/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2002-2005 Neterion, Inc. * All right Reserved. * * FileName : xgehal-device.h * * Description: HAL device object functionality * * Created: 14 May 2004 */ #ifndef XGE_HAL_DEVICE_H #define XGE_HAL_DEVICE_H #include "xge-os-pal.h" #include "xge-queue.h" #include "xgehal-event.h" #include "xgehal-config.h" #include "xgehal-regs.h" #include "xgehal-channel.h" #include "xgehal-stats.h" #define XGE_HAL_DEVICE_XMSI_WAIT_MAX_MILLIS 500 #define XGE_HAL_DEVICE_CMDMEM_WAIT_MAX_MILLIS 500 #define XGE_HAL_DEVICE_QUIESCENT_WAIT_MAX_MILLIS 500 #define XGE_HAL_DEVICE_FAULT_WAIT_MAX_MILLIS 50 #define XGE_HAL_DEVICE_RESET_WAIT_MAX_MILLIS 250 #define XGE_HAL_DEVICE_SPDM_READY_WAIT_MAX_MILLIS 250 /* TODO */ #define XGE_HAL_MAX_MSIX_MESSAGES 64 #define XGE_HAL_MAGIC 0x12345678 #define XGE_HAL_DEAD 0xDEADDEAD #define XGE_HAL_DUMP_BUF_SIZE 0x4000 #define XGE_HAL_MAX_LRO_SESSIONS 15 /** * enum xge_hal_card_e - Xframe adapter type. * @XGE_HAL_CARD_UNKNOWN: Unknown device. * @XGE_HAL_CARD_XENA: Xframe I device. * @XGE_HAL_CARD_HERC: Xframe II (PCI-266Mhz) device. * * Enumerates Xframe adapter types. The corresponding PCI device * IDs are listed in the file xgehal-defs.h. * (See XGE_PCI_DEVICE_ID_XENA_1, etc.) * * See also: xge_hal_device_check_id(). */ typedef enum xge_hal_card_e { XGE_HAL_CARD_UNKNOWN = 0, XGE_HAL_CARD_XENA = 1, XGE_HAL_CARD_HERC = 2, } xge_hal_card_e; /** * struct xge_hal_device_attr_t - Device memory spaces. * @regh0: BAR0 mapped memory handle (Solaris), or simply PCI device @pdev * (Linux and the rest.) * @regh1: BAR1 mapped memory handle. Same comment as above. * @bar0: BAR0 virtual address. * @bar1: BAR1 virtual address. * @bar2: BAR2 virtual address. * @irqh: IRQ handle (Solaris). * @cfgh: Configuration space handle (Solaris), or PCI device @pdev (Linux). * @pdev: PCI device object. * * Device memory spaces. Includes configuration, BAR0, BAR1, etc. per device * mapped memories. Also, includes a pointer to OS-specific PCI device object. */ typedef struct xge_hal_device_attr_t { pci_reg_h regh0; pci_reg_h regh1; pci_reg_h regh2; char *bar0; char *bar1; char *bar2; pci_irq_h irqh; pci_cfg_h cfgh; pci_dev_h pdev; } xge_hal_device_attr_t; /** * enum xge_hal_device_link_state_e - Link state enumeration. * @XGE_HAL_LINK_NONE: Invalid link state. * @XGE_HAL_LINK_DOWN: Link is down. * @XGE_HAL_LINK_UP: Link is up. * */ typedef enum xge_hal_device_link_state_e { XGE_HAL_LINK_NONE, XGE_HAL_LINK_DOWN, XGE_HAL_LINK_UP } xge_hal_device_link_state_e; /** * enum xge_hal_pci_mode_e - PIC bus speed and mode specific enumeration. * @XGE_HAL_PCI_33MHZ_MODE: 33 MHZ pci mode. * @XGE_HAL_PCI_66MHZ_MODE: 66 MHZ pci mode. * @XGE_HAL_PCIX_M1_66MHZ_MODE: PCIX M1 66MHZ mode. * @XGE_HAL_PCIX_M1_100MHZ_MODE: PCIX M1 100MHZ mode. * @XGE_HAL_PCIX_M1_133MHZ_MODE: PCIX M1 133MHZ mode. * @XGE_HAL_PCIX_M2_66MHZ_MODE: PCIX M2 66MHZ mode. * @XGE_HAL_PCIX_M2_100MHZ_MODE: PCIX M2 100MHZ mode. * @XGE_HAL_PCIX_M2_133MHZ_MODE: PCIX M3 133MHZ mode. * @XGE_HAL_PCIX_M1_RESERVED: PCIX M1 reserved mode. * @XGE_HAL_PCIX_M1_66MHZ_NS: PCIX M1 66MHZ mode not supported. * @XGE_HAL_PCIX_M1_100MHZ_NS: PCIX M1 100MHZ mode not supported. * @XGE_HAL_PCIX_M1_133MHZ_NS: