Index: head/sys/dev/sfxge/common/efx.h =================================================================== --- head/sys/dev/sfxge/common/efx.h (revision 293899) +++ head/sys/dev/sfxge/common/efx.h (revision 293900) @@ -1,2317 +1,2318 @@ /*- * Copyright (c) 2006-2015 Solarflare Communications Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are * those of the authors and should not be interpreted as representing official * policies, either expressed or implied, of the FreeBSD Project. * * $FreeBSD$ */ #ifndef _SYS_EFX_H #define _SYS_EFX_H #include "efsys.h" #include "efx_phy_ids.h" #ifdef __cplusplus extern "C" { #endif #define EFX_STATIC_ASSERT(_cond) \ ((void)sizeof(char[(_cond) ? 1 : -1])) #define EFX_ARRAY_SIZE(_array) \ (sizeof(_array) / sizeof((_array)[0])) #define EFX_FIELD_OFFSET(_type, _field) \ ((size_t) &(((_type *)0)->_field)) /* Return codes */ typedef __success(return == 0) int efx_rc_t; /* Chip families */ typedef enum efx_family_e { EFX_FAMILY_INVALID, EFX_FAMILY_FALCON, EFX_FAMILY_SIENA, EFX_FAMILY_HUNTINGTON, EFX_FAMILY_MEDFORD, EFX_FAMILY_NTYPES } efx_family_t; extern __checkReturn efx_rc_t efx_family( __in uint16_t venid, __in uint16_t devid, __out efx_family_t *efp); extern __checkReturn efx_rc_t efx_infer_family( __in efsys_bar_t *esbp, __out efx_family_t *efp); #define EFX_PCI_VENID_SFC 0x1924 #define EFX_PCI_DEVID_FALCON 0x0710 /* SFC4000 */ #define EFX_PCI_DEVID_BETHPAGE 0x0803 /* SFC9020 */ #define EFX_PCI_DEVID_SIENA 0x0813 /* SFL9021 */ #define EFX_PCI_DEVID_SIENA_F1_UNINIT 0x0810 #define EFX_PCI_DEVID_HUNTINGTON_PF_UNINIT 0x0901 #define EFX_PCI_DEVID_FARMINGDALE 0x0903 /* SFC9120 PF */ #define EFX_PCI_DEVID_GREENPORT 0x0923 /* SFC9140 PF */ #define EFX_PCI_DEVID_FARMINGDALE_VF 0x1903 /* SFC9120 VF */ #define EFX_PCI_DEVID_GREENPORT_VF 0x1923 /* SFC9140 VF */ #define EFX_PCI_DEVID_MEDFORD_PF_UNINIT 0x0913 #define EFX_PCI_DEVID_MEDFORD 0x0A03 /* SFC9240 PF */ #define EFX_PCI_DEVID_MEDFORD_VF 0x1A03 /* SFC9240 VF */ #define EFX_MEM_BAR 2 /* Error codes */ enum { EFX_ERR_INVALID, EFX_ERR_SRAM_OOB, EFX_ERR_BUFID_DC_OOB, EFX_ERR_MEM_PERR, EFX_ERR_RBUF_OWN, EFX_ERR_TBUF_OWN, EFX_ERR_RDESQ_OWN, EFX_ERR_TDESQ_OWN, EFX_ERR_EVQ_OWN, EFX_ERR_EVFF_OFLO, EFX_ERR_ILL_ADDR, EFX_ERR_SRAM_PERR, EFX_ERR_NCODES }; /* Calculate the IEEE 802.3 CRC32 of a MAC addr */ extern __checkReturn uint32_t efx_crc32_calculate( __in uint32_t crc_init, __in_ecount(length) uint8_t const *input, __in int length); /* Type prototypes */ typedef struct efx_rxq_s efx_rxq_t; /* NIC */ typedef struct efx_nic_s efx_nic_t; #define EFX_NIC_FUNC_PRIMARY 0x00000001 #define EFX_NIC_FUNC_LINKCTRL 0x00000002 #define EFX_NIC_FUNC_TRUSTED 0x00000004 extern __checkReturn efx_rc_t efx_nic_create( __in efx_family_t family, __in efsys_identifier_t *esip, __in efsys_bar_t *esbp, __in efsys_lock_t *eslp, __deref_out efx_nic_t **enpp); extern __checkReturn efx_rc_t efx_nic_probe( __in efx_nic_t *enp); #if EFSYS_OPT_PCIE_TUNE extern __checkReturn efx_rc_t efx_nic_pcie_tune( __in efx_nic_t *enp, unsigned int nlanes); extern __checkReturn efx_rc_t efx_nic_pcie_extended_sync( __in efx_nic_t *enp); #endif /* EFSYS_OPT_PCIE_TUNE */ extern __checkReturn efx_rc_t efx_nic_init( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_nic_reset( __in efx_nic_t *enp); #if EFSYS_OPT_DIAG extern __checkReturn efx_rc_t efx_nic_register_test( __in efx_nic_t *enp); #endif /* EFSYS_OPT_DIAG */ extern void efx_nic_fini( __in efx_nic_t *enp); extern void efx_nic_unprobe( __in efx_nic_t *enp); extern void efx_nic_destroy( __in efx_nic_t *enp); #if EFSYS_OPT_MCDI #if EFSYS_OPT_HUNTINGTON || EFSYS_OPT_MEDFORD /* Huntington and Medford require MCDIv2 commands */ #define WITH_MCDI_V2 1 #endif typedef struct efx_mcdi_req_s efx_mcdi_req_t; typedef enum efx_mcdi_exception_e { EFX_MCDI_EXCEPTION_MC_REBOOT, EFX_MCDI_EXCEPTION_MC_BADASSERT, } efx_mcdi_exception_t; #if EFSYS_OPT_MCDI_LOGGING typedef enum efx_log_msg_e { EFX_LOG_INVALID, EFX_LOG_MCDI_REQUEST, EFX_LOG_MCDI_RESPONSE, } efx_log_msg_t; #endif /* EFSYS_OPT_MCDI_LOGGING */ typedef struct efx_mcdi_transport_s { void *emt_context; efsys_mem_t *emt_dma_mem; void (*emt_execute)(void *, efx_mcdi_req_t *); void (*emt_ev_cpl)(void *); void (*emt_exception)(void *, efx_mcdi_exception_t); #if EFSYS_OPT_MCDI_LOGGING void (*emt_logger)(void *, efx_log_msg_t, void *, size_t, void *, size_t); #endif /* EFSYS_OPT_MCDI_LOGGING */ #if EFSYS_OPT_MCDI_PROXY_AUTH void (*emt_ev_proxy_response)(void *, uint32_t, efx_rc_t); #endif /* EFSYS_OPT_MCDI_PROXY_AUTH */ } efx_mcdi_transport_t; extern __checkReturn efx_rc_t efx_mcdi_init( __in efx_nic_t *enp, __in const efx_mcdi_transport_t *mtp); extern __checkReturn efx_rc_t efx_mcdi_reboot( __in efx_nic_t *enp); void efx_mcdi_new_epoch( __in efx_nic_t *enp); extern void efx_mcdi_request_start( __in efx_nic_t *enp, __in efx_mcdi_req_t *emrp, __in boolean_t ev_cpl); extern __checkReturn boolean_t efx_mcdi_request_poll( __in efx_nic_t *enp); extern __checkReturn boolean_t efx_mcdi_request_abort( __in efx_nic_t *enp); extern void efx_mcdi_fini( __in efx_nic_t *enp); #endif /* EFSYS_OPT_MCDI */ /* INTR */ #define EFX_NINTR_FALCON 64 #define EFX_NINTR_SIENA 1024 typedef enum efx_intr_type_e { EFX_INTR_INVALID = 0, EFX_INTR_LINE, EFX_INTR_MESSAGE, EFX_INTR_NTYPES } efx_intr_type_t; #define EFX_INTR_SIZE (sizeof (efx_oword_t)) extern __checkReturn efx_rc_t efx_intr_init( __in efx_nic_t *enp, __in efx_intr_type_t type, __in efsys_mem_t *esmp); extern void efx_intr_enable( __in efx_nic_t *enp); extern void efx_intr_disable( __in efx_nic_t *enp); extern void efx_intr_disable_unlocked( __in efx_nic_t *enp); #define EFX_INTR_NEVQS 32 extern __checkReturn efx_rc_t efx_intr_trigger( __in efx_nic_t *enp, __in unsigned int level); extern void efx_intr_status_line( __in efx_nic_t *enp, __out boolean_t *fatalp, __out uint32_t *maskp); extern void efx_intr_status_message( __in efx_nic_t *enp, __in unsigned int message, __out boolean_t *fatalp); extern void efx_intr_fatal( __in efx_nic_t *enp); extern void efx_intr_fini( __in efx_nic_t *enp); /* MAC */ #if EFSYS_OPT_MAC_STATS /* START MKCONFIG GENERATED EfxHeaderMacBlock e323546097fd7c65 */ typedef enum efx_mac_stat_e { EFX_MAC_RX_OCTETS, EFX_MAC_RX_PKTS, EFX_MAC_RX_UNICST_PKTS, EFX_MAC_RX_MULTICST_PKTS, EFX_MAC_RX_BRDCST_PKTS, EFX_MAC_RX_PAUSE_PKTS, EFX_MAC_RX_LE_64_PKTS, EFX_MAC_RX_65_TO_127_PKTS, EFX_MAC_RX_128_TO_255_PKTS, EFX_MAC_RX_256_TO_511_PKTS, EFX_MAC_RX_512_TO_1023_PKTS, EFX_MAC_RX_1024_TO_15XX_PKTS, EFX_MAC_RX_GE_15XX_PKTS, EFX_MAC_RX_ERRORS, EFX_MAC_RX_FCS_ERRORS, EFX_MAC_RX_DROP_EVENTS, EFX_MAC_RX_FALSE_CARRIER_ERRORS, EFX_MAC_RX_SYMBOL_ERRORS, EFX_MAC_RX_ALIGN_ERRORS, EFX_MAC_RX_INTERNAL_ERRORS, EFX_MAC_RX_JABBER_PKTS, EFX_MAC_RX_LANE0_CHAR_ERR, EFX_MAC_RX_LANE1_CHAR_ERR, EFX_MAC_RX_LANE2_CHAR_ERR, EFX_MAC_RX_LANE3_CHAR_ERR, EFX_MAC_RX_LANE0_DISP_ERR, EFX_MAC_RX_LANE1_DISP_ERR, EFX_MAC_RX_LANE2_DISP_ERR, EFX_MAC_RX_LANE3_DISP_ERR, EFX_MAC_RX_MATCH_FAULT, EFX_MAC_RX_NODESC_DROP_CNT, EFX_MAC_TX_OCTETS, EFX_MAC_TX_PKTS, EFX_MAC_TX_UNICST_PKTS, EFX_MAC_TX_MULTICST_PKTS, EFX_MAC_TX_BRDCST_PKTS, EFX_MAC_TX_PAUSE_PKTS, EFX_MAC_TX_LE_64_PKTS, EFX_MAC_TX_65_TO_127_PKTS, EFX_MAC_TX_128_TO_255_PKTS, EFX_MAC_TX_256_TO_511_PKTS, EFX_MAC_TX_512_TO_1023_PKTS, EFX_MAC_TX_1024_TO_15XX_PKTS, EFX_MAC_TX_GE_15XX_PKTS, EFX_MAC_TX_ERRORS, EFX_MAC_TX_SGL_COL_PKTS, EFX_MAC_TX_MULT_COL_PKTS, EFX_MAC_TX_EX_COL_PKTS, EFX_MAC_TX_LATE_COL_PKTS, EFX_MAC_TX_DEF_PKTS, EFX_MAC_TX_EX_DEF_PKTS, EFX_MAC_PM_TRUNC_BB_OVERFLOW, EFX_MAC_PM_DISCARD_BB_OVERFLOW, EFX_MAC_PM_TRUNC_VFIFO_FULL, EFX_MAC_PM_DISCARD_VFIFO_FULL, EFX_MAC_PM_TRUNC_QBB, EFX_MAC_PM_DISCARD_QBB, EFX_MAC_PM_DISCARD_MAPPING, EFX_MAC_RXDP_Q_DISABLED_PKTS, EFX_MAC_RXDP_DI_DROPPED_PKTS, EFX_MAC_RXDP_STREAMING_PKTS, EFX_MAC_RXDP_HLB_FETCH, EFX_MAC_RXDP_HLB_WAIT, EFX_MAC_VADAPTER_RX_UNICAST_PACKETS, EFX_MAC_VADAPTER_RX_UNICAST_BYTES, EFX_MAC_VADAPTER_RX_MULTICAST_PACKETS, EFX_MAC_VADAPTER_RX_MULTICAST_BYTES, EFX_MAC_VADAPTER_RX_BROADCAST_PACKETS, EFX_MAC_VADAPTER_RX_BROADCAST_BYTES, EFX_MAC_VADAPTER_RX_BAD_PACKETS, EFX_MAC_VADAPTER_RX_BAD_BYTES, EFX_MAC_VADAPTER_RX_OVERFLOW, EFX_MAC_VADAPTER_TX_UNICAST_PACKETS, EFX_MAC_VADAPTER_TX_UNICAST_BYTES, EFX_MAC_VADAPTER_TX_MULTICAST_PACKETS, EFX_MAC_VADAPTER_TX_MULTICAST_BYTES, EFX_MAC_VADAPTER_TX_BROADCAST_PACKETS, EFX_MAC_VADAPTER_TX_BROADCAST_BYTES, EFX_MAC_VADAPTER_TX_BAD_PACKETS, EFX_MAC_VADAPTER_TX_BAD_BYTES, EFX_MAC_VADAPTER_TX_OVERFLOW, EFX_MAC_NSTATS } efx_mac_stat_t; /* END MKCONFIG GENERATED EfxHeaderMacBlock */ #endif /* EFSYS_OPT_MAC_STATS */ typedef enum efx_link_mode_e { EFX_LINK_UNKNOWN = 0, EFX_LINK_DOWN, EFX_LINK_10HDX, EFX_LINK_10FDX, EFX_LINK_100HDX, EFX_LINK_100FDX, EFX_LINK_1000HDX, EFX_LINK_1000FDX, EFX_LINK_10000FDX, EFX_LINK_40000FDX, EFX_LINK_NMODES } efx_link_mode_t; #define EFX_MAC_ADDR_LEN 6 #define EFX_MAC_ADDR_IS_MULTICAST(_address) (((uint8_t*)_address)[0] & 0x01) #define EFX_MAC_MULTICAST_LIST_MAX 256 #define EFX_MAC_SDU_MAX 9202 #define EFX_MAC_PDU(_sdu) \ P2ROUNDUP(((_sdu) \ + /* EtherII */ 14 \ + /* VLAN */ 4 \ + /* CRC */ 4 \ + /* bug16011 */ 16), \ (1 << 3)) #define EFX_MAC_PDU_MIN 60 #define EFX_MAC_PDU_MAX EFX_MAC_PDU(EFX_MAC_SDU_MAX) extern __checkReturn efx_rc_t efx_mac_pdu_set( __in efx_nic_t *enp, __in size_t pdu); extern __checkReturn efx_rc_t efx_mac_addr_set( __in efx_nic_t *enp, __in uint8_t *addr); extern __checkReturn efx_rc_t efx_mac_filter_set( __in efx_nic_t *enp, __in boolean_t all_unicst, __in boolean_t mulcst, __in boolean_t all_mulcst, __in boolean_t brdcst); extern __checkReturn efx_rc_t efx_mac_multicast_list_set( __in efx_nic_t *enp, __in_ecount(6*count) uint8_t const *addrs, __in int count); extern __checkReturn efx_rc_t efx_mac_filter_default_rxq_set( __in efx_nic_t *enp, __in efx_rxq_t *erp, __in boolean_t using_rss); extern void efx_mac_filter_default_rxq_clear( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_mac_drain( __in efx_nic_t *enp, __in boolean_t enabled); extern __checkReturn efx_rc_t efx_mac_up( __in efx_nic_t *enp, __out boolean_t *mac_upp); #define EFX_FCNTL_RESPOND 0x00000001 #define EFX_FCNTL_GENERATE 0x00000002 extern __checkReturn efx_rc_t efx_mac_fcntl_set( __in efx_nic_t *enp, __in unsigned int fcntl, __in boolean_t autoneg); extern void efx_mac_fcntl_get( __in efx_nic_t *enp, __out unsigned int *fcntl_wantedp, __out unsigned int *fcntl_linkp); #if EFSYS_OPT_MAC_STATS #if EFSYS_OPT_NAMES extern __checkReturn const char * efx_mac_stat_name( __in efx_nic_t *enp, __in unsigned int id); #endif /* EFSYS_OPT_NAMES */ #define EFX_MAC_STATS_SIZE 0x400 /* * Upload mac statistics supported by the hardware into the given buffer. * * The reference buffer must be at least %EFX_MAC_STATS_SIZE bytes, * and page aligned. * * The hardware will only DMA statistics that it understands (of course). * Drivers should not make any assumptions about which statistics are * supported, especially when the statistics are generated by firmware. * * Thus, drivers should zero this buffer before use, so that not-understood * statistics read back as zero. */ extern __checkReturn efx_rc_t efx_mac_stats_upload( __in efx_nic_t *enp, __in efsys_mem_t *esmp); extern __checkReturn efx_rc_t efx_mac_stats_periodic( __in efx_nic_t *enp, __in efsys_mem_t *esmp, __in uint16_t period_ms, __in boolean_t events); extern __checkReturn efx_rc_t efx_mac_stats_update( __in efx_nic_t *enp, __in efsys_mem_t *esmp, __inout_ecount(EFX_MAC_NSTATS) efsys_stat_t *stat, __inout_opt uint32_t *generationp); #endif /* EFSYS_OPT_MAC_STATS */ /* MON */ typedef enum efx_mon_type_e { EFX_MON_INVALID = 0, EFX_MON_NULL, EFX_MON_LM87, EFX_MON_MAX6647, EFX_MON_SFC90X0, EFX_MON_SFC91X0, EFX_MON_SFC92X0, EFX_MON_NTYPES } efx_mon_type_t; #if EFSYS_OPT_NAMES extern const char * efx_mon_name( __in efx_nic_t *enp); #endif /* EFSYS_OPT_NAMES */ extern __checkReturn efx_rc_t efx_mon_init( __in efx_nic_t *enp); #if EFSYS_OPT_MON_STATS #define EFX_MON_STATS_PAGE_SIZE 0x100 #define EFX_MON_MASK_ELEMENT_SIZE 32 /* START MKCONFIG GENERATED MonitorHeaderStatsBlock c09b13f732431f23 */ typedef enum efx_mon_stat_e { EFX_MON_STAT_2_5V, EFX_MON_STAT_VCCP1, EFX_MON_STAT_VCC, EFX_MON_STAT_5V, EFX_MON_STAT_12V, EFX_MON_STAT_VCCP2, EFX_MON_STAT_EXT_TEMP, EFX_MON_STAT_INT_TEMP, EFX_MON_STAT_AIN1, EFX_MON_STAT_AIN2, EFX_MON_STAT_INT_COOLING, EFX_MON_STAT_EXT_COOLING, EFX_MON_STAT_1V, EFX_MON_STAT_1_2V, EFX_MON_STAT_1_8V, EFX_MON_STAT_3_3V, EFX_MON_STAT_1_2VA, EFX_MON_STAT_VREF, EFX_MON_STAT_VAOE, EFX_MON_STAT_AOE_TEMP, EFX_MON_STAT_PSU_AOE_TEMP, EFX_MON_STAT_PSU_TEMP, EFX_MON_STAT_FAN0, EFX_MON_STAT_FAN1, EFX_MON_STAT_FAN2, EFX_MON_STAT_FAN3, EFX_MON_STAT_FAN4, EFX_MON_STAT_VAOE_IN, EFX_MON_STAT_IAOE, EFX_MON_STAT_IAOE_IN, EFX_MON_STAT_NIC_POWER, EFX_MON_STAT_0_9V, EFX_MON_STAT_I0_9V, EFX_MON_STAT_I1_2V, EFX_MON_STAT_0_9V_ADC, EFX_MON_STAT_INT_TEMP2, EFX_MON_STAT_VREG_TEMP, EFX_MON_STAT_VREG_0_9V_TEMP, EFX_MON_STAT_VREG_1_2V_TEMP, EFX_MON_STAT_INT_VPTAT, EFX_MON_STAT_INT_ADC_TEMP, EFX_MON_STAT_EXT_VPTAT, EFX_MON_STAT_EXT_ADC_TEMP, EFX_MON_STAT_AMBIENT_TEMP, EFX_MON_STAT_AIRFLOW, EFX_MON_STAT_VDD08D_VSS08D_CSR, EFX_MON_STAT_VDD08D_VSS08D_CSR_EXTADC, EFX_MON_STAT_HOTPOINT_TEMP, EFX_MON_STAT_PHY_POWER_SWITCH_PORT0, EFX_MON_STAT_PHY_POWER_SWITCH_PORT1, EFX_MON_STAT_MUM_VCC, EFX_MON_STAT_0V9_A, EFX_MON_STAT_I0V9_A, EFX_MON_STAT_0V9_A_TEMP, EFX_MON_STAT_0V9_B, EFX_MON_STAT_I0V9_B, EFX_MON_STAT_0V9_B_TEMP, EFX_MON_STAT_CCOM_AVREG_1V2_SUPPLY, EFX_MON_STAT_CCOM_AVREG_1V2_SUPPLY_EXT_ADC, EFX_MON_STAT_CCOM_AVREG_1V8_SUPPLY, EFX_MON_STAT_CCOM_AVREG_1V8_SUPPLY_EXT_ADC, EFX_MON_STAT_CONTROLLER_MASTER_VPTAT, EFX_MON_STAT_CONTROLLER_MASTER_INTERNAL_TEMP, EFX_MON_STAT_CONTROLLER_MASTER_VPTAT_EXT_ADC, EFX_MON_STAT_CONTROLLER_MASTER_INTERNAL_TEMP_EXT_ADC, EFX_MON_STAT_CONTROLLER_SLAVE_VPTAT, EFX_MON_STAT_CONTROLLER_SLAVE_INTERNAL_TEMP, EFX_MON_STAT_CONTROLLER_SLAVE_VPTAT_EXT_ADC, EFX_MON_STAT_CONTROLLER_SLAVE_INTERNAL_TEMP_EXT_ADC, EFX_MON_STAT_SODIMM_VOUT, EFX_MON_STAT_SODIMM_0_TEMP, EFX_MON_STAT_SODIMM_1_TEMP, EFX_MON_STAT_PHY0_VCC, EFX_MON_STAT_PHY1_VCC, EFX_MON_STAT_CONTROLLER_TDIODE_TEMP, EFX_MON_NSTATS } efx_mon_stat_t; /* END MKCONFIG GENERATED MonitorHeaderStatsBlock */ typedef enum efx_mon_stat_state_e { EFX_MON_STAT_STATE_OK = 0, EFX_MON_STAT_STATE_WARNING = 1, EFX_MON_STAT_STATE_FATAL = 2, EFX_MON_STAT_STATE_BROKEN = 3, EFX_MON_STAT_STATE_NO_READING = 4, } efx_mon_stat_state_t; typedef struct efx_mon_stat_value_s { uint16_t emsv_value; uint16_t emsv_state; } efx_mon_stat_value_t; #if EFSYS_OPT_NAMES extern const char * efx_mon_stat_name( __in efx_nic_t *enp, __in efx_mon_stat_t id); #endif /* EFSYS_OPT_NAMES */ extern __checkReturn efx_rc_t efx_mon_stats_update( __in efx_nic_t *enp, __in efsys_mem_t *esmp, __inout_ecount(EFX_MON_NSTATS) efx_mon_stat_value_t *values); #endif /* EFSYS_OPT_MON_STATS */ extern void efx_mon_fini( __in efx_nic_t *enp); /* PHY */ #define PMA_PMD_MMD 1 #define PCS_MMD 3 #define PHY_XS_MMD 4 #define DTE_XS_MMD 5 #define AN_MMD 7 #define CL22EXT_MMD 29 #define MAXMMD ((1 << 5) - 1) extern __checkReturn efx_rc_t efx_phy_verify( __in efx_nic_t *enp); #if EFSYS_OPT_PHY_LED_CONTROL typedef enum efx_phy_led_mode_e { EFX_PHY_LED_DEFAULT = 0, EFX_PHY_LED_OFF, EFX_PHY_LED_ON, EFX_PHY_LED_FLASH, EFX_PHY_LED_NMODES } efx_phy_led_mode_t; extern __checkReturn efx_rc_t efx_phy_led_set( __in efx_nic_t *enp, __in efx_phy_led_mode_t mode); #endif /* EFSYS_OPT_PHY_LED_CONTROL */ extern __checkReturn efx_rc_t efx_port_init( __in efx_nic_t *enp); #if EFSYS_OPT_LOOPBACK typedef enum efx_loopback_type_e { EFX_LOOPBACK_OFF = 0, EFX_LOOPBACK_DATA = 1, EFX_LOOPBACK_GMAC = 2, EFX_LOOPBACK_XGMII = 3, EFX_LOOPBACK_XGXS = 4, EFX_LOOPBACK_XAUI = 5, EFX_LOOPBACK_GMII = 6, EFX_LOOPBACK_SGMII = 7, EFX_LOOPBACK_XGBR = 8, EFX_LOOPBACK_XFI = 9, EFX_LOOPBACK_XAUI_FAR = 10, EFX_LOOPBACK_GMII_FAR = 11, EFX_LOOPBACK_SGMII_FAR = 12, EFX_LOOPBACK_XFI_FAR = 13, EFX_LOOPBACK_GPHY = 14, EFX_LOOPBACK_PHY_XS = 15, EFX_LOOPBACK_PCS = 16, EFX_LOOPBACK_PMA_PMD = 17, EFX_LOOPBACK_XPORT = 18, EFX_LOOPBACK_XGMII_WS = 19, EFX_LOOPBACK_XAUI_WS = 20, EFX_LOOPBACK_XAUI_WS_FAR = 21, EFX_LOOPBACK_XAUI_WS_NEAR = 22, EFX_LOOPBACK_GMII_WS = 23, EFX_LOOPBACK_XFI_WS = 24, EFX_LOOPBACK_XFI_WS_FAR = 25, EFX_LOOPBACK_PHYXS_WS = 26, EFX_LOOPBACK_PMA_INT = 27, EFX_LOOPBACK_SD_NEAR = 28, EFX_LOOPBACK_SD_FAR = 29, EFX_LOOPBACK_PMA_INT_WS = 30, EFX_LOOPBACK_SD_FEP2_WS = 31, EFX_LOOPBACK_SD_FEP1_5_WS = 32, EFX_LOOPBACK_SD_FEP_WS = 33, EFX_LOOPBACK_SD_FES_WS = 34, EFX_LOOPBACK_NTYPES } efx_loopback_type_t; typedef enum efx_loopback_kind_e { EFX_LOOPBACK_KIND_OFF = 0, EFX_LOOPBACK_KIND_ALL, EFX_LOOPBACK_KIND_MAC, EFX_LOOPBACK_KIND_PHY, EFX_LOOPBACK_NKINDS } efx_loopback_kind_t; extern void efx_loopback_mask( __in efx_loopback_kind_t loopback_kind, __out efx_qword_t *maskp); extern __checkReturn efx_rc_t efx_port_loopback_set( __in efx_nic_t *enp, __in efx_link_mode_t link_mode, __in efx_loopback_type_t type); #if EFSYS_OPT_NAMES extern __checkReturn const char * efx_loopback_type_name( __in efx_nic_t *enp, __in efx_loopback_type_t type); #endif /* EFSYS_OPT_NAMES */ #endif /* EFSYS_OPT_LOOPBACK */ extern __checkReturn efx_rc_t efx_port_poll( __in efx_nic_t *enp, __out_opt efx_link_mode_t *link_modep); extern void efx_port_fini( __in efx_nic_t *enp); typedef enum efx_phy_cap_type_e { EFX_PHY_CAP_INVALID = 0, EFX_PHY_CAP_10HDX, EFX_PHY_CAP_10FDX, EFX_PHY_CAP_100HDX, EFX_PHY_CAP_100FDX, EFX_PHY_CAP_1000HDX, EFX_PHY_CAP_1000FDX, EFX_PHY_CAP_10000FDX, EFX_PHY_CAP_PAUSE, EFX_PHY_CAP_ASYM, EFX_PHY_CAP_AN, EFX_PHY_CAP_40000FDX, EFX_PHY_CAP_NTYPES } efx_phy_cap_type_t; #define EFX_PHY_CAP_CURRENT 0x00000000 #define EFX_PHY_CAP_DEFAULT 0x00000001 #define EFX_PHY_CAP_PERM 0x00000002 extern void efx_phy_adv_cap_get( __in efx_nic_t *enp, __in uint32_t flag, __out uint32_t *maskp); extern __checkReturn efx_rc_t efx_phy_adv_cap_set( __in efx_nic_t *enp, __in uint32_t mask); extern void efx_phy_lp_cap_get( __in efx_nic_t *enp, __out uint32_t *maskp); extern __checkReturn efx_rc_t efx_phy_oui_get( __in efx_nic_t *enp, __out uint32_t *ouip); typedef enum efx_phy_media_type_e { EFX_PHY_MEDIA_INVALID = 0, EFX_PHY_MEDIA_XAUI, EFX_PHY_MEDIA_CX4, EFX_PHY_MEDIA_KX4, EFX_PHY_MEDIA_XFP, EFX_PHY_MEDIA_SFP_PLUS, EFX_PHY_MEDIA_BASE_T, EFX_PHY_MEDIA_QSFP_PLUS, EFX_PHY_MEDIA_NTYPES } efx_phy_media_type_t; /* Get the type of medium currently used. If the board has ports for * modules, a module is present, and we recognise the media type of * the module, then this will be the media type of the module. * Otherwise it will be the media type of the port. */ extern void efx_phy_media_type_get( __in efx_nic_t *enp, __out efx_phy_media_type_t *typep); #if EFSYS_OPT_PHY_STATS /* START MKCONFIG GENERATED PhyHeaderStatsBlock 30ed56ad501f8e36 */ typedef enum efx_phy_stat_e { EFX_PHY_STAT_OUI, EFX_PHY_STAT_PMA_PMD_LINK_UP, EFX_PHY_STAT_PMA_PMD_RX_FAULT, EFX_PHY_STAT_PMA_PMD_TX_FAULT, EFX_PHY_STAT_PMA_PMD_REV_A, EFX_PHY_STAT_PMA_PMD_REV_B, EFX_PHY_STAT_PMA_PMD_REV_C, EFX_PHY_STAT_PMA_PMD_REV_D, EFX_PHY_STAT_PCS_LINK_UP, EFX_PHY_STAT_PCS_RX_FAULT, EFX_PHY_STAT_PCS_TX_FAULT, EFX_PHY_STAT_PCS_BER, EFX_PHY_STAT_PCS_BLOCK_ERRORS, EFX_PHY_STAT_PHY_XS_LINK_UP, EFX_PHY_STAT_PHY_XS_RX_FAULT, EFX_PHY_STAT_PHY_XS_TX_FAULT, EFX_PHY_STAT_PHY_XS_ALIGN, EFX_PHY_STAT_PHY_XS_SYNC_A, EFX_PHY_STAT_PHY_XS_SYNC_B, EFX_PHY_STAT_PHY_XS_SYNC_C, EFX_PHY_STAT_PHY_XS_SYNC_D, EFX_PHY_STAT_AN_LINK_UP, EFX_PHY_STAT_AN_MASTER, EFX_PHY_STAT_AN_LOCAL_RX_OK, EFX_PHY_STAT_AN_REMOTE_RX_OK, EFX_PHY_STAT_CL22EXT_LINK_UP, EFX_PHY_STAT_SNR_A, EFX_PHY_STAT_SNR_B, EFX_PHY_STAT_SNR_C, EFX_PHY_STAT_SNR_D, EFX_PHY_STAT_PMA_PMD_SIGNAL_A, EFX_PHY_STAT_PMA_PMD_SIGNAL_B, EFX_PHY_STAT_PMA_PMD_SIGNAL_C, EFX_PHY_STAT_PMA_PMD_SIGNAL_D, EFX_PHY_STAT_AN_COMPLETE, EFX_PHY_STAT_PMA_PMD_REV_MAJOR, EFX_PHY_STAT_PMA_PMD_REV_MINOR, EFX_PHY_STAT_PMA_PMD_REV_MICRO, EFX_PHY_STAT_PCS_FW_VERSION_0, EFX_PHY_STAT_PCS_FW_VERSION_1, EFX_PHY_STAT_PCS_FW_VERSION_2, EFX_PHY_STAT_PCS_FW_VERSION_3, EFX_PHY_STAT_PCS_FW_BUILD_YY, EFX_PHY_STAT_PCS_FW_BUILD_MM, EFX_PHY_STAT_PCS_FW_BUILD_DD, EFX_PHY_STAT_PCS_OP_MODE, EFX_PHY_NSTATS } efx_phy_stat_t; /* END MKCONFIG GENERATED PhyHeaderStatsBlock */ #if EFSYS_OPT_NAMES extern const char * efx_phy_stat_name( __in efx_nic_t *enp, __in efx_phy_stat_t stat); #endif /* EFSYS_OPT_NAMES */ #define EFX_PHY_STATS_SIZE 0x100 extern __checkReturn efx_rc_t efx_phy_stats_update( __in efx_nic_t *enp, __in efsys_mem_t *esmp, __inout_ecount(EFX_PHY_NSTATS) uint32_t *stat); #endif /* EFSYS_OPT_PHY_STATS */ #if EFSYS_OPT_PHY_PROPS #if EFSYS_OPT_NAMES extern const char * efx_phy_prop_name( __in efx_nic_t *enp, __in unsigned int id); #endif /* EFSYS_OPT_NAMES */ #define EFX_PHY_PROP_DEFAULT 0x00000001 extern __checkReturn efx_rc_t efx_phy_prop_get( __in efx_nic_t *enp, __in unsigned int id, __in uint32_t flags, __out uint32_t *valp); extern __checkReturn efx_rc_t efx_phy_prop_set( __in efx_nic_t *enp, __in unsigned int id, __in uint32_t val); #endif /* EFSYS_OPT_PHY_PROPS */ #if EFSYS_OPT_BIST typedef enum efx_bist_type_e { EFX_BIST_TYPE_UNKNOWN, EFX_BIST_TYPE_PHY_NORMAL, EFX_BIST_TYPE_PHY_CABLE_SHORT, EFX_BIST_TYPE_PHY_CABLE_LONG, EFX_BIST_TYPE_MC_MEM, /* Test the MC DMEM and IMEM */ EFX_BIST_TYPE_SAT_MEM, /* Test the DMEM and IMEM of satellite cpus*/ EFX_BIST_TYPE_REG, /* Test the register memories */ EFX_BIST_TYPE_NTYPES, } efx_bist_type_t; typedef enum efx_bist_result_e { EFX_BIST_RESULT_UNKNOWN, EFX_BIST_RESULT_RUNNING, EFX_BIST_RESULT_PASSED, EFX_BIST_RESULT_FAILED, } efx_bist_result_t; typedef enum efx_phy_cable_status_e { EFX_PHY_CABLE_STATUS_OK, EFX_PHY_CABLE_STATUS_INVALID, EFX_PHY_CABLE_STATUS_OPEN, EFX_PHY_CABLE_STATUS_INTRAPAIRSHORT, EFX_PHY_CABLE_STATUS_INTERPAIRSHORT, EFX_PHY_CABLE_STATUS_BUSY, } efx_phy_cable_status_t; typedef enum efx_bist_value_e { EFX_BIST_PHY_CABLE_LENGTH_A, EFX_BIST_PHY_CABLE_LENGTH_B, EFX_BIST_PHY_CABLE_LENGTH_C, EFX_BIST_PHY_CABLE_LENGTH_D, EFX_BIST_PHY_CABLE_STATUS_A, EFX_BIST_PHY_CABLE_STATUS_B, EFX_BIST_PHY_CABLE_STATUS_C, EFX_BIST_PHY_CABLE_STATUS_D, EFX_BIST_FAULT_CODE, /* Memory BIST specific values. These match to the MC_CMD_BIST_POLL * response. */ EFX_BIST_MEM_TEST, EFX_BIST_MEM_ADDR, EFX_BIST_MEM_BUS, EFX_BIST_MEM_EXPECT, EFX_BIST_MEM_ACTUAL, EFX_BIST_MEM_ECC, EFX_BIST_MEM_ECC_PARITY, EFX_BIST_MEM_ECC_FATAL, EFX_BIST_NVALUES, } efx_bist_value_t; extern __checkReturn efx_rc_t efx_bist_enable_offline( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_bist_start( __in efx_nic_t *enp, __in efx_bist_type_t type); extern __checkReturn efx_rc_t efx_bist_poll( __in efx_nic_t *enp, __in efx_bist_type_t type, __out efx_bist_result_t *resultp, __out_opt uint32_t *value_maskp, __out_ecount_opt(count) unsigned long *valuesp, __in size_t count); extern void efx_bist_stop( __in efx_nic_t *enp, __in efx_bist_type_t type); #endif /* EFSYS_OPT_BIST */ #define EFX_FEATURE_IPV6 0x00000001 #define EFX_FEATURE_LFSR_HASH_INSERT 0x00000002 #define EFX_FEATURE_LINK_EVENTS 0x00000004 #define EFX_FEATURE_PERIODIC_MAC_STATS 0x00000008 #define EFX_FEATURE_WOL 0x00000010 #define EFX_FEATURE_MCDI 0x00000020 #define EFX_FEATURE_LOOKAHEAD_SPLIT 0x00000040 #define EFX_FEATURE_MAC_HEADER_FILTERS 0x00000080 #define EFX_FEATURE_TURBO 0x00000100 #define EFX_FEATURE_MCDI_DMA 0x00000200 #define EFX_FEATURE_TX_SRC_FILTERS 0x00000400 #define EFX_FEATURE_PIO_BUFFERS 0x00000800 #define EFX_FEATURE_FW_ASSISTED_TSO 0x00001000 #define EFX_FEATURE_FW_ASSISTED_TSO_V2 0x00002000 typedef struct efx_nic_cfg_s { uint32_t enc_board_type; uint32_t enc_phy_type; #if EFSYS_OPT_NAMES char enc_phy_name[21]; #endif char enc_phy_revision[21]; efx_mon_type_t enc_mon_type; #if EFSYS_OPT_MON_STATS uint32_t enc_mon_stat_dma_buf_size; uint32_t enc_mon_stat_mask[(EFX_MON_NSTATS + 31) / 32]; #endif unsigned int enc_features; uint8_t enc_mac_addr[6]; uint8_t enc_port; /* PHY port number */ uint32_t enc_func_flags; uint32_t enc_intr_vec_base; uint32_t enc_intr_limit; uint32_t enc_evq_limit; uint32_t enc_txq_limit; uint32_t enc_rxq_limit; uint32_t enc_buftbl_limit; uint32_t enc_piobuf_limit; uint32_t enc_piobuf_size; uint32_t enc_piobuf_min_alloc_size; uint32_t enc_evq_timer_quantum_ns; uint32_t enc_evq_timer_max_us; uint32_t enc_clk_mult; uint32_t enc_rx_prefix_size; uint32_t enc_rx_buf_align_start; uint32_t enc_rx_buf_align_end; #if EFSYS_OPT_LOOPBACK efx_qword_t enc_loopback_types[EFX_LINK_NMODES]; #endif /* EFSYS_OPT_LOOPBACK */ #if EFSYS_OPT_PHY_FLAGS uint32_t enc_phy_flags_mask; #endif /* EFSYS_OPT_PHY_FLAGS */ #if EFSYS_OPT_PHY_LED_CONTROL uint32_t enc_led_mask; #endif /* EFSYS_OPT_PHY_LED_CONTROL */ #if EFSYS_OPT_PHY_STATS uint64_t enc_phy_stat_mask; #endif /* EFSYS_OPT_PHY_STATS */ #if EFSYS_OPT_PHY_PROPS unsigned int enc_phy_nprops; #endif /* EFSYS_OPT_PHY_PROPS */ #if EFSYS_OPT_SIENA uint8_t enc_mcdi_mdio_channel; #if EFSYS_OPT_PHY_STATS uint32_t enc_mcdi_phy_stat_mask; #endif /* EFSYS_OPT_PHY_STATS */ #endif /* EFSYS_OPT_SIENA */ #if (EFSYS_OPT_SIENA || EFSYS_OPT_HUNTINGTON || EFSYS_OPT_MEDFORD) #if EFSYS_OPT_MON_STATS uint32_t *enc_mcdi_sensor_maskp; uint32_t enc_mcdi_sensor_mask_size; #endif /* EFSYS_OPT_MON_STATS */ #endif /* (EFSYS_OPT_SIENA || EFSYS_OPT_HUNTINGTON || EFSYS_OPT_MEDFORD) */ #if EFSYS_OPT_BIST uint32_t enc_bist_mask; #endif /* EFSYS_OPT_BIST */ #if EFSYS_OPT_HUNTINGTON || EFSYS_OPT_MEDFORD uint32_t enc_pf; uint32_t enc_vf; uint32_t enc_privilege_mask; #endif /* EFSYS_OPT_HUNTINGTON || EFSYS_OPT_MEDFORD */ boolean_t enc_bug26807_workaround; boolean_t enc_bug35388_workaround; boolean_t enc_bug41750_workaround; boolean_t enc_rx_batching_enabled; /* Maximum number of descriptors completed in an rx event. */ uint32_t enc_rx_batch_max; /* Number of rx descriptors the hardware requires for a push. */ uint32_t enc_rx_push_align; /* * Maximum number of bytes into the packet the TCP header can start for * the hardware to apply TSO packet edits. */ uint32_t enc_tx_tso_tcp_header_offset_limit; boolean_t enc_fw_assisted_tso_enabled; boolean_t enc_fw_assisted_tso_v2_enabled; boolean_t enc_hw_tx_insert_vlan_enabled; /* Datapath firmware vadapter/vport/vswitch support */ boolean_t enc_datapath_cap_evb; boolean_t