Ian Munsie | a9282d0 | 2014-10-08 19:55:05 +1100 | [diff] [blame] | 1 | Coherent Accelerator Interface (CXL) |
| 2 | ==================================== |
| 3 | |
| 4 | Introduction |
| 5 | ============ |
| 6 | |
| 7 | The coherent accelerator interface is designed to allow the |
| 8 | coherent connection of accelerators (FPGAs and other devices) to a |
| 9 | POWER system. These devices need to adhere to the Coherent |
| 10 | Accelerator Interface Architecture (CAIA). |
| 11 | |
| 12 | IBM refers to this as the Coherent Accelerator Processor Interface |
| 13 | or CAPI. In the kernel it's referred to by the name CXL to avoid |
| 14 | confusion with the ISDN CAPI subsystem. |
| 15 | |
| 16 | Coherent in this context means that the accelerator and CPUs can |
| 17 | both access system memory directly and with the same effective |
| 18 | addresses. |
| 19 | |
| 20 | |
| 21 | Hardware overview |
| 22 | ================= |
| 23 | |
| 24 | POWER8 FPGA |
| 25 | +----------+ +---------+ |
| 26 | | | | | |
| 27 | | CPU | | AFU | |
| 28 | | | | | |
| 29 | | | | | |
| 30 | | | | | |
| 31 | +----------+ +---------+ |
| 32 | | PHB | | | |
| 33 | | +------+ | PSL | |
| 34 | | | CAPP |<------>| | |
| 35 | +---+------+ PCIE +---------+ |
| 36 | |
| 37 | The POWER8 chip has a Coherently Attached Processor Proxy (CAPP) |
| 38 | unit which is part of the PCIe Host Bridge (PHB). This is managed |
| 39 | by Linux by calls into OPAL. Linux doesn't directly program the |
| 40 | CAPP. |
| 41 | |
| 42 | The FPGA (or coherently attached device) consists of two parts. |
| 43 | The POWER Service Layer (PSL) and the Accelerator Function Unit |
| 44 | (AFU). The AFU is used to implement specific functionality behind |
| 45 | the PSL. The PSL, among other things, provides memory address |
| 46 | translation services to allow each AFU direct access to userspace |
| 47 | memory. |
| 48 | |
| 49 | The AFU is the core part of the accelerator (eg. the compression, |
| 50 | crypto etc function). The kernel has no knowledge of the function |
| 51 | of the AFU. Only userspace interacts directly with the AFU. |
| 52 | |
| 53 | The PSL provides the translation and interrupt services that the |
| 54 | AFU needs. This is what the kernel interacts with. For example, if |
| 55 | the AFU needs to read a particular effective address, it sends |
| 56 | that address to the PSL, the PSL then translates it, fetches the |
| 57 | data from memory and returns it to the AFU. If the PSL has a |
| 58 | translation miss, it interrupts the kernel and the kernel services |
| 59 | the fault. The context to which this fault is serviced is based on |
| 60 | who owns that acceleration function. |
| 61 | |
| 62 | |
| 63 | AFU Modes |
| 64 | ========= |
| 65 | |
| 66 | There are two programming modes supported by the AFU. Dedicated |
| 67 | and AFU directed. AFU may support one or both modes. |
| 68 | |
| 69 | When using dedicated mode only one MMU context is supported. In |
| 70 | this mode, only one userspace process can use the accelerator at |
| 71 | time. |
| 72 | |
| 73 | When using AFU directed mode, up to 16K simultaneous contexts can |
| 74 | be supported. This means up to 16K simultaneous userspace |
| 75 | applications may use the accelerator (although specific AFUs may |
| 76 | support fewer). In this mode, the AFU sends a 16 bit context ID |
| 77 | with each of its requests. This tells the PSL which context is |
| 78 | associated with each operation. If the PSL can't translate an |
| 79 | operation, the ID can also be accessed by the kernel so it can |
| 80 | determine the userspace context associated with an operation. |
| 81 | |
| 82 | |
| 83 | MMIO space |
| 84 | ========== |
| 85 | |
