Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Aviad Krawczyk | 1213 | 72.20% | 4 | 33.33% |
Luo bin | 345 | 20.54% | 4 | 33.33% |
Xue Chaojing | 118 | 7.02% | 1 | 8.33% |
Thomas Gleixner | 2 | 0.12% | 1 | 8.33% |
Guangbin Huang | 1 | 0.06% | 1 | 8.33% |
Yang Shen | 1 | 0.06% | 1 | 8.33% |
Total | 1680 | 12 |
// SPDX-License-Identifier: GPL-2.0-only /* * Huawei HiNIC PCI Express Linux driver * Copyright(c) 2017 Huawei Technologies Co., Ltd */ #include <linux/pci.h> #include <linux/device.h> #include <linux/errno.h> #include <linux/io.h> #include <linux/types.h> #include <linux/bitops.h> #include <linux/delay.h> #include "hinic_hw_csr.h" #include "hinic_hw_if.h" #define PCIE_ATTR_ENTRY 0 #define VALID_MSIX_IDX(attr, msix_index) ((msix_index) < (attr)->num_irqs) #define WAIT_HWIF_READY_TIMEOUT 10000 #define HINIC_SELFTEST_RESULT 0x883C /** * hinic_msix_attr_set - set message attribute for msix entry * @hwif: the HW interface of a pci function device * @msix_index: msix_index * @pending_limit: the maximum pending interrupt events (unit 8) * @coalesc_timer: coalesc period for interrupt (unit 8 us) * @lli_timer: replenishing period for low latency credit (unit 8 us) * @lli_credit_limit: maximum credits for low latency msix messages (unit 8) * @resend_timer: maximum wait for resending msix (unit coalesc period) * * Return 0 - Success, negative - Failure **/ int hinic_msix_attr_set(struct hinic_hwif *hwif, u16 msix_index, u8 pending_limit, u8 coalesc_timer, u8 lli_timer, u8 lli_credit_limit, u8 resend_timer) { u32 msix_ctrl, addr; if (!VALID_MSIX_IDX(&hwif->attr, msix_index)) return -EINVAL; msix_ctrl = HINIC_MSIX_ATTR_SET(pending_limit, PENDING_LIMIT) | HINIC_MSIX_ATTR_SET(coalesc_timer, COALESC_TIMER) | HINIC_MSIX_ATTR_SET(lli_timer, LLI_TIMER) | HINIC_MSIX_ATTR_SET(lli_credit_limit, LLI_CREDIT) | HINIC_MSIX_ATTR_SET(resend_timer, RESEND_TIMER); addr = HINIC_CSR_MSIX_CTRL_ADDR(msix_index); hinic_hwif_write_reg(hwif, addr, msix_ctrl); return 0; } /** * hinic_msix_attr_get - get message attribute of msix entry * @hwif: the HW interface of a pci function device * @msix_index: msix_index * @pending_limit: the maximum pending interrupt events (unit 8) * @coalesc_timer: coalesc period for interrupt (unit 8 us) * @lli_timer: replenishing period for low latency credit (unit 8 us) * @lli_credit_limit: maximum credits for low latency msix messages (unit 8) * @resend_timer: maximum wait for resending msix (unit coalesc period) * * Return 0 - Success, negative - Failure **/ int hinic_msix_attr_get(struct hinic_hwif *hwif, u16 msix_index, u8 *pending_limit, u8 *coalesc_timer, u8 *lli_timer, u8 *lli_credit_limit, u8 *resend_timer) { u32 addr, val; if (!VALID_MSIX_IDX(&hwif->attr, msix_index)) return -EINVAL; addr = HINIC_CSR_MSIX_CTRL_ADDR(msix_index); val = hinic_hwif_read_reg(hwif, addr); *pending_limit = HINIC_MSIX_ATTR_GET(val, PENDING_LIMIT); *coalesc_timer = HINIC_MSIX_ATTR_GET(val, COALESC_TIMER); *lli_timer = HINIC_MSIX_ATTR_GET(val, LLI_TIMER); *lli_credit_limit = HINIC_MSIX_ATTR_GET(val, LLI_CREDIT); *resend_timer = HINIC_MSIX_ATTR_GET(val, RESEND_TIMER); return 0; } /** * hinic_msix_attr_cnt_clear - clear message attribute counters for msix entry * @hwif: the HW interface of a pci function device * @msix_index: msix_index * * Return 0 - Success, negative - Failure **/ int hinic_msix_attr_cnt_clear(struct hinic_hwif *hwif, u16 msix_index) { u32 msix_ctrl, addr; if (!VALID_MSIX_IDX(&hwif->attr, msix_index)) return -EINVAL; msix_ctrl = HINIC_MSIX_CNT_SET(1, RESEND_TIMER); addr = HINIC_CSR_MSIX_CNT_ADDR(msix_index); hinic_hwif_write_reg(hwif, addr, msix_ctrl); return 0; } /** * hinic_set_pf_action - set action on pf channel * @hwif: the HW interface of a pci function device * @action: action on pf channel * * Return 0 - Success, negative - Failure **/ void hinic_set_pf_action(struct hinic_hwif *hwif, enum hinic_pf_action action) { u32 attr5; if (HINIC_IS_VF(hwif)) return; attr5 = hinic_hwif_read_reg(hwif, HINIC_CSR_FUNC_ATTR5_ADDR); attr5 = HINIC_FA5_CLEAR(attr5, PF_ACTION); attr5 |= HINIC_FA5_SET(action, PF_ACTION); hinic_hwif_write_reg(hwif, HINIC_CSR_FUNC_ATTR5_ADDR, attr5); } enum hinic_outbound_state hinic_outbound_state_get(struct hinic_hwif *hwif) { u32 attr4 = hinic_hwif_read_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR); return HINIC_FA4_GET(attr4, OUTBOUND_STATE); } void hinic_outbound_state_set(struct hinic_hwif *hwif, enum hinic_outbound_state outbound_state) { u32 attr4 = hinic_hwif_read_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR); attr4 = HINIC_FA4_CLEAR(attr4, OUTBOUND_STATE); attr4 |= HINIC_FA4_SET(outbound_state, OUTBOUND_STATE); hinic_hwif_write_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR, attr4); } enum hinic_db_state hinic_db_state_get(struct hinic_hwif *hwif) { u32 attr4 = hinic_hwif_read_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR); return HINIC_FA4_GET(attr4, DB_STATE); } void hinic_db_state_set(struct hinic_hwif *hwif, enum hinic_db_state db_state) { u32 attr4 = hinic_hwif_read_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR); attr4 = HINIC_FA4_CLEAR(attr4, DB_STATE); attr4 |= HINIC_FA4_SET(db_state, DB_STATE); hinic_hwif_write_reg(hwif, HINIC_CSR_FUNC_ATTR4_ADDR, attr4); } void hinic_set_msix_state(struct hinic_hwif *hwif, u16 msix_idx, enum hinic_msix_state flag) { u32 offset = msix_idx * HINIC_PCI_MSIX_ENTRY_SIZE + HINIC_PCI_MSIX_ENTRY_VECTOR_CTRL; u32 mask_bits; mask_bits = readl(hwif->intr_regs_base + offset); mask_bits &= ~HINIC_PCI_MSIX_ENTRY_CTRL_MASKBIT; if (flag) mask_bits |= HINIC_PCI_MSIX_ENTRY_CTRL_MASKBIT; writel(mask_bits, hwif->intr_regs_base + offset); } /** * hwif_ready - test if the HW is ready for use * @hwif: the HW interface of a pci function device * * Return 0 - Success, negative - Failure **/ static int hwif_ready(struct hinic_hwif *hwif) { u32 addr, attr1; addr = HINIC_CSR_FUNC_ATTR1_ADDR; attr1 = hinic_hwif_read_reg(hwif, addr); if (!HINIC_FA1_GET(attr1, MGMT_INIT_STATUS)) return -EBUSY; if (HINIC_IS_VF(hwif)) { if (!HINIC_FA1_GET(attr1, PF_INIT_STATUS)) return -EBUSY; } return 0; } static int