New upstream version 18.11-rc1

[deb_dpdk.git] / drivers / net / octeontx / base / octeontx_io.h

/* SPDX-License-Identifier: BSD-3-Clause
 * Copyright(c) 2017 Cavium, Inc
 */

#ifndef __OCTEONTX_IO_H__
#define __OCTEONTX_IO_H__

#include <stddef.h>
#include <stdint.h>

#include <rte_io.h>

/* In Cavium OCTEON TX SoC, all accesses to the device registers are
 * implicitly strongly ordered. So, The relaxed version of IO operation is
 * safe to use with out any IO memory barriers.
 */
#define octeontx_read64 rte_read64_relaxed
#define octeontx_write64 rte_write64_relaxed

/* ARM64 specific functions */
#if defined(RTE_ARCH_ARM64)
#define octeontx_prefetch_store_keep(_ptr) ({\
        asm volatile("prfm pstl1keep, %a0\n" : : "p" (_ptr)); })

#define octeontx_load_pair(val0, val1, addr) ({         \
                        asm volatile(                   \
                        "ldp %x[x0], %x[x1], [%x[p1]]"  \
                        :[x0]"=r"(val0), [x1]"=r"(val1) \
                        :[p1]"r"(addr)                  \
                        ); })

#define octeontx_store_pair(val0, val1, addr) ({                \
                        asm volatile(                   \
                        "stp %x[x0], %x[x1], [%x[p1]]"  \
                        ::[x0]"r"(val0), [x1]"r"(val1), [p1]"r"(addr) \
                        ); })
#else /* Un optimized functions for building on non arm64 arch */

#define octeontx_prefetch_store_keep(_ptr) do {} while (0)

#define octeontx_load_pair(val0, val1, addr)            \
do {                                                    \
        val0 = rte_read64(addr);                        \
        val1 = rte_read64(((uint8_t *)addr) + 8);       \
} while (0)

#define octeontx_store_pair(val0, val1, addr)           \
do {                                                    \
        rte_write64(val0, addr);                        \
        rte_write64(val1, (((uint8_t *)addr) + 8));     \
} while (0)
#endif

#if defined(RTE_ARCH_ARM64)
/**
 * Perform an atomic fetch-and-add operation.
 */
static inline uint64_t
octeontx_reg_ldadd_u64(void *addr, int64_t off)
{
        uint64_t old_val;

        __asm__ volatile(
                " .cpu          generic+lse\n"
                " ldadd %1, %0, [%2]\n"
                : "=r" (old_val) : "r" (off), "r" (addr) : "memory");

        return old_val;
}

/**
 * Perform a LMTST operation - an atomic write of up to 128 byte to
 * an I/O block that supports this operation type.
 *
 * @param lmtline_va is the address where LMTLINE is mapped
 * @param ioreg_va is the virtual address of the device register
 * @param cmdbuf is the array of peripheral commands to execute
 * @param cmdsize is the number of 64-bit words in 'cmdbuf'
 *
 * @return N/A
 */
static inline void
octeontx_reg_lmtst(void *lmtline_va, void *ioreg_va, const uint64_t cmdbuf[],
                   uint64_t cmdsize)
{
        uint64_t result;
        uint64_t word_count;
        uint64_t *lmtline = lmtline_va;

        word_count = cmdsize;

        do {
                /* Copy commands to LMTLINE */
                for (result = 0; result < word_count; result += 2) {
                        lmtline[result + 0] = cmdbuf[result + 0];
                        lmtline[result + 1] = cmdbuf[result + 1];
                }

                /* LDEOR initiates atomic transfer to I/O device */
                __asm__ volatile(
                        " .cpu          generic+lse\n"
                        " ldeor xzr, %0, [%1]\n"
                        : "=r" (result) : "r" (ioreg_va) : "memory");
        } while (!result);
}

#else

static inline uint64_t
octeontx_reg_ldadd_u64(void *addr, int64_t off)
{
        RTE_SET_USED(addr);
        RTE_SET_USED(off);
        return 0;
}

static inline void
octeontx_reg_lmtst(void *lmtline_va, void *ioreg_va, const uint64_t cmdbuf[],
                   uint64_t cmdsize)
{
        RTE_SET_USED(lmtline_va);
        RTE_SET_USED(ioreg_va);
        RTE_SET_USED(cmdbuf);
        RTE_SET_USED(cmdsize);
}

#endif
#endif /* __OCTEONTX_IO_H__ */