/*- * Copyright(c) 2002-2011 Exar Corp. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification are permitted provided the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * 3. Neither the name of the Exar Corporation nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ /*$FreeBSD$*/ #ifndef VXGE_HAL_CONFIG_H #define VXGE_HAL_CONFIG_H __EXTERN_BEGIN_DECLS #define VXGE_HAL_USE_FLASH_DEFAULT VXGE_HAL_DEFAULT_32 #define VXGE_HAL_MAX_INTR_PER_VP 4 #define VXGE_HAL_VPATH_MSIX_MAX 4 #define VXGE_HAL_VPATH_INTR_TX 0 #define VXGE_HAL_VPATH_INTR_RX 1 #define VXGE_HAL_VPATH_INTR_EINTA 2 #define VXGE_HAL_VPATH_INTR_BMAP 3 #define WAIT_FACTOR 1 /* * struct vxge_hal_driver_config_t - HAL driver object configuration. * * @level: Debug Level. See vxge_debug_level_e {} * * Currently this structure contains just a few basic values. */ typedef struct vxge_hal_driver_config_t { vxge_debug_level_e level; } vxge_hal_driver_config_t; /* * struct vxge_hal_wire_port_config_t - Wire Port configuration (Physical ports) * @port_id: Port number * @media: Transponder type. * @mtu: mtu size used on this port. * @autoneg_mode: The device supports several mechanisms to auto-negotiate the * port data rate. The Fixed mode essentially means no * auto-negotiation and the data rate is determined by the RATE * field of this register. The MDIO-based mode determines the data * rate by reading MDIO registers in the external PHY chip. The * Backplane Ethernet mode using parallel detect and/or * DME-signaled exchange of page information with the PHY chip in * order to figure out the proper rate. * 00 - Fixed * 01 - MDIO-based * 10 - Backplane Ethernet * 11 - Reserved * @autoneg_rate: When MODE is set to Fixed, then this field determines the data * rate of the port. * 0 - 1G * 1 - 10G * @fixed_use_fsm: When MODE is set to Fixed, then this field determines whether * a processor (i.e. F/W or host driver) or hardware-based state * machine is used to run the auto-negotiation. * 0 - Use processor. Either on-chip F/W or host-based driver used. * 1 - Use H/W state machine * @antp_use_fsm: When MODE is set to ANTP (Auto-Negotiation for Twisted Pair), * this field determines whether a processor (F/W or host driver) * or hardware-based state machine is used to talk to the PHY chip * via the MDIO interface. * 0 - Use processor. Either on-chip F/W or host-based driver used. * 1 - Use H/W state machine * @anbe_use_fsm: When MODE is set to ANBE-based, then this field determines * whether a processor (i.e. F/W or host driver) or hardware-based * state machine is used to talk to the Backplane Ethernet logic * inside the device * 0 - Use processor. Either on-chip F/W or host-based driver used. * 1 - Use H/W state machine * @link_stability_period: Timeout for the link stability * @port_stability_period: Timeout for the port stability * @tmac_en: TMAC enable. 0 - Disable; 1 - Enable * @rmac_en: RMAC enable. 0 - Disable; 1 - Enable * @tmac_pad: Determines whether padding is appended to transmitted frames. * 0 - No padding appended * 1 - Pad to 64 bytes (not including preamble/SFD) * @tmac_pad_byte: The byte that is used to pad * @tmac_util_period: The sampling period over which the transmit utilization * is calculated. * @rmac_strip_fcs: Determines whether FCS of received frames is removed by the * MAC or sent to the host. * 0 - Send FCS to host. * 1 - FCS removed by MAC. * @rmac_prom_en: Enable/Disable promiscuous mode. In promiscuous mode all * received frames are passed to the host. PROM_EN overrules the * configuration determined by the UCAST_ALL_ADDR_EN, * MCAST_ALL_ADDR_EN and ALL_VID_EN fields of RXMAC_VCFG, as well * as the configurable discard fields in RMAC_ERR_CFG_PORTn. * Note: PROM_EN does not overrule DISCARD_PFRM (i.e. discard of * pause frames by receive MAC is controlled solely by * DISCARD_PFRM). * 0 - Disable * 1 - Enable * @rmac_discard_pfrm: Determines whether received pause frames are discarded at * the receive MAC or passed to the host. * Note: Other MAC control frames are always passed to the host. * 0 - Send to host. * 1 - Pause frames discarded by MAC. * @rmac_util_period: The sampling period over which the receive utilization * is calculated. * @rmac_strip_pad: Determines whether padding of received frames is removed by * the MAC or sent to the host. * @rmac_bcast_en: Enable frames containing broadcast address to be * passed to the host. * @rmac_pause_gen_en: Received pause generation enable. * @rmac_pause_rcv_en: Receive pause enable. * @rmac_pause_time: The value to be inserted in outgoing pause frames. * Has units of pause quanta (one pause quanta = 512 bit times). * @limiter_en: Enables logic that limits the contribution that any one receive * queue can have on the transmission of pause frames. This avoids * a situation where the adapter will permanently send pause frames * due to a receive VPATH that is either undergoing a long reset or * is in a dead state. * 0 - Don't limit the contribution of any queue. If any queue's * fill level sits above the high threshold, then a pause frame * is sent. * 1 - Place a cap on the number of pause frames that are sent * because any one queue has crossed its high threshold. * See MAX_LIMIT for more details. * @max_limit: Contains the value that is loaded into the per-queue limiting * counters that exist in the flow control logic. Essentially, * this represents the maximum number of pause frames that are sent * due to any one particular queue having crossed its high * threshold. Each counter is set to this max limit the first time * the corresponding queue's high threshold is crossed. The counter * decrements each time the queue remains above the high threshold * and the adapter requests pause frame transmission. Once the * counter expires that queue no longer contributes to pause frame * transmission requests. The queue's fill level must drop below * the low pause threshold before it is once again allowed to * contribute. Note: This field is only used when LIMITER_EN is set * to 1. * * Wire Port Configuration */ typedef struct vxge_hal_wire_port_config_t { u32 port_id; #define VXGE_HAL_WIRE_PORT_PORT0 0 #define VXGE_HAL_WIRE_PORT_PORT1 1 #define VXGE_HAL_WIRE_PORT_MAX_PORTS VXGE_HAL_MAC_MAX_WIRE_PORTS u32 media; #define VXGE_HAL_WIRE_PORT_MIN_MEDIA 0 #define VXGE_HAL_WIRE_PORT_MEDIA_SR 0 #define VXGE_HAL_WIRE_PORT_MEDIA_SW 1 #define VXGE_HAL_WIRE_PORT_MEDIA_LR 2 #define VXGE_HAL_WIRE_PORT_MEDIA_LW 3 #define VXGE_HAL_WIRE_PORT_MEDIA_ER 4 #define VXGE_HAL_WIRE_PORT_MEDIA_EW 5 #define VXGE_HAL_WIRE_PORT_MAX_MEDIA 5 #define VXGE_HAL_WIRE_PORT_MEDIA_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 mtu; #define VXGE_HAL_WIRE_PORT_MIN_INITIAL_MTU VXGE_HAL_MIN_MTU #define VXGE_HAL_WIRE_PORT_MAX_INITIAL_MTU VXGE_HAL_MAX_MTU #define VXGE_HAL_WIRE_PORT_DEF_INITIAL_MTU VXGE_HAL_USE_FLASH_DEFAULT u32 autoneg_mode; #define VXGE_HAL_WIRE_PORT_AUTONEG_MODE_FIXED 0 #define VXGE_HAL_WIRE_PORT_AUTONEG_MODE_ANTP 1 #define VXGE_HAL_WIRE_PORT_AUTONEG_MODE_ANBE 2 #define VXGE_HAL_WIRE_PORT_AUTONEG_MODE_RESERVED 3 #define VXGE_HAL_WIRE_PORT_AUTONEG_MODE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 autoneg_rate; #define VXGE_HAL_WIRE_PORT_AUTONEG_RATE_1G 0 #define VXGE_HAL_WIRE_PORT_AUTONEG_RATE_10G 1 #define VXGE_HAL_WIRE_PORT_AUTONEG_RATE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 fixed_use_fsm; #define VXGE_HAL_WIRE_PORT_FIXED_USE_FSM_PROCESSOR 0 #define VXGE_HAL_WIRE_PORT_FIXED_USE_FSM_HW 1 #define VXGE_HAL_WIRE_PORT_FIXED_USE_FSM_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 antp_use_fsm; #define VXGE_HAL_WIRE_PORT_ANTP_USE_FSM_PROCESSOR 0 #define VXGE_HAL_WIRE_PORT_ANTP_USE_FSM_HW 1 #define VXGE_HAL_WIRE_PORT_ANTP_USE_FSM_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 anbe_use_fsm; #define VXGE_HAL_WIRE_PORT_ANBE_USE_FSM_PROCESSOR 0 #define VXGE_HAL_WIRE_PORT_ANBE_USE_FSM_HW 1 #define VXGE_HAL_WIRE_PORT_ANBE_USE_FSM_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 link_stability_period; #define VXGE_HAL_WIRE_PORT_MIN_LINK_STABILITY_PERIOD 0x0 /* 0s */ #define VXGE_HAL_WIRE_PORT_MAX_LINK_STABILITY_PERIOD 0xF /* 2s */ #define VXGE_HAL_WIRE_PORT_DEF_LINK_STABILITY_PERIOD \ VXGE_HAL_USE_FLASH_DEFAULT u32 port_stability_period; #define VXGE_HAL_WIRE_PORT_MIN_PORT_STABILITY_PERIOD 0x0 /* 0s */ #define VXGE_HAL_WIRE_PORT_MAX_PORT_STABILITY_PERIOD 0xF /* 2s */ #define VXGE_HAL_WIRE_PORT_DEF_PORT_STABILITY_PERIOD \ VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_en; #define VXGE_HAL_WIRE_PORT_TMAC_ENABLE 1 #define VXGE_HAL_WIRE_PORT_TMAC_DISABLE 0 #define VXGE_HAL_WIRE_PORT_TMAC_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_en; #define VXGE_HAL_WIRE_PORT_RMAC_ENABLE 1 #define VXGE_HAL_WIRE_PORT_RMAC_DISABLE 0 #define VXGE_HAL_WIRE_PORT_RMAC_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_pad; #define VXGE_HAL_WIRE_PORT_TMAC_NO_PAD 0 #define VXGE_HAL_WIRE_PORT_TMAC_64B_PAD 1 #define VXGE_HAL_WIRE_PORT_TMAC_PAD_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_pad_byte; #define VXGE_HAL_WIRE_PORT_MIN_TMAC_PAD_BYTE 0 #define VXGE_HAL_WIRE_PORT_MAX_TMAC_PAD_BYTE 255 #define VXGE_HAL_WIRE_PORT_DEF_TMAC_PAD_BYTE VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_util_period; #define VXGE_HAL_WIRE_PORT_MIN_TMAC_UTIL_PERIOD 0 #define VXGE_HAL_WIRE_PORT_MAX_TMAC_UTIL_PERIOD 15 #define VXGE_HAL_WIRE_PORT_DEF_TMAC_UTIL_PERIOD VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_strip_fcs; #define VXGE_HAL_WIRE_PORT_RMAC_STRIP_FCS 1 #define VXGE_HAL_WIRE_PORT_RMAC_SEND_FCS_TO_HOST 0 #define VXGE_HAL_WIRE_PORT_RMAC_STRIP_FCS_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_prom_en; #define VXGE_HAL_WIRE_PORT_RMAC_PROM_EN_ENABLE 1 #define VXGE_HAL_WIRE_PORT_RMAC_PROM_EN_DISABLE 0 #define VXGE_HAL_WIRE_PORT_RMAC_PROM_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_discard_pfrm; #define VXGE_HAL_WIRE_PORT_RMAC_DISCARD_PFRM 1 #define VXGE_HAL_WIRE_PORT_RMAC_SEND_PFRM_TO_HOST 0 #define VXGE_HAL_WIRE_PORT_RMAC_DISCARD_PFRM_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_util_period; #define VXGE_HAL_WIRE_PORT_MIN_RMAC_UTIL_PERIOD 0 #define VXGE_HAL_WIRE_PORT_MAX_RMAC_UTIL_PERIOD 15 #define VXGE_HAL_WIRE_PORT_DEF_RMAC_UTIL_PERIOD VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_gen_en; #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_GEN_EN_ENABLE 1 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_GEN_EN_DISABLE 0 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_GEN_EN_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_rcv_en; #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_RCV_EN_ENABLE 1 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_RCV_EN_DISABLE 0 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_RCV_EN_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_time; #define VXGE_HAL_WIRE_PORT_MIN_RMAC_HIGH_PTIME 16 #define VXGE_HAL_WIRE_PORT_MAX_RMAC_HIGH_PTIME 65535 #define VXGE_HAL_WIRE_PORT_DEF_RMAC_HIGH_PTIME VXGE_HAL_USE_FLASH_DEFAULT u32 limiter_en; #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_LIMITER_ENABLE 1 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_LIMITER_DISABLE 0 #define VXGE_HAL_WIRE_PORT_RMAC_PAUSE_LIMITER_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 max_limit; #define VXGE_HAL_WIRE_PORT_MIN_RMAC_MAX_LIMIT 0 #define VXGE_HAL_WIRE_PORT_MAX_RMAC_MAX_LIMIT 255 #define VXGE_HAL_WIRE_PORT_DEF_RMAC_MAX_LIMIT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_wire_port_config_t; /* * struct vxge_hal_switch_port_config_t - Switch Port configuration(vm-vm port) * @mtu: mtu size used on this port. * @tmac_en: TMAC enable. 0 - Disable; 1 - Enable * @rmac_en: RMAC enable. 