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qemu / skiboot / 47488feb70d3fea5325174a391451e6e1d0c3cf1 / . / platforms / astbmc / mihawk.c
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// SPDX-License-Identifier: Apache-2.0
/*
* Copyright 2019 Wistron Corp.
* Copyright 2017 IBM Corp.
*/
#include <skiboot.h>
#include <device.h>
#include <console.h>
#include <chip.h>
#include <ipmi.h>
#include <psi.h>
#include <npu-regs.h>
#include <npu2.h>
#include <pci.h>
#include <pci-cfg.h>
#include <timebase.h>
#include "astbmc.h"
/* IPMI message code for Riser-F query (OEM). */
#define IPMI_RISERF_QUERY IPMI_CODE(0x32, 0x01)
static bool mihawk_riserF_found = false;
static bool bmc_query_waiting = false;
#define OPAL_ID_SLOT2 0x01
#define OPAL_ID_SLOT4 0x03
#define OPAL_ID_SLOT7 0x31
#define OPAL_ID_SLOT9 0x33
/* nvme backplane slots */
static const struct slot_table_entry hdd_bay_s2_slots[] = {
SW_PLUGGABLE("nvme13", 0x0),
SW_PLUGGABLE("nvme14", 0x1),
SW_PLUGGABLE("nvme15", 0x2),
SW_PLUGGABLE("nvme16", 0x3),
{ .etype = st_end },
};
static const struct slot_table_entry hdd_bay_s4_slots[] = {
SW_PLUGGABLE("nvme17", 0x0),
SW_PLUGGABLE("nvme18", 0x1),
SW_PLUGGABLE("nvme19", 0x2),
SW_PLUGGABLE("nvme20", 0x3),
SW_PLUGGABLE("nvme21", 0x4),
SW_PLUGGABLE("nvme22", 0x5),
SW_PLUGGABLE("nvme23", 0x6),
SW_PLUGGABLE("nvme24", 0x7),
{ .etype = st_end },
};
static const struct slot_table_entry hdd_bay_s7_slots[] = {
SW_PLUGGABLE("nvme9", 0x0),
SW_PLUGGABLE("nvme10", 0x1),
SW_PLUGGABLE("nvme11", 0x2),
SW_PLUGGABLE("nvme12", 0x3),
{ .etype = st_end },
};
static const struct slot_table_entry hdd_bay_s9_slots[] = {
SW_PLUGGABLE("nvme1", 0x0),
SW_PLUGGABLE("nvme2", 0x1),
SW_PLUGGABLE("nvme3", 0x2),
SW_PLUGGABLE("nvme4", 0x3),
SW_PLUGGABLE("nvme5", 0x4),
SW_PLUGGABLE("nvme6", 0x5),
SW_PLUGGABLE("nvme7", 0x6),
SW_PLUGGABLE("nvme8", 0x7),
{ .etype = st_end },
};
static void mihawk_get_slot_info(struct phb *phb, struct pci_device *pd)
{
const struct slot_table_entry *ent = NULL;
if (!pd || pd->slot)
return;
/*
* If we find a 8533 or c012 switch then assume it's the NVMe Rack.
* This might break if we have another switch with the same vdid in
* the system for some reason. This is a really dumb hack, but until
* we get query the BMC about wether we have a HDD rack or not we
* don't have much of a choice.
