u-boot/arch/arm/include/asm/arch-octeontx2/csrs/csrs-rvu.h

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/* SPDX-License-Identifier: GPL-2.0
*
* Copyright (C) 2020 Marvell International Ltd.
*
* https://spdx.org/licenses
*/
#ifndef __CSRS_RVU_H__
#define __CSRS_RVU_H__
/**
* @file
*
* Configuration and status register (CSR) address and type definitions for
* RVU.
*
* This file is auto generated. Do not edit.
*
*/
/**
* Enumeration rvu_af_int_vec_e
*
* RVU Admin Function Interrupt Vector Enumeration Enumerates the MSI-X
* interrupt vectors. Internal: RVU maintains the state of these vectors
* internally, and generates GIB messages for it without accessing the
* MSI-X table region in LLC/DRAM.
*/
#define RVU_AF_INT_VEC_E_GEN (3)
#define RVU_AF_INT_VEC_E_MBOX (4)
#define RVU_AF_INT_VEC_E_PFFLR (1)
#define RVU_AF_INT_VEC_E_PFME (2)
#define RVU_AF_INT_VEC_E_POISON (0)
/**
* Enumeration rvu_bar_e
*
* RVU Base Address Register Enumeration Enumerates the base address
* registers. Internal: For documentation only.
*/
#define RVU_BAR_E_RVU_PFX_BAR0(a) (0x840000000000ll + 0x1000000000ll * (a))
#define RVU_BAR_E_RVU_PFX_BAR0_SIZE 0x10000000ull
#define RVU_BAR_E_RVU_PFX_FUNCX_BAR2(a, b) \
(0x840200000000ll + 0x1000000000ll * (a) + 0x2000000ll * (b))
#define RVU_BAR_E_RVU_PFX_FUNCX_BAR2_SIZE 0x100000ull
#define RVU_BAR_E_RVU_PFX_FUNCX_BAR4(a, b) \
(0x840400000000ll + 0x1000000000ll * (a) + 0x2000000ll * (b))
#define RVU_BAR_E_RVU_PFX_FUNCX_BAR4_SIZE 0x10000ull
/**
* Enumeration rvu_block_addr_e
*
* RVU Block Address Enumeration Enumerates addressing of RVU resource
* blocks within each RVU BAR, i.e. values of RVU_FUNC_ADDR_S[BLOCK] and
* RVU_AF_ADDR_S[BLOCK]. CNXXXX may not implement all enumerated blocks.
* Software can read RVU_PF/RVU_VF_BLOCK_ADDR()_DISC[IMP] to discover
* which blocks are implemented and enabled.
*/
#define RVU_BLOCK_ADDR_E_CPTX(a) (0xa + (a))
#define RVU_BLOCK_ADDR_E_LMT (1)
#define RVU_BLOCK_ADDR_E_NDCX(a) (0xc + (a))
#define RVU_BLOCK_ADDR_E_NIXX(a) (4 + (a))
#define RVU_BLOCK_ADDR_E_NPA (3)
#define RVU_BLOCK_ADDR_E_NPC (6)
#define RVU_BLOCK_ADDR_E_RX(a) (0 + (a))
#define RVU_BLOCK_ADDR_E_REEX(a) (0x14 + (a))
#define RVU_BLOCK_ADDR_E_RVUM (0)
#define RVU_BLOCK_ADDR_E_SSO (7)
#define RVU_BLOCK_ADDR_E_SSOW (8)
#define RVU_BLOCK_ADDR_E_TIM (9)
/**
* Enumeration rvu_block_type_e
*
* RVU Block Type Enumeration Enumerates values of
* RVU_PF/RVU_VF_BLOCK_ADDR()_DISC[BTYPE].
*/
#define RVU_BLOCK_TYPE_E_CPT (9)
#define RVU_BLOCK_TYPE_E_DDF (0xb)
#define RVU_BLOCK_TYPE_E_LMT (2)
#define RVU_BLOCK_TYPE_E_NDC (0xa)
#define RVU_BLOCK_TYPE_E_NIX (3)
#define RVU_BLOCK_TYPE_E_NPA (4)
#define RVU_BLOCK_TYPE_E_NPC (5)
#define RVU_BLOCK_TYPE_E_RAD (0xd)
#define RVU_BLOCK_TYPE_E_REE (0xe)
#define RVU_BLOCK_TYPE_E_RVUM (0)
#define RVU_BLOCK_TYPE_E_SSO (6)
#define RVU_BLOCK_TYPE_E_SSOW (7)
#define RVU_BLOCK_TYPE_E_TIM (8)
#define RVU_BLOCK_TYPE_E_ZIP (0xc)
/**
* Enumeration rvu_bus_lf_e
*
* INTERNAL: RVU Bus LF Range Enumeration Enumerates the LF range for
* the RVU bus. Internal: This is an enum used in csr3 virtual equations.
*/
#define RVU_BUS_LF_E_RVU_BUS_LFX(a) (0 + 0x2000000 * (a))
/**
* Enumeration rvu_bus_lf_slot_e
*
* INTERNAL: RVU Bus LF Slot Range Enumeration Enumerates the LF and
* Slot range for the RVU bus. Internal: This is an enum used in csr3
* virtual equations.
*/
#define RVU_BUS_LF_SLOT_E_RVU_BUS_LFX_SLOTX(a, b) \
(0 + 0x2000000 * (a) + 0x1000 * (b))
/**
* Enumeration rvu_bus_pf_e
*
* INTERNAL: RVU Bus PF Range Enumeration Enumerates the PF range for
* the RVU bus. Internal: This is an enum used in csr3 virtual equations.
*/
#define RVU_BUS_PF_E_RVU_BUS_PFX(a) (0ll + 0x1000000000ll * (a))
/**
* Enumeration rvu_bus_pfvf_e
*
* INTERNAL: RVU Bus PFVF Range Enumeration Enumerates the PF and VF
* ranges for the RVU bus. Internal: This is an enum used in csr3 virtual
* equations.
*/
#define RVU_BUS_PFVF_E_RVU_BUS_PFX(a) (0 + 0x2000000 * (a))
#define RVU_BUS_PFVF_E_RVU_BUS_VFX(a) (0 + 0x2000000 * (a))
/**
* Enumeration rvu_busbar_e
*
* INTERNAL: RVU Bus Base Address Region Enumeration Enumerates the base
* address region for the RVU bus. Internal: This is an enum used in csr3
* virtual equations.
*/
#define RVU_BUSBAR_E_RVU_BUSBAR0 (0)
#define RVU_BUSBAR_E_RVU_BUSBAR2 (0x200000000ll)
/**
* Enumeration rvu_busdid_e
*
* INTERNAL: RVU Bus DID Enumeration Enumerates the DID offset for the
* RVU bus. Internal: This is an enum used in csr3 virtual equations.
*/
#define RVU_BUSDID_E_RVU_BUSDID (0x840000000000ll)
/**
* Enumeration rvu_pf_int_vec_e
*
* RVU PF Interrupt Vector Enumeration Enumerates the MSI-X interrupt
* vectors.
