/*
* xwidget_register:
* Register a xtalk device (xwidget) by doing the following.
* -allocate and initialize xwidget_info data
* -allocate a hwgraph vertex with name based on widget number (id)
* -look up the widget's initialization function and call it,
* or remember the vertex for later initialization.
*
*/
int
xwidget_register(xwidget_hwid_t hwid, /* widget's hardware ID */
vertex_hdl_t widget, /* widget to initialize */
xwidgetnum_t id, /* widget's target id (0..f) */
vertex_hdl_t master, /* widget's master vertex */
xwidgetnum_t targetid) /* master's target id (9/a) */
{
xwidget_info_t widget_info;
char *s,devnm[MAXDEVNAME];
/* Allocate widget_info and associate it with widget vertex */
NEW(widget_info);
/* Initialize widget_info */
widget_info->w_vertex = widget;
widget_info->w_id = id;
widget_info->w_master = master;
widget_info->w_masterid = targetid;
widget_info->w_hwid = *hwid; /* structure copy */
widget_info->w_efunc = 0;
widget_info->w_einfo = 0;
/*
* get the name of this xwidget vertex and keep the info.
* This is needed during errors and interupts, but as
* long as we have it, we can use it elsewhere.
*/
s = dev_to_name(widget,devnm,MAXDEVNAME);
widget_info->w_name = kmalloc(strlen(s) + 1, GFP_KERNEL);
strcpy(widget_info->w_name,s);
xwidget_info_set(widget, widget_info);
device_master_set(widget, master);
/*
* Add pointer to async attach info -- tear down will be done when
* the particular descendant is done with the info.
*/
return cdl_add_connpt(hwid->part_num, hwid->mfg_num,
widget, 0);
}
/* ARGSUSED */
static void __init
klhwg_add_node(vertex_hdl_t hwgraph_root, cnodeid_t cnode)
{
nasid_t nasid;
lboard_t *brd;
klhub_t *hub;
vertex_hdl_t node_vertex = NULL;
char path_buffer[100];
int rv;
char *s;
int board_disabled = 0;
klcpu_t *cpu;
vertex_hdl_t cpu_dir;
nasid = cnodeid_to_nasid(cnode);
brd = find_lboard_any((lboard_t *)KL_CONFIG_INFO(nasid), KLTYPE_SNIA);
ASSERT(brd);
/* Generate a hardware graph path for this board. */
board_to_path(brd, path_buffer);
rv = hwgraph_path_add(hwgraph_root, path_buffer, &node_vertex);
if (rv != GRAPH_SUCCESS) {
printk("Node vertex creation failed. Path == %s", path_buffer);
return;
}
HWGRAPH_DEBUG(__FILE__, __FUNCTION__, __LINE__, node_vertex, NULL, "Created path for SHUB node.\n");
hub = (klhub_t *)find_first_component(brd, KLSTRUCT_HUB);
ASSERT(hub);
if(hub->hub_info.flags & KLINFO_ENABLE)
board_disabled = 0;
else
board_disabled = 1;
if(!board_disabled) {
mark_nodevertex_as_node(node_vertex, cnode);
s = dev_to_name(node_vertex, path_buffer, sizeof(path_buffer));
NODEPDA(cnode)->hwg_node_name =
kmalloc(strlen(s) + 1, GFP_KERNEL);
if (NODEPDA(cnode)->hwg_node_name <= 0) {
printk("%s: no memory\n", __FUNCTION__);
return;
}
strcpy(NODEPDA(cnode)->hwg_node_name, s);
hubinfo_set(node_vertex, NODEPDA(cnode)->pdinfo);
NODEPDA(cnode)->slotdesc = brd->brd_slot;
NODEPDA(cnode)->geoid = brd->brd_geoid;
NODEPDA(cnode)->module = module_lookup(geo_module(brd->brd_geoid));
klhwg_add_hub(node_vertex, hub, cnode);
}
/*
* If there's at least 1 CPU, add a "cpu" directory to represent
* the collection of all CPUs attached to this node.