0 - Disable; 1 - Enable * @tmac_pad: Determines whether padding is appended to transmitted frames. * 0 - No padding appended * 1 - Pad to 64 bytes (not including preamble/SFD) * @tmac_pad_byte: The byte that is used to pad * @tmac_util_period: The sampling period over which the transmit utilization * is calculated. * @rmac_strip_fcs: Determines whether FCS of received frames is removed by the * MAC or sent to the host. * 0 - Send FCS to host. * 1 - FCS removed by MAC. * @rmac_prom_en: Enable/Disable promiscuous mode. In promiscuous mode all * received frames are passed to the host. PROM_EN overrules the * configuration determined by the UCAST_ALL_ADDR_EN, * MCAST_ALL_ADDR_EN and ALL_VID_EN fields of RXMAC_VCFG, as well * as the configurable discard fields in RMAC_ERR_CFG_PORTn. * Note: PROM_EN does not overrule DISCARD_PFRM (i.e. discard of * pause frames by receive MAC is controlled solely by * DISCARD_PFRM). * 0 - Disable * 1 - Enable * @rmac_discard_pfrm: Determines whether received pause frames are discarded at * the receive MAC or passed to the host. * Note: Other MAC control frames are always passed to the host. * 0 - Send to host. * 1 - Pause frames discarded by MAC. * @rmac_util_period: The sampling period over which the receive utilization * is calculated. * @rmac_strip_pad: Determines whether padding of received frames is removed by * the MAC or sent to the host. * @rmac_bcast_en: Enable frames containing broadcast address to be * passed to the host. * @rmac_pause_gen_en: Received pause generation enable. * @rmac_pause_rcv_en: Receive pause enable. * @rmac_pause_time: The value to be inserted in outgoing pause frames. * Has units of pause quanta (one pause quanta = 512 bit times). * @limiter_en: Enables logic that limits the contribution that any one receive * queue can have on the transmission of pause frames. This avoids * a situation where the adapter will permanently send pause frames * due to a receive VPATH that is either undergoing a long reset or * is in a dead state. * 0 - Don't limit the contribution of any queue. If any queue's * fill level sits above the high threshold, then a pause frame * is sent. * 1 - Place a cap on the number of pause frames that are sent * because any one queue has crossed its high threshold. * See MAX_LIMIT for more details. * @max_limit: Contains the value that is loaded into the per-queue limiting * counters that exist in the flow control logic. Essentially, * this represents the maximum number of pause frames that are sent * due to any one particular queue having crossed its high * threshold. Each counter is set to this max limit the first time * the corresponding queue's high threshold is crossed. The counter * decrements each time the queue remains above the high threshold * and the adapter requests pause frame transmission. Once the * counter expires that queue no longer contributes to pause frame * transmission requests. The queue's fill level must drop below * the low pause threshold before it is once again allowed to * contribute. Note: This field is only used when LIMITER_EN is set * to 1. * * Switch Port Configuration */ typedef struct vxge_hal_switch_port_config_t { u32 mtu; #define VXGE_HAL_SWITCH_PORT_MIN_INITIAL_MTU VXGE_HAL_MIN_MTU #define VXGE_HAL_SWITCH_PORT_MAX_INITIAL_MTU VXGE_HAL_MAX_MTU #define VXGE_HAL_SWITCH_PORT_DEF_INITIAL_MTU VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_en; #define VXGE_HAL_SWITCH_PORT_TMAC_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_TMAC_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_TMAC_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_en; #define VXGE_HAL_SWITCH_PORT_RMAC_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_RMAC_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_RMAC_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_pad; #define VXGE_HAL_SWITCH_PORT_TMAC_NO_PAD 0 #define VXGE_HAL_SWITCH_PORT_TMAC_64B_PAD 1 #define VXGE_HAL_SWITCH_PORT_TMAC_PAD_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_pad_byte; #define VXGE_HAL_SWITCH_PORT_MIN_TMAC_PAD_BYTE 0 #define VXGE_HAL_SWITCH_PORT_MAX_TMAC_PAD_BYTE 255 #define VXGE_HAL_SWITCH_PORT_DEF_TMAC_PAD_BYTE VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_util_period; #define VXGE_HAL_SWITCH_PORT_MIN_TMAC_UTIL_PERIOD 0 #define VXGE_HAL_SWITCH_PORT_MAX_TMAC_UTIL_PERIOD 15 #define VXGE_HAL_SWITCH_PORT_DEF_TMAC_UTIL_PERIOD VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_strip_fcs; #define VXGE_HAL_SWITCH_PORT_RMAC_STRIP_FCS 1 #define VXGE_HAL_SWITCH_PORT_RMAC_SEND_FCS_TO_HOST 0 #define VXGE_HAL_SWITCH_PORT_RMAC_STRIP_FCS_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_prom_en; #define VXGE_HAL_SWITCH_PORT_RMAC_PROM_EN_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_RMAC_PROM_EN_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_RMAC_PROM_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_discard_pfrm; #define VXGE_HAL_SWITCH_PORT_RMAC_DISCARD_PFRM 1 #define VXGE_HAL_SWITCH_PORT_RMAC_SEND_PFRM_TO_HOST 0 #define VXGE_HAL_SWITCH_PORT_RMAC_DISCARD_PFRM_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_util_period; #define VXGE_HAL_SWITCH_PORT_MIN_RMAC_UTIL_PERIOD 0 #define VXGE_HAL_SWITCH_PORT_MAX_RMAC_UTIL_PERIOD 15 #define VXGE_HAL_SWITCH_PORT_DEF_RMAC_UTIL_PERIOD VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_gen_en; #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_GEN_EN_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_GEN_EN_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_GEN_EN_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_rcv_en; #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_RCV_EN_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_RCV_EN_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_RCV_EN_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rmac_pause_time; #define VXGE_HAL_SWITCH_PORT_MIN_RMAC_HIGH_PTIME 16 #define VXGE_HAL_SWITCH_PORT_MAX_RMAC_HIGH_PTIME 65535 #define VXGE_HAL_SWITCH_PORT_DEF_RMAC_HIGH_PTIME VXGE_HAL_USE_FLASH_DEFAULT u32 limiter_en; #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_LIMITER_ENABLE 1 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_LIMITER_DISABLE 0 #define VXGE_HAL_SWITCH_PORT_RMAC_PAUSE_LIMITER_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 max_limit; #define VXGE_HAL_SWITCH_PORT_MIN_RMAC_MAX_LIMIT 0 #define VXGE_HAL_SWITCH_PORT_MAX_RMAC_MAX_LIMIT 255 #define VXGE_HAL_SWITCH_PORT_DEF_RMAC_MAX_LIMIT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_switch_port_config_t; /* * struct vxge_hal_mac_config_t - MAC configuration (Physical ports). * @wire_port_config: Wire Port configuration * @switch_port_config: Switch Port configuration * @network_stability_period: The wait period for network stability * @mc_pause_threshold: Contains thresholds for pause frame generation * for queues 0 through 15. The threshold value indicates portion * of the individual receive buffer queue size. Thresholds have a * range of 0 to 255, allowing 256 possible watermarks in a queue. * @tmac_perma_stop_en: Controls TMAC reaction to double ECC errors on its * internal SRAMs. * 0 - Disable TMAC permanent stop * 1 - Enable TMAC permanent stop whenever double ECC errors are * detected on the internal transmit SRAMs. * @tmac_tx_switch_dis: Allows the user to disable the switching of transmit * frames back to the receive path. * 0 - Tx frames are switched based on the result of the DA lookup * 1 - The DA lookup result is ignored and all traffic is sent to * the wire. * Note that this register field does not impact the multicast * replication on the receive side. * @tmac_lossy_switch_en: Controls the behaviour of the internal Tx to Rx switch * in the event of back-pressure on the receive path due to * priority given to traffic arriving off the wire or simply due to * a full receive external buffer. br> * 0 - No frames are dropped on the switch path. Instead, in the * event of back-pressure, the transmit path is backed up. * 1 - Whenever back-pressure is present and the next frame is * bound for the switch path, then the frame is dropped. * If it is also destined for the transmit wire, it is still * sent there. * Note: HIP traffic that is bound for the switch path is never * dropped - the transmit path is forced to backup. * @tmac_lossy_wire_en: Controls the behaviour of the TMAC when the wire path * is unavailable. This occurs when the target wire port is down. * 0 - No frames are dropped on the wire path. Instead,in the event * of port failure, the transmit path is backed up. * 1 - Whenever a wire port is down and the next frame is bound for * that port, then the frame is dropped. If it is also destined * for the switch path, it is still sent there. * @tmac_bcast_to_wire_dis: Suppresses the transmission of broadcast frames to * the wire. * 0 - Transmit broadcast frames are sent out the wire and also * sent along the switch path. * 1 - Transmit broadcast frame are only sent along the switch path * @tmac_bcast_to_switch_dis: Suppresses the transmission of broadcast frames * along the switch path. * 0 - Transmit broadcast frames are sent out the wire and also * sent along the switch path. * 1 - Transmit broadcast frame are only sent out the wire. * @tmac_host_append_fcs_en: Suppresses the H/W from appending the FCS to the * end of transmitted frames. The host is responsible for tacking * on the 4-byte FCS at the end of the frame. * 0 - Normal operation. H/W appends FCS to all transmitted frames. * 1 - Host appends FCS to frame. Transmit MAC passes it through * @tpa_support_snap_ab_n: When set to 0, the TPA will accept LLC-SAP values of * 0xAB as valid. If set to 1, the TPA rejects LLC-SAP values of * 0xAB (only 0xAA is accepted). * @tpa_ecc_enable_n: Allows ECC protection of TPA internal memories to be * disabled without having to disable ECC protection for entire * chip. * 0 - Disable TPA ECC protection * 1 - Enable TPA ECC protection. * Note: If chip-wide ECC protection is disabled, then so is TPA * ECC protection. * @rpa_ignore_frame_err: Ignore Frame Error. The RPA may detect frame integrity * errors as it processes each received frame. If this bit is set * to '0', the RPA will tag such frames as "errored" in the RxDMA * descriptor. If the bit is set to '1', the frame will not be * tagged as "errored". * Detectable errors include: * 1) early end-of-frame error, which occurs when the frame ends * before the number of bytes predicted by the IP "total length" * field have been received; * 2) IP version mismatches; * 3) IPv6 packets that include routing headers that are not type 0 * 4) Frames which contain IP packets but have an illegal SNAP-OUI * or LLC-CTRL fields, unless IGNORE_SNAP_OUI or IGNORE_LLC_CTRL * are set * @rpa_support_snap_ab_n: When set to 0, the RPA will accept LLC-SAP values of * 0xAB as valid. If set to 1, the RPA rejects LLC-SAP values of * 0xAB (only 0xAA is accepted). * @rpa_search_for_hao: Enable searching for the Home Address Option.If this bit * is set, the RPA will parse through Destination Address Headers * searching for the H.A.O. If the bit is not set, the RPA will not * perform a search and these headers will effectively be ignored. * @rpa_support_ipv6_mobile_hdrs: Enable/disable support for the mobile-ipv6 * Home Address Option (HAO) and Route 2 Routing Headers,as defined * in RFC 3775. * 0 - Do not support mobile IPv6. * 1 - Support mobile IPv6 * @rpa_ipv6_stop_searching: Enable/disable unknown IPv6 extension header * parsing. If the adapter discovers an unknown extension header, * it can either continue to search for a L4 protocol, or stop * searching. * 0 - do not stop searching for L4 when an unknown header is * encountered. * 1 - stop searching when an unknown header is encountered. * @rpa_no_ps_if_unknown: Enable/disable pseudo-header inclusion if an unknown * IPv6 extension header is encountered. * If this bit is set to '1' and an unknown routing header or IPv6 * extension header is discovered, the L4 checksum will not include * a pseudo-header. * If it is set to '0', the adapter will use the addresses found * in the IPv6 base header, and/or the addresses found in a Routing * Header or Home Address Option (if it is enabled). * This applies to frames not on LRO sessions only. For frames on * LRO sessions, the pseudo-header is always included in the L4 * checksum * @rpa_search_for_etype: For receive traffic steering purposes, indicates * whether the RPA should parse through the LLC header to find the * Ethertype of the packet. * 0 - RPA presents the 802.3 length/type field, which for an * LLC-encoded frame is interpreted as a length. * 1 - RPA parses the LLC-header and presents the Ethertype to the * traffic steering logic. When SEARCH_FOR_ETYPE is set and a jumbo * snap frame is received then GLOBAL_PA_CFG.EN_JS determines the * value that is presented to the traffic steering logic. If EN_JS * is set, then the RPA parses inside the header to find the * Ethertype, while if EN_JS is not set the RPA presents 0x8870. * @rpa_repl_l4_comp_csum: Controls whether or not to complement the L4 checksum * after the final calculation. * 0: Do not complement the L4 checksum. * 1: Complement the L4 checksum. * For the behaviour on non-replicated frames see FAU_RPA_VCFG. * @rpa_repl_l3_incl_cf: Controls whether or not to include the L3 checksum * field in the checksum calculation. * 0: Do not include the L3 checksum field in checksum calculation * 1: Include the L4 checksum field in the checksum calculation. * For the behaviour on non-replicated frames see FAU_RPA_VCFG. * @rpa_repl_l3_comp_csum: Controls whether or not to complement the L3 checksum * after the final calculation. * 0: Do not complement the L3 checksum. * 1: Complement the L3 checksum. * For the behaviour on non-replicated frames see FAU_RPA_VCFG. * @rpa_repl_ipv4_tcp_incl_ph: For received frames that are replicated at the * internal L2 switch, determines whether the pseudo-header is * included in the calculation of the L4 checksum that is passed to * the host. * @rpa_repl_ipv6_tcp_incl_ph: For received frames that are replicated at the * internal L2 switch, determines whether the pseudo-header is * included in the calculation of the L4 checksum that is passed to * the host. * @rpa_repl_ipv4_udp_incl_ph: For received frames that are replicated at the * internal L2 switch, determines whether the pseudo-header is * included in the calculation of the L4 checksum that is passed to * the host. * @rpa_repl_ipv6_udp_incl_ph: For received frames that are replicated at the * internal L2 switch, determines whether the pseudo-header is * included in the calculation of the L4 checksum that is passed to * the host. * @rpa_repl_l4_incl_cf: For received frames that are replicated at the internal * L2 switch, determines whether the checksum field (CF) of the * received frame is included in the calculation of the L4 * checksum that is passed to the host. * @rpa_repl_strip_vlan_tag: Strip VLAN Tag enable/disable. Instructs the device * to remove the VLAN tag from all received tagged frames that * are replicated at the internal L2 switch (i.e. multicast frames * that are placed in the replication queue). * 0 - Do not strip the VLAN tag. * 1 - Strip