/* SPDX-License-Identifier: BSD-3-Clause */ /* Copyright(c) 2007-2022 Intel Corporation */ /* $FreeBSD$ */ #ifndef ADF_ACCEL_DEVICES_H_ #define ADF_ACCEL_DEVICES_H_ #include "qat_freebsd.h" #include "adf_cfg_common.h" #define ADF_CFG_NUM_SERVICES 4 #define ADF_DH895XCC_DEVICE_NAME "dh895xcc" #define ADF_DH895XCCVF_DEVICE_NAME "dh895xccvf" #define ADF_C62X_DEVICE_NAME "c6xx" #define ADF_C62XVF_DEVICE_NAME "c6xxvf" #define ADF_C3XXX_DEVICE_NAME "c3xxx" #define ADF_C3XXXVF_DEVICE_NAME "c3xxxvf" #define ADF_200XX_DEVICE_NAME "200xx" #define ADF_200XXVF_DEVICE_NAME "200xxvf" #define ADF_C4XXX_DEVICE_NAME "c4xxx" #define ADF_C4XXXVF_DEVICE_NAME "c4xxxvf" #define ADF_4XXX_DEVICE_NAME "4xxx" #define ADF_DH895XCC_PCI_DEVICE_ID 0x435 #define ADF_DH895XCCIOV_PCI_DEVICE_ID 0x443 #define ADF_C62X_PCI_DEVICE_ID 0x37c8 #define ADF_C62XIOV_PCI_DEVICE_ID 0x37c9 #define ADF_C3XXX_PCI_DEVICE_ID 0x19e2 #define ADF_C3XXXIOV_PCI_DEVICE_ID 0x19e3 #define ADF_200XX_PCI_DEVICE_ID 0x18ee #define ADF_200XXIOV_PCI_DEVICE_ID 0x18ef #define ADF_D15XX_PCI_DEVICE_ID 0x6f54 #define ADF_D15XXIOV_PCI_DEVICE_ID 0x6f55 #define ADF_C4XXX_PCI_DEVICE_ID 0x18a0 #define ADF_C4XXXIOV_PCI_DEVICE_ID 0x18a1 #define ADF_4XXX_PCI_DEVICE_ID 0x4940 #define ADF_401XX_PCI_DEVICE_ID 0x4942 #define IS_QAT_GEN3(ID) ({ (ID == ADF_C4XXX_PCI_DEVICE_ID); }) static inline bool IS_QAT_GEN4(const unsigned int id) { return (id == ADF_4XXX_PCI_DEVICE_ID || id == ADF_401XX_PCI_DEVICE_ID); } #define IS_QAT_GEN3_OR_GEN4(ID) (IS_QAT_GEN3(ID) || IS_QAT_GEN4(ID)) #define ADF_VF2PF_SET_SIZE 32 #define ADF_MAX_VF2PF_SET 4 #define ADF_VF2PF_SET_OFFSET(set_nr) ((set_nr)*ADF_VF2PF_SET_SIZE) #define ADF_VF2PF_VFNR_TO_SET(vf_nr) ((vf_nr) / ADF_VF2PF_SET_SIZE) #define ADF_VF2PF_VFNR_TO_MASK(vf_nr) \ ({ \ u32 vf_nr_ = (vf_nr); \ BIT((vf_nr_)-ADF_VF2PF_SET_SIZE *ADF_VF2PF_VFNR_TO_SET( \ vf_nr_)); \ }) #define ADF_DEVICE_FUSECTL_OFFSET 0x40 #define ADF_DEVICE_LEGFUSE_OFFSET 0x4C #define ADF_DEVICE_FUSECTL_MASK 0x80000000 #define ADF_PCI_MAX_BARS 3 #define ADF_DEVICE_NAME_LENGTH 32 #define ADF_ETR_MAX_RINGS_PER_BANK 16 #define ADF_MAX_MSIX_VECTOR_NAME 32 #define ADF_DEVICE_NAME_PREFIX "qat_" #define ADF_STOP_RETRY 50 #define ADF_NUM_THREADS_PER_AE (8) #define ADF_AE_ADMIN_THREAD (7) #define ADF_NUM_PKE_STRAND (2) #define ADF_AE_STRAND0_THREAD (8) #define ADF_AE_STRAND1_THREAD (9) #define ADF_CFG_NUM_SERVICES 4 #define ADF_SRV_TYPE_BIT_LEN 3 #define ADF_SRV_TYPE_MASK 0x7 #define ADF_RINGS_PER_SRV_TYPE 2 #define ADF_THRD_ABILITY_BIT_LEN 4 #define ADF_THRD_ABILITY_MASK 0xf #define ADF_VF_OFFSET 0x8 #define ADF_MAX_FUNC_PER_DEV 0x7 #define ADF_PCI_DEV_OFFSET 0x3 #define ADF_SRV_TYPE_BIT_LEN 3 #define ADF_SRV_TYPE_MASK 0x7 #define GET_SRV_TYPE(ena_srv_mask, srv) \ (((ena_srv_mask) >> (ADF_SRV_TYPE_BIT_LEN * (srv))) & ADF_SRV_TYPE_MASK) #define GET_CSR_OPS(accel_dev) (&(accel_dev)->hw_device->csr_info.csr_ops) #define ADF_DEFAULT_RING_TO_SRV_MAP \ (CRYPTO | CRYPTO << ADF_CFG_SERV_RING_PAIR_1_SHIFT | \ NA << ADF_CFG_SERV_RING_PAIR_2_SHIFT | \ COMP << ADF_CFG_SERV_RING_PAIR_3_SHIFT) enum adf_accel_capabilities { ADF_ACCEL_CAPABILITIES_NULL = 0, ADF_ACCEL_CAPABILITIES_CRYPTO_SYMMETRIC = 1, ADF_ACCEL_CAPABILITIES_CRYPTO_ASYMMETRIC = 