*/
if (pd->dev_type == PCIE_TYPE_SWITCH_DNPORT) {
if (pd->vdid == 0x853311f8) { // for microsemi controller
for (ent = hdd_bay_s9_slots; ent->etype != st_end; ent++)
if (ent->location == (pd->bdfn & 0xff))
break;
} else if (pd->vdid == 0xc0121000) { // for broadcom nvme hba
switch (phb->opal_id) {
case OPAL_ID_SLOT2:
ent = hdd_bay_s2_slots;
break;
case OPAL_ID_SLOT4:
ent = hdd_bay_s4_slots;
break;
case OPAL_ID_SLOT7:
ent = hdd_bay_s7_slots;
break;
case OPAL_ID_SLOT9:
default:
ent = hdd_bay_s9_slots;
break;
}
for (; ent->etype != st_end; ent++)
if (ent->location == (pd->bdfn & 0xff))
break;
}
}
if (ent)
slot_table_add_slot_info(pd, ent);
else
slot_table_get_slot_info(phb, pd);
}
static const char *mihawk_ocapi_slot_label(uint32_t chip_id,
uint32_t brick_index)
{
const char *name = NULL;
if (chip_id == 0) {
if (brick_index == 2)
name = "JP90NVB1";
else
name = "JP90NVT1";
} else {
if (brick_index == 2)
name = "JP91NVB1";
else
name = "JP91NVT1";
}
return name;
}
static const struct ocapi_phy_setup mihawk_phy = {
.tx_ffe_pre_coeff = 0x3,
.tx_ffe_post_coeff = 0x14,
.tx_ffe_boost_en = 0,
};
static const struct platform_ocapi mihawk_ocapi = {
.i2c_engine = 1,
.i2c_port = 4,
.i2c_reset_addr = 0x20,
.i2c_reset_brick2 = (1 << 1),
.i2c_reset_brick3 = (1 << 6),
.i2c_reset_brick4 = 0, /* unused */
.i2c_reset_brick5 = 0, /* unused */
.i2c_presence_addr = 0x20,
.i2c_presence_brick2 = (1 << 2), /* bottom connector */
.i2c_presence_brick3 = (1 << 7), /* top connector */
.i2c_presence_brick4 = 0, /* unused */
.i2c_presence_brick5 = 0, /* unused */
.odl_phy_swap = true,
.ocapi_slot_label = mihawk_ocapi_slot_label,
.phy_setup = &mihawk_phy,
};
static const struct slot_table_entry P1E1A_x8_PLX8748_RiserA_down[] = {
SW_PLUGGABLE("Slot7", 0x10),
SW_PLUGGABLE("Slot8", 0x8),
SW_PLUGGABLE("Slot10", 0x9),
{ .etype = st_end }
};
static const struct slot_table_entry P1E1A_x8_PLX8748_RiserA_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E1A_x8_PLX8748_RiserA_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p1phb1_rA_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E1A_x8_PLX8748_RiserA_up,
},
{ .etype = st_end },
};
static const struct slot_table_entry P0E1A_x8_PLX8748_RiserA_down[] = {
SW_PLUGGABLE("Slot2", 0x10),
SW_PLUGGABLE("Slot3", 0x8),
SW_PLUGGABLE("Slot5", 0x9),
{ .etype = st_end }
};
static const struct slot_table_entry P0E1A_x8_PLX8748_RiserA_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E1A_x8_PLX8748_RiserA_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p0phb1_rA_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E1A_x8_PLX8748_RiserA_up,
},
{ .etype = st_end },
};
static const struct slot_table_entry P1E1A_x8_PLX8748_RiserF_down[] = {
SW_PLUGGABLE("Slot7", 0x10),
SW_PLUGGABLE("Slot10", 0x9),
{ .etype = st_end }
};
static const struct slot_table_entry P1E1A_x8_PLX8748_RiserF_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E1A_x8_PLX8748_RiserF_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p1phb1_rF_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E1A_x8_PLX8748_RiserF_up,
