/* SPDX-License-Identifier: BSD-3-Clause * * Copyright 2016,2018 NXP * */ #include #include #include #include #include #include #include #include #include #include #include #include #include "fslmc_logs.h" #include int dpaa2_logtype_bus; #define VFIO_IOMMU_GROUP_PATH "/sys/kernel/iommu_groups" #define FSLMC_BUS_NAME fslmc struct rte_fslmc_bus rte_fslmc_bus; uint8_t dpaa2_virt_mode; uint32_t rte_fslmc_get_device_count(enum rte_dpaa2_dev_type device_type) { if (device_type > DPAA2_DEVTYPE_MAX) return 0; return rte_fslmc_bus.device_count[device_type]; } RTE_DEFINE_PER_LCORE(struct dpaa2_portal_dqrr, dpaa2_held_bufs); static void cleanup_fslmc_device_list(void) { struct rte_dpaa2_device *dev; struct rte_dpaa2_device *t_dev; TAILQ_FOREACH_SAFE(dev, &rte_fslmc_bus.device_list, next, t_dev) { TAILQ_REMOVE(&rte_fslmc_bus.device_list, dev, next); free(dev); dev = NULL; } } static int compare_dpaa2_devname(struct rte_dpaa2_device *dev1, struct rte_dpaa2_device *dev2) { int comp; if (dev1->dev_type > dev2->dev_type) { comp = 1; } else if (dev1->dev_type < dev2->dev_type) { comp = -1; } else { /* Check the ID as types match */ if (dev1->object_id > dev2->object_id) comp = 1; else if (dev1->object_id < dev2->object_id) comp = -1; else comp = 0; /* Duplicate device name */ } return comp; } static void insert_in_device_list(struct rte_dpaa2_device *newdev) { int comp, inserted = 0; struct rte_dpaa2_device *dev = NULL; struct rte_dpaa2_device *tdev = NULL; TAILQ_FOREACH_SAFE(dev, &rte_fslmc_bus.device_list, next, tdev) { comp = compare_dpaa2_devname(newdev, dev); if (comp < 0) { TAILQ_INSERT_BEFORE(dev, newdev, next); inserted = 1; break; } } if (!inserted) TAILQ_INSERT_TAIL(&rte_fslmc_bus.device_list, newdev, next); } static struct rte_devargs * fslmc_devargs_lookup(struct rte_dpaa2_device *dev) { struct rte_devargs *devargs; char dev_name[32]; RTE_EAL_DEVARGS_FOREACH("fslmc", devargs) { devargs->bus->parse(devargs->name, &dev_name); if (strcmp(dev_name, dev->device.name) == 0) { DPAA2_BUS_INFO("**Devargs matched %s", dev_name); return devargs; } } return NULL; } static void dump_device_list(void) { struct rte_dpaa2_device *dev; uint32_t global_log_level; int local_log_level; /* Only if the log level has been set to Debugging, print list */ global_log_level = rte_log_get_global_level(); local_log_level = rte_log_get_level(dpaa2_logtype_bus); if (global_log_level == RTE_LOG_DEBUG || local_log_level == RTE_LOG_DEBUG) { DPAA2_BUS_LOG(DEBUG, "List of devices scanned on bus:"); TAILQ_FOREACH(dev, &rte_fslmc_bus.device_list, next) { DPAA2_BUS_LOG(DEBUG, "\t\t%s", dev->device.name); } } } static int scan_one_fslmc_device(char *dev_name) { char *dup_dev_name, *t_ptr; struct rte_dpaa2_device *dev; if (!dev_name) return -1; /* Ignore the Container name itself */ if (!strncmp("dprc", dev_name, 4)) return 0; /* Creating a temporary copy to perform cut-parse over string */ dup_dev_name = strdup(dev_name); if (!dup_dev_name) { DPAA2_BUS_ERR("Unable to allocate device name