2, ADF_ACCEL_CAPABILITIES_CIPHER = 4, ADF_ACCEL_CAPABILITIES_AUTHENTICATION = 8, ADF_ACCEL_CAPABILITIES_COMPRESSION = 32, ADF_ACCEL_CAPABILITIES_DEPRECATED = 64, ADF_ACCEL_CAPABILITIES_RANDOM_NUMBER = 128 }; struct adf_bar { rman_res_t base_addr; struct resource *virt_addr; rman_res_t size; } __packed; struct adf_accel_msix { struct msix_entry *entries; u32 num_entries; } __packed; struct adf_accel_pci { device_t pci_dev; struct adf_accel_msix msix_entries; struct adf_bar pci_bars[ADF_PCI_MAX_BARS]; uint8_t revid; uint8_t sku; int node; } __packed; enum dev_state { DEV_DOWN = 0, DEV_UP }; enum dev_sku_info { DEV_SKU_1 = 0, DEV_SKU_2, DEV_SKU_3, DEV_SKU_4, DEV_SKU_VF, DEV_SKU_1_CY, DEV_SKU_2_CY, DEV_SKU_3_CY, DEV_SKU_UNKNOWN }; static inline const char * get_sku_info(enum dev_sku_info info) { switch (info) { case DEV_SKU_1: return "SKU1"; case DEV_SKU_1_CY: return "SKU1CY"; case DEV_SKU_2: return "SKU2"; case DEV_SKU_2_CY: return "SKU2CY"; case DEV_SKU_3: return "SKU3"; case DEV_SKU_3_CY: return "SKU3CY"; case DEV_SKU_4: return "SKU4"; case DEV_SKU_VF: return "SKUVF"; case DEV_SKU_UNKNOWN: default: break; } return "Unknown SKU"; } enum adf_accel_unit_services { ADF_ACCEL_SERVICE_NULL = 0, ADF_ACCEL_INLINE_CRYPTO = 1, ADF_ACCEL_CRYPTO = 2, ADF_ACCEL_COMPRESSION = 4, ADF_ACCEL_ASYM = 8, ADF_ACCEL_ADMIN = 16 }; struct adf_ae_info { u32 num_asym_thd; u32 num_sym_thd; u32 num_dc_thd; } __packed; struct adf_accel_unit { u8 au_mask; u32 accel_mask; u64 ae_mask; u64 comp_ae_mask; u32 num_ae; enum adf_accel_unit_services services; } __packed; struct adf_accel_unit_info { u32 inline_ingress_msk; u32 inline_egress_msk; u32 sym_ae_msk; u32 asym_ae_msk; u32 dc_ae_msk; u8 num_cy_au; u8 num_dc_au; u8 num_asym_au; u8 num_inline_au; struct adf_accel_unit *au; const struct adf_ae_info *ae_info; } __packed; struct adf_hw_aram_info { /* Inline Egress mask. "1" = AE is working with egress traffic */ u32 inline_direction_egress_mask; /* Inline congestion managmenet profiles set in config file */ u32 inline_congest_mngt_profile; /* Initialise CY AE mask, "1" = AE is used for CY operations */ u32 cy_ae_mask; /* Initialise DC AE mask, "1" = AE is used for DC operations */ u32 dc_ae_mask; /* Number of long words used to define the ARAM regions */ u32 num_aram_lw_entries; /* ARAM region definitions */ u32 mmp_region_size; u32 mmp_region_offset; u32 skm_region_size; u32 skm_region_offset; /* * Defines size and offset of compression intermediate buffers stored * in ARAM (device's on-chip memory). */ u32 inter_buff_aram_region_size; u32 inter_buff_aram_region_offset; u32 sadb_region_size; u32 sadb_region_offset; } __packed; struct adf_hw_device_class { const char *name; const enum adf_device_type type; uint32_t instances; } __packed; struct arb_info { u32 arbiter_offset; u32 wrk_thd_2_srv_arb_map; u32 wrk_cfg_offset; } __packed; struct admin_info { u32 admin_msg_ur; u32 admin_msg_lr; u32 mailbox_offset; } __packed; struct adf_hw_csr_ops { u64 (*build_csr_ring_base_addr)(bus_addr_t addr, u32 size); u32 (*read_csr_ring_head)(struct resource *csr_base_addr, u32 bank, u32 ring); void (*write_csr_ring_head)(struct resource *csr_base_addr, u32 bank, u32 ring, u32 value); u32 (*read_csr_ring_tail)(struct