/* * SPDX-FileCopyrightText: Copyright (c) 2017-2019 NVIDIA CORPORATION & AFFILIATES. All rights reserved. * SPDX-License-Identifier: MIT * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /* * nv-ibmnpu.c - interface with the ibmnpu (IBM NVLink Processing Unit) "module" */ #include "nv-linux.h" #if defined(NVCPU_PPC64LE) #include "nv-ibmnpu.h" #include "nv-rsync.h" /* * Temporary query to get the L1D cache block size directly from the device * tree for the offline cache flush workaround, since the ppc64_caches symbol * is unavailable to us. */ const NvU32 P9_L1D_CACHE_DEFAULT_BLOCK_SIZE = 0x80; #if defined(NV_OF_GET_PROPERTY_PRESENT) static NvU32 nv_ibm_get_cpu_l1d_cache_block_size(void) { const __be32 *block_size_prop; /* * Attempt to look up the block size from device tree. If unavailable, just * return the default that we see on these systems. */ struct device_node *cpu = of_find_node_by_type(NULL, "cpu"); if (!cpu) { return P9_L1D_CACHE_DEFAULT_BLOCK_SIZE; } block_size_prop = of_get_property(cpu, "d-cache-block-size", NULL); if (!block_size_prop) { return P9_L1D_CACHE_DEFAULT_BLOCK_SIZE; } return be32_to_cpu(*block_size_prop); } #else static NvU32 nv_ibm_get_cpu_l1d_cache_block_size(void) { return P9_L1D_CACHE_DEFAULT_BLOCK_SIZE; } #endif /* * GPU device memory can be exposed to the kernel as NUMA node memory via the * IBMNPU devices associated with the GPU. The platform firmware will specify * the parameters of where the memory lives in the system address space via * firmware properties on the IBMNPU devices. These properties specify what * memory can be accessed through the IBMNPU device, and the driver can online * a GPU device's memory into the range accessible by its associated IBMNPU * devices. * * This function calls over to the IBMNPU driver to query the parameters from * firmware, and validates that the resulting parameters are acceptable. */ static void nv_init_ibmnpu_numa_info(nv_state_t *nv) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); nv_npu_numa_info_t *npu_numa_info = &nvl->npu->numa_info; struct pci_dev *npu_dev = nvl->npu->devs[0]; NvU64 spa, gpa, aper_size; /* * Terminology: * - system physical address (spa): 47-bit NVIDIA physical address, which * is the CPU real address with the NVLink address compression scheme * already applied in firmware. * - guest physical address (gpa): 56-bit physical address as seen by the * operating system. This is the base address that we should use for * onlining device memory. */ nvl->numa_info.node_id = ibmnpu_device_get_memory_config(npu_dev, &spa, &gpa, &aper_size); if (nvl->numa_info.node_id == NUMA_NO_NODE) { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "No NUMA memory aperture found\n"); return; } /* Validate that the compressed system physical address is not too wide */ if (spa & (~(BIT_ULL(nv_volta_dma_addr_size) - 1))) { NV_DEV_PRINTF(NV_DBG_ERRORS, nv, "Invalid NUMA memory system pa 0x%llx" " on IBM-NPU device %04x:%02x:%02x.%u\n", spa, NV_PCI_DOMAIN_NUMBER(npu_dev), NV_PCI_BUS_NUMBER(npu_dev), NV_PCI_SLOT_NUMBER(npu_dev), PCI_FUNC(npu_dev->devfn)); goto invalid_numa_config; } /* * Validate that the guest physical address is aligned to 128GB. * This alignment requirement comes from the Volta address space * size on POWER9. */ if (!IS_ALIGNED(gpa, BIT_ULL(nv_volta_addr_space_width))) { NV_DEV_PRINTF(NV_DBG_ERRORS, nv, "Invalid alignment in NUMA memory guest pa 0x%llx" " on IBM-NPU device %04x:%02x:%02x.