the VLAN tag. * Regardless of this setting, VLAN tags are always placed into * the RxDMA descriptor. * * MAC configuration. This includes various aspects of configuration, including: * - Pause frame threshold; * - sampling rate to calculate link utilization; * - enabling/disabling broadcasts. * * See X3100 ER User Guide for more details. * Note: Valid (min, max) range for each attribute is specified in the body of * the vxge_hal_mac_config_t {} structure. Please refer to the * corresponding include file. */ typedef struct vxge_hal_mac_config_t { vxge_hal_wire_port_config_t wire_port_config[ \ VXGE_HAL_MAC_MAX_WIRE_PORTS]; vxge_hal_switch_port_config_t switch_port_config; u32 network_stability_period; #define VXGE_HAL_MAC_MIN_NETWORK_STABILITY_PERIOD 0x0 /* 0s */ #define VXGE_HAL_MAC_MAX_NETWORK_STABILITY_PERIOD 0x7 /* 2s */ #define VXGE_HAL_MAC_DEF_NETWORK_STABILITY_PERIOD VXGE_HAL_USE_FLASH_DEFAULT u32 mc_pause_threshold[16]; #define VXGE_HAL_MAC_MIN_MC_PAUSE_THRESHOLD 0 #define VXGE_HAL_MAC_MAX_MC_PAUSE_THRESHOLD 254 #define VXGE_HAL_MAC_DEF_MC_PAUSE_THRESHOLD VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_perma_stop_en; #define VXGE_HAL_MAC_TMAC_PERMA_STOP_ENABLE 1 #define VXGE_HAL_MAC_TMAC_PERMA_STOP_DISABLE 0 #define VXGE_HAL_MAC_TMAC_PERMA_STOP_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_tx_switch_dis; #define VXGE_HAL_MAC_TMAC_TX_SWITCH_ENABLE 0 #define VXGE_HAL_MAC_TMAC_TX_SWITCH_DISABLE 1 #define VXGE_HAL_MAC_TMAC_TX_SWITCH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_lossy_switch_en; #define VXGE_HAL_MAC_TMAC_LOSSY_SWITCH_ENABLE 1 #define VXGE_HAL_MAC_TMAC_LOSSY_SWITCH_DISABLE 0 #define VXGE_HAL_MAC_TMAC_LOSSY_SWITCH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_lossy_wire_en; #define VXGE_HAL_MAC_TMAC_LOSSY_WIRE_ENABLE 1 #define VXGE_HAL_MAC_TMAC_LOSSY_WIRE_DISABLE 0 #define VXGE_HAL_MAC_TMAC_LOSSY_WIRE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_bcast_to_wire_dis; #define VXGE_HAL_MAC_TMAC_BCAST_TO_WIRE_DISABLE 1 #define VXGE_HAL_MAC_TMAC_BCAST_TO_WIRE_ENABLE 0 #define VXGE_HAL_MAC_TMAC_BCAST_TO_WIRE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_bcast_to_switch_dis; #define VXGE_HAL_MAC_TMAC_BCAST_TO_SWITCH_DISABLE 1 #define VXGE_HAL_MAC_TMAC_BCAST_TO_SWITCH_ENABLE 0 #define VXGE_HAL_MAC_TMAC_BCAST_TO_SWITCH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tmac_host_append_fcs_en; #define VXGE_HAL_MAC_TMAC_HOST_APPEND_FCS_ENABLE 1 #define VXGE_HAL_MAC_TMAC_HOST_APPEND_FCS_DISABLE 0 #define VXGE_HAL_MAC_TMAC_HOST_APPEND_FCS_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_support_snap_ab_n; #define VXGE_HAL_MAC_TPA_SUPPORT_SNAP_AB_N_LLC_SAP_AB 0 #define VXGE_HAL_MAC_TPA_SUPPORT_SNAP_AB_N_LLC_SAP_AA 1 #define VXGE_HAL_MAC_TPA_SUPPORT_SNAP_AB_N_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_ecc_enable_n; #define VXGE_HAL_MAC_TPA_ECC_ENABLE_N_ENABLE 1 #define VXGE_HAL_MAC_TPA_ECC_ENABLE_N_DISABLE 0 #define VXGE_HAL_MAC_TPA_ECC_ENABLE_N_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ignore_frame_err; #define VXGE_HAL_MAC_RPA_IGNORE_FRAME_ERR_ENABLE 1 #define VXGE_HAL_MAC_RPA_IGNORE_FRAME_ERR_DISABLE 0 #define VXGE_HAL_MAC_RPA_IGNORE_FRAME_ERR_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_support_snap_ab_n; #define VXGE_HAL_MAC_RPA_SUPPORT_SNAP_AB_N_ENABLE 1 #define VXGE_HAL_MAC_RPA_SUPPORT_SNAP_AB_N_DISABLE 0 #define VXGE_HAL_MAC_RPA_SUPPORT_SNAP_AB_N_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_search_for_hao; #define VXGE_HAL_MAC_RPA_SEARCH_FOR_HAO_ENABLE 1 #define VXGE_HAL_MAC_RPA_SEARCH_FOR_HAO_DISABLE 0 #define VXGE_HAL_MAC_RPA_SEARCH_FOR_HAO_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_support_ipv6_mobile_hdrs; #define VXGE_HAL_MAC_RPA_SUPPORT_IPV6_MOBILE_HDRS_ENABLE 1 #define VXGE_HAL_MAC_RPA_SUPPORT_IPV6_MOBILE_HDRS_DISABLE 0 #define VXGE_HAL_MAC_RPA_SUPPORT_IPV6_MOBILE_HDRS_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ipv6_stop_searching; #define VXGE_HAL_MAC_RPA_IPV6_STOP_SEARCHING 1 #define VXGE_HAL_MAC_RPA_IPV6_DONT_STOP_SEARCHING 0 #define VXGE_HAL_MAC_RPA_IPV6_STOP_SEARCHING_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_no_ps_if_unknown; #define VXGE_HAL_MAC_RPA_NO_PS_IF_UNKNOWN_ENABLE 1 #define VXGE_HAL_MAC_RPA_NO_PS_IF_UNKNOWN_DISABLE 0 #define VXGE_HAL_MAC_RPA_NO_PS_IF_UNKNOWN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_search_for_etype; #define VXGE_HAL_MAC_RPA_SEARCH_FOR_ETYPE_ENABLE 1 #define VXGE_HAL_MAC_RPA_SEARCH_FOR_ETYPE_DISABLE 0 #define VXGE_HAL_MAC_RPA_SEARCH_FOR_ETYPE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_l4_comp_csum; #define VXGE_HAL_MAC_RPA_REPL_L4_COMP_CSUM_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_L4_COMP_CSUM_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_l4_COMP_CSUM_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_l3_incl_cf; #define VXGE_HAL_MAC_RPA_REPL_L3_INCL_CF_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_L3_INCL_CF_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_L3_INCL_CF_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_l3_comp_csum; #define VXGE_HAL_MAC_RPA_REPL_L3_COMP_CSUM_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_L3_COMP_CSUM_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_l3_COMP_CSUM_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_ipv4_tcp_incl_ph; #define VXGE_HAL_MAC_RPA_REPL_IPV4_TCP_INCL_PH_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_IPV4_TCP_INCL_PH_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_IPV4_TCP_INCL_PH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_ipv6_tcp_incl_ph; #define VXGE_HAL_MAC_RPA_REPL_IPV6_TCP_INCL_PH_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_IPV6_TCP_INCL_PH_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_IPV6_TCP_INCL_PH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_ipv4_udp_incl_ph; #define VXGE_HAL_MAC_RPA_REPL_IPV4_UDP_INCL_PH_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_IPV4_UDP_INCL_PH_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_IPV4_UDP_INCL_PH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_ipv6_udp_incl_ph; #define VXGE_HAL_MAC_RPA_REPL_IPV6_UDP_INCL_PH_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_IPV6_UDP_INCL_PH_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_IPV6_UDP_INCL_PH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_l4_incl_cf; #define VXGE_HAL_MAC_RPA_REPL_L4_INCL_CF_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_L4_INCL_CF_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_L4_INCL_CF_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_repl_strip_vlan_tag; #define VXGE_HAL_MAC_RPA_REPL_STRIP_VLAN_TAG_ENABLE 1 #define VXGE_HAL_MAC_RPA_REPL_STRIP_VLAN_TAG_DISABLE 0 #define VXGE_HAL_MAC_RPA_REPL_STRIP_VLAN_TAG_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_mac_config_t; /* * struct vxge_hal_lag_port_config_t - LAG Port configuration(For privileged * mode driver only) * * @port_id: Port Id * @lag_en: Enables or disables the port from joining a link aggregation group. * If link aggregation is enabled and this port is disabled, then * this port does not carry traffic (it is not associated with an * Aggregator). Both this bit and port_enabled from the physical * layer logic must be asserted to permit the Receive machine to * move beyond the PORT_DISABLED state. * 0 - Disable; * 1 - Enable; * @discard_slow_proto: Discard received frames that contain the Slow Protocols * Multicast address (IEEE 802.3-2005 Clause 43B) -- Such frames * are used for link aggregation Marker Protocol and for LACP. * 0 - Pass to host; * 1 - Discard; * @host_chosen_aggr: When the host is running the Link Aggregation Control * algorithm, this field determines which aggregator is attached * to this port. This field is only valid when LAG_LACP_CFG.EN is 0 * 0 - Aggregator 0 is attached to this port. * 1 - Aggregator 1 is attached to this port. * @discard_unknown_slow_proto: Discard received frames that contain the Slow * Protocols Multicast address (IEEE 802.3-2005 Clause 43B), * but have an unknown Slow Protocols PDU. * 0 - Pass to host * 1 - Discard * Note: This field is only relevant when DISCARD_SLOW_PROTO * is set to 0. * @actor_port_num: The port number assigned to the port. Port Number 0 is * reserved and must not be assigned to any port. * @actor_port_priority: The priority value assigned to the port. * @actor_key_10g: The port's administrative Key when auto-negotiated to 10Gbps * The null (all zeros) Key value is not available for local use. * @actor_key_1g: The port's administrative Key when auto-negotiated to 1Gbps. * The null (all zeros) Key value is not available for local use. * @actor_lacp_activity: Indicates the Activity control value for this port. * 0 - Passive LACP * 1 - Active LACP * @actor_lacp_timeout: Indicates the Timeout control value for this port. * 0 - Long Timeout * 1 - Short Timeout * @actor_aggregation: Indicates if the port is a potential candidate for * aggregation. * 0 - Link is Individual * 1 - Link is Aggregateable * @actor_synchronization: Indicates if the port is in sync. * 0 - Link is out of sync; it is in the wrong Aggregation * 1 - Link is in sync (allocated to the correct Link Aggregation * Group, the group is associated with a compatible Aggregator, * and the identity of the Link Aggregation Group is consistent * with the System ID and operational Key information transmitted) * @actor_collecting: Indicates whether collecting of incoming frames is enabled * on this port. * 0 - Not collecting * 1 - Collection is enabled * @actor_distributing: Indicates whether distribution of outgoing frames is * enabled on this port. * 0 - Not distributing * 1 - Distribution is enabled * @actor_defaulted: Indicates whether the Actor's Receive state machine is * using administratively configured information for the Partner. * 0 - The operational Partner info has been received in a LACPDU * 1 - The operation Partner info is using administrative defaults * @actor_expired: Indicates whether the Actor's Receive state machine is in the * EXPIRED state. * 0 - Not in the EXPIRED state * 1 - Is in the EXPIRED state * @partner_sys_pri: The administrative default for the System Priority * component of the System Identifier of the Partner. * @partner_key: The administrative default for the Partner's Key. The null * (all zeros) Key value is not available for local use. * @partner_port_num: The administrative default for the Port Number component * of the Partner's Port Identifier. * @partner_port_priority: The administrative default for the Port Identifier * component of the Partner's Port Identifier. * @partner_lacp_activity: Indicates the Activity control value for this port. * 0 - Passive LACP * 1 - Active LACP * @partner_lacp_timeout: Indicates the Timeout control value for this port. * 0 - Long Timeout * 1 - Short Timeout * @partner_aggregation: Indicates if the port is a potential candidate for * aggregation. * 0 - Link is Individual * 1 - Link is Aggregateable * @partner_synchronization: Indicates if the port is in sync. * 0 - Link is out of sync; it is in the wrong Aggregation * 1 - Link is in sync (allocated to the correct Link Aggregation * Group, the group is associated with a compatible Aggregator, * and the identity of the Link Aggregation Group is consistent * with the System ID and operational Key information transmitted) * @partner_collecting: Indicates whether collecting of incoming frames is * enabled on this port. * 0 - Not collecting * 1 - Collection is enabled. * Note: According to IEEE 802.3-2005, the value of the * partner_collecting field of this register must be the same as * the value of the partner_synchronization field of this register * @partner_distributing: Indicates whether distribution of outgoing frames is * enabled on this port. * 0 - Not distributing * 1 - Distribution is enabled * @partner_defaulted: Indicates whether the Actor's Receive state machine is * using administratively configured information for the Partner. * 0 - The operational Partner information has been received in * a LACPDU * 1 - The operation Partner information is using administrative * defaults * @partner_expired: Indicates whether the Actor's Receive state machine is in * the expired state. * 0 - Not in the EXPIRED state * 1 - Is in the EXPIRED state * @partner_mac_addr: Default value for the MAC address of the Partner. * * This structure is configuration for LAG Port of device */ typedef struct vxge_hal_lag_port_config_t { u32 port_id; #define VXGE_HAL_LAG_PORT_PORT_ID_0 1 #define VXGE_HAL_LAG_PORT_PORT_ID_1 2 #define VXGE_HAL_LAG_PORT_MAX_PORTS VXGE_HAL_MAC_MAX_WIRE_PORTS u32 lag_en; #define VXGE_HAL_LAG_PORT_LAG_EN_DISABLE 0 #define VXGE_HAL_LAG_PORT_LAG_EN_ENABLE 1 #define VXGE_HAL_LAG_PORT_LAG_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 discard_slow_proto; #define VXGE_HAL_LAG_PORT_DISCARD_SLOW_PROTO_DISABLE 0 #define VXGE_HAL_LAG_PORT_DISCARD_SLOW_PROTO_ENABLE 1 #define VXGE_HAL_LAG_PORT_DISCARD_SLOW_PROTO_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 host_chosen_aggr; #define VXGE_HAL_LAG_PORT_HOST_CHOSEN_AGGR_0 0 #define VXGE_HAL_LAG_PORT_HOST_CHOSEN_AGGR_1 1 #define VXGE_HAL_LAG_PORT_HOST_CHOSEN_AGGR_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 discard_unknown_slow_proto; #define VXGE_HAL_LAG_PORT_DISCARD_UNKNOWN_SLOW_PROTO_DISABLE 0 #define VXGE_HAL_LAG_PORT_DISCARD_UNKNOWN_SLOW_PROTO_ENABLE 1 #define