*/
cpu = (klcpu_t *)find_first_component(brd, KLSTRUCT_CPU);
if (cpu) {
graph_error_t rv;
rv = hwgraph_path_add(node_vertex, EDGE_LBL_CPU, &cpu_dir);
if (rv != GRAPH_SUCCESS) {
printk("klhwg_add_node: Cannot create CPU directory\n");
return;
}
HWGRAPH_DEBUG(__FILE__, __FUNCTION__, __LINE__, cpu_dir, NULL, "Created cpu directiry on SHUB node.\n");
}
while (cpu) {
cpuid_t cpu_id;
cpu_id = nasid_slice_to_cpuid(nasid,cpu->cpu_info.physid);
if (cpu_online(cpu_id))
klhwg_add_cpu(node_vertex, cnode, cpu);
else
klhwg_add_disabled_cpu(node_vertex, cnode, cpu, brd->brd_slot);
cpu = (klcpu_t *)
find_component(brd, (klinfo_t *)cpu, KLSTRUCT_CPU);
}
}
/*
* PIC has two buses under a single widget. pic_attach() calls pic_attach2()
* to attach each of those buses.
*/
static int
pic_attach2(vertex_hdl_t xconn_vhdl, void *bridge,
vertex_hdl_t pcibr_vhdl, int busnum, pcibr_soft_t *ret_softp)
{
vertex_hdl_t ctlr_vhdl;
pcibr_soft_t pcibr_soft;
pcibr_info_t pcibr_info;
xwidget_info_t info;
xtalk_intr_t xtalk_intr;
pcibr_list_p self;
int entry, slot, ibit, i;
vertex_hdl_t noslot_conn;
char devnm[MAXDEVNAME], *s;
pcibr_hints_t pcibr_hints;
picreg_t id;
picreg_t int_enable;
picreg_t pic_ctrl_reg;
int iobrick_type_get_nasid(nasid_t nasid);
int iomoduleid_get(nasid_t nasid);
int irq;
int cpu;
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_ATTACH, pcibr_vhdl,
"pic_attach2: bridge=0x%lx, busnum=%d\n", bridge, busnum));
ctlr_vhdl = NULL;
ctlr_vhdl = hwgraph_register(pcibr_vhdl, EDGE_LBL_CONTROLLER, 0,
0, 0, 0,
S_IFCHR | S_IRUSR | S_IWUSR | S_IRGRP, 0, 0,
(struct file_operations *)&pcibr_fops, (void *)pcibr_vhdl);
ASSERT(ctlr_vhdl != NULL);
id = pcireg_bridge_id_get(bridge);
hwgraph_info_add_LBL(pcibr_vhdl, INFO_LBL_PCIBR_ASIC_REV,
(arbitrary_info_t)XWIDGET_PART_REV_NUM(id));
/*
* Get the hint structure; if some NIC callback marked this vertex as
* "hands-off" then we just return here, before doing anything else.
*/
pcibr_hints = pcibr_hints_get(xconn_vhdl, 0);
if (pcibr_hints && pcibr_hints->ph_hands_off)
return -1;
/* allocate soft structure to hang off the vertex. Link the new soft
* structure to the pcibr_list linked list
*/
pcibr_soft = kmalloc(sizeof (*(pcibr_soft)), GFP_KERNEL);
if ( !pcibr_soft )
return -ENOMEM;
self = kmalloc(sizeof (*(self)), GFP_KERNEL);
if ( !self ) {
kfree(pcibr_soft);
return -ENOMEM;
}
memset(pcibr_soft, 0, sizeof (*(pcibr_soft)));
memset(self, 0, sizeof (*(self)));
self->bl_soft = pcibr_soft;
self->bl_vhdl = pcibr_vhdl;
self->bl_next = pcibr_list;
pcibr_list = self;
if (ret_softp)
*ret_softp = pcibr_soft;
memset(pcibr_soft, 0, sizeof *pcibr_soft);
pcibr_soft_set(pcibr_vhdl, pcibr_soft);
s = dev_to_name(pcibr_vhdl, devnm, MAXDEVNAME);
pcibr_soft->bs_name = kmalloc(strlen(s) + 1, GFP_KERNEL);
if (!pcibr_soft->bs_name)
return -ENOMEM;
strcpy(pcibr_soft->bs_name, s);
pcibr_soft->bs_conn = xconn_vhdl;
pcibr_soft->bs_vhdl = pcibr_vhdl;
