/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (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 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. * * Inter-Domain Network */ #ifndef _SYS_IDN_H #define _SYS_IDN_H #pragma ident "%Z%%M% %I% %E% SMI" #ifndef _ASM #ifdef _KERNEL #include #include #include #include #include #include #include #include #include #include #include #include #include #endif /* _KERNEL */ #ifdef __cplusplus extern "C" { #endif typedef const char * const procname_t; #define MB2B(m) ((size_t)(m) << 20) /* MBytes to Bytes */ #define B2MB(b) ((uint_t)((b) >> 20)) /* Bytes to MBytes */ #ifdef _KERNEL /* * IDN_PROP_SMRSIZE - User specified size in MBytes. * IDN_PROP_SMRADDR - OBP's internal physical address of the region. * * OBP properties of "memory" node that define the SMR space. */ #define IDN_PROP_SMRSIZE "idn-smr-size" #define IDN_PROP_SMRADDR "idn-smr-addr" /* * IDN_AWOLMSG_INTERVAL (driver.conf) * * Number of seconds between AWOL messages on a per-domain basis. * The purpose is to throttle the frequency at which these * messages appear. * * IDN_MSGWAIT_NEGO (driver.conf) * IDN_MSGWAIT_CFG * IDN_MSGWAIT_CON * IDN_MSGWAIT_FIN * IDN_MSGWAIT_CMD * IDN_MSGWAIT_DATA * * Number of seconds to wait for response to respective * message type. * * IDN_RETRYFREQ_NEGO (driver.conf) * IDN_RETRYFREQ_CON * IDN_RETRYFREQ_FIN * * Number of seconds to wait between retries of the respective * message type. * * IDN_SMR_ALIGN (not tunable) * * The hardware registers that describe the SMR are based on a 64K * aligned physical address. * * IDN_SMR_SIZE (OBP [only]) * * Total size of the SMR (Shared Memory Region) in bytes. * * IDN_NWR_SIZE (driver.conf) * * Total size of the NWR (NetWork Region) portion of the SMR which * is actually used to support network activity. The NWR is managed * as simply a pool of I/O buffers which are distributed by the * Master domain to the Slaves for the purpose of communicating * between each other. If not set then the entire SMR is used * as the NWR. * Req: IDN_NWR_SIZE <= IDN_SMR_SIZE * * IDN_SMR_BUFSIZE (driver.conf) * * Size of individual SMR buffers. The SMR is divided into chunks * of IDN_SMR_BUFSIZE bytes. The IDN_MTU is based on this size * and thus the IDN_SMR_BUFSIZE should be chosen based on performance. * * IDN_DATA_SIZE (NOT tunable) * * Portion of IDN_SMR_BUFSIZE that can contain raw non-IDN dependent * data. We subtract IDN_ALIGNSIZE bytes to allow for fast bcopy * alignment. * Req: IDN_DATA_SIZE <= * (IDN_SMR_BUFSIZE - sizeof (smr_pkthdr_t) - IDN_ALIGNSIZE) * * IDN_MTU (indirectly tunable via IDN_SMR_BUFSIZE) * * This size represents the portion of an SMR I/O buffers that can * contain (ethernet headerless) data. * Req: IDN_MTU <= IDN_DATA_SIZE - sizeof (ether_header) * * IDN_WINDOW_MAX (driver.conf) * * Maximum number of outstanding packets that are allowed per * domain. If this value is exceeded for a particular domain * no further I/Os will be transmitted to that domain until it * has acknowledged enough of the previous transmission to bring * down its outstanding I/O count (idn_domain.dio) below this * value. In addition, if this value is exceeded then a Timer * is scheduled to check for any response from the remote domain. * * IDN_WINDOW_INCR (driver.conf) * * As more channels/nets are activated on a particular domain * the greater the number of possible outstanding data packets * that can be outstanding to a given domain. Since this natural * occurence can result in the outstanding-I/O count to a given * domain to increase we run the risk of dropping into the * IDN_WINDOW_MAX region even though the receiving domain * may be fine with handling the load. In order to compensate * for this increased activity and to not incur unjustified * slips into the IDN_WINDOW_MAX region, the IDN_WINDOW_MAX * value is adjusted by IDN_WINDOW_INCR for each channel/net * that is activated for a given domain. * * IDN_WINDOW_EMAX (not tunable) * * The effective value of IDN_WINDOW_MAX once it has * been adjusted by IDN_WINDOW_INCR. * * IDN_RECLAIM_MIN (driver.conf) * * Minimum number of outstanding packets that our allowed * before subsequent sends will attempt to reclaim some number * of outstanding data packets. * * IDN_RECLAIM_MAX (driver.conf) * This value represents the maximum number of outstanding * packets we will try to reclaim during a send once we've * passed the IDN_RECLAIM_MIN boundary. * * IDN_MODUNLOADABLE (ndd) * * By default the IDN driver is unloadable. Setting this * variable will allow the IDN driver to be unloaded provided * it's not in use. * * IDN_LOWAT/IDN_HIWAT (driver.conf) * * Low/High water marks for the STREAM interface to IDN. * * IDN_MBOX_PER_NET (driver.conf) * * Number of mailbox entries that are allocated per channel/net. * This value effectively represents the amount of outstanding * activity that can reside at a domain. Increasing this value * allows more packets to be in transit to a domain, however * at some point there are diminishing returns since the receiver * can only consume packets so fast. * * IDN_MAX_NETS (driver.conf) * * Maximum number of network interfaces (channels) that IDN * is currently configured to allow. The absolute max is * IDN_MAXMAX_NETS. We don't automatically default IDN_MAX_NETS * to IDN_MAXMAX_NETS because it would mean wasted space in * the mailbox region having to reserve mailboxes that will * very likely go unused. The smaller this value the fewer * the number of mailboxes in the SMR and thus the greater the * number of possible I/O buffers available. * Req: IDN_MAX_NETS <= IDN_MAXMAX_NETS * * IDN_CHECKSUM (driver.conf) * * If enabled, IDN validates the smr_pkthdr_t of incoming packets * via a checksum, and calculates the checksum for outgoing packets. * Only the first 3 fields of smr_pkthdr_t are checksummed and * must be set to their expected values prior to calculating the * checksum. Turned OFF by default when compiled DEBUG. * * IDN_SMR_MAXSIZE (not tunable) * * The absolute maximum size of the SMR region that we'll allow. * Note that the virtual address space comes out kernelmap. */ #define IDN_AWOLMSG_INTERVAL 60 /* seconds */ #define IDN_MSGWAIT_NEGO 20 /* seconds */ #define IDN_MSGWAIT_CFG 40 #define IDN_MSGWAIT_CON 20 #define IDN_MSGWAIT_FIN 40 #define IDN_MSGWAIT_CMD 40 #define IDN_MSGWAIT_DATA 30 #define IDN_RETRYFREQ_NEGO 2 #define IDN_RETRYFREQ_CON 2 #define IDN_RETRYFREQ_FIN 3 #define IDN_SMR_BUFSIZE_MIN 512 #define IDN_SMR_BUFSIZE_MAX (512*1024) #define IDN_SMR_BUFSIZE_DEF (16*1024) #define IDN_SMR_SHIFT (16) #define IDN_SMR_ALIGN (1 << IDN_SMR_SHIFT) /* 64K */ #define IDN_SMR_SIZE idn_smr_size #define IDN_NWR_SIZE idn_nwr_size #define IDN_SMR_BUFSIZE idn_smr_bufsize #define IDN_DATA_SIZE (IDN_SMR_BUFSIZE \ - sizeof (smr_pkthdr_t) \ - IDN_ALIGNSIZE) #define IDN_MTU (IDN_DATA_SIZE - sizeof (struct ether_header)) #define IDN_WINDOW_MAX idn_window_max #define IDN_WINDOW_INCR idn_window_incr #define IDN_WINDOW_EMAX idn_window_emax #define IDN_RECLAIM_MIN idn_reclaim_min #define IDN_RECLAIM_MAX idn_reclaim_max #define IDN_MODUNLOADABLE idn_modunloadable #define IDN_LOWAT idn_lowat #define IDN_HIWAT idn_hiwat #define IDN_MBOX_PER_NET idn_mbox_per_net #define IDN_MAX_NETS idn_max_nets #define IDN_CHECKSUM idn_checksum #define IDN_SMR_MAXSIZE 96 #define _IDN_SMR_SIZE 32 /* 32M */ #define _IDN_NWR_SIZE _IDN_SMR_SIZE /* 32M */ #define _IDN_SMR_BUFSIZE (16 * 1024) /* 16K */ #define IDN_TUNEVAR_NAME(v) (*(char **)((ulong_t)&(v)+(sizeof (ulong_t)))) #define IDN_TUNEVAR_VALUE(v) (v) /* * History structure to support problem analysis. */ #define IDN_HISTORY_NUM 1024 #define IDN_HISTORY_LOG(op, d0, d1, d2) \ if (idn_history) { \ mutex_enter(&idnhlog.h_mutex); \ idnhlog.h_log[idnhlog.h_index].e_time = TIMESTAMP(); \ idnhlog.h_log[idnhlog.h_index].e_op = (ushort_t)(op); \ idnhlog.h_log[idnhlog.h_index].e_data[0] = (ushort_t)(d0); \ idnhlog.h_log[idnhlog.h_index].e_data[1] = (ushort_t)(d1); \ idnhlog.h_log[idnhlog.h_index].e_data[2] = (ushort_t)(d2); \ idnhlog.h_index++; \ idnhlog.h_index &= (IDN_HISTORY_NUM - 1); \ mutex_exit(&idnhlog.h_mutex); \ } #define IDNH_GSTATE 0x0001 /* d0=gstate, d1=, d2= */ #define IDNH_DSTATE 0x0002 /* d0=domid, d1=dstate, d2=cpuid */ #define IDNH_AWOL 0x0003 /* d0=domid, d1=dstate, d2=cpuid */ #define IDNH_MASTERID 0x0004 /* d0=masterid, d1=oldid, d2= */ #define IDNH_NEGO 0x0005 /* d0=domid, d1=ds_trans_on, d2=ds_connected */ #define IDNH_FIN 0x0006 /* d0=domid, d1=finstate, d2= */ #define IDNH_RELINK 0x0007 /* d0=domid, d1=dstate, d2=ds_relink */ struct idn_h_entry { hrtime_t e_time; ushort_t e_op; ushort_t e_data[3]; }; struct idn_history { kmutex_t h_mutex; int h_index; struct idn_h_entry h_log[IDN_HISTORY_NUM]; }; #endif /* _KERNEL */ /* * IDN_SIGBPIL - Interrupt level at which IDN driver * wakes up idn_sigbhandler_thread */ #define IDN_SIGBPIL PIL_3 /* * Definition of sigbintr.sb_busy values which * represents state of idn_sigbhandler. */ #define IDNSIGB_NOTREADY ((uchar_t)0) #define IDNSIGB_INACTIVE ((uchar_t)1) #define IDNSIGB_STARTED ((uchar_t)2) #define IDNSIGB_ACTIVE ((uchar_t)3) #define IDNSIGB_DIE ((uchar_t)4) /* * Some Xfire based macros that assume 4 cpus per board. */ #define CPUID_TO_BOARDID(c) ((c) >> 2) #define MAX_CPU_PER_BRD 4 #define CPUSET_TO_BOARDSET(cset, bset) \ { \ register int c, b; \ (bset) = 0; \ for (b = 0; b < MAX_BOARDS; b++) \ for (c = 0; c < MAX_CPU_PER_BRD; c++) \ if (CPU_IN_SET((cset), \ (b * MAX_CPU_PER_BRD) + c)) \ (bset) |= 1 << b; \ } /* * Macros to manipulate boardset and domainset masks. */ typedef ushort_t boardset_t; /* assumes max of 16 boards */ typedef ushort_t domainset_t; /* assumes max of 16 domains */ #define BOARDSET(brd) ((boardset_t)(1 << (brd))) #define BOARDSET_ALL ((boardset_t)~0) #define BOARD_IN_SET(set, brd) ((set) & BOARDSET(brd)) #define BOARDSET_ADD(set, brd) ((set) |= BOARDSET(brd)) #define BOARDSET_DEL(set, brd) ((set) &= ~BOARDSET(brd)) #define DOMAINSET(d) ((domainset_t)1 << (d)) #define DOMAINSET_ALL ((domainset_t)~0) #define DOMAIN_IN_SET(s, d) ((s) & DOMAINSET(d)) #define DOMAINSET_ADD(s, d) ((s) |= DOMAINSET(d)) #define DOMAINSET_DEL(s, d) ((s) &= ~DOMAINSET(d)) /* * PFN_TO_SMADDR macro converts a PFN to a IDN_SMR_ALIGN'ed * address suitable for the CIC bar/lar registers. */ #if (IDN_SMR_SHIFT <= MMU_PAGESHIFT) #define PFN_TO_SMADDR(pfn) ((pfn) << (MMU_PAGESHIFT - IDN_SMR_SHIFT)) #else #define PFN_TO_SMADDR(pfn) ((pfn) >> (IDN_SMR_SHIFT - MMU_PAGESHIFT)) #endif /* * Translate a physical address to a unique domain identifier. * IMPORTANT - Assumes each board's memory is configured on a 8GB * boundary. PA(8G) = PFN(1M). */ #define MEM8G_SHIFT 33 /* (1 << 33) == 8G */ #define PADDR_TO_DOMAINID(paddr) ((int)((paddr) >> MEM8G_SHIFT) & 0xf) #define VALID_NWROFFSET(off, align) \ (((uint_t)(off) >= 0) && \ ((size_t)(off) < MB2B(IDN_NWR_SIZE)) && \ !((uint_t)(off) & ((align) - 1))) #define VALID_NWRADDR(addr, align) \ (((caddr_t)(addr) >= idn.smr.vaddr) && \ VALID_NWROFFSET(((caddr_t)(addr) - idn.smr.vaddr), (align))) #define VALID_DOMAINID(d) (((d) >= 0) && ((d) < MAX_DOMAINS)) #define VALID_UDOMAINID(d) ((d) < MAX_DOMAINS) #define VALID_CPUID(c) (((c) >= 0) && ((c) < NCPU)) #define VALID_CHANNEL(c) (((c) >= 0) && ((c) < IDN_MAX_NETS)) #define VALID_UCHANNEL(c) ((c) < IDN_MAX_NETS) /* * The following are bit values of idn_debug, currently * only useful if compiled with DEBUG. */ #ifdef DEBUG #define STRING(sss) char sss[20] #define INUM2STR(mm, ss) inum2str((mm), (ss)) #define IDNDBG_XDC 0x00000001 #define IDNDBG_XF 0x00000002 #define IDNDBG_REGS 0x00000004 #define IDNDBG_SMR 0x00000008 #define IDNDBG_PROTO 0x00000010 #define IDNDBG_STR 0x00000020 #define IDNDBG_DRV 0x00000040 #define IDNDBG_DATA 0x00000080 #define IDNDBG_STATE 0x00000100 #define IDNDBG_DLPI 0x00000200 #define IDNDBG_KERN 0x00000400 #define IDNDBG_ALLOC 0x00000800 #define IDNDBG_REMAP 0x00001000 #define IDNDBG_TIMER 0x00002000 #define IDNDBG_CHAN 0x00004000 #define IDNDBG_AWOL 0x00008000 #define IDNDBG_SYNC 0x00010000 #define _IDNDBG_UNUSED0 0x00020000 #define IDNDBG_HITLIST 0x00040000 #define IDNDBG_XMON 0x00080000 #define IDNDBG_TEST 0x80000000 #define IDNDBG_ALL ((uint_t)-1) #define PR_ALL if (idn_debug) printf #define PR_XDC if (idn_debug & IDNDBG_XDC) printf #define PR_XF if (idn_debug & IDNDBG_XF) printf #define PR_REGS if (idn_debug & IDNDBG_REGS) printf #define PR_SMR if (idn_debug & IDNDBG_SMR) printf #define PR_PROTO if (idn_debug & IDNDBG_PROTO) printf #define PR_STR if (idn_debug & IDNDBG_STR) printf #define PR_DRV if (idn_debug & IDNDBG_DRV) printf #define PR_DATA if (idn_debug & IDNDBG_DATA) printf #define PR_STATE if (idn_debug & IDNDBG_STATE) printf #define PR_DLPI if (idn_debug & IDNDBG_DLPI) printf #define PR_KERN if (idn_debug & IDNDBG_KERN) printf #define PR_ALLOC if (idn_debug & IDNDBG_ALLOC) printf #define PR_REMAP if (idn_debug & (IDNDBG_SMR|IDNDBG_REMAP)) printf #define PR_TIMER if (idn_debug & IDNDBG_TIMER) printf #define PR_CHAN if (idn_debug & IDNDBG_CHAN) printf #define PR_AWOL if (idn_debug & (IDNDBG_PROTO|IDNDBG_AWOL)) printf #define PR_SYNC if (idn_debug & IDNDBG_SYNC) printf #define _PR_UNUSED0 if (idn_debug & _IDNDBG_UNUSED0) printf #define PR_HITLIST if (idn_debug & IDNDBG_HITLIST) printf #define PR_XMON if (idn_debug & IDNDBG_XMON) printf #define PR_TEST if (idn_debug & IDNDBG_TEST) printf #else #define STRING(sss) char *sss = "" #define INUM2STR(mm, ss) #define PR_ALL if (0) printf #define PR_XDC PR_ALL #define PR_XF PR_ALL #define PR_REGS PR_ALL #define PR_SMR PR_ALL #define PR_PROTO PR_ALL #define PR_STR PR_ALL #define PR_DRV PR_ALL #define PR_DATA PR_ALL #define PR_STATE PR_ALL #define PR_DLPI PR_ALL #define PR_KERN PR_ALL #define PR_ALLOC PR_ALL #define PR_REMAP PR_ALL #define PR_TIMER PR_ALL #define PR_CHAN PR_ALL #define PR_AWOL PR_ALL #define PR_SYNC PR_ALL #define PR_SNOOP PR_ALL #define PR_HITLIST PR_ALL #define PR_XMON PR_ALL #define PR_TEST PR_ALL #endif /* DEBUG */ #ifdef _KERNEL /* * IDN drivers fields. * * IDNMINPSZ Minimum packet size the IDN supports. * * IDNMAXPSZ Maximum packet size that IDN supports from upper * layers. Is equal to IDN_MTU + ether_header. Note * that the IDN driver could support larger packets * however the infrastructure to support fragmentation * does not (and should not) exist with respect to * ethernet packet types. */ #ifdef DEBUG #define IDNDESC "Inter-Domain Network (DEBUG)" #else #define IDNDESC "Inter-Domain Network" #endif /* DEBUG */ #define IDNIDNUM 8264 #define IDNNAME "idn" #define IDNMINPSZ 0 /* set at idnopen() */ #define IDNMAXPSZ 0 /* set at idnopen() */ #endif /* _KERNEL */ /* * IDN Global States. */ typedef enum { /* 0 */ IDNGS_OFFLINE = 0, /* idle */ /* 1 */ IDNGS_CONNECT, /* connecting initial domain */ /* 2 */ IDNGS_ONLINE, /* master selected */ /* 3 */ IDNGS_DISCONNECT, /* local is unlinking */ /* 4 */ IDNGS_RECONFIG, /* selecting new master */ /* 5 */ _IDNGS_UNUNSED5, /* 6 */ _IDNGS_UNUNSED6, /* 7 */ _IDNGS_UNUNSED7, /* 8 */ _IDNGS_UNUNSED8, /* 9 */ _IDNGS_UNUNSED9, /* 10 */ IDNGS_IGNORE /* ignore requests (fault injection) */ } idn_gstate_t; #ifdef _KERNEL #define TIMESTAMP() (gethrtime() / 1000000ull) /* * Spaced defined in: * sigblkp[cpu0.cpu_id]->sigb_idn.reserved1. */ #define IDNSB_GSTATE_NEW 0 #define IDNSB_GSTATE_OLD 1 #define IDNSB_MASTERCPU 2 #define IDNSB_RESERVED 3 #define IDNSB_HWCHKPT_MAX 4 #define IDNSB_SIZE 72 /* * This structure gets overlay onto: * sigblkp[cpu0.cpu_id]->sigb_idn.reserved1. * * This structure must be exactly IDNSB_SIZE bytes. */ typedef struct idnsb { uchar_t id_gstate; uchar_t id_pgstate; uchar_t id_master_board; uchar_t id_pmaster_board; uchar_t reserved_DO_NOT_USE[24]; /* idnevent_t field */ struct { uchar_t d_board; uchar_t d_state; } id_status[MAX_DOMAINS]; uint_t id_hwstate; ushort_t id_hwchkpt[IDNSB_HWCHKPT_MAX]; } idnsb_t; /* sizeof = 72 (0x48) 18X bytes */ #define IDNSB_DOMAIN_UPDATE(dp) \ { \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ int domid = (dp)->domid; \ if ((dp)->dcpu == IDN_NIL_DCPU) \ idn.idnsb->id_status[domid].d_board = \ (uchar_t)0xff; \ else if ((dp)->dvote.v.board == 0) \ idn.idnsb->id_status[domid].d_board = \ (uchar_t)CPUID_TO_BOARDID((dp)->dcpu); \ else \ idn.idnsb->id_status[domid].d_board = \ (uchar_t)(dp)->dvote.v.board; \ idn.idnsb->id_status[domid].d_state = \ (uchar_t)(dp)->dstate; \ } \ mutex_exit(&idn.idnsb_mutex); \ } /* * The following definitions and macros pertain to the * id_hwstate and id_hwchkpt[] fields. * * id_hwstate (m = mark: 1=open, 2=close) * 0 1 2 3 4 5 6 7 * --------------------------------- * | m | m | m | m | XX unused XXX | * --------------------------------- * | | | | * | | | +- CACHE * | | +- CHAN * | +- LINK * +- SMR * * Note that nibble 4 is used in DEBUG for noting cache * flush progress through idnxf_flushall_ecache(). This * will override id_hwchkpt[] since it only has room for * 4 items, however the BBSRAM space is there and * unofficially available :-o * * id_hwchkpt[0] = SMR boardset * id_hwchkpt[1] = LINK boardset * id_hwchkpt[2] = CHAN boardset * id_hwchkpt[3] = CACHE boardset. */ #define IDNSB_CHKPT_SMR 0 #define IDNSB_CHKPT_LINK 1 #define IDNSB_CHKPT_CHAN 2 #define IDNSB_CHKPT_CACHE 3 #define IDNSB_CHKPT_UNUSED 4 /* This is the max you can have */ #define _CHKPT_MARKIT(item, mark) \ { \ uint_t mk = (((uint_t)((mark) & 0xf)) << \ (((sizeof (uint_t) << 1) - 1 - (item)) << 2)); \ uint_t *sp = &idn.idnsb->id_hwstate; \ ASSERT(idn.idnsb); \ *sp &= ~(((uint_t)0xf) << (((sizeof (uint_t) << 1) \ - 1 - (item)) << 2)); \ *sp |= mk; \ } #define CHECKPOINT_OPENED(item, bset, mark) \ { \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ ushort_t *sp = &idn.idnsb->id_hwchkpt[0]; \ _CHKPT_MARKIT((item), (mark)); \ sp[item] |= ((ushort_t)(bset)); \ } \ mutex_exit(&idn.idnsb_mutex); \ } #define CHECKPOINT_CLOSED(item, bset, mark) \ { \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ ushort_t *sp = &idn.idnsb->id_hwchkpt[0]; \ _CHKPT_MARKIT((item), (mark)); \ sp[item] &= (ushort_t)~(bset); \ } \ mutex_exit(&idn.idnsb_mutex); \ } #define CHECKPOINT_CLEAR(item, mark) \ { \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ ushort_t *sp = &idn.idnsb->id_hwchkpt[0]; \ _CHKPT_MARKIT((item), (mark)); \ sp[item] = 0; \ } \ mutex_exit(&idn.idnsb_mutex); \ } #ifdef DEBUG #define CHECKPOINT_CACHE_CLEAR_DEBUG(mark) \ CHECKPOINT_CLEAR(IDNSB_CHKPT_UNUSED, (mark)) #define CHECKPOINT_CACHE_STEP_DEBUG(bset, mark) \ CHECKPOINT_OPENED(IDNSB_CHKPT_UNUSED, (bset), (mark)) #else #define CHECKPOINT_CACHE_CLEAR_DEBUG(mark) #define CHECKPOINT_CACHE_STEP_DEBUG(bset, mark) #endif /* DEBUG */ #ifdef DEBUG #define IDN_GSTATE_TRANSITION(ns) \ { \ hrtime_t tstamp; \ /*LINTED*/ \ IDN_HISTORY_LOG(IDNH_GSTATE, (ns), 0, 0); \ tstamp = TIMESTAMP(); \ ASSERT(IDN_GLOCK_IS_EXCL()); \ PR_STATE("GSTATE:%ld: (l=%d) %s(%d) -> %s(%d)\n", \ (uint64_t)tstamp, __LINE__, \ idngs_str[idn.state], idn.state, \ idngs_str[ns], (ns)); \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ idn.idnsb->id_pgstate = (uchar_t)idn.state; \ idn.idnsb->id_gstate = (uchar_t)(ns); \ } \ mutex_exit(&idn.idnsb_mutex); \ idn.state = (ns); \ } #else #define IDN_GSTATE_TRANSITION(ns) \ { \ IDN_HISTORY_LOG(IDNH_GSTATE, (ns), 0, 0); \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ idn.idnsb->id_pgstate = (uchar_t)idn.state; \ idn.idnsb->id_gstate = (uchar_t)(ns); \ } \ mutex_exit(&idn.idnsb_mutex); \ idn.state = (ns); \ } #endif /* DEBUG */ /* * IDN link/unlink operations occur asynchronously with respect to the * caller. The following definitions are to support the return of * success/failure back to the original requesting thread. It's * unlikely to have multiple outstanding link/unlink requests so we * just provide a very small cache of waiting list entries. If the * cache becomes exhausted then additional ones are kmem_alloc'd. */ #define IDNOP_CACHE_SIZE 3 #define IDNOP_IN_CACHE(dwl) \ (((dwl) >= &idn.dopers->_dop_wcache[0]) && \ ((dwl) < &idn.dopers->_dop_wcache[IDNOP_CACHE_SIZE])) typedef struct dop_waitlist { struct dop_waitlist *dw_next; domainset_t dw_reqset; domainset_t dw_domset; short dw_op; domainset_t dw_errset; idnsb_error_t *dw_idnerr; short dw_errors[MAX_DOMAINS]; } dop_waitlist_t; typedef uint_t idn_xdcargs_t[4]; typedef uint_t idn_chanset_t; /* * Types of synchronization zones which a connection * could be in. */ typedef enum { IDNSYNC_NIL, IDNSYNC_CONNECT, IDNSYNC_DISCONNECT } idn_synccmd_t; /* * Type of sync-registration that is being requested. */ typedef enum { IDNSYNC_REG_REG, IDNSYNC_REG_NEW, IDNSYNC_REG_QUERY } idn_syncreg_t; #define IDN_SYNC_NUMZONE 3 #define IDN_SYNC_GETZONE(s) ((((s) != IDNSYNC_CONNECT) && \ ((s) != IDNSYNC_DISCONNECT)) ? \ -1 : (int)(s) - 1) #define IDN_SYNC_GETTRANS(s) (((s) == IDNSYNC_CONNECT) ? \ idn.domset.ds_trans_on : \ ((s) == IDNSYNC_DISCONNECT) ? \ idn.domset.ds_trans_off : 0) /* * Generic states when in a state transition region. * These ultimately map to domain states via * a idn_xphase_t definition. General model: * * PEND * /\ * / \ * | | * V V * SENT--->RCVD * \ / * \ / * VV * FINAL * * Start these types with PEND = 0 so that they're * compatible with idnxs_state_table[] and idn_xphase_t * phases that use the value as an index. */ typedef enum { /* 0 */ IDNXS_PEND = 0, /* 1 */ IDNXS_SENT, /* 2 */ IDNXS_RCVD, /* 3 */ IDNXS_FINAL, /* 4 */ IDNXS_NIL } idn_xstate_t; /* * Locking protocol: * * Each routine is called with SYNC_LOCK and * the respective domain's DLOCK(EXCL) held. * The routines must return with these locks * still held. */ struct idn_msgtype; typedef struct { int t_state; int (*t_check)(int domid, struct idn_msgtype *mtp, idn_xdcargs_t xargs); void (*t_action)(int domid, struct idn_msgtype *mtp, idn_xdcargs_t xargs); void (*t_error)(int domid, struct idn_msgtype *mtp, idn_xdcargs_t xargs); } idn_trans_t; /* * The callback routines (xt_final & xt_exit) are called with * DLOCK and SYNC_LOCK held and they are required to return * with these locks still held. */ typedef struct { uint_t xt_msgtype; idn_trans_t xt_trans[4]; void (*xt_final)(int domid); void (*xt_exit)(int domid, uint_t msgtype); } idn_xphase_t; /* * Synchronization entry representing the synchronization * state with respect to a given domain for a given zone. */ typedef struct idn_syncop { struct idn_syncop *s_next; int s_domid; idn_synccmd_t s_cmd; int s_msg; domainset_t s_set_exp; domainset_t s_set_rdy; int (*s_transfunc)(int domid, void *arg); void *s_transarg; #ifdef DEBUG int s_query[MAX_DOMAINS]; #endif /* DEBUG */ } idn_syncop_t; #ifdef DEBUG #define IDN_SYNC_QUERY_INIT(d) \ (bzero((caddr_t)idn_domain[d].dsync.s_query, \ sizeof (idn_domain[d].dsync.s_query))) #define IDN_SYNC_QUERY_UPDATE(md, sd) (idn_domain[md].dsync.s_query[sd]++) #else /* DEBUG */ #define IDN_SYNC_QUERY_INIT(d) #define IDN_SYNC_QUERY_UPDATE(md, sd) #endif /* DEBUG */ typedef struct { idn_syncop_t *sc_op; int sc_cnt; } idn_synczone_t; #endif /* _KERNEL */ /* * Vote Ticket used during negotiations and elections. * * 31 0 * ----------------------------------------- * |m...|....|pppp|....|Cbbb|bccc|cccB|BBB1| * ----------------------------------------- * m [31] = master/slave * . [30:24] = unused * p [23:20] = priority * . [19:16] = unused * C [15] = connected (has master) * b [14:11] = nmembrds-1 * c [10:5] = ncpus-1 * B [4:1] = board_id * 1 [0] = one */ typedef union { struct { uint_t master :1; uint_t unused0 :7; uint_t priority :4; uint_t unused1 :4; uint_t connected :1; uint_t nmembrds :4; uint_t ncpus :6; uint_t board :4; uint_t one :1; } v; uint_t ticket; } idn_vote_t; #define IDNVOTE_PRI_MASK 0xf #define IDNVOTE_MAXPRI 0xf #define IDNVOTE_MINPRI 0 #define IDNVOTE_DEFPRI 1 /* must be larger than MINPRI */ /* * Initially: * vote.v.priority = IDNVOTE_DEFPRI * vote.v.one = 1 */ #define IDNVOTE_INITIAL_TICKET ((IDNVOTE_DEFPRI << 20) | 1) #define IDNVOTE_PRIVALUE(vvv) \ ((int)vvv.v.priority + ((int)vvv.v.master ? IDNVOTE_MAXPRI : 0)) /* * During elections we only use the "elect" attributes of the * election ticket, i.e. those physical attributes pertaining * to the individual domain (priority, nboards, ncpus, board). */ #define IDNVOTE_ELECT_MASK 0x00f07fff #define IDNVOTE_ELECT(tkt) ((tkt).ticket & IDNVOTE_ELECT_MASK) #define IDNVOTE_BASICS_MASK 0x00f0ffff #define IDNVOTE_BASICS(tkt) ((tkt).ticket & IDNVOTE_BASICS_MASK) /* * Values used in idn_select_master(). */ #define MASTER_IS_NONE 0 /* index into master_select_table */ #define MASTER_IS_OTHER 1 #define MASTER_IS_LOCAL 2 #define MASTER_IS_REMOTE 3 typedef enum { MASTER_SELECT_VOTE, MASTER_SELECT_VOTE_RCFG, MASTER_SELECT_CONNECT, MASTER_SELECT_REMOTE, MASTER_SELECT_LOCAL, MASTER_SELECT_WAIT, MASTER_SELECT_ERROR } idn_master_select_t; /* * Used to synchronize completion of link/unlink with respect to * the original requester (user). Necessary since link establishment * occurs asynchronously. */ typedef enum { /* 0 */ IDNOP_DISCONNECTED, /* successfully disconnected */ /* 1 */ IDNOP_CONNECTED, /* successfully established */ /* 2 */ IDNOP_ERROR /* error trying to link/unlink */ } idn_opflag_t; /* * IDN Protocol Messages. * These are IDN version (IDN_VERSION) dependent. * * ----- 7, --- 6,5.................0 * | ack | nack | IDN message type | * ---------------------------------- */ #define IDN_VERSION 1 /* * Must be no more than 6-bits. See DMV private data. */ #define IDNP_ACK 0x20 #define IDNP_NACK 0x10 #define IDNP_NULL 0x00 #define IDNP_NEGO 0x01 #define IDNP_CON 0x02 #define IDNP_CFG 0x03 #define IDNP_FIN 0x04 #define IDNP_CMD 0x05 #define IDNP_DATA 0x06 #define IDN_NUM_MSGTYPES 7 #define IDNP_ACKNACK_MASK (IDNP_ACK | IDNP_NACK) #define IDNP_MSGTYPE_MASK 0x0f #define VALID_MSGTYPE(m) (((m) >= IDNP_NEGO) && ((m) < IDN_NUM_MSGTYPES)) typedef struct idn_msgtype { ushort_t mt_mtype; ushort_t mt_atype; ushort_t mt_cookie; } idn_msgtype_t; /* * IDN private data section of DMV layout (48 bits). * * 47......40,39.....34,33.....28,27..24,23......16,15..............0 * | version | msgtype | acktype | did | cpuid | cookie | * ------------------------------------------------------------------ * * version Local domain's version of IDN software. * msgtype Type of IDN message, e.g. nego, syn, etc. * acktype If msgtype is a ACK or NACK, then acktype is the * type of ack that we're receiving, e.g. ack/nego|ack. * did Local domain's ID (netid) - system-wide unique. * cpuid Local domain's CPU->cpu_id that sending message. * cookie Cookie assigned by remote domain for authentication. * For NEGO & NEGO+ACK messages, it's the cookie that * the sender expects the receiver to use in subsequent * messages. The upper-eight bits represent a timer * cookie to associate timers with expected messages. */ #endif /* !