void
mark_nodevertex_as_node(devfs_handle_t vhdl, cnodeid_t cnodeid)
{
if (cnodeid == CNODEID_NONE)
return;
cnodeid_to_vertex(cnodeid) = vhdl;
labelcl_info_add_LBL(vhdl, INFO_LBL_CNODEID, INFO_DESC_EXPORT,
(arbitrary_info_t)cnodeid);
{
char cnodeid_buffer[10];
if (hwgraph_all_cnodes == GRAPH_VERTEX_NONE) {
(void)hwgraph_path_add( hwgraph_root,
EDGE_LBL_NODENUM,
&hwgraph_all_cnodes);
}
sprintf(cnodeid_buffer, "%d", cnodeid);
(void)hwgraph_edge_add( hwgraph_all_cnodes,
vhdl,
cnodeid_buffer);
}
}
static void
io_init_xswitch_widgets(vertex_hdl_t xswitchv, cnodeid_t cnode)
{
xwidgetnum_t widgetnum;
DBG("io_init_xswitch_widgets: xswitchv 0x%p for cnode %d\n", xswitchv, cnode);
for (widgetnum = HUB_WIDGET_ID_MIN; widgetnum <= HUB_WIDGET_ID_MAX; widgetnum++) {
io_xswitch_widget_init(xswitchv, cnodeid_to_vertex(cnode), widgetnum);
}
}
void
hubii_eint_init(cnodeid_t cnode)
{
int bit, rv;
ii_iidsr_u_t hubio_eint;
hubinfo_t hinfo;
cpuid_t intr_cpu;
devfs_handle_t hub_v;
ii_ilcsr_u_t ilcsr;
int bit_pos_to_irq(int bit);
int synergy_intr_connect(int bit, int cpuid);
hub_v = (devfs_handle_t)cnodeid_to_vertex(cnode);
ASSERT_ALWAYS(hub_v);
hubinfo_get(hub_v, &hinfo);
ASSERT(hinfo);
ASSERT(hinfo->h_cnodeid == cnode);
ilcsr.ii_ilcsr_regval = REMOTE_HUB_L(hinfo->h_nasid, IIO_ILCSR);
if ((ilcsr.ii_ilcsr_fld_s.i_llp_stat & 0x2) == 0) {
/*
* HUB II link is not up.
* Just disable LLP, and don't connect any interrupts.
*/
ilcsr.ii_ilcsr_fld_s.i_llp_en = 0;
REMOTE_HUB_S(hinfo->h_nasid, IIO_ILCSR, ilcsr.ii_ilcsr_regval);
return;
}
/* Select a possible interrupt target where there is a free interrupt
* bit and also reserve the interrupt bit for this IO error interrupt
*/
intr_cpu = intr_heuristic(hub_v,0,INTRCONNECT_ANYBIT,II_ERRORINT,hub_v,
"HUB IO error interrupt",&bit);
if (intr_cpu == CPU_NONE) {
printk("hubii_eint_init: intr_reserve_level failed, cnode %d", cnode);
return;
}
rv = intr_connect_level(intr_cpu, bit, 0, NULL);
synergy_intr_connect(bit, intr_cpu);
request_irq(bit_pos_to_irq(bit) + (intr_cpu << 8), hubii_eint_handler, 0, "SN hub error", (void *)hub_v);
ASSERT_ALWAYS(rv >= 0);
hubio_eint.ii_iidsr_regval = 0;
hubio_eint.ii_iidsr_fld_s.i_enable = 1;
hubio_eint.ii_iidsr_fld_s.i_level = bit;/* Take the least significant bits*/
hubio_eint.ii_iidsr_fld_s.i_node = COMPACT_TO_NASID_NODEID(cnode);
hubio_eint.ii_iidsr_fld_s.i_pi_id = cpuid_to_subnode(intr_cpu);
REMOTE_HUB_S(hinfo->h_nasid, IIO_IIDSR, hubio_eint.ii_iidsr_regval);
}
void
hubii_eint_init(cnodeid_t cnode)
{
int bit, rv;
ii_iidsr_u_t hubio_eint;
hubinfo_t hinfo;
cpuid_t intr_cpu;
vertex_hdl_t hub_v;
int bit_pos_to_irq(int bit);
ii_ilcsr_u_t ilcsr;
hub_v = (vertex_hdl_t)cnodeid_to_vertex(cnode);
ASSERT_ALWAYS(hub_v);
hubinfo_get(hub_v, &hinfo);
ASSERT(hinfo);
ASSERT(hinfo->h_cnodeid == cnode);
ilcsr.ii_ilcsr_regval = REMOTE_HUB_L(hinfo->h_nasid, IIO_ILCSR);
if ((ilcsr.ii_ilcsr_fld_s.i_llp_stat & 0x2) == 0) {
/*
* HUB II link is not up. Disable LLP. Clear old errors.
