.
420It uses the QAIC_CONTROL MHI channel.
421
422Each NNC request is packaged into a message. Each message is a series of
423transactions. A passthrough type transaction can contain elements known as
424commands.
425
426QSM requires NNC messages be little endian encoded and the fields be naturally
427aligned. Since there are 64-bit elements in some NNC messages, 64-bit alignment
428must be maintained.
429
430A message contains a header and then a series of transactions. A message may be
431at most 4K in size from QSM to the host. From the host to the QSM, a message
432can be at most 64K (maximum size of a single MHI packet), but there is a
433continuation feature where message N+1 can be marked as a continuation of
434message N. This is used for exceedingly large DMA xfer transactions.
435
436Transaction descriptions
437------------------------
438
439passthrough
440	Allows userspace to send an opaque payload directly to the QSM.
441	This is used for NNC commands. Userspace is responsible for managing
442	the QSM message requirements in the payload.
443
444dma_xfer
445	DMA transfer. Describes an object that the QSM should DMA into the
446	device via address and size tuples.
447
448activate
449	Activate a workload onto NSPs. The host must provide memory to be
450	used by the DBC.
451
452deactivate
453	Deactivate an active workload and return the NSPs to idle.
454
455status
456	Query the QSM about it's NNC implementation. Returns the NNC version,
457	and if CRC is used.
458
459terminate
460	Release a user's resources.
461
462dma_xfer_cont
463	Continuation of a previous DMA transfer. If a DMA transfer
464	cannot be specified in a single message (highly fragmented), this
465	transaction can be used to specify more ranges.
466
467validate_partition
468	Query to QSM to determine if a partition identifier is valid.
469
470Each message is tagged with a user id, and a partition id. The user id allows
471QSM to track resources, and release them when the user goes away (eg the process
472crashes). A partition id identifies the resource partition that QSM manages,
473which this message applies to.
474
475Messages may have CRCs. Messages should have CRCs applied until the QSM
476reports via the status transaction that CRCs are not needed. The QSM on the
477SA9000P requires CRCs for black channel safing.
478
479Subsystem Restart (SSR)
480=======================
481
482SSR is the concept of limiting the impact of an error. An AIC100 device may
483have multiple users, each with their own workload running. If the workload of
484one user crashes, the fallout of that should be limited to that workload and not
485impact other workloads. SSR accomplishes this.
486
487If a particular workload crashes, QSM notifies the host via the QAIC_SSR MHI
488channel. This notification identifies the workload by it's assigned DBC. A
489multi-stage recovery process is then used to cleanup both sides, and get the
490DBC/NSPs into a working state.
491
492When SSR occurs, any state in the workload is lost. Any inputs that were in
493process, or queued by not yet serviced, are lost. The loaded artifacts will
494remain in on-card DDR, but the host will need to re-activate the workload if
495it desires to recover the workload.
496
497Reliability, Accessibility, Serviceability (RAS)
498================================================
499
500AIC100 is expected to be deployed in server systems where RAS ideology is
501applied. Simply put, RAS is the concept of detecting, classifying, and
502reporting errors. While PCIe has AER (Advanced Error Reporting) which factors
503into RAS, AER does not allow for a device to report details about internal
504errors. Therefore, AIC100 implements a custom RAS mechanism. When a RAS event
505occurs, QSM will report the event with appropriate details via the QAIC_STATUS
506MHI channel. A sysadmin may determine that a particular device needs
507additional service based on RAS reports.
508
509Telemetry
510=========
511
512QSM has the ability to report various physical attributes of the device, and in
513some cases, to allow the host to control them. Examples include thermal limits,
514thermal readings, and power readings. These items are communicated via the
515QAIC_TELEMETRY MHI channel.
516