enc_rx_disable_scatter_supported; boolean_t enc_allow_set_mac_with_installed_filters; /* External port identifier */ uint8_t enc_external_port; uint32_t enc_mcdi_max_payload_length; } efx_nic_cfg_t; #define EFX_PCI_FUNCTION_IS_PF(_encp) ((_encp)->enc_vf == 0xffff) #define EFX_PCI_FUNCTION_IS_VF(_encp) ((_encp)->enc_vf != 0xffff) #define EFX_PCI_FUNCTION(_encp) \ (EFX_PCI_FUNCTION_IS_PF(_encp) ? (_encp)->enc_pf : (_encp)->enc_vf) #define EFX_PCI_VF_PARENT(_encp) ((_encp)->enc_pf) extern const efx_nic_cfg_t * efx_nic_cfg_get( __in efx_nic_t *enp); /* Driver resource limits (minimum required/maximum usable). */ typedef struct efx_drv_limits_s { uint32_t edl_min_evq_count; uint32_t edl_max_evq_count; uint32_t edl_min_rxq_count; uint32_t edl_max_rxq_count; uint32_t edl_min_txq_count; uint32_t edl_max_txq_count; /* PIO blocks (sub-allocated from piobuf) */ uint32_t edl_min_pio_alloc_size; uint32_t edl_max_pio_alloc_count; } efx_drv_limits_t; extern __checkReturn efx_rc_t efx_nic_set_drv_limits( __inout efx_nic_t *enp, __in efx_drv_limits_t *edlp); typedef enum efx_nic_region_e { EFX_REGION_VI, /* Memory BAR UC mapping */ EFX_REGION_PIO_WRITE_VI, /* Memory BAR WC mapping */ } efx_nic_region_t; extern __checkReturn efx_rc_t efx_nic_get_bar_region( __in efx_nic_t *enp, __in efx_nic_region_t region, __out uint32_t *offsetp, __out size_t *sizep); extern __checkReturn efx_rc_t efx_nic_get_vi_pool( __in efx_nic_t *enp, __out uint32_t *evq_countp, __out uint32_t *rxq_countp, __out uint32_t *txq_countp); #if EFSYS_OPT_VPD typedef enum efx_vpd_tag_e { EFX_VPD_ID = 0x02, EFX_VPD_END = 0x0f, EFX_VPD_RO = 0x10, EFX_VPD_RW = 0x11, } efx_vpd_tag_t; typedef uint16_t efx_vpd_keyword_t; typedef struct efx_vpd_value_s { efx_vpd_tag_t evv_tag; efx_vpd_keyword_t evv_keyword; uint8_t evv_length; uint8_t evv_value[0x100]; } efx_vpd_value_t; #define EFX_VPD_KEYWORD(x, y) ((x) | ((y) << 8)) extern __checkReturn efx_rc_t efx_vpd_init( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_vpd_size( __in efx_nic_t *enp, __out size_t *sizep); extern __checkReturn efx_rc_t efx_vpd_read( __in efx_nic_t *enp, __out_bcount(size) caddr_t data, __in size_t size); extern __checkReturn efx_rc_t efx_vpd_verify( __in efx_nic_t *enp, __in_bcount(size) caddr_t data, __in size_t size); extern __checkReturn efx_rc_t efx_vpd_reinit( __in efx_nic_t *enp, __in_bcount(size) caddr_t data, __in size_t size); extern __checkReturn efx_rc_t efx_vpd_get( __in efx_nic_t *enp, __in_bcount(size) caddr_t data, __in size_t size, __inout efx_vpd_value_t *evvp); extern __checkReturn efx_rc_t efx_vpd_set( __in efx_nic_t *enp, __inout_bcount(size) caddr_t data, __in size_t size, __in efx_vpd_value_t *evvp); extern __checkReturn efx_rc_t efx_vpd_next( __in efx_nic_t *enp, __inout_bcount(size) caddr_t data, __in size_t size, __out efx_vpd_value_t *evvp, __inout unsigned int *contp); extern __checkReturn efx_rc_t efx_vpd_write( __in efx_nic_t *enp, __in_bcount(size) caddr_t data, __in size_t size); extern void efx_vpd_fini( __in efx_nic_t *enp); #endif /* EFSYS_OPT_VPD */ /* NVRAM */ #if EFSYS_OPT_NVRAM typedef enum efx_nvram_type_e { EFX_NVRAM_INVALID = 0, EFX_NVRAM_BOOTROM, EFX_NVRAM_BOOTROM_CFG, EFX_NVRAM_MC_FIRMWARE, EFX_NVRAM_MC_GOLDEN, EFX_NVRAM_PHY, EFX_NVRAM_NULLPHY, EFX_NVRAM_FPGA, EFX_NVRAM_FCFW, EFX_NVRAM_CPLD, EFX_NVRAM_FPGA_BACKUP, EFX_NVRAM_DYNAMIC_CFG, + EFX_NVRAM_LICENSE, EFX_NVRAM_NTYPES, } efx_nvram_type_t; extern __checkReturn efx_rc_t efx_nvram_init( __in efx_nic_t *enp); #if EFSYS_OPT_DIAG extern __checkReturn efx_rc_t efx_nvram_test( __in efx_nic_t *enp); #endif /* EFSYS_OPT_DIAG */ extern __checkReturn efx_rc_t efx_nvram_size( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out size_t *sizep); extern __checkReturn efx_rc_t efx_nvram_rw_start( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out_opt size_t *pref_chunkp); extern void efx_nvram_rw_finish( __in efx_nic_t *enp, __in efx_nvram_type_t type); extern __checkReturn efx_rc_t efx_nvram_get_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out uint32_t *subtypep, __out_ecount(4) uint16_t version[4]); extern __checkReturn efx_rc_t efx_nvram_read_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size); extern __checkReturn efx_rc_t efx_nvram_set_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in_ecount(4) uint16_t version[4]); /* Validate contents of TLV formatted partition */ extern __checkReturn efx_rc_t efx_nvram_tlv_validate( __in efx_nic_t *enp, __in uint32_t partn, __in_bcount(partn_size) caddr_t partn_data, __in size_t partn_size); extern __checkReturn efx_rc_t efx_nvram_erase( __in efx_nic_t *enp, __in efx_nvram_type_t type); extern __checkReturn efx_rc_t efx_nvram_write_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __in_bcount(size) caddr_t data, __in size_t size); extern void efx_nvram_fini( __in efx_nic_t *enp); #endif /* EFSYS_OPT_NVRAM */ #if EFSYS_OPT_BOOTCFG extern efx_rc_t efx_bootcfg_read( __in efx_nic_t *enp, __out_bcount(size) caddr_t data, __in size_t size); extern efx_rc_t efx_bootcfg_write( __in efx_nic_t *enp, __in_bcount(size) caddr_t data, __in size_t size); #endif /* EFSYS_OPT_BOOTCFG */ #if EFSYS_OPT_WOL typedef enum efx_wol_type_e { EFX_WOL_TYPE_INVALID, EFX_WOL_TYPE_MAGIC, EFX_WOL_TYPE_BITMAP, EFX_WOL_TYPE_LINK, EFX_WOL_NTYPES, } efx_wol_type_t; typedef enum efx_lightsout_offload_type_e { EFX_LIGHTSOUT_OFFLOAD_TYPE_INVALID, EFX_LIGHTSOUT_OFFLOAD_TYPE_ARP, EFX_LIGHTSOUT_OFFLOAD_TYPE_NS, } efx_lightsout_offload_type_t; #define EFX_WOL_BITMAP_MASK_SIZE (48) #define EFX_WOL_BITMAP_VALUE_SIZE (128) typedef union efx_wol_param_u { struct { uint8_t mac_addr[6]; } ewp_magic; struct { uint8_t mask[EFX_WOL_BITMAP_MASK_SIZE]; /* 1 bit per byte */ uint8_t value[EFX_WOL_BITMAP_VALUE_SIZE]; /* value to match */ uint8_t value_len; } ewp_bitmap; } efx_wol_param_t; typedef union efx_lightsout_offload_param_u { struct { uint8_t mac_addr[6]; uint32_t ip; } elop_arp; struct { uint8_t mac_addr[6]; uint32_t solicited_node[4]; uint32_t ip[4]; } elop_ns; } efx_lightsout_offload_param_t; extern __checkReturn efx_rc_t efx_wol_init( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_wol_filter_clear( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_wol_filter_add( __in efx_nic_t *enp, __in efx_wol_type_t type, __in efx_wol_param_t *paramp, __out uint32_t *filter_idp); extern __checkReturn efx_rc_t efx_wol_filter_remove( __in efx_nic_t *enp, __in uint32_t filter_id); extern __checkReturn efx_rc_t efx_lightsout_offload_add( __in efx_nic_t *enp, __in efx_lightsout_offload_type_t type, __in efx_lightsout_offload_param_t *paramp, __out uint32_t *filter_idp); extern __checkReturn efx_rc_t efx_lightsout_offload_remove( __in efx_nic_t *enp, __in efx_lightsout_offload_type_t type, __in uint32_t filter_id); extern void efx_wol_fini( __in efx_nic_t *enp); #endif /* EFSYS_OPT_WOL */ #if EFSYS_OPT_DIAG typedef enum efx_pattern_type_t { EFX_PATTERN_BYTE_INCREMENT = 0, EFX_PATTERN_ALL_THE_SAME, EFX_PATTERN_BIT_ALTERNATE, EFX_PATTERN_BYTE_ALTERNATE, EFX_PATTERN_BYTE_CHANGING, EFX_PATTERN_BIT_SWEEP, EFX_PATTERN_NTYPES } efx_pattern_type_t; typedef void (*efx_sram_pattern_fn_t)( __in size_t row, __in boolean_t negate, __out efx_qword_t *eqp); extern __checkReturn efx_rc_t efx_sram_test( __in efx_nic_t *enp, __in efx_pattern_type_t type); #endif /* EFSYS_OPT_DIAG */ extern __checkReturn efx_rc_t efx_sram_buf_tbl_set( __in efx_nic_t *enp, __in uint32_t id, __in efsys_mem_t *esmp, __in size_t n); extern void efx_sram_buf_tbl_clear( __in efx_nic_t *enp, __in uint32_t id, __in size_t n); #define EFX_BUF_TBL_SIZE 0x20000 #define EFX_BUF_SIZE 4096 /* EV */ typedef struct efx_evq_s efx_evq_t; #if EFSYS_OPT_QSTATS /* START MKCONFIG GENERATED EfxHeaderEventQueueBlock 6f3843f5fe7cc843 */ typedef enum efx_ev_qstat_e { EV_ALL, EV_RX, EV_RX_OK, EV_RX_FRM_TRUNC, EV_RX_TOBE_DISC, EV_RX_PAUSE_FRM_ERR, EV_RX_BUF_OWNER_ID_ERR, EV_RX_IPV4_HDR_CHKSUM_ERR, EV_RX_TCP_UDP_CHKSUM_ERR, EV_RX_ETH_CRC_ERR, EV_RX_IP_FRAG_ERR, EV_RX_MCAST_PKT, EV_RX_MCAST_HASH_MATCH, EV_RX_TCP_IPV4, EV_RX_TCP_IPV6, EV_RX_UDP_IPV4, EV_RX_UDP_IPV6, EV_RX_OTHER_IPV4, EV_RX_OTHER_IPV6, EV_RX_NON_IP, EV_RX_BATCH, EV_TX, EV_TX_WQ_FF_FULL, EV_TX_PKT_ERR, EV_TX_PKT_TOO_BIG, EV_TX_UNEXPECTED, EV_GLOBAL, EV_GLOBAL_MNT, EV_DRIVER, EV_DRIVER_SRM_UPD_DONE, EV_DRIVER_TX_DESCQ_FLS_DONE, EV_DRIVER_RX_DESCQ_FLS_DONE, EV_DRIVER_RX_DESCQ_FLS_FAILED, EV_DRIVER_RX_DSC_ERROR, EV_DRIVER_TX_DSC_ERROR, EV_DRV_GEN, EV_MCDI_RESPONSE, EV_NQSTATS } efx_ev_qstat_t; /* END MKCONFIG GENERATED EfxHeaderEventQueueBlock */ #endif /* EFSYS_OPT_QSTATS */ extern __checkReturn efx_rc_t efx_ev_init( __in efx_nic_t *enp); extern void efx_ev_fini( __in efx_nic_t *enp); #define EFX_EVQ_MAXNEVS 32768 #define EFX_EVQ_MINNEVS 512 #define EFX_EVQ_SIZE(_nevs) ((_nevs) * sizeof (efx_qword_t)) #define EFX_EVQ_NBUFS(_nevs) (EFX_EVQ_SIZE(_nevs) / EFX_BUF_SIZE) extern __checkReturn efx_rc_t efx_ev_qcreate( __in efx_nic_t *enp, __in unsigned int index, __in efsys_mem_t *esmp, __in size_t n, __in uint32_t id, __deref_out efx_evq_t **eepp); extern void efx_ev_qpost( __in efx_evq_t *eep, __in uint16_t data); typedef __checkReturn boolean_t (*efx_initialized_ev_t)( __in_opt void *arg); #define EFX_PKT_UNICAST 0x0004 #define EFX_PKT_START 0x0008 #define EFX_PKT_VLAN_TAGGED 0x0010 #define EFX_CKSUM_TCPUDP 0x0020 #define EFX_CKSUM_IPV4 0x0040 #define EFX_PKT_CONT 0x0080 #define EFX_CHECK_VLAN 0x0100 #define EFX_PKT_TCP 0x0200 #define EFX_PKT_UDP 0x0400 #define EFX_PKT_IPV4 0x0800 #define EFX_PKT_IPV6 0x1000 #define EFX_PKT_PREFIX_LEN 0x2000 #define EFX_ADDR_MISMATCH 0x4000 #define EFX_DISCARD 0x8000 #define EFX_EV_RX_NLABELS 32 #define EFX_EV_TX_NLABELS 32 typedef __checkReturn boolean_t (*efx_rx_ev_t)( __in_opt void *arg, __in uint32_t label, __in uint32_t id, __in uint32_t size, __in uint16_t flags); typedef __checkReturn boolean_t (*efx_tx_ev_t)( __in_opt void *arg, __in uint32_t label, __in uint32_t id); #define EFX_EXCEPTION_RX_RECOVERY 0x00000001 #define EFX_EXCEPTION_RX_DSC_ERROR 0x00000002 #define EFX_EXCEPTION_TX_DSC_ERROR 0x00000003 #define EFX_EXCEPTION_UNKNOWN_SENSOREVT 0x00000004 #define EFX_EXCEPTION_FWALERT_SRAM 0x00000005 #define EFX_EXCEPTION_UNKNOWN_FWALERT 0x00000006 #define EFX_EXCEPTION_RX_ERROR 0x00000007 #define EFX_EXCEPTION_TX_ERROR 0x00000008 #define EFX_EXCEPTION_EV_ERROR 0x00000009 typedef __checkReturn boolean_t (*efx_exception_ev_t)( __in_opt void *arg, __in uint32_t label, __in uint32_t data); typedef __checkReturn boolean_t (*efx_rxq_flush_done_ev_t)( __in_opt void *arg, __in uint32_t rxq_index); typedef __checkReturn boolean_t (*efx_rxq_flush_failed_ev_t)( __in_opt void *arg, __in uint32_t rxq_index); typedef __checkReturn boolean_t (*efx_txq_flush_done_ev_t)( __in_opt void *arg, __in uint32_t txq_index); typedef __checkReturn boolean_t (*efx_software_ev_t)( __in_opt void *arg, __in uint16_t magic); typedef __checkReturn boolean_t (*efx_sram_ev_t)( __in_opt void *arg, __in uint32_t code); #define EFX_SRAM_CLEAR 0 #define EFX_SRAM_UPDATE 1 #define EFX_SRAM_ILLEGAL_CLEAR 2 typedef __checkReturn boolean_t (*efx_wake_up_ev_t)( __in_opt void *arg, __in uint32_t label); typedef __checkReturn boolean_t (*efx_timer_ev_t)( __in_opt void *arg, __in uint32_t label); typedef __checkReturn boolean_t (*efx_link_change_ev_t)( __in_opt void *arg, __in efx_link_mode_t link_mode); #if EFSYS_OPT_MON_STATS typedef __checkReturn boolean_t (*efx_monitor_ev_t)( __in_opt void *arg, __in efx_mon_stat_t id, __in efx_mon_stat_value_t value); #endif /* EFSYS_OPT_MON_STATS */ #if EFSYS_OPT_MAC_STATS typedef __checkReturn boolean_t (*efx_mac_stats_ev_t)( __in_opt void *arg, __in uint32_t generation ); #endif /* EFSYS_OPT_MAC_STATS */ typedef struct efx_ev_callbacks_s { efx_initialized_ev_t eec_initialized; efx_rx_ev_t eec_rx; efx_tx_ev_t eec_tx; efx_exception_ev_t eec_exception; efx_rxq_flush_done_ev_t eec_rxq_flush_done; efx_rxq_flush_failed_ev_t eec_rxq_flush_failed; efx_txq_flush_done_ev_t eec_txq_flush_done; efx_software_ev_t eec_software; efx_sram_ev_t eec_sram; efx_wake_up_ev_t eec_wake_up; efx_timer_ev_t eec_timer; efx_link_change_ev_t eec_link_change; #if EFSYS_OPT_MON_STATS efx_monitor_ev_t eec_monitor; #endif /* EFSYS_OPT_MON_STATS */ #if EFSYS_OPT_MAC_STATS efx_mac_stats_ev_t eec_mac_stats; #endif /* EFSYS_OPT_MAC_STATS */ } efx_ev_callbacks_t; extern __checkReturn boolean_t efx_ev_qpending( __in efx_evq_t *eep, __in unsigned int count); #if EFSYS_OPT_EV_PREFETCH extern void efx_ev_qprefetch( __in efx_evq_t *eep, __in unsigned int count); #endif /* EFSYS_OPT_EV_PREFETCH */ extern void efx_ev_qpoll( __in efx_evq_t *eep, __inout unsigned int *countp, __in const efx_ev_callbacks_t *eecp, __in_opt void *arg); extern __checkReturn efx_rc_t efx_ev_qmoderate( __in efx_evq_t *eep, __in unsigned int us); extern __checkReturn efx_rc_t efx_ev_qprime( __in efx_evq_t *eep, __in unsigned int count); #if EFSYS_OPT_QSTATS #if EFSYS_OPT_NAMES extern const char * efx_ev_qstat_name( __in efx_nic_t *enp, __in unsigned int id); #endif /* EFSYS_OPT_NAMES */ extern void efx_ev_qstats_update( __in efx_evq_t *eep, __inout_ecount(EV_NQSTATS) efsys_stat_t *stat); #endif /* EFSYS_OPT_QSTATS */ extern void efx_ev_qdestroy( __in efx_evq_t *eep); /* RX */ extern __checkReturn efx_rc_t efx_rx_init( __inout efx_nic_t *enp); extern void efx_rx_fini( __in efx_nic_t *enp); #if EFSYS_OPT_RX_SCATTER __checkReturn efx_rc_t efx_rx_scatter_enable( __in efx_nic_t *enp, __in unsigned int buf_size); #endif /* EFSYS_OPT_RX_SCATTER */ #if EFSYS_OPT_RX_SCALE typedef enum efx_rx_hash_alg_e { EFX_RX_HASHALG_LFSR = 0, EFX_RX_HASHALG_TOEPLITZ } efx_rx_hash_alg_t; typedef enum efx_rx_hash_type_e { EFX_RX_HASH_IPV4 = 0, EFX_RX_HASH_TCPIPV4, EFX_RX_HASH_IPV6, EFX_RX_HASH_TCPIPV6, } efx_rx_hash_type_t; typedef enum efx_rx_hash_support_e { EFX_RX_HASH_UNAVAILABLE = 0, /* Hardware hash not inserted */ EFX_RX_HASH_AVAILABLE /* Insert hash with/without RSS */ } efx_rx_hash_support_t; #define EFX_RSS_TBL_SIZE 128 /* Rows in RX indirection table */ #define EFX_MAXRSS 64 /* RX indirection entry range */ #define EFX_MAXRSS_LEGACY 16 /* See bug16611 and bug17213 */ typedef enum efx_rx_scale_support_e { EFX_RX_SCALE_UNAVAILABLE = 0, /* Not supported */ EFX_RX_SCALE_EXCLUSIVE, /* Writable key/indirection table */ EFX_RX_SCALE_SHARED /* Read-only key/indirection table */ } efx_rx_scale_support_t; extern __checkReturn efx_rc_t efx_rx_hash_support_get( __in efx_nic_t *enp, __out efx_rx_hash_support_t *supportp); extern __checkReturn efx_rc_t efx_rx_scale_support_get( __in efx_nic_t *enp, __out efx_rx_scale_support_t *supportp); extern __checkReturn efx_rc_t efx_rx_scale_mode_set( __in efx_nic_t *enp, __in efx_rx_hash_alg_t alg, __in efx_rx_hash_type_t type, __in boolean_t insert); extern __checkReturn efx_rc_t efx_rx_scale_tbl_set( __in efx_nic_t *enp, __in_ecount(n) unsigned int *table, __in size_t n); extern __checkReturn efx_rc_t efx_rx_scale_key_set( __in efx_nic_t *enp, __in_ecount(n) uint8_t *key, __in size_t n); extern __checkReturn uint32_t efx_psuedo_hdr_hash_get( __in efx_nic_t *enp, __in efx_rx_hash_alg_t func, __in uint8_t *buffer); #endif /* EFSYS_OPT_RX_SCALE */ extern __checkReturn efx_rc_t efx_psuedo_hdr_pkt_length_get( __in efx_nic_t *enp, __in uint8_t *buffer, __out uint16_t *pkt_lengthp); #define EFX_RXQ_MAXNDESCS 4096 #define EFX_RXQ_MINNDESCS 512 #define EFX_RXQ_SIZE(_ndescs) ((_ndescs) * sizeof (efx_qword_t)) #define EFX_RXQ_NBUFS(_ndescs) (EFX_RXQ_SIZE(_ndescs) / EFX_BUF_SIZE) #define EFX_RXQ_LIMIT(_ndescs) ((_ndescs) - 16) #define EFX_RXQ_DC_NDESCS(_dcsize) (8 << _dcsize) typedef enum efx_rxq_type_e { EFX_RXQ_TYPE_DEFAULT, EFX_RXQ_TYPE_SCATTER, EFX_RXQ_NTYPES } efx_rxq_type_t; extern __checkReturn efx_rc_t efx_rx_qcreate( __in efx_nic_t *enp, __in unsigned int index, __in unsigned int label, __in efx_rxq_type_t type, __in efsys_mem_t *esmp, __in size_t n, __in uint32_t id, __in efx_evq_t *eep, __deref_out efx_rxq_t **erpp); typedef struct efx_buffer_s { efsys_dma_addr_t eb_addr; size_t eb_size; boolean_t eb_eop; } efx_buffer_t; typedef struct efx_desc_s { efx_qword_t ed_eq; } efx_desc_t; extern void efx_rx_qpost( __in efx_rxq_t *erp, __in_ecount(n) efsys_dma_addr_t *addrp, __in size_t size, __in unsigned int n, __in unsigned int completed, __in unsigned int added); extern void efx_rx_qpush( __in efx_rxq_t *erp, __in unsigned int added, __inout unsigned int *pushedp); extern __checkReturn efx_rc_t efx_rx_qflush( __in efx_rxq_t *erp); extern void efx_rx_qenable( __in efx_rxq_t *erp); extern void efx_rx_qdestroy( __in efx_rxq_t *erp); /* TX */ typedef struct efx_txq_s efx_txq_t; #if EFSYS_OPT_QSTATS /* START MKCONFIG GENERATED EfxHeaderTransmitQueueBlock 12dff8778598b2db */ typedef enum efx_tx_qstat_e { TX_POST, TX_POST_PIO, TX_NQSTATS } efx_tx_qstat_t; /* END MKCONFIG GENERATED EfxHeaderTransmitQueueBlock */ #endif /* EFSYS_OPT_QSTATS */ extern __checkReturn efx_rc_t efx_tx_init( __in efx_nic_t *enp); extern void efx_tx_fini( __in efx_nic_t *enp); #define EFX_BUG35388_WORKAROUND(_encp) \ (((_encp) == NULL) ? 1 : ((_encp)->enc_bug35388_workaround != 0)) #define EFX_TXQ_MAXNDESCS(_encp) \ ((EFX_BUG35388_WORKAROUND(_encp)) ? 2048 : 4096) #define EFX_TXQ_MINNDESCS 512 #define EFX_TXQ_SIZE(_ndescs) ((_ndescs) * sizeof (efx_qword_t)) #define EFX_TXQ_NBUFS(_ndescs) (EFX_TXQ_SIZE(_ndescs) / EFX_BUF_SIZE) #define EFX_TXQ_LIMIT(_ndescs) ((_ndescs) - 16) #define EFX_TXQ_DC_NDESCS(_dcsize) (8 << _dcsize) #define EFX_TXQ_MAX_BUFS 8 /* Maximum independent of EFX_BUG35388_WORKAROUND. */ #define EFX_TXQ_CKSUM_IPV4 0x0001 #define EFX_TXQ_CKSUM_TCPUDP 0x0002 #define EFX_TXQ_FATSOV2 0x0004 extern __checkReturn efx_rc_t efx_tx_qcreate( __in efx_nic_t *enp, __in unsigned int index, __in unsigned int label, __in efsys_mem_t *esmp, __in size_t n, __in uint32_t id, __in uint16_t flags, __in efx_evq_t *eep, __deref_out efx_txq_t **etpp, __out unsigned int *addedp); extern __checkReturn efx_rc_t efx_tx_qpost( __in efx_txq_t *etp, __in_ecount(n) efx_buffer_t *eb, __in unsigned int n, __in unsigned int completed, __inout unsigned int *addedp); extern __checkReturn efx_rc_t efx_tx_qpace( __in efx_txq_t *etp, __in unsigned int ns); extern void efx_tx_qpush( __in efx_txq_t *etp, __in unsigned int added, __in unsigned int pushed); extern __checkReturn efx_rc_t efx_tx_qflush( __in efx_txq_t *etp); extern void efx_tx_qenable( __in efx_txq_t *etp); extern __checkReturn efx_rc_t efx_tx_qpio_enable( __in efx_txq_t *etp); extern void efx_tx_qpio_disable( __in efx_txq_t *etp); extern __checkReturn efx_rc_t efx_tx_qpio_write( __in efx_txq_t *etp, __in_ecount(buf_length) uint8_t *buffer, __in size_t buf_length, __in size_t pio_buf_offset); extern __checkReturn efx_rc_t efx_tx_qpio_post( __in efx_txq_t *etp, __in size_t pkt_length, __in unsigned int completed, __inout unsigned int *addedp); extern __checkReturn efx_rc_t efx_tx_qdesc_post( __in efx_txq_t *etp, __in_ecount(n) efx_desc_t *ed, __in unsigned int n, __in unsigned int completed, __inout unsigned int *addedp); extern void efx_tx_qdesc_dma_create( __in efx_txq_t *etp, __in efsys_dma_addr_t addr, __in size_t size, __in boolean_t eop, __out efx_desc_t *edp); extern void efx_tx_qdesc_tso_create( __in efx_txq_t *etp, __in uint16_t ipv4_id, __in uint32_t tcp_seq, __in uint8_t tcp_flags, __out efx_desc_t *edp); /* Number of FATSOv2 option descriptors */ #define EFX_TX_FATSOV2_OPT_NDESCS 2 /* Maximum number of DMA segments per TSO packet (not superframe) */ #define EFX_TX_FATSOV2_DMA_SEGS_PER_PKT_MAX 24 extern void efx_tx_qdesc_tso2_create( __in efx_txq_t *etp, __in uint16_t ipv4_id, __in uint32_t tcp_seq, __in uint16_t tcp_mss, __out_ecount(count) efx_desc_t *edp, __in int count); extern void efx_tx_qdesc_vlantci_create( __in efx_txq_t *etp, __in uint16_t tci, __out efx_desc_t *edp); #if EFSYS_OPT_QSTATS #if EFSYS_OPT_NAMES extern const char * efx_tx_qstat_name( __in efx_nic_t *etp, __in unsigned int id); #endif /* EFSYS_OPT_NAMES */ extern void efx_tx_qstats_update( __in efx_txq_t *etp, __inout_ecount(TX_NQSTATS) efsys_stat_t *stat); #endif /* EFSYS_OPT_QSTATS */ extern void efx_tx_qdestroy( __in efx_txq_t *etp); /* FILTER */ #if EFSYS_OPT_FILTER #define EFX_ETHER_TYPE_IPV4 0x0800 #define EFX_ETHER_TYPE_IPV6 0x86DD #define EFX_IPPROTO_TCP 6 #define EFX_IPPROTO_UDP 17 typedef enum efx_filter_flag_e { EFX_FILTER_FLAG_RX_RSS = 0x01, /* use RSS to spread across * multiple queues */ EFX_FILTER_FLAG_RX_SCATTER = 0x02, /* enable RX scatter */ EFX_FILTER_FLAG_RX_OVER_AUTO = 0x04, /* Override an automatic filter * (priority EFX_FILTER_PRI_AUTO). * May only be set by the filter * implementation for each type. * A removal request will * restore the automatic filter * in its place. */ EFX_FILTER_FLAG_RX = 0x08, /* Filter is for RX */ EFX_FILTER_FLAG_TX = 0x10, /* Filter is for TX */ } efx_filter_flag_t; typedef enum efx_filter_match_flags_e { EFX_FILTER_MATCH_REM_HOST = 0x0001, /* Match by remote IP host * address */ EFX_FILTER_MATCH_LOC_HOST = 0x0002, /* Match by local IP host * address */ EFX_FILTER_MATCH_REM_MAC = 0x0004, /* Match by remote MAC address */ EFX_FILTER_MATCH_REM_PORT = 0x0008, /* Match by remote TCP/UDP port */ EFX_FILTER_MATCH_LOC_MAC = 0x0010, /* Match by remote TCP/UDP port */ EFX_FILTER_MATCH_LOC_PORT = 0x0020, /* Match by local TCP/UDP port */ EFX_FILTER_MATCH_ETHER_TYPE = 0x0040, /* Match by Ether-type */ EFX_FILTER_MATCH_INNER_VID = 0x0080, /* Match by inner VLAN ID */ EFX_FILTER_MATCH_OUTER_VID = 0x0100, /* Match by outer VLAN ID */ EFX_FILTER_MATCH_IP_PROTO = 0x0200, /* Match by IP transport * protocol */ EFX_FILTER_MATCH_LOC_MAC_IG = 0x0400, /* Match by local MAC address * I/G bit. Used for RX default * unicast and multicast/ * broadcast filters. */ } efx_filter_match_flags_t; typedef enum efx_filter_priority_s { EFX_FILTER_PRI_HINT = 0, /* Performance hint */ EFX_FILTER_PRI_AUTO, /* Automatic filter based on device * address list or hardware * requirements. This may only be used * by the filter implementation for * each NIC type. */ EFX_FILTER_PRI_MANUAL, /* Manually configured filter */ EFX_FILTER_PRI_REQUIRED, /* Required for correct behaviour of the * client (e.g. SR-IOV, HyperV VMQ etc.) */ } efx_filter_priority_t; /* * FIXME: All these fields are assumed to be in little-endian byte order. * It may be better for some to be big-endian. See bug42804. */ typedef struct efx_filter_spec_s { uint32_t efs_match_flags:12; uint32_t efs_priority:2; uint32_t efs_flags:6; uint32_t efs_dmaq_id:12; uint32_t efs_rss_context; uint16_t efs_outer_vid; uint16_t efs_inner_vid; uint8_t efs_loc_mac[EFX_MAC_ADDR_LEN]; uint8_t efs_rem_mac[EFX_MAC_ADDR_LEN]; uint16_t efs_ether_type; uint8_t efs_ip_proto; uint16_t efs_loc_port; uint16_t efs_rem_port; efx_oword_t efs_rem_host; efx_oword_t efs_loc_host; } efx_filter_spec_t; /* Default values for use in filter specifications */ #define EFX_FILTER_SPEC_RSS_CONTEXT_DEFAULT 0xffffffff #define EFX_FILTER_SPEC_RX_DMAQ_ID_DROP 0xfff #define EFX_FILTER_SPEC_VID_UNSPEC 0xffff extern __checkReturn efx_rc_t efx_filter_init( __in efx_nic_t *enp); extern void efx_filter_fini( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_filter_insert( __in efx_nic_t *enp, __inout efx_filter_spec_t *spec); extern __checkReturn efx_rc_t efx_filter_remove( __in efx_nic_t *enp, __inout efx_filter_spec_t *spec); extern __checkReturn efx_rc_t efx_filter_restore( __in efx_nic_t *enp); extern __checkReturn efx_rc_t efx_filter_supported_filters( __in efx_nic_t *enp, __out uint32_t *list, __out size_t *length); extern void efx_filter_spec_init_rx( __out efx_filter_spec_t *spec, __in efx_filter_priority_t priority, __in efx_filter_flag_t flags, __in efx_rxq_t *erp); extern void efx_filter_spec_init_tx( __out efx_filter_spec_t *spec, __in efx_txq_t *etp); extern __checkReturn efx_rc_t efx_filter_spec_set_ipv4_local( __inout efx_filter_spec_t *spec, __in uint8_t proto, __in uint32_t host, __in uint16_t port); extern __checkReturn efx_rc_t efx_filter_spec_set_ipv4_full( __inout efx_filter_spec_t *spec, __in uint8_t proto, __in uint32_t lhost, __in uint16_t lport, __in uint32_t rhost, __in uint16_t rport); extern __checkReturn efx_rc_t efx_filter_spec_set_eth_local( __inout efx_filter_spec_t *spec, __in uint16_t vid, __in const uint8_t *addr); extern __checkReturn efx_rc_t efx_filter_spec_set_uc_def( __inout efx_filter_spec_t *spec); extern __checkReturn efx_rc_t efx_filter_spec_set_mc_def( __inout efx_filter_spec_t *spec); #endif /* EFSYS_OPT_FILTER */ /* HASH */ extern __checkReturn uint32_t efx_hash_dwords( __in_ecount(count) uint32_t const *input, __in size_t count, __in uint32_t init); extern __checkReturn uint32_t efx_hash_bytes( __in_ecount(length) uint8_t const *input, __in size_t length, __in uint32_t init); #ifdef __cplusplus } #endif #endif /* _SYS_EFX_H */ Index: head/sys/dev/sfxge/common/hunt_nvram.c =================================================================== --- head/sys/dev/sfxge/common/hunt_nvram.c (revision 293899) +++ head/sys/dev/sfxge/common/hunt_nvram.c (revision 293900) @@ -1,1892 +1,1900 @@ /*- * Copyright (c) 2012-2015 Solarflare Communications Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are * those of the authors and should not be interpreted as representing official * policies, either expressed or implied, of the FreeBSD Project. */ #include __FBSDID("$FreeBSD$"); #include "efx.h" #include "efx_impl.h" #if EFSYS_OPT_HUNTINGTON #if EFSYS_OPT_VPD || EFSYS_OPT_NVRAM #include "ef10_tlv_layout.h" /* Cursor for TLV partition format */ typedef struct tlv_cursor_s { uint32_t *block; /* Base of data block */ uint32_t *current; /* Cursor position */ uint32_t *end; /* End tag position */ uint32_t *limit; /* Last dword of data block */ } tlv_cursor_t; static __checkReturn efx_rc_t tlv_validate_state( __in tlv_cursor_t *cursor); /* * Operations on TLV formatted partition data. */ static uint32_t tlv_tag( __in tlv_cursor_t *cursor) { uint32_t dword, tag; dword = cursor->current[0]; tag = __LE_TO_CPU_32(dword); return (tag); } static size_t tlv_length( __in tlv_cursor_t *cursor) { uint32_t dword, length; if (tlv_tag(cursor) == TLV_TAG_END) return (0); dword = cursor->current[1]; length = __LE_TO_CPU_32(dword); return ((size_t)length); } static uint8_t * tlv_value( __in tlv_cursor_t *cursor) { if (tlv_tag(cursor) == TLV_TAG_END) return (NULL); return ((uint8_t *)(&cursor->current[2])); } static uint8_t * tlv_item( __in tlv_cursor_t *cursor) { if (tlv_tag(cursor) == TLV_TAG_END) return (NULL); return ((uint8_t *)cursor->current); } /* * TLV item DWORD length is tag + length + value (rounded up to DWORD) * equivalent to tlv_n_words_for_len in mc-comms tlv.c */ #define TLV_DWORD_COUNT(length) \ (1 + 1 + (((length) + sizeof (uint32_t) - 1) / sizeof (uint32_t))) static uint32_t * tlv_next_item_ptr( __in tlv_cursor_t *cursor) { uint32_t length; length = tlv_length(cursor); return (cursor->current + TLV_DWORD_COUNT(length)); } static efx_rc_t tlv_advance( __in tlv_cursor_t *cursor) { efx_rc_t rc; if ((rc = tlv_validate_state(cursor)) != 0) goto fail1; if (cursor->current == cursor->end) { /* No more tags after END tag */ cursor->current = NULL; rc = ENOENT; goto fail2; } /* Advance to next item and validate */ cursor->current = tlv_next_item_ptr(cursor); if ((rc = tlv_validate_state(cursor)) != 0) goto fail3; return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } static efx_rc_t tlv_rewind( __in tlv_cursor_t *cursor) { efx_rc_t rc; cursor->current = cursor->block; if ((rc = tlv_validate_state(cursor)) != 0) goto fail1; return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } static efx_rc_t tlv_find( __in tlv_cursor_t *cursor, __in uint32_t tag) { efx_rc_t rc; rc = tlv_rewind(cursor); while (rc == 0) { if (tlv_tag(cursor) == tag) break; rc = tlv_advance(cursor); } return (rc); } static __checkReturn efx_rc_t tlv_validate_state( __in tlv_cursor_t *cursor) { efx_rc_t rc; /* Check cursor position */ if (cursor->current < cursor->block) { rc = EINVAL; goto fail1; } if (cursor->current > cursor->limit) { rc = EINVAL; goto fail2; } if (tlv_tag(cursor) != TLV_TAG_END) { /* Check current item has space for tag and length */ if (cursor->current > (cursor->limit - 2)) { cursor->current = NULL; rc = EFAULT; goto fail3; } /* Check we have value data for current item and another tag */ if (tlv_next_item_ptr(cursor) > (cursor->limit - 1)) { cursor->current = NULL; rc = EFAULT; goto fail4; } } return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } static efx_rc_t tlv_init_cursor( __out tlv_cursor_t *cursor, __in uint32_t *block, __in uint32_t *limit) { cursor->block = block; cursor->limit = limit; cursor->current = cursor->block; cursor->end = NULL; return (tlv_validate_state(cursor)); } static efx_rc_t tlv_init_cursor_from_size( __out tlv_cursor_t *cursor, __in uint8_t *block, __in size_t size) { uint32_t *limit; limit = (uint32_t *)(block + size - sizeof (uint32_t)); return (tlv_init_cursor(cursor, (uint32_t *)block, limit)); } static efx_rc_t tlv_require_end( __in tlv_cursor_t *cursor) { uint32_t *pos; efx_rc_t rc; if (cursor->end == NULL) { pos = cursor->current; if ((rc = tlv_find(cursor, TLV_TAG_END)) != 0) goto fail1; cursor->end = cursor->current; cursor->current = pos; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } static size_t tlv_block_length_used( __in tlv_cursor_t *cursor) { efx_rc_t rc; if ((rc = tlv_validate_state(cursor)) != 0) goto fail1; if ((rc = tlv_require_end(cursor)) != 0) goto fail2; /* Return space used (including the END tag) */ return (cursor->end + 1 - cursor->block) * sizeof (uint32_t); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (0); } static __checkReturn uint32_t * tlv_write( __in tlv_cursor_t *cursor, __in uint32_t tag, __in_bcount(size) uint8_t *data, __in size_t size) { uint32_t len = size; uint32_t *ptr; ptr = cursor->current; *ptr++ = __CPU_TO_LE_32(tag); *ptr++ = __CPU_TO_LE_32(len); if (len > 0) { ptr[(len - 1) / sizeof (uint32_t)] = 0; memcpy(ptr, data, len); ptr += P2ROUNDUP(len, sizeof (uint32_t)) / sizeof (*ptr); } return (ptr); } static __checkReturn efx_rc_t tlv_insert( __in tlv_cursor_t *cursor, __in uint32_t tag, __in uint8_t *data, __in size_t size) { unsigned int delta; efx_rc_t rc; if ((rc = tlv_validate_state(cursor)) != 0) goto fail1; if ((rc = tlv_require_end(cursor)) != 0) goto fail2; if (tag == TLV_TAG_END) { rc = EINVAL; goto fail3; } delta = TLV_DWORD_COUNT(size); if (cursor->end + 1 + delta > cursor->limit) { rc = ENOSPC; goto fail4; } /* Move data up: new space at cursor->current */ memmove(cursor->current + delta, cursor->current, (cursor->end + 1 - cursor->current) * sizeof (uint32_t)); /* Adjust the end pointer */ cursor->end += delta; /* Write new TLV item */ tlv_write(cursor, tag, data, size); return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } static __checkReturn efx_rc_t tlv_modify( __in tlv_cursor_t *cursor, __in uint32_t tag, __in uint8_t *data, __in size_t size) { uint32_t *pos; unsigned int old_ndwords; unsigned int new_ndwords; unsigned int delta; efx_rc_t rc; if ((rc = tlv_validate_state(cursor)) != 0) goto fail1; if (tlv_tag(cursor) == TLV_TAG_END) { rc = EINVAL; goto fail2; } if (tlv_tag(cursor) != tag) { rc = EINVAL; goto fail3; } old_ndwords = TLV_DWORD_COUNT(tlv_length(cursor)); new_ndwords = TLV_DWORD_COUNT(size); if ((rc = tlv_require_end(cursor)) != 0) goto fail4; if (new_ndwords > old_ndwords) { /* Expand space used for TLV item */ delta = new_ndwords - old_ndwords; pos = cursor->current + old_ndwords; if (cursor->end + 1 + delta > cursor->limit) { rc = ENOSPC; goto fail5; } /* Move up: new space at (cursor->current + old_ndwords) */ memmove(pos + delta, pos, (cursor->end + 1 - pos) * sizeof (uint32_t)); /* Adjust the end pointer */ cursor->end += delta; } else if (new_ndwords < old_ndwords) { /* Shrink space used for TLV item */ delta = old_ndwords - new_ndwords; pos = cursor->current + new_ndwords; /* Move down: remove words at (cursor->current + new_ndwords) */ memmove(pos, pos + delta, (cursor->end + 1 - pos) * sizeof (uint32_t)); /* Zero the new space at the end of the TLV chain */ memset(cursor->end + 1 - delta, 0, delta * sizeof (uint32_t)); /* Adjust the end pointer */ cursor->end -= delta; } /* Write new data */ tlv_write(cursor, tag, data, size); return (0); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* Validate TLV formatted partition contents (before writing to flash) */ __checkReturn efx_rc_t efx_nvram_tlv_validate( __in efx_nic_t *enp, __in uint32_t partn, __in_bcount(partn_size) caddr_t partn_data, __in size_t partn_size) { tlv_cursor_t cursor; struct tlv_partition_header *header; struct tlv_partition_trailer *trailer; size_t total_length; uint32_t cksum; int pos; efx_rc_t rc; EFX_STATIC_ASSERT(sizeof (*header) <= EF10_NVRAM_CHUNK); if ((partn_data == NULL) || (partn_size == 0)) { rc = EINVAL; goto fail1; } /* The partition header must be the first item (at offset zero) */ if ((rc = tlv_init_cursor_from_size(&cursor, (uint8_t *)partn_data, partn_size)) != 0) { rc = EFAULT; goto fail2; } if (tlv_tag(&cursor) != TLV_TAG_PARTITION_HEADER) { rc = EINVAL; goto fail3; } header = (struct tlv_partition_header *)tlv_item(&cursor); /* Check TLV partition length (includes the END tag) */ total_length = __LE_TO_CPU_32(header->total_length); if (total_length > partn_size) { rc = EFBIG; goto fail4; } /* Check partition ends with PARTITION_TRAILER and END tags */ if ((rc = tlv_find(&cursor, TLV_TAG_PARTITION_TRAILER)) != 0) { rc = EINVAL; goto fail5; } trailer = (struct tlv_partition_trailer *)tlv_item(&cursor); if ((rc = tlv_advance(&cursor)) != 0) { rc = EINVAL; goto fail6; } if (tlv_tag(&cursor) != TLV_TAG_END) { rc = EINVAL; goto fail7; } /* Check generation counts are consistent */ if (trailer->generation != header->generation) { rc = EINVAL; goto fail8; } /* Verify partition checksum */ cksum = 0; for (pos = 0; (size_t)pos < total_length; pos += sizeof (uint32_t)) { cksum += *((uint32_t *)(partn_data + pos)); } if (cksum != 0) { rc = EINVAL; goto fail9; } return (0); fail9: EFSYS_PROBE(fail9); fail8: EFSYS_PROBE(fail8); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Read and validate a segment from a partition. A segment is a complete * tlv chain between PARTITION_HEADER and PARTITION_END tags. There may * be multiple segments in a partition, so seg_offset allows segments * beyond the first to be read. */ static __checkReturn efx_rc_t ef10_nvram_read_tlv_segment( __in efx_nic_t *enp, __in uint32_t partn, __in size_t seg_offset, __in_bcount(max_seg_size) caddr_t seg_data, __in size_t max_seg_size) { tlv_cursor_t cursor; struct tlv_partition_header *header; struct tlv_partition_trailer *trailer; size_t total_length; uint32_t cksum; int pos; efx_rc_t rc; EFX_STATIC_ASSERT(sizeof (*header) <= EF10_NVRAM_CHUNK); if ((seg_data == NULL) || (max_seg_size == 0)) { rc = EINVAL; goto fail1; } /* Read initial chunk of the segment, starting at offset */ if ((rc = ef10_nvram_partn_read(enp, partn, seg_offset, seg_data, EF10_NVRAM_CHUNK)) != 0) { goto fail2; } /* A PARTITION_HEADER tag must be the first item at the given offset */ if ((rc = tlv_init_cursor_from_size(&cursor, (uint8_t *)seg_data, max_seg_size)) != 0) { rc = EFAULT; goto fail3; } if (tlv_tag(&cursor) != TLV_TAG_PARTITION_HEADER) { rc = EINVAL; goto fail4; } header = (struct tlv_partition_header *)tlv_item(&cursor); /* Check TLV segment length (includes the END tag) */ total_length = __LE_TO_CPU_32(header->total_length); if (total_length > max_seg_size) { rc = EFBIG; goto fail5; } /* Read the remaining segment content */ if (total_length > EF10_NVRAM_CHUNK) { if ((rc = ef10_nvram_partn_read(enp, partn, seg_offset + EF10_NVRAM_CHUNK, seg_data + EF10_NVRAM_CHUNK, total_length - EF10_NVRAM_CHUNK)) != 0) goto fail6; } /* Check segment ends with PARTITION_TRAILER and END tags */ if ((rc = tlv_find(&cursor, TLV_TAG_PARTITION_TRAILER)) != 0) { rc = EINVAL; goto fail7; } trailer = (struct tlv_partition_trailer *)tlv_item(&cursor); if ((rc = tlv_advance(&cursor)) != 0) { rc = EINVAL; goto fail8; } if (tlv_tag(&cursor) != TLV_TAG_END) { rc = EINVAL; goto fail9; } /* Check data read from segment is consistent */ if (trailer->generation != header->generation) { /* * The partition data may have been modified between successive * MCDI NVRAM_READ requests by the MC or another PCI function. * * The caller must retry to obtain consistent partition data. */ rc = EAGAIN; goto fail10; } /* Verify segment checksum */ cksum = 0; for (pos = 0; (size_t)pos < total_length; pos += sizeof (uint32_t)) { cksum += *((uint32_t *)(seg_data + pos)); } if (cksum != 0) { rc = EINVAL; goto fail11; } return (0); fail11: EFSYS_PROBE(fail11); fail10: EFSYS_PROBE(fail10); fail9: EFSYS_PROBE(fail9); fail8: EFSYS_PROBE(fail8); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Read a single TLV item from a host memory * buffer containing a TLV formatted segment. */ __checkReturn efx_rc_t ef10_nvram_buf_read_tlv( __in efx_nic_t *enp, __in_bcount(max_seg_size) caddr_t seg_data, __in size_t max_seg_size, __in uint32_t tag, __deref_out_bcount_opt(*sizep) caddr_t *datap, __out size_t *sizep) { tlv_cursor_t cursor; caddr_t data; size_t length; caddr_t value; efx_rc_t rc; if ((seg_data == NULL) || (max_seg_size == 0)) { rc = EINVAL; goto fail1; } /* Find requested TLV tag in segment data */ if ((rc = tlv_init_cursor_from_size(&cursor, (uint8_t *)seg_data, max_seg_size)) != 0) { rc = EFAULT; goto fail2; } if ((rc = tlv_find(&cursor, tag)) != 0) { rc = ENOENT; goto fail3; } value = (caddr_t)tlv_value(&cursor); length = tlv_length(&cursor); if (length == 0) data = NULL; else { /* Copy out data from TLV item */ EFSYS_KMEM_ALLOC(enp->en_esip, length, data); if (data == NULL) { rc = ENOMEM; goto fail4; } memcpy(data, value, length); } *datap = data; *sizep = length; return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* Read a single TLV item from the first segment in a TLV formatted partition */ __checkReturn efx_rc_t ef10_nvram_partn_read_tlv( __in efx_nic_t *enp, __in uint32_t partn, __in uint32_t tag, __deref_out_bcount_opt(*seg_sizep) caddr_t *seg_datap, __out size_t *seg_sizep) { caddr_t seg_data = NULL; size_t partn_size = 0; size_t length; caddr_t data; int retry; efx_rc_t rc; /* Allocate sufficient memory for the entire partition */ if ((rc = ef10_nvram_partn_size(enp, partn, &partn_size)) != 0) goto fail1; if (partn_size == 0) { rc = ENOENT; goto fail2; } EFSYS_KMEM_ALLOC(enp->en_esip, partn_size, seg_data); if (seg_data == NULL) { rc = ENOMEM; goto fail3; } /* * Read the first segment in a TLV partition. Retry until consistent * segment contents are returned. Inconsistent data may be read if: * a) the segment contents are invalid * b) the MC has rebooted while we were reading the partition * c) the partition has been modified while we were reading it * Limit retry attempts to ensure forward progress. */ retry = 10; do { rc = ef10_nvram_read_tlv_segment(enp, partn, 0, seg_data, partn_size); } while ((rc == EAGAIN) && (--retry > 0)); if (rc != 0) { /* Failed to obtain consistent segment data */ goto fail4; } if ((rc = ef10_nvram_buf_read_tlv(enp, seg_data, partn_size, tag, &data, &length)) != 0) goto fail5; EFSYS_KMEM_FREE(enp->en_esip, partn_size, seg_data); *seg_datap = data; *seg_sizep = length; return (0); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); EFSYS_KMEM_FREE(enp->en_esip, partn_size, seg_data); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* Compute the size of a segment. */ static __checkReturn efx_rc_t ef10_nvram_buf_segment_size( __in caddr_t seg_data, __in size_t max_seg_size, __out size_t *seg_sizep) { efx_rc_t rc; tlv_cursor_t cursor; struct tlv_partition_header *header; uint32_t cksum; int pos; uint32_t *end_tag_position; uint32_t segment_length; /* A PARTITION_HEADER tag must be the first item at the given offset */ if ((rc = tlv_init_cursor_from_size(&cursor, (uint8_t *)seg_data, max_seg_size)) != 0) { rc = EFAULT; goto fail1; } if (tlv_tag(&cursor) != TLV_TAG_PARTITION_HEADER) { rc = EINVAL; goto fail2; } header = (struct tlv_partition_header *)tlv_item(&cursor); /* Check TLV segment length (includes the END tag) */ *seg_sizep = __LE_TO_CPU_32(header->total_length); if (*seg_sizep > max_seg_size) { rc = EFBIG; goto fail3; } /* Check segment ends with PARTITION_TRAILER and END tags */ if ((rc = tlv_find(&cursor, TLV_TAG_PARTITION_TRAILER)) != 0) { rc = EINVAL; goto fail4; } if ((rc = tlv_advance(&cursor)) != 0) { rc = EINVAL; goto fail5; } if (tlv_tag(&cursor) != TLV_TAG_END) { rc = EINVAL; goto fail6; } end_tag_position = cursor.current; /* Verify segment checksum */ cksum = 0; for (pos = 0; (size_t)pos < *seg_sizep; pos += sizeof (uint32_t)) { cksum += *((uint32_t *)(seg_data + pos)); } if (cksum != 0) { rc = EINVAL; goto fail7; } /* * Calculate total length from HEADER to END tags and compare to * max_seg_size and the total_length field in the HEADER tag. */ segment_length = tlv_block_length_used(&cursor); if (segment_length > max_seg_size) { rc = EINVAL; goto fail8; } if (segment_length != *seg_sizep) { rc = EINVAL; goto fail9; } /* Skip over the first HEADER tag. */ rc = tlv_rewind(&cursor); rc = tlv_advance(&cursor); while (rc == 0) { if (tlv_tag(&cursor) == TLV_TAG_END) { /* Check that the END tag is the one found earlier. */ if (cursor.current != end_tag_position) goto fail10; break; } /* Check for duplicate HEADER tags before the END tag. */ if (tlv_tag(&cursor) == TLV_TAG_PARTITION_HEADER) { rc = EINVAL; goto fail11; } rc = tlv_advance(&cursor); } if (rc != 0) goto fail12; return (0); fail12: EFSYS_PROBE(fail12); fail11: EFSYS_PROBE(fail11); fail10: EFSYS_PROBE(fail10); fail9: EFSYS_PROBE(fail9); fail8: EFSYS_PROBE(fail8); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Add or update a single TLV item in a host memory buffer containing a TLV * formatted segment. Historically partitions consisted of only one segment. */ __checkReturn efx_rc_t ef10_nvram_buf_write_tlv( __inout_bcount(max_seg_size) caddr_t seg_data, __in size_t max_seg_size, __in uint32_t tag, __in_bcount(tag_size) caddr_t tag_data, __in size_t tag_size, __out size_t *total_lengthp) { tlv_cursor_t cursor; struct tlv_partition_header *header; struct tlv_partition_trailer *trailer; uint32_t generation; uint32_t cksum; int pos; efx_rc_t rc; /* A PARTITION_HEADER tag must be the first item (at offset zero) */ if ((rc = tlv_init_cursor_from_size(&cursor, (uint8_t *)seg_data, max_seg_size)) != 0) { rc = EFAULT; goto fail1; } if (tlv_tag(&cursor) != TLV_TAG_PARTITION_HEADER) { rc = EINVAL; goto fail2; } header = (struct tlv_partition_header *)tlv_item(&cursor); /* Update the TLV chain to contain the new data */ if ((rc = tlv_find(&cursor, tag)) == 0) { /* Modify existing TLV item */ if ((rc = tlv_modify(&cursor, tag, (uint8_t *)tag_data, tag_size)) != 0) goto fail3; } else { /* Insert a new TLV item before the PARTITION_TRAILER */ rc = tlv_find(&cursor, TLV_TAG_PARTITION_TRAILER); if (rc != 0) { rc = EINVAL; goto fail4; } if ((rc = tlv_insert(&cursor, tag, (uint8_t *)tag_data, tag_size)) != 0) { rc = EINVAL; goto fail5; } } /* Find the trailer tag */ if ((rc = tlv_find(&cursor, TLV_TAG_PARTITION_TRAILER)) != 0) { rc = EINVAL; goto fail6; } trailer = (struct tlv_partition_trailer *)tlv_item(&cursor); /* Update PARTITION_HEADER and PARTITION_TRAILER fields */ *total_lengthp = tlv_block_length_used(&cursor); if (*total_lengthp > max_seg_size) { rc = ENOSPC; goto fail7; } generation = __LE_TO_CPU_32(header->generation) + 1; header->total_length = __CPU_TO_LE_32(*total_lengthp); header->generation = __CPU_TO_LE_32(generation); trailer->generation = __CPU_TO_LE_32(generation); /* Recompute PARTITION_TRAILER checksum */ trailer->checksum = 0; cksum = 0; for (pos = 0; (size_t)pos < *total_lengthp; pos += sizeof (uint32_t)) { cksum += *((uint32_t *)(seg_data + pos)); } trailer->checksum = ~cksum + 1; return (0); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Add or update a single TLV item in the first segment of a TLV formatted * dynamic config partition. The first segment is the current active * configuration. */ __checkReturn efx_rc_t ef10_nvram_partn_write_tlv( __in efx_nic_t *enp, __in uint32_t partn, __in uint32_t tag, __in_bcount(size) caddr_t data, __in size_t size) { return ef10_nvram_partn_write_segment_tlv(enp, partn, tag, data, size, B_FALSE); } /* * Read a segment from nvram at the given offset into a buffer (segment_data) * and optionally write a new tag to it. */ static __checkReturn efx_rc_t ef10_nvram_segment_write_tlv( __in efx_nic_t *enp, __in uint32_t partn, __in uint32_t tag, __in_bcount(size) caddr_t data, __in size_t size, __inout caddr_t *seg_datap, __inout size_t *partn_offsetp, __inout size_t *src_remain_lenp, __inout size_t *dest_remain_lenp, __in boolean_t write) { efx_rc_t rc; efx_rc_t status; size_t original_segment_size; size_t modified_segment_size; /* * Read the segment from NVRAM into the segment_data buffer and validate * it, returning if it does not validate. This is not a failure unless * this is the first segment in a partition. In this case the caller * must propogate the error. */ status = ef10_nvram_read_tlv_segment(enp, partn, *partn_offsetp, *seg_datap, *src_remain_lenp); if (status != 0) return (EINVAL); status = ef10_nvram_buf_segment_size(*seg_datap, *src_remain_lenp, &original_segment_size); if (status != 0) return (EINVAL); if (write) { /* Update the contents of the segment in the buffer */ if ((rc = ef10_nvram_buf_write_tlv(*seg_datap, *dest_remain_lenp, tag, data, size, &modified_segment_size)) != 0) goto fail1; *dest_remain_lenp -= modified_segment_size; *seg_datap += modified_segment_size; } else { /* * We won't modify this segment, but still need to update the * remaining lengths and pointers. */ *dest_remain_lenp -= original_segment_size; *seg_datap += original_segment_size; } *partn_offsetp += original_segment_size; *src_remain_lenp -= original_segment_size; return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Add or update a single TLV item in either the first segment or in all * segments in a TLV formatted dynamic config partition. Dynamic config * partitions on boards that support RFID are divided into a number of segments, * each formatted like a partition, with header, trailer and end tags. The first * segment is the current active configuration. * * The segments are initialised by manftest and each contain a different * configuration e.g. firmware variant. The firmware can be instructed * via RFID to copy a segment to replace the first segment, hence changing the * active configuration. This allows ops to change the configuration of a board * prior to shipment using RFID. * * Changes to the dynamic config may need to be written to all segments (e.g. * firmware versions) or just the first segment (changes to the active * configuration). See SF-111324-SW "The use of RFID in Solarflare Products". * If only the first segment is written the code still needs to be aware of the * possible presence of subsequent segments as writing to a segment may cause * its size to increase, which would overwrite the subsequent segments and * invalidate them. */ __checkReturn efx_rc_t ef10_nvram_partn_write_segment_tlv( __in efx_nic_t *enp, __in uint32_t partn, __in uint32_t tag, __in_bcount(size) caddr_t data, __in size_t size, __in boolean_t all_segments) { size_t partn_size = 0; caddr_t partn_data; size_t total_length = 0; efx_rc_t rc; size_t current_offset = 0; size_t remaining_original_length; size_t remaining_modified_length; caddr_t segment_data; EFSYS_ASSERT3U(partn, ==, NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG); /* Allocate sufficient memory for the entire partition */ if ((rc = ef10_nvram_partn_size(enp, partn, &partn_size)) != 0) goto fail1; EFSYS_KMEM_ALLOC(enp->en_esip, partn_size, partn_data); if (partn_data == NULL) { rc = ENOMEM; goto fail2; } remaining_original_length = partn_size; remaining_modified_length = partn_size; segment_data = partn_data; /* Lock the partition */ if ((rc = ef10_nvram_partn_lock(enp, partn)) != 0) goto fail3; /* Iterate over each (potential) segment to update it. */ do { boolean_t write = all_segments || current_offset == 0; rc = ef10_nvram_segment_write_tlv(enp, partn, tag, data, size, &segment_data, ¤t_offset, &remaining_original_length, &remaining_modified_length, write); if (rc != 0) { if (current_offset == 0) { /* * If no data has been read then the first * segment is invalid, which is an error. */ goto fail4; } break; } } while (current_offset < partn_size); total_length = segment_data - partn_data; /* * We've run out of space. This should actually be dealt with by * ef10_nvram_buf_write_tlv returning ENOSPC. */ if (total_length > partn_size) { rc = ENOSPC; goto fail5; } /* Erase the whole partition in NVRAM */ if ((rc = ef10_nvram_partn_erase(enp, partn, 0, partn_size)) != 0) goto fail6; /* Write new partition contents from the buffer to NVRAM */ if ((rc = ef10_nvram_partn_write(enp, partn, 0, partn_data, total_length)) != 0) goto fail7; /* Unlock the partition */ ef10_nvram_partn_unlock(enp, partn); EFSYS_KMEM_FREE(enp->en_esip, partn_size, partn_data); return (0); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); ef10_nvram_partn_unlock(enp, partn); fail3: EFSYS_PROBE(fail3); EFSYS_KMEM_FREE(enp->en_esip, partn_size, partn_data); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } /* * Get the size of a NVRAM partition. This is the total size allocated in nvram, * not the data used by the segments in the partition. */ __checkReturn efx_rc_t ef10_nvram_partn_size( __in efx_nic_t *enp, __in uint32_t partn, __out size_t *sizep) { efx_rc_t rc; if ((rc = efx_mcdi_nvram_info(enp, partn, sizep, NULL, NULL, NULL)) != 0) goto fail1; return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_partn_lock( __in efx_nic_t *enp, __in uint32_t partn) { efx_rc_t rc; if ((rc = efx_mcdi_nvram_update_start(enp, partn)) != 0) goto fail1; return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_partn_read( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { size_t chunk; efx_rc_t rc; while (size > 0) { chunk = MIN(size, EF10_NVRAM_CHUNK); if ((rc = efx_mcdi_nvram_read(enp, partn, offset, data, chunk)) != 0) { goto fail1; } size -= chunk; data += chunk; offset += chunk; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_partn_erase( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __in size_t size) { efx_rc_t rc; uint32_t erase_size; if ((rc = efx_mcdi_nvram_info(enp, partn, NULL, NULL, &erase_size, NULL)) != 0) goto fail1; if (erase_size == 0) { if ((rc = efx_mcdi_nvram_erase(enp, partn, offset, size)) != 0) goto fail2; } else { if (size % erase_size != 0) { rc = EINVAL; goto fail3; } while (size > 0) { if ((rc = efx_mcdi_nvram_erase(enp, partn, offset, erase_size)) != 0) goto fail4; offset += erase_size; size -= erase_size; } } return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_partn_write( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { size_t chunk; uint32_t write_size; efx_rc_t rc; if ((rc = efx_mcdi_nvram_info(enp, partn, NULL, NULL, NULL, &write_size)) != 0) goto fail1; if (write_size != 0) { /* * Check that the size is a multiple of the write chunk size if * the write chunk size is available. */ if (size % write_size != 0) { rc = EINVAL; goto fail2; } } else { write_size = EF10_NVRAM_CHUNK; } while (size > 0) { chunk = MIN(size, write_size); if ((rc = efx_mcdi_nvram_write(enp, partn, offset, data, chunk)) != 0) { goto fail3; } size -= chunk; data += chunk; offset += chunk; } return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } void ef10_nvram_partn_unlock( __in efx_nic_t *enp, __in uint32_t partn) { boolean_t reboot; efx_rc_t rc; reboot = B_FALSE; if ((rc = efx_mcdi_nvram_update_finish(enp, partn, reboot)) != 0) goto fail1; return; fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); } __checkReturn efx_rc_t ef10_nvram_partn_set_version( __in efx_nic_t *enp, __in uint32_t partn, __in_ecount(4) uint16_t version[4]) { struct tlv_partition_version partn_version; size_t size; efx_rc_t rc; /* Add or modify partition version TLV item */ partn_version.version_w = __CPU_TO_LE_16(version[0]); partn_version.version_x = __CPU_TO_LE_16(version[1]); partn_version.version_y = __CPU_TO_LE_16(version[2]); partn_version.version_z = __CPU_TO_LE_16(version[3]); size = sizeof (partn_version) - (2 * sizeof (uint32_t)); /* Write the version number to all segments in the partition */ if ((rc = ef10_nvram_partn_write_segment_tlv(enp, NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, TLV_TAG_PARTITION_VERSION(partn), (caddr_t)&partn_version.version_w, size, B_TRUE)) != 0) goto fail1; return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } #endif /* EFSYS_OPT_VPD || EFSYS_OPT_NVRAM */ #if EFSYS_OPT_NVRAM typedef struct ef10_parttbl_entry_s { unsigned int partn; unsigned int port; efx_nvram_type_t nvtype; } ef10_parttbl_entry_t; /* Translate EFX NVRAM types to firmware partition types */ static ef10_parttbl_entry_t hunt_parttbl[] = { {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 1, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 2, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 3, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 4, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 1, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 2, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 3, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 4, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 1, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 2, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 3, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 4, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT0, 1, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT1, 2, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT2, 3, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT3, 4, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 1, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 2, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 3, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 4, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_FPGA, 1, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 2, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 3, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 4, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 1, EFX_NVRAM_FPGA_BACKUP}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 2, EFX_NVRAM_FPGA_BACKUP}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 3, EFX_NVRAM_FPGA_BACKUP}, - {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 4, EFX_NVRAM_FPGA_BACKUP} + {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 4, EFX_NVRAM_FPGA_BACKUP}, + {NVRAM_PARTITION_TYPE_LICENSE, 1, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 2, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 3, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 4, EFX_NVRAM_LICENSE} }; static ef10_parttbl_entry_t medford_parttbl[] = { {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 1, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 2, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 3, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE, 4, EFX_NVRAM_MC_FIRMWARE}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 1, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 2, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 3, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_MC_FIRMWARE_BACKUP, 4, EFX_NVRAM_MC_GOLDEN}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 1, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 2, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 3, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPANSION_ROM, 4, EFX_NVRAM_BOOTROM}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT0, 1, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT0, 2, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT0, 3, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_EXPROM_CONFIG_PORT0, 4, EFX_NVRAM_BOOTROM_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 1, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 2, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 3, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_DYNAMIC_CONFIG, 4, EFX_NVRAM_DYNAMIC_CFG}, {NVRAM_PARTITION_TYPE_FPGA, 1, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 2, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 3, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA, 4, EFX_NVRAM_FPGA}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 1, EFX_NVRAM_FPGA_BACKUP}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 2, EFX_NVRAM_FPGA_BACKUP}, {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 3, EFX_NVRAM_FPGA_BACKUP}, - {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 4, EFX_NVRAM_FPGA_BACKUP} + {NVRAM_PARTITION_TYPE_FPGA_BACKUP, 4, EFX_NVRAM_FPGA_BACKUP}, + {NVRAM_PARTITION_TYPE_LICENSE, 1, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 2, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 3, EFX_NVRAM_LICENSE}, + {NVRAM_PARTITION_TYPE_LICENSE, 4, EFX_NVRAM_LICENSE} }; static __checkReturn efx_rc_t ef10_parttbl_get( __in efx_nic_t *enp, __out ef10_parttbl_entry_t **parttblp, __out size_t *parttbl_rowsp) { switch (enp->en_family) { case EFX_FAMILY_HUNTINGTON: *parttblp = hunt_parttbl; *parttbl_rowsp = EFX_ARRAY_SIZE(hunt_parttbl); break; case EFX_FAMILY_MEDFORD: *parttblp = medford_parttbl; *parttbl_rowsp = EFX_ARRAY_SIZE(medford_parttbl); break; default: EFSYS_ASSERT(B_FALSE); return (EINVAL); } return (0); } __checkReturn efx_rc_t ef10_nvram_type_to_partn( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out uint32_t *partnp) { efx_mcdi_iface_t *emip = &(enp->en_mcdi.em_emip); ef10_parttbl_entry_t *parttbl = NULL; size_t parttbl_rows = 0; unsigned int i; EFSYS_ASSERT3U(type, <, EFX_NVRAM_NTYPES); EFSYS_ASSERT(partnp != NULL); if (ef10_parttbl_get(enp, &parttbl, &parttbl_rows) == 0) { for (i = 0; i < parttbl_rows; i++) { ef10_parttbl_entry_t *entry = &parttbl[i]; if (entry->nvtype == type && entry->port == emip->emi_port) { *partnp = entry->partn; return (0); } } } return (ENOTSUP); } static __checkReturn efx_rc_t ef10_nvram_partn_to_type( __in efx_nic_t *enp, __in uint32_t partn, __out efx_nvram_type_t *typep) { efx_mcdi_iface_t *emip = &(enp->en_mcdi.em_emip); ef10_parttbl_entry_t *parttbl = NULL; size_t parttbl_rows = 0; unsigned int i; EFSYS_ASSERT(typep != NULL); if (ef10_parttbl_get(enp, &parttbl, &parttbl_rows) == 0) { for (i = 0; i < parttbl_rows; i++) { ef10_parttbl_entry_t *entry = &parttbl[i]; if (entry->partn == partn && entry->port == emip->emi_port) { *typep = entry->nvtype; return (0); } } } return (ENOTSUP); } #if EFSYS_OPT_DIAG __checkReturn efx_rc_t ef10_nvram_test( __in efx_nic_t *enp) { efx_nvram_type_t type; unsigned int npartns = 0; uint32_t *partns = NULL; size_t size; unsigned int i; efx_rc_t rc; /* Read available partitions from NVRAM partition map */ size = MC_CMD_NVRAM_PARTITIONS_OUT_TYPE_ID_MAXNUM * sizeof (uint32_t); EFSYS_KMEM_ALLOC(enp->en_esip, size, partns); if (partns == NULL) { rc = ENOMEM; goto fail1; } if ((rc = efx_mcdi_nvram_partitions(enp, (caddr_t)partns, size, &npartns)) != 0) { goto fail2; } for (i = 0; i < npartns; i++) { /* Check if the partition is supported for this port */ if ((rc = ef10_nvram_partn_to_type(enp, partns[i], &type)) != 0) continue; if ((rc = efx_mcdi_nvram_test(enp, partns[i])) != 0) goto fail3; } EFSYS_KMEM_FREE(enp->en_esip, size, partns); return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); EFSYS_KMEM_FREE(enp->en_esip, size, partns); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } #endif /* EFSYS_OPT_DIAG */ __checkReturn efx_rc_t ef10_nvram_get_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out uint32_t *subtypep, __out_ecount(4) uint16_t version[4]) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; /* FIXME: get highest partn version from all ports */ /* FIXME: return partn description if available */ if ((rc = efx_mcdi_nvram_metadata(enp, partn, subtypep, version, NULL, 0)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_rw_start( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out size_t *chunk_sizep) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = ef10_nvram_partn_lock(enp, partn)) != 0) goto fail2; if (chunk_sizep != NULL) *chunk_sizep = EF10_NVRAM_CHUNK; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_read_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = ef10_nvram_partn_read(enp, partn, offset, data, size)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_erase( __in efx_nic_t *enp, __in efx_nvram_type_t type) { uint32_t partn; size_t size; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = ef10_nvram_partn_size(enp, partn, &size)) != 0) goto fail2; if ((rc = ef10_nvram_partn_erase(enp, partn, 0, size)) != 0) goto fail3; return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t ef10_nvram_write_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __in_bcount(size) caddr_t data, __in size_t size) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = ef10_nvram_partn_write(enp, partn, offset, data, size)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } void ef10_nvram_rw_finish( __in efx_nic_t *enp, __in efx_nvram_type_t type) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) == 0) ef10_nvram_partn_unlock(enp, partn); } __checkReturn efx_rc_t ef10_nvram_set_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in_ecount(4) uint16_t version[4]) { uint32_t partn; efx_rc_t rc; if ((rc = ef10_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = ef10_nvram_partn_set_version(enp, partn, version)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } #endif /* EFSYS_OPT_NVRAM */ #endif /* EFSYS_OPT_HUNTINGTON */ Index: head/sys/dev/sfxge/common/siena_nvram.c =================================================================== --- head/sys/dev/sfxge/common/siena_nvram.c (revision 293899) +++ head/sys/dev/sfxge/common/siena_nvram.c (revision 293900) @@ -1,828 +1,830 @@ /*- * Copyright (c) 2009-2015 Solarflare Communications Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are * those of the authors and should not be interpreted as representing official * policies, either expressed or implied, of the FreeBSD Project. */ #include __FBSDID("$FreeBSD$"); #include "efx.h" #include "efx_impl.h" #if EFSYS_OPT_SIENA #if EFSYS_OPT_VPD || EFSYS_OPT_NVRAM __checkReturn efx_rc_t siena_nvram_partn_size( __in efx_nic_t *enp, __in uint32_t partn, __out size_t *sizep) { efx_rc_t rc; if ((1 << partn) & ~enp->en_u.siena.enu_partn_mask) { rc = ENOTSUP; goto fail1; } if ((rc = efx_mcdi_nvram_info(enp, partn, sizep, NULL, NULL, NULL)) != 0) { goto fail2; } return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_partn_lock( __in efx_nic_t *enp, __in uint32_t partn) { efx_rc_t rc; if ((rc = efx_mcdi_nvram_update_start(enp, partn)) != 0) { goto fail1; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_partn_read( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { size_t chunk; efx_rc_t rc; while (size > 0) { chunk = MIN(size, SIENA_NVRAM_CHUNK); if ((rc = efx_mcdi_nvram_read(enp, partn, offset, data, chunk)) != 0) { goto fail1; } size -= chunk; data += chunk; offset += chunk; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_partn_erase( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __in size_t size) { efx_rc_t rc; if ((rc = efx_mcdi_nvram_erase(enp, partn, offset, size)) != 0) { goto fail1; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_partn_write( __in efx_nic_t *enp, __in uint32_t partn, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { size_t chunk; efx_rc_t rc; while (size > 0) { chunk = MIN(size, SIENA_NVRAM_CHUNK); if ((rc = efx_mcdi_nvram_write(enp, partn, offset, data, chunk)) != 0) { goto fail1; } size -= chunk; data += chunk; offset += chunk; } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } void siena_nvram_partn_unlock( __in efx_nic_t *enp, __in uint32_t partn) { boolean_t reboot; efx_rc_t rc; /* * Reboot into the new image only for PHYs. The driver has to * explicitly cope with an MC reboot after a firmware update. */ reboot = (partn == MC_CMD_NVRAM_TYPE_PHY_PORT0 || partn == MC_CMD_NVRAM_TYPE_PHY_PORT1 || partn == MC_CMD_NVRAM_TYPE_DISABLED_CALLISTO); if ((rc = efx_mcdi_nvram_update_finish(enp, partn, reboot)) != 0) { goto fail1; } return; fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); } #endif /* EFSYS_OPT_VPD || EFSYS_OPT_NVRAM */ #if EFSYS_OPT_NVRAM typedef struct siena_parttbl_entry_s { unsigned int partn; unsigned int port; efx_nvram_type_t nvtype; } siena_parttbl_entry_t; static siena_parttbl_entry_t siena_parttbl[] = { {MC_CMD_NVRAM_TYPE_DISABLED_CALLISTO, 1, EFX_NVRAM_NULLPHY}, {MC_CMD_NVRAM_TYPE_DISABLED_CALLISTO, 2, EFX_NVRAM_NULLPHY}, {MC_CMD_NVRAM_TYPE_MC_FW, 1, EFX_NVRAM_MC_FIRMWARE}, {MC_CMD_NVRAM_TYPE_MC_FW, 2, EFX_NVRAM_MC_FIRMWARE}, {MC_CMD_NVRAM_TYPE_MC_FW_BACKUP, 1, EFX_NVRAM_MC_GOLDEN}, {MC_CMD_NVRAM_TYPE_MC_FW_BACKUP, 2, EFX_NVRAM_MC_GOLDEN}, {MC_CMD_NVRAM_TYPE_EXP_ROM, 1, EFX_NVRAM_BOOTROM}, {MC_CMD_NVRAM_TYPE_EXP_ROM, 2, EFX_NVRAM_BOOTROM}, {MC_CMD_NVRAM_TYPE_EXP_ROM_CFG_PORT0, 1, EFX_NVRAM_BOOTROM_CFG}, {MC_CMD_NVRAM_TYPE_EXP_ROM_CFG_PORT1, 2, EFX_NVRAM_BOOTROM_CFG}, {MC_CMD_NVRAM_TYPE_PHY_PORT0, 1, EFX_NVRAM_PHY}, {MC_CMD_NVRAM_TYPE_PHY_PORT1, 2, EFX_NVRAM_PHY}, {MC_CMD_NVRAM_TYPE_FPGA, 1, EFX_NVRAM_FPGA}, {MC_CMD_NVRAM_TYPE_FPGA, 2, EFX_NVRAM_FPGA}, {MC_CMD_NVRAM_TYPE_FPGA_BACKUP, 1, EFX_NVRAM_FPGA_BACKUP}, {MC_CMD_NVRAM_TYPE_FPGA_BACKUP, 2, EFX_NVRAM_FPGA_BACKUP}, {MC_CMD_NVRAM_TYPE_FC_FW, 1, EFX_NVRAM_FCFW}, {MC_CMD_NVRAM_TYPE_FC_FW, 2, EFX_NVRAM_FCFW}, {MC_CMD_NVRAM_TYPE_CPLD, 1, EFX_NVRAM_CPLD}, {MC_CMD_NVRAM_TYPE_CPLD, 2, EFX_NVRAM_CPLD}, + {MC_CMD_NVRAM_TYPE_LICENSE, 1, EFX_NVRAM_LICENSE}, + {MC_CMD_NVRAM_TYPE_LICENSE, 2, EFX_NVRAM_LICENSE} }; __checkReturn efx_rc_t siena_nvram_type_to_partn( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out uint32_t *partnp) { efx_mcdi_iface_t *emip = &(enp->en_mcdi.em_emip); unsigned int i; EFSYS_ASSERT3U(type, <, EFX_NVRAM_NTYPES); EFSYS_ASSERT(partnp != NULL); for (i = 0; i < EFX_ARRAY_SIZE(siena_parttbl); i++) { siena_parttbl_entry_t *entry = &siena_parttbl[i]; if (entry->port == emip->emi_port && entry->nvtype == type) { *partnp = entry->partn; return (0); } } return (ENOTSUP); } #if EFSYS_OPT_DIAG __checkReturn efx_rc_t siena_nvram_test( __in efx_nic_t *enp) { efx_mcdi_iface_t *emip = &(enp->en_mcdi.em_emip); siena_parttbl_entry_t *entry; unsigned int i; efx_rc_t rc; /* * Iterate over the list of supported partition types * applicable to *this* port */ for (i = 0; i < EFX_ARRAY_SIZE(siena_parttbl); i++) { entry = &siena_parttbl[i]; if (entry->port != emip->emi_port || !