},
{ .etype = st_end },
};
static const struct slot_table_entry P0E1A_x8_PLX8748_RiserF_down[] = {
SW_PLUGGABLE("Slot2", 0x10),
SW_PLUGGABLE("Slot5", 0x9),
{ .etype = st_end }
};
static const struct slot_table_entry P0E1A_x8_PLX8748_RiserF_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E1A_x8_PLX8748_RiserF_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p0phb1_rF_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E1A_x8_PLX8748_RiserF_up,
},
{ .etype = st_end },
};
static const struct slot_table_entry P1E2_x16_Switch_down[] = {
SW_PLUGGABLE("Slot8", 0x1),
SW_PLUGGABLE("Slot9", 0x0),
{ .etype = st_end }
};
static const struct slot_table_entry P1E2_x16_Switch_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E2_x16_Switch_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p1phb3_switch_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P1E2_x16_Switch_up,
},
{ .etype = st_end },
};
static const struct slot_table_entry P0E2_x16_Switch_down[] = {
SW_PLUGGABLE("Slot3", 0x1),
SW_PLUGGABLE("Slot4", 0x0),
{ .etype = st_end }
};
static const struct slot_table_entry P0E2_x16_Switch_up[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E2_x16_Switch_down,
},
{ .etype = st_end }
};
static const struct slot_table_entry p0phb3_switch_slot[] = {
{
.etype = st_builtin_dev,
.location = ST_LOC_DEVFN(0,0),
.children = P0E2_x16_Switch_up,
},
{ .etype = st_end },
};
ST_PLUGGABLE(p0phb0_slot, "Slot1");
ST_PLUGGABLE(p0phb3_slot, "Slot4");
ST_PLUGGABLE(p1phb0_slot, "Slot6");
ST_PLUGGABLE(p1phb3_slot, "Slot9");
static const struct slot_table_entry mihawk_riserA_phb_table[] = {
/* ==== CPU0 ==== */
ST_PHB_ENTRY(0, 0, p0phb0_slot), /* P0E0_x16_Slot1 */
ST_PHB_ENTRY(0, 1, p0phb1_rA_slot), /* P0E1A_x8_PLX8748-1_Slot2-3-5 */
//ST_PHB_ENTRY(0, 2, p0phb2_slot), /* P0E1B_x8_USBTI7340 */
ST_PHB_ENTRY(0, 3, p0phb3_slot), /* P0E2_x16_Slot4 */
/* ==== CPU1 ==== */
ST_PHB_ENTRY(8, 0, p1phb0_slot), /* P1E0_x16_Slot6 */
ST_PHB_ENTRY(8, 1, p1phb1_rA_slot), /* P1E1A_x8_PLX8748-2_Slot7-8-10 */
//ST_PHB_ENTRY(8, 2, p1phb2_slot), /* P1E1B_x8_NA */
ST_PHB_ENTRY(8, 3, p1phb3_slot), /* P1E2_x16_Slot9 */
{ .etype = st_end },
};
static const struct slot_table_entry mihawk_riserF_phb_table[] = {
/* ==== CPU0 ==== */
ST_PHB_ENTRY(0, 0, p0phb0_slot), /* P0E0_x16_Slot1 */
ST_PHB_ENTRY(0, 1, p0phb1_rF_slot), /* P0E1A_x8_PLX8748-1_Slot2-5 */
//ST_PHB_ENTRY(0, 2, p0phb2_slot), /* P0E1B_x8_USBTI7340 */
ST_PHB_ENTRY(0, 3, p0phb3_switch_slot),/* P0E2_x16_SWITCH_Slot3-4 */
/* ==== CPU1 ==== */
ST_PHB_ENTRY(8, 0, p1phb0_slot), /* P1E0_x16_Slot6 */
ST_PHB_ENTRY(8, 1, p1phb1_rF_slot), /* P1E1A_x8_PLX8748-2_Slot7-10 */
//ST_PHB_ENTRY(8, 2, p1phb2_slot), /* P1E1B_x8_NA */
ST_PHB_ENTRY(8, 3, p1phb3_switch_slot),/* P1E2_x16_SWITCH_Slot8-9 */
{ .etype = st_end },
};
#define NPU_BASE 0x5011000
#define NPU_SIZE 0x2c
#define NPU_INDIRECT0 0x8000000009010c3fUL /* OB0 - no OB3 on Mihawk */
/* OpenCAPI only */
static void create_link(struct dt_node *npu, int group, int index)
{
struct dt_node *link;
uint32_t lane_mask;
char namebuf[32];
