// SPDX-License-Identifier: GPL-2.0-only
/*
 * Copyright (C) 2016 Broadcom
 *      Author: Jayachandran C <jchandra@broadcom.com>
 * Copyright (C) 2016 Semihalf
 *      Author: Tomasz Nowicki <tn@semihalf.com>
 */

#define pr_fmt(fmt) "ACPI: " fmt

#include <linux/kernel.h>
#include <linux/pci.h>
#include <linux/pci-acpi.h>
#include <linux/pci-ecam.h>

/* Structure to hold entries from the MCFG table */
struct mcfg_entry {
        struct list_head        list;
        phys_addr_t             addr;
        u16                     segment;
        u8                      bus_start;
        u8                      bus_end;
};

#ifdef CONFIG_PCI_QUIRKS
struct mcfg_fixup {
        char oem_id[ACPI_OEM_ID_SIZE + 1];
        char oem_table_id[ACPI_OEM_TABLE_ID_SIZE + 1];
        u32 oem_revision;
        u16 segment;
        struct resource bus_range;
        const struct pci_ecam_ops *ops;
        struct resource cfgres;
};

#define MCFG_BUS_RANGE(start, end)      DEFINE_RES_NAMED((start),       \
                                                ((end) - (start) + 1),  \
                                                NULL, IORESOURCE_BUS)
#define MCFG_BUS_ANY                    MCFG_BUS_RANGE(0x0, 0xff)

static struct mcfg_fixup mcfg_quirks[] = {
/*      { OEM_ID, OEM_TABLE_ID, REV, SEGMENT, BUS_RANGE, ops, cfgres }, */

#define AL_ECAM(table_id, rev, seg, ops) \
        { "AMAZON", table_id, rev, seg, MCFG_BUS_ANY, ops }

        AL_ECAM("GRAVITON", 0, 0, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 1, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 2, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 3, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 4, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 5, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 6, &al_pcie_ops),
        AL_ECAM("GRAVITON", 0, 7, &al_pcie_ops),

#define QCOM_ECAM32(seg) \
        { "QCOM  ", "QDF2432 ", 1, seg, MCFG_BUS_ANY, &pci_32b_ops }

        QCOM_ECAM32(0),
        QCOM_ECAM32(1),
        QCOM_ECAM32(2),
        QCOM_ECAM32(3),
        QCOM_ECAM32(4),
        QCOM_ECAM32(5),
        QCOM_ECAM32(6),
        QCOM_ECAM32(7),

#define HISI_QUAD_DOM(table_id, seg, ops) \
        { "HISI  ", table_id, 0, (seg) + 0, MCFG_BUS_ANY, ops }, \
        { "HISI  ", table_id, 0, (seg) + 1, MCFG_BUS_ANY, ops }, \
        { "HISI  ", table_id, 0, (seg) + 2, MCFG_BUS_ANY, ops }, \
        { "HISI  ", table_id, 0, (seg) + 3, MCFG_BUS_ANY, ops }

        HISI_QUAD_DOM("HIP05   ",  0, &hisi_pcie_ops),
        HISI_QUAD_DOM("HIP06   ",  0, &hisi_pcie_ops),
        HISI_QUAD_DOM("HIP07   ",  0, &hisi_pcie_ops),
        HISI_QUAD_DOM("HIP07   ",  4, &hisi_pcie_ops),
        HISI_QUAD_DOM("HIP07   ",  8, &hisi_pcie_ops),
        HISI_QUAD_DOM("HIP07   ", 12, &hisi_pcie_ops),

#define THUNDER_PEM_RES(addr, node) \
        DEFINE_RES_MEM((addr) + ((u64) (node) << 44), 0x39 * SZ_16M)

#define THUNDER_PEM_QUIRK(rev, node) \
        { "CAVIUM", "THUNDERX", rev, 4 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x88001f000000UL, node) },  \
        { "CAVIUM", "THUNDERX", rev, 5 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x884057000000UL, node) },  \
        { "CAVIUM", "THUNDERX", rev, 6 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x88808f000000UL, node) },  \
        { "CAVIUM", "THUNDERX", rev, 7 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x89001f000000UL, node) },  \
        { "CAVIUM", "THUNDERX", rev, 8 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x894057000000UL, node) },  \
        { "CAVIUM", "THUNDERX", rev, 9 + (10 * (node)), MCFG_BUS_ANY,       \
          &thunder_pem_ecam_ops, THUNDER_PEM_RES(0x89808f000000UL, node) }

#define THUNDER_ECAM_QUIRK(rev, seg)                                    \
        { "CAVIUM", "THUNDERX", rev, seg, MCFG_BUS_ANY,                 \
        &pci_thunder_ecam_ops }