*/
#define RVU_PF_INT_VEC_E_AFPF_MBOX (6)
#define RVU_PF_INT_VEC_E_VFFLRX(a) (0 + (a))
#define RVU_PF_INT_VEC_E_VFMEX(a) (2 + (a))
#define RVU_PF_INT_VEC_E_VFPF_MBOXX(a) (4 + (a))
/**
* Enumeration rvu_vf_int_vec_e
*
* RVU VF Interrupt Vector Enumeration Enumerates the MSI-X interrupt
* vectors.
*/
#define RVU_VF_INT_VEC_E_MBOX (0)
/**
* Structure rvu_af_addr_s
*
* RVU Admin Function Register Address Structure Address format for
* accessing shared Admin Function (AF) registers in RVU PF BAR0. These
* registers may be accessed by all RVU PFs whose
* RVU_PRIV_PF()_CFG[AF_ENA] bit is set.
*/
union rvu_af_addr_s {
u64 u;
struct rvu_af_addr_s_s {
u64 addr : 28;
u64 block : 5;
u64 reserved_33_63 : 31;
} s;
/* struct rvu_af_addr_s_s cn; */
};
/**
* Structure rvu_func_addr_s
*
* RVU Function-unique Address Structure Address format for accessing
* function-unique registers in RVU PF/FUNC BAR2.
*/
union rvu_func_addr_s {
u32 u;
struct rvu_func_addr_s_s {
u32 addr : 12;
u32 lf_slot : 8;
u32 block : 5;
u32 reserved_25_31 : 7;
} s;
/* struct rvu_func_addr_s_s cn; */
};
/**
* Structure rvu_msix_vec_s
*
* RVU MSI-X Vector Structure Format of entries in the RVU MSI-X table
* region in LLC/DRAM. See RVU_PRIV_PF()_MSIX_CFG.
*/
union rvu_msix_vec_s {
u64 u[2];
struct rvu_msix_vec_s_s {
u64 addr : 64;
u64 data : 32;
u64 mask : 1;
u64 pend : 1;
u64 reserved_98_127 : 30;
} s;
/* struct rvu_msix_vec_s_s cn; */
};
/**
* Structure rvu_pf_func_s
*
* RVU PF Function Identification Structure Identifies an RVU PF/VF, and
* format of *_PRIV_LF()_CFG[PF_FUNC] in RVU resource blocks, e.g.
* NPA_PRIV_LF()_CFG[PF_FUNC]. Internal: Also used for PF/VF
* identification on inter-coprocessor hardware interfaces (NPA, SSO,
* CPT, ...).
*/
union rvu_pf_func_s {
u32 u;
struct rvu_pf_func_s_s {
u32 func : 10;
u32 pf : 6;
u32 reserved_16_31 : 16;
} s;
/* struct rvu_pf_func_s_s cn; */
};
/**
* Register (RVU_PF_BAR0) rvu_af_afpf#_mbox#
*
* RVU Admin Function AF/PF Mailbox Registers
*/
union rvu_af_afpfx_mboxx {
u64 u;
struct rvu_af_afpfx_mboxx_s {
u64 data : 64;
} s;
/* struct rvu_af_afpfx_mboxx_s cn; */
};
static inline u64 RVU_AF_AFPFX_MBOXX(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_AFPFX_MBOXX(u64 a, u64 b)
{
return 0x2000 + 0x10 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR0) rvu_af_bar2_alias#
*
* INTERNAL: RVU Admin Function BAR2 Alias Registers These registers
* alias to the RVU BAR2 registers for the PF and function selected by
* RVU_AF_BAR2_SEL[PF_FUNC]. Internal: Not implemented. Placeholder for
* bug33464.
*/
union rvu_af_bar2_aliasx {
u64 u;
struct rvu_af_bar2_aliasx_s {
u64 data : 64;
} s;
/* struct rvu_af_bar2_aliasx_s cn; */
};
static inline u64 RVU_AF_BAR2_ALIASX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_BAR2_ALIASX(u64 a)
{
return 0x9100000 + 8 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_af_bar2_sel
*
* INTERNAL: RVU Admin Function BAR2 Select Register This register
* configures BAR2 accesses from the RVU_AF_BAR2_ALIAS() registers in
* BAR0. Internal: Not implemented. Placeholder for bug33464.
*/
union rvu_af_bar2_sel {
u64 u;
struct rvu_af_bar2_sel_s {
u64 alias_pf_func : 16;
u64 alias_ena : 1;
u64 reserved_17_63 : 47;
} s;
/* struct rvu_af_bar2_sel_s cn; */
};
static inline u64 RVU_AF_BAR2_SEL(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_BAR2_SEL(void)
{
return 0x9000000;
}
/**
* Register (RVU_PF_BAR0) rvu_af_blk_rst
*
* RVU Master Admin Function Block Reset Register
*/
union rvu_af_blk_rst {
u64 u;
struct rvu_af_blk_rst_s {
u64 rst : 1;
u64 reserved_1_62 : 62;
u64 busy : 1;
} s;
/* struct rvu_af_blk_rst_s cn; */
};
static inline u64 RVU_AF_BLK_RST(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_BLK_RST(void)
{
return 0x30;
}
/**
* Register (RVU_PF_BAR0) rvu_af_bp_test
*
* INTERNAL: RVUM Backpressure Test Registers
*/
union rvu_af_bp_test {
u64 u;
struct rvu_af_bp_test_s {
u64 lfsr_freq : 12;
u64 reserved_12_15 : 4;
u64 bp_cfg : 16;
u64 enable : 8;
u64 reserved_40_63 : 24;
} s;
/* struct rvu_af_bp_test_s cn; */
};
static inline u64 RVU_AF_BP_TEST(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_BP_TEST(void)
{
return 0x4000;
}
/**
* Register (RVU_PF_BAR0) rvu_af_eco
*
* INTERNAL: RVU Admin Function ECO Register
*/
union rvu_af_eco {
u64 u;
struct rvu_af_eco_s {
u64 eco_rw : 32;
u64 reserved_32_63 : 32;
} s;
/* struct rvu_af_eco_s cn; */
};
static inline u64 RVU_AF_ECO(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_ECO(void)
{
return 0x20;
}
/**
* Register (RVU_PF_BAR0) rvu_af_gen_int
*
* RVU Admin Function General Interrupt Register This register contains
* General interrupt summary bits.
*/
union rvu_af_gen_int {
u64 u;
struct rvu_af_gen_int_s {
u64 unmapped : 1;
u64 msix_fault : 1;
u64 reserved_2_63 : 62;
} s;
/* struct rvu_af_gen_int_s cn; */
};
static inline u64 RVU_AF_GEN_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_GEN_INT(void)
{
return 0x120;
}
/**
* Register (RVU_PF_BAR0) rvu_af_gen_int_ena_w1c
*
* RVU Admin Function General Interrupt Enable Clear Register This
* register clears interrupt enable bits.
*/
union rvu_af_gen_int_ena_w1c {
u64 u;
struct rvu_af_gen_int_ena_w1c_s {
u64 unmapped : 1;
u64 msix_fault : 1;
u64 reserved_2_63 : 62;
} s;
/* struct rvu_af_gen_int_ena_w1c_s cn; */
};
static inline u64 RVU_AF_GEN_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_GEN_INT_ENA_W1C(void)
{
return 0x138;
}
/**
* Register (RVU_PF_BAR0) rvu_af_gen_int_ena_w1s
*
* RVU Admin Function General Interrupt Enable Set Register This register
* sets interrupt enable bits.
