/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _BGE_IMPL_H #define _BGE_IMPL_H #pragma ident "%Z%%M% %I% %E% SMI" #ifdef __cplusplus extern "C" { #endif #include #include #include #include #include #include #include #include #include #ifdef __sparcv9 #include #endif /* __sparcv9 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __amd64 #include #endif /* * *may* already have provided the typedef ether_addr_t; * but of course C doesn't provide a way to check this directly. So here * we rely on the fact that the symbol ETHERTYPE_AT was added to the * header file (as a #define, which we *can* test for) at the same time * as the typedef for ether_addr_t ;-! */ #ifndef ETHERTYPE_AT typedef uchar_t ether_addr_t[ETHERADDRL]; #endif /* ETHERTYPE_AT */ /* * Reconfiguring the network devices requires the net_config privilege * in Solaris 10+. */ extern int secpolicy_net_config(const cred_t *, boolean_t); #include /* originally from cassini */ #include /* by fjlite out of intel */ #include "bge.h" #include "bge_hw.h" /* * Compile-time feature switches ... */ #define BGE_DO_PPIO 0 /* peek/poke ioctls */ #define BGE_RX_SOFTINT 0 /* softint per receive ring */ #define BGE_CHOOSE_SEND_METHOD 0 /* send by copying only */ /* * NOTES: * * #defines: * * BGE_PCI_CONFIG_RNUMBER and BGE_PCI_OPREGS_RNUMBER are the * register-set numbers to use for the config space registers * and the operating registers respectively. On an OBP-based * machine, regset 0 refers to CONFIG space, and regset 1 will * be the operating registers in MEMORY space. If an expansion * ROM is fitted, it may appear as a further register set. * * BGE_DMA_MODE defines the mode (STREAMING/CONSISTENT) used * for the data buffers. The descriptors are always set up * in CONSISTENT mode. * * BGE_HEADROOM defines how much space we'll leave in allocated * mblks before the first valid data byte. This should be chosen * to be 2 modulo 4, so that once the ethernet header (14 bytes) * has been stripped off, the packet data will be 4-byte aligned. * The remaining space can be used by upstream modules to prepend * any headers required. */ #define BGE_PCI_CONFIG_RNUMBER 0 #define BGE_PCI_OPREGS_RNUMBER 1 #define BGE_DMA_MODE DDI_DMA_STREAMING #define BGE_HEADROOM 34 /* * BGE_HALFTICK is half the period of the cyclic callback (in * nanoseconds), chosen so that 0.5s <= cyclic period <= 1s. * Other time values are derived as odd multiples of this value * so that there's little chance of ambiguity w.r.t. which tick * a timeout expires on. * * BGE_PHY_STABLE_TIME is the period for which the contents of the * PHY's status register must remain unchanging before we accept * that the link has come up. [Sometimes the link comes up, only * to go down again within a short time as the autonegotiation * process cycles through various options before finding the best * compatible mode. We don't want to report repeated link up/down * cycles, so we wait until we think it's stable.] * * BGE_SERDES_STABLE_TIME is the analogous value for the SerDes * interface. It's much shorter, 'cos the SerDes doesn't show * these effects as much as the copper PHY. * * BGE_LINK_SETTLE_TIME is the period during which we regard link * up/down cycles as an normal event after resetting/reprogramming * the PHY. During this time, link up/down messages are sent to * the log only, not the console. At any other time, link change * events are regarded as unexpected and sent to both console & log. * * These latter two values have no theoretical justification, but * are derived from observations and heuristics - the values below * just seem to work quite well. */ #define BGE_HALFTICK 268435456LL /* 2**28 ns! */ #define BGE_CYCLIC_PERIOD (2*BGE_HALFTICK) /* ~0.5s */ #define BGE_SERDES_STABLE_TIME (3*BGE_HALFTICK) /* ~0.8s */ #define BGE_PHY_STABLE_TIME (11*BGE_HALFTICK) /* ~3.0s */ #define BGE_LINK_SETTLE_TIME (111*BGE_HALFTICK) /* ~30.0s */ /* * Indices used to identify the different buffer rings internally */ #define BGE_STD_BUFF_RING 0 #define BGE_JUMBO_BUFF_RING 1 #define BGE_MINI_BUFF_RING 2 /* * Current implementation limits */ #define BGE_BUFF_RINGS_USED 2 /* std & jumbo ring */ /* for now */ #define BGE_RECV_RINGS_USED 16 /* up to 16 rtn rings */ /* for now */ #define BGE_SEND_RINGS_USED 4 /* up to 4 tx rings */ /* for now */ #define BGE_HASH_TABLE_SIZE 128 /* may be 256 later */ /* * Ring/buffer size parameters * * All of the (up to) 16 TX rings & and the corresponding buffers are the * same size. * * Each of the (up to) 3 receive producer (aka buffer) rings is a different * size and has different sized buffers associated with it too. * * The (up to) 16 receive return rings have no buffers associated with them. * The number of slots per receive return ring must be 2048 if the mini * ring is enabled, otherwise it may be 1024. See Broadcom document * 570X-PG102-R page 56. * * Note: only the 5700 supported external memory (and therefore the mini * ring); the 5702/3/4 don't. This driver doesn't support the original * 5700, so we won't ever use the mini ring capability. */ #define BGE_SEND_RINGS_DEFAULT 1 #define BGE_RECV_RINGS_DEFAULT 1 #define BGE_SEND_BUFF_SIZE_DEFAULT 1536 #define BGE_SEND_BUFF_SIZE_JUMBO 9022 #define BGE_SEND_SLOTS_USED 512 #define BGE_STD_BUFF_SIZE 1536 /* 0x600 */ #define BGE_STD_SLOTS_USED 512 #define BGE_JUMBO_BUFF_SIZE 9022 /* 9k */ #define BGE_JUMBO_SLOTS_USED 256 #define BGE_MINI_BUFF_SIZE 128 /* 64? 