        /* SoC pass2.x */
        THUNDER_PEM_QUIRK(1, 0),
        THUNDER_PEM_QUIRK(1, 1),
        THUNDER_ECAM_QUIRK(1, 10),

        /* SoC pass1.x */
        THUNDER_PEM_QUIRK(2, 0),        /* off-chip devices */
        THUNDER_PEM_QUIRK(2, 1),        /* off-chip devices */
        THUNDER_ECAM_QUIRK(2,  0),
        THUNDER_ECAM_QUIRK(2,  1),
        THUNDER_ECAM_QUIRK(2,  2),
        THUNDER_ECAM_QUIRK(2,  3),
        THUNDER_ECAM_QUIRK(2, 10),
        THUNDER_ECAM_QUIRK(2, 11),
        THUNDER_ECAM_QUIRK(2, 12),
        THUNDER_ECAM_QUIRK(2, 13),

        { "NVIDIA", "TEGRA194", 1, 0, MCFG_BUS_ANY, &tegra194_pcie_ops},
        { "NVIDIA", "TEGRA194", 1, 1, MCFG_BUS_ANY, &tegra194_pcie_ops},
        { "NVIDIA", "TEGRA194", 1, 2, MCFG_BUS_ANY, &tegra194_pcie_ops},
        { "NVIDIA", "TEGRA194", 1, 3, MCFG_BUS_ANY, &tegra194_pcie_ops},
        { "NVIDIA", "TEGRA194", 1, 4, MCFG_BUS_ANY, &tegra194_pcie_ops},
        { "NVIDIA", "TEGRA194", 1, 5, MCFG_BUS_ANY, &tegra194_pcie_ops},

#define XGENE_V1_ECAM_MCFG(rev, seg) \
        {"APM   ", "XGENE   ", rev, seg, MCFG_BUS_ANY, \
                &xgene_v1_pcie_ecam_ops }

#define XGENE_V2_ECAM_MCFG(rev, seg) \
        {"APM   ", "XGENE   ", rev, seg, MCFG_BUS_ANY, \
                &xgene_v2_pcie_ecam_ops }

        /* X-Gene SoC with v1 PCIe controller */
        XGENE_V1_ECAM_MCFG(1, 0),
        XGENE_V1_ECAM_MCFG(1, 1),
        XGENE_V1_ECAM_MCFG(1, 2),
        XGENE_V1_ECAM_MCFG(1, 3),
        XGENE_V1_ECAM_MCFG(1, 4),
        XGENE_V1_ECAM_MCFG(2, 0),
        XGENE_V1_ECAM_MCFG(2, 1),
        XGENE_V1_ECAM_MCFG(2, 2),
        XGENE_V1_ECAM_MCFG(2, 3),
        XGENE_V1_ECAM_MCFG(2, 4),
        /* X-Gene SoC with v2.1 PCIe controller */
        XGENE_V2_ECAM_MCFG(3, 0),
        XGENE_V2_ECAM_MCFG(3, 1),
        /* X-Gene SoC with v2.2 PCIe controller */
        XGENE_V2_ECAM_MCFG(4, 0),
        XGENE_V2_ECAM_MCFG(4, 1),
        XGENE_V2_ECAM_MCFG(4, 2),

#define ALTRA_ECAM_QUIRK(rev, seg) \
        { "Ampere", "Altra   ", rev, seg, MCFG_BUS_ANY, &pci_32b_read_ops }

        ALTRA_ECAM_QUIRK(1, 0),
        ALTRA_ECAM_QUIRK(1, 1),
        ALTRA_ECAM_QUIRK(1, 2),
        ALTRA_ECAM_QUIRK(1, 3),
        ALTRA_ECAM_QUIRK(1, 4),
        ALTRA_ECAM_QUIRK(1, 5),
        ALTRA_ECAM_QUIRK(1, 6),
        ALTRA_ECAM_QUIRK(1, 7),
        ALTRA_ECAM_QUIRK(1, 8),
        ALTRA_ECAM_QUIRK(1, 9),
        ALTRA_ECAM_QUIRK(1, 10),
        ALTRA_ECAM_QUIRK(1, 11),
        ALTRA_ECAM_QUIRK(1, 12),
        ALTRA_ECAM_QUIRK(1, 13),
        ALTRA_ECAM_QUIRK(1, 14),
        ALTRA_ECAM_QUIRK(1, 15),
};

static char mcfg_oem_id[ACPI_OEM_ID_SIZE];
static char mcfg_oem_table_id[ACPI_OEM_TABLE_ID_SIZE];
static u32 mcfg_oem_revision;

