--- /dev/null
+/*-
+ * Copyright (c) 2016 Solarflare Communications Inc.
+ * All rights reserved.
+ *
+ * This software was jointly developed between OKTET Labs (under contract
+ * for Solarflare) and Solarflare Communications, Inc.
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions are met:
+ *
+ * 1. Redistributions of source code must retain the above copyright notice,
+ * this list of conditions and the following disclaimer.
+ * 2. Redistributions in binary form must reproduce the above copyright notice,
+ * this list of conditions and the following disclaimer in the documentation
+ * and/or other materials provided with the distribution.
+ *
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+ * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
+ * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
+ * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
+ * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
+ * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
+ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
+ * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
+ * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
+ * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
+ * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+ */
+
+#ifndef _SFC_COMMON_EFSYS_H
+#define _SFC_COMMON_EFSYS_H
+
+#include <stdbool.h>
+
+#include <rte_spinlock.h>
+#include <rte_byteorder.h>
+#include <rte_debug.h>
+#include <rte_memzone.h>
+#include <rte_memory.h>
+#include <rte_memcpy.h>
+#include <rte_cycles.h>
+#include <rte_prefetch.h>
+#include <rte_common.h>
+#include <rte_malloc.h>
+#include <rte_log.h>
+
+#include "sfc_debug.h"
+
+#ifdef __cplusplus
+extern "C" {
+#endif
+
+#define EFSYS_HAS_UINT64 1
+#define EFSYS_USE_UINT64 1
+#define EFSYS_HAS_SSE2_M128 1
+
+#if RTE_BYTE_ORDER == RTE_BIG_ENDIAN
+#define EFSYS_IS_BIG_ENDIAN 1
+#define EFSYS_IS_LITTLE_ENDIAN 0
+#elif RTE_BYTE_ORDER == RTE_LITTLE_ENDIAN
+#define EFSYS_IS_BIG_ENDIAN 0
+#define EFSYS_IS_LITTLE_ENDIAN 1
+#else
+#error "Cannot determine system endianness"
+#endif
+#include "efx_types.h"
+
+
+#ifndef _NOTE
+#define _NOTE(s)
+#endif
+
+typedef bool boolean_t;
+
+#ifndef B_FALSE
+#define B_FALSE false
+#endif
+#ifndef B_TRUE
+#define B_TRUE true
+#endif
+
+/*
+ * RTE_MAX() and RTE_MIN() cannot be used since braced-group within
+ * expression allowed only inside a function, but MAX() is used as
+ * a number of elements in array.
+ */
+#ifndef MAX
+#define MAX(v1, v2) ((v1) > (v2) ? (v1) : (v2))
+#endif
+#ifndef MIN
+#define MIN(v1, v2) ((v1) < (v2) ? (v1) : (v2))
+#endif
+
+/* There are macros for alignment in DPDK, but we need to make a proper
+ * correspondence here, if we want to re-use them at all
+ */
+#ifndef IS_P2ALIGNED
+#define IS_P2ALIGNED(v, a) ((((uintptr_t)(v)) & ((uintptr_t)(a) - 1)) == 0)
+#endif
+
+#ifndef P2ROUNDUP
+#define P2ROUNDUP(x, align) (-(-(x) & -(align)))
+#endif
+
+#ifndef P2ALIGN
+#define P2ALIGN(_x, _a) ((_x) & -(_a))
+#endif
+
+#ifndef IS2P
+#define ISP2(x) rte_is_power_of_2(x)
+#endif
+
+#define ENOTACTIVE ENOTCONN
+
+static inline void
+prefetch_read_many(const volatile void *addr)
+{
+ rte_prefetch0(addr);
+}
+
+static inline void
+prefetch_read_once(const volatile void *addr)
+{