PCIX M1 133MHZ not supported. * @XGE_HAL_PCIX_M2_RESERVED: PCIX M2 reserved. * @XGE_HAL_PCIX_533_RESERVED: PCIX 533 reserved. * @XGE_HAL_PCI_BASIC_MODE: PCI basic mode, XENA specific value. * @XGE_HAL_PCIX_BASIC_MODE: PCIX basic mode, XENA specific value. * @XGE_HAL_PCI_INVALID_MODE: Invalid PCI or PCIX mode. * */ typedef enum xge_hal_pci_mode_e { XGE_HAL_PCI_33MHZ_MODE = 0x0, XGE_HAL_PCI_66MHZ_MODE = 0x1, XGE_HAL_PCIX_M1_66MHZ_MODE = 0x2, XGE_HAL_PCIX_M1_100MHZ_MODE = 0x3, XGE_HAL_PCIX_M1_133MHZ_MODE = 0x4, XGE_HAL_PCIX_M2_66MHZ_MODE = 0x5, XGE_HAL_PCIX_M2_100MHZ_MODE = 0x6, XGE_HAL_PCIX_M2_133MHZ_MODE = 0x7, XGE_HAL_PCIX_M1_RESERVED = 0x8, XGE_HAL_PCIX_M1_66MHZ_NS = 0xA, XGE_HAL_PCIX_M1_100MHZ_NS = 0xB, XGE_HAL_PCIX_M1_133MHZ_NS = 0xC, XGE_HAL_PCIX_M2_RESERVED = 0xD, XGE_HAL_PCIX_533_RESERVED = 0xE, XGE_HAL_PCI_BASIC_MODE = 0x10, XGE_HAL_PCIX_BASIC_MODE = 0x11, XGE_HAL_PCI_INVALID_MODE = 0x12, } xge_hal_pci_mode_e; /** * enum xge_hal_pci_bus_frequency_e - PCI bus frequency enumeration. * @XGE_HAL_PCI_BUS_FREQUENCY_33MHZ: PCI bus frequency 33MHZ * @XGE_HAL_PCI_BUS_FREQUENCY_66MHZ: PCI bus frequency 66MHZ * @XGE_HAL_PCI_BUS_FREQUENCY_100MHZ: PCI bus frequency 100MHZ * @XGE_HAL_PCI_BUS_FREQUENCY_133MHZ: PCI bus frequency 133MHZ * @XGE_HAL_PCI_BUS_FREQUENCY_266MHZ: PCI bus frequency 266MHZ * @XGE_HAL_PCI_BUS_FREQUENCY_UNKNOWN: Unrecognized PCI bus frequency value. * */ typedef enum xge_hal_pci_bus_frequency_e { XGE_HAL_PCI_BUS_FREQUENCY_33MHZ = 33, XGE_HAL_PCI_BUS_FREQUENCY_66MHZ = 66, XGE_HAL_PCI_BUS_FREQUENCY_100MHZ = 100, XGE_HAL_PCI_BUS_FREQUENCY_133MHZ = 133, XGE_HAL_PCI_BUS_FREQUENCY_200MHZ = 200, XGE_HAL_PCI_BUS_FREQUENCY_266MHZ = 266, XGE_HAL_PCI_BUS_FREQUENCY_UNKNOWN = 0 } xge_hal_pci_bus_frequency_e; /** * enum xge_hal_pci_bus_width_e - PCI bus width enumeration. * @XGE_HAL_PCI_BUS_WIDTH_64BIT: 64 bit bus width. * @XGE_HAL_PCI_BUS_WIDTH_32BIT: 32 bit bus width. * @XGE_HAL_PCI_BUS_WIDTH_UNKNOWN: unknown bus width. * */ typedef enum xge_hal_pci_bus_width_e { XGE_HAL_PCI_BUS_WIDTH_64BIT = 0, XGE_HAL_PCI_BUS_WIDTH_32BIT = 1, XGE_HAL_PCI_BUS_WIDTH_UNKNOWN = 2, } xge_hal_pci_bus_width_e; #if defined (XGE_HAL_CONFIG_LRO) #define IP_TOTAL_LENGTH_OFFSET 2 #define IP_FAST_PATH_HDR_MASK 0x45 #define TCP_FAST_PATH_HDR_MASK1 0x50 #define TCP_FAST_PATH_HDR_MASK2 0x10 #define TCP_FAST_PATH_HDR_MASK3 0x18 #define IP_SOURCE_ADDRESS_OFFSET 12 #define IP_DESTINATION_ADDRESS_OFFSET 16 #define TCP_DESTINATION_PORT_OFFSET 2 #define TCP_SOURCE_PORT_OFFSET 0 #define TCP_DATA_OFFSET_OFFSET 12 #define TCP_WINDOW_OFFSET 14 #define TCP_SEQUENCE_NUMBER_OFFSET 4 #define TCP_ACKNOWLEDGEMENT_NUMBER_OFFSET 8 typedef struct tcplro { u16 source; u16 dest; u32 seq; u32 ack_seq; u8 doff_res; u8 ctrl; u16 window; u16 check; u16 urg_ptr; } tcplro_t; typedef struct iplro { u8 version_ihl; u8 tos; u16 tot_len; u16 id; u16 frag_off; u8 ttl; u8 protocol; u16 check; u32 saddr; u32 daddr; /*The options start here. */ } iplro_t; /* * LRO object, one per each LRO session. */ typedef struct lro { /* non-linear: contains scatter-gather list of xframe-mapped received buffers */ OS_NETSTACK_BUF os_buf; OS_NETSTACK_BUF os_buf_end; /* link layer header of the first frame; remains intack