256? */ #define BGE_MINI_SLOTS_USED 0 /* must be 0; see above */ #define BGE_RECV_BUFF_SIZE 0 #if BGE_MINI_SLOTS_USED > 0 #define BGE_RECV_SLOTS_USED 2048 /* required */ #else #define BGE_RECV_SLOTS_USED 1024 /* could be 2048 anyway */ #endif #define BGE_SEND_BUF_NUM 512 #define BGE_SEND_BUF_ARRAY 16 #define BGE_SEND_BUF_ARRAY_JUMBO 3 #define BGE_SEND_BUF_MAX (BGE_SEND_BUF_NUM*BGE_SEND_BUF_ARRAY) /* * PCI type. PCI-Express or PCI/PCIX */ #define BGE_PCI 0 #define BGE_PCI_E 1 #define BGE_PCI_X 2 /* * Statistic type. There are two type of statistic: * statistic block and statistic registers */ #define BGE_STAT_BLK 1 #define BGE_STAT_REG 2 /* * MTU.for all chipsets ,the default is 1500 ,and some chipsets * support 9k jumbo frames size */ #define BGE_DEFAULT_MTU 1500 #define BGE_MAXIMUM_MTU 9000 /* * Pad the h/w defined status block (which can be up to 80 bytes long) * to a power-of-two boundary */ #define BGE_STATUS_PADDING (128 - sizeof (bge_status_t)) /* * On platforms which support DVMA, we can simply allocate one big piece * of memory for all the Tx buffers and another for the Rx buffers, and * then carve them up as required. It doesn't matter if they aren't just * one physically contiguous piece each, because both the CPU *and* the * I/O device can see them *as though they were*. * * However, if only physically-addressed DMA is possible, this doesn't * work; we can't expect to get enough contiguously-addressed memory for * all the buffers of each type, so in this case we request a number of * smaller pieces, each still large enough for several buffers but small * enough to fit within "an I/O page" (e.g. 64K). * * The #define below specifies how many pieces of memory are to be used; * 16 has been shown to work on an i86pc architecture but this could be * different on other non-DVMA platforms ... */ #ifdef _DMA_USES_VIRTADDR #define BGE_SPLIT 1 /* no split required */ #else #if ((BGE_BUFF_RINGS_USED > 1) || (BGE_SEND_RINGS_USED > 1) || \ (BGE_RECV_RINGS_USED > 1)) #define BGE_SPLIT 128 /* split 128 ways */ #else #define BGE_SPLIT 16 /* split 16 ways */ #endif #endif /* _DMA_USES_VIRTADDR */ #define BGE_RECV_RINGS_SPLIT (BGE_RECV_RINGS_MAX + 1) /* * STREAMS parameters */ #define BGE_IDNUM 0 /* zero seems to work */ #define BGE_LOWAT (256) #define BGE_HIWAT (256*1024) /* * Basic data types, for clarity in distinguishing 'numbers' * used for different purposes ... * * A is a register 'address' (offset) in any one of * various address spaces (PCI config space, PCI memory-mapped I/O * register space, MII registers, etc). None of these exceeds 64K, * so we could use a 16-bit representation but pointer-sized objects * are more "natural" in most architectures; they seem to be handled * more efficiently on SPARC and no worse on x86. * * BGE_REGNO_NONE represents the non-existent value in this space. */ typedef uintptr_t bge_regno_t; /* register # (offset) */ #define BGE_REGNO_NONE (~(uintptr_t)0u) /* * Describes one chunk of allocated DMA-able memory * * In some cases, this is a single chunk as allocated from the system; * but we also use this structure to represent slices carved off such * a chunk. Even when we don't really need all the information, we * use this structure as a convenient way of correlating the various * ways of looking at a piece of memory (kernel VA, IO space DVMA, * handle+offset, etc). */ typedef struct { ddi_acc_handle_t acc_hdl; /* handle for memory */ void *mem_va; /* CPU VA of memory */ uint32_t nslots; /* number of slots */ uint32_t size; /* size per slot */ size_t alength; /* allocated size */ /* >= product of above */ ddi_dma_handle_t dma_hdl; /* DMA handle */ offset_t offset; /* relative to handle */ ddi_dma_cookie_t cookie; /* associated cookie */ uint32_t ncookies; /* must be 1 */ uint32_t token; /* arbitrary identifier */ } dma_area_t; /* 0x50 (80) bytes */ typedef struct bge_queue_item { struct bge_queue_item *next; void *item; } bge_queue_item_t; typedef struct bge_queue { bge_queue_item_t *head; uint32_t count; kmutex_t *lock; } bge_queue_t; /* * Software version of the Receive Buffer Descriptor * There's one of these for each receive buffer (up to 256/512/1024 per ring). */ typedef struct sw_rbd { dma_area_t pbuf; /* (const) related */ /* buffer area */ } sw_rbd_t; /* 0x50 (80) bytes */ /* * Software Receive Buffer (Producer) Ring Control Block * There's one of these for each receiver producer ring (up to 3), * but each holds buffers of a different size. */ typedef struct buff_ring { dma_area_t desc; /* (const) related h/w */ /* descriptor area */ dma_area_t buf[BGE_SPLIT]; /* (const) related */ /* buffer area(s) */ bge_rcb_t hw_rcb; /* (const) image of h/w */ /* RCB, and used to */ struct bge *bgep; /* (const) containing */ /* driver soft state */ /* initialise same */ volatile uint16_t *cons_index_p; /* (const) ptr to h/w */ /* "consumer index" */ /* (in status block) */ /* * The rf_lock must be held when updating the h/w producer index * mailbox register (*chip_mbox_reg), or the s/w producer index * (rf_next). */ bge_regno_t chip_mbx_reg; /* (const) h/w producer */ /* index mailbox offset */ kmutex_t rf_lock[1]; /* serialize refill */ uint64_t rf_next; /* next slot to refill */ /* ("producer index") */ sw_rbd_t *sw_rbds; /* software descriptors */ void *spare[4]; /* padding */ } buff_ring_t; /* 0x100 (256) bytes */ /* * Software Receive (Return) Ring Control Block * There's one of these for each receiver return ring (up to 16). */ typedef struct recv_ring { /* * The elements flagged (const) in the comments below are * set up once during initialiation and thereafter unchanged. */ dma_area_t desc; /* (const) related h/w */ /* descriptor area */ bge_rcb_t hw_rcb; /* (const) image of h/w */ /* RCB, and used to */ /* initialise same */ struct bge *bgep; /* (const) containing */ /* driver soft state */ ddi_softintr_t rx_softint; /* (const) per-ring */ /* receive callback */ volatile uint16_t *prod_index_p; /* (const) ptr to h/w */ /* "producer index" */ /* (in status block) */ /* * The rx_lock must be held when updating the h/w consumer index * mailbox register (*chip_mbox_reg), or the s/w consumer index * (rx_next). */ bge_regno_t chip_mbx_reg; /* (const) h/w consumer */ /* index mailbox offset */ kmutex_t rx_lock[1]; /* serialize receive */ uint64_t rx_next; /* next slot to examine */ mac_resource_handle_t handle; /* per ring cookie */ /* ("producer index") */ } recv_ring_t; /* 0x90 (144) bytes */ /* * Send packet structure */ typedef struct send_pkt { uint16_t vlan_tci; uint32_t pflags; boolean_t tx_ready; bge_queue_item_t *txbuf_item; } send_pkt_t; /* * Software version of tx buffer structure */ typedef struct sw_txbuf { dma_area_t buf; uint32_t copy_len; } sw_txbuf_t; /* * Software version of the Send Buffer Descriptor * There's one of these for each send buffer (up to 512 per ring) */ typedef struct sw_sbd { dma_area_t desc; /* (const) related h/w */ /* descriptor area */ bge_queue_item_t *pbuf; /* (const) related */ /* buffer area */ } sw_sbd_t; /* * Software Send Ring Control Block * There's one of these for each of (up to) 16 send rings */ typedef struct send_ring { /* * The elements flagged (const) in the comments below are * set up once during initialiation and thereafter unchanged. */ dma_area_t desc; /* (const) related h/w */ /* descriptor area */ dma_area_t buf[BGE_SEND_BUF_ARRAY][BGE_SPLIT]; /* buffer area(s) */ bge_rcb_t hw_rcb; /* (const) image of h/w */ /* RCB, and used to */ /* initialise same */ struct bge *bgep; /* (const) containing */ /* driver soft state */ volatile uint16_t *cons_index_p; /* (const) ptr to h/w */ /* "consumer index" */ /* (in status block) */ bge_regno_t chip_mbx_reg; /* (const) h/w producer */ /* index mailbox offset */ /* * Tx buffer queue */ bge_queue_t txbuf_queue; bge_queue_t freetxbuf_queue; bge_queue_t *txbuf_push_queue; bge_queue_t *txbuf_pop_queue; kmutex_t txbuf_lock[1]; kmutex_t freetxbuf_lock[1]; bge_queue_item_t *txbuf_head; send_pkt_t *pktp; uint64_t txpkt_next; uint64_t txfill_next; sw_txbuf_t *txbuf; uint32_t tx_buffers; uint32_t tx_buffers_low; uint32_t tx_array_max; uint32_t tx_array; kmutex_t tx_lock[1]; /* serialize h/w update */ /* ("producer index") */ uint64_t tx_next; /* next slot to use */ uint64_t tx_flow; /* # concurrent sends */ uint64_t tx_block; uint64_t tx_nobd; uint64_t tx_nobuf; uint64_t tx_alloc_fail; /* * These counters/indexes are manipulated in the transmit * path using atomics rather than mutexes for speed */ uint64_t tx_free; /* # of slots available */ /* * The tc_lock must be held while manipulating the s/w consumer * index (tc_next). */ kmutex_t tc_lock[1]; /* serialize recycle */ uint64_t tc_next; /* next slot to recycle */ /* ("consumer index") */ sw_sbd_t *sw_sbds; /* software descriptors */ uint64_t mac_resid; /* special per resource id */ } send_ring_t; /* 0x100 (256) bytes */ typedef struct { ether_addr_t addr; /* in canonical form */ uint8_t spare; boolean_t set; /* B_TRUE => valid */ } bge_mac_addr_t; /* * The original 5700/01 supported only SEEPROMs. Later chips (5702+) * support