In this patch series we are adding below two features for Aero/Sea HBA device. Aero/Sea series HBA is PCI4.0 based controllers. 1. Add Atomic Request descriptor support: Atomic Request Descriptor is an alternative method for posting an entry onto a request queue. The posting of an Atomic Request Descriptor is an atomic operation. 2. Max Performance using balanced performance mode. (~3.0 Million IOPs for Random Read/Write): Aero Hardware interrupt coalescing behavior: H/W Interrupt coalescing is effective within a group of reply queue. Each reply queue group consists of 8 reply queues. This particular h/w interface allows to configure mixture of interrupt coalescing on/off per controller. In 128 vector mode, every 8 MSI-x vectors will be grouped together. If a reply is sent to a MSI-x vector not in the present group, h/w will flush all outstanding IOS. Below are some examples to understand h/w interrupt coalescing behavior. Let’s consider some simple io submission and completion flow to understand h/w interrupt coalescing behavior. Reply queue starts with index 0. Reply return from back end device in the same order as it was submitted (this just to explain simple case). Reply queue 0-7 is one interrupt coalescing group. Another interrupt coalescing group is 8-15. Let’s consider that CoalescingTimeout is max value just to explain h/w behavior. CoalescingDepth = 0x4 and CoalescingTimeout = 0xFFFF. Coalescing timeout: Reply coalescing timeout in units of one-half of a microsecond (500 nanoseconds). When the amount of time from the first pending reply exceeds this value, the IOC sends the replies to the host using a single interrupt. Coalescing Depth: This field specifies the reply coalescing depth. When the number of pending replies exceeds this number, the IOC sends the replies to the host using a single interrupt. 1. Driver has submitted 4 IOS to firmware for targeted reply queue groups 4, 5, 6, and 7. In this case, OS will receive 4 interrupt for 4 replies. Interrupt on reply queue group 4, 5, 6 is due to next io completion is on different msix vector group. Interrupt on reply queue 7 is due to coalescing timeout criteria (as their are no IOs after this). 2. Driver has submitted 4 IOS to firmware for targeted reply queues group 4, 4, 6, and 6. In this case, OS will receive 2 interrupt for 4 replies. First interrupt on reply queue group 4 will be before coalescing timeout elapsed. Since next io completion is on a different msix vector group, interrupt on reply queue group 6 will be after coalescing timeout elapsed. 3. Driver has submitted 6 IOS to firmware for targeted reply queue group 4, 4, 4, 4, 4 and 5. In this case, OS will receive 3 interrupt for 6 replies. First Interrupt on reply queue 4 will be before coalescing timeout elapsed due to coalesced depth criteria meet. Second Interrupt on reply queue 4 will be before coalescing timeout elapsed, since next io completion is on different msix vector. Third interrupt on reply queue group 5 will be after coalescing timeout elapsed. Balanced performance interface for Aero/Sea: Driver will use combination of interrupt coalescing and no interrupt coalescing in h/w. Driver will create few high iops queue to get high IOPs on Aero/Sea family controllers. Low latency queues are queues without interrupt coalsecing. High iops queue are special queue which has interrupt coalescing ON (e.a 0x4 Coalescing depth and 0x20 Coalescing Timeout). In general, high iops queue and low latency queue together should fit into 128 reply queue (max reply queue supported by Aero/Sea). Driver should pick only few high iops queue because it should not change low latency io path as much as possible and at the same time few high iops queue should be good enough to get the high iops numbers. High level design of creating number of high iops queues: If there are unused reply queue left in the system due to logical cpu count is less than firmware supported msix vectors, driver should increase effective reply queues. Example: 2 socket server (total 72 logical CPU). There are total 56 reply queue unmapped in that system. Driver should map low latency reply queue starting from 8 to 79 and should map high iops reply queue starting from 0 to 7. If #online cpus are more than or equal to 120 (derives from #total msix supported by firmware minus high iops queue), allocate 128 reply queues. Driver should map low latency reply queue starting from 8 to 127. Driver should map high iops reply queue starting from 0 to 7. If driver is not able to allocate required reply queues, it should fall back to legacy mode (without high iops queue) IO submission (Below is applicable only if high iops queue is enabled): If outstanding IOs per scsi device is less than or equal to 8, use legacy io path (i.e use low latency reply queue). If outstanding IOs per scsi device is more than 8 - Driver should do round robin io submission in batches on high iops queue. Example: Batches of the 16. “First 16 IOS submitted to reply queue 0, next 16 IOS submitted to reply queue 1 etc”. Suganath Prabu S (10): mpt3sas: function pointers of request descriptor mpt3sas: Add Atomic Request Descriptor support on Aero mpt3sas: Add flag high_iops_queues mpt3sas: change _base_get_msix_index prototype mpt3sas: Use highiops queues if more in-flights mpt3sas: save msix index and use same while posting RD mpt3sas: Affinity high iops queues IRQs to local node mpt3sas: Enable interrupt coalescing on high iops mpt3sas: Introduce perf_mode module parameter mpt3sas: Update driver version to 29.100.00.00 drivers/scsi/mpt3sas/mpi/mpi2_cnfg.h | 2 +- drivers/scsi/mpt3sas/mpt3sas_base.c | 470 ++++++++++++++++++++++++++++--- drivers/scsi/mpt3sas/mpt3sas_base.h | 34 ++- drivers/scsi/mpt3sas/mpt3sas_config.c | 73 ++++- drivers/scsi/mpt3sas/mpt3sas_ctl.c | 20 +- drivers/scsi/mpt3sas/mpt3sas_scsih.c | 38 ++- drivers/scsi/mpt3sas/mpt3sas_transport.c | 8 +- 7 files changed, 571 insertions(+), 74 deletions(-) -- 1.8.3.1