+ rte_prefetch_non_temporal(addr);
+}
+
+/* Modifiers used for Windows builds */
+#define __in
+#define __in_opt
+#define __in_ecount(_n)
+#define __in_ecount_opt(_n)
+#define __in_bcount(_n)
+#define __in_bcount_opt(_n)
+
+#define __out
+#define __out_opt
+#define __out_ecount(_n)
+#define __out_ecount_opt(_n)
+#define __out_bcount(_n)
+#define __out_bcount_opt(_n)
+
+#define __deref_out
+
+#define __inout
+#define __inout_opt
+#define __inout_ecount(_n)
+#define __inout_ecount_opt(_n)
+#define __inout_bcount(_n)
+#define __inout_bcount_opt(_n)
+#define __inout_bcount_full_opt(_n)
+
+#define __deref_out_bcount_opt(n)
+
+#define __checkReturn
+#define __success(_x)
+
+#define __drv_when(_p, _c)
+
+/* Code inclusion options */
+
+
+#define EFSYS_OPT_NAMES 0
+
+/* Disable SFN5xxx/SFN6xxx since it requires specific support in the PMD */
+#define EFSYS_OPT_SIENA 0
+/* Enable SFN7xxx support */
+#define EFSYS_OPT_HUNTINGTON 1
+/* Enable SFN8xxx support */
+#define EFSYS_OPT_MEDFORD 1
+#ifdef RTE_LIBRTE_SFC_EFX_DEBUG
+#define EFSYS_OPT_CHECK_REG 1
+#else
+#define EFSYS_OPT_CHECK_REG 0
+#endif
+
+/* MCDI is required for SFN7xxx and SFN8xx */
+#define EFSYS_OPT_MCDI 1
+#define EFSYS_OPT_MCDI_LOGGING 0
+#define EFSYS_OPT_MCDI_PROXY_AUTH 0
+
+#define EFSYS_OPT_MAC_STATS 0
+
+#define EFSYS_OPT_LOOPBACK 0
+
+#define EFSYS_OPT_MON_MCDI 0
+#define EFSYS_OPT_MON_STATS 0
+
+#define EFSYS_OPT_PHY_STATS 0
+#define EFSYS_OPT_BIST 0
+#define EFSYS_OPT_PHY_LED_CONTROL 0
+#define EFSYS_OPT_PHY_FLAGS 0
+
+#define EFSYS_OPT_VPD 0
+#define EFSYS_OPT_NVRAM 0
+#define EFSYS_OPT_BOOTCFG 0
+
+#define EFSYS_OPT_DIAG 0
+#define EFSYS_OPT_RX_SCALE 0
+#define EFSYS_OPT_QSTATS 0
+/* Filters support is required for SFN7xxx and SFN8xx */
+#define EFSYS_OPT_FILTER 1
+#define EFSYS_OPT_RX_SCATTER 0
+
+#define EFSYS_OPT_EV_PREFETCH 0
+
+#define EFSYS_OPT_DECODE_INTR_FATAL 0
+
+#define EFSYS_OPT_LICENSING 0
+
+#define EFSYS_OPT_ALLOW_UNCONFIGURED_NIC 0
+
+#define EFSYS_OPT_RX_PACKED_STREAM 0
+
+/* ID */
+
+typedef struct __efsys_identifier_s efsys_identifier_t;
+
+
+#define EFSYS_PROBE(_name) \
+ do { } while (0)
+
+#define EFSYS_PROBE1(_name, _type1, _arg1) \
+ do { } while (0)
+
+#define EFSYS_PROBE2(_name, _type1, _arg1, _type2, _arg2) \
+ do { } while (0)
+
+#define EFSYS_PROBE3(_name, _type1, _arg1, _type2, _arg2, \
+ _type3, _arg3) \
+ do { } while (0)
+
+#define EFSYS_PROBE4(_name, _type1, _arg1, _type2, _arg2, \
+ _type3, _arg3, _type4, _arg4) \
+ do { } while (0)
+
+#define EFSYS_PROBE5(_name, _type1, _arg1, _type2, _arg2, \
+ _type3, _arg3, _type4, _arg4, _type5, _arg5) \
+ do { } while (0)
+
+#define EFSYS_PROBE6(_name, _type1, _arg1, _type2, _arg2, \
+ _type3, _arg3, _type4, _arg4, _type5, _arg5, \
+ _type6, _arg6) \
+ do { } while (0)
+
+#define EFSYS_PROBE7(_name, _type1, _arg1, _type2, _arg2, \
+ _type3, _arg3, _type4, _arg4, _type5, _arg5, \
+ _type6, _arg6, _type7, _arg7) \
+ do { } while (0)
+
+
+/* DMA */
+
+typedef phys_addr_t efsys_dma_addr_t;
+
+typedef struct efsys_mem_s {
+ const struct rte_memzone *esm_mz;
+ /*
+ * Ideally it should have volatile qualifier to denote that
+ * the memory may be updated by someone else. However, it adds
+ * qualifier discard warnings when the pointer or its derivative
+ * is passed to memset() or rte_mov16().