| 86 | A portion of the accelerator MMIO space can be directly mapped |
| 87 | from the AFU to userspace. Either the whole space can be mapped or |
| 88 | just a per context portion. The hardware is self describing, hence |
| 89 | the kernel can determine the offset and size of the per context |
| 90 | portion. |
| 91 | |
| 92 | |
| 93 | Interrupts |
| 94 | ========== |
| 95 | |
| 96 | AFUs may generate interrupts that are destined for userspace. These |
| 97 | are received by the kernel as hardware interrupts and passed onto |
| 98 | userspace by a read syscall documented below. |
| 99 | |
| 100 | Data storage faults and error interrupts are handled by the kernel |
| 101 | driver. |
| 102 | |
| 103 | |
| 104 | Work Element Descriptor (WED) |
| 105 | ============================= |
| 106 | |
| 107 | The WED is a 64-bit parameter passed to the AFU when a context is |
| 108 | started. Its format is up to the AFU hence the kernel has no |
| 109 | knowledge of what it represents. Typically it will be the |
| 110 | effective address of a work queue or status block where the AFU |
| 111 | and userspace can share control and status information. |
| 112 | |
| 113 | |
| 114 | |
| 115 | |
| 116 | User API |
| 117 | ======== |
| 118 | |
| 119 | For AFUs operating in AFU directed mode, two character device |
| 120 | files will be created. /dev/cxl/afu0.0m will correspond to a |
| 121 | master context and /dev/cxl/afu0.0s will correspond to a slave |
| 122 | context. Master contexts have access to the full MMIO space an |
| 123 | AFU provides. Slave contexts have access to only the per process |
| 124 | MMIO space an AFU provides. |
| 125 | |
| 126 | For AFUs operating in dedicated process mode, the driver will |
| 127 | only create a single character device per AFU called |
| 128 | /dev/cxl/afu0.0d. This will have access to the entire MMIO space |
| 129 | that the AFU provides (like master contexts in AFU directed). |
| 130 | |
| 131 | The types described below are defined in include/uapi/misc/cxl.h |
| 132 | |
| 133 | The following file operations are supported on both slave and |
| 134 | master devices. |
| 135 | |
| 136 | |
| 137 | open |
| 138 | ---- |
| 139 | |
| 140 | Opens the device and allocates a file descriptor to be used with |
| 141 | the rest of the API. |
| 142 | |
| 143 | A dedicated mode AFU only has one context and only allows the |
| 144 | device to be opened once. |
| 145 | |
| 146 | An AFU directed mode AFU can have many contexts, the device can be |
| 147 | opened once for each context that is available. |
| 148 | |
| 149 | When all available contexts are allocated the open call will fail |
| 150 | and return -ENOSPC. |
| 151 | |
| 152 | Note: IRQs need to be allocated for each context, which may limit |
| 153 | the number of contexts that can be created, and therefore |
| 154 | how many times the device can be opened. The POWER8 CAPP |
| 155 | supports 2040 IRQs and 3 are used by the kernel, so 2037 are |
| 156 | left. If 1 IRQ is needed per context, then only 2037 |
| 157 | contexts can be allocated. If 4 IRQs are needed per context, |
| 158 | then only 2037/4 = 509 contexts can be allocated. |
| 159 | |
| 160 | |
| 161 | ioctl |
| 162 | ----- |
| 163 | |
| 164 | CXL_IOCTL_START_WORK: |
| 165 | Starts the AFU context and associates it with the current |
| 166 | process. Once this ioctl is successfully executed, all memory |
| 167 | mapped into this process is accessible to this AFU context |
| 168 | using the same effective addresses. No additional calls are |
| 169 | required to map/unmap memory. The AFU memory context will be |
| 170 | updated as userspace allocates and frees memory. This ioctl |
| 171 | returns once the AFU context is started. |
| 172 | |
| 173 | Takes a pointer to a struct cxl_ioctl_start_work: |
