Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Zhu Lingshan | 2022 | 99.75% | 15 | 83.33% |
Angus Chen | 2 | 0.10% | 1 | 5.56% |
Eli Cohen | 2 | 0.10% | 1 | 5.56% |
Stefano Garzarella | 1 | 0.05% | 1 | 5.56% |
Total | 2027 | 18 |
// SPDX-License-Identifier: GPL-2.0-only /* * Intel IFC VF NIC driver for virtio dataplane offloading * * Copyright (C) 2020 Intel Corporation. * * Author: Zhu Lingshan <lingshan.zhu@intel.com> * */ #include "ifcvf_base.h" struct ifcvf_adapter *vf_to_adapter(struct ifcvf_hw *hw) { return container_of(hw, struct ifcvf_adapter, vf); } u16 ifcvf_set_vq_vector(struct ifcvf_hw *hw, u16 qid, int vector) { struct virtio_pci_common_cfg __iomem *cfg = hw->common_cfg; vp_iowrite16(qid, &cfg->queue_select); vp_iowrite16(vector, &cfg->queue_msix_vector); return vp_ioread16(&cfg->queue_msix_vector); } u16 ifcvf_set_config_vector(struct ifcvf_hw *hw, int vector) { struct virtio_pci_common_cfg __iomem *cfg = hw->common_cfg; vp_iowrite16(vector, &cfg->msix_config); return vp_ioread16(&cfg->msix_config); } static void __iomem *get_cap_addr(struct ifcvf_hw *hw, struct virtio_pci_cap *cap) { struct ifcvf_adapter *ifcvf; struct pci_dev *pdev; u32 length, offset; u8 bar; length = le32_to_cpu(cap->length); offset = le32_to_cpu(cap->offset); bar = cap->bar; ifcvf= vf_to_adapter(hw); pdev = ifcvf->pdev; if (bar >= IFCVF_PCI_MAX_RESOURCE) { IFCVF_DBG(pdev, "Invalid bar number %u to get capabilities\n", bar); return NULL; } if (offset + length > pci_resource_len(pdev, bar)) { IFCVF_DBG(pdev, "offset(%u) + len(%u) overflows bar%u's capability\n", offset, length, bar); return NULL; } return hw->base[bar] + offset; } static int ifcvf_read_config_range(struct pci_dev *dev, uint32_t *val, int size, int where) { int ret, i; for (i = 0; i < size; i += 4) { ret = pci_read_config_dword(dev, where + i, val + i / 4); if (ret < 0) return ret; } return 0; } int ifcvf_init_hw(struct ifcvf_hw *hw, struct pci_dev *pdev) { struct virtio_pci_cap cap; u16 notify_off; int ret; u8 pos; u32 i; ret = pci_read_config_byte(pdev, PCI_CAPABILITY_LIST, &pos); if (ret < 0) { IFCVF_ERR(pdev, "Failed to read PCI capability list\n"); return -EIO; } while (pos) { ret = ifcvf_read_config_range(pdev, (u32 *)&cap, sizeof(cap), pos); if (ret < 0) { IFCVF_ERR(pdev, "Failed to get PCI capability at %x\n", pos); break; } if (cap.cap_vndr != PCI_CAP_ID_VNDR) goto next; switch (cap.cfg_type) { case VIRTIO_PCI_CAP_COMMON_CFG: hw->common_cfg = get_cap_addr(hw, &cap); IFCVF_DBG(pdev, "hw->common_cfg = %p\n", hw->common_cfg); break; case VIRTIO_PCI_CAP_NOTIFY_CFG: pci_read_config_dword(pdev, pos + sizeof(cap), &hw->notify_off_multiplier); hw->notify_bar = cap.bar; hw->notify_base = get_cap_addr(hw, &cap); hw->notify_base_pa = pci_resource_start(pdev, cap.bar) + le32_to_cpu(cap.offset); IFCVF_DBG(pdev, "hw->notify_base = %p\n", hw->notify_base); break; case VIRTIO_PCI_CAP_ISR_CFG: hw->isr = get_cap_addr(hw, &cap); IFCVF_DBG(pdev, "hw->isr = %p\n", hw->isr); break; case VIRTIO_PCI_CAP_DEVICE_CFG: hw->dev_cfg = get_cap_addr(hw, &cap); hw->cap_dev_config_size = le32_to_cpu(cap.length); IFCVF_DBG(pdev, "hw->dev_cfg = %p\n", hw->dev_cfg); break; } next: pos = cap.cap_next; } if (hw->common_cfg == NULL || hw->notify_base == NULL || hw->isr == NULL || hw->dev_cfg == NULL) { IFCVF_ERR(pdev, "Incomplete PCI capabilities\n"); return -EIO; } hw->nr_vring = vp_ioread16(&hw->common_cfg->num_queues); for (i = 0; i < hw->nr_vring; i++) { vp_iowrite16(i, &hw->common_cfg->queue_select); notify_off = vp_ioread16(&hw->common_cfg->queue_notify_off); hw->vring[i].notify_addr = hw->notify_base + notify_off * hw->notify_off_multiplier; hw->vring[i].notify_pa = hw->notify_base_pa + notify_off * hw->notify_off_multiplier; hw->vring[i].irq = -EINVAL; } hw->lm_cfg = hw->base[IFCVF_LM_BAR]; IFCVF_DBG(pdev, "PCI capability mapping: common cfg: %p, notify base: %p\n, isr cfg: %p, device cfg: %p, multiplier: %u\n", hw->common_cfg, hw->notify_base, hw->isr, hw->dev_cfg, hw->notify_off_multiplier); hw->vqs_reused_irq = -EINVAL; hw->config_irq = -EINVAL; return 0; } u8 ifcvf_get_status(struct ifcvf_hw *hw) { return vp_ioread8(&hw->common_cfg->device_status); } void ifcvf_set_status(struct ifcvf_hw *hw, u8 status) { vp_iowrite8(status, &hw->common_cfg->device_status); } void ifcvf_reset(struct ifcvf_hw *hw) { hw->config_cb.callback = NULL; hw->config_cb.private = NULL; ifcvf_set_status(hw, 0); /* flush set_status, make sure VF is stopped, reset */ ifcvf_get_status(hw); } static void ifcvf_add_status(struct ifcvf_hw *hw, u8 status) { if (status != 0) status |= ifcvf_get_status(hw); ifcvf_set_status(hw, status); ifcvf_get_status(hw); } u64 ifcvf_get_hw_features(struct ifcvf_hw *hw) { struct virtio_pci_common_cfg __iomem *cfg = hw->common_cfg; u32 features_lo, features_hi; u64 features; vp_iowrite32(0, &cfg->device_feature_select); features_lo = vp_ioread32(&cfg->device_feature); vp_iowrite32(1, &cfg->device_feature_select); features_hi = vp_ioread32(&cfg->device_feature); features = ((u64)features_hi << 32) | features_lo; return features; } u64 ifcvf_get_features(struct ifcvf_hw *hw) { return hw->hw_features; } int ifcvf_verify_min_features(struct ifcvf_hw *hw, u64 features) { struct ifcvf_adapter *ifcvf = vf_to_adapter(hw); if (!(features & BIT_ULL(VIRTIO_F_ACCESS_PLATFORM)) && features) { IFCVF_ERR(ifcvf->pdev, "VIRTIO_F_ACCESS_PLATFORM is not negotiated\n"); return -EINVAL; } return 0; } u32 ifcvf_get_config_size(struct ifcvf_hw *hw) { struct ifcvf_adapter *adapter; u32 net_config_size = sizeof(struct virtio_net_config); u32 blk_config_size = sizeof(struct virtio_blk_config); u32 cap_size = hw->cap_dev_config_size; u32 config_size; adapter = vf_to_adapter(hw); /* If the onboard device config space size is greater than * the size of struct virtio_net/blk_config, only the spec * implementing contents size is returned, this is very * unlikely, defensive programming. */ switch (hw->dev_type) { case VIRTIO_ID_NET: config_size = min(cap_size, net_config_size); break; case VIRTIO_ID_BLOCK: config_size = min(cap_size, blk_config_size); break; default: config_size = 0; IFCVF_ERR(adapter->pdev, "VIRTIO ID %u not supported\n", hw->dev_type); } return config_size; } void ifcvf_read_dev_config(struct ifcvf_hw *hw, u64 offset, void *dst, int length) { u8 old_gen, new_gen, *p; int i; WARN_ON(offset + length > hw->config_size); do { old_gen = vp_ioread8(&hw->common_cfg->config_generation); p = dst; for (i = 