+ * So, skip the qualifier here, but make sure that it is added
+ * below in access macros.
+ */
+ void *esm_base;
+ efsys_dma_addr_t esm_addr;
+} efsys_mem_t;
+
+
+#define EFSYS_MEM_ZERO(_esmp, _size) \
+ do { \
+ (void)memset((void *)(_esmp)->esm_base, 0, (_size)); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_MEM_READD(_esmp, _offset, _edp) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile uint32_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_dword_t))); \
+ \
+ _addr = (volatile uint32_t *)(_base + (_offset)); \
+ (_edp)->ed_u32[0] = _addr[0]; \
+ \
+ EFSYS_PROBE2(mem_readl, unsigned int, (_offset), \
+ uint32_t, (_edp)->ed_u32[0]); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_MEM_READQ(_esmp, _offset, _eqp) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile uint64_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_qword_t))); \
+ \
+ _addr = (volatile uint64_t *)(_base + (_offset)); \
+ (_eqp)->eq_u64[0] = _addr[0]; \
+ \
+ EFSYS_PROBE3(mem_readq, unsigned int, (_offset), \
+ uint32_t, (_eqp)->eq_u32[1], \
+ uint32_t, (_eqp)->eq_u32[0]); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_MEM_READO(_esmp, _offset, _eop) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile __m128i *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_oword_t))); \
+ \
+ _addr = (volatile __m128i *)(_base + (_offset)); \
+ (_eop)->eo_u128[0] = _addr[0]; \
+ \
+ EFSYS_PROBE5(mem_reado, unsigned int, (_offset), \
+ uint32_t, (_eop)->eo_u32[3], \
+ uint32_t, (_eop)->eo_u32[2], \
+ uint32_t, (_eop)->eo_u32[1], \
+ uint32_t, (_eop)->eo_u32[0]); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+
+#define EFSYS_MEM_WRITED(_esmp, _offset, _edp) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile uint32_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_dword_t))); \
+ \
+ EFSYS_PROBE2(mem_writed, unsigned int, (_offset), \
+ uint32_t, (_edp)->ed_u32[0]); \
+ \
+ _addr = (volatile uint32_t *)(_base + (_offset)); \
+ _addr[0] = (_edp)->ed_u32[0]; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_MEM_WRITEQ(_esmp, _offset, _eqp) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile uint64_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_qword_t))); \
+ \
+ EFSYS_PROBE3(mem_writeq, unsigned int, (_offset), \
+ uint32_t, (_eqp)->eq_u32[1], \
+ uint32_t, (_eqp)->eq_u32[0]); \
+ \
+ _addr = (volatile uint64_t *)(_base + (_offset)); \
+ _addr[0] = (_eqp)->eq_u64[0]; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_MEM_WRITEO(_esmp, _offset, _eop) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ volatile __m128i *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_oword_t))); \
+ \
+ \
+ EFSYS_PROBE5(mem_writeo, unsigned int, (_offset), \
+ uint32_t, (_eop)->eo_u32[3], \
+ uint32_t, (_eop)->eo_u32[2], \
+ uint32_t, (_eop)->eo_u32[1], \
+ uint32_t, (_eop)->eo_u32[0]); \
+ \
+ _addr = (volatile __m128i *)(_base + (_offset)); \
+ _addr[0] = (_eop)->eo_u128[0]; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+
+#define EFSYS_MEM_ADDR(_esmp) \
+ ((_esmp)->esm_addr)
+
+#define EFSYS_MEM_IS_NULL(_esmp) \
+ ((_esmp)->esm_base == NULL)
+
+#define EFSYS_MEM_PREFETCH(_esmp, _offset) \
+ do { \
+ volatile uint8_t *_base = (_esmp)->esm_base; \
+ \
+ rte_prefetch0(_base + (_offset)); \
+ } while (0)
+
+
+/* BAR */
+
+typedef struct efsys_bar_s {
+ rte_spinlock_t esb_lock;
+ int esb_rid;