| 174 | |
| 175 | struct cxl_ioctl_start_work { |
| 176 | __u64 flags; |
| 177 | __u64 work_element_descriptor; |
| 178 | __u64 amr; |
| 179 | __s16 num_interrupts; |
| 180 | __s16 reserved1; |
| 181 | __s32 reserved2; |
| 182 | __u64 reserved3; |
| 183 | __u64 reserved4; |
| 184 | __u64 reserved5; |
| 185 | __u64 reserved6; |
| 186 | }; |
| 187 | |
| 188 | flags: |
| 189 | Indicates which optional fields in the structure are |
| 190 | valid. |
| 191 | |
| 192 | work_element_descriptor: |
| 193 | The Work Element Descriptor (WED) is a 64-bit argument |
| 194 | defined by the AFU. Typically this is an effective |
| 195 | address pointing to an AFU specific structure |
| 196 | describing what work to perform. |
| 197 | |
| 198 | amr: |
| 199 | Authority Mask Register (AMR), same as the powerpc |
| 200 | AMR. This field is only used by the kernel when the |
| 201 | corresponding CXL_START_WORK_AMR value is specified in |
| 202 | flags. If not specified the kernel will use a default |
| 203 | value of 0. |
| 204 | |
| 205 | num_interrupts: |
| 206 | Number of userspace interrupts to request. This field |
| 207 | is only used by the kernel when the corresponding |
| 208 | CXL_START_WORK_NUM_IRQS value is specified in flags. |
| 209 | If not specified the minimum number required by the |
| 210 | AFU will be allocated. The min and max number can be |
| 211 | obtained from sysfs. |
| 212 | |
| 213 | reserved fields: |
| 214 | For ABI padding and future extensions |
| 215 | |
| 216 | CXL_IOCTL_GET_PROCESS_ELEMENT: |
| 217 | Get the current context id, also known as the process element. |
| 218 | The value is returned from the kernel as a __u32. |
| 219 | |
| 220 | |
| 221 | mmap |
| 222 | ---- |
| 223 | |
| 224 | An AFU may have an MMIO space to facilitate communication with the |
| 225 | AFU. If it does, the MMIO space can be accessed via mmap. The size |
| 226 | and contents of this area are specific to the particular AFU. The |
| 227 | size can be discovered via sysfs. |
| 228 | |
| 229 | In AFU directed mode, master contexts are allowed to map all of |
| 230 | the MMIO space and slave contexts are allowed to only map the per |
| 231 | process MMIO space associated with the context. In dedicated |
| 232 | process mode the entire MMIO space can always be mapped. |
| 233 | |
| 234 | This mmap call must be done after the START_WORK ioctl. |
| 235 | |
| 236 | Care should be taken when accessing MMIO space. Only 32 and 64-bit |
| 237 | accesses are supported by POWER8. Also, the AFU will be designed |
| 238 | with a specific endianness, so all MMIO accesses should consider |
| 239 | endianness (recommend endian(3) variants like: le64toh(), |
| 240 | be64toh() etc). These endian issues equally apply to shared memory |
| 241 | queues the WED may describe. |
| 242 | |
| 243 | |
| 244 | read |
| 245 | ---- |
| 246 | |
| 247 | Reads events from the AFU. Blocks if no events are pending |
| 248 | (unless O_NONBLOCK is supplied). Returns -EIO in the case of an |
| 249 | unrecoverable error or if the card is removed. |
| 250 | |
| 251 | read() will always return an integral number of events. |
| 252 | |
| 253 | The buffer passed to read() must be at least 4K bytes. |
| 254 | |
| 255 | The result of the read will be a buffer of one or more events, |
| 256 | each event is of type struct cxl_event, of varying size. |
| 257 | |
| 258 | struct cxl_event { |
| 259 | struct cxl_event_header header; |
| 260 | union { |
| 261 | struct cxl_event_afu_interrupt irq; |
| 262 | struct cxl_event_data_storage fault; |
| 263 | struct cxl_event_afu_error afu_error; |
| 264 | }; |
| 265 | }; |
| 266 | |
| 267 | The struct cxl_event_header is defined as: |
| 268 | |