pcibr_soft->bs_base = (void *)bridge;
pcibr_soft->bs_rev_num = XWIDGET_PART_REV_NUM(id);
pcibr_soft->bs_intr_bits = (pcibr_intr_bits_f *)pcibr_intr_bits;
pcibr_soft->bsi_err_intr = 0;
pcibr_soft->bs_min_slot = 0;
pcibr_soft->bs_max_slot = 3;
pcibr_soft->bs_busnum = busnum;
pcibr_soft->bs_bridge_type = PCIBR_BRIDGETYPE_PIC;
pcibr_soft->bs_int_ate_size = PIC_INTERNAL_ATES;
/* Make sure this is called after setting the bs_base and bs_bridge_type */
pcibr_soft->bs_bridge_mode = (pcireg_speed_get(pcibr_soft) << 1) |
pcireg_mode_get(pcibr_soft);
info = xwidget_info_get(xconn_vhdl);
pcibr_soft->bs_xid = xwidget_info_id_get(info);
pcibr_soft->bs_master = xwidget_info_master_get(info);
pcibr_soft->bs_mxid = xwidget_info_masterid_get(info);
strcpy(pcibr_soft->bs_asic_name, "PIC");
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_ATTACH, pcibr_vhdl,
"pic_attach2: pcibr_soft=0x%lx, mode=0x%x\n",
pcibr_soft, pcibr_soft->bs_bridge_mode));
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_ATTACH, pcibr_vhdl,
"pic_attach2: %s ASIC: rev %s (code=0x%x)\n",
pcibr_soft->bs_asic_name,
(IS_PIC_PART_REV_A(pcibr_soft->bs_rev_num)) ? "A" :
(IS_PIC_PART_REV_B(pcibr_soft->bs_rev_num)) ? "B" :
(IS_PIC_PART_REV_C(pcibr_soft->bs_rev_num)) ? "C" :
"unknown", pcibr_soft->bs_rev_num));
/* PV854845: Must clear write request buffer to avoid parity errors */
for (i=0; i < PIC_WR_REQ_BUFSIZE; i++) {
((pic_t *)bridge)->p_wr_req_lower[i] = 0;
((pic_t *)bridge)->p_wr_req_upper[i] = 0;
((pic_t *)bridge)->p_wr_req_parity[i] = 0;
}
pcibr_soft->bs_nasid = NASID_GET(bridge);
pcibr_soft->bs_bricktype = iobrick_type_get_nasid(pcibr_soft->bs_nasid);
if (pcibr_soft->bs_bricktype < 0)
printk(KERN_WARNING "%s: bricktype was unknown by L1 (ret val = 0x%x)\n",
pcibr_soft->bs_name, pcibr_soft->bs_bricktype);
pcibr_soft->bs_moduleid = iomoduleid_get(pcibr_soft->bs_nasid);
if (pcibr_soft->bs_bricktype > 0) {
switch (pcibr_soft->bs_bricktype) {
case MODULE_PXBRICK:
case MODULE_IXBRICK:
case MODULE_OPUSBRICK:
pcibr_soft->bs_first_slot = 0;
pcibr_soft->bs_last_slot = 1;
pcibr_soft->bs_last_reset = 1;
/* Bus 1 of IXBrick has a IO9, so there are 4 devices, not 2 */
if ((pcibr_widget_to_bus(pcibr_vhdl) == 1)
&& isIO9(pcibr_soft->bs_nasid)) {
pcibr_soft->bs_last_slot = 3;
pcibr_soft->bs_last_reset = 3;
}
break;
case MODULE_CGBRICK:
pcibr_soft->bs_first_slot = 0;
pcibr_soft->bs_last_slot = 0;
pcibr_soft->bs_last_reset = 0;
break;
default:
printk(KERN_WARNING "%s: Unknown bricktype: 0x%x\n",
pcibr_soft->bs_name, pcibr_soft->bs_bricktype);
break;
}
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_ATTACH, pcibr_vhdl,
"pic_attach2: bricktype=%d, brickbus=%d, "
"slots %d-%d\n", pcibr_soft->bs_bricktype,
pcibr_widget_to_bus(pcibr_vhdl),
pcibr_soft->bs_first_slot, pcibr_soft->bs_last_slot));
}
/*
* Initialize bridge and bus locks
*/
spin_lock_init(&pcibr_soft->bs_lock);
/*
* If we have one, process the hints structure.