* Enable interrupts to handle BTE errors.
*/
ilcsr.ii_ilcsr_fld_s.i_llp_en = 0;
REMOTE_HUB_S(hinfo->h_nasid, IIO_ILCSR, ilcsr.ii_ilcsr_regval);
}
/* Select a possible interrupt target where there is a free interrupt
* bit and also reserve the interrupt bit for this IO error interrupt
*/
intr_cpu = intr_heuristic(hub_v,0,SGI_II_ERROR,0,hub_v,
"HUB IO error interrupt",&bit);
if (intr_cpu == CPU_NONE) {
printk("hubii_eint_init: intr_reserve_level failed, cnode %d", cnode);
return;
}
rv = intr_connect_level(intr_cpu, SGI_II_ERROR, 0, NULL);
request_irq(SGI_II_ERROR, hubii_eint_handler, SA_SHIRQ, "SN_hub_error", (void *)hub_v);
irq_desc(bit)->status |= SN2_IRQ_PER_HUB;
ASSERT_ALWAYS(rv >= 0);
hubio_eint.ii_iidsr_regval = 0;
hubio_eint.ii_iidsr_fld_s.i_enable = 1;
hubio_eint.ii_iidsr_fld_s.i_level = bit;/* Take the least significant bits*/
hubio_eint.ii_iidsr_fld_s.i_node = COMPACT_TO_NASID_NODEID(cnode);
hubio_eint.ii_iidsr_fld_s.i_pi_id = cpuid_to_subnode(intr_cpu);
REMOTE_HUB_S(hinfo->h_nasid, IIO_IIDSR, hubio_eint.ii_iidsr_regval);
}
static void __init
klhwg_add_xbow(cnodeid_t cnode, nasid_t nasid)
{
lboard_t *brd;
klxbow_t *xbow_p;
nasid_t hub_nasid;
cnodeid_t hub_cnode;
int widgetnum;
vertex_hdl_t xbow_v, hubv;
/*REFERENCED*/
graph_error_t err;
if (!(brd = find_lboard_nasid((lboard_t *)KL_CONFIG_INFO(nasid),
nasid, KLTYPE_IOBRICK_XBOW)))
return;
if (KL_CONFIG_DUPLICATE_BOARD(brd))
return;
if ((xbow_p = (klxbow_t *)find_component(brd, NULL, KLSTRUCT_XBOW))
== NULL)
return;
for (widgetnum = HUB_WIDGET_ID_MIN; widgetnum <= HUB_WIDGET_ID_MAX; widgetnum++) {
if (!XBOW_PORT_TYPE_HUB(xbow_p, widgetnum))
continue;
hub_nasid = XBOW_PORT_NASID(xbow_p, widgetnum);
if (hub_nasid == INVALID_NASID) {
printk(KERN_WARNING "hub widget %d, skipping xbow graph\n", widgetnum);
continue;
}
hub_cnode = nasid_to_cnodeid(hub_nasid);
if (hub_cnode == INVALID_CNODEID) {
continue;
}
hubv = cnodeid_to_vertex(hub_cnode);
err = hwgraph_path_add(hubv, EDGE_LBL_XTALK, &xbow_v);
if (err != GRAPH_SUCCESS) {
if (err == GRAPH_DUP)
printk(KERN_WARNING "klhwg_add_xbow: Check for "
"working routers and router links!");
printk("klhwg_add_xbow: Failed to add "
"edge: vertex 0x%p to vertex 0x%p,"
"error %d\n",
(void *)hubv, (void *)xbow_v, err);
return;
}
HWGRAPH_DEBUG(__FILE__, __FUNCTION__, __LINE__, xbow_v, NULL, "Created path for xtalk.\n");
xswitch_vertex_init(xbow_v);
NODEPDA(hub_cnode)->xbow_vhdl = xbow_v;
/*
* XXX - This won't work is we ever hook up two hubs
* by crosstown through a crossbow.