*/
union rvu_af_gen_int_ena_w1s {
u64 u;
struct rvu_af_gen_int_ena_w1s_s {
u64 unmapped : 1;
u64 msix_fault : 1;
u64 reserved_2_63 : 62;
} s;
/* struct rvu_af_gen_int_ena_w1s_s cn; */
};
static inline u64 RVU_AF_GEN_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_GEN_INT_ENA_W1S(void)
{
return 0x130;
}
/**
* Register (RVU_PF_BAR0) rvu_af_gen_int_w1s
*
* RVU Admin Function General Interrupt Set Register This register sets
* interrupt bits.
*/
union rvu_af_gen_int_w1s {
u64 u;
struct rvu_af_gen_int_w1s_s {
u64 unmapped : 1;
u64 msix_fault : 1;
u64 reserved_2_63 : 62;
} s;
/* struct rvu_af_gen_int_w1s_s cn; */
};
static inline u64 RVU_AF_GEN_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_GEN_INT_W1S(void)
{
return 0x128;
}
/**
* Register (RVU_PF_BAR0) rvu_af_hwvf_rst
*
* RVU Admin Function Hardware VF Reset Register
*/
union rvu_af_hwvf_rst {
u64 u;
struct rvu_af_hwvf_rst_s {
u64 hwvf : 8;
u64 reserved_8_11 : 4;
u64 exec : 1;
u64 reserved_13_63 : 51;
} s;
/* struct rvu_af_hwvf_rst_s cn; */
};
static inline u64 RVU_AF_HWVF_RST(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_HWVF_RST(void)
{
return 0x2850;
}
/**
* Register (RVU_PF_BAR0) rvu_af_msixtr_base
*
* RVU Admin Function MSI-X Table Region Base-Address Register
*/
union rvu_af_msixtr_base {
u64 u;
struct rvu_af_msixtr_base_s {
u64 reserved_0_6 : 7;
u64 addr : 46;
u64 reserved_53_63 : 11;
} s;
/* struct rvu_af_msixtr_base_s cn; */
};
static inline u64 RVU_AF_MSIXTR_BASE(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_MSIXTR_BASE(void)
{
return 0x10;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pf#_vf_bar4_addr
*
* RVU Admin Function PF/VF BAR4 Address Registers
*/
union rvu_af_pfx_vf_bar4_addr {
u64 u;
struct rvu_af_pfx_vf_bar4_addr_s {
u64 reserved_0_15 : 16;
u64 addr : 48;
} s;
/* struct rvu_af_pfx_vf_bar4_addr_s cn; */
};
static inline u64 RVU_AF_PFX_VF_BAR4_ADDR(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFX_VF_BAR4_ADDR(u64 a)
{
return 0x1000 + 0x10 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pf_bar4_addr
*
* RVU Admin Function PF BAR4 Address Registers
*/
union rvu_af_pf_bar4_addr {
u64 u;
struct rvu_af_pf_bar4_addr_s {
u64 reserved_0_15 : 16;
u64 addr : 48;
} s;
/* struct rvu_af_pf_bar4_addr_s cn; */
};
static inline u64 RVU_AF_PF_BAR4_ADDR(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PF_BAR4_ADDR(void)
{
return 0x40;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pf_rst
*
* RVU Admin Function PF Reset Register
*/
union rvu_af_pf_rst {
u64 u;
struct rvu_af_pf_rst_s {
u64 pf : 4;
u64 reserved_4_11 : 8;
u64 exec : 1;
u64 reserved_13_63 : 51;
} s;
/* struct rvu_af_pf_rst_s cn; */
};
static inline u64 RVU_AF_PF_RST(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PF_RST(void)
{
return 0x2840;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfaf_mbox_int
*
* RVU Admin Function PF to AF Mailbox Interrupt Registers
*/
union rvu_af_pfaf_mbox_int {
u64 u;
struct rvu_af_pfaf_mbox_int_s {
u64 mbox : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfaf_mbox_int_s cn; */
};
static inline u64 RVU_AF_PFAF_MBOX_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFAF_MBOX_INT(void)
{
return 0x2880;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfaf_mbox_int_ena_w1c
*
* RVU Admin Function PF to AF Mailbox Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union rvu_af_pfaf_mbox_int_ena_w1c {
u64 u;
struct rvu_af_pfaf_mbox_int_ena_w1c_s {
u64 mbox : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfaf_mbox_int_ena_w1c_s cn; */
};
static inline u64 RVU_AF_PFAF_MBOX_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFAF_MBOX_INT_ENA_W1C(void)
{
return 0x2898;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfaf_mbox_int_ena_w1s
*
* RVU Admin Function PF to AF Mailbox Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union rvu_af_pfaf_mbox_int_ena_w1s {
u64 u;
struct rvu_af_pfaf_mbox_int_ena_w1s_s {
u64 mbox : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfaf_mbox_int_ena_w1s_s cn; */
};
static inline u64 RVU_AF_PFAF_MBOX_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFAF_MBOX_INT_ENA_W1S(void)
{
return 0x2890;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfaf_mbox_int_w1s
*
* RVU Admin Function PF to AF Mailbox Interrupt Set Registers This
* register sets interrupt bits.
*/
union rvu_af_pfaf_mbox_int_w1s {
u64 u;
struct rvu_af_pfaf_mbox_int_w1s_s {
u64 mbox : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfaf_mbox_int_w1s_s cn; */
};
static inline u64 RVU_AF_PFAF_MBOX_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFAF_MBOX_INT_W1S(void)
{
return 0x2888;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfflr_int
*
* RVU Admin Function PF Function Level Reset Interrupt Registers
*/
union rvu_af_pfflr_int {
u64 u;
struct rvu_af_pfflr_int_s {
u64 flr : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfflr_int_s cn; */
};
static inline u64 RVU_AF_PFFLR_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFFLR_INT(void)
{
return 0x28a0;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfflr_int_ena_w1c
*
* RVU Admin Function PF Function Level Reset Interrupt Enable Clear
* Registers This register clears interrupt enable bits.
*/
union rvu_af_pfflr_int_ena_w1c {
u64 u;
struct rvu_af_pfflr_int_ena_w1c_s {
u64 flr : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfflr_int_ena_w1c_s cn; */
};
static inline u64 RVU_AF_PFFLR_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFFLR_INT_ENA_W1C(void)
{
return 0x28b8;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfflr_int_ena_w1s
*
* RVU Admin Function PF Function Level Reset Interrupt Enable Set
* Registers This register sets interrupt enable bits.
*/
union rvu_af_pfflr_int_ena_w1s {
u64 u;
struct rvu_af_pfflr_int_ena_w1s_s {
u64 flr : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfflr_int_ena_w1s_s cn; */
};
static inline u64 RVU_AF_PFFLR_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFFLR_INT_ENA_W1S(void)
{
return 0x28b0;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfflr_int_w1s
*
* RVU Admin Function PF Function Level Reset Interrupt Set Registers
* This register sets interrupt bits.