+ struct rte_pci_device *esb_dev;
+ /*
+ * Ideally it should have volatile qualifier to denote that
+ * the memory may be updated by someone else. However, it adds
+ * qualifier discard warnings when the pointer or its derivative
+ * is passed to memset() or rte_mov16().
+ * So, skip the qualifier here, but make sure that it is added
+ * below in access macros.
+ */
+ void *esb_base;
+} efsys_bar_t;
+
+#define SFC_BAR_LOCK_INIT(_esbp, _ifname) \
+ do { \
+ rte_spinlock_init(&(_esbp)->esb_lock); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+#define SFC_BAR_LOCK_DESTROY(_esbp) ((void)0)
+#define SFC_BAR_LOCK(_esbp) rte_spinlock_lock(&(_esbp)->esb_lock)
+#define SFC_BAR_UNLOCK(_esbp) rte_spinlock_unlock(&(_esbp)->esb_lock)
+
+#define EFSYS_BAR_READD(_esbp, _offset, _edp, _lock) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile uint32_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_dword_t))); \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ _addr = (volatile uint32_t *)(_base + (_offset)); \
+ rte_rmb(); \
+ (_edp)->ed_u32[0] = _addr[0]; \
+ \
+ EFSYS_PROBE2(bar_readd, unsigned int, (_offset), \
+ uint32_t, (_edp)->ed_u32[0]); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_BAR_READQ(_esbp, _offset, _eqp) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile uint64_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_qword_t))); \
+ \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ _addr = (volatile uint64_t *)(_base + (_offset)); \
+ rte_rmb(); \
+ (_eqp)->eq_u64[0] = _addr[0]; \
+ \
+ EFSYS_PROBE3(bar_readq, unsigned int, (_offset), \
+ uint32_t, (_eqp)->eq_u32[1], \
+ uint32_t, (_eqp)->eq_u32[0]); \
+ \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_BAR_READO(_esbp, _offset, _eop, _lock) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile __m128i *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_oword_t))); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ _addr = (volatile __m128i *)(_base + (_offset)); \
+ rte_rmb(); \
+ (_eop)->eo_u128[0] = _addr[0]; \
+ \
+ EFSYS_PROBE5(bar_reado, unsigned int, (_offset), \
+ uint32_t, (_eop)->eo_u32[3], \
+ uint32_t, (_eop)->eo_u32[2], \
+ uint32_t, (_eop)->eo_u32[1], \
+ uint32_t, (_eop)->eo_u32[0]); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+
+#define EFSYS_BAR_WRITED(_esbp, _offset, _edp, _lock) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile uint32_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_dword_t))); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ EFSYS_PROBE2(bar_writed, unsigned int, (_offset), \
+ uint32_t, (_edp)->ed_u32[0]); \
+ \
+ _addr = (volatile uint32_t *)(_base + (_offset)); \
+ _addr[0] = (_edp)->ed_u32[0]; \
+ rte_wmb(); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_BAR_WRITEQ(_esbp, _offset, _eqp) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile uint64_t *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_qword_t))); \
+ \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ EFSYS_PROBE3(bar_writeq, unsigned int, (_offset), \
+ uint32_t, (_eqp)->eq_u32[1], \
+ uint32_t, (_eqp)->eq_u32[0]); \
+ \
+ _addr = (volatile uint64_t *)(_base + (_offset)); \
+ _addr[0] = (_eqp)->eq_u64[0]; \
+ rte_wmb(); \
+ \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/*
+ * Guarantees 64bit aligned 64bit writes to write combined BAR mapping
+ * (required by PIO hardware).
