Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Shay Drory | 2140 | 71.50% | 20 | 58.82% |
Leon Romanovsky | 457 | 15.27% | 4 | 11.76% |
Yuval Avnery | 314 | 10.49% | 2 | 5.88% |
Parav Pandit | 60 | 2.00% | 1 | 2.94% |
Tariq Toukan | 11 | 0.37% | 2 | 5.88% |
Ariel Levkovich | 3 | 0.10% | 1 | 2.94% |
caihuoqing | 2 | 0.07% | 1 | 2.94% |
Linus Torvalds | 2 | 0.07% | 1 | 2.94% |
Nitesh Narayan Lal | 2 | 0.07% | 1 | 2.94% |
Saeed Mahameed | 2 | 0.07% | 1 | 2.94% |
Total | 2993 | 34 |
// SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB /* Copyright (c) 2019 Mellanox Technologies. */ #include <linux/interrupt.h> #include <linux/notifier.h> #include <linux/mlx5/driver.h> #include "mlx5_core.h" #include "mlx5_irq.h" #include "pci_irq.h" #include "lib/sf.h" #ifdef CONFIG_RFS_ACCEL #include <linux/cpu_rmap.h> #endif #define MLX5_SFS_PER_CTRL_IRQ 64 #define MLX5_IRQ_CTRL_SF_MAX 8 /* min num of vectors for SFs to be enabled */ #define MLX5_IRQ_VEC_COMP_BASE_SF 2 #define MLX5_EQ_SHARE_IRQ_MAX_COMP (8) #define MLX5_EQ_SHARE_IRQ_MAX_CTRL (UINT_MAX) #define MLX5_EQ_SHARE_IRQ_MIN_COMP (1) #define MLX5_EQ_SHARE_IRQ_MIN_CTRL (4) struct mlx5_irq { struct atomic_notifier_head nh; cpumask_var_t mask; char name[MLX5_MAX_IRQ_NAME]; struct mlx5_irq_pool *pool; int refcount; u32 index; int irqn; }; struct mlx5_irq_table { struct mlx5_irq_pool *pf_pool; struct mlx5_irq_pool *sf_ctrl_pool; struct mlx5_irq_pool *sf_comp_pool; }; /** * mlx5_get_default_msix_vec_count - Get the default number of MSI-X vectors * to be ssigned to each VF. * @dev: PF to work on * @num_vfs: Number of enabled VFs */ int mlx5_get_default_msix_vec_count(struct mlx5_core_dev *dev, int num_vfs) { int num_vf_msix, min_msix, max_msix; num_vf_msix = MLX5_CAP_GEN_MAX(dev, num_total_dynamic_vf_msix); if (!num_vf_msix) return 0; min_msix = MLX5_CAP_GEN(dev, min_dynamic_vf_msix_table_size); max_msix = MLX5_CAP_GEN(dev, max_dynamic_vf_msix_table_size); /* Limit maximum number of MSI-X vectors so the default configuration * has some available in the pool. This will allow the user to increase * the number of vectors in a VF without having to first size-down other * VFs. */ return max(min(num_vf_msix / num_vfs, max_msix / 2), min_msix); } /** * mlx5_set_msix_vec_count - Set dynamically allocated MSI-X on the VF * @dev: PF to work on * @function_id: Internal PCI VF function IDd * @msix_vec_count: Number of MSI-X vectors to set */ int mlx5_set_msix_vec_count(struct mlx5_core_dev *dev, int function_id, int msix_vec_count) { int query_sz = MLX5_ST_SZ_BYTES(query_hca_cap_out); int set_sz = MLX5_ST_SZ_BYTES(set_hca_cap_in); void *hca_cap = NULL, *query_cap = NULL, *cap; int num_vf_msix, min_msix, max_msix; int ret; num_vf_msix = MLX5_CAP_GEN_MAX(dev, num_total_dynamic_vf_msix); if (!num_vf_msix) return 0; if (!MLX5_CAP_GEN(dev, vport_group_manager) || !mlx5_core_is_pf(dev)) return -EOPNOTSUPP; min_msix = MLX5_CAP_GEN(dev, min_dynamic_vf_msix_table_size); max_msix = MLX5_CAP_GEN(dev, max_dynamic_vf_msix_table_size); if (msix_vec_count < min_msix) return -EINVAL; if (msix_vec_count > max_msix) return -EOVERFLOW; query_cap = kvzalloc(query_sz, GFP_KERNEL); hca_cap = kvzalloc(set_sz, GFP_KERNEL); if (!hca_cap || !query_cap) { ret = -ENOMEM; goto out; } ret = mlx5_vport_get_other_func_cap(dev, function_id, query_cap); if (ret) goto out; cap = MLX5_ADDR_OF(set_hca_cap_in, hca_cap, capability); memcpy(cap, MLX5_ADDR_OF(query_hca_cap_out, query_cap, capability), MLX5_UN_SZ_BYTES(hca_cap_union)); MLX5_SET(cmd_hca_cap, cap, dynamic_msix_table_size, msix_vec_count); MLX5_SET(set_hca_cap_in, hca_cap, opcode, MLX5_CMD_OP_SET_HCA_CAP); MLX5_SET(set_hca_cap_in, hca_cap, other_function, 1); MLX5_SET(set_hca_cap_in, hca_cap, function_id, function_id); MLX5_SET(set_hca_cap_in, hca_cap, op_mod, MLX5_SET_HCA_CAP_OP_MOD_GENERAL_DEVICE << 1); ret = mlx5_cmd_exec_in(dev, set_hca_cap, hca_cap); out: kvfree(hca_cap); kvfree(query_cap); return ret; } static void irq_release(struct mlx5_irq *irq) { struct mlx5_irq_pool *pool = irq->pool; xa_erase(&pool->irqs, irq->index); /* free_irq requires that affinity_hint and rmap will be cleared * before calling it. This is why there is asymmetry with set_rmap * which should be called after alloc_irq but before request_irq. */ irq_update_affinity_hint(irq->irqn, NULL); free_cpumask_var(irq->mask); free_irq(irq->irqn, &irq->nh); kfree(irq); } int mlx5_irq_put(struct mlx5_irq *irq) { struct mlx5_irq_pool *pool = irq->pool; int ret = 0; mutex_lock(&pool->lock); irq->refcount--; if (!irq->refcount) { irq_release(irq); ret = 1; } mutex_unlock(&pool->lock); return ret; } int mlx5_irq_read_locked(struct mlx5_irq *irq) { lockdep_assert_held(&irq->pool->lock); return irq->refcount; } int mlx5_irq_get_locked(struct mlx5_irq *irq) { lockdep_assert_held(&irq->pool->lock); if (WARN_ON_ONCE(!irq->refcount)) return 0; irq->refcount++; return 1; } static int irq_get(struct mlx5_irq *irq) { int err; mutex_lock(&irq->pool->lock); err = mlx5_irq_get_locked(irq); mutex_unlock(&irq->pool->lock); return err; } static irqreturn_t irq_int_handler(int irq, void *nh) { atomic_notifier_call_chain(nh, 0, NULL); return IRQ_HANDLED; } static void irq_sf_set_name(struct mlx5_irq_pool *pool, char *name, int vecidx) { snprintf(name, MLX5_MAX_IRQ_NAME, "%s%d", pool->name, vecidx); } static void irq_set_name(struct mlx5_irq_pool *pool, char *name, int vecidx) { if (!pool->xa_num_irqs.max) { /* in case we only have a single irq for the device */ snprintf(name, MLX5_MAX_IRQ_NAME, "mlx5_combined%d", vecidx); return; } if (vecidx == pool->xa_num_irqs.max) { snprintf(name, MLX5_MAX_IRQ_NAME, "mlx5_async%d", vecidx); return; } snprintf(name, MLX5_MAX_IRQ_NAME, "mlx5_comp%d", vecidx); } struct mlx5_irq *mlx5_irq_alloc(struct mlx5_irq_pool *pool, int i, const struct cpumask *affinity) { struct mlx5_core_dev *dev = pool->dev; char name[MLX5_MAX_IRQ_NAME]; struct mlx5_irq *irq; int err; irq = kzalloc(sizeof(*irq), GFP_KERNEL); if (!irq) return