The Qualcomm Cloud AI 100 (AIC100) device is an Artificial Intelligence accelerator PCIe card. It contains a number of components both in the SoC and on the card which facilitate running workloads: QSM: management processor NSPs: workload compute units DMA Bridge: dedicated data mover for the workloads MHI: multiplexed communication channels DDR: workload storage and memory The Linux kernel driver for AIC100 is called "QAIC" and is located in the accel subsystem. Signed-off-by: Jeffrey Hugo <quic_jhugo@xxxxxxxxxxx> Reviewed-by: Carl Vanderlip <quic_carlv@xxxxxxxxxxx> --- Documentation/accel/index.rst | 1 + Documentation/accel/qaic/aic100.rst | 498 ++++++++++++++++++++++++++++++++++++ Documentation/accel/qaic/index.rst | 13 + Documentation/accel/qaic/qaic.rst | 169 ++++++++++++ 4 files changed, 681 insertions(+) create mode 100644 Documentation/accel/qaic/aic100.rst create mode 100644 Documentation/accel/qaic/index.rst create mode 100644 Documentation/accel/qaic/qaic.rst diff --git a/Documentation/accel/index.rst b/Documentation/accel/index.rst index 2b43c9a..e94a016 100644 --- a/Documentation/accel/index.rst +++ b/Documentation/accel/index.rst @@ -8,6 +8,7 @@ Compute Accelerators :maxdepth: 1 introduction + qaic/index .. only:: subproject and html diff --git a/Documentation/accel/qaic/aic100.rst b/Documentation/accel/qaic/aic100.rst new file mode 100644 index 0000000..773aa54 --- /dev/null +++ b/Documentation/accel/qaic/aic100.rst @@ -0,0 +1,498 @@ +.. SPDX-License-Identifier: GPL-2.0-only + +=============================== + Qualcomm Cloud AI 100 (AIC100) +=============================== + +Overview +======== + +The Qualcomm Cloud AI 100/AIC100 family of products (including SA9000P - part of +Snapdragon Ride) are PCIe adapter cards which contain a dedicated SoC ASIC for +the purpose of efficiently running Artificial Intelligence (AI) Deep Learning +inference workloads. They are AI accelerators. + +The PCIe interface of AIC100 is capable of PCIe Gen4 speeds over eight lanes +(x8). An individual SoC on a card can have up to 16 NSPs for running workloads. +Each SoC has an A53 management CPU. On card, there can be up to 32 GB of DDR. + +Multiple AIC100 cards can be hosted in a single system to scale overall +performance. + +Hardware Description +==================== + +An AIC100 card consists of an AIC100 SoC, on-card DDR, and a set of misc +peripherals (PMICs, etc). + +An AIC100 card can either be a PCIe HHHL form factor (a traditional PCIe card), +or a Dual M.2 card. Both use PCIe to connect to the host system. + +As a PCIe endpoint/adapter, AIC100 uses the standard VendorID(VID)/ +DeviceID(DID) combination to uniquely identify itself to the host. AIC100 +uses the standard Qualcomm VID (0x17cb). All AIC100 instances use the same +AIC100 DID (0xa100). + +AIC100 does not implement FLR (function level reset). + +AIC100 implements MSI but does not implement MSI-X. AIC100 requires 17 MSIs to +operate (1 for MHI, 16 for the DMA Bridge). + +As a PCIe device, AIC100 utilizes BARs to provide host interfaces to the device +hardware. AIC100 provides 3, 64-bit BARs. + +* The first BAR is 4K in size, and exposes the MHI interface to the host. + +* The second BAR is 2M in size, and exposes the DMA Bridge interface to the + host. + +* The third BAR is variable in size based on an individual AIC100's + configuration, but defaults to 64K. This BAR currently has no purpose. + +From the host perspective, AIC100 has several key hardware components- + +* QSM (QAIC Service Manager) +* NSPs (Neural Signal Processor) +* DMA Bridge +* DDR +* MHI (Modem Host Interface) + +QSM +--- + +QAIC Service Manager. This is an ARM A53 CPU that runs the primary +firmware of the card and performs on-card management tasks. It also +communicates with the host via MHI. Each AIC100 has one of +these. + +NSP +--- + +Neural Signal Processor. Each AIC100 has up to 16 of these. These are +the processors that run the workloads on AIC100. Each NSP is a Qualcomm Hexagon +(Q6) DSP with HVX and HMX. Each NSP can only run one workload at a time, but +multiple NSPs may be assigned to a single