%u\n", gpa, NV_PCI_DOMAIN_NUMBER(npu_dev), NV_PCI_BUS_NUMBER(npu_dev), NV_PCI_SLOT_NUMBER(npu_dev), PCI_FUNC(npu_dev->devfn)); goto invalid_numa_config; } /* Validate that the aperture can map all of the device's framebuffer */ if (aper_size < nv->fb->size) { NV_DEV_PRINTF(NV_DBG_ERRORS, nv, "Insufficient NUMA memory aperture size 0x%llx" " on IBM-NPU device %04x:%02x:%02x.%u (0x%llx required)\n", aper_size, NV_PCI_DOMAIN_NUMBER(npu_dev), NV_PCI_BUS_NUMBER(npu_dev), NV_PCI_SLOT_NUMBER(npu_dev), PCI_FUNC(npu_dev->devfn), nv->fb->size); goto invalid_numa_config; } npu_numa_info->compr_sys_phys_addr = spa; npu_numa_info->guest_phys_addr = gpa; if (NVreg_EnableUserNUMAManagement) { NV_ATOMIC_SET(nvl->numa_info.status, NV_IOCTL_NUMA_STATUS_OFFLINE); } else { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "User-mode NUMA onlining disabled.\n"); nvl->numa_info.node_id = NUMA_NO_NODE; } NV_DEV_PRINTF(NV_DBG_SETUP, nv, "NUMA memory aperture: " "[spa = 0x%llx, gpa = 0x%llx, aper_size = 0x%llx]\n", spa, gpa, aper_size); /* Get the CPU's L1D cache block size for offlining cache flush */ npu_numa_info->l1d_cache_block_size = nv_ibm_get_cpu_l1d_cache_block_size(); return; invalid_numa_config: NV_DEV_PRINTF(NV_DBG_ERRORS, nv, "NUMA memory aperture disabled due to invalid firmware configuration\n"); nvl->numa_info.node_id = NUMA_NO_NODE; } void nv_init_ibmnpu_info(nv_state_t *nv) { #if defined(NV_PNV_PCI_GET_NPU_DEV_PRESENT) nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); struct pci_dev *npu_dev = pnv_pci_get_npu_dev(nvl->pci_dev, 0); NvU8 dev_count; if (!npu_dev) { return; } if (os_alloc_mem((void **)&nvl->npu, sizeof(nv_ibmnpu_info_t)) != NV_OK) { return; } os_mem_set(nvl->npu, 0, sizeof(nv_ibmnpu_info_t)); /* Find any other IBMNPU devices attached to this GPU */ for (nvl->npu->devs[0] = npu_dev, dev_count = 1; dev_count < NV_MAX_ATTACHED_IBMNPUS; dev_count++) { nvl->npu->devs[dev_count] = pnv_pci_get_npu_dev(nvl->pci_dev, dev_count); if (!nvl->npu->devs[dev_count]) { break; } } nvl->npu->dev_count = dev_count; /* * If we run out of space for IBMNPU devices, NV_MAX_ATTACHED_IBMNPUS will * need to be bumped. */ WARN_ON((dev_count == NV_MAX_ATTACHED_IBMNPUS) && pnv_pci_get_npu_dev(nvl->pci_dev, dev_count)); ibmnpu_device_get_genregs_info(npu_dev, &nvl->npu->genregs); if (nvl->npu->genregs.size > 0) { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "IBM-NPU device %04x:%02x:%02x.%u associated with GPU " " has a generation register space 0x%llx-0x%llx\n", NV_PCI_DOMAIN_NUMBER(npu_dev), NV_PCI_BUS_NUMBER(npu_dev), NV_PCI_SLOT_NUMBER(npu_dev), PCI_FUNC(npu_dev->devfn), nvl->npu->genregs.start_addr, nvl->npu->genregs.start_addr + nvl->npu->genregs.size - 1); } else { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "IBM-NPU device %04x:%02x:%02x.%u associated with GPU " "does not support generation registers\n", NV_PCI_DOMAIN_NUMBER(npu_dev), NV_PCI_BUS_NUMBER(npu_dev), NV_PCI_SLOT_NUMBER(npu_dev), PCI_FUNC(npu_dev->devfn)); } nv_init_ibmnpu_numa_info(nv); #endif } void nv_destroy_ibmnpu_info(nv_state_t *nv) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (nvl->npu != NULL) { os_free_mem(nvl->npu); nvl->npu = NULL; } } int nv_init_ibmnpu_devices(nv_state_t *nv) { NvU8 i; nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (!nvl->npu) { return 0; } for (i = 0; i < nvl->npu->dev_count; i++) { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "Initializing IBM-NPU device %04x:%02x:%02x.