_ASM */ #ifdef _KERNEL #define _IDNPD_COOKIE_MASK 0xffff #define _IDNPD_COOKIE_SHIFT 32 #define _IDNPD_VER_MASK 0xff #define _IDNPD_VER_SHIFT 24 #define _IDNPD_MTYPE_MASK 0x3f #define _IDNPD_MTYPE_SHIFT 18 #define _IDNPD_ATYPE_MASK 0x3f #define _IDNPD_ATYPE_SHIFT 12 #define _IDNPD_DOMID_MASK 0xf #define _IDNPD_DOMID_SHIFT 8 #define _IDNPD_CPUID_MASK 0xff #define _IDNPD_CPUID_SHIFT 0 #define _IDNPD_COOKIE_LEN 16 #ifndef _ASM #define IDN_PD2COOKIE(pdata) \ (((uint_t)((pdata) >> _IDNPD_COOKIE_SHIFT)) & _IDNPD_COOKIE_MASK) #define IDN_PD2VER(pdata) \ (((uint_t)((pdata) >> _IDNPD_VER_SHIFT)) & _IDNPD_VER_MASK) #define IDN_PD2MTYPE(pdata) \ (((uint_t)((pdata) >> _IDNPD_MTYPE_SHIFT)) & _IDNPD_MTYPE_MASK) #define IDN_PD2ATYPE(pdata) \ (((uint_t)((pdata) >> _IDNPD_ATYPE_SHIFT)) & _IDNPD_ATYPE_MASK) #define IDN_PD2DOMID(pdata) \ (((uint_t)((pdata) >> _IDNPD_DOMID_SHIFT)) & _IDNPD_DOMID_MASK) #define IDN_PD2CPUID(pdata) \ (((uint_t)((pdata) >> _IDNPD_CPUID_SHIFT)) & _IDNPD_CPUID_MASK) #define IDN_MAKE_PDATA(mtype, atype, cookie) \ ((((uint64_t)(cookie) & UINT64_C(_IDNPD_COOKIE_MASK)) << \ _IDNPD_COOKIE_SHIFT) | \ (((uint64_t)idn.version & UINT64_C(_IDNPD_VER_MASK)) << \ _IDNPD_VER_SHIFT) | \ (((uint64_t)(mtype) & UINT64_C(_IDNPD_MTYPE_MASK)) << \ _IDNPD_MTYPE_SHIFT) | \ (((uint64_t)(atype) & UINT64_C(_IDNPD_ATYPE_MASK)) << \ _IDNPD_ATYPE_SHIFT) | \ (((uint64_t)idn.localid & UINT64_C(_IDNPD_DOMID_MASK)) << \ _IDNPD_DOMID_SHIFT) | \ (((uint64_t)CPU->cpu_id & UINT64_C(_IDNPD_CPUID_MASK)) << \ _IDNPD_CPUID_SHIFT)) #define IDN_TCOOKIE(ck) (((ck) >> 8) & 0xff) #define IDN_DCOOKIE(ck) ((ck) & 0xff) #define IDN_MAKE_COOKIE(d, t) ((((t) & 0xff) << 8) | ((d) & 0xff)) /* * IDNP_NEGO * * 127........96,95........64,63........32,31.........0 * | vote | domainset | * ---------------------------------------------------- * vote Local/Remote domain's vote ticket. * domainset Mask of cpuids of domains to which * sender is connected. Position in domainset * designates respective domainid. * E.g. domainset[6] = 20 -> domainid 6 is * accessible via cpuid 20. * The slot for the receiving domain * contains the masterid of the sending * domain. If the sending domain does * not have a master then the entry will * contain IDNNEG_NO_MASTER. * * These macros insert a domainid-cpuid pair into the * domainset to be subsequently passed in a NEGO message, * also retrieve the cpuid from the domainset for a * given domainid. * * Usage: * Sending: * mask = IDNNEG_DSET_MYMASK(); * IDNNEG_DSET_INIT(dset, mask) * for (all domains except self) * IDNNEG_DSET_SET(dset, domain, cpuid, mask); * * Receiving: * IDNNEG_DSET_GET_MASK(dset, recv_domid, recv_mask); * for (all domains except recv_domid) * IDNNEG_DSET_GET(dset, domid, cpuid, recv_mask); */ typedef uint_t idnneg_dset_t[3]; #define IDNNEG_NO_MASTER 0x3f #define __IDNNEG_DSET_CLEAR(dset) (bzero((caddr_t)(dset), \ sizeof (idnneg_dset_t))) #define IDNNEG_DSET_MYMASK() (idn_domain[idn.localid].dcpu) #define IDNNEG_DSET_INIT(dset, mask) \ { \ __IDNNEG_DSET_CLEAR(dset); \ IDNNEG_DSET_SET((dset), idn.localid, (mask), idn.localid); \ } #define IDNNEG_DSET_SET(dset, domid, cpuid, mask) \ { \ uint_t _s = ((domid) & 0xf) * 6; \ int _i = _s >> 5; \ uint_t _s0 = _s & 0x1f; \ uint_t _t = ((cpuid) ^ (mask)) & 0x3f; \ /*LINTED*/ \ ASSERT(((domid) == idn.localid) ? \ ((mask) == idn.localid) : ((cpuid) != (mask))); \ (dset)[_i] |= _t << _s0; \ if ((_s0 + 6) > 32) \ (dset)[_i + 1] |= _t >> (32 - _s0); \ } #define __IDNNEG_DSET_GET(dset, domid, cpuid, mask, uncond) \ { \ uint_t _s = ((domid) & 0xf) * 6; \ int _i = _s >> 5; \ uint_t _s0 = _s & 0x1f; \ uint_t _s1 = (_s + 6) & 0x1f; \ (cpuid) = ((dset)[_i] >> _s0) & 0x3f; \ if ((_s0 + 6) > 32) \ (cpuid) |= ((dset)[_i + 1] << (6 - _s1)) & 0x3f; \ if ((cpuid) || (uncond)) \ (cpuid) ^= (mask) & 0x3f; \ else \ (cpuid) = -1; \ } #define IDNNEG_DSET_GET_MASK(dset, domid, mask) \ __IDNNEG_DSET_GET((dset), (domid), (mask), (domid), 1) #define IDNNEG_DSET_GET_MASTER(dset, master) \ __IDNNEG_DSET_GET((dset), idn.localid, (master), \ idn.localid+MAX_DOMAINS, 0) #define IDNNEG_DSET_SET_MASTER(dset, domid, master) \ IDNNEG_DSET_SET((dset), (domid), (master), \ (domid)+MAX_DOMAINS) #define IDNNEG_DSET_GET(dset, domid, cpuid, mask) \ __IDNNEG_DSET_GET((dset), (domid), (cpuid), (mask), 0) /* * IDNP_CFG sub-types. * * Format of first 32 bit word in XDC: * stX = sub-type. * staX = sub-type arg. * X = position in idn_cfgsubtype_t.param.p[] array. * num = number of parameters in this XDC (0-3) * * 31...28,27...24,23...20,19...16,15...12,11....8,7.....3,2....0 * | st0 . sta0 | st1 . sta1 | st2 . sta2 | phase | num | * -------------------------------------------------------------- * * Note that since the first 32-bit word in a (IDNP_CFG) XDC is used * for a sub-type, subsequent three 32-bits words are used for data that * pertains to respective sub-type, i.e. first sub-type corresponds * to first of the 3x32-bit words (pos=0), second sub-type corresponds * to second of the 3x32-bit words (pos=1), etc. Obviously, a max of * only three sub-types can be sent per xdc. */ #define IDNCFG_BARLAR 0x1 /* SMR base/limit pfn */ #define IDNCFGARG_BARLAR_BAR 0 /* BAR */ #define IDNCFGARG_BARLAR_LAR 1 /* LAR */ #define IDNCFG_MCADR 0x2 /* MC ADR, arg = board number */ #define IDNCFG_NMCADR 0x3 /* Number of MC ADRs to expect */ #define IDNCFG_CPUSET 0x4 /* dcpuset of remote domain */ #define IDNCFGARG_CPUSET_UPPER 0 /* 1st word */ #define IDNCFGARG_CPUSET_LOWER 1 /* 2nd word */ #define IDNCFG_NETID 0x5 /* dnetid, arg = 0 */ #define IDNCFG_BOARDSET 0x6 /* board set, arg = 0 */ #define IDNCFG_SIZE 0x7 /* SMR size parameters */ #define IDNCFGARG_SIZE_MTU 0 /* IDN_MTU */ #define IDNCFGARG_SIZE_BUF 1 /* IDN_SMR_BUFSIZE */ #define IDNCFGARG_SIZE_SLAB 2 /* IDN_SLAB_BUFCOUNT */ #define IDNCFGARG_SIZE_NWR 3 /* IDN_NWR_SIZE */ #define IDNCFG_DATAMBOX 0x8 /* SMR data mailbox info */ #define IDNCFGARG_DATAMBOX_TABLE 0 /* recvmbox table */ #define IDNCFGARG_DATAMBOX_DOMAIN 1 /* domain's recvmbox */ #define IDNCFGARG_DATAMBOX_INDEX 2 /* domain's index into table */ #define IDNCFG_DATASVR 0x9 /* Data server info */ #define IDNCFGARG_DATASVR_MAXNETS 0 /* max # of nets/channels */ #define IDNCFGARG_DATASVR_MBXPERNET 1 /* # mbox per net/channel */ #define IDNCFG_OPTIONS 0xa /* various options */ #define IDNCFGARG_CHECKSUM 0 /* IDN_CHECKSUM */ #define IDN_CFGPARAM(st, sta) ((uchar_t)((((st) & 0xf) << 4) | ((sta) & 0xf))) #define IDN_CFGPARAM_TYPE(p) (((p) >> 4) & 0xf) #define IDN_CFGPARAM_ARG(p) ((p) & 0xf) typedef union { struct { uchar_t p[3]; uchar_t _num_phase; /* info.num, info.phase used instead */ } param; struct { uint_t _p : 24; /* param.p[] used instead */ uint_t num : 2; uint_t phase : 6; } info; uint_t val; } idn_cfgsubtype_t; /* * IDN_MASTER_NCFGITEMS * Minimum number of config items expected from master. * * IDN_SLAVE_NCFGITEMS * Number of config items expected from slave. */ #define IDN_MASTER_NCFGITEMS 17 /* max = +14 (mcadrs) */ #define IDN_SLAVE_NCFGITEMS 12 /* * IDNP_CMD sub-types. */ typedef enum { /* 1 */ IDNCMD_SLABALLOC = 1, /* Request to allocate a slab */ /* 2 */ IDNCMD_SLABFREE, /* Request to free a slab */ /* 3 */ IDNCMD_SLABREAP, /* Reap any free slabs */ /* 4 */ IDNCMD_NODENAME /* Query nodename of domain */ } idn_cmd_t; #define VALID_IDNCMD(c) (((int)(c) >= (int)IDNCMD_SLABALLOC) && \ ((int)(c) <= (int)IDNCMD_NODENAME)) /* * IDNP_NACK */ typedef enum { /* 1 */ IDNNACK_NOCONN = 1, /* 2 */ IDNNACK_BADCHAN, /* 3 */ IDNNACK_BADCFG, /* 4 */ IDNNACK_BADCMD, /* 5 */ IDNNACK_RETRY, /* 6 */ IDNNACK_DUP, /* 7 */ IDNNACK_EXIT, /* 8 */ IDNNACK_RESERVED1, /* 9 */ IDNNACK_RESERVED2, /* 10 */ IDNNACK_RESERVED3 } idn_nack_t; /* * IDNP_CON sub-types. */ typedef enum { /* 0 */ IDNCON_OFF = 0, /* 1 */ IDNCON_NORMAL, /* regular connect sequence */ /* 2 */ IDNCON_QUERY /* query for connect info */ } idn_con_t; /* * IDNP_FIN sub-types. */ typedef enum { /* 0 */ IDNFIN_OFF = 0, /* active, no fin */ /* 1 */ IDNFIN_NORMAL, /* normal disconnect req */ /* 2 */ IDNFIN_FORCE_SOFT, /* normal dis, force if goes AWOL */ /* 3 */ IDNFIN_FORCE_HARD, /* force disconnect of AWOL domain */ /* 4 */ IDNFIN_QUERY /* query for fin info */ } idn_fin_t; #define VALID_FIN(f) (((int)(f) > 0) && \ ((int)(f) < (int)IDNFIN_QUERY)) #define FIN_IS_FORCE(f) (((f) == IDNFIN_FORCE_SOFT) || \ ((f) == IDNFIN_FORCE_HARD)) /* * FIN ARG types - reasons a FIN was sent. */ typedef enum { /* 0 */ IDNFIN_ARG_NONE = 0, /* no argument */ /* 1 */ IDNFIN_ARG_SMRBAD, /* SMR is corrupted */ /* 2 */ IDNFIN_ARG_CPUCFG, /* missing cpu per board */ /* 3 */ IDNFIN_ARG_HWERR, /* error programming hardware */ /* 4 */ IDNFIN_ARG_CFGERR_FATAL, /* Fatal error during CONFIG */ /* 5 */ IDNFIN_ARG_CFGERR_MTU, /* MTU sizes conflict */ /* 6 */ IDNFIN_ARG_CFGERR_BUF, /* SMR_BUF_SIZE conflicts */ /* 7 */ IDNFIN_ARG_CFGERR_SLAB, /* SLAB sizes conflict */ /* 8 */ IDNFIN_ARG_CFGERR_NWR, /* NWR sizes conflict */ /* 9 */ IDNFIN_ARG_CFGERR_NETS, /* MAX_NETS conflict */ /* 10 */ IDNFIN_ARG_CFGERR_MBOX, /* MBOX_PER_NET conflict */ /* 11 */ IDNFIN_ARG_CFGERR_NMCADR, /* NMCADR mismatches actual */ /* 12 */ IDNFIN_ARG_CFGERR_MCADR, /* missing some MCADRs */ /* 13 */ IDNFIN_ARG_CFGERR_CKSUM, /* checksum settings conflict */ /* 14 */ IDNFIN_ARG_CFGERR_SMR /* SMR sizes conflict */ } idn_finarg_t; #define IDNFIN_ARG_IS_FATAL(fa) ((fa) > IDNFIN_ARG_NONE) #define SET_FIN_TYPE(x, t) \ ((x) &= 0xffff, (x) |= (((uint_t)(t) & 0xffff) << 16)) #define SET_FIN_ARG(x, a) \ ((x) &= ~0xffff, (x) |= ((uint_t)(a) & 0xffff)) #define GET_FIN_TYPE(x) ((idn_fin_t)(((x) >> 16) & 0xffff)) #define GET_FIN_ARG(x) ((idn_finarg_t)((x) & 0xffff)) #define FINARG2IDNKERR(fa) \ (((fa) == IDNFIN_ARG_SMRBAD) ? IDNKERR_SMR_CORRUPTED : \ ((fa) == IDNFIN_ARG_CPUCFG) ? IDNKERR_CPU_CONFIG : \ ((fa) == IDNFIN_ARG_HWERR) ? IDNKERR_HW_ERROR : \ ((fa) == IDNFIN_ARG_CFGERR_FATAL) ? IDNKERR_HW_ERROR : \ ((fa) == IDNFIN_ARG_CFGERR_MTU) ? IDNKERR_CONFIG_MTU : \ ((fa) == IDNFIN_ARG_CFGERR_BUF) ? IDNKERR_CONFIG_BUF : \ ((fa) == IDNFIN_ARG_CFGERR_SLAB) ? IDNKERR_CONFIG_SLAB : \ ((fa) == IDNFIN_ARG_CFGERR_NWR) ? IDNKERR_CONFIG_NWR : \ ((fa) == IDNFIN_ARG_CFGERR_NETS) ? IDNKERR_CONFIG_NETS : \ ((fa) == IDNFIN_ARG_CFGERR_MBOX) ? IDNKERR_CONFIG_MBOX : \ ((fa) == IDNFIN_ARG_CFGERR_NMCADR) ? IDNKERR_CONFIG_NMCADR : \ ((fa) == IDNFIN_ARG_CFGERR_MCADR) ? IDNKERR_CONFIG_MCADR : \ ((fa) == IDNFIN_ARG_CFGERR_CKSUM) ? IDNKERR_CONFIG_CKSUM : \ ((fa) == IDNFIN_ARG_CFGERR_SMR) ? IDNKERR_CONFIG_SMR : 0) /* * FIN SYNC types. */ #define IDNFIN_SYNC_OFF 0 /* not set */ #define IDNFIN_SYNC_NO 1 /* no-sync necessary */ #define IDNFIN_SYNC_YES 2 /* do fin synchronously */ typedef short idn_finsync_t; /* * IDNP_FIN options. */ typedef enum { /* 0 */ IDNFIN_OPT_NONE = 0, /* none (used w/query) */ /* 1 */ IDNFIN_OPT_UNLINK, /* normal unlink request */ /* 2 */ IDNFIN_OPT_RELINK /* disconnect and retry link */ } idn_finopt_t; #define VALID_FINOPT(f) (((f) == IDNFIN_OPT_UNLINK) || \ ((f) == IDNFIN_OPT_RELINK)) #define FIN_MASTER_DOMID(x) (((((x) >> 16) & 0xffff) == 0xffff) ? \ IDN_NIL_DOMID : (((x) >> 16) & 0xffff)) #define FIN_MASTER_CPUID(x) ((((x) & 0xffff) == 0xffff) ? \ IDN_NIL_DCPU : ((x) & 0xfff)) #define MAKE_FIN_MASTER(d, c) ((((uint_t)(d) & 0xffff) << 16) | \ ((uint_t)(c) & 0xffff)) #define NIL_FIN_MASTER MAKE_FIN_MASTER(IDN_NIL_DOMID, IDN_NIL_DCPU) #ifdef DEBUG #define IDN_FSTATE_TRANSITION(dp, ns) \ { \ int _id; \ _id = (dp)->domid; \ if ((dp)->dfin != (ns)) { \ hrtime_t tstamp; \ tstamp = TIMESTAMP(); \ IDN_HISTORY_LOG(IDNH_FIN, _id, (ns), 0); \ PR_STATE("FSTATE:%ld:%d: (l=%d, b/p=%d/%d) " \ "%s(%d) -> %s(%d)\n", \ (uint64_t)tstamp, _id, \ __LINE__, \ ((dp)->dcpu == IDN_NIL_DCPU) ? -1 : \ CPUID_TO_BOARDID((dp)->dcpu), \ (dp)->dcpu, \ idnfin_str[(dp)->dfin], (dp)->dfin, \ idnfin_str[ns], (ns)); \ (dp)->dfin = (ns); \ } \ } #else #define IDN_FSTATE_TRANSITION(dp, ns) \ { \ IDN_HISTORY_LOG(IDNH_FIN, (dp)->domid, (ns), 0); \ (dp)->dfin = (ns); \ } #endif /* DEBUG */ #endif /* !_ASM */ #endif /* _KERNEL */ #ifndef _ASM /* * IDN Per-Domain States. */ typedef enum { /* 0 */ IDNDS_CLOSED, /* idle */ /* 1 */ IDNDS_NEGO_PEND, /* link initiating */ /* 2 */ IDNDS_NEGO_SENT, /* link initiated, nego sent */ /* 3 */ IDNDS_NEGO_RCVD, /* link wanted, nego+ack sent */ /* 4 */ IDNDS_CONFIG, /* passing config info, prgm hw */ /* 5 */ IDNDS_CON_PEND, /* connection pending */ /* 6 */ IDNDS_CON_SENT, /* con sent */ /* 7 */ IDNDS_CON_RCVD, /* con sent & received */ /* 8 */ IDNDS_CON_READY, /* ready to establish link */ /* 9 */ IDNDS_CONNECTED, /* established - linked */ /* 10 */ IDNDS_FIN_PEND, /* unlink initiating */ /* 11 */ IDNDS_FIN_SENT, /* unlink initiated, fin sent */ /* 12 */ IDNDS_FIN_RCVD, /* unlink wanted by remote */ /* 13 */ IDNDS_DMAP /* deprogramming hw */ } idn_dstate_t; #define IDNDS_IS_CLOSED(dp) (((dp)->dstate == IDNDS_CLOSED) || \ ((dp)->dstate == IDNDS_DMAP)) #define IDNDS_IS_CONNECTING(dp) (((dp)->dstate > IDNDS_CLOSED) && \ ((dp)->dstate < IDNDS_CONNECTED)) #define IDNDS_IS_DISCONNECTING(dp) ((dp)->dstate > IDNDS_CONNECTED) #define IDNDS_CONFIG_DONE(dp) (((dp)->dstate == IDNDS_CLOSED) || \ ((dp)->dstate > IDNDS_CONFIG)) #define IDNDS_SYNC_TYPE(dp) (((dp)->dfin_sync != IDNFIN_SYNC_OFF) ? \ (dp)->dfin_sync : \ ((dp)->dstate < IDNDS_CON_READY) ? \ IDNFIN_SYNC_NO : IDNFIN_SYNC_YES) #endif /* !