| 269 | struct cxl_event_header { |
| 270 | __u16 type; |
| 271 | __u16 size; |
| 272 | __u16 process_element; |
| 273 | __u16 reserved1; |
| 274 | }; |
| 275 | |
| 276 | type: |
| 277 | This defines the type of event. The type determines how |
| 278 | the rest of the event is structured. These types are |
| 279 | described below and defined by enum cxl_event_type. |
| 280 | |
| 281 | size: |
| 282 | This is the size of the event in bytes including the |
| 283 | struct cxl_event_header. The start of the next event can |
| 284 | be found at this offset from the start of the current |
| 285 | event. |
| 286 | |
| 287 | process_element: |
| 288 | Context ID of the event. |
| 289 | |
| 290 | reserved field: |
| 291 | For future extensions and padding. |
| 292 | |
| 293 | If the event type is CXL_EVENT_AFU_INTERRUPT then the event |
| 294 | structure is defined as: |
| 295 | |
| 296 | struct cxl_event_afu_interrupt { |
| 297 | __u16 flags; |
| 298 | __u16 irq; /* Raised AFU interrupt number */ |
| 299 | __u32 reserved1; |
| 300 | }; |
| 301 | |
| 302 | flags: |
| 303 | These flags indicate which optional fields are present |
| 304 | in this struct. Currently all fields are mandatory. |
| 305 | |
| 306 | irq: |
| 307 | The IRQ number sent by the AFU. |
| 308 | |
| 309 | reserved field: |
| 310 | For future extensions and padding. |
| 311 | |
| 312 | If the event type is CXL_EVENT_DATA_STORAGE then the event |
| 313 | structure is defined as: |
| 314 | |
| 315 | struct cxl_event_data_storage { |
| 316 | __u16 flags; |
| 317 | __u16 reserved1; |
| 318 | __u32 reserved2; |
| 319 | __u64 addr; |
| 320 | __u64 dsisr; |
| 321 | __u64 reserved3; |
| 322 | }; |
| 323 | |
| 324 | flags: |
| 325 | These flags indicate which optional fields are present in |
| 326 | this struct. Currently all fields are mandatory. |
| 327 | |
| 328 | address: |
| 329 | The address that the AFU unsuccessfully attempted to |
| 330 | access. Valid accesses will be handled transparently by the |
| 331 | kernel but invalid accesses will generate this event. |
| 332 | |
| 333 | dsisr: |
| 334 | This field gives information on the type of fault. It is a |
| 335 | copy of the DSISR from the PSL hardware when the address |
| 336 | fault occurred. The form of the DSISR is as defined in the |
| 337 | CAIA. |
| 338 | |
| 339 | reserved fields: |
| 340 | For future extensions |
| 341 | |
| 342 | If the event type is CXL_EVENT_AFU_ERROR then the event structure |
| 343 | is defined as: |
| 344 | |
| 345 | struct cxl_event_afu_error { |
| 346 | __u16 flags; |
| 347 | __u16 reserved1; |
| 348 | __u32 reserved2; |
| 349 | __u64 error; |
| 350 | }; |
| 351 | |
| 352 | flags: |
| 353 | These flags indicate which optional fields are present in |
| 354 | this struct. Currently all fields are Mandatory. |
| 355 | |
| 356 | error: |
| 357 | Error status from the AFU. Defined by the AFU. |
| 358 | |
| 359 | reserved fields: |
| 360 | For future extensions and padding |
| 361 | |
| 362 | Sysfs Class |
| 363 | =========== |
| 364 | |
| 365 | A cxl sysfs class is added under /sys/class/cxl to facilitate |
| 366 | enumeration and tuning of the accelerators. Its layout is |
| 367 | described in Documentation/ABI/testing/sysfs-class-cxl |
| 368 | |
| 369 | Udev rules |
| 370 | ========== |
| 371 | |
| 372 | The following udev rules could be used to create a symlink to the |
| 373 | most logical chardev to use in any programming mode (afuX.Yd for |
| 374 | dedicated, afuX.Ys for afu directed), since the API is virtually |
| 375 | identical for each: |
| 376 | |
| 377 | SUBSYSTEM=="cxl", ATTRS{mode}=="dedicated_process", SYMLINK="cxl/%b" |
| 378 | SUBSYSTEM=="cxl", ATTRS{mode}=="afu_directed", \ |
| 379 | KERNEL=="afu[0-9]*.[0-9]*s", SYMLINK="cxl/%b" |