both SEEPROMs (using the same 2-wire CLK/DATA interface for * the hardware and a backwards-compatible software access method), and * buffered or unbuffered FLASH devices connected to the 4-wire SPI bus * and using a new software access method. * * The access methods for SEEPROM and Flash are generally similar, with * the chip handling the serialisation/deserialisation and handshaking, * but the registers used are different, as are a few details of the * protocol, and the timing, so we have to determine which (if any) is * fitted. * * The value UNKNOWN means just that; we haven't yet tried to determine * the device type. * * The value NONE can indicate either that a real and definite absence of * any NVmem has been detected, or that there may be NVmem but we can't * determine its type, perhaps because the NVconfig pins on the chip have * been wired up incorrectly. In either case, access to the NVmem (if any) * is not supported. */ enum bge_nvmem_type { BGE_NVTYPE_NONE = -1, /* (or indeterminable) */ BGE_NVTYPE_UNKNOWN, /* not yet checked */ BGE_NVTYPE_SEEPROM, /* BCM5700/5701 only */ BGE_NVTYPE_LEGACY_SEEPROM, /* 5702+ */ BGE_NVTYPE_UNBUFFERED_FLASH, /* 5702+ */ BGE_NVTYPE_BUFFERED_FLASH /* 5702+ */ }; /* * Describes the characteristics of a specific chip * * Note: elements from to are filled in by during * the first phase of chip initialisation (see bge_chip_cfg_init()). * The remaining ones are determined just after the first RESET, in * bge_poll_firmware(). Thereafter, the entire structure is readonly. */ typedef struct { uint32_t asic_rev; /* masked from MHCR */ uint32_t businfo; /* from private reg */ uint16_t command; /* saved during attach */ uint16_t vendor; /* vendor-id */ uint16_t device; /* device-id */ uint16_t subven; /* subsystem-vendor-id */ uint16_t subdev; /* subsystem-id */ uint8_t revision; /* revision-id */ uint8_t clsize; /* cache-line-size */ uint8_t latency; /* latency-timer */ uint8_t flags; uint16_t chip_label; /* numeric part only */ /* (e.g. 5703/5794/etc) */ uint32_t mbuf_base; /* Mbuf pool parameters */ uint32_t mbuf_length; /* depend on chiptype */ uint32_t pci_type; uint32_t statistic_type; uint32_t bge_dma_rwctrl; uint32_t bge_mlcr_default; uint32_t recv_slots; /* receive ring size */ enum bge_nvmem_type nvtype; /* SEEPROM or Flash */ uint16_t jumbo_slots; uint16_t ethmax_size; uint16_t snd_buff_size; uint16_t recv_jumbo_size; uint16_t std_buf_size; uint32_t mbuf_hi_water; uint32_t mbuf_lo_water_rmac; uint32_t mbuf_lo_water_rdma; uint32_t rx_rings; /* from bge.conf */ uint32_t tx_rings; /* from bge.conf */ uint32_t default_mtu; /* from bge.conf */ uint64_t hw_mac_addr; /* from chip register */ bge_mac_addr_t vendor_addr; /* transform of same */ boolean_t msi_enabled; /* default to true */ uint32_t rx_ticks_norm; uint32_t rx_count_norm; } chip_id_t; #define CHIP_FLAG_SUPPORTED 0x80 #define CHIP_FLAG_SERDES 0x40 #define CHIP_FLAG_PARTIAL_CSUM 0x20 #define CHIP_FLAG_NO_JUMBO 0x1 /* * Collection of physical-layer functions to: * (re)initialise the physical layer * update it to match software settings * check for link status change */ typedef struct { int (*phys_restart)(struct bge *, boolean_t); int (*phys_update)(struct bge *); boolean_t (*phys_check)(struct bge *, boolean_t); } phys_ops_t; /* * Named Data (ND) Parameter Management Structure */ typedef struct { int ndp_info; int ndp_min; int ndp_max; int ndp_val; char *ndp_name; } nd_param_t; /* 0x18 (24) bytes */ /* * NDD parameter indexes, divided into: * * read-only parameters describing the hardware's capabilities * read-write parameters controlling the advertised capabilities * read-only parameters describing the partner's capabilities * read-only parameters describing the link state */ enum { PARAM_AUTONEG_CAP, PARAM_PAUSE_CAP, PARAM_ASYM_PAUSE_CAP, PARAM_1000FDX_CAP, PARAM_1000HDX_CAP, PARAM_100T4_CAP, PARAM_100FDX_CAP, PARAM_100HDX_CAP, PARAM_10FDX_CAP, PARAM_10HDX_CAP, PARAM_ADV_AUTONEG_CAP, PARAM_ADV_PAUSE_CAP, PARAM_ADV_ASYM_PAUSE_CAP, PARAM_ADV_1000FDX_CAP, PARAM_ADV_1000HDX_CAP, PARAM_ADV_100T4_CAP, PARAM_ADV_100FDX_CAP, PARAM_ADV_100HDX_CAP, PARAM_ADV_10FDX_CAP, PARAM_ADV_10HDX_CAP, PARAM_LP_AUTONEG_CAP, PARAM_LP_PAUSE_CAP, PARAM_LP_ASYM_PAUSE_CAP, PARAM_LP_1000FDX_CAP, PARAM_LP_1000HDX_CAP, PARAM_LP_100T4_CAP, PARAM_LP_100FDX_CAP, PARAM_LP_100HDX_CAP, PARAM_LP_10FDX_CAP, PARAM_LP_10HDX_CAP, PARAM_LINK_STATUS, PARAM_LINK_SPEED, PARAM_LINK_DUPLEX, PARAM_LINK_AUTONEG, PARAM_LINK_RX_PAUSE, PARAM_LINK_TX_PAUSE, PARAM_MSI_CNT, PARAM_DRAIN_MAX, PARAM_COUNT }; /* * Actual state of the BCM570x chip */ enum bge_chip_state { BGE_CHIP_FAULT = -2, /* fault, need reset */ BGE_CHIP_ERROR, /* error, want reset */ BGE_CHIP_INITIAL, /* Initial state only */ BGE_CHIP_RESET, /* reset, need init */ BGE_CHIP_STOPPED, /* Tx/Rx stopped */ BGE_CHIP_RUNNING /* with