wait_hwif_ready(struct hinic_hwif *hwif) { unsigned long timeout = 0; do { if (!hwif_ready(hwif)) return 0; usleep_range(999, 1000); timeout++; } while (timeout <= WAIT_HWIF_READY_TIMEOUT); dev_err(&hwif->pdev->dev, "Wait for hwif timeout\n"); return -EBUSY; } /** * set_hwif_attr - set the attributes in the relevant members in hwif * @hwif: the HW interface of a pci function device * @attr0: the first attribute that was read from the hw * @attr1: the second attribute that was read from the hw * @attr2: the third attribute that was read from the hw **/ static void set_hwif_attr(struct hinic_hwif *hwif, u32 attr0, u32 attr1, u32 attr2) { hwif->attr.func_idx = HINIC_FA0_GET(attr0, FUNC_IDX); hwif->attr.pf_idx = HINIC_FA0_GET(attr0, PF_IDX); hwif->attr.pci_intf_idx = HINIC_FA0_GET(attr0, PCI_INTF_IDX); hwif->attr.func_type = HINIC_FA0_GET(attr0, FUNC_TYPE); hwif->attr.num_aeqs = BIT(HINIC_FA1_GET(attr1, AEQS_PER_FUNC)); hwif->attr.num_ceqs = BIT(HINIC_FA1_GET(attr1, CEQS_PER_FUNC)); hwif->attr.num_irqs = BIT(HINIC_FA1_GET(attr1, IRQS_PER_FUNC)); hwif->attr.num_dma_attr = BIT(HINIC_FA1_GET(attr1, DMA_ATTR_PER_FUNC)); hwif->attr.global_vf_id_of_pf = HINIC_FA2_GET(attr2, GLOBAL_VF_ID_OF_PF); } /** * read_hwif_attr - read the attributes and set members in hwif * @hwif: the HW interface of a pci function device **/ static void read_hwif_attr(struct hinic_hwif *hwif) { u32 addr, attr0, attr1, attr2; addr = HINIC_CSR_FUNC_ATTR0_ADDR; attr0 = hinic_hwif_read_reg(hwif, addr); addr = HINIC_CSR_FUNC_ATTR1_ADDR; attr1 = hinic_hwif_read_reg(hwif, addr); addr = HINIC_CSR_FUNC_ATTR2_ADDR; attr2 = hinic_hwif_read_reg(hwif, addr); set_hwif_attr(hwif, attr0, attr1, attr2); } /** * set_ppf - try to set hwif as ppf and set the type of hwif in this case * @hwif: the HW interface of a pci function device **/ static void set_ppf(struct hinic_hwif *hwif) { struct hinic_func_attr *attr = &hwif->attr; u32 addr, val, ppf_election; /* Read Modify Write */ addr = HINIC_CSR_PPF_ELECTION_ADDR(HINIC_HWIF_PCI_INTF(hwif)); val = hinic_hwif_read_reg(hwif, addr); val = HINIC_PPF_ELECTION_CLEAR(val, IDX); ppf_election = HINIC_PPF_ELECTION_SET(HINIC_HWIF_FUNC_IDX(hwif), IDX); val |= ppf_election; hinic_hwif_write_reg(hwif, addr, val); /* check PPF */ val = hinic_hwif_read_reg(hwif, addr); attr->ppf_idx = HINIC_PPF_ELECTION_GET(val, IDX); if (attr->ppf_idx == HINIC_HWIF_FUNC_IDX(hwif)) attr->func_type = HINIC_PPF; } /** * set_dma_attr - set the dma attributes in the HW * @hwif: the HW interface of a pci function device * @entry_idx: the entry index in the dma table * @st: PCIE TLP steering tag * @at: PCIE TLP AT field * @ph: PCIE TLP Processing Hint field * @no_snooping: PCIE TLP No snooping * @tph_en: PCIE TLP Processing Hint Enable **/ static void set_dma_attr(struct hinic_hwif *hwif, u32 entry_idx, u8 st, u8 at, u8 ph, enum hinic_pcie_nosnoop no_snooping, enum hinic_pcie_tph tph_en) { u32 addr, val, dma_attr_entry; /* Read Modify Write */ addr = HINIC_CSR_DMA_ATTR_ADDR(entry_idx); val = hinic_hwif_read_reg(hwif, addr); val = HINIC_DMA_ATTR_CLEAR(val, ST) & HINIC_DMA_ATTR_CLEAR(val, AT) & HINIC_DMA_ATTR_CLEAR(val, PH) & HINIC_DMA_ATTR_CLEAR(val, NO_SNOOPING) & HINIC_DMA_ATTR_CLEAR(val, TPH_EN); dma_attr_entry = HINIC_DMA_ATTR_SET(st, ST) | HINIC_DMA_ATTR_SET(at, AT) | HINIC_DMA_ATTR_SET(ph, PH) | HINIC_DMA_ATTR_SET(no_snooping, NO_SNOOPING) | HINIC_DMA_ATTR_SET(tph_en, TPH_EN); val |= dma_attr_entry; hinic_hwif_write_reg(hwif, addr, val); } /** * dma_attr_init - initialize the default dma attributes * @hwif: the HW interface of a pci function device **/ static void dma_attr_init(struct hinic_hwif *hwif) { set_dma_attr(hwif, PCIE_ATTR_ENTRY, HINIC_PCIE_ST_DISABLE, HINIC_PCIE_AT_DISABLE, HINIC_PCIE_PH_DISABLE, HINIC_PCIE_SNOOP, HINIC_PCIE_TPH_DISABLE); } u16 hinic_glb_pf_vf_offset(struct hinic_hwif *hwif) { if (!hwif) return 0; return hwif->attr.global_vf_id_of_pf; } u16 hinic_global_func_id_hw(struct hinic_hwif *hwif) { u32 addr, attr0; addr = HINIC_CSR_FUNC_ATTR0_ADDR; attr0 = hinic_hwif_read_reg(hwif, addr); return HINIC_FA0_GET(attr0, FUNC_IDX); } u16 hinic_pf_id_of_vf_hw(struct hinic_hwif *hwif) { u32 addr, attr0; addr = HINIC_CSR_FUNC_ATTR0_ADDR; attr0 = hinic_hwif_read_reg(hwif, addr); return HINIC_FA0_GET(attr0, PF_IDX); } static void __print_selftest_reg(struct hinic_hwif *hwif) { u32 addr, attr0, attr1; addr = HINIC_CSR_FUNC_ATTR1_ADDR; attr1 = hinic_hwif_read_reg(hwif, addr); if (attr1 == HINIC_PCIE_LINK_DOWN) { dev_err(&hwif->pdev->dev, "PCIE is link down\n"); return; } addr = HINIC_CSR_FUNC_ATTR0_ADDR; attr0 = hinic_hwif_read_reg(hwif, addr); if (HINIC_FA0_GET(attr0, FUNC_TYPE) != HINIC_VF && !HINIC_FA0_GET(attr0, PCI_INTF_IDX)) dev_err(&hwif->pdev->dev, "Selftest reg: 0x%08x\n", hinic_hwif_read_reg(hwif, HINIC_SELFTEST_RESULT)); } /** * hinic_init_hwif - initialize the hw interface * @hwif: the HW interface of a pci function device * @pdev: the pci device for accessing PCI resources * * Return 0 - Success, negative - Failure **/ int hinic_init_hwif(struct hinic_hwif *hwif, struct pci_dev *pdev) { int err; hwif->pdev = pdev; hwif->cfg_regs_bar = pci_ioremap_bar(pdev, HINIC_PCI_CFG_REGS_BAR); if (!hwif->cfg_regs_bar) { dev_err(&pdev->dev, "Failed to map configuration regs\n"); return -ENOMEM; } hwif->intr_regs_base = pci_ioremap_bar(pdev, HINIC_PCI_INTR_REGS_BAR); if (!hwif->intr_regs_base) { dev_err(&pdev->dev, "Failed to map configuration regs\n"); err = -ENOMEM; goto err_map_intr_bar; } err = wait_hwif_ready(hwif); if (err) { dev_err(&pdev->dev, "HW interface is not ready\n"); __print_selftest_reg(hwif); goto err_hwif_ready; } read_hwif_attr(hwif); if (HINIC_IS_PF(hwif)) set_ppf(hwif); /* No transactionss before DMA is initialized */ dma_attr_init(hwif); return 0; err_hwif_ready: iounmap(hwif->intr_regs_base); err_map_intr_bar: iounmap(hwif->cfg_regs_bar); return err; } /** * hinic_free_hwif - free the HW interface * @hwif: the HW interface of a pci function device **/ void hinic_free_hwif(struct hinic_hwif *hwif) { iounmap(hwif->intr_regs_base); iounmap(hwif->cfg_regs_bar); }
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