workload. Since each NSP can only run +one workload, AIC100 is limited to 16 concurrent workloads. Workload +"scheduling" is under the purview of the host. AIC100 does not automatically +timeslice. + +DMA Bridge +---------- + +The DMA Bridge is custom DMA engine that manages the flow of data +in and out of workloads. AIC100 has one of these. The DMA Bridge has 16 +channels, each consisting of a set of request/response FIFOs. Each active +workload is assigned a single DMA Bridge channel. The DMA Bridge exposes +hardware registers to manage the FIFOs (head/tail pointers), but requires host +memory to store the FIFOs. + +DDR +--- + +AIC100 has on-card DDR. In total, an AIC100 can have up to 32 GB of DDR. +This DDR is used to store workloads, data for the workloads, and is used by the +QSM for managing the device. NSPs are granted access to sections of the DDR by +the QSM. The host does not have direct access to the DDR, and must make +requests to the QSM to transfer data to the DDR. + +MHI +--- + +AIC100 has one MHI interface over PCIe. MHI itself is documented at +Documentation/mhi/index.rst MHI is the mechanism the host uses to communicate +with the QSM. Except for workload data via the DMA Bridge, all interaction with +he device occurs via MHI. + +High-level Use Flow +=================== + +AIC100 is a programmable accelerator typically used for running +neural networks in inferencing mode to efficiently perform AI operations. +AIC100 is not intended for training neural networks. AIC100 can be utilitized +for generic compute workloads. + +Assuming a user wants to utilize AIC100, they would follow these steps: + +1. Compile the workload into an ELF targeting the NSP(s) +2. Make requests to the QSM to load the workload and related artifacts into the + device DDR +3. Make a request to the QSM to activate the workload onto a set of idle NSPs +4. Make requests to the DMA Bridge to send input data to the workload to be + processed, and other requests to receive processed output data from the + workload. +5. Once the workload is no longer required, make a request to the QSM to + deactivate the workload, thus putting the NSPs back into an idle state. +6. Once the workload and related artifacts are no longer needed for future + sessions, make requests to the QSM to unload the data from DDR. This frees + the DDR to be used by other users. + + +Boot Flow +========= + +AIC100 uses a flashless boot flow, derived from Qualcomm MSMs. + +When AIC100 is first powered on, it begins executing PBL (Primary Bootloader) +from ROM. PBL enumerates the PCIe link, and initializes the BHI (Boot Host +Interface) component of MHI. + +Using BHI, the host points PBL to the location of the SBL (Secondary Bootloader) +image. The PBL pulls the image from the host, validates it, and begins +execution of SBL. + +SBL initializes MHI, and uses MHI to notify the host that the device has entered +the SBL stage. SBL performs a number of operations: + +* SBL initializes the majority of hardware (anything PBL left uninitialized), + including DDR. +* SBL offloads the bootlog to the host. +* SBL synchonizes timestamps with the host for future logging. +* SBL uses the Sahara protocol to obtain the runtime firmware images from the + host. + +Once SBL has obtained and validated the runtime firmware, it brings the NSPs out +of reset, and jumps into the QSM. + +The QSM uses MHI to notify the host that the device has entered the QSM stage +(AMSS in MHI terms). At this point, the AIC100 device is fully functional, and +ready to process workloads. + +Userspace components +==================== + +Compiler +-------- + +An open compiler for AIC100 based on upstream LLVM can be found at: +https://github.com/quic/software-kit-for-qualcomm-cloud-ai-100-cc + +Usermode Driver (UMD) +--------------------- + +An open UMD that interfaces with the qaic kernel driver can be found at: +https://github.com/quic/software-kit-for-qualcomm-cloud-ai-100 + +Sahara loader +------------- + +An open implementation of the Sahara protocol called kickstart can be found at: +https://github.com/andersson/qdl + +MHI Channels +============ + +AIC100 defines a number of MHI channels for different purposes. This is a list +of the defined channels, and their uses. + +| QAIC_LOOPBACK +| Channels 0/1 +| Valid for AMSS +| Any data sent to the device on this channel is sent back to the host. + +| QAIC_SAHARA +| Channels 2/3 +| Valid for SBL +| Used by SBL to obtain the runtime firmware from the host. + +| QAIC_DIAG +| Channels 4/5 +| Valid for AMSS +| Used to communicate with QSM via the Diag protocol. + +| QAIC_SSR +| Channels 6/7 +| Valid for AMSS +| Used to notify the host of subsystem restart events, and to offload SSR crashdumps. + +| QAIC_QDSS +| Channels 8/9 +| Valid for AMSS +| Used for the Qualcomm Debug Subsystem. + +| QAIC_CONTROL +| Channels 10/11 +| Valid for AMSS +| Used for the Neural Network Control (NNC) protocol. This is the primary channel between host and QSM for managing workloads. + +| QAIC_LOGGING +| Channels 12/13 +| Valid for SBL +| Used by the SBL to send the bootlog to the host. + +| QAIC_STATUS +| Channels 14/15 +| Valid for AMSS +| Used to notify the host of Reliability, Accessability, Serviceability (RAS) events. + +| QAIC_TELEMETRY +| Channels 16/17 +| Valid for AMSS +| Used to get/set power/thermal/etc attributes. + +| QAIC_DEBUG +| Channels 18/19 +| Valid for AMSS +| Not used. + +| QAIC_TIMESYNC +| Channels 20/21 +| Valid for SBL/AMSS +| Used to synchronize timestamps in the device side logs with the host time source. + +DMA Bridge +========== + +Overview +-------- + +The DMA Bridge is one of the main interfaces to the host from the device +(the other being MHI). As part of activating a workload to run on NSPs, the QSM +assigns that network a DMA Bridge channel. A workload's DMA Bridge channel +(DBC for short) is solely for the use of that workload and is not shared with +other workloads. + +Each DBC is a pair of FIFOs that manage data in and out of the workload. One +FIFO is the request FIFO. The other FIFO is the response FIFO. + +Each DBC contains 4 registers in hardware: + +* Request FIFO head pointer (offset 0x0). Read only to the host. Indicates the + latest item in the FIFO the device has consumed. +* Request FIFO tail pointer (offset 0x4). Read/write by the host. Host + increments this register to add new items to the FIFO. +* Response FIFO head pointer (offset 0x8). Read/write by the host. Indicates + the latest item in the FIFO the host has consumed. +* Response FIFO tail pointer (offset 0xc). Read only to the host. Device + increments this register to add new items to the FIFO. + +The values in each register are indexes in the FIFO. To get the location of the +FIFO element pointed to by the register: FIFO base address + register * element +size. + +DBC registers are exposed to the host via the second BAR. Each DBC consumes +0x1000 of space in the BAR. + +The actual FIFOs are backed by host memory. When sending a request to the QSM +to activate a network, the host must donate memory to be used for the FIFOs. +Due to internal mapping limitations of the device, a single contigious chunk of +memory must be provided per DBC, which hosts both FIFOs. The request FIFO will +consume the beginning of the memory chunk, and the response FIFO will consume +the end of the memory chunk. + +Request FIFO +------------ + +A request FIFO element has the following structure: + +| { +| u16 req_id; +| u8 seq_id; +| u8 pcie_dma_cmd; +| u32 reserved; +| u64 pcie_dma_source_addr; +| u64 pcie_dma_dest_addr; +| u32 pcie_dma_len; +| u32 reserved; +| u64 doorbell_addr; +| u8 doorbell_attr; +| u8 reserved; +| u16 reserved; +| u32 doorbell_data; +| u32 sem_cmd0; +| u32 sem_cmd1; +| u32 sem_cmd2; +| u32 sem_cmd3; +| } + +Request field descriptions: + +| req_id- request ID. A request FIFO element and a response FIFO element with +| the same request ID refer to the same command. + +| seq_id- sequence ID within a request. Ignored by the DMA Bridge. + +| pcie_dma_cmd- describes the DMA element of this request. +| Bit(7) is the force msi flag, which overrides the DMA Bridge MSI logic +| and generates a MSI when this request is complete, and QSM +| configures the DMA Bridge