throughout the processing */ u8 *ll_hdr; /* IP header - gets _collapsed_ */ iplro_t *ip_hdr; /* transport header - gets _collapsed_ */ tcplro_t *tcp_hdr; /* Next tcp sequence number */ u32 tcp_next_seq_num; /* Current tcp seq & ack */ u32 tcp_seq_num; u32 tcp_ack_num; /* total number of accumulated (so far) frames */ int sg_num; /* total data length */ int total_length; /* receive side hash value, available from Hercules */ u32 rth_value; /* In use */ u8 in_use; /* Total length of the fragments clubbed with the inital frame */ u32 frags_len; } lro_t; #endif /* * xge_hal_spdm_entry_t * * Represents a single spdm entry in the SPDM table. */ typedef struct xge_hal_spdm_entry_t { xge_hal_ipaddr_t src_ip; xge_hal_ipaddr_t dst_ip; u32 jhash_value; u16 l4_sp; u16 l4_dp; u16 spdm_entry; u8 in_use; u8 is_tcp; u8 is_ipv4; u8 tgt_queue; } xge_hal_spdm_entry_t; /* * xge_hal_device_t * * HAL device object. Represents Xframe. */ typedef struct { int magic; pci_reg_h regh0; pci_reg_h regh1; pci_reg_h regh2; char *bar0; char *isrbar0; char *bar1; char *bar2; pci_irq_h irqh; pci_cfg_h cfgh; pci_dev_h pdev; xge_hal_pci_config_t pci_config_space; #if defined(XGE_HAL_MSI_X) u64 msix_vector_table[XGE_HAL_MAX_MSIX_MESSAGES * 2]; #endif xge_hal_device_config_t config; xge_list_t free_channels; xge_list_t fifo_channels; xge_list_t ring_channels; volatile int is_initialized; volatile int terminating; xge_hal_stats_t stats; macaddr_t macaddr[1]; xge_queue_h queueh; volatile int mcast_refcnt; int is_promisc; volatile xge_hal_device_link_state_e link_state; void *upper_layer_info; xge_hal_device_attr_t orig_attr; u16 device_id; u8 revision; int msi_enabled; int hw_is_initialized; u64 inject_serr; u64 inject_ecc; u8 inject_bad_tcode; int inject_bad_tcode_for_chan_type; int reset_needed_after_close; char *spdm_mem_base; u16 spdm_max_entries; xge_hal_spdm_entry_t **spdm_table; spinlock_t spdm_lock; #if defined(XGE_HAL_MSI) u32 msi_mask; #endif #if defined(XGE_HAL_CONFIG_LRO) lro_t g_lro_pool[XGE_HAL_MAX_LRO_SESSIONS]; #endif spinlock_t xena_post_lock; u64 rxufca_lbolt; u64 rxufca_lbolt_time; u64 rxufca_intr_thres; char* dump_buf; int mtu_first_time_set; xge_hal_pci_mode_e pci_mode; xge_hal_pci_bus_frequency_e bus_frequency; xge_hal_pci_bus_width_e bus_width; volatile int in_poll; } xge_hal_device_t; /* ========================== PRIVATE API ================================= */ void __hal_pio_mem_write32_upper(pci_dev_h pdev, pci_reg_h regh, u32 val, void *addr); void __hal_pio_mem_write32_lower(pci_dev_h pdev, pci_reg_h regh, u32 val, void *addr); xge_hal_status_e __hal_device_handle_txpic(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_txdma(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_txmac(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_txxgxs(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_rxpic(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_rxdma(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_rxmac(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_rxxgxs(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_handle_mc(xge_hal_device_t *hldev, u64 reason); xge_hal_status_e __hal_device_register_poll(xge_hal_device_t *hldev, u64 *reg, int