*/
if (pcibr_hints) {
unsigned rrb_fixed;
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_HINTS, pcibr_vhdl,
"pic_attach2: pcibr_hints=0x%lx\n", pcibr_hints));
rrb_fixed = pcibr_hints->ph_rrb_fixed;
pcibr_soft->bs_rrb_fixed = rrb_fixed;
if (pcibr_hints->ph_intr_bits)
pcibr_soft->bs_intr_bits = pcibr_hints->ph_intr_bits;
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
int hslot = pcibr_hints->ph_host_slot[slot] - 1;
if (hslot < 0) {
pcibr_soft->bs_slot[slot].host_slot = slot;
} else {
pcibr_soft->bs_slot[slot].has_host = 1;
pcibr_soft->bs_slot[slot].host_slot = hslot;
}
}
}
/*
* Set-up initial values for state fields
*/
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
pcibr_soft->bs_slot[slot].bss_devio.bssd_space = PCIIO_SPACE_NONE;
pcibr_soft->bs_slot[slot].bss_devio.bssd_ref_cnt = 0;
pcibr_soft->bs_slot[slot].bss_d64_base = PCIBR_D64_BASE_UNSET;
pcibr_soft->bs_slot[slot].bss_d32_base = PCIBR_D32_BASE_UNSET;
pcibr_soft->bs_rrb_valid_dflt[slot][VCHAN0] = -1;
}
for (ibit = 0; ibit < 8; ++ibit) {
pcibr_soft->bs_intr[ibit].bsi_xtalk_intr = 0;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_soft = pcibr_soft;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_list = NULL;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_ibit = ibit;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_hdlrcnt = 0;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_shared = 0;
pcibr_soft->bs_intr[ibit].bsi_pcibr_intr_wrap.iw_connected = 0;
}
/*
* connect up our error handler. PIC has 2 busses (thus resulting in 2
* pcibr_soft structs under 1 widget), so only register a xwidget error
* handler for PIC's bus0. NOTE: for PIC pcibr_error_handler_wrapper()
* is a wrapper routine we register that will call the real error handler
* pcibr_error_handler() with the correct pcibr_soft struct.
*/
if (busnum == 0) {
xwidget_error_register(xconn_vhdl,
pcibr_error_handler_wrapper, pcibr_soft);
}
/*
* Clear all pending interrupts. Assume all interrupts are from slot 3
* until otherise setup.
*/
pcireg_intr_reset_set(pcibr_soft, PIC_IRR_ALL_CLR);
pcireg_intr_device_set(pcibr_soft, 0x006db6db);
/* Setup the mapping register used for direct mapping */
pcibr_directmap_init(pcibr_soft);
/*
* Initialize the PICs control register.
*/
pic_ctrl_reg = pcireg_control_get(pcibr_soft);
/* Bridges Requester ID: bus = busnum, dev = 0, func = 0 */
pic_ctrl_reg &= ~PIC_CTRL_BUS_NUM_MASK;
pic_ctrl_reg |= PIC_CTRL_BUS_NUM(busnum);
pic_ctrl_reg &= ~PIC_CTRL_DEV_NUM_MASK;
pic_ctrl_reg &= ~PIC_CTRL_FUN_NUM_MASK;
pic_ctrl_reg &= ~PIC_CTRL_NO_SNOOP;
pic_ctrl_reg &= ~PIC_CTRL_RELAX_ORDER;
/* enable parity checking on PICs internal RAM */
pic_ctrl_reg |= PIC_CTRL_PAR_EN_RESP;
pic_ctrl_reg |= PIC_CTRL_PAR_EN_ATE;
/* PIC BRINGUP WAR (PV# 862253): dont enable write request parity */
if (!PCIBR_WAR_ENABLED(PV862253, pcibr_soft)) {
pic_ctrl_reg |= PIC_CTRL_PAR_EN_REQ;
}
pic_ctrl_reg |= PIC_CTRL_PAGE_SIZE;
pcireg_control_set(pcibr_soft, pic_ctrl_reg);
/* Initialize internal mapping entries (ie. the ATEs) */
for (entry = 0; entry < pcibr_soft->bs_int_ate_size; entry++)
pcireg_int_ate_set(pcibr_soft, entry, 0);
pcibr_soft->bs_int_ate_resource.start = 0;
pcibr_soft->bs_int_ate_resource.end = pcibr_soft->bs_int_ate_size - 1;
/* Setup the PICs error interrupt handler. */
xtalk_intr = xtalk_intr_alloc(xconn_vhdl, (device_desc_t)0, pcibr_vhdl);
ASSERT(xtalk_intr != NULL);
irq = ((hub_intr_t)xtalk_intr)->i_bit;
cpu = ((hub_intr_t)xtalk_intr)->i_cpuid;
intr_unreserve_level(cpu, irq);
((hub_intr_t)xtalk_intr)->i_bit = SGI_PCIBR_ERROR;
xtalk_intr->xi_vector = SGI_PCIBR_ERROR;
pcibr_soft->bsi_err_intr = xtalk_intr;
/*
* On IP35 with XBridge, we do some extra checks in pcibr_setwidint
* in order to work around some addressing limitations. In order
* for that fire wall to work properly, we need to make sure we
* start from a known clean state.