to look at this bit. +| Bits(6:5) are reserved. +| Bit(4) is the completion code flag, and indicates that the DMA Bridge +| shall generate a response FIFO element when this request is +| complete. +| Bit(3) indicates if this request is a linked list transfer(0) or a bulk +| transfer(1). +| Bit(2) is reserved. +| Bits(1:0) indicate the type of transfer. No transfer(0), to device(1), +| from device(2). Value 3 is illegal. + +| pcie_dma_source_addr- source address for a bulk transfer, or the address of +| the linked list. + +| pcie_dma_dest_addr- destination address for a bulk transfer. + +| pcie_dma_len- length of the bulk transfer. Note that the size of this field +| limits transfers to 4G in size. + +| doorbell_addr- address of the doorbell to ring when this request is complete. + +| doorbell_attr- doorbell attributes. +| Bit(7) indicates if a write to a doorbell is to occur. +| Bits(6:2) are reserved. +| Bits(1:0) contain the encoding of the doorbell length. 0 is 32-bit, +| 1 is 16-bit, 2 is 8-bit, 3 is reserved. The doorbell address +| must be naturally aligned to the specified length. + +| doorbell_data- data to write to the doorbell. Only the bits corresponding to +| the doorbell length are valid. + +| sem_cmdN- semaphore command. +| Bit(31) indicates this semaphore command is enabled. +| Bit(30) is the to-device DMA fence. Block this request until all +| to-device DMA transfers are complete. +| Bit(29) is the from-device DMA fence. Block this request until all +| from-device DMA transfers are complete. +| Bits(28:27) are reserved. +| Bits(26:24) are the semaphore command. 0 is NOP. 1 is init with the +| specified value. 2 is increment. 3 is decrement. 4 is wait +| until the semaphore is equal to the specified value. 5 is wait +| until the semaphore is greater or equal to the specified value. +| 6 is "P", wait until semaphore is greater than 0, then +| decrement by 1. 7 is reserved. +| Bit(23) is reserved. +| Bit(22) is the semaphore sync. 0 is post sync, which means that the +| semaphore operation is done after the DMA transfer. 1 is +| presync, which gates the DMA transfer. Only one presync is +| allowed per request. +| Bit(21) is reserved. +| Bits(20:16) is the index of the semaphore to operate on. +| Bits(15:12) are reserved. +| Bits(11:0) are the semaphore value to use in operations. + +Overall, a request is processed in 4 steps: + +1. If specified, the presync semaphore condition must be true +2. If enabled, the DMA transfer occurs +3. If specified, the postsync semaphore conditions must be true +4. If enabled, the doorbell is written + +By using the semaphores in conjunction with the workload running on the NSPs, +the data pipeline can be synchronized such that the host can queue multiple +requests of data for the workload to process, but the DMA Bridge will only copy +the data into the memory of the workload when the workload is ready to process +the next input. + +Response FIFO +------------- + +Once a request is fully processed, a response FIFO element is generated if +specified in pcie_dma_cmd. The structure of a response FIFO element: + +| { +| u16 req_id; +| u16 completion_code; +| } + +req_id- matches the req_id of the request that generated this element. + +completion_code- status of this request. 0 is success. non-zero is an error. + +The DMA Bridge will generate a MSI to the host as a reaction to activity in the +response FIFO of a DBC. The DMA Bridge hardware has an IRQ storm mitigation +algorithm, where it will only generate a MSI when the response FIFO transitions +from empty to non-empty (unless force MSI is enabled and triggered). In +response to this MSI, the host is expected to drain the response FIFO, and must +take care to handle any race conditions between draining the FIFO, and the +device inserting elements into the FIFO. + +Neural Network Control (NNC) Protocol +===================================== + +The NNC protocol is how the host makes requests to the QSM to manage workloads. +It uses the QAIC_CONTROL MHI channel. + +Each NNC request is packaged into a message. Each message is a series of +transactions. A