(enp->en_u.siena.enu_partn_mask & (1 << entry->partn))) continue; if ((rc = efx_mcdi_nvram_test(enp, entry->partn)) != 0) { goto fail1; } } return (0); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } #endif /* EFSYS_OPT_DIAG */ #define SIENA_DYNAMIC_CFG_SIZE(_nitems) \ (sizeof (siena_mc_dynamic_config_hdr_t) + ((_nitems) * \ sizeof (((siena_mc_dynamic_config_hdr_t *)NULL)->fw_version[0]))) __checkReturn efx_rc_t siena_nvram_get_dynamic_cfg( __in efx_nic_t *enp, __in uint32_t partn, __in boolean_t vpd, __out siena_mc_dynamic_config_hdr_t **dcfgp, __out size_t *sizep) { siena_mc_dynamic_config_hdr_t *dcfg = NULL; size_t size; uint8_t cksum; unsigned int vpd_offset; unsigned int vpd_length; unsigned int hdr_length; unsigned int nversions; unsigned int pos; unsigned int region; efx_rc_t rc; EFSYS_ASSERT(partn == MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT0 || partn == MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT1); /* * Allocate sufficient memory for the entire dynamiccfg area, even * if we're not actually going to read in the VPD. */ if ((rc = siena_nvram_partn_size(enp, partn, &size)) != 0) goto fail1; EFSYS_KMEM_ALLOC(enp->en_esip, size, dcfg); if (dcfg == NULL) { rc = ENOMEM; goto fail2; } if ((rc = siena_nvram_partn_read(enp, partn, 0, (caddr_t)dcfg, SIENA_NVRAM_CHUNK)) != 0) goto fail3; /* Verify the magic */ if (EFX_DWORD_FIELD(dcfg->magic, EFX_DWORD_0) != SIENA_MC_DYNAMIC_CONFIG_MAGIC) goto invalid1; /* All future versions of the structure must be backwards compatable */ EFX_STATIC_ASSERT(SIENA_MC_DYNAMIC_CONFIG_VERSION == 0); hdr_length = EFX_WORD_FIELD(dcfg->length, EFX_WORD_0); nversions = EFX_DWORD_FIELD(dcfg->num_fw_version_items, EFX_DWORD_0); vpd_offset = EFX_DWORD_FIELD(dcfg->dynamic_vpd_offset, EFX_DWORD_0); vpd_length = EFX_DWORD_FIELD(dcfg->dynamic_vpd_length, EFX_DWORD_0); /* Verify the hdr doesn't overflow the partn size */ if (hdr_length > size || vpd_offset > size || vpd_length > size || vpd_length + vpd_offset > size) goto invalid2; /* Verify the header has room for all it's versions */ if (hdr_length < SIENA_DYNAMIC_CFG_SIZE(0) || hdr_length < SIENA_DYNAMIC_CFG_SIZE(nversions)) goto invalid3; /* * Read the remaining portion of the dcfg, either including * the whole of VPD (there is no vpd length in this structure, * so we have to parse each tag), or just the dcfg header itself */ region = vpd ? vpd_offset + vpd_length : hdr_length; if (region > SIENA_NVRAM_CHUNK) { if ((rc = siena_nvram_partn_read(enp, partn, SIENA_NVRAM_CHUNK, (caddr_t)dcfg + SIENA_NVRAM_CHUNK, region - SIENA_NVRAM_CHUNK)) != 0) goto fail4; } /* Verify checksum */ cksum = 0; for (pos = 0; pos < hdr_length; pos++) cksum += ((uint8_t *)dcfg)[pos]; if (cksum != 0) goto invalid4; goto done; invalid4: EFSYS_PROBE(invalid4); invalid3: EFSYS_PROBE(invalid3); invalid2: EFSYS_PROBE(invalid2); invalid1: EFSYS_PROBE(invalid1); /* * Construct a new "null" dcfg, with an empty version vector, * and an empty VPD chunk trailing. This has the neat side effect * of testing the exception paths in the write path. */ EFX_POPULATE_DWORD_1(dcfg->magic, EFX_DWORD_0, SIENA_MC_DYNAMIC_CONFIG_MAGIC); EFX_POPULATE_WORD_1(dcfg->length, EFX_WORD_0, sizeof (*dcfg)); EFX_POPULATE_BYTE_1(dcfg->version, EFX_BYTE_0, SIENA_MC_DYNAMIC_CONFIG_VERSION); EFX_POPULATE_DWORD_1(dcfg->dynamic_vpd_offset, EFX_DWORD_0, sizeof (*dcfg)); EFX_POPULATE_DWORD_1(dcfg->dynamic_vpd_length, EFX_DWORD_0, 0); EFX_POPULATE_DWORD_1(dcfg->num_fw_version_items, EFX_DWORD_0, 0); done: *dcfgp = dcfg; *sizep = size; return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); EFSYS_KMEM_FREE(enp->en_esip, size, dcfg); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_get_subtype( __in efx_nic_t *enp, __in uint32_t partn, __out uint32_t *subtypep) { efx_mcdi_req_t req; uint8_t payload[MAX(MC_CMD_GET_BOARD_CFG_IN_LEN, MC_CMD_GET_BOARD_CFG_OUT_LENMAX)]; efx_word_t *fw_list; efx_rc_t rc; (void) memset(payload, 0, sizeof (payload)); req.emr_cmd = MC_CMD_GET_BOARD_CFG; req.emr_in_buf = payload; req.emr_in_length = MC_CMD_GET_BOARD_CFG_IN_LEN; req.emr_out_buf = payload; req.emr_out_length = MC_CMD_GET_BOARD_CFG_OUT_LENMAX; efx_mcdi_execute(enp, &req); if (req.emr_rc != 0) { rc = req.emr_rc; goto fail1; } if (req.emr_out_length_used < MC_CMD_GET_BOARD_CFG_OUT_LENMIN) { rc = EMSGSIZE; goto fail2; } if (req.emr_out_length_used < MC_CMD_GET_BOARD_CFG_OUT_FW_SUBTYPE_LIST_OFST + (partn + 1) * sizeof (efx_word_t)) { rc = ENOENT; goto fail3; } fw_list = MCDI_OUT2(req, efx_word_t, GET_BOARD_CFG_OUT_FW_SUBTYPE_LIST); *subtypep = EFX_WORD_FIELD(fw_list[partn], EFX_WORD_0); return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_get_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out uint32_t *subtypep, __out_ecount(4) uint16_t version[4]) { siena_mc_dynamic_config_hdr_t *dcfg; siena_parttbl_entry_t *entry; uint32_t dcfg_partn; uint32_t partn; unsigned int i; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((1 << partn) & ~enp->en_u.siena.enu_partn_mask) { rc = ENOTSUP; goto fail2; } if ((rc = siena_nvram_get_subtype(enp, partn, subtypep)) != 0) goto fail3; /* * Some partitions are accessible from both ports (for instance BOOTROM) * Find the highest version reported by all dcfg structures on ports * that have access to this partition. */ version[0] = version[1] = version[2] = version[3] = 0; for (i = 0; i < EFX_ARRAY_SIZE(siena_parttbl); i++) { unsigned int nitems; uint16_t temp[4]; size_t length; entry = &siena_parttbl[i]; if (entry->partn != partn) continue; dcfg_partn = (entry->port == 1) ? MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT0 : MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT1; /* * Ingore missing partitions on port 2, assuming they're due * to to running on a single port part. */ if ((1 << dcfg_partn) & ~enp->en_u.siena.enu_partn_mask) { if (entry->port == 2) continue; } if ((rc = siena_nvram_get_dynamic_cfg(enp, dcfg_partn, B_FALSE, &dcfg, &length)) != 0) goto fail4; nitems = EFX_DWORD_FIELD(dcfg->num_fw_version_items, EFX_DWORD_0); if (nitems < entry->partn) goto done; temp[0] = EFX_WORD_FIELD(dcfg->fw_version[partn].version_w, EFX_WORD_0); temp[1] = EFX_WORD_FIELD(dcfg->fw_version[partn].version_x, EFX_WORD_0); temp[2] = EFX_WORD_FIELD(dcfg->fw_version[partn].version_y, EFX_WORD_0); temp[3] = EFX_WORD_FIELD(dcfg->fw_version[partn].version_z, EFX_WORD_0); if (memcmp(version, temp, sizeof (temp)) < 0) memcpy(version, temp, sizeof (temp)); done: EFSYS_KMEM_FREE(enp->en_esip, length, dcfg); } return (0); fail4: EFSYS_PROBE(fail4); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_rw_start( __in efx_nic_t *enp, __in efx_nvram_type_t type, __out size_t *chunk_sizep) { uint32_t partn; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = siena_nvram_partn_lock(enp, partn)) != 0) goto fail2; if (chunk_sizep != NULL) *chunk_sizep = SIENA_NVRAM_CHUNK; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_read_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __out_bcount(size) caddr_t data, __in size_t size) { uint32_t partn; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = siena_nvram_partn_read(enp, partn, offset, data, size)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_erase( __in efx_nic_t *enp, __in efx_nvram_type_t type) { size_t size; uint32_t partn; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = siena_nvram_partn_size(enp, partn, &size)) != 0) goto fail2; if ((rc = siena_nvram_partn_erase(enp, partn, 0, size)) != 0) goto fail3; return (0); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } __checkReturn efx_rc_t siena_nvram_write_chunk( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in unsigned int offset, __in_bcount(size) caddr_t data, __in size_t size) { uint32_t partn; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; if ((rc = siena_nvram_partn_write(enp, partn, offset, data, size)) != 0) goto fail2; return (0); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } void siena_nvram_rw_finish( __in efx_nic_t *enp, __in efx_nvram_type_t type) { uint32_t partn; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) == 0) siena_nvram_partn_unlock(enp, partn); } __checkReturn efx_rc_t siena_nvram_set_version( __in efx_nic_t *enp, __in efx_nvram_type_t type, __in_ecount(4) uint16_t version[4]) { efx_mcdi_iface_t *emip = &(enp->en_mcdi.em_emip); siena_mc_dynamic_config_hdr_t *dcfg = NULL; siena_mc_fw_version_t *fwverp; uint32_t dcfg_partn, partn; size_t dcfg_size; unsigned int hdr_length; unsigned int vpd_length; unsigned int vpd_offset; unsigned int nitems; unsigned int required_hdr_length; unsigned int pos; uint8_t cksum; uint32_t subtype; size_t length; efx_rc_t rc; if ((rc = siena_nvram_type_to_partn(enp, type, &partn)) != 0) goto fail1; dcfg_partn = (emip->emi_port == 1) ? MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT0 : MC_CMD_NVRAM_TYPE_DYNAMIC_CFG_PORT1; if ((rc = siena_nvram_partn_size(enp, dcfg_partn, &dcfg_size)) != 0) goto fail2; if ((rc = siena_nvram_partn_lock(enp, dcfg_partn)) != 0) goto fail2; if ((rc = siena_nvram_get_dynamic_cfg(enp, dcfg_partn, B_TRUE, &dcfg, &length)) != 0) goto fail3; hdr_length = EFX_WORD_FIELD(dcfg->length, EFX_WORD_0); nitems = EFX_DWORD_FIELD(dcfg->num_fw_version_items, EFX_DWORD_0); vpd_length = EFX_DWORD_FIELD(dcfg->dynamic_vpd_length, EFX_DWORD_0); vpd_offset = EFX_DWORD_FIELD(dcfg->dynamic_vpd_offset, EFX_DWORD_0); /* * NOTE: This function will blatt any fields trailing the version * vector, or the VPD chunk. */ required_hdr_length = SIENA_DYNAMIC_CFG_SIZE(partn + 1); if (required_hdr_length + vpd_length > length) { rc = ENOSPC; goto fail4; } if (vpd_offset < required_hdr_length) { (void) memmove((caddr_t)dcfg + required_hdr_length, (caddr_t)dcfg + vpd_offset, vpd_length); vpd_offset = required_hdr_length; EFX_POPULATE_DWORD_1(dcfg->dynamic_vpd_offset, EFX_DWORD_0, vpd_offset); } if (hdr_length < required_hdr_length) { (void) memset((caddr_t)dcfg + hdr_length, 0, required_hdr_length - hdr_length); hdr_length = required_hdr_length; EFX_POPULATE_WORD_1(dcfg->length, EFX_WORD_0, hdr_length); } /* Get the subtype to insert into the fw_subtype array */ if ((rc = siena_nvram_get_subtype(enp, partn, &subtype)) != 0) goto fail5; /* Fill out the new version */ fwverp = &dcfg->fw_version[partn]; EFX_POPULATE_DWORD_1(fwverp->fw_subtype, EFX_DWORD_0, subtype); EFX_POPULATE_WORD_1(fwverp->version_w, EFX_WORD_0, version[0]); EFX_POPULATE_WORD_1(fwverp->version_x, EFX_WORD_0, version[1]); EFX_POPULATE_WORD_1(fwverp->version_y, EFX_WORD_0, version[2]); EFX_POPULATE_WORD_1(fwverp->version_z, EFX_WORD_0, version[3]); /* Update the version count */ if (nitems < partn + 1) { nitems = partn + 1; EFX_POPULATE_DWORD_1(dcfg->num_fw_version_items, EFX_DWORD_0, nitems); } /* Update the checksum */ cksum = 0; for (pos = 0; pos < hdr_length; pos++) cksum += ((uint8_t *)dcfg)[pos]; dcfg->csum.eb_u8[0] -= cksum; /* Erase and write the new partition */ if ((rc = siena_nvram_partn_erase(enp, dcfg_partn, 0, dcfg_size)) != 0) goto fail6; /* Write out the new structure to nvram */ if ((rc = siena_nvram_partn_write(enp, dcfg_partn, 0, (caddr_t)dcfg, vpd_offset + vpd_length)) != 0) goto fail7; EFSYS_KMEM_FREE(enp->en_esip, length, dcfg); siena_nvram_partn_unlock(enp, dcfg_partn); return (0); fail7: EFSYS_PROBE(fail7); fail6: EFSYS_PROBE(fail6); fail5: EFSYS_PROBE(fail5); fail4: EFSYS_PROBE(fail4); EFSYS_KMEM_FREE(enp->en_esip, length, dcfg); fail3: EFSYS_PROBE(fail3); fail2: EFSYS_PROBE(fail2); fail1: EFSYS_PROBE1(fail1, efx_rc_t, rc); return (rc); } #endif /* EFSYS_OPT_NVRAM */ #endif /* EFSYS_OPT_SIENA */