_ASM */ #ifdef _KERNEL #ifndef _ASM /* * --------------------------------------------------------------------- */ typedef struct idn_timer { struct idn_timer *t_forw, *t_back; struct idn_timerq *t_q; timeout_id_t t_id; short t_domid; short t_onq; ushort_t t_type; ushort_t t_subtype; uint_t t_cookie; #ifdef DEBUG hrtime_t t_posttime; hrtime_t t_exectime; #endif /* DEBUG */ } idn_timer_t; #define IDN_TIMER_PUBLIC_COOKIE 0xf #define IDN_TIMERQ_IS_LOCKED(tq) (MUTEX_HELD(&(tq)->tq_mutex)) #define IDN_TIMERQ_LOCK(tq) (mutex_enter(&(tq)->tq_mutex)) #define IDN_TIMERQ_UNLOCK(tq) (mutex_exit(&(tq)->tq_mutex)) #define IDN_TIMERQ_INIT(tq) (idn_timerq_init(tq)) #define IDN_TIMERQ_DEINIT(tq) (idn_timerq_deinit(tq)) #define IDN_TIMER_ALLOC() (idn_timer_alloc()) #define IDN_TIMER_FREE(tp) (idn_timer_free(tp)) #define IDN_TIMER_START(tq, tp, tim) \ (idn_timer_start((tq), (tp), (tim))) #define IDN_TIMER_STOP(tq, typ, ck) \ ((void) idn_timer_stop((tq), (typ), (ck))) #define IDN_TIMER_STOPALL(tp) \ ((void) idn_timer_stopall(tp)) #define IDN_TIMER_GET(tq, typ, tp, ck) \ { \ mutex_enter(&((tq)->tq_mutex)); \ (tp) = idn_timer_get((tq), (typ), (ck)); \ mutex_exit(&((tq)->tq_mutex)); \ } #define IDN_TIMER_DEQUEUE(tq, tp) \ (idn_timer_dequeue((tq), (tp))) #ifdef DEBUG #define IDN_TIMER_POST(tp) \ ((tp)->t_posttime = gethrtime(), (tp)->t_exectime = 0) #define IDN_TIMER_EXEC(tp) ((tp)->t_exectime = gethrtime()) #else /* DEBUG */ #define IDN_TIMER_POST(tp) #define IDN_TIMER_EXEC(tp) #endif /* DEBUG */ #define IDN_MSGTIMER_START(domid, typ, subtyp, tim, ckp) \ { \ idn_timer_t *_tp; \ char _str[15]; \ ushort_t *_ckp = (ckp); \ inum2str((typ), _str); \ PR_TIMER("msgtimer:%d: START: type = %s (0x%x)\n", \ (domid), _str, (typ)); \ _tp = IDN_TIMER_ALLOC(); \ _tp->t_type = (ushort_t)(typ); \ _tp->t_subtype = (ushort_t)(subtyp); \ _tp->t_domid = (short)(domid); \ _tp->t_cookie = (_ckp) ? *(_ckp) : 0; \ IDN_TIMER_POST(_tp); \ if (_ckp) { \ *(_ckp) = IDN_TIMER_START(&idn_domain[domid].dtimerq, \ _tp, (tim)); \ } else { \ (void) IDN_TIMER_START(&idn_domain[domid].dtimerq, \ _tp, (tim)); \ } \ } #define IDN_MSGTIMER_STOP(domid, typ, ck) \ { \ char _str[15]; \ inum2str((typ), _str); \ PR_TIMER("msgtimer:%d: STOP: type = %s (0x%x), " \ "cookie = 0x%x\n", \ (domid), _str, (typ), (ck)); \ IDN_TIMER_STOP(&idn_domain[domid].dtimerq, (typ), (ck)); \ } #define IDN_MSGTIMER_GET(dp, typ, tp, ck) \ IDN_TIMER_GET(&(dp)->dtimerq, (typ), (tp), (ck)) /* * IDN_SLABALLOC_WAITTIME * Max wait time in ticks that local domains waits for * master to respond to a slab allocation request. Has * to be at least as long as wait time for a response to * the command. */ #define IDN_SLABALLOC_WAITTIME ((3 * idn_msg_waittime[IDNP_CMD]) / 2) /* * Domain state transition macros. */ #ifdef DEBUG #define IDN_DSTATE_TRANSITION(dp, ns) \ { \ int id; \ hrtime_t tstamp; \ tstamp = TIMESTAMP(); \ ASSERT(RW_WRITE_HELD(&(dp)->drwlock)); \ id = (dp)->domid; \ IDN_HISTORY_LOG(IDNH_DSTATE, id, (ns), \ (uint_t)(dp)->dcpu); \ PR_STATE("DSTATE:%ld:%d: (l=%d, b/p=%d/%d) " \ "%s(%d) -> %s(%d)\n", \ (uint64_t)tstamp, id, \ __LINE__, \ ((dp)->dcpu == IDN_NIL_DCPU) ? \ -1 : CPUID_TO_BOARDID((dp)->dcpu), \ (dp)->dcpu, \ idnds_str[(dp)->dstate], (dp)->dstate, \ idnds_str[ns], (ns)); \ (dp)->dstate = (ns); \ IDNSB_DOMAIN_UPDATE(dp); \ } #else #define IDN_DSTATE_TRANSITION(dp, ns) \ { \ IDN_HISTORY_LOG(IDNH_DSTATE, (dp)->domid, \ (ns), (uint_t)(dp)->dcpu); \ (dp)->dstate = (ns); \ IDNSB_DOMAIN_UPDATE(dp); \ } #endif /* DEBUG */ #define IDN_XSTATE_TRANSITION(dp, xs) \ { \ int _xs = (xs); \ (dp)->dxstate = _xs; \ if (_xs != IDNXS_NIL) { \ ASSERT((dp)->dxp); \ IDN_DSTATE_TRANSITION((dp), \ (dp)->dxp->xt_trans[_xs].t_state); \ } \ } /* * --------------------------------------------------------------------- * IDN Per-Domain Data * * The comment to the right of the respective field represents * what lock protects that field. If there is no comment then * no lock is required to access the field. * --------------------------------------------------------------------- */ #define MAXDNAME 32 typedef struct idn_domain { krwlock_t drwlock; /* * Assigned domid for domain. Never * changes once idn_domain[] is * initialized. We are guaranteed that * all domains in IDN will have a * uniqueue domid in the range (0-15). */ int domid; idn_dstate_t dstate; /* drwlock */ idn_xstate_t dxstate; /* drwlock */ /* * Gotten from uname -n for local * domain. Remote domains pass * theirs during Config phase. */ char dname[MAXDNAME]; /* drwlock */ /* * IDN-wide unique identifier for the * given domain. This value will be * the same as the domid. */ ushort_t dnetid; /* drwlock */ idn_vote_t dvote; /* drwlock */ /* * Used during FIN sequenece to * determine what type of shutdown * (unlink) we're executing with * respect to the given domain. */ idn_fin_t dfin; /* drwlock */ /* * A non-zero value for dfin_sync * indicates that unlink of respective * domain does not need to be performed * synchronously among all the IDN * member domains. */ short dfin_sync; /* grwlock */ /* * Cookie used to determine the * proper context in which we're * receiving messages from the given * domain. Assigned cookies are exchanged * during initial NEGO messages. */ ushort_t dcookie_send; /* drwlock */ ushort_t dcookie_recv; /* drwlock */ short dcookie_err; /* drwlock */ int dcookie_errcnt; /* drwlock */ /* * Primary target cpu for sending * messages. Can change to help * distribute interrupts on receiving * side. */ int dcpu; /* drwlock */ /* * Used to store dcpu from a previous * life. Only used when requesting * a RELINK with a domain we were just * previously linked with. Thus, it * does represent a valid cpu in the * remote domain. */ int dcpu_save; /* drwlock */ /* * Used to store from which cpu the * last message was received. */ int dcpu_last; /* * Transition phase area. This field * points to the proper phase structure * depending on what stage the given * domain is in. */ idn_xphase_t *dxp; /* drwlock */ /* * Actual synchronization object for * the given domain. */ idn_syncop_t dsync; /* drwlock & idn.sync.sz_mutex */ /* * Slab information for given domain. * If the local domain is a master, * then this field in each domain is used * to store which slabs have been assigned * to given domain. If the local domain * is a slave, then this information is * NULL for all remote idn_domain[] * entries, but for local domain holds * those slabs assigned to local domain. */ smr_slab_t *dslab; /* dslab_rwlock */ short dnslabs; /* dslab_rwlock */ short dslab_state; /* dslab_rwlock */ krwlock_t dslab_rwlock; /* * Set of cpus belonging to domain. */ cpuset_t dcpuset; /* drwlock */ int dncpus; /* drwlock */ /* * Index into dcpumap to determine * which cpu to target next for * interrupt. Intended to allow fair * distribution of interrupts on * remote domain. */ uint_t dcpuindex; /* drwlock */ /* * Quick look-up map of cpus belonging * to domain. Used to select next target. */ uchar_t *dcpumap; /* drwlock */ /* * Non-zero indicates outstanding * I/O's to given domain. */ int dio; /* drwlock */ int dioerr; /* drwlock */ /* * Set when we fail to allocate a buffer * for a domain. Dictates whether to * reclaim max buffers or not. */ lock_t diowanted; /* * Set when remote domain does not * seem to be picking up messages sent * to it. Non-zero indicates we have * an outstanding "ping" to domain. */ lock_t diocheck; /* drwlock */ short dslabsize; /* drwlock */ uint_t dmtu; /* drwlock */ uint_t dbufsize; /* drwlock */ short dnwrsize; /* drwlock */ lock_t dreclaim_inprogress; /* drwlock */ uchar_t dreclaim_index; /* drwlock */ /* * The following field is primarily * used during CFG exchange to keep * track of certain per-domain information. */ union { /* all - drwlock */ struct { uint_t _dcfgphase : 6; uint_t _dcfgsnddone : 1; uint_t _dcfgrcvdone : 1; uint_t _dcksum : 2; uint_t _dmaxnets : 6; uint_t _dmboxpernet : 9; uint_t _dncfgitems : 6; uint_t _drecfg : 1; } _s; int _dtmp; } _u; /* * Each domain entry maintains a * timer queue holding timers for * messages outstanding to that domain. */ struct idn_timerq { int tq_cookie; /* tq_mutex */ kmutex_t tq_mutex; int tq_count; /* tq_mutex */ idn_timer_t *tq_queue; /* tq_mutex */ } dtimerq; /* * dawol is used to keep * track of AWOL details for * given domain when it is * non-responsive. */ struct { int a_count; /* drwlock */ clock_t a_time; /* drwlock */ clock_t a_last; /* drwlock */ clock_t a_msg; /* drwlock */ } dawol; struct hwconfig { short dh_nboards; /* drwlock */ short dh_nmcadr; /* drwlock */ boardset_t dh_boardset; /* drwlock */ uint_t dh_mcadr[MAX_BOARDS]; /* drwlock */ } dhw; /* * Mailbox information used to * send/recv messages to given domain. */ struct { kmutex_t m_mutex; struct idn_mboxtbl *m_tbl; /* m_mutex */ struct idn_mainmbox *m_send; /* m_mutex */ struct idn_mainmbox *m_recv; /* m_mutex */ } dmbox; } idn_domain_t; typedef struct idn_timerq idn_timerq_t; #define dcfgphase _u._s._dcfgphase #define dcfgsnddone _u._s._dcfgsnddone #define dcfgrcvdone _u._s._dcfgrcvdone #define dcksum _u._s._dcksum #define dmaxnets _u._s._dmaxnets #define dmboxpernet _u._s._dmboxpernet #define dncfgitems _u._s._dncfgitems #define drecfg _u._s._drecfg #define dbindport _u._dbindport #define dconnected _u._dconnected #define dtmp _u._dtmp #define IDN_DLOCK_EXCL(dd) (rw_enter(&idn_domain[dd].drwlock, RW_WRITER)) #define IDN_DLOCK_SHARED(dd) (rw_enter(&idn_domain[dd].drwlock, RW_READER)) #define IDN_DLOCK_TRY_SHARED(dd) \ (rw_tryenter(&idn_domain[dd].drwlock, \ RW_READER)) #define IDN_DLOCK_DOWNGRADE(dd) (rw_downgrade(&idn_domain[dd].drwlock)) #define IDN_DUNLOCK(dd) (rw_exit(&idn_domain[dd].drwlock)) #define IDN_DLOCK_IS_EXCL(dd) (RW_WRITE_HELD(&idn_domain[dd].drwlock)) #define IDN_DLOCK_IS_SHARED(dd) (RW_READ_HELD(&idn_domain[dd].drwlock)) #define IDN_DLOCK_IS_HELD(dd) (RW_LOCK_HELD(&idn_domain[dd].drwlock)) #define IDN_MBOX_LOCK(dd) (mutex_enter(&idn_domain[dd].dmbox.m_mutex)) #define IDN_MBOX_UNLOCK(dd) (mutex_exit(&idn_domain[dd].dmbox.m_mutex)) #define IDN_RESET_COOKIES(dd) \ (idn_domain[dd].dcookie_send = idn_domain[dd].dcookie_recv = 0) #define DSLAB_STATE_UNKNOWN 0 #define DSLAB_STATE_LOCAL 1 #define DSLAB_STATE_REMOTE 2 #define DSLAB_READ_HELD(d) RW_READ_HELD(&idn_domain[d].dslab_rwlock) #define DSLAB_WRITE_HELD(d) RW_WRITE_HELD(&idn_domain[d].dslab_rwlock) #define DSLAB_LOCK_EXCL(d) \ rw_enter(&idn_domain[d].dslab_rwlock, RW_WRITER) #define DSLAB_LOCK_SHARED(d) \ rw_enter(&idn_domain[d].dslab_rwlock, RW_READER) #define DSLAB_LOCK_TRYUPGRADE(d) \ rw_tryupgrade(&idn_domain[d].dslab_rwlock) #define DSLAB_UNLOCK(d) rw_exit(&idn_domain[d].dslab_rwlock) /* * --------------------------------------------------------------------- * Macro to pick another target for the given domain. This hopefully * improves performance by better distributing the SSI responsibilities * at the target domain. * --------------------------------------------------------------------- */ #define BUMP_INDEX(set, index) \ { \ register int p; \ for (p = (index)+1; p < NCPU; p++) \ if (CPU_IN_SET((set), p)) \ break; \ if (p >= NCPU) \ for (p = 0; p <= (index); p++) \ if (CPU_IN_SET((set), p)) \ break; \ if (!CPU_IN_SET((set), p)) { \ uint_t _u32, _l32; \ _u32 = UPPER32_CPUMASK(set); \ _l32 = LOWER32_CPUMASK(set); \ cmn_err(CE_PANIC, \ "IDN: cpu %d not in cpuset 0x%x.%0x\n", \ p, _u32, _l32); \ } \ (index) = p; \ } #define IDN_ASSIGN_DCPU(dp, cookie) \ ((dp)->dcpu = (int)((dp)->dcpumap[(cookie) & (NCPU-1)])) /* * --------------------------------------------------------------------- * Atomic increment/decrement, swap, compare-swap functions. * --------------------------------------------------------------------- */ #define ATOMIC_INC(v) atomic_inc_32((uint_t *)&(v)) #define ATOMIC_DEC(v) atomic_dec_32((uint_t *)&(v)) #define ATOMIC_SUB(v, n) atomic_add_32((uint_t *)&(v), -(n)) #define ATOMIC_CAS(a, c, n) atomic_cas_32((uint32_t *)(a), (uint32_t)(c), \ (uint32_t)(n)) #define ATOMIC_SWAPL(a, v) atomic_swap_32((uint32_t *)(a), (uint32_t)(v)) /* * DMV vector interrupt support. * * A fixed-size circular buffer is maintained as a queue of * incoming interrupts. The low-level idn_dmv_handler() waits * for an entry to become FREE and will atomically mark it INUSE. * Once he has filled in the appropriate fields it will be marked * as READY. The high-level idn_handler() will be invoked and will * process all messages in the queue that are READY. Each message * is marked PROCESS, a protojob job created and filled in, and * then the interrupt message is marked FREE for use in the next * interrupt. The iv_state field is used to hold the relevant * state and is updated atomically. */ #define IDN_PIL PIL_8 #define IDN_DMV_PENDING_MAX 128 /* per cpu */ #endif /* !_ASM */ #ifndef _ASM /* * The size of this structure must be a power of 2 * so that we can do a simple shift to calculate * our offset into based on cpuid. */ typedef struct idn_dmv_cpu { uint32_t idn_dmv_current; int32_t idn_dmv_lostintr; lock_t idn_dmv_active; char _padding[(2 * sizeof (uint64_t)) - \ sizeof (uint32_t) - \ sizeof (lock_t) - \ sizeof (int32_t)]; } idn_dmv_cpu_t; typedef struct idn_dmv_data { uint_t idn_soft_inum; uint64_t idn_dmv_qbase; idn_dmv_cpu_t idn_dmv_cpu[NCPU]; } idn_dmv_data_t; /* * Requirements of the following data structure: * - MUST be double-word (8 bytes) aligned. * - _iv_head field MUST start on double-word boundary. * - iv_xargs0 MUST start on double-word boundary * with iv_xargs1 immediately following. * - iv_xargs2 MUST start on double-word boundary * with iv_xargs3 immediately following. */ typedef struct idn_dmv_msg { uint32_t iv_next; /* offset */ uchar_t iv_inuse; uchar_t iv_ready; ushort_t _padding; uint32_t iv_head : 16; uint32_t iv_cookie : 16; uint32_t iv_ver : 8; uint32_t iv_mtype : 6; uint32_t iv_atype : 6; uint32_t iv_domid : 4; uint32_t iv_cpuid : 8; uint32_t iv_xargs0; uint32_t iv_xargs1; uint32_t iv_xargs2; uint32_t iv_xargs3; } idn_dmv_msg_t; extern uint_t idn_dmv_inum; extern uint_t idn_soft_inum; /* * An IDN-network address has the following format: * * 31......16,15........0 * | channel | dnetid | * ---------------------- * channel - network interface. * netid - idn_domain[].dnetid */ #define IDN_MAXMAX_NETS 32 #define IDN_BROADCAST_ALLCHAN ((ushort_t)-1) #define IDN_BROADCAST_ALLNETID ((ushort_t)-1) typedef union { struct { ushort_t chan; ushort_t netid; } net; uint_t netaddr; } idn_netaddr_t; #define CHANSET_ALL (~((idn_chanset_t)0)) #define CHANSET(c) \ ((idn_chanset_t)1 << ((c) & 31)) #define CHAN_IN_SET(m, c) \ (((m) & ((idn_chanset_t)1 << ((c) & 31))) != 0) #define CHANSET_ADD(m, c) \ ((m) |= ((idn_chanset_t)1 << ((c) & 31))) #define CHANSET_DEL(m, c) \ ((m) &= ~((idn_chanset_t)1 << ((c) & 31))) #define CHANSET_ZERO(m) ((m) = 0) typedef enum { /* 0 */ IDNCHAN_OPEN, /* 1 */ IDNCHAN_SOFT_CLOSE, /* 2 */ IDNCHAN_HARD_CLOSE, /* 3 */ IDNCHAN_OFFLINE, /* 4 */ IDNCHAN_ONLINE } idn_chanop_t; /* * Retry support. */ #define IDN_RETRY_TOKEN(d, x) ((((d) & 0xf) << 16) | \ (0xffff & (uint_t)(x))) #define IDN_RETRY_TOKEN2DOMID(t) ((int)(((t) >> 16) & 0xf)) #define IDN_RETRY_TOKEN2TYPE(t) ((idn_retry_t)((t) & 0xffff)) #define IDN_RETRY_TYPEALL ((idn_retry_t)0xffff) #define IDN_RETRY_INTERVAL hz /* 1 sec */ #define IDN_RETRY_RECFG_MULTIPLE 10 #define IDN_RETRYINTERVAL_NEGO (2 * hz) #define IDN_RETRYINTERVAL_CON (2 * hz) #define IDN_RETRYINTERVAL_FIN (2 * hz) typedef struct idn_retry_job { struct idn_retry_job *rj_prev; struct idn_retry_job *rj_next; void (*rj_func)(uint_t token, void *arg); void *rj_arg; uint_t rj_token; short rj_onq; timeout_id_t rj_id; } idn_retry_job_t; #define IDNRETRY_ALLOCJOB() \ ((idn_retry_job_t *)kmem_cache_alloc(idn.retryqueue.rq_cache, KM_SLEEP)) #define IDNRETRY_FREEJOB(j) \ (kmem_cache_free(idn.retryqueue.rq_cache, (void *)(j))) typedef enum { /* 0 */ IDNRETRY_NIL = 0, /* 1 */ IDNRETRY_NEGO, /* 2 */ IDNRETRY_CON, /* 3 */ IDNRETRY_CONQ, /* for CON queries */ /* 4 */ IDNRETRY_FIN, /* 5 */ IDNRETRY_FINQ, /* for FIN queries */ /* 6 */ IDN_NUM_RETRYTYPES } idn_retry_t; /* * --------------------------------------------------------------------- */ typedef struct { int m_domid; int m_cpuid; ushort_t m_msgtype; ushort_t m_acktype; ushort_t m_cookie; idn_xdcargs_t m_xargs; } idn_protomsg_t; typedef struct idn_protojob { struct idn_protojob *j_next; int j_cache; idn_protomsg_t j_msg; } idn_protojob_t; typedef struct idn_protoqueue { struct idn_protoqueue *q_next; idn_protojob_t *q_joblist; idn_protojob_t *q_joblist_tail; int q_die; int q_id; ksema_t *q_morgue; kthread_id_t q_threadp; kcondvar_t q_cv; kmutex_t q_mutex; } idn_protoqueue_t; #define IDN_PROTOCOL_NSERVERS 4 #define IDN_PROTOCOL_SERVER_HASH(d) ((d) % idn.nservers) #define IDN_PROTOJOB_CHUNKS (idn.nservers) /* * --------------------------------------------------------------------- * Data Server definitions. * * idn_datasvr_t - Describes data server thread. * . ds_id - Per-domain identifier for data server. * . ds_domid - Domain which data server is handling. * . ds_state - Flag to enable/disable/terminate * data server. * . ds_mboxp - Pointer to data server's (local) * mailbox to be serviced. * . ds_waittime - cv_timedwait sleep time before * checking respective mailbox. * . ds_threadp - Pointer to data server thread. * . ds_cv - Condvar for sleeping. * . ds_morguep - Semaphore for terminating thread. * * idn_mboxhdr_t - Resides in SMR space (MUST be cache_linesize). * . mh_svr_active - Non-zero indicates data server is * actively reading mailbox for messages. * . mh_svr_ready - Non-zero indicates data server has * allocated and is ready to accept data. * . mh_cookie - Identifier primarily for debug purposes. * * idn_mboxmsg_t - Entry in the SMR space circular queue use to * represent a data packet. * . mm_owner - Non-zero indicates entry is available * to be processed by receiver's data server. * . mm_flag - Indicates whether entry needs to be * reclaimed by the sender. Also holds error * indications (e.g. bad offset). * . mm_offset - SMR offset of respective data packet. * * idn_mboxtbl_t - Encapsulation of a per-domain mailbox (SMR space). * . mt_header - Header information for synchronization. * . mt_queue - Circular queue of idn_mboxmsg_t entries. * * idn_mainmbox_t - Encapsulation of main SMR recv/send mailboxes. * . mm_mutex - Protects mm_* entries, enqueuing, and * dequeuing of messages. Also protects * updates to the route table pointed to * by mm_routetbl. * . mm_count - send: Current number of messages * enqueued. * - recv: Cumulative number of messages * processed. * . mm_max_count - send: Maximum number of messages * enqueued per iteration. * recv: Maximum number of messages * dequeued per iteration. * . mm_smr_mboxp - Pointer to SMR (vaddr) space where * respective mailbox resides. * --------------------------------------------------------------------- */ #define IDN_MBOXHDR_COOKIE_TOP ((uint_t)0xc0c0) #define IDN_MAKE_MBOXHDR_COOKIE(pd, sd, ch) \ ((IDN_MBOXHDR_COOKIE_TOP << 16) \ | (((uint_t)(pd) & 0xf) << 12) \ | (((uint_t)(sd) & 0xf) << 8) \ | ((uint_t)(ch) & 0xf)) #define IDN_GET_MBOXHDR_COOKIE(mhp) \ ((mhp)->mh_cookie & ~0xff00) #define VALID_MBOXHDR(mhp, ch, cksum) \ ((IDN_GET_MBOXHDR_COOKIE(mhp) == \ IDN_MAKE_MBOXHDR_COOKIE(0, 0, (ch))) && \ ((cksum) == (*(mhp)).mh_cksum)) /* * The number of entries in a mailbox queue must be chosen so * that (IDN_MMBOX_NUMENTRIES * sizeof (idn_mboxmsg_t)) is a multiple * of a cacheline size (64). */ #define IDN_MMBOX_NUMENTRIES IDN_MBOX_PER_NET /* * We step through the mailboxes in effectively cacheline size * incremenents so that the source and receiving cpus are not competing * for the same cacheline when transmitting/receiving messages into/from * the mailboxes. The hard requirement is that the step value be even * since the mailbox size will be chosen odd. This allows us to wraparound * the mailbox uniquely touching each entry until we've exhausted them * all at which point we'll end up where we initially started and repeat * again. */ #define IDN_MMBOXINDEX_STEP (((64 / sizeof (idn_mboxmsg_t)) + 1) & 0xfffe) #define IDN_MMBOXINDEX_INC(i) \ { \ if (((i) += IDN_MMBOXINDEX_STEP) >= IDN_MMBOX_NUMENTRIES) \ (i) -= IDN_MMBOX_NUMENTRIES; \ } #define IDN_MMBOXINDEX_DIFF(i, j) \ (((i) >= (j)) ? (((i) - (j)) / IDN_MMBOXINDEX_STEP) \ : ((((i) + IDN_MMBOX_NUMENTRIES) - (j)) / IDN_MMBOXINDEX_STEP)) /* * Require IDN_MBOXAREA_SIZE <= IDN_SLAB_SIZE so we don't waste * slab space. * * Each domain maintains a MAX_DOMAIN(16) entry mbox_table. Each * entry represents a receive mailbox for a possible domain to which * the given domain may have a connection. The send mailbox for each * respective domain is given to the local domain at the time of * connection establishment. */ /* * --------------------------------------------------------------------- */ #define IDN_MBOXTBL_SIZE \ (IDNROUNDUP(((IDN_MBOX_PER_NET * sizeof (idn_mboxmsg_t)) \ + sizeof (idn_mboxhdr_t)), IDN_ALIGNSIZE)) /* * --------------------------------------------------------------------- * Each domain has idn_max_nets worth of possible mailbox tables * for each domain to which it might possibly be connected. * --------------------------------------------------------------------- */ #define IDN_MBOXAREA_SIZE \ (IDN_MBOXTBL_SIZE * IDN_MAX_NETS * MAX_DOMAINS * MAX_DOMAINS) #define IDN_MBOXAREA_OFFSET(d) \ ((d) * IDN_MBOXTBL_SIZE * IDN_MAX_NETS * MAX_DOMAINS) /* * --------------------------------------------------------------------- * Return the base of the mailbox area (set of tables) assigned * to the given domain id. * --------------------------------------------------------------------- */ #define IDN_MBOXAREA_BASE(m, d) \ ((idn_mboxtbl_t *)(((ulong_t)(m)) + IDN_MBOXAREA_OFFSET(d))) /* * --------------------------------------------------------------------- * Return the pointer to the respective receive mailbox (table set) * for the given domain id relative to the given base mailbox table. * --------------------------------------------------------------------- */ #define IDN_MBOXTBL_PTR(t, d) \ ((idn_mboxtbl_t *)(((ulong_t)(t)) + ((d) * IDN_MBOXTBL_SIZE \ * IDN_MAX_NETS))) /* * --------------------------------------------------------------------- * Return the pointer to the actual target mailbox based on the * given channel in the given mailbox table. * --------------------------------------------------------------------- */ #define IDN_MBOXTBL_PTR_CHAN(t, c) \ ((idn_mboxtbl_t *)(((ulong_t)(t)) + ((c) * IDN_MBOXTBL_SIZE))) #define IDN_MBOXTBL_PTR_INC(t) \ ((t) = (idn_mboxtbl_t *)(((ulong_t)(t)) + IDN_MBOXTBL_SIZE)) #define IDN_MBOXCHAN_INC(i) \ { \ if (++(i) == IDN_MAX_NETS) \ (i) = 0; \ } /* * --------------------------------------------------------------------- * Return the absolute location within the entire mailbox area * of the mboxtbl for the given primary and secondary domain and * channel. Only relevant when done by the master. * --------------------------------------------------------------------- */ #define IDN_MBOXTBL_ABS_PTR(mt, pd, sd, ch) \ (IDN_MBOXTBL_PTR_CHAN( \ IDN_MBOXTBL_PTR( \ IDN_MBOXAREA_BASE((mt), (pd)), \ (sd)), \ (ch))) #define IDN_BFRAME_SHIFT idn.bframe_shift #define IDN_BFRAME2OFFSET(bf) ((bf) << IDN_BFRAME_SHIFT) #define IDN_BFRAME2ADDR(bf) IDN_OFFSET2ADDR(IDN_BFRAME2OFFSET(bf)) #define IDN_OFFSET2BFRAME(off) (((off) >> IDN_BFRAME_SHIFT) & 0xffffff) #define IDN_ADDR2BFRAME(addr) IDN_OFFSET2BFRAME(IDN_ADDR2OFFSET(addr)) typedef struct idn_mboxmsg { uint_t ms_owner : 1, ms_flag : 7, ms_bframe : 24; } idn_mboxmsg_t; typedef idn_mboxmsg_t idn_mboxq_t[1]; #define IDN_CKSUM_MBOX_COUNT \ (((int)&((idn_mboxhdr_t *)(0))->mh_svr_ready) / 2) #define IDN_CKSUM_MBOX(h) \ (IDN_CHECKSUM ? \ idn_cksum((ushort_t *)(h), IDN_CKSUM_MBOX_COUNT) : 0) typedef struct idn_mboxhdr { uint_t mh_cookie; uint_t mh_svr_ready_ptr; uint_t mh_svr_active_ptr; ushort_t mh_svr_ready; ushort_t mh_svr_active; uint_t _padding[(64 - (4*sizeof (uint_t)) - (2*sizeof (ushort_t))) / sizeof (uint_t)]; uint_t mh_cksum; } idn_mboxhdr_t; typedef struct idn_mboxtbl { idn_mboxhdr_t mt_header; idn_mboxq_t mt_queue; } idn_mboxtbl_t; #define IDN_CHAN_DOMAIN_REGISTER(csp, dom) \ (DOMAINSET_ADD((csp)->ch_reg_domset, (dom))) #define IDN_CHAN_DOMAIN_UNREGISTER(csp, dom) \ (DOMAINSET_DEL((csp)->ch_reg_domset, (dom))) #define IDN_CHAN_DOMAIN_IS_REGISTERED(csp, dom) \ (DOMAIN_IN_SET((csp)->ch_reg_domset, (dom))) #define IDN_CHANSVR_SCANSET_ADD_PENDING(csp, dom) \ { \ register int _d; \ register uint64_t _domset; \ (dom) &= MAX_DOMAINS - 1; /* Assumes power of 2 */ \ _domset = 0ull; \ for (_d = 0; _d < (csp)->ch_recv_domcount; _d++) { \ if ((int)(((csp)->ch_recv_scanset_pending >> \ (_d * 4)) & 0xf) == (dom)) \ break; \ else \ _domset = (_domset << 4) | 0xfull; \ } \ if (_d == (csp)->ch_recv_domcount) { \ _domset &= (csp)->ch_recv_scanset_pending; \ _domset |= (uint64_t)(dom) << \ ((csp)->ch_recv_domcount * 4); \ (csp)->ch_recv_domcount++; \ (csp)->ch_recv_scanset_pending = 0ull; \ for (_d = 0; _d < 16; \ _d += (csp)->ch_recv_domcount) { \ (csp)->ch_recv_scanset_pending |= _domset; \ _domset <<= (csp)->ch_recv_domcount * 4; \ } \ } \ } #define IDN_CHANSVR_SCANSET_DEL_PENDING(csp, dom) \ { \ register int _d; \ register uint64_t _domset; \ (dom) &= MAX_DOMAINS - 1; /* Assumes power of 2 */ \ _domset = 0ull; \ for (_d = 0; _d < (csp)->ch_recv_domcount; _d++) { \ if ((int)(((csp)->ch_recv_scanset_pending >> \ (_d * 4)) & 0xf) == (dom)) \ break; \ else \ _domset = (_domset << 4) | 0xfull; \ } \ if (_d < (csp)->ch_recv_domcount) { \ _domset &= (csp)->ch_recv_scanset_pending; \ (csp)->ch_recv_scanset_pending >>= 4; \ (csp)->ch_recv_domcount--; \ for (; _d < (csp)->ch_recv_domcount; _d++) \ _domset |= (csp)->ch_recv_scanset_pending &\ (0xfull << (_d * 4)); \ (csp)->ch_recv_scanset_pending = 0ull; \ if ((csp)->ch_recv_domcount) { \ for (_d = 0; _d < 16; \ _d += (csp)->ch_recv_domcount) { \ (csp)->ch_recv_scanset_pending |= \ _domset; \ _domset <<= \ (csp)->ch_recv_domcount * 4; \ } \ } \ } \ } #define IDN_CHAN_TRYLOCK_GLOBAL(csp) \ mutex_tryenter(&(csp)->ch_mutex) #define IDN_CHAN_LOCK_GLOBAL(csp) \ mutex_enter(&(csp)->ch_mutex) #define IDN_CHAN_UNLOCK_GLOBAL(csp) \ mutex_exit(&(csp)->ch_mutex) #define IDN_CHAN_GLOBAL_IS_LOCKED(csp) \ (MUTEX_HELD(&(csp)->ch_mutex)) #define IDN_CHAN_LOCAL_IS_LOCKED(csp) \ (MUTEX_HELD(&(csp)->ch_send.c_mutex) && \ MUTEX_HELD(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_LOCK_LOCAL(csp) \ (mutex_enter(&(csp)->ch_recv.c_mutex, \ mutex_enter(&(csp)->ch_send.c_mutex)) #define IDN_CHAN_UNLOCK_LOCAL(csp) \ (mutex_exit(&(csp)->ch_send.c_mutex), \ mutex_exit(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_RECV_IS_LOCKED(csp) \ (MUTEX_HELD(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_TRYLOCK_RECV(csp) \ (mutex_tryenter(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_LOCK_RECV(csp) \ (mutex_enter(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_UNLOCK_RECV(csp) \ (mutex_exit(&(csp)->ch_recv.c_mutex)) #define IDN_CHAN_SEND_IS_LOCKED(csp) \ (MUTEX_HELD(&(csp)->ch_send.c_mutex)) #define IDN_CHAN_TRYLOCK_SEND(csp) \ (mutex_tryenter(&(csp)->ch_send.c_mutex)) #define IDN_CHAN_LOCK_SEND(csp) \ (mutex_enter(&(csp)->ch_send.c_mutex)) #define IDN_CHAN_UNLOCK_SEND(csp) \ (mutex_exit(&(csp)->ch_send.c_mutex)) /* * A channel table is an array of pointers to mailboxes * for the respective domains for the given channel. * Used a cache for the frequently used items. Respective * fields in mainmbox are updated just prior to sleeping. */ /* * Reading c_state requires either c_mutex or ch_mutex. * Writing c_state requires both c_mutex and ch_mutex in the order: * ch_mutex * c_mutex */ typedef struct idn_chaninfo { kmutex_t c_mutex; uchar_t c_state; /* protected by c_mutex */ uchar_t c_checkin; /* asynchronous flag */ kcondvar_t c_cv; ushort_t c_waiters; /* protected by c_mutex */ ushort_t c_inprogress; /* protected by c_mutex */ } idn_chaninfo_t; /* * Reading/Writing ch_state requires ch_mutex. * When updating both recv and send c_state's for the locks * must be grabbed in the following order: * ch_mutex * ch_recv.c_mutex * ch_send.c_mutex * This order is necessary to prevent deadlocks. * In general ch_state is intended to represent c_state of * individual send/recv sides. During state transitions the * ch_state and c_state values may be slightly different, * but eventually should end up identical. */ typedef struct idn_chansvr { uchar_t ch_id; uchar_t ch_state; /* protected by ch_mutex */ lock_t ch_initlck; lock_t ch_actvlck; domainset_t ch_reg_domset; kmutex_t ch_mutex; idn_chaninfo_t ch_send; int _padding2[(64 - (2*sizeof (uchar_t)) - (2*sizeof (lock_t)) - sizeof (uint_t) - sizeof (kmutex_t) - sizeof (idn_chaninfo_t)) / sizeof (int)]; idn_chaninfo_t ch_recv; uint64_t ch_recv_scanset; uint64_t ch_recv_scanset_pending; domainset_t ch_recv_domset; domainset_t ch_recv_domset_pending; short ch_recv_domcount; kcondvar_t ch_recv_cv; int ch_recv_waittime; int ch_recv_changed; kthread_id_t ch_recv_threadp; ksema_t *ch_recv_morguep; int ch_bound_cpuid; int ch_bound_cpuid_pending; } idn_chansvr_t; typedef struct idn_mainmbox { kmutex_t mm_mutex; short mm_channel; short mm_domid; ushort_t mm_flags; short mm_type; idn_chansvr_t *mm_csp; /* non-NULL indicates reg'd */ int mm_count; int mm_dropped; idn_mboxtbl_t *mm_smr_mboxp; /* SMR vaddr */ ushort_t *mm_smr_activep; /* SMR pointer */ ushort_t *mm_smr_readyp; /* SMR pointer */ int mm_qiget; /* next msg to get */ int mm_qiput; /* next slot to put msg */ } idn_mainmbox_t; /* * mm_flags */ #define IDNMMBOX_FLAG_CORRUPTED 0x01 /* * mm_type */ #define IDNMMBOX_TYPE_RECV 0x1 #define IDNMMBOX_TYPE_SEND 0x2 #define IDNMBOX_IS_RECV(m) ((m) == IDNMMBOX_TYPE_RECV) #define IDNMBOX_IS_SEND(m) ((m) == IDNMMBOX_TYPE_SEND) /* * Period between sending wakeup xdc's to remote domain. */ #define IDN_CHANNEL_WAKEUP_PERIOD (hz >> 1) /* * ms_flag bit values. */ #define IDN_MBOXMSG_FLAG_RECLAIM 0x1 /* needs to be reclaimed */ #define IDN_MBOXMSG_FLAG_INPROCESS 0x2 #define IDN_MBOXMSG_FLAG_ERR_BADOFFSET 0x4 #define IDN_MBOXMSG_FLAG_ERR_NOMBOX 0x8 #define IDN_MBOXMSG_FLAG_ERRMASK 0xc /* * ch_state/c_state bit values. */ #define IDN_CHANSVC_STATE_ATTACHED 0x01 #define IDN_CHANSVC_STATE_ENABLED 0x02 #define IDN_CHANSVC_STATE_ACTIVE 0x04 #define IDN_CHANSVC_STATE_FLUSH 0x10 #define IDN_CHANSVC_STATE_CORRUPTED 0x20 #define IDN_CHANSVC_STATE_MASK 0x07 /* ATTACHED/ENABLED/ACTIVE */ #define IDN_CHANSVC_PENDING_BITS (IDN_CHANSVC_STATE_ATTACHED | \ IDN_CHANSVC_STATE_ENABLED) /* * GLOBAL */ #define IDN_CHANNEL_IS_ATTACHED(csp) \ ((csp)->ch_state & IDN_CHANSVC_STATE_ATTACHED) #define IDN_CHANNEL_IS_DETACHED(csp) \ (!IDN_CHANNEL_IS_ATTACHED(csp)) #define IDN_CHANNEL_IS_PENDING(csp) \ (((csp)->ch_state & IDN_CHANSVC_STATE_MASK) == \ IDN_CHANSVC_PENDING_BITS) #define IDN_CHANNEL_IS_ACTIVE(csp) \ ((csp)->ch_state & IDN_CHANSVC_STATE_ACTIVE) #define IDN_CHANNEL_IS_ENABLED(csp) \ ((csp)->ch_state & IDN_CHANSVC_STATE_ENABLED) /* * SEND */ #define IDN_CHANNEL_IS_SEND_ACTIVE(csp) \ ((csp)->ch_send.c_state & IDN_CHANSVC_STATE_ACTIVE) /* * RECV */ #define IDN_CHANNEL_IS_RECV_ACTIVE(csp) \ ((csp)->ch_recv.c_state & IDN_CHANSVC_STATE_ACTIVE) #define IDN_CHANNEL_IS_RECV_CORRUPTED(csp) \ ((csp)->ch_recv.c_state & IDN_CHANSVC_STATE_CORRUPTED) #define IDN_CHAN_SEND_INPROGRESS(csp) ((csp)->ch_send.c_inprogress++) #define IDN_CHAN_SEND_DONE(csp) \ { \ ASSERT((csp)->ch_send.c_inprogress > 0); \ if ((--((csp)->ch_send.c_inprogress) == 0) && \ ((csp)->ch_send.c_waiters != 0)) \ cv_broadcast(&(csp)->ch_send.c_cv); \ } #define IDN_CHAN_RECV_INPROGRESS(csp) ((csp)->ch_recv.c_inprogress++) #define IDN_CHAN_RECV_DONE(csp) \ { \ ASSERT((csp)->ch_recv.c_inprogress > 0); \ if ((--((csp)->ch_recv.c_inprogress) == 0) && \ ((csp)->ch_recv.c_waiters != 0)) \ cv_broadcast(&(csp)->ch_recv.c_cv); \ } #define IDN_CHANSVC_MARK_ATTACHED(csp) \ ((csp)->ch_state = IDN_CHANSVC_STATE_ATTACHED) #define IDN_CHANSVC_MARK_DETACHED(csp) \ ((csp)->ch_state = 0) #define IDN_CHANSVC_MARK_PENDING(csp) \ ((csp)->ch_state |= IDN_CHANSVC_STATE_ENABLED) #define IDN_CHANSVC_MARK_DISABLED(csp) \ ((csp)->ch_state &= ~IDN_CHANSVC_STATE_ENABLED) #define IDN_CHANSVC_MARK_ACTIVE(csp) \ ((csp)->ch_state |= IDN_CHANSVC_STATE_ACTIVE) #define IDN_CHANSVC_MARK_IDLE(csp) \ ((csp)->ch_state &= ~IDN_CHANSVC_STATE_ACTIVE) #define IDN_CHANSVC_MARK_RECV_ACTIVE(csp) \ ((csp)->ch_recv.c_state |= IDN_CHANSVC_STATE_ACTIVE) #define IDN_CHANSVC_MARK_RECV_CORRUPTED(csp) \ ((csp)->ch_recv.c_state |= IDN_CHANSVC_STATE_CORRUPTED) #define IDN_CHANSVC_MARK_SEND_ACTIVE(csp) \ ((csp)->ch_send.c_state |= IDN_CHANSVC_STATE_ACTIVE) typedef enum { IDNCHAN_ACTION_DETACH, /* DETACH (ATTACHED = 0) */ IDNCHAN_ACTION_STOP, /* DISABLE (ENABLED = 0) */ IDNCHAN_ACTION_SUSPEND, /* IDLE (ACTIVE = 0) */ IDNCHAN_ACTION_RESUME, IDNCHAN_ACTION_RESTART, IDNCHAN_ACTION_ATTACH } idn_chanaction_t; #define IDN_CHANNEL_SUSPEND(c, w) \ (idn_chan_action((c), IDNCHAN_ACTION_SUSPEND, (w))) #define IDN_CHANNEL_RESUME(c) \ (idn_chan_action((c), IDNCHAN_ACTION_RESUME, 0)) #define IDN_CHANNEL_STOP(c, w) \ (idn_chan_action((c), IDNCHAN_ACTION_STOP, (w))) #define IDN_CHANNEL_RESTART(c) \ (idn_chan_action((c), IDNCHAN_ACTION_RESTART, 0)) #define IDN_CHANNEL_DETACH(c, w) \ (idn_chan_action((c), IDNCHAN_ACTION_DETACH, (w))) #define IDN_CHANNEL_ATTACH(c) \ (idn_chan_action((c), IDNCHAN_ACTION_ATTACH, 0)) /* * ds_waittime range values. * When a packet arrives the waittime starts at MIN and gradually * shifts up to MAX until another packet arrives. If still no * packet arrives then we go to a hard sleep */ #define IDN_NETSVR_SPIN_COUNT idn_netsvr_spin_count #define IDN_NETSVR_WAIT_MIN idn_netsvr_wait_min #define IDN_NETSVR_WAIT_MAX idn_netsvr_wait_max #define IDN_NETSVR_WAIT_SHIFT idn_netsvr_wait_shift /* * --------------------------------------------------------------------- * IDN Global Data * * The comment to the right of the respective field represents * what lock protects that field. If there is no comment then * no lock is required to access the field. * --------------------------------------------------------------------- */ typedef struct idn_global { /* protected by... */ krwlock_t grwlock; /* * Global state of IDN w.r.t. * the local domain. */ idn_gstate_t state; /* grwlock */ /* * Version of the IDN driver. * Is passed in DMV header so that * other domains can validate they * support protocol used by local * domain. */ int version; /* * Set to 1 if SMR region properly * allocated and available. */ int enabled; /* * Local domains "domain id". */ int localid; /* * Domain id of the Master domain. * Set to IDN_NIL_DOMID if none * currently exists. */ int masterid; /* grwlock */ /* * Primarily used during Reconfiguration * to track the expected new Master. * Once the current IDN is dismantled * the local domain will attempt to * connect to this new domain. */ int new_masterid; /* grwlock */ /* * Number of protocol servers configured. */ int nservers; dev_info_t *dip; struct { /* * dmv_inum * Interrupt number assigned by * DMV subsystem to IDN's DMV * handler. * soft_inum * Soft interrupt number assigned * by OS (add_softintr) for Soft * interrupt dispatched by DMV * handler. */ uint_t dmv_inum; uint_t soft_inum; caddr_t dmv_data; size_t dmv_data_len; } intr; /* * first_swlink * Used as synchronization to * know whether channels need * to be activated or not. * first_hwlink * Used as mechanism to determine * whether local domain needs * to publicize its SMR, assuming * it is the Master. * first_hwmaster * Domainid of the domain that * was the master at the time * the hardware was programmed. * We need to keep this so that * we deprogram with respect to * the correct domain that the * hardware was originally * programmed to. */ lock_t first_swlink; lock_t first_hwlink; short first_hwmasterid; /* * The xmit* fields are used to set-up a background * thread to monitor when a channel is ready to be * enabled again. This is necessary since IDN * can't rely on hardware to interrupt it when * things are ready to go. We need this ability * to wakeup our STREAMS queues. * Criteria for reenabling queues. * gstate == IDNGS_ONLINE * channel = !check-in * buffers are available * * xmit_chanset_wanted * Indicates which channels wish to have * their queues reenabled when ready. * xmit_tid * Timeout-id of monitor. */ kmutex_t xmit_lock; idn_chanset_t xmit_chanset_wanted; /* xmit_lock */ timeout_id_t xmit_tid; /* xmit_lock */ struct { /* * ready * Indicates SMR region allocated * and available from OBP. * vaddr * Virtual address assigned to SMR. * locpfn * Page Frame Number associated * with local domain's SMR. * rempfn * Page Frame Number associated * with remote (Master) domain's SMR. * rempfnlim * PFN past end of remote domain's * SMR. * prom_paddr/prom_size * Physical address and size of * SMR that were assigned by OBP. */ int ready; caddr_t vaddr; pfn_t locpfn; pfn_t rempfn; /* grwlock */ pfn_t rempfnlim; /* grwlock */ uint64_t prom_paddr; uint64_t prom_size; } smr; /* * idnsb_mutex * Protects access to IDN's * sigblock area. * idnsb_eventp * IDN's private area in sigblock * used for signaling events * regarding IDN state to SSP. * idnsb * Area within IDN's private * sigblock area used for tracking * certain IDN state which might * be useful during arbstop * conditions (if caused by IDN!). */ kmutex_t idnsb_mutex; idnsb_event_t *idnsb_eventp; idnsb_t *idnsb; struct sigbintr { /* * sb_mutex * Protects sigbintr elements * to synchronize execution of * sigblock (IDN) mailbox handling. * sb_cpuid * Cpu whose sigblock mailbox * originally received IDN request * from SSP. Necessary to know * where to put response. * sb_busy * Flag indicating state of * sigblock handler thread. * Synchronize activity between * SSP and current IDN requests that * are in progress. * sb_cv * Condition variable for sigblock * handler thread to wait on. * sb_inum * Soft interrupt number assigned * by OS to handle soft interrupt * request make by low-level (IDN) * sigblock handler to dispatch actual * processing of sigblock (mailbox) * request. */ kmutex_t sb_mutex; uchar_t sb_cpuid; /* sigbintr.sb_mutex */ uchar_t sb_busy; /* sigbintr.sb_mutex */ kcondvar_t sb_cv; /* sigbintr.sb_mutex */ uint_t sb_inum; /* sigbintr.sb_mutex */ } sigbintr; /* * struprwlock, strup, sip, siplock * Standard network streams * handling structures to manage * instances of IDN driver. */ krwlock_t struprwlock; struct idnstr *strup; /* struprwlock */ struct idn *sip; /* siplock */ kmutex_t sipwenlock; kmutex_t siplock; /* * Area where IDN maintains its kstats. */ kstat_t *ksp; /* * Number of domains that local domain * has "open". */ int ndomains; /* grwlock */ /* * Number of domains that local domain * has registered as non-responsive. */ int nawols; /* grwlock */ /* * Number of network channels (interfaces) * which are currently active. */ int nchannels; /* grwlock */ /* * Bitmask representing channels * that are currently active. */ idn_chanset_t chanset; /* grwlock */ /* * Array of channel (network/data) servers * that have been created. Not necessarily * all active. */ idn_chansvr_t *chan_servers; /* elmts = ch_mutex */ /* * Pointer to sigblock handler thread * which ultimately processes SSP * IDN requests. */ kthread_id_t sigb_threadp; /* * Pointer to area used by Master * to hold mailbox structures. * Actual memory is in SMR. */ idn_mboxtbl_t *mboxarea; /* grwlock */ struct { /* * IDN_SYNC_LOCK - Provides serialization * mechanism when performing synchronous * operations across domains. */ kmutex_t sz_mutex; /* * Actual synchronization zones for * CONNECT/DISCONNECT phases. */ idn_synczone_t sz_zone[IDN_SYNC_NUMZONE]; } sync; /* sz_mutex */ struct { /* * ds_trans_on * Set of domains which are trying * to establish a link w/local. * ds_ready_on * Set of domains which local knows * are ready for linking, but has * not yet confirmed w/peers. * ds_connected * Set of domains that local has * confirmed as being ready. * ds_trans_off * Set of domains which are trying * to unlink from local. * ds_ready_off * Set of domains which local knows * are ready for unlink, but has * not yet confirmed w/peers. * ds_relink * Set of domains we're expecting * to relink with subsequent to * a RECONFIG (new master selection). * ds_hwlinked * Set of domains for which local * has programmed its hardware. * ds_flush * Set of domains requiring that * local flush its ecache prior * to unlinking. * ds_awol * Set of domains believed to be * AWOL - haven't responded to * any queries. * ds_hitlist * Set of domains which local domain * is unlinking from and wishes to ignore * any extraneous indirect link requests * from other domains, e.g. during a * Reconfig. */ domainset_t ds_trans_on; /* sz_mutex */ domainset_t ds_ready_on; /* sz_mutex */ domainset_t ds_connected; /* sz_mutex */ domainset_t ds_trans_off; /* sz_mutex */ domainset_t ds_ready_off; /* sz_mutex */ domainset_t ds_relink; /* sz_mutex */ domainset_t ds_hwlinked; /* sz_mutex */ domainset_t ds_flush; /* sz_mutex */ domainset_t ds_awol; /* sz_mutex */ domainset_t ds_hitlist; /* sz_mutex */ } domset; /* * Bitmask identifying all cpus in * the local IDN. */ cpuset_t dc_cpuset; /* * Bitmask identifying all boards in * the local IDN. */ boardset_t dc_boardset; struct dopers { /* * Waiting area for IDN requests, * i.e. link & unlinks. IDN requests * are performed asynchronously so * we need a place to wait until the * operation has completed. * * dop_domset * Identifies which domains the * current waiter is interested in. * dop_waitcount * Number of waiters in the room. * dop_waitlist * Actual waiting area. * dop_freelist * Freelist (small cache) of * structs for waiting area. */ kmutex_t dop_mutex; kcondvar_t dop_cv; /* dop_mutex */ domainset_t dop_domset; /* dop_mutex */ int dop_waitcount; /* dop_mutex */ dop_waitlist_t *dop_waitlist; /* dop_mutex */ dop_waitlist_t *dop_freelist; /* dop_mutex */ /* dop_mutex */ dop_waitlist_t _dop_wcache[IDNOP_CACHE_SIZE]; } *dopers; struct { /* * Protocol Server: * * p_server * Linked list of queues * describing protocol * servers in use. * p_jobpool * Kmem cache of structs * used to enqueue protocol * jobs for protocol servers. * p_morgue * Synchronization (check-in) * area used when terminating * protocol servers (threads). */ struct idn_protoqueue *p_serverq; kmem_cache_t *p_jobpool; ksema_t p_morgue; } protocol; struct idn_retry_queue { /* * rq_jobs * Queue of Retry jobs * that are outstanding. * rq_count * Number of jobs on retry * queue. * rq_cache * Kmem cache for structs * used to describe retry * jobs. */ idn_retry_job_t *rq_jobs; /* rq_mutex */ int rq_count; /* rq_mutex */ kmutex_t rq_mutex; /* rq_mutex */ kcondvar_t rq_cv; /* rq_mutex */ kmem_cache_t *rq_cache; } retryqueue; struct slabpool { /* * Slabpool: * * ntotslabs * Total number of slabs * in SMR (free & in-use). * npools * Number of pools available * in list. One smr_slabtbl * exists for each pool. */ int ntotslabs; int npools; struct smr_slabtbl { /* * sarray * Array of slab structs * representing slabs in SMR. * nfree * Number of slabs actually * available in sarray. * nslabs * Number of slabs represented * in sarray (free & in-use). */ smr_slab_t *sarray; int nfree; int nslabs; } *pool; /* * Holds array of smr_slab_t structs kmem_alloc'd * for slabpool. */ smr_slab_t *savep; } *slabpool; struct slabwaiter { /* * Waiting area for threads * requesting slab allocations. * Used by Slaves for all requests, * but used by Master only for * redundant requests, i.e. multiple * requests on behalf of the same * domain. One slabwaiter area * exist for each possible domain. * * w_nwaiters * Number of threads waiting * in waiting area. * w_done * Flag to indicate that * allocation request has * completed. * w_serrno * Non-zero indicates an * errno value to represent * error that