*/
if (hub_nasid != nasid) {
NODEPDA(hub_cnode)->xbow_peer = nasid;
NODEPDA(nasid_to_cnodeid(nasid))->xbow_peer =
hub_nasid;
}
}
}
/*
* Initialize all I/O on the specified node.
*/
static void
io_init_node(cnodeid_t cnodeid)
{
/*REFERENCED*/
vertex_hdl_t hubv, switchv, widgetv;
struct xwidget_hwid_s hwid;
hubinfo_t hubinfo;
int is_xswitch;
nodepda_t *npdap;
struct semaphore *peer_sema = 0;
uint32_t widget_partnum;
cpuid_t c = 0;
npdap = NODEPDA(cnodeid);
/*
* Get the "top" vertex for this node's hardware
* graph; it will carry the per-hub hub-specific
* data, and act as the crosstalk provider master.
* It's canonical path is probably something of the
* form /hw/module/%M/slot/%d/node
*/
hubv = cnodeid_to_vertex(cnodeid);
DBG("io_init_node: Initialize IO for cnode %d hubv(node) 0x%p npdap 0x%p\n", cnodeid, hubv, npdap);
ASSERT(hubv != GRAPH_VERTEX_NONE);
/*
* Read mfg info on this hub
*/
/*
* If nothing connected to this hub's xtalk port, we're done.
*/
early_probe_for_widget(hubv, &hwid);
if (hwid.part_num == XWIDGET_PART_NUM_NONE) {
#ifdef PROBE_TEST
if ((cnodeid == 1) || (cnodeid == 2)) {
int index;
for (index = 0; index < 600; index++)
DBG("Interfering with device probing!!!\n");
}
#endif
/* io_init_done takes cpu cookie as 2nd argument
* to do a restorenoderun for the setnoderun done
* at the start of this thread
*/
DBG("**** io_init_node: Node's 0x%p hub widget has XWIDGET_PART_NUM_NONE ****\n", hubv);
return;
/* NOTREACHED */
}
/*
* attach our hub_provider information to hubv,
* so we can use it as a crosstalk provider "master"
* vertex.
*/
xtalk_provider_register(hubv, &hub_provider);
xtalk_provider_startup(hubv);
/*
* Create a vertex to represent the crosstalk bus
* attached to this hub, and a vertex to be used
* as the connect point for whatever is out there
* on the other side of our crosstalk connection.
*
* Crosstalk Switch drivers "climb up" from their
* connection point to try and take over the switch
* point.
*
* Of course, the edges and verticies may already
* exist, in which case our net effect is just to
* associate the "xtalk_" driver with the connection
* point for the device.
*/
(void)hwgraph_path_add(hubv, EDGE_LBL_XTALK, &switchv);
DBG("io_init_node: Created 'xtalk' entry to '../node/' xtalk vertex 0x%p\n", switchv);
ASSERT(switchv != GRAPH_VERTEX_NONE);
(void)hwgraph_edge_add(hubv, switchv, EDGE_LBL_IO);
DBG("io_init_node: Created symlink 'io' from ../node/io to ../node/xtalk \n");
/*
* We need to find the widget id and update the basew_id field
* accordingly. In particular, SN00 has direct connected bridge,
* and hence widget id is Not 0.
*/
widget_partnum = (((*(volatile int32_t *)(NODE_SWIN_BASE(COMPACT_TO_NASID_NODEID(cnodeid), 0) + WIDGET_ID))) & WIDGET_PART_NUM) >> WIDGET_PART_NUM_SHFT;
if (widget_partnum == BRIDGE_WIDGET_PART_NUM ||
widget_partnum == XBRIDGE_WIDGET_PART_NUM){
npdap->basew_id = (((*(volatile int32_t *)(NODE_SWIN_BASE(COMPACT_TO_NASID_NODEID(cnodeid), 0) + BRIDGE_WID_CONTROL))) & WIDGET_WIDGET_ID);
DBG("io_init_node: Found XBRIDGE widget_partnum= 0x%x\n", widget_partnum);
} else if ((widget_partnum == XBOW_WIDGET_PART_NUM) ||
(widget_partnum == XXBOW_WIDGET_PART_NUM) ||
(widget_partnum == PXBOW_WIDGET_PART_NUM) ) {
/*
* Xbow control register does not have the widget ID field.