resource *csr_base_addr, u32 bank, u32 ring); void (*write_csr_ring_tail)(struct resource *csr_base_addr, u32 bank, u32 ring, u32 value); u32 (*read_csr_e_stat)(struct resource *csr_base_addr, u32 bank); void (*write_csr_ring_config)(struct resource *csr_base_addr, u32 bank, u32 ring, u32 value); void (*write_csr_ring_base)(struct resource *csr_base_addr, u32 bank, u32 ring, bus_addr_t addr); void (*write_csr_int_flag)(struct resource *csr_base_addr, u32 bank, u32 value); void (*write_csr_int_srcsel)(struct resource *csr_base_addr, u32 bank); void (*write_csr_int_col_en)(struct resource *csr_base_addr, u32 bank, u32 value); void (*write_csr_int_col_ctl)(struct resource *csr_base_addr, u32 bank, u32 value); void (*write_csr_int_flag_and_col)(struct resource *csr_base_addr, u32 bank, u32 value); u32 (*read_csr_ring_srv_arb_en)(struct resource *csr_base_addr, u32 bank); void (*write_csr_ring_srv_arb_en)(struct resource *csr_base_addr, u32 bank, u32 value); }; struct adf_hw_csr_info { struct adf_hw_csr_ops csr_ops; u32 csr_addr_offset; u32 ring_bundle_size; u32 bank_int_flag_clear_mask; u32 num_rings_per_int_srcsel; u32 arb_enable_mask; }; struct adf_cfg_device_data; struct adf_accel_dev; struct adf_etr_data; struct adf_etr_ring_data; struct adf_hw_device_data { struct adf_hw_device_class *dev_class; uint32_t (*get_accel_mask)(struct adf_accel_dev *accel_dev); uint32_t (*get_ae_mask)(struct adf_accel_dev *accel_dev); uint32_t (*get_sram_bar_id)(struct adf_hw_device_data *self); uint32_t (*get_misc_bar_id)(struct adf_hw_device_data *self); uint32_t (*get_etr_bar_id)(struct adf_hw_device_data *self); uint32_t (*get_num_aes)(struct adf_hw_device_data *self); uint32_t (*get_num_accels)(struct adf_hw_device_data *self); void (*notify_and_wait_ethernet)(struct adf_accel_dev *accel_dev); bool (*get_eth_doorbell_msg)(struct adf_accel_dev *accel_dev); uint32_t (*get_pf2vf_offset)(uint32_t i); uint32_t (*get_vintmsk_offset)(uint32_t i); u32 (*get_vintsou_offset)(void); void (*get_arb_info)(struct arb_info *arb_csrs_info); void (*get_admin_info)(struct admin_info *admin_csrs_info); void (*get_errsou_offset)(u32 *errsou3, u32 *errsou5); uint32_t (*get_num_accel_units)(struct adf_hw_device_data *self); int (*init_accel_units)(struct adf_accel_dev *accel_dev); void (*exit_accel_units)(struct adf_accel_dev *accel_dev); uint32_t (*get_clock_speed)(struct adf_hw_device_data *self); enum dev_sku_info (*get_sku)(struct adf_hw_device_data *self); bool (*check_prod_sku)(struct adf_accel_dev *accel_dev); int (*alloc_irq)(struct adf_accel_dev *accel_dev); void (*free_irq)(struct adf_accel_dev *accel_dev); void (*enable_error_correction)(struct adf_accel_dev *accel_dev); int (*check_uncorrectable_error)(struct adf_accel_dev *accel_dev); void (*print_err_registers)(struct adf_accel_dev *accel_dev); void (*disable_error_interrupts)(struct adf_accel_dev *accel_dev); int (*init_ras)(struct adf_accel_dev *accel_dev); void (*exit_ras)(struct adf_accel_dev *accel_dev); void (*disable_arb)(struct adf_accel_dev *accel_dev); void (*update_ras_errors)(struct adf_accel_dev *accel_dev, int error); bool (*ras_interrupts)(struct adf_accel_dev *accel_dev, bool *reset_required); int (*init_admin_comms)(struct