%u\n", NV_PCI_DOMAIN_NUMBER(nvl->npu->devs[i]), NV_PCI_BUS_NUMBER(nvl->npu->devs[i]), NV_PCI_SLOT_NUMBER(nvl->npu->devs[i]), PCI_FUNC(nvl->npu->devs[i]->devfn)); if (ibmnpu_init_device(nvl->npu->devs[i]) != NVL_SUCCESS) { nv_unregister_ibmnpu_devices(nv); return -EIO; } nvl->npu->initialized_dev_count++; } return 0; } void nv_unregister_ibmnpu_devices(nv_state_t *nv) { NvU8 i; nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (!nvl->npu) { return; } for (i = 0; i < nvl->npu->initialized_dev_count; i++) { NV_DEV_PRINTF(NV_DBG_SETUP, nv, "Unregistering IBM-NPU device %04x:%02x:%02x.%u\n", NV_PCI_DOMAIN_NUMBER(nvl->npu->devs[i]), NV_PCI_BUS_NUMBER(nvl->npu->devs[i]), NV_PCI_SLOT_NUMBER(nvl->npu->devs[i]), PCI_FUNC(nvl->npu->devs[i]->devfn)); ibmnpu_unregister_device(nvl->npu->devs[i]); } nvl->npu->initialized_dev_count = 0; } NV_STATUS NV_API_CALL nv_get_ibmnpu_genreg_info(nv_state_t *nv, NvU64 *addr, NvU64 *size, void **device) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (nvl->npu == NULL || nvl->npu->genregs.size == 0) { return NV_ERR_NOT_SUPPORTED; } if (addr) { *addr = nvl->npu->genregs.start_addr; } if (size) { *size = nvl->npu->genregs.size; } if (device) { *device = (void*)nvl->npu->devs[0]; } return NV_OK; } NV_STATUS NV_API_CALL nv_get_ibmnpu_relaxed_ordering_mode(nv_state_t *nv, NvBool *mode) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (nvl->npu == NULL || nvl->npu->genregs.size == 0) { return NV_ERR_NOT_SUPPORTED; } *mode = nv_get_rsync_relaxed_ordering_mode(nv); return NV_OK; } void NV_API_CALL nv_wait_for_ibmnpu_rsync(nv_state_t *nv) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (nvl->npu == NULL || nvl->npu->genregs.size == 0) { return; } nv_wait_for_rsync(nv); } int nv_get_ibmnpu_chip_id(nv_state_t *nv) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); if (nvl->npu == NULL) { return -1; } return ibmnpu_device_get_chip_id(nvl->npu->devs[0]); } void NV_API_CALL nv_ibmnpu_cache_flush_range(nv_state_t *nv, NvU64 cpu_virtual, NvU64 size) { nv_linux_state_t *nvl = NV_GET_NVL_FROM_NV_STATE(nv); NvU64 offset, cbsize; /* * The range is commonly an ioremap()ed mapping of the GPU's ATS range and * needs to be compared against the created mappings. Alternatively, kernel * page tables can be dumped through sysfs if CONFIG_PPC_PTDUMP is enabled. */ NV_DEV_PRINTF(NV_DBG_INFO, nv, "Flushing CPU virtual range [0x%llx, 0x%llx)\n", cpu_virtual, cpu_virtual + size); cbsize = nvl->npu->numa_info.l1d_cache_block_size; CACHE_FLUSH(); /* Force eviction of any cache lines from the NUMA-onlined region. */ for (offset = 0; offset < size; offset += cbsize) { asm volatile("dcbf %0,%1" :: "r" (cpu_virtual), "r" (offset) : "memory"); /* Reschedule if necessary to avoid lockup warnings */ cond_resched(); } CACHE_FLUSH(); } #else void nv_init_ibmnpu_info(nv_state_t *nv) { } void nv_destroy_ibmnpu_info(nv_state_t *nv) { } int nv_init_ibmnpu_devices(nv_state_t *nv) { return 0; } void nv_unregister_ibmnpu_devices(nv_state_t *nv) { } NV_STATUS NV_API_CALL nv_get_ibmnpu_genreg_info(nv_state_t *nv, NvU64 *addr, NvU64 *size, void **device) { return NV_ERR_NOT_SUPPORTED; } NV_STATUS NV_API_CALL nv_get_ibmnpu_relaxed_ordering_mode(nv_state_t *nv, NvBool *mode) { return NV_ERR_NOT_SUPPORTED; } void NV_API_CALL nv_wait_for_ibmnpu_rsync(nv_state_t *nv) { } int nv_get_ibmnpu_chip_id(nv_state_t *nv) { return -1; } void NV_API_CALL nv_ibmnpu_cache_flush_range(nv_state_t *nv, NvU64 virtual, NvU64 size) { } void nv_ibmnpu_cache_flush_numa_region(nv_state_t *nv) { } #endif