ERR_PTR(-ENOMEM); irq->irqn = pci_irq_vector(dev->pdev, i); if (!mlx5_irq_pool_is_sf_pool(pool)) irq_set_name(pool, name, i); else irq_sf_set_name(pool, name, i); ATOMIC_INIT_NOTIFIER_HEAD(&irq->nh); snprintf(irq->name, MLX5_MAX_IRQ_NAME, "%s@pci:%s", name, pci_name(dev->pdev)); err = request_irq(irq->irqn, irq_int_handler, 0, irq->name, &irq->nh); if (err) { mlx5_core_err(dev, "Failed to request irq. err = %d\n", err); goto err_req_irq; } if (!zalloc_cpumask_var(&irq->mask, GFP_KERNEL)) { mlx5_core_warn(dev, "zalloc_cpumask_var failed\n"); err = -ENOMEM; goto err_cpumask; } if (affinity) { cpumask_copy(irq->mask, affinity); irq_set_affinity_and_hint(irq->irqn, irq->mask); } irq->pool = pool; irq->refcount = 1; irq->index = i; err = xa_err(xa_store(&pool->irqs, irq->index, irq, GFP_KERNEL)); if (err) { mlx5_core_err(dev, "Failed to alloc xa entry for irq(%u). err = %d\n", irq->index, err); goto err_xa; } return irq; err_xa: irq_update_affinity_hint(irq->irqn, NULL); free_cpumask_var(irq->mask); err_cpumask: free_irq(irq->irqn, &irq->nh); err_req_irq: kfree(irq); return ERR_PTR(err); } int mlx5_irq_attach_nb(struct mlx5_irq *irq, struct notifier_block *nb) { int ret; ret = irq_get(irq); if (!ret) /* Something very bad happens here, we are enabling EQ * on non-existing IRQ. */ return -ENOENT; ret = atomic_notifier_chain_register(&irq->nh, nb); if (ret) mlx5_irq_put(irq); return ret; } int mlx5_irq_detach_nb(struct mlx5_irq *irq, struct notifier_block *nb) { int err = 0; err = atomic_notifier_chain_unregister(&irq->nh, nb); mlx5_irq_put(irq); return err; } struct cpumask *mlx5_irq_get_affinity_mask(struct mlx5_irq *irq) { return irq->mask; } int mlx5_irq_get_index(struct mlx5_irq *irq) { return irq->index; } /* irq_pool API */ /* requesting an irq from a given pool according to given index */ static struct mlx5_irq * irq_pool_request_vector(struct mlx5_irq_pool *pool, int vecidx, struct cpumask *affinity) { struct mlx5_irq *irq; mutex_lock(&pool->lock); irq = xa_load(&pool->irqs, vecidx); if (irq) { mlx5_irq_get_locked(irq); goto unlock; } irq = mlx5_irq_alloc(pool, vecidx, affinity); unlock: mutex_unlock(&pool->lock); return irq; } static struct mlx5_irq_pool *sf_ctrl_irq_pool_get(struct mlx5_irq_table *irq_table) { return irq_table->sf_ctrl_pool; } static struct mlx5_irq_pool *sf_irq_pool_get(struct mlx5_irq_table *irq_table) { return irq_table->sf_comp_pool; } struct mlx5_irq_pool *mlx5_irq_pool_get(struct mlx5_core_dev *dev) { struct mlx5_irq_table *irq_table = mlx5_irq_table_get(dev); struct mlx5_irq_pool *pool = NULL; if (mlx5_core_is_sf(dev)) pool = sf_irq_pool_get(irq_table); /* In some configs, there won't be a pool of SFs IRQs. Hence, returning * the PF IRQs pool in case the SF pool doesn't exist. */ return pool ? pool : irq_table->pf_pool; } static struct mlx5_irq_pool *ctrl_irq_pool_get(struct mlx5_core_dev *dev) { struct mlx5_irq_table *irq_table = mlx5_irq_table_get(dev); struct mlx5_irq_pool *pool = NULL; if (mlx5_core_is_sf(dev)) pool = sf_ctrl_irq_pool_get(irq_table); /* In some configs, there won't be a pool of SFs IRQs. Hence, returning * the PF IRQs pool in case the SF pool doesn't exist. */ return pool ? pool : irq_table->pf_pool; } /** * mlx5_irqs_release - release one or more IRQs back to the system. * @irqs: IRQs to be released. * @nirqs: number of IRQs to be released. */ static void mlx5_irqs_release(struct mlx5_irq **irqs, int nirqs) { int i; for (i = 0; i < nirqs; i++) { synchronize_irq(irqs[i]->irqn); mlx5_irq_put(irqs[i]); } } /** * mlx5_ctrl_irq_release - release a ctrl IRQ back to the system. * @ctrl_irq: ctrl IRQ to be released. */ void mlx5_ctrl_irq_release(struct mlx5_irq *ctrl_irq) { mlx5_irqs_release(&ctrl_irq, 1); } /** * mlx5_ctrl_irq_request - request a ctrl IRQ for mlx5 device. * @dev: mlx5 device that requesting the IRQ. * * This function returns a pointer to IRQ, or ERR_PTR in case of error. */ struct mlx5_irq *mlx5_ctrl_irq_request(struct mlx5_core_dev *dev) { struct mlx5_irq_pool *pool = ctrl_irq_pool_get(dev); cpumask_var_t req_mask; struct mlx5_irq *irq; if (!zalloc_cpumask_var(&req_mask, GFP_KERNEL)) return ERR_PTR(-ENOMEM); cpumask_copy(req_mask, cpu_online_mask); if (!mlx5_irq_pool_is_sf_pool(pool)) { /* In case we are allocating a control IRQ for PF/VF */ if (!pool->xa_num_irqs.max) { cpumask_clear(req_mask); /* In case we only have a single IRQ for PF/VF */ cpumask_set_cpu(cpumask_first(cpu_online_mask), req_mask); } /* Allocate the IRQ in the last index of the pool */ irq = irq_pool_request_vector(pool, pool->xa_num_irqs.max, req_mask); } else { irq = mlx5_irq_affinity_request(pool, req_mask); } free_cpumask_var(req_mask); return irq; } /** * mlx5_irq_request - request an IRQ for mlx5 PF/VF device. * @dev: mlx5 device that requesting the IRQ. * @vecidx: vector index of the IRQ. This argument is ignore if affinity is * provided. * @affinity: cpumask requested for this IRQ. * * This function returns a pointer to IRQ, or ERR_PTR in case of error. */ struct mlx5_irq *mlx5_irq_request(struct mlx5_core_dev *dev, u16 vecidx, struct cpumask *affinity) { struct mlx5_irq_table *irq_table = mlx5_irq_table_get(dev); struct mlx5_irq_pool *pool; struct mlx5_irq *irq; pool = irq_table->pf_pool; irq = irq_pool_request_vector(pool, vecidx, affinity); if (IS_ERR(irq)) return irq; mlx5_core_dbg(dev, "irq %u mapped to cpu %*pbl, %u EQs on this irq\n", irq->irqn, cpumask_pr_args(affinity), irq->refcount / MLX5_EQ_REFS_PER_IRQ); return irq; } /** * mlx5_irqs_release_vectors - release one or more IRQs back to the system. * @irqs: IRQs to be released. * @nirqs: number of IRQs to be released. */ void mlx5_irqs_release_vectors(struct mlx5_irq **irqs, int nirqs) { mlx5_irqs_release(irqs, nirqs); } /** * mlx5_irqs_request_vectors - request one or more IRQs for mlx5 device. * @dev: mlx5 device that is requesting the IRQs. * @cpus: CPUs array for binding the IRQs * @nirqs: number of IRQs to request. * @irqs: an output array of IRQs