* So, hard code the widget ID to be zero.
*/
DBG("io_init_node: Found XBOW widget_partnum= 0x%x\n", widget_partnum);
npdap->basew_id = 0;
} else {
npdap->basew_id = (((*(volatile int32_t *)(NODE_SWIN_BASE(COMPACT_TO_NASID_NODEID(cnodeid), 0) + BRIDGE_WID_CONTROL))) & WIDGET_WIDGET_ID);
panic(" ****io_init_node: Unknown Widget Part Number 0x%x Widget ID 0x%x attached to Hubv 0x%p ****\n", widget_partnum, npdap->basew_id, (void *)hubv);
/*NOTREACHED*/
}
{
char widname[10];
sprintf(widname, "%x", npdap->basew_id);
(void)hwgraph_path_add(switchv, widname, &widgetv);
DBG("io_init_node: Created '%s' to '..node/xtalk/' vertex 0x%p\n", widname, widgetv);
ASSERT(widgetv != GRAPH_VERTEX_NONE);
}
nodepda->basew_xc = widgetv;
is_xswitch = xwidget_hwid_is_xswitch(&hwid);
/*
* Try to become the master of the widget. If this is an xswitch
* with multiple hubs connected, only one will succeed. Mastership
* of an xswitch is used only when touching registers on that xswitch.
* The slave xwidgets connected to the xswitch can be owned by various
* masters.
*/
if (device_master_set(widgetv, hubv) == 0) {
/* Only one hub (thread) per Crosstalk device or switch makes
* it to here.
*/
/*
* Initialize whatever xwidget is hanging off our hub.
* Whatever it is, it's accessible through widgetnum 0.
*/
hubinfo_get(hubv, &hubinfo);
(void)xwidget_register(&hwid, widgetv, npdap->basew_id, hubv, hubinfo->h_widgetid);
if (!is_xswitch) {
/* io_init_done takes cpu cookie as 2nd argument
* to do a restorenoderun for the setnoderun done
* at the start of this thread
*/
io_init_done(cnodeid,c);
/* NOTREACHED */
}
/*
* Special handling for Crosstalk Switches (e.g. xbow).
* We need to do things in roughly the following order:
* 1) Initialize xswitch hardware (done above)
* 2) Determine which hubs are available to be widget masters
* 3) Discover which links are active from the xswitch
* 4) Assign xwidgets hanging off the xswitch to hubs
* 5) Initialize all xwidgets on the xswitch
*/
DBG("call volunteer_for_widgets\n");
volunteer_for_widgets(switchv, hubv);
/* If there's someone else on this crossbow, recognize him */
if (npdap->xbow_peer != INVALID_NASID) {
nodepda_t *peer_npdap = NODEPDA(NASID_TO_COMPACT_NODEID(npdap->xbow_peer));
peer_sema = &peer_npdap->xbow_sema;
DBG("call volunteer_for_widgets again\n");
volunteer_for_widgets(switchv, peer_npdap->node_vertex);
}
assign_widgets_to_volunteers(switchv, hubv);
/* Signal that we're done */
if (peer_sema) {
up(peer_sema);
}
}
else {
/* Wait 'til master is done assigning widgets. */
down(&npdap->xbow_sema);
}
#ifdef PROBE_TEST
if ((cnodeid == 1) || (cnodeid == 2)) {
int index;
for (index = 0; index < 500; index++)
DBG("Interfering with device probing!!!\n");
}
#endif
/* Now both nodes can safely inititialize widgets */
io_init_xswitch_widgets(switchv, cnodeid);
io_link_xswitch_widgets(switchv, cnodeid);
/* io_init_done takes cpu cookie as 2nd argument
* to do a restorenoderun for the setnoderun done
* at the start of this thread
*/
io_init_done(cnodeid,c);
DBG("\nio_init_node: DONE INITIALIZED ALL I/O FOR CNODEID %d\n\n", cnodeid);
}
void
io_xswitch_widget_init(devfs_handle_t xswitchv,
devfs_handle_t hubv,
xwidgetnum_t widgetnum,
async_attach_t aa)
{
xswitch_info_t xswitch_info;
xwidgetnum_t hub_widgetid;
devfs_handle_t widgetv;
cnodeid_t cnode;
widgetreg_t widget_id;
nasid_t nasid, peer_nasid;
struct xwidget_hwid_s hwid;
hubinfo_t hubinfo;
/*REFERENCED*/
int rc;
char slotname[SLOTNUM_MAXLENGTH];
char pathname[128];
char new_name[64];
moduleid_t module;
slotid_t slot;
lboard_t *board = NULL;
char buffer[16];
slotid_t get_widget_slotnum(int xbow, int widget);
DBG("\nio_xswitch_widget_init: hubv 0x%p, xswitchv 0x%p, widgetnum 0x%x\n", hubv, xswitchv, widgetnum);
/*
* Verify that xswitchv is indeed an attached xswitch.