VXGE_HAL_LAG_PORT_DISCARD_UNKNOWN_SLOW_PROTO_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 actor_port_num; #define VXGE_HAL_LAG_PORT_MIN_ACTOR_PORT_NUM 0 #define VXGE_HAL_LAG_PORT_MAX_ACTOR_PORT_NUM 65535 #define VXGE_HAL_LAG_PORT_DEF_ACTOR_PORT_NUM VXGE_HAL_USE_FLASH_DEFAULT u32 actor_port_priority; #define VXGE_HAL_LAG_PORT_MIN_ACTOR_PORT_PRIORITY 0 #define VXGE_HAL_LAG_PORT_MAX_ACTOR_PORT_PRIORITY 65535 #define VXGE_HAL_LAG_PORT_DEF_ACTOR_PORT_PRIORITY VXGE_HAL_USE_FLASH_DEFAULT u32 actor_key_10g; #define VXGE_HAL_LAG_PORT_MIN_ACTOR_KEY_10G 0 #define VXGE_HAL_LAG_PORT_MAX_ACTOR_KEY_10G 65535 #define VXGE_HAL_LAG_PORT_DEF_ACTOR_KEY_10G VXGE_HAL_USE_FLASH_DEFAULT u32 actor_key_1g; #define VXGE_HAL_LAG_PORT_MIN_ACTOR_KEY_1G 0 #define VXGE_HAL_LAG_PORT_MAX_ACTOR_KEY_1G 65535 #define VXGE_HAL_LAG_PORT_DEF_ACTOR_KEY_1G VXGE_HAL_USE_FLASH_DEFAULT u32 actor_lacp_activity; #define VXGE_HAL_LAG_PORT_ACTOR_LACP_ACTIVITY_PASSIVE 0 #define VXGE_HAL_LAG_PORT_ACTOR_LACP_ACTIVITY_ACTIVE 1 #define VXGE_HAL_LAG_PORT_ACTOR_LACP_ACTIVITY_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 actor_lacp_timeout; #define VXGE_HAL_LAG_PORT_ACTOR_LACP_TIMEOUT_LONG 0 #define VXGE_HAL_LAG_PORT_ACTOR_LACP_TIMEOUT_SHORT 1 #define VXGE_HAL_LAG_PORT_ACTOR_LACP_TIMEOUT_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 actor_aggregation; #define VXGE_HAL_LAG_PORT_ACTOR_AGGREGATION_INDIVIDUAL 0 #define VXGE_HAL_LAG_PORT_ACTOR_AGGREGATION_AGGREGATEABLE 1 #define VXGE_HAL_LAG_PORT_ACTOR_AGGREGATION_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 actor_synchronization; #define VXGE_HAL_LAG_PORT_ACTOR_SYNCHRONIZATION_OUT_OF_SYNC 0 #define VXGE_HAL_LAG_PORT_ACTOR_SYNCHRONIZATION_IN_SYNC 1 #define VXGE_HAL_LAG_PORT_ACTOR_SYNCHRONIZATION_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 actor_collecting; #define VXGE_HAL_LAG_PORT_ACTOR_COLLECTING_DISABLE 0 #define VXGE_HAL_LAG_PORT_ACTOR_COLLECTING_ENABLE 1 #define VXGE_HAL_LAG_PORT_ACTOR_COLLECTING_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 actor_distributing; #define VXGE_HAL_LAG_PORT_ACTOR_DISTRIBUTING_DISABLE 0 #define VXGE_HAL_LAG_PORT_ACTOR_DISTRIBUTING_ENABLE 1 #define VXGE_HAL_LAG_PORT_ACTOR_DISTRIBUTING_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 actor_defaulted; #define VXGE_HAL_LAG_PORT_ACTOR_DEFAULTED 0 #define VXGE_HAL_LAG_PORT_ACTOR_NOT_DEFAULTED 1 #define VXGE_HAL_LAG_PORT_ACTOR_DEFAULTED_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 actor_expired; #define VXGE_HAL_LAG_PORT_ACTOR_EXPIRED 0 #define VXGE_HAL_LAG_PORT_ACTOR_NOT_EXPIRED 1 #define VXGE_HAL_LAG_PORT_ACTOR_EXPIRED_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 partner_sys_pri; #define VXGE_HAL_LAG_PORT_MIN_PARTNER_SYS_PRI 0 #define VXGE_HAL_LAG_PORT_MAX_PARTNER_SYS_PRI 65535 #define VXGE_HAL_LAG_PORT_DEF_PARTNER_SYS_PRI VXGE_HAL_USE_FLASH_DEFAULT u32 partner_key; #define VXGE_HAL_LAG_PORT_MIN_PARTNER_KEY 0 #define VXGE_HAL_LAG_PORT_MAX_PARTNER_KEY 65535 #define VXGE_HAL_LAG_PORT_DEF_PARTNER_KEY VXGE_HAL_USE_FLASH_DEFAULT u32 partner_port_num; #define VXGE_HAL_LAG_PORT_MIN_PARTNER_PORT_NUM 0 #define VXGE_HAL_LAG_PORT_MAX_PARTNER_PORT_NUM 65535 #define VXGE_HAL_LAG_PORT_DEF_PARTNER_PORT_NUM VXGE_HAL_USE_FLASH_DEFAULT u32 partner_port_priority; #define VXGE_HAL_LAG_PORT_MIN_PARTNER_PORT_PRIORITY 0 #define VXGE_HAL_LAG_PORT_MAX_PARTNER_PORT_PRIORITY 65535 #define VXGE_HAL_LAG_PORT_DEF_PARTNER_PORT_PRIORITY VXGE_HAL_USE_FLASH_DEFAULT u32 partner_lacp_activity; #define VXGE_HAL_LAG_PORT_PARTNER_LACP_ACTIVITY_PASSIVE 0 #define VXGE_HAL_LAG_PORT_PARTNER_LACP_ACTIVITY_ACTIVE 1 #define VXGE_HAL_LAG_PORT_PARTNER_LACP_ACTIVITY_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_lacp_timeout; #define VXGE_HAL_LAG_PORT_PARTNER_LACP_TIMEOUT_LONG 0 #define VXGE_HAL_LAG_PORT_PARTNER_LACP_TIMEOUT_SHORT 1 #define VXGE_HAL_LAG_PORT_PARTNER_LACP_TIMEOUT_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_aggregation; #define VXGE_HAL_LAG_PORT_PARTNER_AGGREGATION_INDIVIDUAL 0 #define VXGE_HAL_LAG_PORT_PARTNER_AGGREGATION_AGGREGATEABLE 1 #define VXGE_HAL_LAG_PORT_PARTNER_AGGREGATION_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_synchronization; #define VXGE_HAL_LAG_PORT_PARTNER_SYNCHRONIZATION_OUT_OF_SYNC 0 #define VXGE_HAL_LAG_PORT_PARTNER_SYNCHRONIZATION_IN_SYNC 1 #define VXGE_HAL_LAG_PORT_PARTNER_SYNCHRONIZATION_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_collecting; #define VXGE_HAL_LAG_PORT_PARTNER_COLLECTING_DISABLE 0 #define VXGE_HAL_LAG_PORT_PARTNER_COLLECTING_ENABLE 1 #define VXGE_HAL_LAG_PORT_PARTNER_COLLECTING_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_distributing; #define VXGE_HAL_LAG_PORT_PARTNER_DISTRIBUTING_DISABLE 0 #define VXGE_HAL_LAG_PORT_PARTNER_DISTRIBUTING_ENABLE 1 #define VXGE_HAL_LAG_PORT_PARTNER_DISTRIBUTING_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 partner_defaulted; #define VXGE_HAL_LAG_PORT_PARTNER_DEFAULTED 0 #define VXGE_HAL_LAG_PORT_PARTNER_NOT_DEFAULTED 1 #define VXGE_HAL_LAG_PORT_PARTNER_DEFAULTED_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 partner_expired; #define VXGE_HAL_LAG_PORT_PARTNER_EXPIRED 0 #define VXGE_HAL_LAG_PORT_PARTNER_NOT_EXPIRED 1 #define VXGE_HAL_LAG_PORT_PARTNER_EXPIRED_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT macaddr_t partner_mac_addr; } vxge_hal_lag_port_config_t; /* * struct vxge_hal_lag_aggr_config_t - LAG Aggregator configuration * (For privileged mode driver only) * * @aggr_id: Aggregator Id * @mac_addr: The MAC address assigned to the Aggregator. * @use_port_mac_addr: Indicates whether the Aggregator should use: * 0 - the address specified in this register * 1 - the station address of one of the ports to which * it is attached * @mac_addr_sel: Indicates which port address to use, if use_port_mac_addr * is set and two ports are attached to the aggregator: * 0 - the station address of port 0 * 1 - the station address of port 1. * @admin_key: The Aggregator's administrative Key under most circumstances * (see alt_admin_key for exceptions). The null (all zeros) Key * value is not available for local use. * This structure is configuration for LAG Aggregators of device */ typedef struct vxge_hal_lag_aggr_config_t { u32 aggr_id; #define VXGE_HAL_LAG_AGGR_AGGR_ID_1 1 #define VXGE_HAL_LAG_AGGR_AGGR_ID_2 2 #define VXGE_HAL_LAG_AGGR_MAX_PORTS VXGE_HAL_MAC_MAX_AGGR_PORTS macaddr_t mac_addr; u32 use_port_mac_addr; #define VXGE_HAL_LAG_AGGR_USE_PORT_MAC_ADDR_DISBALE 0 #define VXGE_HAL_LAG_AGGR_USE_PORT_MAC_ADDR_ENABLE 1 #define VXGE_HAL_LAG_AGGR_USE_PORT_MAC_ADDR_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 mac_addr_sel; #define VXGE_HAL_LAG_AGGR_MAC_ADDR_SEL_PORT_0 0 #define VXGE_HAL_LAG_AGGR_MAC_ADDR_SEL_PORT_1 1 #define VXGE_HAL_LAG_AGGR_MAC_ADDR_SEL_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 admin_key; #define VXGE_HAL_LAG_AGGR_MIN_ADMIN_KEY 0 #define VXGE_HAL_LAG_AGGR_MAX_ADMIN_KEY 65535 #define VXGE_HAL_LAG_AGGR_DEF_ADMIN_KEY VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_aggr_config_t; /* * struct vxge_hal_lag_la_config_t - LAG Link Aggregator mode configuration( * For privileged mode driver only) * * @tx_discard: When the state of the port state attached to the Tx Aggregator * is not Distributing, this field determines whether frames from * the Frame Distributor are discarded by the Aggregator Mux * @distrib_alg_sel: Configures the link aggregation distribution algorithm, * which determines the destination port of each wire-bound frame. * 0x0 - The source VPATH determines the target port and the * mapping is controlled by the MAP_VPATHn fields of this * register. * 0x1 - Even parity over the frame's MAC destination address * 0x2 - Even parity over the frame's MAC source address * 0x3 - Even parity over the frame's MAC destination address and * MAC source address * Note: If the host changes this mapping while traffic is flowing, * then (to avoid mis-ordering at the receiver) host must either * enable the Marker protocol or assume responsibility for ensuring * that no frames pertaining to the conversations (that are moving * to a new port) are in flight. * @distrib_dest: When LAG_TX_CFG.DISTRIB_ALG_SEL is set to use the source * VPATH, then this field indicates the target adapter port for * frames that come from a particular VPATH. * 0 - Send frames from this VPATH to port 0 * 1 - Send frames from this VPATH to port 1 * Note: If the host updates this mapping while traffic is flowing, * then (to avoid mis-ordering at the receiver) the host must * either enable the Marker protocol or assume responsibility for * ensuring that no frames pertaining to the conversations (that * are moving to a new port) are in flight. * @distrib_remap_if_fail: When lag_mode is Link Aggregated, this field controls * whether frames are re-distributed to the working port if one * port goes down. * 0 - Don't remap. Enforce frames destined for port 'x' to remain * destined for it and let LAG_CFG.TX_DISCARD_BEHAV determine * what happens to the frames. * 1 - Remap the frames to the working port, essentially ignoring * the mapping table. * @coll_max_delay: Collector Max Delay - the maximum amount of time (measured * in units of tens of microseconds) that the Frame Collector is * allowed to delay delivery of frames to the host. The contents * of this field are placed into the transmitted LACPDU. * @rx_discard: When the state of the port state attached to the Rx Aggregator * is not Collecting, this field determines whether frames to the * Frame Collector are discarded by the Aggregator Parser * * Link Aggregation Link Aggregator Mode Configuration */ typedef struct vxge_hal_lag_la_config_t { u32 tx_discard; #define VXGE_HAL_LAG_TX_DISCARD_DISBALE 0 #define VXGE_HAL_LAG_TX_DISCARD_ENABLE 1 #define VXGE_HAL_LAG_TX_DISCARD_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 distrib_alg_sel; #define VXGE_HAL_LAG_DISTRIB_ALG_SEL_SRC_VPATH 0 #define VXGE_HAL_LAG_DISTRIB_ALG_SEL_DEST_MAC_ADDR 1 #define VXGE_HAL_LAG_DISTRIB_ALG_SEL_SRC_MAC_ADDR 2 #define VXGE_HAL_LAG_DISTRIB_ALG_SEL_BOTH_MAC_ADDR 3 #define VXGE_HAL_LAG_DISTRIB_ALG_SEL_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u64 distrib_dest; #define VXGE_HAL_LAG_DISTRIB_DEST_VPATH_TO_PORT_PORT0(vpid) 0 #define VXGE_HAL_LAG_DISTRIB_DEST_VPATH_TO_PORT_PORT1(vpid) mBIT(vpid) #define VXGE_HAL_LAG_DISTRIB_DEST_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 distrib_remap_if_fail; #define VXGE_HAL_LAG_DISTRIB_REMAP_IF_FAIL_DISBALE 0 #define VXGE_HAL_LAG_DISTRIB_REMAP_IF_FAIL_ENABLE 1 #define VXGE_HAL_LAG_DISTRIB_REMAP_IF_FAIL_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 coll_max_delay; #define VXGE_HAL_LAG_MIN_COLL_MAX_DELAY 0 #define VXGE_HAL_LAG_MAX_COLL_MAX_DELAY 65535 #define VXGE_HAL_LAG_DEF_COLL_MAX_DELAY VXGE_HAL_USE_FLASH_DEFAULT u32 rx_discard; #define VXGE_HAL_LAG_RX_DISCARD_DISBALE 0 #define VXGE_HAL_LAG_RX_DISCARD_ENABLE 1 #define VXGE_HAL_LAG_RX_DISCARD_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_la_config_t; /* * struct vxge_hal_lag_ap_config_t - LAG Active Passive Failover mode * configuration(For privileged mode driver only) * * @hot_standby: Keep the standby port alive even when it is not carrying * traffic * 0 - Standby port disabled until needed. The hardware behaves as * if XGMAC_CFG_PORTn.PORT_EN has disabled the port. * 1 - Standby port kept up * @lacp_decides: This field determines whether or not the LACP Selection logic * handles hot standby port interaction. This field is only used * when hot_standby is 1. * 0 - LACP Selection logic does not explicitly determine standby * port, instead internal logic changes the aggregator's key * using information found in the alt_admin_key * field. Note that this does not disable LACP. * 1 - LACP Selection logic explicitly determines standby port by * enforcing a rule that if one port is already attached to any * aggregator, then the other port is put into STANDBY. Assuming * both ports have the same Key, at startup (or anytime both * ports have become UNSELECTED) the Selection logic uses * pref_active_port to choose the active (and consequently * standby) port. After that it only selects a new port when * the active port goes down. * @pref_active_port: Indicates the preferred active port number. * If hot_standby is disabled (i.e. "cold standby"), then * pref_active_port determines which port remains powered up * (and consequently which one is powered down). If hot_standby is * enabled, then pref_active_port is used by the Selection logic * whenever both ports have become UNSELECTED and the Selection * logic must decide which to make SELECTED and which to make * STANDBY. * 0 - Link0 is preferred (Link1 becomes the standby port). * 1 - Link1 is preferred * @auto_failback: When LACP Selection logic is not handling standby port * interaction, this register provides additional user flexibility * for standby port handling. The AUTO_FAILBACK field controls * whether the device automatically fails back to the preferred * (i.e. non-alternate) Aggregator+Port pair in the event that the * preferred port comes back up after a failure. Only used when * hot_standby is set to 1 and lacp_decides is set to 0. * 0 - After a failure on the preferred port, stay on alternate * port even if the preferred port comes back up. Return to * preferred port only when host indicates to return * (via FAILBACK_EN) * 1 - After a failure on the preferred port,automatically failback * to preferred port whenever it comes back up. * @failback_en: This