adf_accel_dev *accel_dev); void (*exit_admin_comms)(struct adf_accel_dev *accel_dev); int (*send_admin_init)(struct adf_accel_dev *accel_dev); void (*set_asym_rings_mask)(struct adf_accel_dev *accel_dev); int (*get_ring_to_svc_map)(struct adf_accel_dev *accel_dev, u16 *ring_to_svc_map); uint32_t (*get_accel_cap)(struct adf_accel_dev *accel_dev); int (*init_arb)(struct adf_accel_dev *accel_dev); void (*exit_arb)(struct adf_accel_dev *accel_dev); void (*get_arb_mapping)(struct adf_accel_dev *accel_dev, const uint32_t **cfg); int (*init_device)(struct adf_accel_dev *accel_dev); int (*get_heartbeat_status)(struct adf_accel_dev *accel_dev); uint32_t (*get_ae_clock)(struct adf_hw_device_data *self); uint32_t (*get_hb_clock)(struct adf_hw_device_data *self); void (*disable_iov)(struct adf_accel_dev *accel_dev); void (*configure_iov_threads)(struct adf_accel_dev *accel_dev, bool enable); void (*enable_ints)(struct adf_accel_dev *accel_dev); bool (*check_slice_hang)(struct adf_accel_dev *accel_dev); int (*set_ssm_wdtimer)(struct adf_accel_dev *accel_dev); int (*enable_vf2pf_comms)(struct adf_accel_dev *accel_dev); int (*disable_vf2pf_comms)(struct adf_accel_dev *accel_dev); void (*reset_device)(struct adf_accel_dev *accel_dev); void (*reset_hw_units)(struct adf_accel_dev *accel_dev); int (*measure_clock)(struct adf_accel_dev *accel_dev); void (*restore_device)(struct adf_accel_dev *accel_dev); uint32_t (*get_obj_cfg_ae_mask)(struct adf_accel_dev *accel_dev, enum adf_accel_unit_services services); enum adf_accel_unit_services ( *get_service_type)(struct adf_accel_dev *accel_dev, s32 obj_num); int (*add_pke_stats)(struct adf_accel_dev *accel_dev); void (*remove_pke_stats)(struct adf_accel_dev *accel_dev); int (*add_misc_error)(struct adf_accel_dev *accel_dev); int (*count_ras_event)(struct adf_accel_dev *accel_dev, u32 *ras_event, char *aeidstr); void (*remove_misc_error)(struct adf_accel_dev *accel_dev); int (*configure_accel_units)(struct adf_accel_dev *accel_dev); uint32_t (*get_objs_num)(struct adf_accel_dev *accel_dev); const char *(*get_obj_name)(struct adf_accel_dev *accel_dev, enum adf_accel_unit_services services); void (*pre_reset)(struct adf_accel_dev *accel_dev); void (*post_reset)(struct adf_accel_dev *accel_dev); void (*set_msix_rttable)(struct adf_accel_dev *accel_dev); void (*get_ring_svc_map_data)(int ring_pair_index, u16 ring_to_svc_map, u8 *serv_type, int *ring_index, int *num_rings_per_srv, int bundle_num); struct adf_hw_csr_info csr_info; const char *fw_name; const char *fw_mmp_name; bool reset_ack; uint32_t fuses; uint32_t accel_capabilities_mask; uint32_t instance_id; uint16_t accel_mask; u32 aerucm_mask; u32 ae_mask; u32 admin_ae_mask; u32 service_mask; u32 service_to_load_mask; u32 heartbeat_ctr_num; uint16_t tx_rings_mask; uint8_t tx_rx_gap; uint8_t num_banks; u8 num_rings_per_bank; uint8_t num_accel; uint8_t num_logical_accel; uint8_t num_engines; uint8_t min_iov_compat_ver; int (*get_storage_enabled)(struct adf_accel_dev *accel_dev, uint32_t *storage_enabled); u8 query_storage_cap; u32 clock_frequency; u8 storage_enable; u32 extended_dc_capabilities; int (*config_device)(struct adf_accel_dev *accel_dev); u16 asym_rings_mask; int (*get_fw_image_type)(struct adf_accel_dev *accel_dev, enum adf_cfg_fw_image_type *fw_image_type); u16 ring_to_svc_map; } __packed; /* helper enum for performing CSR operations */ enum operation { AND, OR, }; /* 32-bit CSR write macro */ #define ADF_CSR_WR(csr_base, csr_offset, val) \ bus_write_4(csr_base, csr_offset, val) /* 64-bit CSR write macro */ #ifdef __x86_64__ #define ADF_CSR_WR64(csr_base, csr_offset, val) \ bus_write_8(csr_base, csr_offset, val) #else static __inline void adf_csr_wr64(struct resource *csr_base, bus_size_t offset, uint64_t value) { bus_write_4(csr_base, offset, (uint32_t)value); bus_write_4(csr_base, offset + 4, (uint32_t)(value >> 32)); } #define ADF_CSR_WR64(csr_base, csr_offset, val) \ adf_csr_wr64(csr_base, csr_offset, val) #endif /* 32-bit CSR read macro */ #define ADF_CSR_RD(csr_base, csr_offset) bus_read_4(csr_base, csr_offset) /* 64-bit CSR read macro */ #ifdef __x86_64__ #define ADF_CSR_RD64(csr_base, csr_offset) bus_read_8(csr_base, csr_offset) #else static __inline uint64_t adf_csr_rd64(struct resource *csr_base, bus_size_t offset) { return (((uint64_t)bus_read_4(csr_base, offset)) | (((uint64_t)bus_read_4(csr_base, offset + 4)) << 32)); } #define ADF_CSR_RD64(csr_base, csr_offset) adf_csr_rd64(csr_base, csr_offset) #endif #define GET_DEV(accel_dev) ((accel_dev)->accel_pci_dev.pci_dev) #define GET_BARS(accel_dev) ((accel_dev)->accel_pci_dev.pci_bars) #define GET_HW_DATA(accel_dev) (accel_dev->hw_device) #define GET_MAX_BANKS(accel_dev) (GET_HW_DATA(accel_dev)->num_banks) #define GET_DEV_SKU(accel_dev) (accel_dev->accel_pci_dev.sku) #define GET_NUM_RINGS_PER_BANK(accel_dev) \ (GET_HW_DATA(accel_dev)->num_rings_per_bank) #define GET_MAX_ACCELENGINES(accel_dev) (GET_HW_DATA(accel_dev)->num_engines) #define accel_to_pci_dev(accel_ptr) accel_ptr->accel_pci_dev.pci_dev #define GET_SRV_TYPE(ena_srv_mask, srv) \ (((ena_srv_mask) >> (ADF_SRV_TYPE_BIT_LEN * (srv))) & ADF_SRV_TYPE_MASK) #define SET_ASYM_MASK(asym_mask, srv) \ ({ \ typeof(srv) srv_ = (srv); \ (asym_mask) |= ((1 << (srv_)*ADF_RINGS_PER_SRV_TYPE) | \ (1 << ((srv_)*ADF_RINGS_PER_SRV_TYPE + 1))); \ }) #define GET_NUM_RINGS_PER_BANK(accel_dev) \ (GET_HW_DATA(accel_dev)->num_rings_per_bank) #define GET_MAX_PROCESSES(accel_dev) \ ({ \ typeof(accel_dev) dev = (accel_dev); \ (GET_MAX_BANKS(dev) * (GET_NUM_RINGS_PER_BANK(dev) / 2)); \ }) #define GET_DU_TABLE(accel_dev) (accel_dev->du_table) static inline void adf_csr_fetch_and_and(struct resource *csr, size_t offs, unsigned long mask) { unsigned int val = ADF_CSR_RD(csr, offs); val &= mask; ADF_CSR_WR(csr, offs, val); } static inline void adf_csr_fetch_and_or(struct resource *csr, size_t offs, unsigned long mask) { unsigned int val = ADF_CSR_RD(csr, offs); val |= mask; ADF_CSR_WR(csr, offs, val); } static inline void adf_csr_fetch_and_update(enum operation op, struct resource *csr, size_t offs, unsigned long mask) { switch (op) { case AND: adf_csr_fetch_and_and(csr, offs, mask); break; case OR: adf_csr_fetch_and_or(csr, offs, mask); break; } } struct pfvf_stats { struct dentry *stats_file; /* Messages put in CSR */ unsigned int tx; /* Messages read from CSR */ unsigned int rx; /* Interrupt fired but int bit was clear */ unsigned