occurred during * attempt to allocate slab. * w_closed * Indicates that waiting area is * closed and won't allow any new * waiters. This occurs during * the small window where we're * trying to suspend a channel. * w_cv * Condvar for waiting on. * w_sp * Holds slab structure of * successfully allocated slab. */ kmutex_t w_mutex; short w_nwaiters; /* w_mutex */ short w_done; /* w_mutex */ short w_serrno; /* w_mutex */ short w_closed; /* w_mutex */ kcondvar_t w_cv; /* w_mutex */ smr_slab_t *w_sp; /* w_mutex */ } *slabwaiter; /* * Kmem cache used for allocating * timer structures for outstanding * IDN requests. */ kmem_cache_t *timer_cache; /* * Effectively constant used in * translating buffer frames in * mailbox message frames to * offsets within SMR. */ int bframe_shift; } idn_global_t; typedef struct idn_retry_queue idn_retry_queue_t; #define IDN_GET_MASTERID() (idn.masterid) #define IDN_SET_MASTERID(mid) \ { \ int _mid = (mid); \ mutex_enter(&idn.idnsb_mutex); \ if (idn.idnsb) { \ idn.idnsb->id_pmaster_board = \ idn.idnsb->id_master_board; \ if (_mid == IDN_NIL_DOMID) \ idn.idnsb->id_master_board = (uchar_t)0xff; \ else \ idn.idnsb->id_master_board = \ (uchar_t)idn_domain[_mid].dvote.v.board; \ } \ mutex_exit(&idn.idnsb_mutex); \ IDN_HISTORY_LOG(IDNH_MASTERID, _mid, idn.masterid, 0); \ PR_STATE("%d: MASTERID %d -> %d\n", __LINE__, \ idn.masterid, _mid); \ idn.masterid = _mid; \ } #define IDN_GET_NEW_MASTERID() (idn.new_masterid) #define IDN_SET_NEW_MASTERID(mid) \ { \ PR_STATE("%d: NEW MASTERID %d -> %d\n", __LINE__, \ idn.new_masterid, (mid)); \ idn.new_masterid = (mid); \ } #define IDN_GLOCK_EXCL() (rw_enter(&idn.grwlock, RW_WRITER)) #define IDN_GLOCK_SHARED() (rw_enter(&idn.grwlock, RW_READER)) #define IDN_GLOCK_TRY_SHARED() (rw_tryenter(&idn.grwlock, RW_READER)) #define IDN_GLOCK_DOWNGRADE() (rw_downgrade(&idn.grwlock)) #define IDN_GUNLOCK() (rw_exit(&idn.grwlock)) #define IDN_GLOCK_IS_EXCL() (RW_WRITE_HELD(&idn.grwlock)) #define IDN_GLOCK_IS_SHARED() (RW_READ_HELD(&idn.grwlock)) #define IDN_GLOCK_IS_HELD() (RW_LOCK_HELD(&idn.grwlock)) #define IDN_SYNC_LOCK() (mutex_enter(&idn.sync.sz_mutex)) #define IDN_SYNC_TRYLOCK() (mutex_tryenter(&idn.sync.sz_mutex)) #define IDN_SYNC_UNLOCK() (mutex_exit(&idn.sync.sz_mutex)) #define IDN_SYNC_IS_LOCKED() (MUTEX_HELD(&idn.sync.sz_mutex)) /* * Macro to reset some globals necessary in preparing * for initialization of HW for IDN. */ #define IDN_PREP_HWINIT() \ { \ ASSERT(IDN_GLOCK_IS_EXCL()); \ lock_clear(&idn.first_swlink); \ lock_clear(&idn.first_hwlink); \ idn.first_hwmasterid = (short)IDN_NIL_DOMID; \ } /* * Return values of idn_send_data. */ #define IDNXMIT_OKAY 0 /* xmit successful */ #define IDNXMIT_LOOP 1 /* loopback */ #define IDNXMIT_DROP 2 /* drop packet */ #define IDNXMIT_RETRY 3 /* retry packet (requeue and qenable) */ #define IDNXMIT_REQUEUE 4 /* requeue packet, but don't qenable */ /* * --------------------------------------------------------------------- * ss_rwlock must be acquired _before_ any idn_domain locks are * acquired if both structs need to be accessed. * idn.struprwlock is acquired when traversing IDN's strup list * and when adding or deleting entries. * * ss_nextp Linked list of streams. * ss_rq Respective read queue. * ss_sip Attached device. * ss_state Current DL state. * ss_sap Bound SAP. * ss_flags Misc. flags. * ss_mccount # enabled multicast addrs. * ss_mctab Table of multicast addrs. * ss_minor Minor device number. * ss_rwlock Protects ss_linkup fields and DLPI state machine. * ss_linkup Boolean flag indicating whether particular (domain) link * is up. * --------------------------------------------------------------------- */ struct idnstr { /* gets shoved into q_ptr */ struct idnstr *ss_nextp; queue_t *ss_rq; struct idn *ss_sip; t_uscalar_t ss_state; t_uscalar_t ss_sap; uint_t ss_flags; uint_t ss_mccount; struct ether_addr *ss_mctab; minor_t ss_minor; krwlock_t ss_rwlock; }; /* * idnstr.ss_flags - Per-stream flags */ #define IDNSFAST 0x01 /* "M_DATA fastpath" mode */ #define IDNSRAW 0x02 /* M_DATA plain raw mode */ #define IDNSALLPHYS 0x04 /* "promiscuous mode" */ #define IDNSALLMULTI 0x08 /* enable all multicast addresses */ #define IDNSALLSAP 0x10 /* enable all ether type values */ /* * Maximum number of multicast address per stream. */ #define IDNMAXMC 64 #define IDNMCALLOC (IDNMAXMC * sizeof (struct ether_addr)) /* * Full DLSAP address length (in struct dladdr format). */ #define IDNADDRL (ETHERADDRL + sizeof (ushort_t)) struct idndladdr { struct ether_addr dl_phys; ushort_t dl_sap; }; #define IDNHEADROOM 64 #define IDNROUNDUP(a, n) (((a) + ((n) - 1)) & ~((n) - 1)) /* * Respective interpretation of bytes in 6 byte ethernet address. */ #define IDNETHER_ZERO 0 #define IDNETHER_COOKIE1 1 #define IDNETHER_COOKIE1_VAL 0xe5 #define IDNETHER_COOKIE2 2 #define IDNETHER_COOKIE2_VAL 0x82 #define IDNETHER_NETID 3 #define IDNETHER_CHANNEL 4 #define IDNETHER_RESERVED 5 #define IDNETHER_RESERVED_VAL 0x64 /* * IDN driver supports multliple instances, however they * still all refer to the same "physical" device. Multiple * instances are supported primarily to allow increased * STREAMs bandwidth since each instance has it's own IP queue. * This structure is primarily defined to be consistent with * other network drivers and also to hold the kernel stats. */ struct idn_kstat { ulong_t si_ipackets; /* # packets received */ ulong_t si_ierrors; /* # total input errors */ ulong_t si_opackets; /* # packets sent */ ulong_t si_oerrors; /* # total output errors */ ulong_t si_txcoll; /* # xmit collisions */ ulong_t si_rxcoll; /* # recv collisions */ ulong_t si_crc; /* # recv crc errors */ ulong_t si_buff; /* # recv pkt sz > buf sz */ ulong_t si_nolink; /* # loss of connection */ ulong_t si_linkdown; /* # link is down */ ulong_t si_inits; /* # driver inits */ ulong_t si_nocanput; /* # canput() failures */ ulong_t si_allocbfail; /* # allocb() failures */ ulong_t si_notbufs; /* # out of xmit buffers */ ulong_t si_reclaim; /* # reclaim failures */ ulong_t si_smraddr; /* # bad SMR addrs */ ulong_t si_txmax; /* # xmit over limit */ ulong_t si_txfull; /* # xmit mbox full */ ulong_t si_xdcall; /* # xdcalls sent */ ulong_t si_sigsvr; /* # data server wakeups */ ulong_t si_mboxcrc; /* # send mbox crc errors */ /* * MIB II kstat variables */ ulong_t si_rcvbytes; /* # bytes received */ ulong_t si_xmtbytes; /* # bytes transmitted */ ulong_t si_multircv; /* # multicast packets received */ ulong_t si_multixmt; /* # multicast packets for xmit */ ulong_t si_brdcstrcv; /* # broadcast packets received */ ulong_t si_brdcstxmt; /* # broadcast packets for xmit */ ulong_t si_norcvbuf; /* # rcv packets discarded */ ulong_t si_noxmtbuf; /* # xmit packets discarded */ /* * PSARC 1997/198 : 64 bit kstats */ uint64_t si_ipackets64; /* # packets received */ uint64_t si_opackets64; /* # packets transmitted */ uint64_t si_rbytes64; /* # bytes received */ uint64_t si_obytes64; /* # bytes transmitted */ /* * PSARC 1997/247 : RFC 1643 dot3Stats... */ ulong_t si_fcs_errors; /* FCSErrors */ ulong_t si_macxmt_errors; /* InternalMacTransmitErrors */ ulong_t si_toolong_errors; /* FrameTooLongs */ ulong_t si_macrcv_errors; /* InternalMacReceiveErrors */ }; /* * Per logical interface private data structure. */ struct idn { struct idn *si_nextp; /* linked instances */ dev_info_t *si_dip; /* assoc. dev_info */ struct ether_addr si_ouraddr; /* enet address */ uint_t si_flags; /* misc. flags */ uint_t si_wantw; /* xmit: out of res. */ queue_t *si_ip4q; /* ip (v4) read queue */ queue_t *si_ip6q; /* ip (v6) read queue */ kstat_t *si_ksp; /* kstat pointer */ struct idn_kstat si_kstat; /* per-inst kstat */ }; struct idn_gkstat { ulong_t gk_reconfigs; /* # reconfigs */ ulong_t gk_reconfig_last; /* timestamep */ ulong_t gk_reaps; /* # of reap request */ ulong_t gk_reap_last; /* timestamep */ ulong_t gk_links; /* # of IDN links */ ulong_t gk_link_last; /* timestamep */ ulong_t gk_unlinks; /* # of IDN unlinks */ ulong_t gk_unlink_last; /* timestamep */ ulong_t gk_buffail; /* # bad bufalloc */ ulong_t gk_buffail_last; /* timestamp */ ulong_t gk_slabfail; /* # bad slaballoc */ ulong_t gk_slabfail_last; /* timestamp */ ulong_t gk_reap_count; /* # of slabs reaped */ ulong_t gk_dropped_intrs; /* dropped intrs */ }; extern struct idn_gkstat sg_kstat; #ifdef IDN_NO_KSTAT #define IDN_KSTAT_INC(s, i) #define IDN_KSTAT_ADD(s, i, n) #define IDN_GKSTAT_INC(i) #define IDN_GKSTAT_ADD(vvv, iii) #define IDN_GKSTAT_GLOBAL_EVENT(vvv, nnn) #else /* IDN_NO_KSTAT */ #define IDN_KSTAT_INC(sss, vvv) \ ((((struct idn *)(sss))->si_kstat.vvv)++) #define IDN_KSTAT_ADD(sss, vvv, nnn) \ ((((struct idn *)(sss))->si_kstat.vvv) += (nnn)) #define IDN_GKSTAT_INC(vvv) ((sg_kstat.vvv)++) #define IDN_GKSTAT_ADD(vvv, iii) ((sg_kstat.vvv) += (iii)) #define IDN_GKSTAT_GLOBAL_EVENT(vvv, ttt) \ ((sg_kstat.vvv)++, ((sg_kstat.ttt) = lbolt)) #endif /* IDN_NO_KSTAT */ /* * idn.si_flags */ #define IDNRUNNING 0x01 /* IDNnet is UP */ #define IDNPROMISC 0x02 /* promiscuous mode enabled */ #define IDNSUSPENDED 0x04 /* suspended (DR) */ typedef struct kstat_named kstate_named_t; struct idn_kstat_named { kstat_named_t sk_ipackets; /* # packets received */ kstat_named_t sk_ierrors; /* # total input errors */ kstat_named_t sk_opackets; /* # packets sent */ kstat_named_t sk_oerrors; /* # total output errors */ kstat_named_t sk_txcoll; /* # xmit collisions */ kstat_named_t sk_rxcoll; /* # recv collisions */ kstat_named_t sk_crc; /* # recv crc errors */ kstat_named_t sk_buff; /* # recv pkt sz > buf sz */ kstat_named_t sk_nolink; /* # loss of connection */ kstat_named_t sk_linkdown; /* # link is down */ kstat_named_t sk_inits; /* # driver inits */ kstat_named_t sk_nocanput; /* # canput() failures */ kstat_named_t sk_allocbfail; /* # allocb() failures */ kstat_named_t sk_notbufs; /* # out of xmit buffers */ kstat_named_t sk_reclaim; /* # reclaim failures */ kstat_named_t sk_smraddr; /* # bad SMR addrs */ kstat_named_t sk_txmax; /* # xmit over limit */ kstat_named_t sk_txfull; /* # xmit mbox full */ kstat_named_t sk_xdcall; /* # xdcalls sent */ kstat_named_t sk_sigsvr; /* # data server wakeups */ kstat_named_t sk_mboxcrc; /* # send mbox crc errors */ /* * MIB II kstat variables */ kstat_named_t sk_rcvbytes; /* # bytes received */ kstat_named_t sk_xmtbytes; /* # bytes transmitted */ kstat_named_t sk_multircv; /* # multicast packets received */ kstat_named_t sk_multixmt; /* # multicast packets for xmit */ kstat_named_t sk_brdcstrcv; /* # broadcast packets received */ kstat_named_t sk_brdcstxmt; /* # broadcast packets for xmit */ kstat_named_t sk_norcvbuf; /* # rcv packets discarded */ kstat_named_t sk_noxmtbuf; /* # xmit packets discarded */ /* * PSARC 1997/198 : 64bit kstats */ kstat_named_t sk_ipackets64; /* # packets received */ kstat_named_t sk_opackets64; /* # packets transmitted */ kstat_named_t sk_rbytes64; /* # bytes received */ kstat_named_t sk_obytes64; /* # bytes transmitted */ /* * PSARC 1997/247 : RFC 1643 dot3Stats... */ kstat_named_t sk_fcs_errors; /* FCSErr */ kstat_named_t sk_macxmt_errors; /* InternalMacXmtErr */ kstat_named_t sk_toolong_errors; /* FrameTooLongs */ kstat_named_t sk_macrcv_errors; /* InternalMacRcvErr */ }; /* * Stats for global events of interest (non-counters). */ struct idn_gkstat_named { kstat_named_t sk_curtime; /* current time */ kstat_named_t sk_reconfigs; /* # master recfgs */ kstat_named_t sk_reconfig_last; /* timestamp */ kstat_named_t sk_reaps; /* # of reap req */ kstat_named_t sk_reap_last; /* timestamp */ kstat_named_t sk_links; /* # of links */ kstat_named_t sk_link_last; /* timestamp */ kstat_named_t sk_unlinks; /* # of unlinks */ kstat_named_t sk_unlink_last; /* timestamp */ kstat_named_t sk_buffail; /* # bad buf alloc */ kstat_named_t sk_buffail_last; /* timestamp */ kstat_named_t sk_slabfail; /* # bad buf alloc */ kstat_named_t sk_slabfail_last; /* timestamp */ kstat_named_t sk_reap_count; /* # slabs reaped */ kstat_named_t sk_dropped_intrs; /* intrs dropped */ }; /* * --------------------------------------------------------------------- */ #ifdef DEBUG #define IDNXDC(d, mt, a1, a2, a3, a4) \ (debug_idnxdc("idnxdc", (int)(d), (mt), \ (uint_t)(a1), (uint_t)(a2), (uint_t)(a3), (uint_t)(a4))) #else /* DEBUG */ #define IDNXDC(d, mt, a1, a2, a3, a4) \ (idnxdc((int)(d), (mt), \ (uint_t)(a1), (uint_t)(a2), (uint_t)(a3), (uint_t)(a4))) #endif /* DEBUG */ #define IDNXDC_BROADCAST(ds, mt, a1, a2, a3, a4) \ (idnxdc_broadcast((domainset_t)(ds), (mt), \ (uint_t)(a1), (uint_t)(a2), (uint_t)(a3), (uint_t)(a4))) /* * --------------------------------------------------------------------- */ #define SET_XARGS(x, a0, a1, a2, a3) \ ((x)[0] = (uint_t)(a0), (x)[1] = (uint_t)(a1), \ (x)[2] = (uint_t)(a2), (x)[3] = (uint_t)(a3)) #define GET_XARGS(x, a0, a1, a2, a3) \ (((a0) ? *(uint_t *)(a0) = (x)[0] : 1), \ ((a1) ? *(uint_t *)(a1) = (x)[1] : 1), \ ((a2) ? *(uint_t *)(a2) = (x)[2] : 1), \ ((a3) ? *(uint_t *)(a3) = (x)[3] : 1)) #define CLR_XARGS(x) \ ((x)[0] = (x)[1] = (x)[2] = (x)[3] = 0) #define GET_XARGS_NEGO_TICKET(x) ((uint_t)(x)[0]) #define GET_XARGS_NEGO_DSET(x, d) \ ((d)[0] = (x)[1], (d)[1] = (x)[2], (d)[2] = (x)[3]) #define SET_XARGS_NEGO_TICKET(x, t) ((x)[0] = (uint_t)(t)) #define SET_XARGS_NEGO_DSET(x, d) \ ((x)[1] = (uint_t)(d)[0], \ (x)[2] = (uint_t)(d)[1], \ (x)[3] = (uint_t)(d)[2]) #define GET_XARGS_CON_TYPE(x) ((idn_con_t)(x)[0]) #define GET_XARGS_CON_DOMSET(x) ((domainset_t)(x)[1]) #define SET_XARGS_CON_TYPE(x, t) ((x)[0] = (uint_t)(t)) #define SET_XARGS_CON_DOMSET(x, s) ((x)[1] = (uint_t)(s)) #define GET_XARGS_FIN_TYPE(x) GET_FIN_TYPE((x)[0]) #define GET_XARGS_FIN_ARG(x) GET_FIN_ARG((x)[0]) #define GET_XARGS_FIN_DOMSET(x) ((domainset_t)(x)[1]) #define GET_XARGS_FIN_OPT(x) ((idn_finopt_t)(x)[2]) #define GET_XARGS_FIN_MASTER(x) ((uint_t)(x)[3]) #define SET_XARGS_FIN_TYPE(x, t) SET_FIN_TYPE((x)[0], (t)) #define SET_XARGS_FIN_ARG(x, a) SET_FIN_ARG((x)[0], (a)) #define SET_XARGS_FIN_DOMSET(x, s) ((x)[1] = (uint_t)(s)) #define