pointers. * * Each IRQ is bound to at most 1 CPU. * This function is requests nirqs IRQs, starting from @vecidx. * * This function returns the number of IRQs requested, (which might be smaller than * @nirqs), if successful, or a negative error code in case of an error. */ int mlx5_irqs_request_vectors(struct mlx5_core_dev *dev, u16 *cpus, int nirqs, struct mlx5_irq **irqs) { cpumask_var_t req_mask; struct mlx5_irq *irq; int i; if (!zalloc_cpumask_var(&req_mask, GFP_KERNEL)) return -ENOMEM; for (i = 0; i < nirqs; i++) { cpumask_set_cpu(cpus[i], req_mask); irq = mlx5_irq_request(dev, i, req_mask); if (IS_ERR(irq)) break; cpumask_clear(req_mask); irqs[i] = irq; } free_cpumask_var(req_mask); return i ? i : PTR_ERR(irq); } static struct mlx5_irq_pool * irq_pool_alloc(struct mlx5_core_dev *dev, int start, int size, char *name, u32 min_threshold, u32 max_threshold) { struct mlx5_irq_pool *pool = kvzalloc(sizeof(*pool), GFP_KERNEL); if (!pool) return ERR_PTR(-ENOMEM); pool->dev = dev; mutex_init(&pool->lock); xa_init_flags(&pool->irqs, XA_FLAGS_ALLOC); pool->xa_num_irqs.min = start; pool->xa_num_irqs.max = start + size - 1; if (name) snprintf(pool->name, MLX5_MAX_IRQ_NAME - MLX5_MAX_IRQ_IDX_CHARS, "%s", name); pool->min_threshold = min_threshold * MLX5_EQ_REFS_PER_IRQ; pool->max_threshold = max_threshold * MLX5_EQ_REFS_PER_IRQ; mlx5_core_dbg(dev, "pool->name = %s, pool->size = %d, pool->start = %d", name, size, start); return pool; } static void irq_pool_free(struct mlx5_irq_pool *pool) { struct mlx5_irq *irq; unsigned long index; /* There are cases in which we are destrying the irq_table before * freeing all the IRQs, fast teardown for example. Hence, free the irqs * which might not have been freed. */ xa_for_each(&pool->irqs, index, irq) irq_release(irq); xa_destroy(&pool->irqs); mutex_destroy(&pool->lock); kfree(pool->irqs_per_cpu); kvfree(pool); } static int irq_pools_init(struct mlx5_core_dev *dev, int sf_vec, int pf_vec) { struct mlx5_irq_table *table = dev->priv.irq_table; int num_sf_ctrl_by_msix; int num_sf_ctrl_by_sfs; int num_sf_ctrl; int err; /* init pf_pool */ table->pf_pool = irq_pool_alloc(dev, 0, pf_vec, NULL, MLX5_EQ_SHARE_IRQ_MIN_COMP, MLX5_EQ_SHARE_IRQ_MAX_COMP); if (IS_ERR(table->pf_pool)) return PTR_ERR(table->pf_pool); if (!mlx5_sf_max_functions(dev)) return 0; if (sf_vec < MLX5_IRQ_VEC_COMP_BASE_SF) { mlx5_core_dbg(dev, "Not enught IRQs for SFs. SF may run at lower performance\n"); return 0; } /* init sf_ctrl_pool */ num_sf_ctrl_by_msix = DIV_ROUND_UP(sf_vec, MLX5_COMP_EQS_PER_SF); num_sf_ctrl_by_sfs = DIV_ROUND_UP(mlx5_sf_max_functions(dev), MLX5_SFS_PER_CTRL_IRQ); num_sf_ctrl = min_t(int, num_sf_ctrl_by_msix, num_sf_ctrl_by_sfs); num_sf_ctrl = min_t(int, MLX5_IRQ_CTRL_SF_MAX, num_sf_ctrl); table->sf_ctrl_pool = irq_pool_alloc(dev, pf_vec, num_sf_ctrl, "mlx5_sf_ctrl", MLX5_EQ_SHARE_IRQ_MIN_CTRL, MLX5_EQ_SHARE_IRQ_MAX_CTRL); if (IS_ERR(table->sf_ctrl_pool)) { err = PTR_ERR(table->sf_ctrl_pool); goto err_pf; } /* init