*/
union rvu_af_pfflr_int_w1s {
u64 u;
struct rvu_af_pfflr_int_w1s_s {
u64 flr : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfflr_int_w1s_s cn; */
};
static inline u64 RVU_AF_PFFLR_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFFLR_INT_W1S(void)
{
return 0x28a8;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfme_int
*
* RVU Admin Function PF Bus Master Enable Interrupt Registers
*/
union rvu_af_pfme_int {
u64 u;
struct rvu_af_pfme_int_s {
u64 me : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfme_int_s cn; */
};
static inline u64 RVU_AF_PFME_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFME_INT(void)
{
return 0x28c0;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfme_int_ena_w1c
*
* RVU Admin Function PF Bus Master Enable Interrupt Enable Clear
* Registers This register clears interrupt enable bits.
*/
union rvu_af_pfme_int_ena_w1c {
u64 u;
struct rvu_af_pfme_int_ena_w1c_s {
u64 me : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfme_int_ena_w1c_s cn; */
};
static inline u64 RVU_AF_PFME_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFME_INT_ENA_W1C(void)
{
return 0x28d8;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfme_int_ena_w1s
*
* RVU Admin Function PF Bus Master Enable Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union rvu_af_pfme_int_ena_w1s {
u64 u;
struct rvu_af_pfme_int_ena_w1s_s {
u64 me : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfme_int_ena_w1s_s cn; */
};
static inline u64 RVU_AF_PFME_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFME_INT_ENA_W1S(void)
{
return 0x28d0;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfme_int_w1s
*
* RVU Admin Function PF Bus Master Enable Interrupt Set Registers This
* register sets interrupt bits.
*/
union rvu_af_pfme_int_w1s {
u64 u;
struct rvu_af_pfme_int_w1s_s {
u64 me : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfme_int_w1s_s cn; */
};
static inline u64 RVU_AF_PFME_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFME_INT_W1S(void)
{
return 0x28c8;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pfme_status
*
* RVU Admin Function PF Bus Master Enable Status Registers
*/
union rvu_af_pfme_status {
u64 u;
struct rvu_af_pfme_status_s {
u64 me : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pfme_status_s cn; */
};
static inline u64 RVU_AF_PFME_STATUS(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFME_STATUS(void)
{
return 0x2800;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pftrpend
*
* RVU Admin Function PF Transaction Pending Registers
*/
union rvu_af_pftrpend {
u64 u;
struct rvu_af_pftrpend_s {
u64 trpend : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pftrpend_s cn; */
};
static inline u64 RVU_AF_PFTRPEND(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFTRPEND(void)
{
return 0x2810;
}
/**
* Register (RVU_PF_BAR0) rvu_af_pftrpend_w1s
*
* RVU Admin Function PF Transaction Pending Set Registers This register
* reads or sets bits.
*/
union rvu_af_pftrpend_w1s {
u64 u;
struct rvu_af_pftrpend_w1s_s {
u64 trpend : 16;
u64 reserved_16_63 : 48;
} s;
/* struct rvu_af_pftrpend_w1s_s cn; */
};
static inline u64 RVU_AF_PFTRPEND_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_PFTRPEND_W1S(void)
{
return 0x2820;
}
/**
* Register (RVU_PF_BAR0) rvu_af_ras
*
* RVU Admin Function RAS Interrupt Register This register is intended
* for delivery of RAS events to the SCP, so should be ignored by OS
* drivers.
*/
union rvu_af_ras {
u64 u;
struct rvu_af_ras_s {
u64 msix_poison : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_af_ras_s cn; */
};
static inline u64 RVU_AF_RAS(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_RAS(void)
{
return 0x100;
}
/**
* Register (RVU_PF_BAR0) rvu_af_ras_ena_w1c
*
* RVU Admin Function RAS Interrupt Enable Clear Register This register
* clears interrupt enable bits.
*/
union rvu_af_ras_ena_w1c {
u64 u;
struct rvu_af_ras_ena_w1c_s {
u64 msix_poison : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_af_ras_ena_w1c_s cn; */
};
static inline u64 RVU_AF_RAS_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_RAS_ENA_W1C(void)
{
return 0x118;
}
/**
* Register (RVU_PF_BAR0) rvu_af_ras_ena_w1s
*
* RVU Admin Function RAS Interrupt Enable Set Register This register
* sets interrupt enable bits.
*/
union rvu_af_ras_ena_w1s {
u64 u;
struct rvu_af_ras_ena_w1s_s {
u64 msix_poison : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_af_ras_ena_w1s_s cn; */
};
static inline u64 RVU_AF_RAS_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_RAS_ENA_W1S(void)
{
return 0x110;
}
/**
* Register (RVU_PF_BAR0) rvu_af_ras_w1s
*
* RVU Admin Function RAS Interrupt Set Register This register sets
* interrupt bits.
*/
union rvu_af_ras_w1s {
u64 u;
struct rvu_af_ras_w1s_s {
u64 msix_poison : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_af_ras_w1s_s cn; */
};
static inline u64 RVU_AF_RAS_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_AF_RAS_W1S(void)
{
return 0x108;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_block_addr#_disc
*
* RVU PF Block Address Discovery Registers These registers allow each PF
* driver to discover block resources that are provisioned to its PF. The
* register's BLOCK_ADDR index is enumerated by RVU_BLOCK_ADDR_E.
*/
union rvu_pf_block_addrx_disc {
u64 u;
struct rvu_pf_block_addrx_disc_s {
u64 num_lfs : 9;
u64 reserved_9_10 : 2;
u64 imp : 1;
u64 rid : 8;
u64 btype : 8;
u64 reserved_28_63 : 36;
} s;
/* struct rvu_pf_block_addrx_disc_s cn; */
};
static inline u64 RVU_PF_BLOCK_ADDRX_DISC(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_BLOCK_ADDRX_DISC(u64 a)
{
return 0x200 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_int
*
* RVU PF Interrupt Registers
*/
union rvu_pf_int {
u64 u;
struct rvu_pf_int_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_pf_int_s cn; */
};
static inline u64 RVU_PF_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_INT(void)
{
return 0xc20;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_int_ena_w1c
*
* RVU PF Interrupt Enable Clear Register This register clears interrupt
* enable bits.
*/
union rvu_pf_int_ena_w1c {
u64 u;
struct rvu_pf_int_ena_w1c_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_pf_int_ena_w1c_s cn; */
};
static inline u64 RVU_PF_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_INT_ENA_W1C(void)
{
return 0xc38;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_int_ena_w1s
*
* RVU PF Interrupt Enable Set Register This register sets interrupt
* enable bits.
*/
union rvu_pf_int_ena_w1s {
u64 u;
struct rvu_pf_int_ena_w1s_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_pf_int_ena_w1s_s cn; */
};
static inline u64 RVU_PF_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_INT_ENA_W1S(void)
{
return 0xc30;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_int_w1s
*
* RVU PF Interrupt Set Register This register sets interrupt bits.
*/
union rvu_pf_int_w1s {
u64 u;
struct rvu_pf_int_w1s_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_pf_int_w1s_s cn; */
};
static inline u64 RVU_PF_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_INT_W1S(void)
{
return 0xc28;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_msix_pba#
*
* RVU PF MSI-X Pending-Bit-Array Registers This register is the MSI-X PF
* PBA table.