*/
xswitch_info = xswitch_info_get(xswitchv);
ASSERT(xswitch_info != NULL);
hubinfo_get(hubv, &hubinfo);
nasid = hubinfo->h_nasid;
cnode = NASID_TO_COMPACT_NODEID(nasid);
hub_widgetid = hubinfo->h_widgetid;
/* Who's the other guy on out crossbow (if anyone) */
peer_nasid = NODEPDA(cnode)->xbow_peer;
if (peer_nasid == INVALID_NASID)
/* If I don't have a peer, use myself. */
peer_nasid = nasid;
/* Check my xbow structure and my peer's */
if (!xbow_port_io_enabled(nasid, widgetnum) &&
!xbow_port_io_enabled(peer_nasid, widgetnum)) {
return;
}
if (xswitch_info_link_ok(xswitch_info, widgetnum)) {
char name[4];
/*
* If the current hub is not supposed to be the master
* for this widgetnum, then skip this widget.
*/
if (xswitch_info_master_assignment_get(xswitch_info,
widgetnum) != hubv) {
return;
}
module = NODEPDA(cnode)->module_id;
#ifdef XBRIDGE_REGS_SIM
/* hardwire for now...could do this with something like:
* xbow_soft_t soft = hwgraph_fastinfo_get(vhdl);
* xbow_t xbow = soft->base;
* xbowreg_t xwidget_id = xbow->xb_wid_id;
* but I don't feel like figuring out vhdl right now..
* and I know for a fact the answer is 0x2d000049
*/
DBG("io_xswitch_widget_init: XBRIDGE_REGS_SIM FIXME: reading xwidget id: hardwired to xbridge (0x2d000049).\n");
DBG("XWIDGET_PART_NUM(0x2d000049)= 0x%x\n", XWIDGET_PART_NUM(0x2d000049));
if (XWIDGET_PART_NUM(0x2d000049)==XXBOW_WIDGET_PART_NUM) {
#else
if (nasid_has_xbridge(nasid)) {
#endif /* XBRIDGE_REGS_SIM */
board = find_lboard_module_class(
(lboard_t *)KL_CONFIG_INFO(nasid),
module,
KLTYPE_IOBRICK);
DBG("io_xswitch_widget_init: Board 0x%p\n", board);
{
lboard_t dummy;
if (board) {
DBG("io_xswitch_widget_init: Found KLTYPE_IOBRICK Board 0x%p brd_type 0x%x\n", board, board->brd_type);
} else {
DBG("io_xswitch_widget_init: FIXME did not find IOBOARD\n");
board = &dummy;
}
}
/*
* Make sure we really want to say xbrick, pbrick,
* etc. rather than XIO, graphics, etc.