memory"); return -ENOMEM; } /* For all other devices, we allocate rte_dpaa2_device. * For those devices where there is no driver, probe would release * the memory associated with the rte_dpaa2_device after necessary * initialization. */ dev = calloc(1, sizeof(struct rte_dpaa2_device)); if (!dev) { DPAA2_BUS_ERR("Unable to allocate device object"); free(dup_dev_name); return -ENOMEM; } dev->device.bus = &rte_fslmc_bus.bus; /* Parse the device name and ID */ t_ptr = strtok(dup_dev_name, "."); if (!t_ptr) { DPAA2_BUS_ERR("Incorrect device name observed"); goto cleanup; } if (!strncmp("dpni", t_ptr, 4)) dev->dev_type = DPAA2_ETH; else if (!strncmp("dpseci", t_ptr, 6)) dev->dev_type = DPAA2_CRYPTO; else if (!strncmp("dpcon", t_ptr, 5)) dev->dev_type = DPAA2_CON; else if (!strncmp("dpbp", t_ptr, 4)) dev->dev_type = DPAA2_BPOOL; else if (!strncmp("dpio", t_ptr, 4)) dev->dev_type = DPAA2_IO; else if (!strncmp("dpci", t_ptr, 4)) dev->dev_type = DPAA2_CI; else if (!strncmp("dpmcp", t_ptr, 5)) dev->dev_type = DPAA2_MPORTAL; else if (!strncmp("dpdmai", t_ptr, 6)) dev->dev_type = DPAA2_QDMA; else dev->dev_type = DPAA2_UNKNOWN; /* Update the device found into the device_count table */ rte_fslmc_bus.device_count[dev->dev_type]++; t_ptr = strtok(NULL, "."); if (!t_ptr) { DPAA2_BUS_ERR("Incorrect device string observed (%s)", t_ptr); goto cleanup; } sscanf(t_ptr, "%hu", &dev->object_id); dev->device.name = strdup(dev_name); if (!dev->device.name) { DPAA2_BUS_ERR("Unable to clone device name. Out of memory"); goto cleanup; } dev->device.devargs = fslmc_devargs_lookup(dev); /* Add device in the fslmc device list */ insert_in_device_list(dev); /* Don't need the duplicated device filesystem entry anymore */ if (dup_dev_name) free(dup_dev_name); return 0; cleanup: if (dup_dev_name) free(dup_dev_name); if (dev) free(dev); return -1; } static int rte_fslmc_parse(const char *name, void *addr) { uint16_t dev_id; char *t_ptr = NULL, *dname = NULL; /* 'name' is expected to contain name of device, for example, dpio.1, * dpni.2, etc. */ dname = strdup(name); if (!dname) return -EINVAL; t_ptr = dname; if (strncmp("dpni", t_ptr, 4) && strncmp("dpseci", t_ptr, 6) && strncmp("dpcon", t_ptr, 5) && strncmp("dpbp", t_ptr, 4) && strncmp("dpio", t_ptr, 4) && strncmp("dpci", t_ptr, 4) && strncmp("dpmcp", t_ptr, 5) && strncmp("dpdmai", t_ptr, 6)) { DPAA2_BUS_ERR("Unknown or unsupported device"); goto err_out; } t_ptr = strchr(name, '.'); if (!t_ptr) { DPAA2_BUS_ERR("Incorrect device string observed (%s)", t_ptr); goto err_out; } t_ptr = (char *)(t_ptr + 1); if (sscanf(t_ptr, "%hu", &dev_id) <= 0) { DPAA2_BUS_ERR("Incorrect device string observed (%s)", t_ptr); goto err_out; } free(dname); if (addr) strcpy(addr, name); return 0; err_out: free(dname); return -EINVAL; } static int rte_fslmc_scan(void) { int ret; int device_count = 0; char fslmc_dirpath[PATH_MAX]; DIR *dir; struct dirent *entry; static int process_once; int groupid; if (process_once) { DPAA2_BUS_DEBUG("Fslmc bus already