*/
union rvu_pf_msix_pbax {
u64 u;
struct rvu_pf_msix_pbax_s {
u64 pend : 64;
} s;
/* struct rvu_pf_msix_pbax_s cn; */
};
static inline u64 RVU_PF_MSIX_PBAX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_MSIX_PBAX(u64 a)
{
return 0xf0000 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_msix_vec#_addr
*
* RVU PF MSI-X Vector-Table Address Registers These registers and
* RVU_PF_MSIX_VEC()_CTL form the PF MSI-X vector table. The number of
* MSI-X vectors for a given PF is specified by
* RVU_PRIV_PF()_MSIX_CFG[PF_MSIXT_SIZEM1] (plus 1). Software must do a
* read after any writes to the MSI-X vector table to ensure that the
* writes have completed before interrupts are generated to the modified
* vectors.
*/
union rvu_pf_msix_vecx_addr {
u64 u;
struct rvu_pf_msix_vecx_addr_s {
u64 secvec : 1;
u64 reserved_1 : 1;
u64 addr : 51;
u64 reserved_53_63 : 11;
} s;
/* struct rvu_pf_msix_vecx_addr_s cn; */
};
static inline u64 RVU_PF_MSIX_VECX_ADDR(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_MSIX_VECX_ADDR(u64 a)
{
return 0x80000 + 0x10 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_msix_vec#_ctl
*
* RVU PF MSI-X Vector-Table Control and Data Registers These registers
* and RVU_PF_MSIX_VEC()_ADDR form the PF MSI-X vector table.
*/
union rvu_pf_msix_vecx_ctl {
u64 u;
struct rvu_pf_msix_vecx_ctl_s {
u64 data : 32;
u64 mask : 1;
u64 reserved_33_63 : 31;
} s;
/* struct rvu_pf_msix_vecx_ctl_s cn; */
};
static inline u64 RVU_PF_MSIX_VECX_CTL(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_MSIX_VECX_CTL(u64 a)
{
return 0x80008 + 0x10 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_pfaf_mbox#
*
* RVU PF/AF Mailbox Registers
*/
union rvu_pf_pfaf_mboxx {
u64 u;
struct rvu_pf_pfaf_mboxx_s {
u64 data : 64;
} s;
/* struct rvu_pf_pfaf_mboxx_s cn; */
};
static inline u64 RVU_PF_PFAF_MBOXX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_PFAF_MBOXX(u64 a)
{
return 0xc00 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vf#_pfvf_mbox#
*
* RVU PF/VF Mailbox Registers
*/
union rvu_pf_vfx_pfvf_mboxx {
u64 u;
struct rvu_pf_vfx_pfvf_mboxx_s {
u64 data : 64;
} s;
/* struct rvu_pf_vfx_pfvf_mboxx_s cn; */
};
static inline u64 RVU_PF_VFX_PFVF_MBOXX(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFX_PFVF_MBOXX(u64 a, u64 b)
{
return 0 + 0x1000 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vf_bar4_addr
*
* RVU PF VF BAR4 Address Registers
*/
union rvu_pf_vf_bar4_addr {
u64 u;
struct rvu_pf_vf_bar4_addr_s {
u64 reserved_0_15 : 16;
u64 addr : 48;
} s;
/* struct rvu_pf_vf_bar4_addr_s cn; */
};
static inline u64 RVU_PF_VF_BAR4_ADDR(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VF_BAR4_ADDR(void)
{
return 0x10;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfflr_int#
*
* RVU PF VF Function Level Reset Interrupt Registers
*/
union rvu_pf_vfflr_intx {
u64 u;
struct rvu_pf_vfflr_intx_s {
u64 flr : 64;
} s;
/* struct rvu_pf_vfflr_intx_s cn; */
};
static inline u64 RVU_PF_VFFLR_INTX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFFLR_INTX(u64 a)
{
return 0x900 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfflr_int_ena_w1c#
*
* RVU PF VF Function Level Reset Interrupt Enable Clear Registers This
* register clears interrupt enable bits.
*/
union rvu_pf_vfflr_int_ena_w1cx {
u64 u;
struct rvu_pf_vfflr_int_ena_w1cx_s {
u64 flr : 64;
} s;
/* struct rvu_pf_vfflr_int_ena_w1cx_s cn; */
};
static inline u64 RVU_PF_VFFLR_INT_ENA_W1CX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFFLR_INT_ENA_W1CX(u64 a)
{
return 0x960 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfflr_int_ena_w1s#
*
* RVU PF VF Function Level Reset Interrupt Enable Set Registers This
* register sets interrupt enable bits.
*/
union rvu_pf_vfflr_int_ena_w1sx {
u64 u;
struct rvu_pf_vfflr_int_ena_w1sx_s {
u64 flr : 64;
} s;
/* struct rvu_pf_vfflr_int_ena_w1sx_s cn; */
};
static inline u64 RVU_PF_VFFLR_INT_ENA_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFFLR_INT_ENA_W1SX(u64 a)
{
return 0x940 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfflr_int_w1s#
*
* RVU PF VF Function Level Reset Interrupt Set Registers This register
* sets interrupt bits.
*/
union rvu_pf_vfflr_int_w1sx {
u64 u;
struct rvu_pf_vfflr_int_w1sx_s {
u64 flr : 64;
} s;
/* struct rvu_pf_vfflr_int_w1sx_s cn; */
};
static inline u64 RVU_PF_VFFLR_INT_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFFLR_INT_W1SX(u64 a)
{
return 0x920 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfme_int#
*
* RVU PF VF Bus Master Enable Interrupt Registers
*/
union rvu_pf_vfme_intx {
u64 u;
struct rvu_pf_vfme_intx_s {
u64 me : 64;
} s;
/* struct rvu_pf_vfme_intx_s cn; */
};
static inline u64 RVU_PF_VFME_INTX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFME_INTX(u64 a)
{
return 0x980 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfme_int_ena_w1c#
*
* RVU PF VF Bus Master Enable Interrupt Enable Clear Registers This
* register clears interrupt enable bits.
*/
union rvu_pf_vfme_int_ena_w1cx {
u64 u;
struct rvu_pf_vfme_int_ena_w1cx_s {
u64 me : 64;
} s;
/* struct rvu_pf_vfme_int_ena_w1cx_s cn; */
};
static inline u64 RVU_PF_VFME_INT_ENA_W1CX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFME_INT_ENA_W1CX(u64 a)
{
return 0x9e0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfme_int_ena_w1s#
*
* RVU PF VF Bus Master Enable Interrupt Enable Set Registers This
* register sets interrupt enable bits.
*/
union rvu_pf_vfme_int_ena_w1sx {
u64 u;
struct rvu_pf_vfme_int_ena_w1sx_s {
u64 me : 64;
} s;
/* struct rvu_pf_vfme_int_ena_w1sx_s cn; */
};
static inline u64 RVU_PF_VFME_INT_ENA_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFME_INT_ENA_W1SX(u64 a)
{
return 0x9c0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfme_int_w1s#
*
* RVU PF VF Bus Master Enable Interrupt Set Registers This register sets
* interrupt bits.