+ *
+ * Neither VFIO, nor UIO, nor NIC UIO (on FreeBSD) support
+ * write-combined memory mapped to user-land, so just abort if used.
+ */
+#define EFSYS_BAR_WC_WRITEQ(_esbp, _offset, _eqp) \
+ do { \
+ rte_panic("Write-combined BAR access not supported"); \
+ } while (B_FALSE)
+
+#define EFSYS_BAR_WRITEO(_esbp, _offset, _eop, _lock) \
+ do { \
+ volatile uint8_t *_base = (_esbp)->esb_base; \
+ volatile __m128i *_addr; \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ SFC_ASSERT(IS_P2ALIGNED(_offset, sizeof(efx_oword_t))); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_LOCK(_esbp); \
+ \
+ EFSYS_PROBE5(bar_writeo, unsigned int, (_offset), \
+ uint32_t, (_eop)->eo_u32[3], \
+ uint32_t, (_eop)->eo_u32[2], \
+ uint32_t, (_eop)->eo_u32[1], \
+ uint32_t, (_eop)->eo_u32[0]); \
+ \
+ _addr = (volatile __m128i *)(_base + (_offset)); \
+ _addr[0] = (_eop)->eo_u128[0]; \
+ rte_wmb(); \
+ \
+ _NOTE(CONSTANTCONDITION); \
+ if (_lock) \
+ SFC_BAR_UNLOCK(_esbp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* Use the standard octo-word write for doorbell writes */
+#define EFSYS_BAR_DOORBELL_WRITEO(_esbp, _offset, _eop) \
+ do { \
+ EFSYS_BAR_WRITEO((_esbp), (_offset), (_eop), B_FALSE); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* SPIN */
+
+#define EFSYS_SPIN(_us) \
+ do { \
+ rte_delay_us(_us); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_SLEEP EFSYS_SPIN
+
+/* BARRIERS */
+
+#define EFSYS_MEM_READ_BARRIER() rte_rmb()
+#define EFSYS_PIO_WRITE_BARRIER() rte_wmb()
+
+/* DMA SYNC */
+
+/*
+ * DPDK does not provide any DMA syncing API, and no PMD drivers
+ * have any traces of explicit DMA syncing.
+ * DMA mapping is assumed to be coherent.