passthrough type transaction can contain elements known as +commands. + +QSM requires NNC messages be little endian encoded and the fields be naturally +aligned. Since there are 64-bit elements in some NNC messages, 64-bit alignment +must be maintained. + +A message contains a header and then a series of transactions. A message may be +at most 4K in size from QSM to the host. From the host to the QSM, a message +can be at most 64K (maximum size of a single MHI packet), but there is a +continuation feature where message N+1 can be marked as a continuation of +message N. This is used for exceedingly large DMA xfer transactions. + +Transaction descriptions: + +passthrough- Allows userspace to send an opaque payload directly to the QSM. +This is used for NNC commands. Userspace is responsible for managing +the QSM message requirements in the payload + +dma_xfer- DMA transfer. Describes an object that the QSM should DMA into the +device via address and size tuples. + +activate- Activate a workload onto NSPs. The host must provide memory to be +used by the DBC. + +deactivate- Deactivate an active workload and return the NSPs to idle. + +status- Query the QSM about it's NNC implementation. Returns the NNC version, +and if CRC is used. + +terminate- Release a user's resources. + +dma_xfer_cont- Continuation of a previous DMA transfer. If a DMA transfer +cannot be specified in a single message (highly fragmented), this +transaction can be used to specify more ranges. + +validate_partition- Query to QSM to determine if a partition identifier is +valid. + +Each message is tagged with a user id, and a partition id. The user id allows +QSM to track resources, and release them when the user goes away (eg the process +crashes). A partition id identifies the resource partition that QSM manages, +which this message applies to. + +Messages may have CRCs. Messages should have CRCs applied until the QSM +reports via the status transaction that CRCs are not needed. The QSM on the +SA9000P requires CRCs for black channel safing. + +Subsystem Restart (SSR) +======================= + +SSR is the concept of limiting the impact of an error. An AIC100 device may +have multiple users, each with their own workload running. If the workload of +one user crashes, the fallout of that should be limited to that workload and not +impact other workloads. SSR accomplishes this. + +If a particular workload crashes, QSM notifies the host via the QAIC_SSR MHI +channel. This notification identifies the workload by it's assigned DBC. A +multi-stage recovery process is then used to cleanup both sides, and get the +DBC/NSPs into a working state. + +When SSR occurs, any state in the workload is lost. Any inputs that were in +process, or queued by not yet serviced, are lost. The loaded artifacts will +remain in on-card DDR, but the host will need to re-activate the workload if +it desires to recover the workload. + +Reliability, Accessability, Serviceability (RAS) +================================================ + +AIC100 is expected to be deployed in server systems where RAS ideology is +applied. Simply put, RAS is the concept of detecting, classifying, and +reporting errors. While PCIe has AER (Advanced Error Reporting) which factors +into RAS, AER does not allow for a device to report details about internal +errors. Therefore, AIC100 implements a custom RAS mechanism. When a RAS event +occurs, QSM will report the event with appropriate details via the QAIC_STATUS +MHI channel. A sysadmin may determine that a particular device needs +additional service based on RAS reports. + +Telemetry +========= + +QSM has the ability to report various physical attributes of the device, and in +some cases, to allow the host to control them. Examples include thermal limits, +thermal readings, and power readings. These items are communicated via the +QAIC_TELEMETRY MHI channel diff --git a/Documentation/accel/qaic/index.rst b/Documentation/accel/qaic/index.rst new file mode 100644 index 0000000..ad19b88 --- /dev/null +++ b/Documentation/accel/qaic/index.rst @@ -0,0 +1,13 @@ +.. SPDX-License-Identifier: GPL-2.0-only + +===================================== + accel/qaic Qualcomm Cloud AI driver +===================================== + +The accel/qaic driver supports the Qualcomm Cloud AI machine learning +accelerator cards. + +.. toctree:: + + qaic + aic100 diff --git a/Documentation/accel/qaic/qaic.rst b/Documentation/accel/qaic/qaic.rst new file mode 100644 index 0000000..b0e7a5f --- /dev/null +++ b/Documentation/accel/qaic/qaic.rst @@ -0,0 +1,169 @@ +.. SPDX-License-Identifier: GPL-2.0-only + +============= + QAIC driver +============= + +The QAIC driver is the Kernel Mode Driver (KMD) for the AIC100 family of AI +accelerator products. + +Interrupts +========== + +While the AIC100 DMA Bridge hardware implements an IRQ storm mitigation +mechanism, it is still possible for an IRQ storm to occur. A storm can happen +if the workload is particularly quick, and the host is responsive. If the host +can drain the response FIFO as quickly as the device can insert elements into +it, then the device will frequently transition the response FIFO from empty to +non-empty and generate MSIs at a rate equilivelent to the speed of the +workload's ability to process inputs. The lprnet (license plate reader network) +workload is known to trigger this condition, and can generate in excess of 100k +MSIs per second. It has been observed that most systems cannot tolerate this +for long, and will crash due to some form of watchdog due to the overhead of +the interrupt controller interrupting the host CPU. + +To mitigate this issue, the QAIC driver implements specific IRQ handling. When +QAIC receives an IRQ, it disables that line. This prevents the interrupt +controller from interrupting the CPU. Then AIC drains the FIFO. Once the FIFO +is drained, QAIC implements a "last chance" polling algorithm where QAIC will +sleep for a time to see if the workload will generate more activity. The IRQ +line remains disabled during this time. If no activity is detected, QAIC exits +polling mode and reenables the IRQ line. + +This mitigation in QAIC is very effective. The same lprnet usecase that +generates 100k IRQs per second (per /proc/interrupts) is reduced to roughly 64 +IRQs over 5 minutes while keeping the host system stable, and having the same +workload throughput performance (within run to run noise variation). + + +Neural Network Control (NNC) Protocol +===================================== + +The implementation of NNC is split between the KMD (QAIC) and UMD. In general +QAIC understands how to encode/decode NNC wire protocol, and elements of the +protocol which require kernelspace knowledge to process (for example, mapping +host memory to device IOVAs). QAIC understands the structure of a message, and +all of the transactions. QAIC does not understand commands (the payload of a +passthrough transaction). + +QAIC handles and enforces the required little endianness and 64-bit alignment, +to the degree that it can. Since QAIC does not know the contents of a +passthrough transaction, it relies on the UMD to saitsfy the requirements. + +The terminate transaction is of particular use to QAIC. QAIC is not aware of +the resources that are loaded onto a device since the majority of that activity +occurs within NNC commands. As a result, QAIC does not have the means to +roll back userspace activity. To ensure that a userspace client's resources +are fully released in the case of a process crash, or a bug, QAIC uses the +terminate command to let QSM know when a user has gone away, and the resources +can be released. + +QSM can report a version number of the NNC protocol it supports. This is in the +form of a Major number and a Minor number. + +Major number updates indicate changes to the NNC protocol which impact the +message format, or transactions (impacts QAIC). + +Minor number updates indicate changes to the NNC protocol which impact the +commands (does not impact QAIC). + +uAPI +==== + +QAIC defines a number of driver specific IOCTLs as part of the userspace API. +This section describes those APIs. + +DRM_IOCTL_QAIC_MANAGE: +This IOCTL allows userspace to send a NNC request to