*/
union rvu_pf_vfme_int_w1sx {
u64 u;
struct rvu_pf_vfme_int_w1sx_s {
u64 me : 64;
} s;
/* struct rvu_pf_vfme_int_w1sx_s cn; */
};
static inline u64 RVU_PF_VFME_INT_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFME_INT_W1SX(u64 a)
{
return 0x9a0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfme_status#
*
* RVU PF VF Bus Master Enable Status Registers
*/
union rvu_pf_vfme_statusx {
u64 u;
struct rvu_pf_vfme_statusx_s {
u64 me : 64;
} s;
/* struct rvu_pf_vfme_statusx_s cn; */
};
static inline u64 RVU_PF_VFME_STATUSX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFME_STATUSX(u64 a)
{
return 0x800 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfpf_mbox_int#
*
* RVU VF to PF Mailbox Interrupt Registers
*/
union rvu_pf_vfpf_mbox_intx {
u64 u;
struct rvu_pf_vfpf_mbox_intx_s {
u64 mbox : 64;
} s;
/* struct rvu_pf_vfpf_mbox_intx_s cn; */
};
static inline u64 RVU_PF_VFPF_MBOX_INTX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFPF_MBOX_INTX(u64 a)
{
return 0x880 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfpf_mbox_int_ena_w1c#
*
* RVU VF to PF Mailbox Interrupt Enable Clear Registers This register
* clears interrupt enable bits.
*/
union rvu_pf_vfpf_mbox_int_ena_w1cx {
u64 u;
struct rvu_pf_vfpf_mbox_int_ena_w1cx_s {
u64 mbox : 64;
} s;
/* struct rvu_pf_vfpf_mbox_int_ena_w1cx_s cn; */
};
static inline u64 RVU_PF_VFPF_MBOX_INT_ENA_W1CX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFPF_MBOX_INT_ENA_W1CX(u64 a)
{
return 0x8e0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfpf_mbox_int_ena_w1s#
*
* RVU VF to PF Mailbox Interrupt Enable Set Registers This register sets
* interrupt enable bits.
*/
union rvu_pf_vfpf_mbox_int_ena_w1sx {
u64 u;
struct rvu_pf_vfpf_mbox_int_ena_w1sx_s {
u64 mbox : 64;
} s;
/* struct rvu_pf_vfpf_mbox_int_ena_w1sx_s cn; */
};
static inline u64 RVU_PF_VFPF_MBOX_INT_ENA_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFPF_MBOX_INT_ENA_W1SX(u64 a)
{
return 0x8c0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vfpf_mbox_int_w1s#
*
* RVU VF to PF Mailbox Interrupt Set Registers This register sets
* interrupt bits.
*/
union rvu_pf_vfpf_mbox_int_w1sx {
u64 u;
struct rvu_pf_vfpf_mbox_int_w1sx_s {
u64 mbox : 64;
} s;
/* struct rvu_pf_vfpf_mbox_int_w1sx_s cn; */
};
static inline u64 RVU_PF_VFPF_MBOX_INT_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFPF_MBOX_INT_W1SX(u64 a)
{
return 0x8a0 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vftrpend#
*
* RVU PF VF Transaction Pending Registers
*/
union rvu_pf_vftrpendx {
u64 u;
struct rvu_pf_vftrpendx_s {
u64 trpend : 64;
} s;
/* struct rvu_pf_vftrpendx_s cn; */
};
static inline u64 RVU_PF_VFTRPENDX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFTRPENDX(u64 a)
{
return 0x820 + 8 * a;
}
/**
* Register (RVU_PF_BAR2) rvu_pf_vftrpend_w1s#
*
* RVU PF VF Transaction Pending Set Registers This register reads or
* sets bits.
*/
union rvu_pf_vftrpend_w1sx {
u64 u;
struct rvu_pf_vftrpend_w1sx_s {
u64 trpend : 64;
} s;
/* struct rvu_pf_vftrpend_w1sx_s cn; */
};
static inline u64 RVU_PF_VFTRPEND_W1SX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PF_VFTRPEND_W1SX(u64 a)
{
return 0x840 + 8 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_active_pc
*
* RVU Active Program Counter Register
*/
union rvu_priv_active_pc {
u64 u;
struct rvu_priv_active_pc_s {
u64 active_pc : 64;
} s;
/* struct rvu_priv_active_pc_s cn; */
};
static inline u64 RVU_PRIV_ACTIVE_PC(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_ACTIVE_PC(void)
{
return 0x8000030;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_block_type#_rev
*
* RVU Privileged Block Type Revision Registers These registers are used
* by configuration software to specify the revision ID of each block
* type enumerated by RVU_BLOCK_TYPE_E, to assist VF/PF software
* discovery.
*/
union rvu_priv_block_typex_rev {
u64 u;
struct rvu_priv_block_typex_rev_s {
u64 rid : 8;
u64 reserved_8_63 : 56;
} s;
/* struct rvu_priv_block_typex_rev_s cn; */
};
static inline u64 RVU_PRIV_BLOCK_TYPEX_REV(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_BLOCK_TYPEX_REV(u64 a)
{
return 0x8000400 + 8 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_clk_cfg
*
* RVU Privileged General Configuration Register
*/
union rvu_priv_clk_cfg {
u64 u;
struct rvu_priv_clk_cfg_s {
u64 blk_clken : 1;
u64 ncbi_clken : 1;
u64 reserved_2_63 : 62;
} s;
/* struct rvu_priv_clk_cfg_s cn; */
};
static inline u64 RVU_PRIV_CLK_CFG(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_CLK_CFG(void)
{
return 0x8000020;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_const
*
* RVU Privileged Constants Register This register contains constants for
* software discovery.
*/
union rvu_priv_const {
u64 u;
struct rvu_priv_const_s {
u64 max_msix : 20;
u64 hwvfs : 12;
u64 pfs : 8;
u64 max_vfs_per_pf : 8;
u64 reserved_48_63 : 16;
} s;
/* struct rvu_priv_const_s cn; */
};
static inline u64 RVU_PRIV_CONST(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_CONST(void)
{
return 0x8000000;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_gen_cfg
*
* RVU Privileged General Configuration Register
*/
union rvu_priv_gen_cfg {
u64 u;
struct rvu_priv_gen_cfg_s {
u64 lock : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_priv_gen_cfg_s cn; */
};
static inline u64 RVU_PRIV_GEN_CFG(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_GEN_CFG(void)
{
return 0x8000010;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_cpt#_cfg
*
* RVU Privileged Hardware VF CPT Configuration Registers Similar to
* RVU_PRIV_HWVF()_NIX()_CFG, but for CPT({a}) block.
*/
union rvu_priv_hwvfx_cptx_cfg {
u64 u;
struct rvu_priv_hwvfx_cptx_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_hwvfx_cptx_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_CPTX_CFG(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_CPTX_CFG(u64 a, u64 b)
{
return 0x8001350 + 0x10000 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_int_cfg
*
* RVU Privileged Hardware VF Interrupt Configuration Registers
*/
union rvu_priv_hwvfx_int_cfg {
u64 u;
struct rvu_priv_hwvfx_int_cfg_s {
u64 msix_offset : 11;
u64 reserved_11 : 1;
u64 msix_size : 8;
u64 reserved_20_63 : 44;
} s;
/* struct rvu_priv_hwvfx_int_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_INT_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_INT_CFG(u64 a)
{
return 0x8001280 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_nix#_cfg
*
* RVU Privileged Hardware VF NIX Configuration Registers These registers
* are used to assist VF software discovery. For each HWVF, if the HWVF
* is mapped to a VF by RVU_PRIV_PF()_CFG[FIRST_HWVF,NVF], software
* writes NIX block's resource configuration for the VF in this register.