*/
pcibr_clearwidint(pcibr_soft);
xtalk_intr_connect(xtalk_intr,
(intr_func_t) pcibr_error_intr_handler,
(intr_arg_t) pcibr_soft,
(xtalk_intr_setfunc_t) pcibr_setwidint,
(void *) pcibr_soft);
request_irq(SGI_PCIBR_ERROR, (void *)pcibr_error_intr_handler, SA_SHIRQ,
"PCIBR error", (intr_arg_t) pcibr_soft);
PCIBR_DEBUG_ALWAYS((PCIBR_DEBUG_INTR_ALLOC, pcibr_vhdl,
"pcibr_setwidint: target_id=0x%lx, int_addr=0x%lx\n",
pcireg_intr_dst_target_id_get(pcibr_soft),
pcireg_intr_dst_addr_get(pcibr_soft)));
/* now we can start handling error interrupts */
int_enable = pcireg_intr_enable_get(pcibr_soft);
int_enable |= PIC_ISR_ERRORS;
/* PIC BRINGUP WAR (PV# 856864 & 856865): allow the tnums that are
* locked out to be freed up sooner (by timing out) so that the
* read tnums are never completely used up.
*/
if (PCIBR_WAR_ENABLED(PV856864, pcibr_soft)) {
int_enable &= ~PIC_ISR_PCIX_REQ_TOUT;
int_enable &= ~PIC_ISR_XREAD_REQ_TIMEOUT;
pcireg_req_timeout_set(pcibr_soft, 0x750);
}
pcireg_intr_enable_set(pcibr_soft, int_enable);
pcireg_intr_mode_set(pcibr_soft, 0); /* dont send 'clear interrupt' pkts */
pcireg_tflush_get(pcibr_soft); /* wait until Bridge PIO complete */
/*
* PIC BRINGUP WAR (PV# 856866, 859504, 861476, 861478): Don't use
* RRB0, RRB8, RRB1, and RRB9. Assign them to DEVICE[2|3]--VCHAN3
* so they are not used. This works since there is currently no
* API to penable VCHAN3.
*/
if (PCIBR_WAR_ENABLED(PV856866, pcibr_soft)) {
pcireg_rrb_bit_set(pcibr_soft, 0, 0x000f000f); /* even rrb reg */
pcireg_rrb_bit_set(pcibr_soft, 1, 0x000f000f); /* odd rrb reg */
}
/* PIC only supports 64-bit direct mapping in PCI-X mode. Since
* all PCI-X devices that initiate memory transactions must be
* capable of generating 64-bit addressed, we force 64-bit DMAs.
*/
pcibr_soft->bs_dma_flags = 0;
if (IS_PCIX(pcibr_soft)) {
pcibr_soft->bs_dma_flags |= PCIIO_DMA_A64;
}
{
iopaddr_t prom_base_addr = pcibr_soft->bs_xid << 24;
int prom_base_size = 0x1000000;
int status;
struct resource *res;
/* Allocate resource maps based on bus page size; for I/O and memory
* space, free all pages except those in the base area and in the
* range set by the PROM.
*
* PROM creates BAR addresses in this format: 0x0ws00000 where w is
* the widget number and s is the device register offset for the slot.