*/
#ifdef SUPPORT_PRINTING_M_FORMAT
sprintf(pathname, EDGE_LBL_MODULE "/%M/"
"%cbrick" "/%s/%d",
NODEPDA(cnode)->module_id,
#else
memset(buffer, 0, 16);
format_module_id(buffer, NODEPDA(cnode)->module_id, MODULE_FORMAT_BRIEF);
sprintf(pathname, EDGE_LBL_MODULE "/%s/"
"%cbrick" "/%s/%d",
buffer,
#endif
(board->brd_type == KLTYPE_IBRICK) ? 'I' :
(board->brd_type == KLTYPE_PBRICK) ? 'P' :
(board->brd_type == KLTYPE_XBRICK) ? 'X' : '?',
EDGE_LBL_XTALK, widgetnum);
}
DBG("io_xswitch_widget_init: path= %s\n", pathname);
rc = hwgraph_path_add(hwgraph_root, pathname, &widgetv);
ASSERT(rc == GRAPH_SUCCESS);
/* This is needed to let the user programs to map the
* module,slot numbers to the corresponding widget numbers
* on the crossbow.
*/
rc = device_master_set(hwgraph_connectpt_get(widgetv), hubv);
/* If we are looking at the global master io6
* then add information about the version of
* the io6prom as a part of "detailed inventory"
* information.
*/
if (is_master_baseio(nasid,
NODEPDA(cnode)->module_id,
get_widget_slotnum(0,widgetnum))) {
extern void klhwg_baseio_inventory_add(devfs_handle_t,
cnodeid_t);
module = NODEPDA(cnode)->module_id;
#ifdef XBRIDGE_REGS_SIM
DBG("io_xswitch_widget_init: XBRIDGE_REGS_SIM FIXME: reading xwidget id: hardwired to xbridge (0x2d000049).\n");
if (XWIDGET_PART_NUM(0x2d000049)==XXBOW_WIDGET_PART_NUM) {
#else
if (nasid_has_xbridge(nasid)) {
#endif /* XBRIDGE_REGS_SIM */
board = find_lboard_module(
(lboard_t *)KL_CONFIG_INFO(nasid),
module);
/*
* Change iobrick to correct i/o brick
*/
#ifdef SUPPORT_PRINTING_M_FORMAT
sprintf(pathname, EDGE_LBL_MODULE "/%M/"
#else
sprintf(pathname, EDGE_LBL_MODULE "/%x/"
#endif
"iobrick" "/%s/%d",
NODEPDA(cnode)->module_id,
EDGE_LBL_XTALK, widgetnum);
} else {
slot = get_widget_slotnum(0, widgetnum);
board = get_board_name(nasid, module, slot,
new_name);
/*
* Create the vertex for the widget,
* using the decimal
* widgetnum as the name of the primary edge.
*/
#ifdef SUPPORT_PRINTING_M_FORMAT
sprintf(pathname, EDGE_LBL_MODULE "/%M/"
EDGE_LBL_SLOT "/%s/%s",
NODEPDA(cnode)->module_id,
slotname, new_name);
#else
memset(buffer, 0, 16);
format_module_id(buffer, NODEPDA(cnode)->module_id, MODULE_FORMAT_BRIEF);
sprintf(pathname, EDGE_LBL_MODULE "/%s/"
EDGE_LBL_SLOT "/%s/%s",
buffer,
slotname, new_name);
#endif
}
rc = hwgraph_path_add(hwgraph_root, pathname, &widgetv);
DBG("io_xswitch_widget_init: (2) path= %s\n", pathname);
/*
* This is a weird ass code needed for error injection
* purposes.
*/
rc = device_master_set(hwgraph_connectpt_get(widgetv), hubv);
klhwg_baseio_inventory_add(widgetv,cnode);
}
sprintf(name, "%d", widgetnum);
DBG("io_xswitch_widget_init: FIXME hwgraph_edge_add %s xswitchv 0x%p, widgetv 0x%p\n", name, xswitchv, widgetv);
rc = hwgraph_edge_add(xswitchv, widgetv, name);
/*
* crosstalk switch code tracks which
* widget is attached to each link.
*/
xswitch_info_vhdl_set(xswitch_info, widgetnum, widgetv);
/*
* Peek at the widget to get its crosstalk part and
* mfgr numbers, then present it to the generic xtalk
* bus provider to have its driver attach routine
* called (or not).
*/
#ifdef XBRIDGE_REGS_SIM
widget_id = 0x2d000049;
DBG("io_xswitch_widget_init: XBRIDGE_REGS_SIM FIXME: id hardwired to widget_id\n");
#else
widget_id = XWIDGET_ID_READ(nasid, widgetnum);
#endif /* XBRIDGE_REGS_SIM */
hwid.part_num = XWIDGET_PART_NUM(widget_id);
hwid.rev_num = XWIDGET_REV_NUM(widget_id);
hwid.mfg_num = XWIDGET_MFG_NUM(widget_id);
/* Store some inventory information about
* the xwidget in the hardware graph.