* The VF driver can read RVU_VF_BLOCK_ADDR()_DISC to discover the
* configuration.
*/
union rvu_priv_hwvfx_nixx_cfg {
u64 u;
struct rvu_priv_hwvfx_nixx_cfg_s {
u64 has_lf : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_priv_hwvfx_nixx_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_NIXX_CFG(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_NIXX_CFG(u64 a, u64 b)
{
return 0x8001300 + 0x10000 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_npa_cfg
*
* RVU Privileged Hardware VF NPA Configuration Registers Similar to
* RVU_PRIV_HWVF()_NIX()_CFG, but for NPA block.
*/
union rvu_priv_hwvfx_npa_cfg {
u64 u;
struct rvu_priv_hwvfx_npa_cfg_s {
u64 has_lf : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_priv_hwvfx_npa_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_NPA_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_NPA_CFG(u64 a)
{
return 0x8001310 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_sso_cfg
*
* RVU Privileged Hardware VF SSO Configuration Registers Similar to
* RVU_PRIV_HWVF()_NIX()_CFG, but for SSO block.
*/
union rvu_priv_hwvfx_sso_cfg {
u64 u;
struct rvu_priv_hwvfx_sso_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_hwvfx_sso_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_SSO_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_SSO_CFG(u64 a)
{
return 0x8001320 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_ssow_cfg
*
* RVU Privileged Hardware VF SSO Work Slot Configuration Registers
* Similar to RVU_PRIV_HWVF()_NIX()_CFG, but for SSOW block.
*/
union rvu_priv_hwvfx_ssow_cfg {
u64 u;
struct rvu_priv_hwvfx_ssow_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_hwvfx_ssow_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_SSOW_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_SSOW_CFG(u64 a)
{
return 0x8001330 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_hwvf#_tim_cfg
*
* RVU Privileged Hardware VF SSO Work Slot Configuration Registers
* Similar to RVU_PRIV_HWVF()_NIX()_CFG, but for TIM block.
*/
union rvu_priv_hwvfx_tim_cfg {
u64 u;
struct rvu_priv_hwvfx_tim_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_hwvfx_tim_cfg_s cn; */
};
static inline u64 RVU_PRIV_HWVFX_TIM_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_HWVFX_TIM_CFG(u64 a)
{
return 0x8001340 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_cfg
*
* RVU Privileged PF Configuration Registers
*/
union rvu_priv_pfx_cfg {
u64 u;
struct rvu_priv_pfx_cfg_s {
u64 first_hwvf : 12;
u64 nvf : 8;
u64 ena : 1;
u64 af_ena : 1;
u64 me_flr_ena : 1;
u64 pf_vf_io_bar4 : 1;
u64 reserved_24_63 : 40;
} s;
struct rvu_priv_pfx_cfg_cn96xxp1 {
u64 first_hwvf : 12;
u64 nvf : 8;
u64 ena : 1;
u64 af_ena : 1;
u64 me_flr_ena : 1;
u64 reserved_23_63 : 41;
} cn96xxp1;
/* struct rvu_priv_pfx_cfg_s cn96xxp3; */
/* struct rvu_priv_pfx_cfg_cn96xxp1 cnf95xx; */
};
static inline u64 RVU_PRIV_PFX_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_CFG(u64 a)
{
return 0x8000100 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_cpt#_cfg
*
* RVU Privileged PF CPT Configuration Registers Similar to
* RVU_PRIV_PF()_NIX()_CFG, but for CPT({a}) block.
*/
union rvu_priv_pfx_cptx_cfg {
u64 u;
struct rvu_priv_pfx_cptx_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_pfx_cptx_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_CPTX_CFG(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_CPTX_CFG(u64 a, u64 b)
{
return 0x8000350 + 0x10000 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_id_cfg
*
* RVU Privileged PF ID Configuration Registers
*/
union rvu_priv_pfx_id_cfg {
u64 u;
struct rvu_priv_pfx_id_cfg_s {
u64 pf_devid : 8;
u64 vf_devid : 8;
u64 class_code : 24;
u64 reserved_40_63 : 24;
} s;
/* struct rvu_priv_pfx_id_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_ID_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_ID_CFG(u64 a)
{
return 0x8000120 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_int_cfg
*
* RVU Privileged PF Interrupt Configuration Registers
*/
union rvu_priv_pfx_int_cfg {
u64 u;
struct rvu_priv_pfx_int_cfg_s {
u64 msix_offset : 11;
u64 reserved_11 : 1;
u64 msix_size : 8;
u64 reserved_20_63 : 44;
} s;
/* struct rvu_priv_pfx_int_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_INT_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_INT_CFG(u64 a)
{
return 0x8000200 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_msix_cfg
*
* RVU Privileged PF MSI-X Configuration Registers These registers
* specify MSI-X table sizes and locations for RVU PFs and associated
* VFs. Hardware maintains all RVU MSI-X tables in a contiguous memory
* region in LLC/DRAM called the MSI-X table region. The table region's
* base AF IOVA is specified by RVU_AF_MSIXTR_BASE, and its size as a
* multiple of 16-byte RVU_MSIX_VEC_S structures must be less than or
* equal to RVU_PRIV_CONST[MAX_MSIX]. A PF's MSI-X table consists of the
* following range of RVU_MSIX_VEC_S structures in the table region: *
* First index: [PF_MSIXT_OFFSET]. * Last index: [PF_MSIXT_OFFSET] +
* [PF_MSIXT_SIZEM1]. If a PF has enabled VFs (associated
* RVU_PRIV_PF()_CFG[NVF] is nonzero), then each VF's MSI-X table
* consumes the following range of RVU_MSIX_VEC_S structures: * First
* index: [VF_MSIXT_OFFSET] + N*([VF_MSIXT_SIZEM1] + 1). * Last index:
* [VF_MSIXT_OFFSET] + N*([VF_MSIXT_SIZEM1] + 1) + [VF_MSIXT_SIZEM1].
* N=0 for the first VF, N=1 for the second VF, etc. Different PFs and
* VFs must have non-overlapping vector ranges, and the last index of any
* range must be less than RVU_PRIV_CONST[MAX_MSIX].
*/
union rvu_priv_pfx_msix_cfg {
u64 u;
struct rvu_priv_pfx_msix_cfg_s {
u64 vf_msixt_sizem1 : 12;
u64 vf_msixt_offset : 20;
u64 pf_msixt_sizem1 : 12;
u64 pf_msixt_offset : 20;
} s;
/* struct rvu_priv_pfx_msix_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_MSIX_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_MSIX_CFG(u64 a)
{
return 0x8000110 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_nix#_cfg
*
* RVU Privileged PF NIX Configuration Registers These registers are used
* to assist PF software discovery. For each enabled RVU PF, software
* writes the block's resource configuration for the PF in this register.
* The PF driver can read RVU_PF_BLOCK_ADDR()_DISC to discover the
* configuration.