scanned. Not rescanning"); return 0; } process_once = 1; ret = fslmc_get_container_group(&groupid); if (ret != 0) goto scan_fail; /* Scan devices on the group */ snprintf(fslmc_dirpath, sizeof(fslmc_dirpath), "%s/%d/devices", VFIO_IOMMU_GROUP_PATH, groupid); dir = opendir(fslmc_dirpath); if (!dir) { DPAA2_BUS_ERR("Unable to open VFIO group directory"); goto scan_fail; } while ((entry = readdir(dir)) != NULL) { if (entry->d_name[0] == '.' || entry->d_type != DT_LNK) continue; ret = scan_one_fslmc_device(entry->d_name); if (ret != 0) { /* Error in parsing directory - exit gracefully */ goto scan_fail_cleanup; } device_count += 1; } closedir(dir); DPAA2_BUS_INFO("FSLMC Bus scan completed"); /* If debugging is enabled, device list is dumped to log output */ dump_device_list(); return 0; scan_fail_cleanup: closedir(dir); /* Remove all devices in the list */ cleanup_fslmc_device_list(); scan_fail: DPAA2_BUS_DEBUG("FSLMC Bus Not Available. Skipping"); /* Irrespective of failure, scan only return success */ return 0; } static int rte_fslmc_match(struct rte_dpaa2_driver *dpaa2_drv, struct rte_dpaa2_device *dpaa2_dev) { if (dpaa2_drv->drv_type == dpaa2_dev->dev_type) return 0; return 1; } static int rte_fslmc_probe(void) { int ret = 0; int probe_all; struct rte_dpaa2_device *dev; struct rte_dpaa2_driver *drv; if (TAILQ_EMPTY(&rte_fslmc_bus.device_list)) return 0; ret = fslmc_vfio_setup_group(); if (ret) { DPAA2_BUS_ERR("Unable to setup VFIO %d", ret); return 0; } /* Map existing segments as well as, in case of hotpluggable memory, * install callback handler. */ ret = rte_fslmc_vfio_dmamap(); if (ret) { DPAA2_BUS_ERR("Unable to DMA map existing VAs: (%d)", ret); /* Not continuing ahead */ DPAA2_BUS_ERR("FSLMC VFIO Mapping failed"); return 0; } ret = fslmc_vfio_process_group(); if (ret) { DPAA2_BUS_ERR("Unable to setup devices %d", ret); return 0; } probe_all = rte_fslmc_bus.bus.conf.scan_mode != RTE_BUS_SCAN_WHITELIST; /* In case of PA, the FD addresses returned by qbman APIs are physical * addresses, which need conversion into equivalent VA address for * rte_mbuf. For that, a table (a serial array, in memory) is used to * increase translation efficiency. * This has to be done before probe as some device initialization * (during) probe allocate memory (dpaa2_sec) which needs to be pinned * to this table. * * Error is ignored as relevant logs are handled within dpaax and * handling for unavailable dpaax table too is transparent to caller. */ dpaax_iova_table_populate(); TAILQ_FOREACH(dev, &rte_fslmc_bus.device_list, next) { TAILQ_FOREACH(drv, &rte_fslmc_bus.driver_list, next) { ret = rte_fslmc_match(drv, dev); if (ret) continue; if (!drv->probe) continue; if (rte_dev_is_probed(&dev->device)) continue; if (dev->device.devargs && dev->device.devargs->policy == RTE_DEV_BLACKLISTED) { DPAA2_BUS_LOG(DEBUG, "%s Blacklisted, skipping", dev->device.name); continue; } if (probe_all || (dev->device.devargs && dev->device.devargs->policy == RTE_DEV_WHITELISTED)) { ret = drv->probe(drv, dev); if (ret) { DPAA2_BUS_ERR("Unable to probe"); } else { dev->driver = drv; dev->device.driver = &drv->driver; } } break; } } if (rte_eal_iova_mode() == RTE_IOVA_VA) dpaa2_virt_mode = 1; return 0; } static struct rte_device * rte_fslmc_find_device(const struct rte_device *start, rte_dev_cmp_t cmp, const void *data) { const struct rte_dpaa2_device *dstart; struct rte_dpaa2_device *dev; if (start != NULL) { dstart = RTE_DEV_TO_FSLMC_CONST(start); dev = TAILQ_NEXT(dstart, next); } else { dev = TAILQ_FIRST(&rte_fslmc_bus.device_list); } while (dev != NULL) { if (cmp(&dev->device, data) == 0) return &dev->device; dev = TAILQ_NEXT(dev, next); } return NULL; } /*register a fslmc bus based dpaa2 driver */ void rte_fslmc_driver_register(struct rte_dpaa2_driver *driver) { RTE_VERIFY(driver); TAILQ_INSERT_TAIL(&rte_fslmc_bus.driver_list, driver, next); /* Update Bus references */ driver->fslmc_bus = &rte_fslmc_bus; } /*un-register a fslmc bus based dpaa2 driver */ void rte_fslmc_driver_unregister(struct rte_dpaa2_driver *driver) { struct rte_fslmc_bus *fslmc_bus; fslmc_bus = driver->fslmc_bus; /* Cleanup the PA->VA Translation table; From whereever this function * is called from. */ dpaax_iova_table_depopulate(); TAILQ_REMOVE(&fslmc_bus->driver_list, driver, next); /* Update Bus references */ driver->fslmc_bus = NULL; } /* * All device has iova as va */ static inline int fslmc_all_device_support_iova(void) { int ret = 0; struct rte_dpaa2_device *dev; struct rte_dpaa2_driver *drv; TAILQ_FOREACH(dev, &rte_fslmc_bus.device_list, next) { TAILQ_FOREACH(drv, &rte_fslmc_bus.driver_list, next) { ret = rte_fslmc_match(drv, dev); if (ret) continue; /* if the driver is not supporting IOVA */ if (!(drv->drv_flags & RTE_DPAA2_DRV_IOVA_AS_VA)) return 0; } } return 1; } /* * Get iommu class of DPAA2 devices on the bus. */ static enum rte_iova_mode rte_dpaa2_get_iommu_class(void) { bool is_vfio_noiommu_enabled = 1; bool has_iova_va; if (TAILQ_EMPTY(&rte_fslmc_bus.device_list)) return RTE_IOVA_DC; #ifdef RTE_LIBRTE_DPAA2_USE_PHYS_IOVA return RTE_IOVA_PA; #endif /* check if all devices on the bus support Virtual addressing or not */ has_iova_va = fslmc_all_device_support_iova(); #ifdef VFIO_PRESENT is_vfio_noiommu_enabled = rte_vfio_noiommu_is_enabled() == true ? true : false; #endif if (has_iova_va && !is_vfio_noiommu_enabled) return RTE_IOVA_VA; return RTE_IOVA_PA; } struct rte_fslmc_bus rte_fslmc_bus = { .bus = { .scan = rte_fslmc_scan, .probe = rte_fslmc_probe, .parse = rte_fslmc_parse, .find_device = rte_fslmc_find_device, .get_iommu_class = rte_dpaa2_get_iommu_class, }, .device_list = TAILQ_HEAD_INITIALIZER(rte_fslmc_bus.device_list), .driver_list = TAILQ_HEAD_INITIALIZER(rte_fslmc_bus.driver_list), .device_count = {0}, }; RTE_REGISTER_BUS(FSLMC_BUS_NAME, rte_fslmc_bus.bus); RTE_INIT(fslmc_init_log) { /* Bus level logs */ dpaa2_logtype_bus = rte_log_register("bus.fslmc"); if (dpaa2_logtype_bus >= 0) rte_log_set_level(dpaa2_logtype_bus, RTE_LOG_NOTICE); }