*/
xwidget_inventory_add(widgetv,board,hwid);
(void)xwidget_register(&hwid, widgetv, widgetnum,
hubv, hub_widgetid,
aa);
#ifdef SN0_USE_BTE
bte_bpush_war(cnode, (void *)board);
#endif
}
}
static void
io_init_xswitch_widgets(devfs_handle_t xswitchv, cnodeid_t cnode)
{
xwidgetnum_t widgetnum;
async_attach_t aa;
aa = async_attach_new();
DBG("io_init_xswitch_widgets: xswitchv 0x%p for cnode %d\n", xswitchv, cnode);
for (widgetnum = HUB_WIDGET_ID_MIN; widgetnum <= HUB_WIDGET_ID_MAX;
widgetnum++) {
io_xswitch_widget_init(xswitchv,
cnodeid_to_vertex(cnode),
widgetnum, aa);
}
/*
* Wait for parallel attach threads, if any, to complete.
*/
async_attach_waitall(aa);
async_attach_free(aa);
}
/* Define the system critical vertices and connect them through
* a canonical parent-child relationships for easy traversal
* during io error handling.
*/
static void
sys_critical_graph_init(void)
{
devfs_handle_t bridge_vhdl,master_node_vhdl;
devfs_handle_t xbow_vhdl = GRAPH_VERTEX_NONE;
extern devfs_handle_t hwgraph_root;
devfs_handle_t pci_slot_conn;
int slot;
devfs_handle_t baseio_console_conn;
DBG("sys_critical_graph_init: FIXME.\n");
baseio_console_conn = hwgraph_connectpt_get(baseio_console_vhdl);
if (baseio_console_conn == NULL) {
return;
}
/* Get the vertex handle for the baseio bridge */
bridge_vhdl = device_master_get(baseio_console_conn);
/* Get the master node of the baseio card */
master_node_vhdl = cnodeid_to_vertex(
master_node_get(baseio_console_vhdl));
/* Add the "root->node" part of the system critical graph */
sys_critical_graph_vertex_add(hwgraph_root,master_node_vhdl);
/* Check if we have a crossbow */
if (hwgraph_traverse(master_node_vhdl,
EDGE_LBL_XTALK"/0",
&xbow_vhdl) == GRAPH_SUCCESS) {
/* We have a crossbow.Add "node->xbow" part of the system
* critical graph.
*/
sys_critical_graph_vertex_add(master_node_vhdl,xbow_vhdl);
/* Add "xbow->baseio bridge" of the system critical graph */
sys_critical_graph_vertex_add(xbow_vhdl,bridge_vhdl);
hwgraph_vertex_unref(xbow_vhdl);
} else
/* We donot have a crossbow. Add "node->baseio_bridge"
* part of the system critical graph.
*/
sys_critical_graph_vertex_add(master_node_vhdl,bridge_vhdl);
/* Add all the populated PCI slot vertices to the system critical
* graph with the bridge vertex as the parent.