interrupts */ }; enum bge_mac_state { BGE_MAC_STOPPED = 0, BGE_MAC_STARTED }; /* * (Internal) return values from ioctl subroutines */ enum ioc_reply { IOC_INVAL = -1, /* bad, NAK with EINVAL */ IOC_DONE, /* OK, reply sent */ IOC_ACK, /* OK, just send ACK */ IOC_REPLY, /* OK, just send reply */ IOC_RESTART_ACK, /* OK, restart & ACK */ IOC_RESTART_REPLY /* OK, restart & reply */ }; /* * (Internal) return values from send_msg subroutines */ enum send_status { SEND_FAIL = -1, /* Not OK */ SEND_KEEP, /* OK, msg queued */ SEND_FREE /* OK, free msg */ }; /* * (Internal) enumeration of this driver's kstats */ enum { BGE_KSTAT_RAW = 0, BGE_KSTAT_STATS, BGE_KSTAT_CHIPID, BGE_KSTAT_DRIVER, BGE_KSTAT_PHYS, BGE_KSTAT_COUNT }; #define BGE_MAX_RESOURCES 255 /* * Per-instance soft-state structure */ typedef struct bge { /* * These fields are set by attach() and unchanged thereafter ... */ dev_info_t *devinfo; /* device instance */ mac_handle_t mh; /* mac module handle */ ddi_acc_handle_t cfg_handle; /* DDI I/O handle */ ddi_acc_handle_t io_handle; /* DDI I/O handle */ void *io_regs; /* mapped registers */ ddi_periodic_t periodic_id; /* periodical callback */ ddi_softintr_t factotum_id; /* factotum callback */ ddi_softintr_t drain_id; /* reschedule callback */ ddi_intr_handle_t *htable; /* For array of interrupts */ int intr_type; /* What type of interrupt */ int intr_cnt; /* # of intrs count returned */ uint_t intr_pri; /* Interrupt priority */ int intr_cap; /* Interrupt capabilities */ uint32_t progress; /* attach tracking */ uint32_t debug; /* per-instance debug */ chip_id_t chipid; const phys_ops_t *physops; char ifname[8]; /* "bge0" ... "bge999" */ int fm_capabilities; /* FMA capabilities */ /* * These structures describe the blocks of memory allocated during * attach(). They remain unchanged thereafter, although the memory * they describe is carved up into various separate regions and may * therefore be described by other structures as well. */ dma_area_t tx_desc; /* transmit descriptors */ dma_area_t rx_desc[BGE_RECV_RINGS_SPLIT]; /* receive descriptors */ dma_area_t tx_buff[BGE_SPLIT]; dma_area_t rx_buff[BGE_SPLIT]; /* * The memory described by the structures above * is carved up into various pieces, which are described by * the structures below. */ dma_area_t statistics; /* describes hardware */ /* statistics area */ dma_area_t status_block; /* describes hardware */ /* status block */ /* * For the BCM5705/5788/5721/5751/5752/5714 and 5715, * the statistic block is not available,the statistic counter must * be gotten from statistic registers.And bge_statistics_reg_t record * the statistic registers value */ bge_statistics_reg_t *pstats; /* * Runtime read-write data starts here ... * * 3 Buffer Rings (std/jumbo/mini) * 16 Receive (Return) Rings * 16 Send Rings * * Note: they're not necessarily all used. */ buff_ring_t buff[BGE_BUFF_RINGS_MAX]; /* 3*0x0100 */ recv_ring_t recv[BGE_RECV_RINGS_MAX]; /* 16*0x0090 */ send_ring_t send[BGE_SEND_RINGS_MAX]; /* 16*0x0100 */ /* * Locks: * * Each buffer ring contains its own which regulates * ring refilling. * * Each receive (return) ring contains its own which * protects the critical cyclic counters etc. * * Each send ring contains two locks: for the send-path * protocol data and for send-buffer recycling. * * Finally is a general lock, protecting most other * operational data in the state structure and chip register * accesses. It is acquired by the interrupt handler and * most "mode-control" routines. * * Any of the locks can be acquired singly, but where multiple * locks are acquired, they *must* be in the order: * * genlock >>> rx_lock >>> rf_lock >>> tx_lock >>> tc_lock. * * and within any one class of lock the rings must be locked in * ascending order (send[0].tc_lock >>> send[1].tc_lock), etc. * * Note: actually I don't believe there's any need to acquire * locks on multiple rings, or even locks of all these classes * concurrently; but I've set out the above order so there is a * clear definition of lock hierarchy in case it's ever needed. * * Note: the combinations of locks that are actually held * concurrently are: * * genlock >>> (bge_chip_interrupt()) * rx_lock[i] >>> (bge_receive()) * rf_lock[n] (bge_refill()) * tc_lock[i] (bge_recycle()) */ kmutex_t genlock[1]; krwlock_t errlock[1]; kmutex_t softintrlock[1]; /* * Current Ethernet addresses and multicast hash (bitmap) and * refcount tables, protected by */ bge_mac_addr_t curr_addr[MAC_ADDRESS_REGS_MAX]; uint32_t mcast_hash[BGE_HASH_TABLE_SIZE/32]; uint8_t mcast_refs[BGE_HASH_TABLE_SIZE]; uint32_t unicst_addr_total; /* total unicst addresses */ uint32_t unicst_addr_avail; /* unused unicst addr slots */ /* * Link state data (protected by genlock) */ link_state_t link_state; /* * Physical layer: copper only */ bge_regno_t phy_mii_addr; /* should be (const) 1! */ uint16_t phy_gen_status; uint16_t phy_aux_status; /* * Physical layer: serdes only */ uint32_t serdes_status; uint32_t serdes_advert; uint32_t serdes_lpadv; /* * Driver kstats, protected by where necessary */ kstat_t *bge_kstats[BGE_KSTAT_COUNT]; /* * Miscellaneous operating variables (protected by genlock) */ uint64_t chip_resets; /* # of chip RESETs */ uint64_t missed_dmas; /* # of missed DMAs */ uint64_t missed_updates; /* # of missed updates */ enum bge_mac_state bge_mac_state; /* definitions above */ enum bge_chip_state bge_chip_state; /* definitions above */ boolean_t send_hw_tcp_csum; boolean_t recv_hw_tcp_csum; boolean_t promisc; boolean_t manual_reset; /* * Miscellaneous operating variables (not synchronised) */ uint32_t watchdog; /* watches for Tx stall */ boolean_t bge_intr_running; boolean_t bge_dma_error; boolean_t tx_resched_needed; uint64_t tx_resched; uint32_t factotum_flag; /* softint pending */ uintptr_t pagemask; /* * NDD parameters (protected by genlock) */ caddr_t nd_data_p; nd_param_t *nd_params; /* * A flag to prevent excessive config space accesses * on platforms having BCM5714C/15C */ boolean_t lastWriteZeroData; /* * Spare space, plus guard element used to check data integrity */ uint64_t spare[5]; uint64_t bge_guard; /* * Receive rules configure */ bge_recv_rule_t recv_rules[RECV_RULES_NUM_MAX]; #ifdef BGE_IPMI_ASF boolean_t asf_enabled; boolean_t asf_wordswapped; boolean_t asf_newhandshake; boolean_t asf_pseudostop; uint32_t asf_status; timeout_id_t asf_timeout_id; #endif uint32_t param_en_pause:1, param_en_asym_pause:1, param_en_1000hdx:1, param_en_1000fdx:1, param_en_100fdx:1, param_en_100hdx:1, param_en_10fdx:1, param_en_10hdx:1, param_pad_to_32:24; uint32_t param_loop_mode; } bge_t; /* * 'Progress' bit flags ... */ #define PROGRESS_CFG 0x0001 /* config space mapped */ #define PROGRESS_REGS 0x0002 /* registers mapped */ #define PROGRESS_BUFS 0x0004 /* ring buffers allocated */ #define PROGRESS_RESCHED 0x0010 /* resched softint registered */ #define PROGRESS_FACTOTUM 0x0020 /* factotum softint registered */ #define PROGRESS_HWINT 0x0040 /* h/w interrupt registered */ /* and mutexen initialised */ #define PROGRESS_INTR 0x0080 /* Intrs enabled */ #define PROGRESS_PHY 0x0100 /* PHY initialised */ #define PROGRESS_NDD 0x1000 /* NDD parameters set up */ #define PROGRESS_KSTATS 0x2000 /* kstats created */ #define PROGRESS_READY 0x8000 /* ready for work */ /* * Shorthand for the NDD parameters */ #define param_adv_autoneg nd_params[PARAM_ADV_AUTONEG_CAP].ndp_val #define param_adv_pause nd_params[PARAM_ADV_PAUSE_CAP].ndp_val #define param_adv_asym_pause nd_params[PARAM_ADV_ASYM_PAUSE_CAP].ndp_val #define param_adv_1000fdx nd_params[PARAM_ADV_1000FDX_CAP].ndp_val #define param_adv_1000hdx nd_params[PARAM_ADV_1000HDX_CAP].ndp_val #define param_adv_100fdx nd_params[PARAM_ADV_100FDX_CAP].ndp_val #define param_adv_100hdx nd_params[PARAM_ADV_100HDX_CAP].ndp_val #define param_adv_10fdx nd_params[PARAM_ADV_10FDX_CAP].ndp_val #define param_adv_10hdx nd_params[PARAM_ADV_10HDX_CAP].ndp_val #define param_lp_autoneg nd_params[PARAM_LP_AUTONEG_CAP].ndp_val #define param_lp_pause nd_params[PARAM_LP_PAUSE_CAP].ndp_val #define param_lp_asym_pause nd_params[PARAM_LP_ASYM_PAUSE_CAP].ndp_val #define param_lp_1000fdx nd_params[PARAM_LP_1000FDX_CAP].ndp_val #define param_lp_1000hdx nd_params[PARAM_LP_1000HDX_CAP].ndp_val #define param_lp_100fdx nd_params[PARAM_LP_100FDX_CAP].ndp_val #define param_lp_100hdx nd_params[PARAM_LP_100HDX_CAP].ndp_val #define param_lp_10fdx nd_params[PARAM_LP_10FDX_CAP].ndp_val #define param_lp_10hdx nd_params[PARAM_LP_10HDX_CAP].ndp_val #define param_link_up nd_params[PARAM_LINK_STATUS].ndp_val #define param_link_speed nd_params[PARAM_LINK_SPEED].ndp_val #define param_link_duplex nd_params[PARAM_LINK_DUPLEX].ndp_val #define param_link_autoneg nd_params[PARAM_LINK_AUTONEG].ndp_val #define param_link_rx_pause nd_params[PARAM_LINK_RX_PAUSE].ndp_val #define param_link_tx_pause nd_params[PARAM_LINK_TX_PAUSE].ndp_val #define param_msi_cnt nd_params[PARAM_MSI_CNT].ndp_val #define param_drain_max nd_params[PARAM_DRAIN_MAX].ndp_val /* * Sync a DMA area described by a dma_area_t */ #define DMA_SYNC(area, flag) ((void) ddi_dma_sync((area).dma_hdl, \ (area).offset, (area).alength, (flag))) /* * Find the (kernel virtual) address of block of memory * described by a dma_area_t */ #define DMA_VPTR(area) ((area).mem_va) /* * Zero a block of memory described by a dma_area_t */ #define DMA_ZERO(area) bzero(DMA_VPTR(area), (area).alength) /* * Next value of a cyclic index */ #define NEXT(index, limit) ((index)+1 < (limit) ? (index)+1 : 0) /* * Property lookups */ #define BGE_PROP_EXISTS(d, n) ddi_prop_exists(DDI_DEV_T_ANY, (d), \ DDI_PROP_DONTPASS, (n)) #define BGE_PROP_GET_INT(d, n) ddi_prop_get_int(DDI_DEV_T_ANY, (d), \ DDI_PROP_DONTPASS, (n), -1) /* * Copy an ethernet address */ #define ethaddr_copy(src, dst) bcopy((src), (dst), ETHERADDRL) /* * Endian swap */ /* BEGIN CSTYLED */ #define BGE_BSWAP_32(x) ((((x) & 0xff000000) >> 24) | \ (((x) & 0x00ff0000) >> 8) | \ (((x) & 0x0000ff00) << 8) | \ (((x) & 0x000000ff) << 24)) /* END CSTYLED */ /* * Marker value placed at the end of the driver's state */ #define BGE_GUARD 0x1919306009031802 /* * Bit flags in the 'debug' word ... */ #define BGE_DBG_STOP 0x00000001 /* early debug_enter() */ #define BGE_DBG_TRACE 0x00000002 /* general flow tracing */ #define BGE_DBG_REGS 0x00000010 /* low-level accesses */ #define BGE_DBG_MII 0x00000020 /* low-level MII access */ #define BGE_DBG_SEEPROM 0x00000040 /* low-level SEEPROM IO */ #define BGE_DBG_CHIP 0x00000080 /* low(ish)-level code */ #define BGE_DBG_RECV 0x00000100 /* receive-side code */ #define BGE_DBG_SEND 0x00000200 /* packet-send code */ #define BGE_DBG_INT 0x00001000 /* interrupt handler */ #define BGE_DBG_FACT 0x00002000 /* factotum (softint) */ #define BGE_DBG_PHY 0x00010000 /* Copper PHY code */ #define BGE_DBG_SERDES 0x00020000 /* SerDes code */ #define BGE_DBG_PHYS 0x00040000 /* Physical layer code */ #define BGE_DBG_LINK 0x00080000 /* Link status check */ #define BGE_DBG_INIT 0x00100000 /* initialisation */ #define BGE_DBG_NEMO 0x00200000 /* nemo interaction */ #define BGE_DBG_ADDR 0x00400000 /* address-setting code */ #define BGE_DBG_STATS 0x00800000 /* statistics */ #define BGE_DBG_IOCTL 0x01000000 /* ioctl handling */ #define BGE_DBG_LOOP 0x02000000 /* loopback ioctl code */ #define BGE_DBG_PPIO 0x04000000 /* Peek/poke ioctls */ #define BGE_DBG_BADIOC 0x08000000 /* unknown ioctls */ #define BGE_DBG_MCTL 0x10000000 /* mctl (csum) code */ #define BGE_DBG_NDD 0x20000000 /* NDD operations */ /* * Debugging ... */ #ifdef DEBUG #define BGE_DEBUGGING 1 #else #define BGE_DEBUGGING 0 #endif /* DEBUG */ /* * 'Do-if-debugging' macro. The parameter should be one or more * C statements (but without the *final* semicolon), which will either be * compiled inline or completely ignored, depending on the BGE_DEBUGGING * compile-time flag. * * You should get a compile-time error (at least on a DEBUG build) if * your statement isn't actually a statement, rather than unexpected * run-time behaviour caused by unintended matching of if-then-elses etc. * * Note that the BGE_DDB() macro itself can only be used as a statement, * not an expression, and should always be followed by a semicolon. */ #if BGE_DEBUGGING #define BGE_DDB(command) do { \ { command; } \ _NOTE(CONSTANTCONDITION) \ } while (0) #else /* BGE_DEBUGGING */ #define BGE_DDB(command) do { \ { _NOTE(EMPTY); } \ _NOTE(CONSTANTCONDITION) \ } while (0) #endif /* BGE_DEBUGGING */ /* * 'Internal' macros used to construct the TRACE/DEBUG macros below. * These provide the primitive conditional-call capability required. * Note: the parameter is a parenthesised list of the actual * printf-style arguments to be passed to the debug function ... */ #define BGE_XDB(b, w, f, args) BGE_DDB(if ((b) & (w)) f args) #define BGE_GDB(b, args) BGE_XDB(b, bge_debug, (*bge_gdb()), args) #define BGE_LDB(b, args) BGE_XDB(b, bgep->debug, (*bge_db(bgep)), args) #define BGE_CDB(f, args) BGE_XDB(BGE_DBG, bgep->debug, f, args) /* * Conditional-print macros. * * Define BGE_DBG to be the relevant member of the set of BGE_DBG_* values * above before using the BGE_GDEBUG() or BGE_DEBUG() macros. The 'G' * versions look at the Global debug flag word (bge_debug); the non-G * versions look in the per-instance data (bgep->debug) and so require a * variable called 'bgep' to be in scope (and initialised!) before use. * * You could redefine BGE_TRC too if you really need two different * flavours of debugging output in the same area of code, but I don't * really recommend it. * * Note: the parameter is a parenthesised list of the actual * arguments to be passed to the debug function, usually a printf-style * format string and corresponding values to be formatted. */ #define BGE_TRC BGE_DBG_TRACE /* default 'trace' bit */ #define BGE_GTRACE(args) BGE_GDB(BGE_TRC, args) #define BGE_GDEBUG(args) BGE_GDB(BGE_DBG, args) #define BGE_TRACE(args) BGE_LDB(BGE_TRC, args) #define BGE_DEBUG(args) BGE_LDB(BGE_DBG, args) /* * Debug-only action macros */ #define BGE_BRKPT(bgep, s) BGE_DDB(bge_dbg_enter(bgep, s)) #define BGE_MARK(bgep) BGE_DDB(bge_led_mark(bgep)) #define BGE_PCICHK(bgep) BGE_DDB(bge_pci_check(bgep)) #define BGE_PKTDUMP(args) BGE_DDB(bge_pkt_dump args) #define BGE_REPORT(args) BGE_DDB(bge_log args) /* * Inter-source-file linkage ... */ /* bge_chip.c */ uint16_t bge_mii_get16(bge_t *bgep, bge_regno_t regno); void bge_mii_put16(bge_t *bgep, bge_regno_t regno, uint16_t value); uint32_t bge_reg_get32(bge_t *bgep, bge_regno_t regno); void bge_reg_put32(bge_t *bgep, bge_regno_t regno, uint32_t value); void bge_reg_set32(bge_t *bgep, bge_regno_t regno, uint32_t bits); void bge_reg_clr32(bge_t *bgep, bge_regno_t regno, uint32_t bits); void bge_mbx_put(bge_t *bgep, bge_regno_t regno, uint64_t value); void bge_chip_cfg_init(bge_t *bgep, chip_id_t *cidp, boolean_t enable_dma); int bge_chip_id_init(bge_t *bgep); int bge_chip_start(bge_t *bgep, boolean_t reset_phy); void bge_chip_stop(bge_t *bgep, boolean_t fault); #ifdef BGE_IPMI_ASF void bge_nic_put32(bge_t *bgep, bge_regno_t addr, uint32_t data); #pragma inline(bge_nic_put32) uint32_t bge_nic_read32(bge_t *bgep, bge_regno_t addr); void bge_ind_put32(bge_t *bgep, bge_regno_t regno, uint32_t val); #pragma inline(bge_ind_put32) uint32_t bge_ind_get32(bge_t *bgep, bge_regno_t regno); #pragma inline(bge_ind_get32) void bge_asf_update_status(bge_t *bgep); void bge_asf_heartbeat(void *bgep); void bge_asf_stop_timer(bge_t *bgep); void bge_asf_get_config(bge_t *bgep); void bge_asf_pre_reset_operations(bge_t *bgep, uint32_t mode); void bge_asf_post_reset_old_mode(bge_t *bgep, uint32_t mode); void bge_asf_post_reset_new_mode(bge_t *bgep, uint32_t mode); int bge_chip_reset(bge_t *bgep, boolean_t enable_dma, uint_t asf_mode); int bge_chip_sync(bge_t *bgep, boolean_t asf_keeplive); #else int bge_chip_reset(bge_t *bgep, boolean_t enable_dma); int bge_chip_sync(bge_t *bgep); #endif void bge_chip_blank(void *arg, time_t ticks, uint_t count); uint_t bge_chip_factotum(caddr_t arg); void bge_chip_cyclic(void *arg); enum ioc_reply bge_chip_ioctl(bge_t *bgep, queue_t *wq, mblk_t *mp, struct iocblk *iocp); uint_t bge_intr(caddr_t arg1, caddr_t arg2); void bge_sync_mac_modes(bge_t *); extern uint32_t bge_rx_ticks_norm; extern uint32_t bge_tx_ticks_norm; extern uint32_t bge_rx_count_norm; extern uint32_t bge_tx_count_norm; extern boolean_t bge_jumbo_enable; extern boolean_t bge_relaxed_ordering; void bge_chip_msi_trig(bge_t *bgep); /* bge_kstats.c */ void bge_init_kstats(bge_t *bgep, int instance); void bge_fini_kstats(bge_t *bgep); int bge_m_stat(void *arg, uint_t stat, uint64_t *val); /* bge_log.c */ #if BGE_DEBUGGING void (*bge_db(bge_t *bgep))(const char *fmt, ...); void (*bge_gdb(void))(const char *fmt, ...); void bge_pkt_dump(bge_t *bgep, bge_rbd_t *hbp, sw_rbd_t *sdp, const char *msg); void bge_dbg_enter(bge_t *bgep, const char *msg); #endif /* BGE_DEBUGGING */ void bge_problem(bge_t *bgep, const char *fmt, ...); void bge_log(bge_t *bgep, const char *fmt, ...); void bge_error(bge_t *bgep, const char *fmt, ...); void bge_fm_ereport(bge_t *bgep, char *detail); extern kmutex_t bge_log_mutex[1]; extern uint32_t bge_debug; /* bge_main.c */ int bge_restart(bge_t *bgep, boolean_t reset_phy); int bge_check_acc_handle(bge_t *bgep, ddi_acc_handle_t handle); int bge_check_dma_handle(bge_t *bgep, ddi_dma_handle_t handle); void bge_init_rings(bge_t *bgep); void bge_fini_rings(bge_t *bgep); bge_queue_item_t *bge_alloc_txbuf_array(bge_t *bgep, send_ring_t *srp); void bge_free_txbuf_arrays(send_ring_t *srp); int bge_alloc_bufs(bge_t *bgep); void bge_free_bufs(bge_t *bgep); void bge_intr_enable(bge_t *bgep); void bge_intr_disable(bge_t *bgep); int bge_reprogram(bge_t *); /* bge_phys.c */ int bge_phys_init(bge_t *bgep); void bge_phys_reset(bge_t *bgep); int bge_phys_idle(bge_t *bgep); int bge_phys_update(bge_t *bgep); boolean_t bge_phys_check(bge_t *bgep); /* bge_ndd.c */ int bge_nd_init(bge_t *bgep); enum ioc_reply bge_nd_ioctl(bge_t *bgep, queue_t *wq, mblk_t *mp, struct iocblk *iocp); void bge_nd_cleanup(bge_t *bgep); /* bge_recv.c */ void bge_receive(bge_t *bgep, bge_status_t *bsp); /* bge_send.c */ mblk_t *bge_m_tx(void *arg, mblk_t *mp); void bge_recycle(bge_t *bgep, bge_status_t *bsp); uint_t bge_send_drain(caddr_t arg); /* bge_atomic.c */ uint64_t bge_atomic_reserve(uint64_t *count_p, uint64_t n); void bge_atomic_renounce(uint64_t *count_p, uint64_t n); uint64_t bge_atomic_claim(uint64_t *count_p, uint64_t limit); uint64_t bge_atomic_next(uint64_t *sp, uint64_t limit); void bge_atomic_sub64(uint64_t *count_p, uint64_t n); uint64_t bge_atomic_clr64(uint64_t *sp, uint64_t bits); uint32_t bge_atomic_shl32(uint32_t *sp, uint_t count); /* * Reset type */ #define BGE_SHUTDOWN_RESET 0 #define BGE_INIT_RESET 1 #define BGE_SUSPEND_RESET 2 /* For asf_status */ #define ASF_STAT_NONE 0 #define ASF_STAT_STOP 1 #define ASF_STAT_RUN 2 #define ASF_STAT_RUN_INIT 3 /* attached but don't plumb */ /* ASF modes for bge_reset() and bge_chip_reset() */ #define ASF_MODE_NONE 0 /* don't launch asf */ #define ASF_MODE_SHUTDOWN 1 /* asf shutdown mode */ #define ASF_MODE_INIT 2 /* asf init mode */ #define ASF_MODE_POST_SHUTDOWN 3 /* only do post-shutdown */ #define ASF_MODE_POST_INIT 4 /* only do post-init */ #define BGE_ASF_HEARTBEAT_INTERVAL 1500000 #ifdef __cplusplus } #endif #endif /* _BGE_IMPL_H */