*/
/* Setup the Bus's PCI IO Root Resource. */
pcibr_soft->bs_io_win_root_resource.start = PCIBR_BUS_IO_BASE;
pcibr_soft->bs_io_win_root_resource.end = 0xffffffff;
res = (struct resource *) kmalloc( sizeof(struct resource), GFP_KERNEL);
if (!res)
panic("PCIBR:Unable to allocate resource structure\n");
/* Block off the range used by PROM. */
res->start = prom_base_addr;
res->end = prom_base_addr + (prom_base_size - 1);
status = request_resource(&pcibr_soft->bs_io_win_root_resource, res);
if (status)
panic("PCIBR:Unable to request_resource()\n");
/* Setup the Small Window Root Resource */
pcibr_soft->bs_swin_root_resource.start = PAGE_SIZE;
pcibr_soft->bs_swin_root_resource.end = 0x000FFFFF;
/* Setup the Bus's PCI Memory Root Resource */
pcibr_soft->bs_mem_win_root_resource.start = 0x200000;
pcibr_soft->bs_mem_win_root_resource.end = 0xffffffff;
res = (struct resource *) kmalloc( sizeof(struct resource), GFP_KERNEL);
if (!res)
panic("PCIBR:Unable to allocate resource structure\n");
/* Block off the range used by PROM. */
res->start = prom_base_addr;
res->end = prom_base_addr + (prom_base_size - 1);
status = request_resource(&pcibr_soft->bs_mem_win_root_resource, res);
if (status)
panic("PCIBR:Unable to request_resource()\n");
}
/* build "no-slot" connection point */
pcibr_info = pcibr_device_info_new(pcibr_soft, PCIIO_SLOT_NONE,
PCIIO_FUNC_NONE, PCIIO_VENDOR_ID_NONE, PCIIO_DEVICE_ID_NONE);
noslot_conn = pciio_device_info_register(pcibr_vhdl, &pcibr_info->f_c);
/* Store no slot connection point info for tearing it down during detach. */
pcibr_soft->bs_noslot_conn = noslot_conn;
pcibr_soft->bs_noslot_info = pcibr_info;
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Find out what is out there */
(void)pcibr_slot_info_init(pcibr_vhdl, slot);
}
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Set up the address space for this slot in the PCI land */
(void)pcibr_slot_addr_space_init(pcibr_vhdl, slot);
}
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Setup the device register */
(void)pcibr_slot_device_init(pcibr_vhdl, slot);
}
if (IS_PCIX(pcibr_soft)) {
pcibr_soft->bs_pcix_rbar_inuse = 0;
pcibr_soft->bs_pcix_rbar_avail = NUM_RBAR;
pcibr_soft->bs_pcix_rbar_percent_allowed =
pcibr_pcix_rbars_calc(pcibr_soft);
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Setup the PCI-X Read Buffer Attribute Registers (RBARs) */
(void)pcibr_slot_pcix_rbar_init(pcibr_soft, slot);
}
}
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Setup host/guest relations */
(void)pcibr_slot_guest_info_init(pcibr_vhdl, slot);
}
/* Handle initial RRB management */
pcibr_initial_rrb(pcibr_vhdl,
pcibr_soft->bs_first_slot, pcibr_soft->bs_last_slot);
/* Before any drivers get called that may want to re-allocate RRB's,
* let's get some special cases pre-allocated. Drivers may override
* these pre-allocations, but by doing pre-allocations now we're
* assured not to step all over what the driver intended.
*/
if (pcibr_soft->bs_bricktype > 0) {
switch (pcibr_soft->bs_bricktype) {
case MODULE_PXBRICK:
case MODULE_IXBRICK:
case MODULE_OPUSBRICK:
/*
* If IO9 in bus 1, allocate RRBs to all the IO9 devices
*/
if ((pcibr_widget_to_bus(pcibr_vhdl) == 1) &&
(pcibr_soft->bs_slot[0].bss_vendor_id == 0x10A9) &&
(pcibr_soft->bs_slot[0].bss_device_id == 0x100A)) {
pcibr_rrb_alloc_init(pcibr_soft, 0, VCHAN0, 4);
pcibr_rrb_alloc_init(pcibr_soft, 1, VCHAN0, 4);
pcibr_rrb_alloc_init(pcibr_soft, 2, VCHAN0, 4);
pcibr_rrb_alloc_init(pcibr_soft, 3, VCHAN0, 4);
} else {
pcibr_rrb_alloc_init(pcibr_soft, 0, VCHAN0, 4);
pcibr_rrb_alloc_init(pcibr_soft, 1, VCHAN0, 4);
}
break;
case MODULE_CGBRICK:
pcibr_rrb_alloc_init(pcibr_soft, 0, VCHAN0, 8);
break;
} /* switch */
}
for (slot = pcibr_soft->bs_min_slot;
slot < PCIBR_NUM_SLOTS(pcibr_soft); ++slot) {
/* Call the device attach */
(void)pcibr_slot_call_device_attach(pcibr_vhdl, slot, 0);
}
pciio_device_attach(noslot_conn, 0);
return 0;
}