0; i < length; i++) *p++ = vp_ioread8(hw->dev_cfg + offset + i); new_gen = vp_ioread8(&hw->common_cfg->config_generation); } while (old_gen != new_gen); } void ifcvf_write_dev_config(struct ifcvf_hw *hw, u64 offset, const void *src, int length) { const u8 *p; int i; p = src; WARN_ON(offset + length > hw->config_size); for (i = 0; i < length; i++) vp_iowrite8(*p++, hw->dev_cfg + offset + i); } static void ifcvf_set_features(struct ifcvf_hw *hw, u64 features) { struct virtio_pci_common_cfg __iomem *cfg = hw->common_cfg; vp_iowrite32(0, &cfg->guest_feature_select); vp_iowrite32((u32)features, &cfg->guest_feature); vp_iowrite32(1, &cfg->guest_feature_select); vp_iowrite32(features >> 32, &cfg->guest_feature); } static int ifcvf_config_features(struct ifcvf_hw *hw) { struct ifcvf_adapter *ifcvf; ifcvf = vf_to_adapter(hw); ifcvf_set_features(hw, hw->req_features); ifcvf_add_status(hw, VIRTIO_CONFIG_S_FEATURES_OK); if (!(ifcvf_get_status(hw) & VIRTIO_CONFIG_S_FEATURES_OK)) { IFCVF_ERR(ifcvf->pdev, "Failed to set FEATURES_OK status\n"); return -EIO; } return 0; } u16 ifcvf_get_vq_state(struct ifcvf_hw *hw, u16 qid) { struct ifcvf_lm_cfg __iomem *ifcvf_lm; void __iomem *avail_idx_addr; u16 last_avail_idx; u32 q_pair_id; ifcvf_lm = (struct ifcvf_lm_cfg __iomem *)hw->lm_cfg; q_pair_id = qid / 2; avail_idx_addr = &ifcvf_lm->vring_lm_cfg[q_pair_id].idx_addr[qid % 2]; last_avail_idx = vp_ioread16(avail_idx_addr); return last_avail_idx; } int ifcvf_set_vq_state(struct ifcvf_hw *hw, u16 qid, u16 num) { struct ifcvf_lm_cfg __iomem *ifcvf_lm; void __iomem *avail_idx_addr; u32 q_pair_id; ifcvf_lm = (struct ifcvf_lm_cfg __iomem *)hw->lm_cfg; q_pair_id = qid / 2; avail_idx_addr = &ifcvf_lm->vring_lm_cfg[q_pair_id].idx_addr[qid % 2]; hw->vring[qid].last_avail_idx = num; vp_iowrite16(num, avail_idx_addr); return 0; } static int ifcvf_hw_enable(struct ifcvf_hw *hw) { struct virtio_pci_common_cfg __iomem *cfg; u32 i; cfg = hw->common_cfg; for (i = 0; i < hw->nr_vring; i++) { if (!hw->vring[i].ready) break; vp_iowrite16(i, &cfg->queue_select); vp_iowrite64_twopart(hw->vring[i].desc, &cfg->queue_desc_lo, &cfg->queue_desc_hi); vp_iowrite64_twopart(hw->vring[i].avail, &cfg->queue_avail_lo, &cfg->queue_avail_hi); vp_iowrite64_twopart(hw->vring[i].used, &cfg->queue_used_lo, &cfg->queue_used_hi); vp_iowrite16(hw->vring[i].size, &cfg->queue_size); ifcvf_set_vq_state(hw, i, hw->vring[i].last_avail_idx); vp_iowrite16(1, &cfg->queue_enable); } return 0; } static void ifcvf_hw_disable(struct ifcvf_hw *hw) { u32 i; ifcvf_set_config_vector(hw, VIRTIO_MSI_NO_VECTOR); for (i = 0; i < hw->nr_vring; i++) { ifcvf_set_vq_vector(hw, i, VIRTIO_MSI_NO_VECTOR); } } int ifcvf_start_hw(struct ifcvf_hw *hw) { ifcvf_reset(hw); ifcvf_add_status(hw, VIRTIO_CONFIG_S_ACKNOWLEDGE); ifcvf_add_status(hw, VIRTIO_CONFIG_S_DRIVER); if (ifcvf_config_features(hw) < 0) return -EINVAL; if (ifcvf_hw_enable(hw) < 0) return -EINVAL; ifcvf_add_status(hw, VIRTIO_CONFIG_S_DRIVER_OK); return 0; } void ifcvf_stop_hw(struct ifcvf_hw *hw) { ifcvf_hw_disable(hw); ifcvf_reset(hw); } void ifcvf_notify_queue(struct ifcvf_hw *hw, u16 qid) { vp_iowrite16(qid, hw->vring[qid].notify_addr); }
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