field is used when hot_standby is set to 1,lacp_decides is * set to 0, and AUTO_FAILBACK is set to 0. The field is also used * when hot_standby is set to 0. The failback_en field allow the * host to control when the adapter is allowed to fail back to the * preferred port. The driver sets this field to indicate to the * adapter that it okay to fail back to the preferred port (i.e. * attempt to acquire a good port on the preferred port). This * field is self-clearing -- the adapter clears it immediately. * Note that the host can use waiting_to_fallback to tell if the * adapter is waiting for host intervention. * 0 - Adapter has acknowledged the request to fail back. * 1 - Host requests that the adapter fail back to preferred port. * @cold_failover_timeout: When cold standby mode is entered, this field * controls how long (in msec) the adapter waits for the preferred * port to come alive (assuming it isn't alreay alive. It the * preferred port does not come up, then the adapter fails over * to the standby port when the timer expires. At the time of * standby port initialization, the timer is started again and * if the standby port does not come up after the timer expires, * then both ports are shut down. * @alt_admin_key: The Aggregator's administrative Key whenever the device is in * active-passive failover mode and both ports are up. This * prevents both ports from becoming active in this case. * The H/W is responsible for choosing the proper key to use in * this case. The null (all zeros) Key value is not available for * local use. * @alt_aggr: Identifies which Aggregator is designated as the alternate * (i.e. unused) Aggregator, when both ports are up. * 0 - Aggregator0 is the alternate * 1 - Aggregator1 is the alternate * * Link Aggregation Active Passive failover mode Configuration */ typedef struct vxge_hal_lag_ap_config_t { u32 hot_standby; #define VXGE_HAL_LAG_HOT_STANDBY_DISBALE_PORT 0 #define VXGE_HAL_LAG_HOT_STANDBY_KEEP_UP_PORT 1 #define VXGE_HAL_LAG_HOT_STANDBY_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 lacp_decides; #define VXGE_HAL_LAG_LACP_DECIDES_DISBALE 0 #define VXGE_HAL_LAG_LACP_DECIDES_ENBALE 1 #define VXGE_HAL_LAG_LACP_DECIDES_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 pref_active_port; #define VXGE_HAL_LAG_PREF_ACTIVE_PORT_0 0 #define VXGE_HAL_LAG_PREF_ACTIVE_PORT_1 1 #define VXGE_HAL_LAG_PREF_ACTIVE_PORT_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 auto_failback; #define VXGE_HAL_LAG_AUTO_FAILBACK_DISBALE 0 #define VXGE_HAL_LAG_AUTO_FAILBACK_ENBALE 1 #define VXGE_HAL_LAG_AUTO_FAILBACK_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 failback_en; #define VXGE_HAL_LAG_FAILBACK_EN_DISBALE 0 #define VXGE_HAL_LAG_FAILBACK_EN_ENBALE 1 #define VXGE_HAL_LAG_FAILBACK_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 cold_failover_timeout; #define VXGE_HAL_LAG_MIN_COLD_FAILOVER_TIMEOUT 0 #define VXGE_HAL_LAG_MAX_COLD_FAILOVER_TIMEOUT 65535 #define VXGE_HAL_LAG_DEF_COLD_FAILOVER_TIMEOUT VXGE_HAL_USE_FLASH_DEFAULT u32 alt_admin_key; #define VXGE_HAL_LAG_MIN_ALT_ADMIN_KEY 0 #define VXGE_HAL_LAG_MAX_ALT_ADMIN_KEY 65535 #define VXGE_HAL_LAG_DEF_ALT_ADMIN_KEY VXGE_HAL_USE_FLASH_DEFAULT u32 alt_aggr; #define VXGE_HAL_LAG_ALT_AGGR_0 0 #define VXGE_HAL_LAG_ALT_AGGR_1 1 #define VXGE_HAL_LAG_ALT_AGGR_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_ap_config_t; /* * struct vxge_hal_lag_sl_config_t - LAG Single Link configuration(For * privileged mode driver only) * * @pref_indiv_port: For Single Link mode, this field indicates the preferred * active port number. It is used by the Selection logic whenever * both ports have become UNSELECTED and the Selection logic must * decide which to make SELECTED and which to keep UNSELECTED. * This field is only valid when the MODE field is set to * 'Single Link'. * * Link Aggregation Single Link Configuration */ typedef struct vxge_hal_lag_sl_config_t { u32 pref_indiv_port; #define VXGE_HAL_LAG_PREF_INDIV_PORT_0 0 #define VXGE_HAL_LAG_PREF_INDIV_PORT_1 1 #define VXGE_HAL_LAG_PREF_INDIV_PORT_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_sl_config_t; /* * struct vxge_hal_lag_lacp_config_t - LAG LACP configuration(For privileged * mode driver only) * * @lacp_en: Enables use of the on-chip LACP implementation. * @lacp_begin: Re-initializes the LACP protocol state machines. * @discard_lacp: If LACP is not enabled on the device, then all LACP frames * are passed to the host. However, when LACP is enabled,this field * determines whether the LACP frames are still passed to the host. * @liberal_len_chk: Controls the length checks that are performed on the * received LACPDU by the RX FSM. Normally, the received value of * the following length fields is a known constant and(as suggested * by IEEE 802.3-2005 43.4.12) the hardware validates them: * Actor_Information_Length, Partner_Information_Length, * Collector_Information_Length, and Terminator_Information_Length. * @marker_gen_recv_en: Enables marker generator/receiver. If this functionality * is disabled, then the host must assume responsibility for * ensuring that no frames pertaining to the conversations (that * are moving to a new port) are in flight, whenever the transmit * distribution algorithm is updated. * @marker_resp_en: Enables the transmission of Marker Response PDUs. Adapter * sends a Marker Response PDU in response to a received Marker PDU * @marker_resp_timeout: Timeout value for response to Marker frame - number * of milliseconds that the frame distribution logic will wait * before assuming that all frames transmitted on a particular * conversation have been successfully received. If a Marker * Response PDU comes back before the timer expires, then the * same assumption is made. * @slow_proto_mrkr_min_interval: Minimum interval (in milliseconds) between * Marker PDU transmissions. Includes both Marker PDUs and Marker * Response PDUs. According to IEEE 802.3-2005 Annex 43B.2, the * device should send no more than 10 frames in any one-second * period. Thus, waiting 100ms between successive transmission * of Slow Protocol frames for the Marker Protocol (i.e. those * that are sourced by our Marker Generator), guarantee that we * satisfy this requirement. To be overly conservative the default * value of this register allows for 200ms between frames. * @throttle_mrkr_resp: Permits the adapter to throttle the tranmission of * Marker Response PDUs to satisfy the Slow Protocols transmission * rate (see IEEE 802.3-2005 Annex 43B). * 0 - Transmission of Marker Response PDUs is not moderated. * A Marker Response PDU is sent in response to every received * Marker frame, regardless of whether the Marker frames are * being received at a rate below the Slow Protocols rate. * 1 - Limit the transmission of Marker Response PDUs to the Slow * Protocols transmission rate. If a remote host is generating * Marker frames too quickly, then some of these frames will * have no corresponding Marker Response PDU generated by the * adapter. * * Link Aggregation LACP Configuration */ typedef struct vxge_hal_lag_lacp_config_t { u32 lacp_en; #define VXGE_HAL_LAG_LACP_EN_DISBALE 0 #define VXGE_HAL_LAG_LACP_EN_ENABLE 1 #define VXGE_HAL_LAG_LACP_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 lacp_begin; #define VXGE_HAL_LAG_LACP_BEGIN_NORMAL 0 #define VXGE_HAL_LAG_LACP_BEGIN_RESET 1 #define VXGE_HAL_LAG_LACP_BEGIN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 discard_lacp; #define VXGE_HAL_LAG_DISCARD_LACP_DISBALE 0 #define VXGE_HAL_LAG_DISCARD_LACP_ENABLE 1 #define VXGE_HAL_LAG_DISCARD_LACP_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 liberal_len_chk; #define VXGE_HAL_LAG_LIBERAL_LEN_CHK_DISBALE 0 #define VXGE_HAL_LAG_LIBERAL_LEN_CHK_ENABLE 1 #define VXGE_HAL_LAG_LIBERAL_LEN_CHK_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 marker_gen_recv_en; #define VXGE_HAL_LAG_MARKER_GEN_RECV_EN_DISBALE 0 #define VXGE_HAL_LAG_MARKER_GEN_RECV_EN_ENABLE 1 #define VXGE_HAL_LAG_MARKER_GEN_RECV_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 marker_resp_en; #define VXGE_HAL_LAG_MARKER_RESP_EN_DISBALE 0 #define VXGE_HAL_LAG_MARKER_RESP_EN_ENABLE 1 #define VXGE_HAL_LAG_MARKER_RESP_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 marker_resp_timeout; #define VXGE_HAL_LAG_MIN_MARKER_RESP_TIMEOUT 0 #define VXGE_HAL_LAG_MAX_MARKER_RESP_TIMEOUT 65535 #define VXGE_HAL_LAG_DEF_MARKER_RESP_TIMEOUT VXGE_HAL_USE_FLASH_DEFAULT u32 slow_proto_mrkr_min_interval; #define VXGE_HAL_LAG_MIN_SLOW_PROTO_MRKR_MIN_INTERVAL 0 #define VXGE_HAL_LAG_MAX_SLOW_PROTO_MRKR_MIN_INTERVAL 65535 #define VXGE_HAL_LAG_DEF_SLOW_PROTO_MRKR_MIN_INTERVAL \ VXGE_HAL_USE_FLASH_DEFAULT u32 throttle_mrkr_resp; #define VXGE_HAL_LAG_THROTTLE_MRKR_RESP_DISBALE 0 #define VXGE_HAL_LAG_THROTTLE_MRKR_RESP_ENABLE 1 #define VXGE_HAL_LAG_THROTTLE_MRKR_RESP_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_lacp_config_t; /* * struct vxge_hal_lag_config_t - LAG configuration(For privileged * mode driver only) * * @lag_en: Enables link aggregation * @lag_mode: Select the mode of operation for link aggregation. The options: * 00 - Link Aggregated * 01 - Active/Passive Failover * 10 - Single Link * @la_mode_config: LAG Link Aggregator mode config * @ap_mode_config: LAG Active Passive Failover mode config * @sl_mode_config: LAG Single Link mode config * @lacp_config: LAG LACP config * @incr_tx_aggr_stats: Controls whether Tx aggregator stats are incremented * when Link Aggregation is disabled. * 0 - Don't increment * 1 - Increment * Note: When LAG is enabled, aggregator stats are always * incremented. * @port_config: Lag Port configuration. See vxge_hal_lag_port_config_t {} * @aggr_config: Lag Aggregator configuration. See vxge_hal_lag_aggr_config_t {} * @sys_pri: The System Priority of the System. Numerically lower values have * higher priority. * @mac_addr: The MAC address assigned to the System. Should be non-zero. * @use_port_mac_addr: Indicates whether the Aggregator should use: * 0 - the address specified in this register. * 1 - the station address of one of the ports in the System * @mac_addr_sel: Indicates which port address to use, if USE_PORT_ADDR is set: * 0 - the station address of port 0 * 1 - the station address of port 1. * @fast_per_time: Fast Periodic Time - number of seconds between periodic * transmissions of Short Timeouts. * @slow_per_time: Slow Periodic Time - number of seconds between periodic * transmissions of Long Timeouts. * @short_timeout: Short Timeout Time - number of seconds before * invalidating received LACPDU information using Short * Timeouts (3 x Fast Periodic Time). * @long_timeout: Long Timeout Time - number of seconds before invalidating * received LACPDU information using Long Timeouts * (3 x Slow Periodic Time). * @churn_det_time: Churn Detection Time - number of seconds that the * Actor and Partner Churn state machines wait for the Actor * or Partner Sync state to stabilize. * @aggr_wait_time: Aggregate Wait Time - number of seconds to delay * aggregation,to allow multiple links to aggregate simultaneously * @short_timer_scale: For simulation purposes, this field allows scaling of * link aggregation timers. Specifically, the included timers are * short (programmed with units of msec) and include 'Emptied Link * Timer', 'Slow Proto Timer for Marker PDU', 'Slow Proto Timer for * Marker Response PDU', and 'Cold Failover Timer'. * 0x0 - No scaling * 0x1 - Scale by 10X (counter expires 10 times faster) * 0x2 - Scale by 100X * 0x3 - Scale by 1000X * @long_timer_scale: For simulation purposes, this field allows scaling of link * aggregation timers. Specifically, the included timers are long * (programmed with units of seconds) and include 'Current While * Timer', 'Periodic Timer', 'Wait While Timer', 'Transmit LACP * Timer', 'Actor Churn Timer', 'Partner Churn Timer', * 0x0 - No scaling * 0x1 - Scale by 10X (counter expires 10 times faster) * 0x2 - Scale by 100X * 0x3 - Scale by 1000X * 0x4 - Scale by 10000X * 0x5 - Scale by 100000X * 0x6 - Scale by 1000000X * * Link Aggregation Configuration */ typedef struct vxge_hal_lag_config_t { u32 lag_en; #define VXGE_HAL_LAG_LAG_EN_DISABLE 0 #define VXGE_HAL_LAG_LAG_EN_ENABLE 1 #define VXGE_HAL_LAG_LAG_EN_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 lag_mode; #define VXGE_HAL_LAG_LAG_MODE_LAG 0 #define VXGE_HAL_LAG_LAG_MODE_ACTIVE_PASSIVE_FAILOVER 1 #define VXGE_HAL_LAG_LAG_MODE_SINGLE_LINK 2 #define VXGE_HAL_LAG_LAG_MODE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT vxge_hal_lag_la_config_t la_mode_config; vxge_hal_lag_ap_config_t ap_mode_config; vxge_hal_lag_sl_config_t sl_mode_config; vxge_hal_lag_lacp_config_t lacp_config; u32 incr_tx_aggr_stats; #define VXGE_HAL_LAG_INCR_TX_AGGR_STATS_DISBALE 0 #define VXGE_HAL_LAG_INCR_TX_AGGR_STATS_ENABLE 1 #define VXGE_HAL_LAG_INCR_TX_AGGR_STATS_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT vxge_hal_lag_port_config_t port_config[VXGE_HAL_LAG_PORT_MAX_PORTS]; vxge_hal_lag_aggr_config_t aggr_config[VXGE_HAL_LAG_AGGR_MAX_PORTS]; u32 sys_pri; #define VXGE_HAL_LAG_MIN_SYS_PRI 0 #define VXGE_HAL_LAG_MAX_SYS_PRI 65535 #define VXGE_HAL_LAG_DEF_SYS_PRI VXGE_HAL_USE_FLASH_DEFAULT macaddr_t mac_addr; u32 use_port_mac_addr; #define VXGE_HAL_LAG_USE_PORT_MAC_ADDR_DISBALE 0 #define VXGE_HAL_LAG_USE_PORT_MAC_ADDR_ENABLE 1 #define VXGE_HAL_LAG_USE_PORT_MAC_ADDR_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 mac_addr_sel; #define