the QSM. The call will +block until a response is received, or the request has timed out. + +DRM_IOCTL_QAIC_CREATE_BO: +This IOCTL allows userspace to allocate a buffer object (BO) which can send or +receive data from a workload. The call will return a GEM handle that +represents the allocated buffer. The BO is not usable until it has been sliced +(see DRM_IOCTL_QAIC_ATTACH_SLICE_BO). + +DRM_IOCTL_QAIC_MMAP_BO: +This IOCTL allows userspace to prepare an allocated BO to be mmap'd into the +userspace process. + +DRM_IOCTL_QAIC_ATTACH_SLICE_BO: +This IOCTL allows userspace to slice a BO in preparation for sending the BO to +the device. Slicing is the operation of describing what portions of a BO get +sent where to a workload. This requires a set of DMA transfers for the DMA +Bridge, and as such, locks the BO to a specific DBC. + +DRM_IOCTL_QAIC_EXECUTE_BO: +This IOCTL allows userspace to submit a set of sliced BOs to the device. The +call is non-blocking. Success only indicates that the BOs have been queued +to the device, but does not guarantee they have been executed. + +DRM_IOCTL_QAIC_PARTIAL_EXECUTE_BO: +This IOCTL operates like DRM_IOCTL_QAIC_EXECUTE_BO, but it allows userspace to +shrink the BOs sent to the device for this specific call. If a BO typically has +N inputs, but only a subset of those is available, this IOCTL allows userspace +to indicate that only the first M bytes of the BO should be sent to the device +to minimize data transfer overhead. This IOCTL dynamically recomputes the +slicing, and therefore has some processing overhead before the BOs can be queued +to the device. + +DRM_IOCTL_QAIC_WAIT_BO: +This IOCTL allows userspace to determine when a particular BO has been processed +by the device. The call will block until either the BO has been processed and +can be re-queued to the device, or a timeout occurs. + +DRM_IOCTL_QAIC_PERF_STATS_BO: +This IOCTL allows userspace to collect performance statistics on the most +recent execution of a BO. This allows userspace to construct an end to end +timeline of the BO processing for a performance analysis. + +DRM_IOCTL_QAIC_PART_DEV: +This IOCTL allows userspace to request a duplicate "shadow device". This extra +accelN device is associated with a specific partition of resources on the AIC100 +device and can be used for limiting a process to some subset of resources. + +Userspace Client Isolation +========================== + +AIC100 supports multiple clients. Multiple DBCs can be consumed by a single +client, and multiple clients can each consume one or more DBCs. Workloads +may contain sensistive information therefore only the client that owns the +workload should be allowed to interface with the DBC. + +Clients are identified by the instance associated with their open(). A client +may only use memory they allocate, and DBCs that are assigned to their +workloads. Attempts to access resources assigned to other clients will be +rejected. + +Module parameters +================= + +QAIC supports the following module parameters: + +**datapath_polling (bool)** + +Configures QAIC to use a polling thread for datapath events instead of relying +on the device interrupts. Useful for platforms with broken multiMSI. Must be +set at QAIC driver initialization. Default is 0 (off). + +**mhi_timeout (int)** + +Sets the timeout value for MHI operations in milliseconds (ms). Must be set +at the time the driver detects a device. Default is 2000 (2 seconds). + +**control_resp_timeout (int)** + +Sets the timeout value for QSM responses to NNC messages in seconds (s). Must +be set at the time the driver is sending a request to QSM. Default is 60 (one +minute). + +**wait_exec_default_timeout (int)** + +Sets the default timeout for the wait_exec ioctl in milliseconds (ms). Must be +set prior to the waic_exec ioctl call. A value specified in the ioctl call +overrides this for that call. Default is 5000 (5 seconds). + +**datapath_poll_interval_us (int)** + +Sets the polling interval in microseconds (us) when datapath polling is active. +Takes effect at the next polling interval. Default is 100 (100 us). -- 2.7.4