+ */
+
+#define EFSYS_DMA_SYNC_FOR_KERNEL(_esmp, _offset, _size) ((void)0)
+#define EFSYS_DMA_SYNC_FOR_DEVICE(_esmp, _offset, _size) ((void)0)
+
+/* TIMESTAMP */
+
+typedef uint64_t efsys_timestamp_t;
+
+#define EFSYS_TIMESTAMP(_usp) \
+ do { \
+ *(_usp) = rte_get_timer_cycles() * 1000000 / \
+ rte_get_timer_hz(); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* KMEM */
+
+#define EFSYS_KMEM_ALLOC(_esip, _size, _p) \
+ do { \
+ (_esip) = (_esip); \
+ (_p) = rte_zmalloc("sfc", (_size), 0); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_KMEM_FREE(_esip, _size, _p) \
+ do { \
+ (void)(_esip); \
+ (void)(_size); \
+ rte_free((_p)); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* LOCK */
+
+typedef rte_spinlock_t efsys_lock_t;
+
+#define SFC_EFSYS_LOCK_INIT(_eslp, _ifname, _label) \
+ rte_spinlock_init((_eslp))
+#define SFC_EFSYS_LOCK_DESTROY(_eslp) ((void)0)
+#define SFC_EFSYS_LOCK(_eslp) \
+ rte_spinlock_lock((_eslp))
+#define SFC_EFSYS_UNLOCK(_eslp) \
+ rte_spinlock_unlock((_eslp))
+#define SFC_EFSYS_LOCK_ASSERT_OWNED(_eslp) \
+ SFC_ASSERT(rte_spinlock_is_locked((_eslp)))
+
+typedef int efsys_lock_state_t;
+
+#define EFSYS_LOCK_MAGIC 0x000010c4
+
+#define EFSYS_LOCK(_lockp, _state) \
+ do { \
+ SFC_EFSYS_LOCK(_lockp); \
+ (_state) = EFSYS_LOCK_MAGIC; \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_UNLOCK(_lockp, _state) \
+ do { \
+ SFC_ASSERT((_state) == EFSYS_LOCK_MAGIC); \
+ SFC_EFSYS_UNLOCK(_lockp); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* STAT */
+
+typedef uint64_t efsys_stat_t;
+
+#define EFSYS_STAT_INCR(_knp, _delta) \
+ do { \
+ *(_knp) += (_delta); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_DECR(_knp, _delta) \
+ do { \
+ *(_knp) -= (_delta); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_SET(_knp, _val) \
+ do { \
+ *(_knp) = (_val); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_SET_QWORD(_knp, _valp) \
+ do { \
+ *(_knp) = rte_le_to_cpu_64((_valp)->eq_u64[0]); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_SET_DWORD(_knp, _valp) \
+ do { \
+ *(_knp) = rte_le_to_cpu_32((_valp)->ed_u32[0]); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_INCR_QWORD(_knp, _valp) \
+ do { \
+ *(_knp) += rte_le_to_cpu_64((_valp)->eq_u64[0]); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+#define EFSYS_STAT_SUBR_QWORD(_knp, _valp) \
+ do { \
+ *(_knp) -= rte_le_to_cpu_64((_valp)->eq_u64[0]); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+
+/* ERR */
+
+#if EFSYS_OPT_DECODE_INTR_FATAL
+#define EFSYS_ERR(_esip, _code, _dword0, _dword1) \
+ do { \
+ (void)(_esip); \
+ RTE_LOG(ERR, PMD, "FATAL ERROR #%u (0x%08x%08x)\n", \
+ (_code), (_dword0), (_dword1)); \
+ _NOTE(CONSTANTCONDITION); \
+ } while (B_FALSE)
+#endif
+
+/* ASSERT */
+
+/* RTE_VERIFY from DPDK treats expressions with % operator incorrectly,
+ * so we re-implement it here
+ */
+#ifdef RTE_LIBRTE_SFC_EFX_DEBUG
+#define EFSYS_ASSERT(_exp) \
+ do { \
+ if (unlikely(!(_exp))) \
+ rte_panic("line %d\tassert \"%s\" failed\n", \
+ __LINE__, (#_exp)); \
+ } while (0)
+#else
+#define EFSYS_ASSERT(_exp) (void)(_exp)
+#endif
+
+#define EFSYS_ASSERT3(_x, _op, _y, _t) EFSYS_ASSERT((_t)(_x) _op (_t)(_y))
+
+#define EFSYS_ASSERT3U(_x, _op, _y) EFSYS_ASSERT3(_x, _op, _y, uint64_t)
+#define EFSYS_ASSERT3S(_x, _op, _y) EFSYS_ASSERT3(_x, _op, _y, int64_t)
+#define EFSYS_ASSERT3P(_x, _op, _y) EFSYS_ASSERT3(_x, _op, _y, uintptr_t)
+
+/* ROTATE */
+
+#define EFSYS_HAS_ROTL_DWORD 0
+
+#ifdef __cplusplus
+}
+#endif
+
+#endif /* _SFC_COMMON_EFSYS_H */