op, u64 mask, int max_millis); xge_hal_status_e __hal_device_rts_mac_configure(xge_hal_device_t *hldev); /* =========================== PUBLIC API ================================= */ unsigned int __hal_fix_time_ival_herc(xge_hal_device_t *hldev, unsigned int time_ival); xge_hal_status_e xge_hal_rts_rth_itable_set(xge_hal_device_t *hldev, u8 *itable, u32 itable_size); void xge_hal_rts_rth_set(xge_hal_device_t *hldev, u8 def_q, u64 hash_type, u16 bucket_size); void xge_hal_rts_rth_init(xge_hal_device_t *hldev); void xge_hal_rts_rth_clr(xge_hal_device_t *hldev); void xge_hal_rts_rth_start(xge_hal_device_t *hldev); void xge_hal_rts_rth_stop(xge_hal_device_t *hldev); void xge_hal_device_rts_rth_key_set(xge_hal_device_t *hldev, u8 KeySize, u8 *Key); xge_hal_status_e xge_hal_device_rts_mac_enable(xge_hal_device_h devh, int index, macaddr_t macaddr); xge_hal_status_e xge_hal_device_rts_mac_disable(xge_hal_device_h devh, int index); /** * xge_hal_device_is_initialized - Returns 0 if device is not * initialized, non-zero otherwise. * @devh: HAL device handle. * * Returns 0 if device is not initialized, non-zero otherwise. */ static inline int xge_hal_device_is_initialized(xge_hal_device_h devh) { return ((xge_hal_device_t*)devh)->is_initialized; } /** * xge_hal_device_in_poll - non-zero, if xge_hal_device_poll() is executing. * @devh: HAL device handle. * * Returns non-zero if xge_hal_device_poll() is executing, and 0 - otherwise. */ static inline int xge_hal_device_in_poll(xge_hal_device_h devh) { return ((xge_hal_device_t*)devh)->in_poll; } /** * xge_hal_device_inject_ecc - Inject ECC error. * @devh: HAL device, pointer to xge_hal_device_t structure. * @err_reg: Contains the error register. * * This function is used to inject ECC error into the driver flow. * This facility can be used to test the driver flow in the * case of ECC error is reported by the firmware. * * Returns: void * See also: xge_hal_device_inject_serr(), * xge_hal_device_inject_bad_tcode() */ static inline void xge_hal_device_inject_ecc(xge_hal_device_h devh, u64 err_reg) { ((xge_hal_device_t*)devh)->inject_ecc = err_reg; } /** * xge_hal_device_inject_serr - Inject SERR error. * @devh: HAL device, pointer to xge_hal_device_t structure. * @err_reg: Contains the error register. * * This function is used to inject SERR error into the driver flow. * This facility can be used to test the driver flow in the * case of SERR error is reported by firmware. * * Returns: void * See also: xge_hal_device_inject_ecc(), * xge_hal_device_inject_bad_tcode() */ static inline void xge_hal_device_inject_serr(xge_hal_device_h devh, u64 err_reg) { ((xge_hal_device_t*)devh)->inject_serr = err_reg; } /** * xge_hal_device_inject_bad_tcode - Inject Bad transfer code. * @devh: HAL device, pointer to xge_hal_device_t structure. * @chan_type: Channel type (fifo/ring). * @t_code: Transfer code. * * This function is used to inject bad (Tx/Rx Data)transfer code * into the driver flow. * * This facility can be used to test the driver flow in the * case of bad transfer code reported by firmware for a Tx/Rx data * transfer. * * Returns: void * See also: xge_hal_device_inject_ecc(), xge_hal_device_inject_serr() */ static inline void