static int pci_mcfg_quirk_matches(struct mcfg_fixup *f, u16 segment,
                                  struct resource *bus_range)
{
        if (!memcmp(f->oem_id, mcfg_oem_id, ACPI_OEM_ID_SIZE) &&
            !memcmp(f->oem_table_id, mcfg_oem_table_id,
                    ACPI_OEM_TABLE_ID_SIZE) &&
            f->oem_revision == mcfg_oem_revision &&
            f->segment == segment &&
            resource_contains(&f->bus_range, bus_range))
                return 1;

        return 0;
}
#endif

static void pci_mcfg_apply_quirks(struct acpi_pci_root *root,
                                  struct resource *cfgres,
                                  const struct pci_ecam_ops **ecam_ops)
{
#ifdef CONFIG_PCI_QUIRKS
        u16 segment = root->segment;
        struct resource *bus_range = &root->secondary;
        struct mcfg_fixup *f;
        int i;

        for (i = 0, f = mcfg_quirks; i < ARRAY_SIZE(mcfg_quirks); i++, f++) {
                if (pci_mcfg_quirk_matches(f, segment, bus_range)) {
                        if (f->cfgres.start)
                                *cfgres = f->cfgres;
                        if (f->ops)
                                *ecam_ops =  f->ops;
                        dev_info(&root->device->dev, "MCFG quirk: ECAM at %pR for %pR with %ps\n",
                                 cfgres, bus_range, *ecam_ops);
                        return;
                }
        }
#endif
}

/* List to save MCFG entries */
static LIST_HEAD(pci_mcfg_list);

int pci_mcfg_lookup(struct acpi_pci_root *root, struct resource *cfgres,
                    const struct pci_ecam_ops **ecam_ops)
{
        const struct pci_ecam_ops *ops = &pci_generic_ecam_ops;
        struct resource *bus_res = &root->secondary;
        u16 seg = root->segment;
        struct mcfg_entry *e;
        struct resource res;

        /* Use address from _CBA if present, otherwise lookup MCFG */
        if (root->mcfg_addr)
                goto skip_lookup;

        /*
         * We expect the range in bus_res in the coverage of MCFG bus range.
         */
        list_for_each_entry(e, &pci_mcfg_list, list) {
                if (e->segment == seg && e->bus_start <= bus_res->start &&
                    e->bus_end >= bus_res->end) {
                        root->mcfg_addr = e->addr;
                }

        }

skip_lookup:
        memset(&res, 0, sizeof(res));
        if (root->mcfg_addr) {
                res.start = root->mcfg_addr + (bus_res->start << 20);
                res.end = res.start + (resource_size(bus_res) << 20) - 1;
                res.flags = IORESOURCE_MEM;
        }

        /*
         * Allow quirks to override default ECAM ops and CFG resource
         * range.  This may even fabricate a CFG resource range in case
         * MCFG does not have it.  Invalid CFG start address means MCFG
         * firmware bug or we need another quirk in array.
         */
        pci_mcfg_apply_quirks(root, &res, &ops);
        if (!res.start)
                return -ENXIO;

        *cfgres = res;
        *ecam_ops = ops;
        return 0;
}

static __init int pci_mcfg_parse(struct acpi_table_header *header)
{
        struct acpi_table_mcfg *mcfg;
        struct acpi_mcfg_allocation *mptr;
        struct mcfg_entry *e, *arr;
        int i, n;

        if (header->length < sizeof(struct acpi_table_mcfg))
                return -EINVAL;

        n = (header->length - sizeof(struct acpi_table_mcfg)) /
                                        sizeof(struct acpi_mcfg_allocation);
        mcfg = (struct acpi_table_mcfg *)header;
        mptr = (struct acpi_mcfg_allocation *) &mcfg[1];

        arr = kcalloc(n, sizeof(*arr), GFP_KERNEL);
        if (!arr)
                return -ENOMEM;

        for (i = 0, e = arr; i < n; i++, mptr++, e++) {
                e->segment = mptr->pci_segment;
                e->addr =  mptr->address;
                e->bus_start = mptr->start_bus_number;
                e->bus_end = mptr->end_bus_number;
                list_add(&e->list, &pci_mcfg_list);
        }

#ifdef CONFIG_PCI_QUIRKS
        /* Save MCFG IDs and revision for quirks matching */
        memcpy(mcfg_oem_id, header->oem_id, ACPI_OEM_ID_SIZE);
        memcpy(mcfg_oem_table_id, header->oem_table_id, ACPI_OEM_TABLE_ID_SIZE);
        mcfg_oem_revision = header->oem_revision;
#endif

        pr_info("MCFG table detected, %d entries\n", n);
        return 0;
}

/* Interface called by ACPI - parse and save MCFG table */
void __init pci_mmcfg_late_init(void)
{
        int err = acpi_table_parse(ACPI_SIG_MCFG, pci_mcfg_parse);
        if (err)
                pr_debug("Failed to parse MCFG (%d)\n", err);
}