VXGE_HAL_LAG_MAC_ADDR_SEL_PORT_0 0 #define VXGE_HAL_LAG_MAC_ADDR_SEL_PORT_1 1 #define VXGE_HAL_LAG_MAC_ADDR_SEL_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 fast_per_time; #define VXGE_HAL_LAG_MIN_FAST_PER_TIME 0 #define VXGE_HAL_LAG_MAX_FAST_PER_TIME 65535 #define VXGE_HAL_LAG_DEF_FAST_PER_TIME VXGE_HAL_USE_FLASH_DEFAULT u32 slow_per_time; #define VXGE_HAL_LAG_MIN_SLOW_PER_TIME 0 #define VXGE_HAL_LAG_MAX_SLOW_PER_TIME 65535 #define VXGE_HAL_LAG_DEF_SLOW_PER_TIME VXGE_HAL_USE_FLASH_DEFAULT u32 short_timeout; #define VXGE_HAL_LAG_MIN_SHORT_TIMEOUT 0 #define VXGE_HAL_LAG_MAX_SHORT_TIMEOUT 65535 #define VXGE_HAL_LAG_DEF_SHORT_TIMEOUT VXGE_HAL_USE_FLASH_DEFAULT u32 long_timeout; #define VXGE_HAL_LAG_MIN_LONG_TIMEOUT 0 #define VXGE_HAL_LAG_MAX_LONG_TIMEOUT 65535 #define VXGE_HAL_LAG_DEF_LONG_TIMEOUT VXGE_HAL_USE_FLASH_DEFAULT u32 churn_det_time; #define VXGE_HAL_LAG_MIN_CHURN_DET_TIME 0 #define VXGE_HAL_LAG_MAX_CHURN_DET_TIME 65535 #define VXGE_HAL_LAG_DEF_CHURN_DET_TIME VXGE_HAL_USE_FLASH_DEFAULT u32 aggr_wait_time; #define VXGE_HAL_LAG_MIN_AGGR_WAIT_TIME 0 #define VXGE_HAL_LAG_MAX_AGGR_WAIT_TIME 65535 #define VXGE_HAL_LAG_DEF_AGGR_WAIT_TIME VXGE_HAL_USE_FLASH_DEFAULT u32 short_timer_scale; #define VXGE_HAL_LAG_SHORT_TIMER_SCALE_1X 0 #define VXGE_HAL_LAG_SHORT_TIMER_SCALE_10X 1 #define VXGE_HAL_LAG_SHORT_TIMER_SCALE_100X 2 #define VXGE_HAL_LAG_SHORT_TIMER_SCALE_1000X 3 #define VXGE_HAL_LAG_SHORT_TIMER_SCALE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 long_timer_scale; #define VXGE_HAL_LAG_LONG_TIMER_SCALE_1X 0 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_10X 1 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_100X 2 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_1000X 3 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_10000X 4 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_100000X 5 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_1000000X 6 #define VXGE_HAL_LAG_LONG_TIMER_SCALE_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_lag_config_t; /* * struct vxge_hal_vpath_qos_config_t - Vpath qos(For privileged * mode driver only) * @priority: The priority of vpath * @min_bandwidth: Minimum Guaranteed bandwidth * @max_bandwidth: Maximum allowed bandwidth * * This structure is vpath qos configuration for MRPCIM section of device */ typedef struct vxge_hal_vpath_qos_config_t { u32 priority; #define VXGE_HAL_VPATH_QOS_PRIORITY_MIN 0 #define VXGE_HAL_VPATH_QOS_PRIORITY_MAX 16 #define VXGE_HAL_VPATH_QOS_PRIORITY_DEFAULT 0 u32 min_bandwidth; #define VXGE_HAL_VPATH_QOS_MIN_BANDWIDTH_MIN 0 #define VXGE_HAL_VPATH_QOS_MIN_BANDWIDTH_MAX 100 #define VXGE_HAL_VPATH_QOS_MIN_BANDWIDTH_DEFAULT 0 u32 max_bandwidth; #define VXGE_HAL_VPATH_QOS_MAX_BANDWIDTH_MIN 0 #define VXGE_HAL_VPATH_QOS_MAX_BANDWIDTH_MAX 100 #define VXGE_HAL_VPATH_QOS_MAX_BANDWIDTH_DEFAULT 0 } vxge_hal_vpath_qos_config_t; /* * struct vxge_hal_mrpcim_config_t - MRPCIM secion configuration(For privileged * mode driver only) * * @mac_config: MAC Port Config. See vxge_hal_mac_config_t {} * @lag_config: MAC Port Config. See vxge_hal_lag_config_t {} * @vp_qos: Vpath QOS * @vpath_to_wire_port_map_en: Mask to enable vpath to wire port mapping. * @vpath_to_wire_port_map: If LAG is not enabled or lag_distrib_dest is not set * then vpath_to_wire_port_map is used to assign independent ports * to vpath * * This structure is configuration for MRPCIM section of device */ typedef struct vxge_hal_mrpcim_config_t { vxge_hal_mac_config_t mac_config; vxge_hal_lag_config_t lag_config; u64 vpath_to_wire_port_map_en; #define VXGE_HAL_VPATH_TO_WIRE_PORT_MAP_EN_DISABLE(vpid) 0 #define VXGE_HAL_VPATH_TO_WIRE_PORT_MAP_EN_ENABLE(vpid) mBIT(vpid) #define VXGE_HAL_VPATH_WIRE_PORTS_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u64 vpath_to_wire_port_map; #define VXGE_HAL_VPATH_TO_WIRE_PORT_MAP_PORT0(vpid) 0 #define VXGE_HAL_VPATH_TO_WIRE_PORT_MAP_PORT1(vpid) mBIT(vpid) #define VXGE_HAL_VPATH_TO_WIRE_PORT_MAP_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT vxge_hal_vpath_qos_config_t vp_qos[VXGE_HAL_MAX_VIRTUAL_PATHS]; } vxge_hal_mrpcim_config_t; /* * struct vxge_hal_tim_intr_config_t - X3100 Tim interrupt configuration. * @intr_enable: Set to 1, if interrupt is enabled. * @btimer_val: Boundary Timer Initialization value in units of 272 ns. * @timer_ac_en: Timer Automatic Cancel. 1 : Automatic Canceling Enable: when * asserted, other interrupt-generating entities will cancel the * scheduled timer interrupt. * @timer_ci_en: Timer Continuous Interrupt. 1 : Continuous Interrupting Enable: * When asserted, an interrupt will be generated every time the * boundary timer expires, even if no traffic has been transmitted * on this interrupt. * @timer_ri_en: Timer Consecutive (Re-) Interrupt 1 : Consecutive * (Re-) Interrupt Enable: When asserted, an interrupt will be * generated the next time the timer expires,even if no traffic has * been transmitted on this interrupt. (This will only happen once * each time that this value is written to the TIM.) This bit is * cleared by H/W at the end of the current-timer-interval when * the interrupt is triggered. * @rtimer_event_sf: Restriction Timer Event Scale Factor. A scale factor that * is to be applied to the current event count before it is added * to the restriction timer value when the restriction timer * is started. * The scale factor is applied as a right or left shift to multiply * or divide by the event count. The programmable values are as * follows: * 0-disable restriction timer and use the base timer value. * 1-Multiply the event count by 2, shift left by 1. * 2-Multiply the event count by 4, shift left by 2. * 3-Multiply the event count by 8, shift left by 3. * 4-Multiply the event count by 16, shift left by 4. * 5-Multiply the event count by 32, shift left by 5. * 6-Multiply the event count by 64, shift left by 6. * 7-Multiply the event count by 128, shift left by 7. * 8-add the event count, no shifting. * 9-Divide the event count by 128, shift right by 7. * 10-Divide the event count by 64, shift right by 6. * 11-Divide the event count by 32, shift right by 5. * 12-Divide the event count by 16, shift right by 4. * 13-Divide the event count by 8, shift right by 3. * 14-Divide the event count by 4, shift right by 2. * 15-Divide the event count by 2, shift right by 1. * @rtimer_val: Restriction Timer Initialization value in units of 272 ns. * @util_sel: Utilization Selector. Selects which of the workload approximations * to use (e.g. legacy Tx utilization, Tx/Rx utilization, host * specified utilization etc.),selects one of the 17 host * configured values. * 0-Virtual Path 0 * 1-Virtual Path 1 * ... * 16-Virtual Path 17 * 17-Legacy Tx network utilization, provided by TPA * 18-Legacy Rx network utilization, provided by FAU * 19-Average of legacy Rx and Tx utilization calculated from link * utilization values. * 20-31-Invalid configurations * 32-Host utilization for Virtual Path 0 * 33-Host utilization for Virtual Path 1 * ... * 48-Host utilization for Virtual Path 17 * 49-Legacy Tx network utilization, provided by TPA * 50-Legacy Rx network utilization, provided by FAU * 51-Average of legacy Rx and Tx utilization calculated from * link utilization values. * 52-63-Invalid configurations * @ltimer_val: Latency Timer Initialization Value in units of 272 ns. * @txfrm_cnt_en: Transmit Frame Event Count Enable. This configuration bit * when set to 1 enables counting of transmit frame's(signalled by * SM), towards utilization event count values. * @txd_cnt_en: TxD Return Event Count Enable. This configuration bit when set * to 1 enables counting of TxD0 returns (signalled by PCC's), * towards utilization event count values. * @urange_a: Defines the upper limit (in percent) for this utilization range * to be active. This range is considered active * if 0 = UTIL = URNG_A and the UEC_A field (below) is non-zero. * @uec_a: Utilization Event Count A. If this range is active, the adapter will * wait until UEC_A events have occurred on the interrupt before * generating an interrupt. * @urange_b: Link utilization range B. * @uec_b: Utilization Event Count B. * @urange_c: Link utilization range C. * @uec_c: Utilization Event Count C. * @urange_d: Link utilization range D. * @uec_d: Utilization Event Count D. * @ufca_intr_thres * @ufca_lo_lim * @ufca_hi_lim * @ufca_lbolt_period: * * Traffic Interrupt Controller Module interrupt configuration. */ typedef struct vxge_hal_tim_intr_config_t { u32 intr_enable; #define VXGE_HAL_TIM_INTR_ENABLE 1 #define VXGE_HAL_TIM_INTR_DISABLE 0 #define VXGE_HAL_TIM_INTR_DEFAULT 0 u32 btimer_val; #define VXGE_HAL_MIN_TIM_BTIMER_VAL 0 #define VXGE_HAL_MAX_TIM_BTIMER_VAL 67108864 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_BTIMER_VAL VXGE_HAL_USE_FLASH_DEFAULT u32 timer_ac_en; #define VXGE_HAL_TIM_TIMER_AC_ENABLE 1 #define VXGE_HAL_TIM_TIMER_AC_DISABLE 0 #define VXGE_HAL_TIM_TIMER_AC_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 timer_ci_en; #define VXGE_HAL_TIM_TIMER_CI_ENABLE 1 #define VXGE_HAL_TIM_TIMER_CI_DISABLE 0 #define VXGE_HAL_TIM_TIMER_CI_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 timer_ri_en; #define VXGE_HAL_TIM_TIMER_RI_ENABLE 1 #define VXGE_HAL_TIM_TIMER_RI_DISABLE 0 #define VXGE_HAL_TIM_TIMER_RI_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rtimer_event_sf; #define VXGE_HAL_MIN_TIM_RTIMER_EVENT_SF 0 #define VXGE_HAL_MAX_TIM_RTIMER_EVENT_SF 15 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_RTIMER_EVENT_SF \ VXGE_HAL_USE_FLASH_DEFAULT u32 rtimer_val; #define VXGE_HAL_MIN_TIM_RTIMER_VAL 0 #define VXGE_HAL_MAX_TIM_RTIMER_VAL 67108864 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_RTIMER_VAL VXGE_HAL_USE_FLASH_DEFAULT u32 util_sel; #define VXGE_HAL_TIM_UTIL_SEL_VPATH(n) n #define VXGE_HAL_TIM_UTIL_SEL_LEGACY_TX_NET_UTIL 17 #define VXGE_HAL_TIM_UTIL_SEL_LEGACY_RX_NET_UTIL 18 #define VXGE_HAL_TIM_UTIL_SEL_LEGACY_TX_RX_AVE_NET_UTIL 19 #define VXGE_HAL_TIM_UTIL_SEL_VPATH(n) n #define VXGE_HAL_TIM_UTIL_SEL_VPATH(n) n #define VXGE_HAL_TIM_UTIL_SEL_HOST_UTIL_VPATH(n) (32+n) #define VXGE_HAL_TIM_UTIL_SEL_TIM_UTIL_VPATH(n) 63 #define VXGE_HAL_TIM_UTIL_SEL_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 ltimer_val; #define VXGE_HAL_MIN_TIM_LTIMER_VAL 0 #define VXGE_HAL_MAX_TIM_LTIMER_VAL 67108864 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_LTIMER_VAL VXGE_HAL_USE_FLASH_DEFAULT /* Line utilization interrupts */ u32 txfrm_cnt_en; #define VXGE_HAL_TXFRM_CNT_EN_ENABLE 1 #define VXGE_HAL_TXFRM_CNT_EN_DISABLE 0 #define VXGE_HAL_TXFRM_CNT_EN_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 txd_cnt_en; #define VXGE_HAL_TXD_CNT_EN_ENABLE 1 #define VXGE_HAL_TXD_CNT_EN_DISABLE 0 #define VXGE_HAL_TXD_CNT_EN_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 urange_a; #define VXGE_HAL_MIN_TIM_URANGE_A 0 #define VXGE_HAL_MAX_TIM_URANGE_A 100 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_URANGE_A VXGE_HAL_USE_FLASH_DEFAULT u32 uec_a; #define VXGE_HAL_MIN_TIM_UEC_A 0 #define VXGE_HAL_MAX_TIM_UEC_A 65535 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_UEC_A VXGE_HAL_USE_FLASH_DEFAULT u32 urange_b; #define VXGE_HAL_MIN_TIM_URANGE_B 0 #define VXGE_HAL_MAX_TIM_URANGE_B 100 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_URANGE_B VXGE_HAL_USE_FLASH_DEFAULT u32 uec_b; #define VXGE_HAL_MIN_TIM_UEC_B 0 #define VXGE_HAL_MAX_TIM_UEC_B 65535 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_UEC_B VXGE_HAL_USE_FLASH_DEFAULT u32 urange_c; #define VXGE_HAL_MIN_TIM_URANGE_C 0 #define VXGE_HAL_MAX_TIM_URANGE_C 100 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_URANGE_C VXGE_HAL_USE_FLASH_DEFAULT u32 uec_c; #define VXGE_HAL_MIN_TIM_UEC_C 0 #define VXGE_HAL_MAX_TIM_UEC_C 65535 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_UEC_C VXGE_HAL_USE_FLASH_DEFAULT u32 uec_d; #define VXGE_HAL_MIN_TIM_UEC_D 0 #define VXGE_HAL_MAX_TIM_UEC_D 65535 #define VXGE_HAL_USE_FLASH_DEFAULT_TIM_UEC_D VXGE_HAL_USE_FLASH_DEFAULT u32 ufca_intr_thres; #define VXGE_HAL_MIN_UFCA_INTR_THRES 1 #define VXGE_HAL_MAX_UFCA_INTR_THRES 4096 #define VXGE_HAL_USE_FLASH_DEFAULT_UFCA_INTR_THRES VXGE_HAL_USE_FLASH_DEFAULT u32 ufca_lo_lim; #define VXGE_HAL_MIN_UFCA_LO_LIM 1 #define VXGE_HAL_MAX_UFCA_LO_LIM 16 #define VXGE_HAL_USE_FLASH_DEFAULT_UFCA_LO_LIM VXGE_HAL_USE_FLASH_DEFAULT u32 ufca_hi_lim; #define VXGE_HAL_MIN_UFCA_HI_LIM 1 #define VXGE_HAL_MAX_UFCA_HI_LIM 256 #define VXGE_HAL_USE_FLASH_DEFAULT_UFCA_HI_LIM VXGE_HAL_USE_FLASH_DEFAULT u32 ufca_lbolt_period; #define VXGE_HAL_MIN_UFCA_LBOLT_PERIOD 1 #define VXGE_HAL_MAX_UFCA_LBOLT_PERIOD 1024 #define VXGE_HAL_USE_FLASH_DEFAULT_UFCA_LBOLT_PERIOD \ VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_tim_intr_config_t; /* * struct vxge_hal_fifo_config_t - Configuration of fifo. * @enable: Is this fifo to be commissioned * @fifo_length: Numbers of TxDLs (that is, lists of Tx descriptors)per queue. * @max_frags: Max number of Tx buffers per TxDL (that is, per single * transmit operation). * No more than 256 transmit buffers can be specified. * @alignment_size: per Tx fragment DMA-able memory used to align transmit data * (e.g., to align on a cache line). * @max_aligned_frags: Number of fragments to be aligned out of * maximum fragments (see @max_frags). * @intr: Boolean. Use 1 to generate interrupt for each completed TxDL. * Use 0 otherwise. * @no_snoop_bits: If non-zero, specifies no-snoop PCI operation, * which generally improves latency of the