xge_hal_device_inject_bad_tcode(xge_hal_device_h devh, int chan_type, u8 t_code) { ((xge_hal_device_t*)devh)->inject_bad_tcode_for_chan_type = chan_type; ((xge_hal_device_t*)devh)->inject_bad_tcode = t_code; } void xge_hal_device_msi_enable(xge_hal_device_h devh); /* * xge_hal_device_msi_mode - Is MSI enabled? * @devh: HAL device handle. * * Returns 0 if MSI is enabled for the specified device, * non-zero otherwise. */ static inline int xge_hal_device_msi_mode(xge_hal_device_h devh) { return ((xge_hal_device_t*)devh)->msi_enabled; } /** * xge_hal_device_queue - Get per-device event queue. * @devh: HAL device handle. * * Returns: event queue associated with the specified HAL device. */ static inline xge_queue_h xge_hal_device_queue (xge_hal_device_h devh) { return ((xge_hal_device_t*)devh)->queueh; } /** * xge_hal_device_attr - Get original (user-specified) device * attributes. * @devh: HAL device handle. * * Returns: original (user-specified) device attributes. */ static inline xge_hal_device_attr_t* xge_hal_device_attr(xge_hal_device_h devh) { return &((xge_hal_device_t*)devh)->orig_attr; } /** * xge_hal_device_private_set - Set ULD context. * @devh: HAL device handle. * @data: pointer to ULD context * * Use HAL device to set upper-layer driver (ULD) context. * * See also: xge_hal_device_from_private(), xge_hal_device_private() */ static inline void xge_hal_device_private_set(xge_hal_device_h devh, void *data) { ((xge_hal_device_t*)devh)->upper_layer_info = data; } /** * xge_hal_device_private - Get ULD context. * @devh: HAL device handle. * * Use HAL device to get upper-layer driver (ULD) context. * * Returns: ULD context. * * See also: xge_hal_device_from_private(), xge_hal_device_private_set() */ static inline void* xge_hal_device_private(xge_hal_device_h devh) { return ((xge_hal_device_t*)devh)->upper_layer_info; } /** * xge_hal_device_from_private - Get HAL device object from private. * @info_ptr: ULD context. * * Use ULD context to get HAL device. * * Returns: Device handle. * * See also: xge_hal_device_private(), xge_hal_device_private_set() */ static inline xge_hal_device_h xge_hal_device_from_private(void *info_ptr) { return xge_container_of(info_ptr, xge_hal_device_t, upper_layer_info); } /** * xge_hal_device_mtu_check - check MTU value for ranges * @hldev: the device * @new_mtu: new MTU value to check * * Will do sanity check for new MTU value. * * Returns: XGE_HAL_OK - success. * XGE_HAL_ERR_INVALID_MTU_SIZE - MTU is invalid. * * See also: xge_hal_device_mtu_set() */ static inline xge_hal_status_e xge_hal_device_mtu_check(xge_hal_device_t *hldev, int new_mtu) { if ((new_mtu < XGE_HAL_MIN_MTU) || (new_mtu > XGE_HAL_MAX_MTU)) { return XGE_HAL_ERR_INVALID_MTU_SIZE; } return XGE_HAL_OK; } void xge_hal_device_bcast_enable(xge_hal_device_h devh); void xge_hal_device_bcast_disable(xge_hal_device_h devh); void xge_hal_device_terminating(xge_hal_device_h devh); xge_hal_status_e xge_hal_device_initialize(xge_hal_device_t *hldev, xge_hal_device_attr_t *attr, xge_hal_device_config_t *config); void xge_hal_device_terminate(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_reset(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_macaddr_get(xge_hal_device_t *hldev, int index, macaddr_t *macaddr); xge_hal_status_e xge_hal_device_macaddr_set(xge_hal_device_t *hldev, int index, macaddr_t macaddr); int xge_hal_device_macaddr_find(xge_hal_device_t *hldev, macaddr_t wanted); xge_hal_status_e xge_hal_device_mtu_set(xge_hal_device_t *hldev, int new_mtu); xge_hal_status_e xge_hal_device_status(xge_hal_device_t *hldev, u64 *hw_status); void xge_hal_device_intr_enable(xge_hal_device_t *hldev); void xge_hal_device_intr_disable(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_mcast_enable(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_mcast_disable(xge_hal_device_t *hldev); void xge_hal_device_promisc_enable(xge_hal_device_t *hldev); void xge_hal_device_promisc_disable(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_disable(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_enable(xge_hal_device_t *hldev); xge_hal_status_e xge_hal_device_handle_tcode(xge_hal_channel_h channelh, xge_hal_dtr_h dtrh, u8 t_code); xge_hal_status_e xge_hal_device_link_state(xge_hal_device_h devh, xge_hal_device_link_state_e *ls); void xge_hal_device_sched_timer(xge_hal_device_h devh, int interval_us, int one_shot); void xge_hal_device_poll(xge_hal_device_h devh); xge_hal_card_e xge_hal_device_check_id(xge_hal_device_h devh); int xge_hal_device_is_slot_freeze(xge_hal_device_h devh); xge_hal_status_e xge_hal_device_pci_info_get(xge_hal_device_h devh, xge_hal_pci_mode_e *pci_mode, xge_hal_pci_bus_frequency_e *bus_frequency, xge_hal_pci_bus_width_e *bus_width); xge_hal_status_e xge_hal_spdm_entry_add(xge_hal_device_h devh, xge_hal_ipaddr_t *src_ip, xge_hal_ipaddr_t *dst_ip, u16 l4_sp, u16 l4_dp, u8 is_tcp, u8 is_ipv4, u8 tgt_queue); xge_hal_status_e xge_hal_spdm_entry_remove(xge_hal_device_h devh, xge_hal_ipaddr_t *src_ip, xge_hal_ipaddr_t *dst_ip, u16 l4_sp, u16 l4_dp, u8 is_tcp, u8 is_ipv4); u32 __hal_calc_jhash(u8 *msg, u32 length, u32 golden_ratio, u32 init_value); int xge_hal_device_is_closed (xge_hal_device_h devh); #if defined(XGE_HAL_MSI) /* Some function protoypes for MSI implementation. */ xge_hal_status_e xge_hal_channel_msi_set (xge_hal_channel_h channelh, int msi, u32 msg_val); void xge_hal_mask_msi(xge_hal_device_t *hldev); void xge_hal_unmask_msi(xge_hal_channel_h channelh); #endif #if defined(XGE_HAL_MSI_X) xge_hal_status_e xge_hal_channel_msix_set(xge_hal_channel_h channelh, int msix_idx); #endif #if defined(XGE_DEBUG_FP) && (XGE_DEBUG_FP & XGE_DEBUG_FP_DEVICE) #define __HAL_STATIC_DEVICE #define __HAL_INLINE_DEVICE __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE int xge_hal_device_rev(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_begin_irq(xge_hal_device_t *hldev, u64 *reason); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_clear_rx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_clear_tx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_continue_irq(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_handle_irq(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_bar0(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_isrbar0(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE char * xge_hal_device_bar1(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_bar0_set(xge_hal_device_t *hldev, char *bar0); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_isrbar0_set(xge_hal_device_t *hldev, char *isrbar0); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_bar1_set(xge_hal_device_t *hldev, xge_hal_channel_h channelh, char *bar1); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_tx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_rx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_mask_all(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_tx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_rx(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE void xge_hal_device_unmask_all(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_tx_channels(xge_hal_device_t *hldev); __HAL_STATIC_DEVICE __HAL_INLINE_DEVICE xge_hal_status_e xge_hal_device_poll_rx_channels(xge_hal_device_t *hldev); #if defined (XGE_HAL_CONFIG_LRO) __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL u8 __hal_header_parse_token_u8(u8 *string,u16 offset); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL u16 __hal_header_parse_token_u16(u8 *string,u16 offset); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL u32 __hal_header_parse_token_u32(u8 *string,u16 offset); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void __hal_header_update_u8(u8 *string, u16 offset, u8 val); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void __hal_header_update_u16(u8 *string, u16 offset, u16 val); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void __hal_header_update_u32(u8 *string, u16 offset, u32 val); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL u16 __hal_tcp_seg_len(u8 *ip, u8 *tcp); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_ip_lro_capable(u8 *ip, xge_hal_dtr_info_t *ext_info); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_tcp_lro_capable(u8 *ip, u8 *tcp); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_lro_capable(u8 *buffer, u8 **ip, u8 **tcp, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_get_lro_session(u8 *buffer, u8 *ip, u8 *tcp, lro_t **lro, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_lro_under_optimal_thresh(u8 *ip, u8 *tcp, lro_t *lro, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_collapse_ip_hdr(u8 *ip, u8 *tcp, lro_t *lro, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_collapse_tcp_hdr(u8 *ip, u8 *tcp, lro_t *lro, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e __hal_append_lro(u8 *ip, u8 *tcp, u32 *seg_len, lro_t *lro, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL xge_hal_status_e xge_hal_accumulate_large_rx(u8 *buffer, u8 **tcp, u32 *seglen, lro_t **lro, xge_hal_dtr_info_t *ext_info, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL void xge_hal_lro_free(lro_t *lro, xge_hal_device_t *hldev); __HAL_STATIC_CHANNEL __HAL_INLINE_CHANNEL lro_t * __hal_lro_malloc(xge_hal_device_t *hldev); void xge_hal_lro_terminate(u32 lro_scale xge_hal_device_t *hldev); xge_hal_status_e xge_hal_lro_init(u32 lro_scale, xge_hal_device_t *hldev); #endif #else /* XGE_FASTPATH_EXTERN */ #define __HAL_STATIC_DEVICE static #define __HAL_INLINE_DEVICE inline #include "xgehal-device-fp.c" #endif /* XGE_FASTPATH_INLINE */ #endif /* XGE_HAL_DEVICE_H */