int spurious; /* Block messages sent */ unsigned int blk_tx; /* Block messages received */ unsigned int blk_rx; /* Blocks received with CRC errors */ unsigned int crc_err; /* CSR in use by other side */ unsigned int busy; /* Receiver did not acknowledge */ unsigned int no_ack; /* Collision detected */ unsigned int collision; /* Couldn't send a response */ unsigned int tx_timeout; /* Didn't receive a response */ unsigned int rx_timeout; /* Responses received */ unsigned int rx_rsp; /* Messages re-transmitted */ unsigned int retry; /* Event put timeout */ unsigned int event_timeout; }; #define NUM_PFVF_COUNTERS 14 void adf_get_admin_info(struct admin_info *admin_csrs_info); struct adf_admin_comms { bus_addr_t phy_addr; bus_addr_t const_tbl_addr; bus_addr_t aram_map_phys_addr; bus_addr_t phy_hb_addr; bus_dmamap_t aram_map; bus_dmamap_t const_tbl_map; bus_dmamap_t hb_map; char *virt_addr; char *virt_hb_addr; struct resource *mailbox_addr; struct sx lock; struct bus_dmamem dma_mem; struct bus_dmamem dma_hb; }; struct icp_qat_fw_loader_handle; struct adf_fw_loader_data { struct icp_qat_fw_loader_handle *fw_loader; const struct firmware *uof_fw; const struct firmware *mmp_fw; }; struct adf_accel_vf_info { struct adf_accel_dev *accel_dev; struct mutex pf2vf_lock; /* protect CSR access for PF2VF messages */ u32 vf_nr; bool init; u8 compat_ver; struct pfvf_stats pfvf_counters; }; struct adf_fw_versions { u8 fw_version_major; u8 fw_version_minor; u8 fw_version_patch; u8 mmp_version_major; u8 mmp_version_minor; u8 mmp_version_patch; }; #define ADF_COMPAT_CHECKER_MAX 8 typedef int (*adf_iov_compat_checker_t)(struct adf_accel_dev *accel_dev, u8 vf_compat_ver); struct adf_accel_compat_manager { u8 num_chker; adf_iov_compat_checker_t iov_compat_checkers[ADF_COMPAT_CHECKER_MAX]; }; struct adf_heartbeat; struct adf_accel_dev { struct adf_hw_aram_info *aram_info; struct adf_accel_unit_info *au_info; struct adf_etr_data *transport; struct adf_hw_device_data *hw_device; struct adf_cfg_device_data *cfg; struct adf_fw_loader_data *fw_loader; struct adf_admin_comms *admin; struct adf_heartbeat *heartbeat; struct adf_fw_versions fw_versions; unsigned int autoreset_on_error; struct adf_fw_counters_data *fw_counters_data; struct sysctl_oid *debugfs_ae_config; struct list_head crypto_list; atomic_t *ras_counters; unsigned long status; atomic_t ref_count; bus_dma_tag_t dma_tag; struct sysctl_ctx_list sysctl_ctx; struct sysctl_oid *ras_correctable; struct sysctl_oid *ras_uncorrectable; struct sysctl_oid *ras_fatal; struct sysctl_oid *ras_reset; struct sysctl_oid *pke_replay_dbgfile; struct sysctl_oid *misc_error_dbgfile; struct list_head list; struct adf_accel_pci accel_pci_dev; struct adf_accel_compat_manager *cm; u8 compat_ver; union { struct { /* vf_info is non-zero when SR-IOV is init'ed */ struct adf_accel_vf_info *vf_info; int num_vfs; } pf; struct { struct resource *irq; void *cookie; char *irq_name; struct task pf2vf_bh_tasklet; struct mutex vf2pf_lock; /* protect CSR access */ int iov_msg_completion; uint8_t compatible; uint8_t pf_version; u8 pf2vf_block_byte; u8 pf2vf_block_resp_type; struct pfvf_stats pfvf_counters; } vf; } u1; bool is_vf; u32 accel_id; void *lac_dev; }; #endif