host bridge operation * (see PCI specification). For valid values please refer * to vxge_hal_fifo_config_t {} in the driver sources. * Configuration of all X3100 fifos. * Note: Valid (min, max) range for each attribute is specified in the body of * the vxge_hal_fifo_config_t {} structure. */ typedef struct vxge_hal_fifo_config_t { u32 enable; #define VXGE_HAL_FIFO_ENABLE 1 #define VXGE_HAL_FIFO_DISABLE 0 #define VXGE_HAL_FIFO_DEFAULT 1 u32 fifo_length; #define VXGE_HAL_MIN_FIFO_LENGTH 1 #define VXGE_HAL_MAX_FIFO_LENGTH 12*1024 #define VXGE_HAL_DEF_FIFO_LENGTH 512 u32 max_frags; #define VXGE_HAL_MIN_FIFO_FRAGS 1 #define VXGE_HAL_MAX_FIFO_FRAGS 256 #define VXGE_HAL_DEF_FIFO_FRAGS 256 u32 alignment_size; #define VXGE_HAL_MIN_FIFO_ALIGNMENT_SIZE 0 #define VXGE_HAL_MAX_FIFO_ALIGNMENT_SIZE 65536 #define VXGE_HAL_DEF_FIFO_ALIGNMENT_SIZE __vxge_os_cacheline_size u32 max_aligned_frags; /* range: (1, @max_frags) */ u32 intr; #define VXGE_HAL_FIFO_QUEUE_INTR_ENABLE 1 #define VXGE_HAL_FIFO_QUEUE_INTR_DISABLE 0 #define VXGE_HAL_FIFO_QUEUE_INTR_DEFAULT 0 u32 no_snoop_bits; #define VXGE_HAL_FIFO_NO_SNOOP_DISABLED 0 #define VXGE_HAL_FIFO_NO_SNOOP_TXD 1 #define VXGE_HAL_FIFO_NO_SNOOP_FRM 2 #define VXGE_HAL_FIFO_NO_SNOOP_ALL 3 #define VXGE_HAL_FIFO_NO_SNOOP_DEFAULT 0 } vxge_hal_fifo_config_t; /* * struct vxge_hal_ring_config_t - Ring configurations. * @enable: Is this ring to be commissioned * @ring_length: Numbers of RxDs in the ring * @buffer_mode: Receive buffer mode (1, 2, 3, or 5); for details please refer * to X3100 User Guide. * @scatter_mode: X3100 supports two receive scatter modes: A and B. * For details please refer to X3100 User Guide. * @post_mode: The RxD post mode. * @max_frm_len: Maximum frame length that can be received on _that_ ring. * Setting this field to VXGE_HAL_USE_FLASH_DEFAULT ensures that * the ring will "accept" * MTU-size frames (note that MTU can be changed at runtime). * Any value other than (VXGE_HAL_USE_FLASH_DEFAULT) specifies a * certain "hard" limit on the receive frame sizes. The field can * be used to activate receive frame-length based steering. * @no_snoop_bits: If non-zero, specifies no-snoop PCI operation, * which generally improves latency of the host bridge operation * (see PCI specification). For valid values please refer * to vxge_hal_ring_config_t {} in the driver sources. * @rx_timer_val: The number of 32ns periods that would be counted between two * timer interrupts. * @greedy_return: If Set it forces the device to return absolutely all RxD * that are consumed and still on board when a timer interrupt * triggers. If Clear, then if the device has already returned * RxD before current timer interrupt trigerred and after the * previous timer interrupt triggered, then the device is not * forced to returned the rest of the consumed RxD that it has * on board which account for a byte count less than the one * programmed into PRC_CFG6.RXD_CRXDT field * @rx_timer_ci: TBD * @backoff_interval_us: Time (in microseconds), after which X3100 * tries to download RxDs posted by the host. * Note that the "backoff" does not happen if host posts receive * descriptors in the timely fashion. * @indicate_max_pkts: Sets maximum number of received frames to be processed * within single interrupt. * @sw_lro_sessions: Number of LRO Sessions * @sw_lro_sg_size: Size of LROable segment * @sw_lro_frm_len: Length of LROable frame * * Ring configuration. */ typedef struct vxge_hal_ring_config_t { u32 enable; #define VXGE_HAL_RING_ENABLE 1 #define VXGE_HAL_RING_DISABLE 0 #define VXGE_HAL_RING_DEFAULT 1 u32 ring_length; #define VXGE_HAL_MIN_RING_LENGTH 1 #define VXGE_HAL_MAX_RING_LENGTH 8096 #define VXGE_HAL_DEF_RING_LENGTH 512 u32 buffer_mode; #define VXGE_HAL_RING_RXD_BUFFER_MODE_1 1 #define VXGE_HAL_RING_RXD_BUFFER_MODE_3 3 #define VXGE_HAL_RING_RXD_BUFFER_MODE_5 5 #define VXGE_HAL_RING_RXD_BUFFER_MODE_DEFAULT 1 u32 scatter_mode; #define VXGE_HAL_RING_SCATTER_MODE_A 0 #define VXGE_HAL_RING_SCATTER_MODE_B 1 #define VXGE_HAL_RING_SCATTER_MODE_C 2 #define VXGE_HAL_RING_SCATTER_MODE_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 post_mode; #define VXGE_HAL_RING_POST_MODE_LEGACY 0 #define VXGE_HAL_RING_POST_MODE_DOORBELL 1 #define VXGE_HAL_RING_POST_MODE_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 max_frm_len; #define VXGE_HAL_MIN_RING_MAX_FRM_LEN VXGE_HAL_MIN_MTU #define VXGE_HAL_MAX_RING_MAX_FRM_LEN VXGE_HAL_MAX_MTU #define VXGE_HAL_MAX_RING_FRM_LEN_USE_MTU VXGE_HAL_USE_FLASH_DEFAULT u32 no_snoop_bits; #define VXGE_HAL_RING_NO_SNOOP_DISABLED 0 #define VXGE_HAL_RING_NO_SNOOP_RXD 1 #define VXGE_HAL_RING_NO_SNOOP_FRM 2 #define VXGE_HAL_RING_NO_SNOOP_ALL 3 #define VXGE_HAL_RING_NO_SNOOP_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rx_timer_val; #define VXGE_HAL_RING_MIN_RX_TIMER_VAL 0 #define VXGE_HAL_RING_MAX_RX_TIMER_VAL 536870912 #define VXGE_HAL_RING_USE_FLASH_DEFAULT_RX_TIMER_VAL \ VXGE_HAL_USE_FLASH_DEFAULT u32 greedy_return; #define VXGE_HAL_RING_GREEDY_RETURN_ENABLE 1 #define VXGE_HAL_RING_GREEDY_RETURN_DISABLE 0 #define VXGE_HAL_RING_GREEDY_RETURN_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rx_timer_ci; #define VXGE_HAL_RING_RX_TIMER_CI_ENABLE 1 #define VXGE_HAL_RING_RX_TIMER_CI_DISABLE 0 #define VXGE_HAL_RING_RX_TIMER_CI_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 backoff_interval_us; #define VXGE_HAL_MIN_BACKOFF_INTERVAL_US 1 #define VXGE_HAL_MAX_BACKOFF_INTERVAL_US 125000 #define VXGE_HAL_USE_FLASH_DEFAULT_BACKOFF_INTERVAL_US \ VXGE_HAL_USE_FLASH_DEFAULT u32 indicate_max_pkts; #define VXGE_HAL_MIN_RING_INDICATE_MAX_PKTS 1 #define VXGE_HAL_MAX_RING_INDICATE_MAX_PKTS 65536 #define VXGE_HAL_DEF_RING_INDICATE_MAX_PKTS 65536 } vxge_hal_ring_config_t; /* * struct vxge_hal_vp_config_t - Configuration of virtual path * @vp_id: Virtual Path Id * @wire_port: Wire port to be associated with the vpath * @bandwidth_limit: Desired bandwidth limit for this vpath. * 0 = Disable limit, 1 = 8192 kBps, 2 = 16384 kBps, ... , * >152588 = 1 GBps * @no_snoop: Enable or disable no snoop for vpath * @ring: See vxge_hal_ring_config_t {}. * @fifo: See vxge_hal_fifo_config_t {}. * @dmq: See vxge_hal_dmq_config_t {}; * @umq: See vxge_hal_umq_config_t {}; * @lro: See vxge_hal_lro_config_t {}; * @tti: Configuration of interrupt associated with Transmit. * see vxge_hal_tim_intr_config_t(); * @rti: Configuration of interrupt associated with Receive. * see vxge_hal_tim_intr_config_t(); * @mtu: mtu size used on this port. * @tpa_lsov2_en: LSOv2 Behaviour for IP ID roll-over * @tpa_ignore_frame_error: Ignore Frame Error. TPA may detect frame integrity * errors as it processes each frame. If this bit is set to '0', * the TPA will tag such frames as invalid and they will be dropped * by the transmit MAC. If the bit is set to '1',the frame will not * be tagged as "errored". Detectable errors include: * 1) early end-of-frame error, which occurs when the frame ends * before the number of bytes predicted by the IP "total length" * field have been received; * 2) IP version mismatches; * 3) IPv6 packets that include routing headers that are not type 0 * 4) Frames which contain IP packets but have an illegal SNAP-OUI * or LLC-CTRL fields, unless IGNORE_SNAP_OUI or IGNORE_LLC_CTRL * are set (see below). * @tpa_ipv6_keep_searching: If unknown IPv6 header is found, * 0 - stop searching for TCP * 1 - keep searching for TCP * @tpa_l4_pshdr_present: If asserted true, indicates the host has provided a * valid pseudo header for TCP or UDP running over IPv4 or IPv6 * @tpa_support_mobile_ipv6_hdrs: This register is somewhat equivalent to * asserting both Hercules register fields LSO_RT2_EN and * LSO_IPV6_HAO_EN. Enable/disable support for Type 2 Routing * Headers, and for Mobile-IPv6 Home Address Option (HAO), * as defined by mobile-ipv6. * @rpa_ipv4_tcp_incl_ph: Determines if the pseudo-header is included in the * calculation of the L4 checksum that is passed to the host. This * field applies to TCP/IPv4 packets only. This field affects both * non-offload and LRO traffic. Note that the RPA always includes * the pseudo-header in the "Checksum Ok" L4 checksum calculation * i.e. the checksum that decides whether a frame is a candidate to * be offloaded. * 0 - Do not include the pseudo-header in L4 checksum calculation. * This setting should be used if the adapter is incorrectly * calculating the pseudo-header. * 1 - Include the pseudo-header in L4 checksum calculation * @rpa_ipv6_tcp_incl_ph: Determines whether the pseudo-header is included in * the calculation of the L4 checksum that is passed to the host. * This field applies to TCP/IPv6 packets only. This field affects * both non-offload and LRO traffic. Note that the RPA always * includes the pseudo-header in the "Checksum Ok" L4 checksum * calculation. i.e. the checksum that decides whether a frame * is a candidate to be offloaded. * 0 - Do not include the pseudo-header in L4 checksum calculation. * This setting should be used if the adapter is incorrectly * calculating the pseudo-header. * 1 - Include the pseudo-header in L4 checksum calculation * @rpa_ipv4_udp_incl_ph: Determines whether the pseudo-header is included in * the calculation of the L4 checksum that is passed to the host. * This field applies to UDP/IPv4 packets only. It only affects * non-offload traffic(since UDP frames are not candidates for LRO) * 0 - Do not include the pseudo-header in L4 checksum calculation. * This setting should be used if the adapter is incorrectly * calculating the pseudo-header. * 1 - Include the pseudo-header in L4 checksum calculation * @rpa_ipv6_udp_incl_ph: Determines if the pseudo-header is included in the * calculation of the L4 checksum that is passed to the host. This * field applies to UDP/IPv6 packets only. It only affects * non-offload traffic(since UDP frames are not candidates for LRO) * 0 - Do not include the pseudo-header in L4 checksum calculation. * This setting should be used if the adapter is incorrectly * calculating the pseudo-header. * 1 - Include the pseudo-header in L4 checksum calculation * @rpa_l4_incl_cf: Determines whether the checksum field (CF) of the received * frame is included in the calculation of the L4 checksum that is * passed to the host. This field affects both non-offload and LRO * traffic. Note that the RPA always includes the checksum field in * the "Checksum Ok" L4 checksum calculation -- i.e. the checksum * that decides whether a frame is a candidate to be offloaded. * 0 - Do not include the checksum field in L4 checksum calculation * 1 - Include the checksum field in L4 checksum calculation * @rpa_strip_vlan_tag: Strip VLAN Tag enable/disable. Instructs the device to * remove the VLAN tag from all received tagged frames that are not * replicated at the internal L2 switch. * 0 - Do not strip the VLAN tag. * 1 - Strip the VLAN tag. Regardless of this setting,VLAN tags are * always placed into the RxDMA descriptor. * @rpa_l4_comp_csum: Determines whether the calculated L4 checksum should be * complemented before it is passed to the host This field affects * both non-offload and LRO traffic. * 0 - Do not complement the calculated L4 checksum. * 1 - Complement the calculated L4 checksum * @rpa_l3_incl_cf: Determines whether the checksum field (CF) of the received * frame is included in the calculation of the L3 checksum that is * passed to the host. This field affects both non-offload and LRO * traffic. Note that the RPA always includes the checksum field in * the "Checksum Ok" L3 checksum calculation--i.e. the checksum * that decides whether a frame is a candidate to be offloaded. * 0 - Do not include the checksum field in L3 checksum calculation * 1 - Include the checksum field in L3 checksum calculation * @rpa_l3_comp_csum: Determines whether the calculated L3 checksum should be * complemented before it is passed to the host This field affects * both non-offload and LRO traffic. * 0 - Do not complement the calculated L3 checksum. * 1 - Complement the calculated L3 checksum * @rpa_ucast_all_addr_en: Enables frames with any unicast address (as its * destination address) to be passed to the host. * @rpa_mcast_all_addr_en: Enables frames with any multicast address (as its * destination address) to be passed to the host. * @rpa_bcast_en: Enables frames with any broadicast address (as its * destination address) to be passed to the host. * @rpa_all_vid_en: romiscuous mode, it overrides the value held in this field. * 0 - Disable; * 1 - Enable * Note: RXMAC_GLOBAL_CFG.AUTHORIZE_VP_ALL_VID must be set to * allow this. * @vp_queue_l2_flow: Allows per-VPATH receive queue from * contributing to L2 flow control. Has precedence over * RMAC_PAUSE_CFG_PORTn.LIMITER_EN. * 0 - Queue is not allowed to contribute to L2 flow control. * 1 - Queue is allowed to contribute to L2 flow control. * * This structure is used by the driver to pass the configuration parameters to * configure Virtual Path. */ typedef struct vxge_hal_vp_config_t { u32 vp_id; u32 wire_port; #define VXGE_HAL_VPATH_USE_DEFAULT_PORT VXGE_HAL_FIFO_HOST_STEER_NORMAL #define VXGE_HAL_VPATH_USE_PORT0 VXGE_HAL_FIFO_HOST_STEER_PORT0 #define VXGE_HAL_VPATH_USE_PORT1 VXGE_HAL_FIFO_HOST_STEER_PORT1 #define VXGE_HAL_VPATH_USE_BOTH VXGE_HAL_FIFO_HOST_STEER_BOTH u32 bandwidth; #define VXGE_HAL_VPATH_BW_LIMIT_MAX 10000 #define VXGE_HAL_VPATH_BW_LIMIT_MIN 100 #define VXGE_HAL_VPATH_BW_LIMIT_DEFAULT 0XFFFFFFFF #define VXGE_HAL_TX_BW_VPATH_LIMIT 8 u32 