sf_comp_pool */ table->sf_comp_pool = irq_pool_alloc(dev, pf_vec + num_sf_ctrl, sf_vec - num_sf_ctrl, "mlx5_sf_comp", MLX5_EQ_SHARE_IRQ_MIN_COMP, MLX5_EQ_SHARE_IRQ_MAX_COMP); if (IS_ERR(table->sf_comp_pool)) { err = PTR_ERR(table->sf_comp_pool); goto err_sf_ctrl; } table->sf_comp_pool->irqs_per_cpu = kcalloc(nr_cpu_ids, sizeof(u16), GFP_KERNEL); if (!table->sf_comp_pool->irqs_per_cpu) { err = -ENOMEM; goto err_irqs_per_cpu; } return 0; err_irqs_per_cpu: irq_pool_free(table->sf_comp_pool); err_sf_ctrl: irq_pool_free(table->sf_ctrl_pool); err_pf: irq_pool_free(table->pf_pool); return err; } static void irq_pools_destroy(struct mlx5_irq_table *table) { if (table->sf_ctrl_pool) { irq_pool_free(table->sf_comp_pool); irq_pool_free(table->sf_ctrl_pool); } irq_pool_free(table->pf_pool); } /* irq_table API */ int mlx5_irq_table_init(struct mlx5_core_dev *dev) { struct mlx5_irq_table *irq_table; if (mlx5_core_is_sf(dev)) return 0; irq_table = kvzalloc_node(sizeof(*irq_table), GFP_KERNEL, dev->priv.numa_node); if (!irq_table) return -ENOMEM; dev->priv.irq_table = irq_table; return 0; } void mlx5_irq_table_cleanup(struct mlx5_core_dev *dev) { if (mlx5_core_is_sf(dev)) return; kvfree(dev->priv.irq_table); } int mlx5_irq_table_get_num_comp(struct mlx5_irq_table *table) { if (!table->pf_pool->xa_num_irqs.max) return 1; return table->pf_pool->xa_num_irqs.max - table->pf_pool->xa_num_irqs.min; } int mlx5_irq_table_create(struct mlx5_core_dev *dev) { int num_eqs = MLX5_CAP_GEN(dev, max_num_eqs) ? MLX5_CAP_GEN(dev, max_num_eqs) : 1 << MLX5_CAP_GEN(dev, log_max_eq); int total_vec; int pf_vec; int err; if (mlx5_core_is_sf(dev)) return 0; pf_vec = MLX5_CAP_GEN(dev, num_ports) * num_online_cpus() + 1; pf_vec = min_t(int, pf_vec, num_eqs); total_vec = pf_vec; if (mlx5_sf_max_functions(dev)) total_vec += MLX5_IRQ_CTRL_SF_MAX + MLX5_COMP_EQS_PER_SF * mlx5_sf_max_functions(dev); total_vec = pci_alloc_irq_vectors(dev->pdev, 1, total_vec, PCI_IRQ_MSIX); if (total_vec < 0) return total_vec; pf_vec = min(pf_vec, total_vec); err = irq_pools_init(dev, total_vec - pf_vec, pf_vec); if (err) pci_free_irq_vectors(dev->pdev); return err; } void mlx5_irq_table_destroy(struct mlx5_core_dev *dev) { struct mlx5_irq_table *table = dev->priv.irq_table; if (mlx5_core_is_sf(dev)) return; /* There are cases where IRQs still will be in used when we reaching * to here. Hence, making sure all the irqs are released. */ irq_pools_destroy(table); pci_free_irq_vectors(dev->pdev); } int mlx5_irq_table_get_sfs_vec(struct mlx5_irq_table *table) { if (table->sf_comp_pool) return min_t(int, num_online_cpus(), table->sf_comp_pool->xa_num_irqs.max - table->sf_comp_pool->xa_num_irqs.min + 1); else return mlx5_irq_table_get_num_comp(table); } struct mlx5_irq_table *mlx5_irq_table_get(struct mlx5_core_dev *dev) { #ifdef CONFIG_MLX5_SF if (mlx5_core_is_sf(dev)) return dev->priv.parent_mdev->priv.irq_table; #endif return dev->priv.irq_table; }
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