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linux/drivers/net/ethernet/huawei/hinic/hinic_hw_if.c
Thomas Gleixner 2025cf9e19 treewide: Replace GPLv2 boilerplate/reference with SPDX - rule 288 
Based on 1 normalized pattern(s):

  this program is free software you can redistribute it and or modify
  it under the terms and conditions of the gnu general public license
  version 2 as published by the free software foundation this program
  is distributed in the hope it will be useful but without any
  warranty without even the implied warranty of merchantability or
  fitness for a particular purpose see the gnu general public license
  for more details

extracted by the scancode license scanner the SPDX license identifier

  GPL-2.0-only

has been chosen to replace the boilerplate/reference in 263 file(s).

Signed-off-by: Thomas Gleixner <tglx@linutronix.de>
Reviewed-by: Allison Randal <allison@lohutok.net>
Reviewed-by: Alexios Zavras <alexios.zavras@intel.com>
Cc: linux-spdx@vger.kernel.org
Link: https://lkml.kernel.org/r/20190529141901.208660670@linutronix.de
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-06-05 17:36:37 +02:00

371 lines
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// 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 "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)
/**
* 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 = 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)
{
struct pci_dev *pdev = hwif->pdev;
u32 addr, attr1;
addr = HINIC_CSR_FUNC_ATTR1_ADDR;
attr1 = hinic_hwif_read_reg(hwif, addr);
if (!HINIC_FA1_GET(attr1, INIT_STATUS)) {
dev_err(&pdev->dev, "hwif status is not ready\n");
return -EFAULT;
}
return 0;
}
/**
* 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
**/
static void set_hwif_attr(struct hinic_hwif *hwif, u32 attr0, u32 attr1)
{
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));
}
/**
* 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;
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);
set_hwif_attr(hwif, attr0, attr1);
}
/**
* 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_table_init - initialize the 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);
}
/**
* hinic_init_hwif - initialize the hw interface
* @hwif: the HW interface of a pci function device
* @pdev: the pci device for acessing 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 = hwif_ready(hwif);
if (err) {
dev_err(&pdev->dev, "HW interface is not ready\n");
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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