*/
for (slot = 0 ; slot < 8; slot++) {
char slot_edge[10];
sprintf(slot_edge,"%d",slot);
if (hwgraph_traverse(bridge_vhdl,slot_edge, &pci_slot_conn)
!= GRAPH_SUCCESS)
continue;
sys_critical_graph_vertex_add(bridge_vhdl,pci_slot_conn);
hwgraph_vertex_unref(pci_slot_conn);
}
hwgraph_vertex_unref(bridge_vhdl);
/* Add the "ioc3 pci connection point -> console ioc3" part
* of the system critical graph
*/
if (hwgraph_traverse(baseio_console_vhdl,"..",&pci_slot_conn) ==
GRAPH_SUCCESS) {
sys_critical_graph_vertex_add(pci_slot_conn,
baseio_console_vhdl);
hwgraph_vertex_unref(pci_slot_conn);
}
/* Add the "ethernet pci connection point -> base ethernet" part of
* the system critical graph
*/
if (hwgraph_traverse(baseio_enet_vhdl,"..",&pci_slot_conn) ==
GRAPH_SUCCESS) {
sys_critical_graph_vertex_add(pci_slot_conn,
baseio_enet_vhdl);
hwgraph_vertex_unref(pci_slot_conn);
}
/* Add the "scsi controller pci connection point -> base scsi
* controller" part of the system critical graph
*/
if (hwgraph_traverse(base_io_scsi_ctlr_vhdl[0],
"../..",&pci_slot_conn) == GRAPH_SUCCESS) {
sys_critical_graph_vertex_add(pci_slot_conn,
base_io_scsi_ctlr_vhdl[0]);
hwgraph_vertex_unref(pci_slot_conn);
}
if (hwgraph_traverse(base_io_scsi_ctlr_vhdl[1],
"../..",&pci_slot_conn) == GRAPH_SUCCESS) {
sys_critical_graph_vertex_add(pci_slot_conn,
base_io_scsi_ctlr_vhdl[1]);
hwgraph_vertex_unref(pci_slot_conn);
}
hwgraph_vertex_unref(baseio_console_conn);
}
/*
* If this PIC is attached to two Cbricks ("dual-ported") then
* attach each bus to opposite Cbricks.
*
* If successful, return a new vertex suitable for attaching the PIC bus.
* If not successful, return zero and both buses will attach to the
* vertex passed into pic_attach().
*/
static vertex_hdl_t
pic_bus1_redist(nasid_t nasid, vertex_hdl_t conn_v)
{
cnodeid_t cnode = nasid_to_cnodeid(nasid);
cnodeid_t xbow_peer = -1;
char pathname[256], peer_path[256], tmpbuf[256];
char *p;
int rc;
vertex_hdl_t peer_conn_v, hubv;
int pos;
slabid_t slab;
if (NODEPDA(cnode)->xbow_peer >= 0) { /* if dual-ported */
/* create a path for this widget on the peer Cbrick */
/* pcibr widget hw/module/001c11/slab/0/Pbrick/xtalk/12 */
/* sprintf(pathname, "%v", conn_v); */
xbow_peer = nasid_to_cnodeid(NODEPDA(cnode)->xbow_peer);
pos = hwgfs_generate_path(conn_v, tmpbuf, 256);
strcpy(pathname, &tmpbuf[pos]);
p = pathname + strlen("hw/module/001c01/slab/0/");
memset(tmpbuf, 0, 16);
format_module_id(tmpbuf, geo_module((NODEPDA(xbow_peer))->geoid), MODULE_FORMAT_BRIEF);
slab = geo_slab((NODEPDA(xbow_peer))->geoid);
sprintf(peer_path, "module/%s/slab/%d/%s", tmpbuf, (int)slab, p);
/* Look for vertex for this widget on the peer Cbrick.
* Expect GRAPH_NOT_FOUND.
*/
rc = hwgraph_traverse(hwgraph_root, peer_path, &peer_conn_v);
if (GRAPH_SUCCESS == rc)
printk("pic_attach: found unexpected vertex: 0x%lx\n",
(uint64_t)peer_conn_v);
else if (GRAPH_NOT_FOUND != rc) {
printk("pic_attach: hwgraph_traverse unexpectedly"
" returned 0x%x\n", rc);
} else {
/* try to add the widget vertex to the peer Cbrick */
rc = hwgraph_path_add(hwgraph_root, peer_path, &peer_conn_v);
if (GRAPH_SUCCESS != rc)
printk("pic_attach: hwgraph_path_add"
" failed with 0x%x\n", rc);
else {
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_ATTACH, conn_v,
"pic_bus1_redist: added vertex %v\n", peer_conn_v));
/* Now hang appropiate stuff off of the new
* vertex. We bail out if we cannot add something.
* In that case, we don't remove the newly added
* vertex but that should be safe and we don't
* really expect the additions to fail anyway.
*/
if (!pic_bus1_widget_info_dup(conn_v, peer_conn_v,
xbow_peer, peer_path))
return 0;
hubv = cnodeid_to_vertex(xbow_peer);
ASSERT(hubv != GRAPH_VERTEX_NONE);
device_master_set(peer_conn_v, hubv);
xtalk_provider_register(hubv, &hub_provider);
xtalk_provider_startup(hubv);
return peer_conn_v;
}
}
}
return 0;
}