priority; #define VXGE_HAL_VPATH_PRIORITY_MIN 0 #define VXGE_HAL_VPATH_PRIORITY_MAX 3 #define VXGE_HAL_VPATH_PRIORITY_DEFAULT 0XFFFFFFFF u32 no_snoop; #define VXGE_HAL_VPATH_NO_SNOOP_ENABLE 1 #define VXGE_HAL_VPATH_NO_SNOOP_DISABLE 0 #define VXGE_HAL_VPATH_NO_SNOOP_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT vxge_hal_ring_config_t ring; vxge_hal_fifo_config_t fifo; vxge_hal_tim_intr_config_t tti; vxge_hal_tim_intr_config_t rti; u32 mtu; #define VXGE_HAL_VPATH_MIN_INITIAL_MTU VXGE_HAL_MIN_MTU #define VXGE_HAL_VPATH_MAX_INITIAL_MTU VXGE_HAL_MAX_MTU #define VXGE_HAL_VPATH_USE_FLASH_DEFAULT_INITIAL_MTU \ VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_lsov2_en; #define VXGE_HAL_VPATH_TPA_LSOV2_EN_ENABLE 1 #define VXGE_HAL_VPATH_TPA_LSOV2_EN_DISABLE 0 #define VXGE_HAL_VPATH_TPA_LSOV2_EN_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_ignore_frame_error; #define VXGE_HAL_VPATH_TPA_IGNORE_FRAME_ERROR_ENABLE 1 #define VXGE_HAL_VPATH_TPA_IGNORE_FRAME_ERROR_DISABLE 0 #define VXGE_HAL_VPATH_TPA_IGNORE_FRAME_ERROR_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_ipv6_keep_searching; #define VXGE_HAL_VPATH_TPA_IPV6_KEEP_SEARCHING_ENABLE 1 #define VXGE_HAL_VPATH_TPA_IPV6_KEEP_SEARCHING_DISABLE 0 #define VXGE_HAL_VPATH_TPA_IPV6_KEEP_SEARCHING_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_l4_pshdr_present; #define VXGE_HAL_VPATH_TPA_L4_PSHDR_PRESENT_ENABLE 1 #define VXGE_HAL_VPATH_TPA_L4_PSHDR_PRESENT_DISABLE 0 #define VXGE_HAL_VPATH_TPA_L4_PSHDR_PRESENT_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 tpa_support_mobile_ipv6_hdrs; #define VXGE_HAL_VPATH_TPA_SUPPORT_MOBILE_IPV6_HDRS_ENABLE 1 #define VXGE_HAL_VPATH_TPA_SUPPORT_MOBILE_IPV6_HDRS_DISABLE 0 #define VXGE_HAL_VPATH_TPA_SUPPORT_MOBILE_IPV6_HDRS_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT #define VXGE_HAL_VPATH_TPA_SUPPORT_MOBILE_IPV6_HDRS_DEFAULT \ VXGE_HAL_VPATH_TPA_SUPPORT_MOBILE_IPV6_HDRS_USE_FLASH_DEFAULT u32 rpa_ipv4_tcp_incl_ph; #define VXGE_HAL_VPATH_RPA_IPV4_TCP_INCL_PH_ENABLE 1 #define VXGE_HAL_VPATH_RPA_IPV4_TCP_INCL_PH_DISABLE 0 #define VXGE_HAL_VPATH_RPA_IPV4_TCP_INCL_PH_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ipv6_tcp_incl_ph; #define VXGE_HAL_VPATH_RPA_IPV6_TCP_INCL_PH_ENABLE 1 #define VXGE_HAL_VPATH_RPA_IPV6_TCP_INCL_PH_DISABLE 0 #define VXGE_HAL_VPATH_RPA_IPV6_TCP_INCL_PH_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ipv4_udp_incl_ph; #define VXGE_HAL_VPATH_RPA_IPV4_UDP_INCL_PH_ENABLE 1 #define VXGE_HAL_VPATH_RPA_IPV4_UDP_INCL_PH_DISABLE 0 #define VXGE_HAL_VPATH_RPA_IPV4_UDP_INCL_PH_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ipv6_udp_incl_ph; #define VXGE_HAL_VPATH_RPA_IPV6_UDP_INCL_PH_ENABLE 1 #define VXGE_HAL_VPATH_RPA_IPV6_UDP_INCL_PH_DISABLE 0 #define VXGE_HAL_VPATH_RPA_IPV6_UDP_INCL_PH_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_l4_incl_cf; #define VXGE_HAL_VPATH_RPA_L4_INCL_CF_ENABLE 1 #define VXGE_HAL_VPATH_RPA_L4_INCL_CF_DISABLE 0 #define VXGE_HAL_VPATH_RPA_L4_INCL_CF_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_strip_vlan_tag; #define VXGE_HAL_VPATH_RPA_STRIP_VLAN_TAG_ENABLE 1 #define VXGE_HAL_VPATH_RPA_STRIP_VLAN_TAG_DISABLE 0 #define VXGE_HAL_VPATH_RPA_STRIP_VLAN_TAG_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_l4_comp_csum; #define VXGE_HAL_VPATH_RPA_L4_COMP_CSUM_ENABLE 1 #define VXGE_HAL_VPATH_RPA_L4_COMP_CSUM_DISABLE 0 #define VXGE_HAL_VPATH_RPA_L4_COMP_CSUM_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_l3_incl_cf; #define VXGE_HAL_VPATH_RPA_L3_INCL_CF_ENABLE 1 #define VXGE_HAL_VPATH_RPA_L3_INCL_CF_DISABLE 0 #define VXGE_HAL_VPATH_RPA_L3_INCL_CF_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_l3_comp_csum; #define VXGE_HAL_VPATH_RPA_L3_COMP_CSUM_ENABLE 1 #define VXGE_HAL_VPATH_RPA_L3_COMP_CSUM_DISABLE 0 #define VXGE_HAL_VPATH_RPA_L3_COMP_CSUM_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_ucast_all_addr_en; #define VXGE_HAL_VPATH_RPA_UCAST_ALL_ADDR_ENABLE 1 #define VXGE_HAL_VPATH_RPA_UCAST_ALL_ADDR_DISABLE 0 #define VXGE_HAL_VPATH_RPA_UCAST_ALL_ADDR_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_mcast_all_addr_en; #define VXGE_HAL_VPATH_RPA_MCAST_ALL_ADDR_ENABLE 1 #define VXGE_HAL_VPATH_RPA_MCAST_ALL_ADDR_DISABLE 0 #define VXGE_HAL_VPATH_RPA_MCAST_ALL_ADDR_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_bcast_en; #define VXGE_HAL_VPATH_RPA_BCAST_ENABLE 1 #define VXGE_HAL_VPATH_RPA_BCAST_DISABLE 0 #define VXGE_HAL_VPATH_RPA_BCAST_USE_FLASH_DEFAULT VXGE_HAL_USE_FLASH_DEFAULT u32 rpa_all_vid_en; #define VXGE_HAL_VPATH_RPA_ALL_VID_ENABLE 1 #define VXGE_HAL_VPATH_RPA_ALL_VID_DISABLE 0 #define VXGE_HAL_VPATH_RPA_ALL_VID_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT u32 vp_queue_l2_flow; #define VXGE_HAL_VPATH_VP_Q_L2_FLOW_ENABLE 1 #define VXGE_HAL_VPATH_VP_Q_L2_FLOW_DISABLE 0 #define VXGE_HAL_VPATH_VP_Q_L2_FLOW_USE_FLASH_DEFAULT \ VXGE_HAL_USE_FLASH_DEFAULT } vxge_hal_vp_config_t; /* * struct vxge_hal_device_config_t - Device configuration. * @dma_blockpool_min: Minimum blocks in the DMA pool * @dma_blockpool_initial: Initial size of DMA Pool * @dma_blockpool_incr: Number of blocks to request each time number of blocks * in the pool reaches dma_pool_min * @dma_blockpool_max: Maximum blocks in DMA pool * @mrpcim_config: MRPCIM section config. Used only for the privileged mode ULD * instance. * @isr_polling_cnt: Maximum number of times to "poll" for Tx and Rx * completions. Used in vxge_hal_device_handle_irq(). * @max_payload_size: Maximum TLP payload size for the device/fFunction. * As a Receiver, the Function/device must handle TLPs as large * as the set value; as . As a Transmitter, the Function/device * must not generate TLPs exceeding the set value. Permissible * values that can be programmed are indicated by the * Max_Payload_Size Supported in the Device Capabilities register * @mmrb_count: Maximum Memory Read Byte Count. Use (VXGE_HAL_USE_FLASH_DEFAULT) * to use default BIOS value. * @stats_refresh_time_sec: Sets the default interval for automatic stats * transfer to the host. This includes MAC stats as well as * PCI stats. * @intr_mode: Line, or MSI-X interrupt. * * @dump_on_unknown: Dump adapter state ("about", statistics, registers) * on UNKNWON#. * @dump_on_serr: Dump adapter state ("about", statistics, registers) on SERR#. * @dump_on_critical: Dump adapter state ("about", statistics, registers) * on CRITICAL#. * @dump_on_eccerr: Dump adapter state ("about", statistics, registers) on * ECC error. * @rth_en: Enable Receive Traffic Hashing(RTH) using IT(Indirection Table). * @rth_it_type: RTH IT table programming type * @rts_mac_en: Enable Receive Traffic Steering using MAC destination address * @rts_qos_en: TBD * @rts_port_en: TBD * @vp_config: Configuration for virtual paths * @max_cqe_groups: The maximum number of adapter CQE group blocks a CQRQ * can own at any one time. * @max_num_wqe_od_groups: The maximum number of WQE Headers/OD Groups that * this S-RQ can own at any one time. * @no_wqe_threshold: Maximum number of times adapter polls WQE Hdr blocks for * WQEs before generating a message or interrupt. * @refill_threshold_high:This field provides a hysteresis upper bound for * automatic adapter refill operations. * @refill_threshold_low:This field provides a hysteresis lower bound for * automatic adapter refill operations. * @eol_policy: This field sets the policy for handling the end of list * condition. * 2'b00 - When EOL is reached, poll until last block wrapper * size is no longer 0. * 2'b01 - Send UMQ message when EOL is reached. * 2'b1x - Poll until the poll_count_max is reached and * if still EOL, send UMQ message * @eol_poll_count_max:sets the maximum number of times the queue manager will * poll fora non-zero block wrapper before giving up and sending * a UMQ message * @ack_blk_limit: Limit on the maximum number of ACK list blocks that can be * held by a session at any one time. * @poll_or_doorbell: TBD * @stats_read_method: Stats read method.(DMA or PIO) * @device_poll_millis: Specify the interval (in mulliseconds) to wait for * register reads * @debug_level: Debug logging level. see vxge_debug_level_e {} * @debug_mask: Module mask for debug logging level. for masks see vxge_debug.h * @lro_enable: SW LRO enable mask * @tracebuf_size: Size of the trace buffer. Set it to '0' to disable. * * X3100 configuration. * Contains per-device configuration parameters, including: * - latency timer (settable via PCI configuration space); * - maximum number of split transactions; * - maximum number of shared splits; * - stats sampling interval, etc. * * In addition, vxge_hal_device_config_t {} includes "subordinate" * configurations, including: * - fifos and rings; * - MAC (done at firmware level). * * See X3100 User Guide for more details. * Note: Valid (min, max) range for each attribute is specified in the body of * the vxge_hal_device_config_t {} structure. Please refer to the * corresponding include file. * See also: vxge_hal_tim_intr_config_t {}. */ typedef struct vxge_hal_device_config_t { u32 dma_blockpool_min; u32 dma_blockpool_initial; u32 dma_blockpool_incr; u32 dma_blockpool_max; #define VXGE_HAL_MIN_DMA_BLOCK_POOL_SIZE 0 #define VXGE_HAL_INITIAL_DMA_BLOCK_POOL_SIZE 0 #define VXGE_HAL_INCR_DMA_BLOCK_POOL_SIZE 4 #define VXGE_HAL_MAX_DMA_BLOCK_POOL_SIZE 4096 vxge_hal_mrpcim_config_t mrpcim_config; u32 isr_polling_cnt; #define VXGE_HAL_MIN_ISR_POLLING_CNT 0 #define VXGE_HAL_MAX_ISR_POLLING_CNT 65536 #define VXGE_HAL_DEF_ISR_POLLING_CNT 1 u32 max_payload_size; #define VXGE_HAL_USE_BIOS_DEFAULT_PAYLOAD_SIZE VXGE_HAL_USE_FLASH_DEFAULT #define VXGE_HAL_MAX_PAYLOAD_SIZE_128 0 #define VXGE_HAL_MAX_PAYLOAD_SIZE_256 1 #define VXGE_HAL_MAX_PAYLOAD_SIZE_512 2 #define VXGE_HAL_MAX_PAYLOAD_SIZE_1024 3 #define VXGE_HAL_MAX_PAYLOAD_SIZE_2048 4 #define VXGE_HAL_MAX_PAYLOAD_SIZE_4096 5 u32 mmrb_count; #define VXGE_HAL_USE_BIOS_DEFAULT_MMRB_COUNT VXGE_HAL_USE_FLASH_DEFAULT #define VXGE_HAL_MMRB_COUNT_128 0 #define VXGE_HAL_MMRB_COUNT_256 1 #define VXGE_HAL_MMRB_COUNT_512 2 #define VXGE_HAL_MMRB_COUNT_1024 3 #define VXGE_HAL_MMRB_COUNT_2048 4 #define VXGE_HAL_MMRB_COUNT_4096 5 u32 stats_refresh_time_sec; #define VXGE_HAL_STATS_REFRESH_DISABLE 0 #define VXGE_HAL_MIN_STATS_REFRESH_TIME 1 #define VXGE_HAL_MAX_STATS_REFRESH_TIME 300 #define VXGE_HAL_USE_FLASH_DEFAULT_STATS_REFRESH_TIME 30 u32 intr_mode; #define VXGE_HAL_INTR_MODE_IRQLINE 0 #define VXGE_HAL_INTR_MODE_MSIX 1 #define VXGE_HAL_INTR_MODE_MSIX_ONE_SHOT 2 #define VXGE_HAL_INTR_MODE_EMULATED_INTA 3 #define VXGE_HAL_INTR_MODE_DEF 0 u32 dump_on_unknown; #define VXGE_HAL_DUMP_ON_UNKNOWN_DISABLE 0 #define VXGE_HAL_DUMP_ON_UNKNOWN_ENABLE 1 #define VXGE_HAL_DUMP_ON_UNKNOWN_DEFAULT 0 u32 dump_on_serr; #define VXGE_HAL_DUMP_ON_SERR_DISABLE 0 #define VXGE_HAL_DUMP_ON_SERR_ENABLE 1 #define VXGE_HAL_DUMP_ON_SERR_DEFAULT 0 u32 dump_on_critical; #define VXGE_HAL_DUMP_ON_CRITICAL_DISABLE 0 #define VXGE_HAL_DUMP_ON_CRITICAL_ENABLE 1 #define VXGE_HAL_DUMP_ON_CRITICAL_DEFAULT 0 u32 dump_on_eccerr; #define VXGE_HAL_DUMP_ON_ECCERR_DISABLE 0 #define VXGE_HAL_DUMP_ON_ECCERR_ENABLE 1 #define VXGE_HAL_DUMP_ON_ECCERR_DEFAULT 0 u32 rth_en; #define VXGE_HAL_RTH_DISABLE 0 #define VXGE_HAL_RTH_ENABLE 1 #define VXGE_HAL_RTH_DEFAULT 0 u32 rth_it_type; #define VXGE_HAL_RTH_IT_TYPE_SOLO_IT 0 #define VXGE_HAL_RTH_IT_TYPE_MULTI_IT 1 #define VXGE_HAL_RTH_IT_TYPE_DEFAULT 0 u32 rts_mac_en; #define VXGE_HAL_RTS_MAC_DISABLE 0 #define VXGE_HAL_RTS_MAC_ENABLE 1 #define VXGE_HAL_RTS_MAC_DEFAULT 0 u32 rts_qos_en; #define VXGE_HAL_RTS_QOS_DISABLE 0 #define VXGE_HAL_RTS_QOS_ENABLE 1 #define VXGE_HAL_RTS_QOS_DEFAULT 0 u32 rts_port_en; #define VXGE_HAL_RTS_PORT_DISABLE 0 #define VXGE_HAL_RTS_PORT_ENABLE 1 #define VXGE_HAL_RTS_PORT_DEFAULT 0 vxge_hal_vp_config_t vp_config[VXGE_HAL_MAX_VIRTUAL_PATHS]; u32 max_cqe_groups; #define VXGE_HAL_MIN_MAX_CQE_GROUPS 1 #define VXGE_HAL_MAX_MAX_CQE_GROUPS 16 #define VXGE_HAL_DEF_MAX_CQE_GROUPS 16 u32 max_num_wqe_od_groups; #define VXGE_HAL_MIN_MAX_NUM_OD_GROUPS 1 #define VXGE_HAL_MAX_MAX_NUM_OD_GROUPS 16 #define VXGE_HAL_DEF_MAX_NUM_OD_GROUPS 16 u32 no_wqe_threshold; #define VXGE_HAL_MIN_NO_WQE_THRESHOLD 1 #define VXGE_HAL_MAX_NO_WQE_THRESHOLD 16 #define VXGE_HAL_DEF_NO_WQE_THRESHOLD 16 u32 refill_threshold_high; #define VXGE_HAL_MIN_REFILL_THRESHOLD_HIGH 1 #define VXGE_HAL_MAX_REFILL_THRESHOLD_HIGH 16 #define VXGE_HAL_DEF_REFILL_THRESHOLD_HIGH 16 u32 refill_threshold_low; #define VXGE_HAL_MIN_REFILL_THRESHOLD_LOW 1 #define VXGE_HAL_MAX_REFILL_THRESHOLD_LOW 16 #define VXGE_HAL_DEF_REFILL_THRESHOLD_LOW 16 u32 ack_blk_limit; #define VXGE_HAL_MIN_ACK_BLOCK_LIMIT 1 #define VXGE_HAL_MAX_ACK_BLOCK_LIMIT 16 #define VXGE_HAL_DEF_ACK_BLOCK_LIMIT 16 u32 poll_or_doorbell; #define VXGE_HAL_POLL_OR_DOORBELL_POLL 1 #define VXGE_HAL_POLL_OR_DOORBELL_DOORBELL 0 #define VXGE_HAL_POLL_OR_DOORBELL_DEFAULT 1 u32 stats_read_method; #define VXGE_HAL_STATS_READ_METHOD_DMA 1 #define VXGE_HAL_STATS_READ_METHOD_PIO 0 #define VXGE_HAL_STATS_READ_METHOD_DEFAULT 1 u32 device_poll_millis; #define VXGE_HAL_MIN_DEVICE_POLL_MILLIS 1 #define VXGE_HAL_MAX_DEVICE_POLL_MILLIS 100000 #define VXGE_HAL_DEF_DEVICE_POLL_MILLIS 1000 vxge_debug_level_e debug_level; u32 debug_mask; #if defined(VXGE_TRACE_INTO_CIRCULAR_ARR) u32 tracebuf_size; #define VXGE_HAL_MIN_CIRCULAR_ARR 4096 #define VXGE_HAL_MAX_CIRCULAR_ARR 65536 #define VXGE_HAL_DEF_CIRCULAR_ARR 16384 #endif } vxge_hal_device_config_t; __EXTERN_END_DECLS #endif /* VXGE_HAL_CONFIG_H */