*/
union rvu_priv_pfx_nixx_cfg {
u64 u;
struct rvu_priv_pfx_nixx_cfg_s {
u64 has_lf : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_priv_pfx_nixx_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_NIXX_CFG(u64 a, u64 b)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_NIXX_CFG(u64 a, u64 b)
{
return 0x8000300 + 0x10000 * a + 8 * b;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_npa_cfg
*
* RVU Privileged PF NPA Configuration Registers Similar to
* RVU_PRIV_PF()_NIX()_CFG, but for NPA block.
*/
union rvu_priv_pfx_npa_cfg {
u64 u;
struct rvu_priv_pfx_npa_cfg_s {
u64 has_lf : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_priv_pfx_npa_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_NPA_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_NPA_CFG(u64 a)
{
return 0x8000310 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_sso_cfg
*
* RVU Privileged PF SSO Configuration Registers Similar to
* RVU_PRIV_PF()_NIX()_CFG, but for SSO block.
*/
union rvu_priv_pfx_sso_cfg {
u64 u;
struct rvu_priv_pfx_sso_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_pfx_sso_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_SSO_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_SSO_CFG(u64 a)
{
return 0x8000320 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_ssow_cfg
*
* RVU Privileged PF SSO Work Slot Configuration Registers Similar to
* RVU_PRIV_PF()_NIX()_CFG, but for SSOW block.
*/
union rvu_priv_pfx_ssow_cfg {
u64 u;
struct rvu_priv_pfx_ssow_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_pfx_ssow_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_SSOW_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_SSOW_CFG(u64 a)
{
return 0x8000330 + 0x10000 * a;
}
/**
* Register (RVU_PF_BAR0) rvu_priv_pf#_tim_cfg
*
* RVU Privileged PF SSO Work Slot Configuration Registers Similar to
* RVU_PRIV_PF()_NIX()_CFG, but for TIM block.
*/
union rvu_priv_pfx_tim_cfg {
u64 u;
struct rvu_priv_pfx_tim_cfg_s {
u64 num_lfs : 9;
u64 reserved_9_63 : 55;
} s;
/* struct rvu_priv_pfx_tim_cfg_s cn; */
};
static inline u64 RVU_PRIV_PFX_TIM_CFG(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_PRIV_PFX_TIM_CFG(u64 a)
{
return 0x8000340 + 0x10000 * a;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_block_addr#_disc
*
* RVU VF Block Address Discovery Registers These registers allow each VF
* driver to discover block resources that are provisioned to its VF. The
* register's BLOCK_ADDR index is enumerated by RVU_BLOCK_ADDR_E.
*/
union rvu_vf_block_addrx_disc {
u64 u;
struct rvu_vf_block_addrx_disc_s {
u64 num_lfs : 9;
u64 reserved_9_10 : 2;
u64 imp : 1;
u64 rid : 8;
u64 btype : 8;
u64 reserved_28_63 : 36;
} s;
/* struct rvu_vf_block_addrx_disc_s cn; */
};
static inline u64 RVU_VF_BLOCK_ADDRX_DISC(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_BLOCK_ADDRX_DISC(u64 a)
{
return 0x200 + 8 * a;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_int
*
* RVU VF Interrupt Registers
*/
union rvu_vf_int {
u64 u;
struct rvu_vf_int_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_vf_int_s cn; */
};
static inline u64 RVU_VF_INT(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_INT(void)
{
return 0x20;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_int_ena_w1c
*
* RVU VF Interrupt Enable Clear Register This register clears interrupt
* enable bits.
*/
union rvu_vf_int_ena_w1c {
u64 u;
struct rvu_vf_int_ena_w1c_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_vf_int_ena_w1c_s cn; */
};
static inline u64 RVU_VF_INT_ENA_W1C(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_INT_ENA_W1C(void)
{
return 0x38;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_int_ena_w1s
*
* RVU VF Interrupt Enable Set Register This register sets interrupt
* enable bits.
*/
union rvu_vf_int_ena_w1s {
u64 u;
struct rvu_vf_int_ena_w1s_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_vf_int_ena_w1s_s cn; */
};
static inline u64 RVU_VF_INT_ENA_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_INT_ENA_W1S(void)
{
return 0x30;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_int_w1s
*
* RVU VF Interrupt Set Register This register sets interrupt bits.
*/
union rvu_vf_int_w1s {
u64 u;
struct rvu_vf_int_w1s_s {
u64 mbox : 1;
u64 reserved_1_63 : 63;
} s;
/* struct rvu_vf_int_w1s_s cn; */
};
static inline u64 RVU_VF_INT_W1S(void)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_INT_W1S(void)
{
return 0x28;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_msix_pba#
*
* RVU VF MSI-X Pending-Bit-Array Registers This register is the MSI-X VF
* PBA table.
*/
union rvu_vf_msix_pbax {
u64 u;
struct rvu_vf_msix_pbax_s {
u64 pend : 64;
} s;
/* struct rvu_vf_msix_pbax_s cn; */
};
static inline u64 RVU_VF_MSIX_PBAX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_MSIX_PBAX(u64 a)
{
return 0xf0000 + 8 * a;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_msix_vec#_addr
*
* RVU VF MSI-X Vector-Table Address Registers These registers and
* RVU_VF_MSIX_VEC()_CTL form the VF MSI-X vector table. The number of
* MSI-X vectors for a given VF is specified by
* RVU_PRIV_PF()_MSIX_CFG[VF_MSIXT_SIZEM1] (plus 1). Software must do a
* read after any writes to the MSI-X vector table to ensure that the
* writes have completed before interrupts are generated to the modified
* vectors.
*/
union rvu_vf_msix_vecx_addr {
u64 u;
struct rvu_vf_msix_vecx_addr_s {
u64 secvec : 1;
u64 reserved_1 : 1;
u64 addr : 51;
u64 reserved_53_63 : 11;
} s;
/* struct rvu_vf_msix_vecx_addr_s cn; */
};
static inline u64 RVU_VF_MSIX_VECX_ADDR(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_MSIX_VECX_ADDR(u64 a)
{
return 0x80000 + 0x10 * a;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_msix_vec#_ctl
*
* RVU VF MSI-X Vector-Table Control and Data Registers These registers
* and RVU_VF_MSIX_VEC()_ADDR form the VF MSI-X vector table.
*/
union rvu_vf_msix_vecx_ctl {
u64 u;
struct rvu_vf_msix_vecx_ctl_s {
u64 data : 32;
u64 mask : 1;
u64 reserved_33_63 : 31;
} s;
/* struct rvu_vf_msix_vecx_ctl_s cn; */
};
static inline u64 RVU_VF_MSIX_VECX_CTL(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_MSIX_VECX_CTL(u64 a)
{
return 0x80008 + 0x10 * a;
}
/**
* Register (RVU_VF_BAR2) rvu_vf_vfpf_mbox#
*
* RVU VF/PF Mailbox Registers
*/
union rvu_vf_vfpf_mboxx {
u64 u;
struct rvu_vf_vfpf_mboxx_s {
u64 data : 64;
} s;
/* struct rvu_vf_vfpf_mboxx_s cn; */
};
static inline u64 RVU_VF_VFPF_MBOXX(u64 a)
__attribute__ ((pure, always_inline));
static inline u64 RVU_VF_VFPF_MBOXX(u64 a)
{
return 0 + 8 * a;
}
#endif /* __CSRS_RVU_H__ */