SET_XARGS_FIN_OPT(x, o) ((x)[2] = (uint_t)(o)) #define SET_XARGS_FIN_MASTER(x, m) ((x)[3] = (uint_t)(m)) #define GET_XARGS_NACK_TYPE(x) ((idn_nack_t)(x)[0]) #define GET_XARGS_NACK_ARG1(x) ((x)[1]) #define GET_XARGS_NACK_ARG2(x) ((x)[2]) #define SET_XARGS_NACK_TYPE(x, t) ((x)[0] = (uint_t)(t)) #define SET_XARGS_NACK_ARG1(x, a1) ((x)[1] = (uint_t)(a1)) #define SET_XARGS_NACK_ARG2(x, a2) ((x)[2] = (uint_t)(a2)) #define GET_XARGS_CFG_PHASE(x) ((int)(x)[0]) #define SET_XARGS_CFG_PHASE(x, p) ((x)[0] = (uint_t)(p)) /* * --------------------------------------------------------------------- */ /* * Device instance to SIP (IDN instance pointer). */ #ifdef DEBUG #define IDN_INST2SIP(i) \ (ASSERT(((i) >= 0) && ((i) < (IDN_MAXMAX_NETS << 1))), \ idn_i2s_table[i]) #else /* DEBUG */ #define IDN_INST2SIP(i) (idn_i2s_table[i]) #endif /* DEBUG */ #define IDN_SET_INST2SIP(i, s) \ { \ ASSERT(((i) >= 0) && ((i) < (IDN_MAXMAX_NETS << 1))); \ idn_i2s_table[i] = (s); \ } #define IDN_NETID2DOMID(n) (VALID_UDOMAINID(n) ? \ ((int)(n)) : IDN_NIL_DOMID) #define IDN_DOMID2NETID(d) ((ushort_t)(d)) #ifdef DEBUG #define IDNDL_ETHER2DOMAIN(eap) \ (_idndl_ether2domain(eap)) #define IDNDL_ETHER2SIP(eap) \ (_idndl_ether2sip(eap)) #else /* * The following values can be returned from IDNDL_ETHER2DOMAIN: * IDN_NIL_DOMID * Ether address is broadcast (0xff) or domain doesn't exist. * domid Domain id with drwlock(reader) held. */ #define IDNDL_ETHER2DOMAIN(eap) \ (IDN_NETID2DOMID((eap)->ether_addr_octet[IDNETHER_NETID])) #define IDNDL_ETHER2SIP(eap) \ (((eap)->ether_addr_octet[IDNETHER_CHANNEL] == 0xff) ? NULL : \ IDN_INST2SIP((int)(eap)->ether_addr_octet[IDNETHER_CHANNEL])) #endif /* DEBUG */ #define UPPER32_CPUMASK(s) _upper32cpumask(s) #define LOWER32_CPUMASK(s) _lower32cpumask(s) #define MAKE64_CPUMASK(s, u, l) _make64cpumask(&(s), (u), (l)) #ifdef DEBUG extern caddr_t _idn_getstruct(char *structname, int size); extern void _idn_freestruct(caddr_t ptr, char *structname, int size); #define GETSTRUCT(structure, num) \ ((structure *)_idn_getstruct("structure", sizeof (structure)*(num))) #define FREESTRUCT(ptr, structure, num) \ (_idn_freestruct((caddr_t)ptr, "structure", sizeof (structure)*(num))) #else /* DEBUG */ #define GETSTRUCT(structure, num) \ ((structure *)kmem_zalloc((uint_t)(sizeof (structure) * (num)), \ KM_SLEEP)) #define FREESTRUCT(ptr, structure, num) \ (kmem_free((caddr_t)(ptr), sizeof (structure) * (num))) #endif /* DEBUG */ extern int idn_debug; extern idn_global_t idn; extern idn_domain_t idn_domain[]; extern struct idn *idn_i2s_table[]; extern int idn_history; extern struct idn_history idnhlog; extern int idn_smr_size; extern int idn_nwr_size; extern int idn_protocol_nservers; extern int idn_awolmsg_interval; extern int idn_smr_bufsize; extern int idn_slab_bufcount; extern int idn_slab_prealloc; extern int idn_slab_mintotal; extern int idn_window_max; extern int idn_window_incr; extern int idn_reclaim_min; extern int idn_reclaim_max; extern int idn_mbox_per_net; extern int idn_max_nets; extern int idn_netsvr_spin_count; extern int idn_netsvr_wait_min; extern int idn_netsvr_wait_max; extern int idn_netsvr_wait_shift; extern int idn_checksum; extern int idn_msgwait_nego; extern int idn_msgwait_cfg; extern int idn_msgwait_con; extern int idn_msgwait_fin; extern int idn_msgwait_cmd; extern int idn_msgwait_data; extern int idn_retryfreq_nego; extern int idn_retryfreq_con; extern int idn_retryfreq_fin; extern int idn_window_emax; /* calculated */ extern int idn_slab_maxperdomain; /* calculated */ /* * --------------------------------------------------------------------- * io/idn.c * --------------------------------------------------------------------- */ extern int board_to_ready_cpu(int board, cpuset_t cpuset); extern int idn_open_domain(int domid, int cpuid, uint_t ticket); extern void idn_close_domain(int domid); extern void inum2str(uint_t inum, char str[]); extern idn_timer_t *idn_timer_alloc(); extern void idn_timer_free(idn_timer_t *tp); extern void idn_timerq_init(idn_timerq_t *tq); extern void idn_timerq_deinit(idn_timerq_t *tq); extern void idn_timerq_free(idn_timerq_t *tq); extern ushort_t idn_timer_start(idn_timerq_t *tq, idn_timer_t *tp, clock_t tval); extern int idn_timer_stopall(idn_timer_t *tp); extern void idn_timer_dequeue(idn_timerq_t *tq, idn_timer_t *tp); extern void idn_timer_stop(idn_timerq_t *tq, int subtype, ushort_t tcookie); extern idn_timer_t *idn_timer_get(idn_timerq_t *tq, int subtype, ushort_t tcookie); extern void idn_domain_resetentry(idn_domain_t *dp); extern void idn_strlinks_enable(uint_t netaddr, int domid); extern void idn_strlinks_disable(uint_t domset, uint_t netaddr, int disconnect); extern void idn_dopcache_init(); extern void idn_dopcache_deinit(); extern void *idn_init_op(idn_opflag_t opflag, boardset_t boardset, idnsb_error_t *sep); extern void idn_add_op(idn_opflag_t opflag, domainset_t domset); extern void idn_update_op(idn_opflag_t opflag, domainset_t domset, idnsb_error_t *sep); extern void idn_deinit_op(void *cookie); extern int idn_wait_op(void *cookie, boardset_t *domsetp, int wait_timeout); extern int idn_wakeup_op(boardset_t boardset, uint_t domset, idn_opflag_t opflag, int error); extern void idn_error_op(uint_t domset, boardset_t boardset, int error); extern void cpuset2str(cpuset_t cset, char buffer[]); extern void domainset2str(domainset_t dset, char buffer[]); extern void boardset2str(boardset_t bset, char buffer[]); extern void mask2str(uint_t mask, char buffer[], int maxnum); extern int idnxdc(int domid, idn_msgtype_t *mtp, uint_t arg1, uint_t arg2, uint_t arg3, uint_t arg4); extern void idnxdc_broadcast(domainset_t domset, idn_msgtype_t *mtp, uint_t arg1, uint_t arg2, uint_t arg3, uint_t arg4); extern void idn_awol_event_set(boardset_t boardset); extern void idn_awol_event_clear(boardset_t boardset); #ifdef DEBUG extern int debug_idnxdc(char *f, int domid, idn_msgtype_t *mtp, uint_t arg1, uint_t arg2, uint_t arg3, uint_t arg4); #endif /* DEBUG */ extern boardset_t cpuset2boardset(cpuset_t portset); extern uint_t _upper32cpumask(cpuset_t cset); extern uint_t _lower32cpumask(cpuset_t cset); extern void _make64cpumask(cpuset_t *csetp, uint_t upper, uint_t lower); /* * --------------------------------------------------------------------- * io/idn_proto.c * --------------------------------------------------------------------- */ extern void idn_assign_cookie(int domid); extern int idn_rput_data(queue_t *q, mblk_t *mp, int isput); extern int idn_wput_data(queue_t *q, mblk_t *mp, int isput); extern int idn_send_data(int dst_domid, idn_netaddr_t dst_netaddr, queue_t *wq, mblk_t *mp); extern void idn_recv_signal(mblk_t *mp); extern int idn_link(int domid, int cpuid, int pri, int waittime, idnsb_error_t *sep); extern int idn_unlink(int domid, boardset_t idnset, idn_fin_t fintype, idn_finopt_t finopt, int waittime, idnsb_error_t *sep); extern int idnh_recv_dataack(int domid, int src_proc, uint_t acknack, idn_xdcargs_t xargs); extern int idnh_recv_other(int sourceid, int src_proc, int dst_proc, uint_t inum, uint_t acknack, idn_xdcargs_t xargs); extern void idn_send_cmd(int domid, idn_cmd_t cmdtype, uint_t arg1, uint_t arg2, uint_t arg3); extern void idn_send_cmdresp(int domid, idn_msgtype_t *mtp, idn_cmd_t cmdtype, uint_t arg1, uint_t arg2, uint_t cerrno); extern void idn_broadcast_cmd(idn_cmd_t cmdtype, uint_t arg1, uint_t arg2, uint_t arg3); extern int idn_reclaim_mboxdata(int domid, int channel, int nbufs); extern void idn_clear_awol(int domid); extern int idn_protocol_init(int nservers); extern void idn_protocol_deinit(); extern void idn_timer_expired(void *arg); extern int idn_open_channel(int channel); extern void idn_close_channel(int channel, idn_chanop_t chanop); extern idn_mainmbox_t *idn_mainmbox_init(int domid, int mbx); extern void idn_mainmbox_deinit(int domid, idn_mainmbox_t *mmp); extern void idn_signal_data_server(int domid, ushort_t channel); extern int idn_chanservers_init(); extern void idn_chanservers_deinit(); extern void idn_chanserver_bind(int net, int cpuid); extern int idn_retry_terminate(uint_t token); extern idn_protojob_t *idn_protojob_alloc(int kmflag); extern void idn_protojob_submit(int cookie, idn_protojob_t *jp); extern int idn_domain_is_registered(int domid, int channel, idn_chanset_t *chansetp); extern void idn_xmit_monitor_kickoff(int chan_wanted); extern void idn_sync_exit(int domid, idn_synccmd_t cmd); /* * --------------------------------------------------------------------- * io/idn_xf.c * --------------------------------------------------------------------- */ extern void idnxf_flushall_ecache(); extern int idnxf_shmem_add(int is_master, boardset_t boardset, pfn_t pfnbase, pfn_t pfnlimit, uint_t *mcadr); extern int idnxf_shmem_sub(int is_master, boardset_t boardset); extern int idn_cpu_per_board(void *p2o, cpuset_t cset, struct hwconfig *hwp); /* * --------------------------------------------------------------------- * io/idn_dlpi.c * --------------------------------------------------------------------- */ extern int idndl_init(struct idn *sip); extern void idndl_uninit(struct idn *sip); extern void idndl_statinit(struct idn *sip); extern void idndl_dodetach(struct idnstr *); extern int idnioc_dlpi(queue_t *wq, mblk_t *mp, int *argsize); extern void idndl_localetheraddr(struct idn *sip, struct ether_addr *eap); extern int idndl_domain_etheraddr(int domid, int instance, struct ether_addr *eap); extern void idndl_dlpi_init(); extern int idndl_start(queue_t *wq, mblk_t *mp, struct idn *sip); extern void idndl_read(struct idn *sip, mblk_t *mp); extern void idndl_proto(queue_t *wq, mblk_t *mp); extern void idndl_sendup(struct idn *, mblk_t *, struct idnstr *(*)()); extern struct idnstr *idndl_accept(struct idnstr *, struct idn *, int, struct ether_addr *); extern struct idnstr *idndl_paccept(struct idnstr *, struct idn *, int, struct ether_addr *); extern void idndl_wenable(struct idn *); /* * --------------------------------------------------------------------- * io/idn_smr.c * --------------------------------------------------------------------- */ extern void smr_slabwaiter_open(domainset_t domset); extern void smr_slabwaiter_close(domainset_t domset); /* * --------------------------------------------------------------------- */ extern void idn_smrsize_init(); extern void idn_init_autolink(); extern void idn_deinit_autolink(); extern void idn_dmv_handler(void *arg); extern void idnxf_init_mondo(uint64_t dmv_word0, uint64_t dmv_word1, uint64_t dmv_word2); extern int idnxf_send_mondo(int upaid); extern clock_t idn_msg_waittime[]; extern clock_t idn_msg_retrytime[]; #endif /* !_ASM */ #endif /* _KERNEL */ #ifndef _ASM /* * --------------------------------------------------------------------- */ #define IDN_NIL_DOMID -1 #define IDN_NIL_DCPU -1 /* * --------------------------------------------------------------------- */ /* * IOCTL Interface * * Commands must stay in the range (1 - 4096) since only 12 bits * are allotted. */ #define _IDN(n) (('I' << 20) | ('D' << 12) | (n)) #define IDNIOC_LINK _IDN(1) /* domain_link */ #define IDNIOC_UNLINK _IDN(2) /* domain_unlink */ #define IDNIOC_unused0 _IDN(3) #define IDNIOC_unused1 _IDN(4) #define IDNIOC_unused2 _IDN(5) #define IDNIOC_unused3 _IDN(6) #define IDNIOC_unused4 _IDN(7) #define IDNIOC_DLPI_ON _IDN(8) /* Turn ON DLPI on str */ #define IDNIOC_DLPI_OFF _IDN(9) /* Turn OFF DLPI on str */ #define IDNIOC_PING _IDN(10) /* For latency testing */ #define IDNIOC_PING_INIT _IDN(11) #define IDNIOC_PING_DEINIT _IDN(12) #define IDNIOC_MEM_RW _IDN(13) /* Random R/W of SMR */ #define VALID_NDOP(op) (((op) == ND_SET) || ((op) == ND_GET)) #define VALID_DLPIOP(op) (((op) == DLIOCRAW) || \ ((op) == DL_IOC_HDR_INFO)) #define VALID_IDNOP(op) (((op) >= _IDN(1)) && ((op) <= _IDN(13))) #define VALID_IDNIOCTL(op) (VALID_IDNOP(op) || \ VALID_NDOP(op) || \ VALID_DLPIOP(op)) typedef union idnop { struct { int domid; /* input */ int cpuid; /* input */ int master; /* input */ int wait; /* input */ } link; struct { int domid; /* input */ int cpuid; /* input */ int force; /* input */ int wait; /* input */ } unlink; struct { int domid; /* input */ int cpuid; /* input */ } ping; struct { uint_t lo_off; /* input */ uint_t hi_off; /* input */ int blksize; /* input */ int num; /* input */ int rw; /* input */ int goawol; /* input */ } rwmem; } idnop_t; #ifdef _KERNEL /* * ndd support for IDN tunables. */ typedef struct idnparam { ulong_t sp_min; ulong_t sp_max; ulong_t sp_val; char *sp_name; } idnparam_t; extern idnparam_t idn_param_arr[]; #define idn_modunloadable idn_param_arr[0].sp_val #ifdef IDN_PERF #define _LP 0 #define _xxx_tbd idn_param_arr[_LP+1].sp_val #endif /* IDN_PERF */ /* * ===================================================================== */ /* * Some junk to pretty print board lists and cpu lists in * log/console messages. Length is big enough to display 64 double * digit cpus separated by a command and single space. (Board list * is similar, but only 16 entries possible. */ #define _DSTRLEN 400 #define ALLOC_DISPSTRING() ((char *)kmem_alloc(_DSTRLEN, KM_NOSLEEP)) #define FREE_DISPSTRING(b) (kmem_free((void *)(b), _DSTRLEN)) /* * These are declared in idn.c. */ extern const char *idnds_str[]; extern const char *idnxs_str[]; extern const char *idngs_str[]; extern const char *idncmd_str[]; extern const char *idncon_str[]; extern const char *idnfin_str[]; extern const char *idnfinarg_str[]; extern const char *idnfinopt_str[]; extern const char *idnreg_str[]; extern const char *idnnack_str[]; extern const char *idnop_str[]; extern const char *idnsync_str[]; extern const char *chanop_str[]; extern const char *chanaction_str[]; extern const char *inum_str[]; extern const int inum_bump; extern const int inum_max; extern const int acknack_shift; extern const char *timer_str[]; extern const char *res_str[]; #endif /* _KERNEL */ #endif /* !_ASM */ #ifdef __cplusplus } #endif #endif /* _SYS_IDN_H */