snprintf(namebuf, sizeof(namebuf), "link@%x", index);
link = dt_new(npu, namebuf);
assert(link);
dt_add_property_string(link, "compatible", "ibm,npu-link");
dt_add_property_cells(link, "ibm,npu-link-index", index);
switch (index) {
case 2:
lane_mask = 0xf1e000; /* 0-3, 7-10 */
break;
case 3:
lane_mask = 0x00078f; /* 13-16, 20-23 */
break;
default:
assert(0);
}
dt_add_property_u64s(link, "ibm,npu-phy", NPU_INDIRECT0);
dt_add_property_cells(link, "ibm,npu-lane-mask", lane_mask);
dt_add_property_cells(link, "ibm,npu-group-id", group);
dt_add_property_u64s(link, "ibm,link-speed", 25000000000ul);
}
/* FIXME: Get rid of this after we get NPU information properly via HDAT/MRW */
static void mihawk_create_npu(void)
{
struct dt_node *xscom, *npu;
int npu_index = 0;
char namebuf[32];
/* Return if there's already an NPU in the device tree */
if (dt_find_compatible_node(dt_root, NULL, "ibm,power9-npu"))
return;
prlog(PR_DEBUG, "OCAPI: Adding NPU device nodes\n");
dt_for_each_compatible(dt_root, xscom, "ibm,xscom") {
snprintf(namebuf, sizeof(namebuf), "npu@%x", NPU_BASE);
npu = dt_new(xscom, namebuf);
dt_add_property_cells(npu, "reg", NPU_BASE, NPU_SIZE);
dt_add_property_strings(npu, "compatible", "ibm,power9-npu");
dt_add_property_cells(npu, "ibm,npu-index", npu_index++);
dt_add_property_cells(npu, "ibm,npu-links", 2);
create_link(npu, 1, 2);
create_link(npu, 2, 3);
}
}
/* FIXME: Get rid of this after we get NPU information properly via HDAT/MRW */
static void mihawk_create_ocapi_i2c_bus(void)
{
struct dt_node *xscom, *i2cm, *i2c_bus;
prlog(PR_DEBUG, "OCAPI: Adding I2C bus device node for OCAPI reset\n");
dt_for_each_compatible(dt_root, xscom, "ibm,xscom") {
i2cm = dt_find_by_name(xscom, "i2cm@a1000");
if (!i2cm) {
prlog(PR_ERR, "OCAPI: Failed to get I2C bus device node\n");
continue;
}
if (dt_find_by_name(i2cm, "i2c-bus@4"))
continue;
i2c_bus = dt_new_addr(i2cm, "i2c-bus", 4);
dt_add_property_cells(i2c_bus, "reg", 4);
dt_add_property_cells(i2c_bus, "bus-frequency", 0x61a80);
dt_add_property_strings(i2c_bus, "compatible",
"ibm,opal-i2c", "ibm,power8-i2c-port",
"ibm,power9-i2c-port");
}
}
/*
* HACK: Hostboot doesn't export the correct data for the system VPD EEPROM
* for this system. So we need to work around it here.
*/
static void vpd_dt_fixup(void)
{
struct dt_node *n = dt_find_by_path(dt_root,
"/xscom@603fc00000000/i2cm@a2000/i2c-bus@0/eeprom@50");
if (n) {
dt_check_del_prop(n, "compatible");
dt_add_property_string(n, "compatible", "atmel,24c512");
dt_check_del_prop(n, "label");
dt_add_property_string(n, "label", "system-vpd");
}
}
static bool mihawk_probe(void)
{
if (!dt_node_is_compatible(dt_root, "ibm,mihawk") &&
!dt_node_is_compatible(dt_root, "wistron,mihawk"))
return false;
/* Lot of common early inits here */
astbmc_early_init();
/* Setup UART for use by OPAL (Linux hvc) */
uart_set_console_policy(UART_CONSOLE_OPAL);
vpd_dt_fixup();
mihawk_create_npu();
mihawk_create_ocapi_i2c_bus();
return true;
}
static void mihawk_riser_query_complete(struct ipmi_msg *msg)
{
uint8_t *riser_state;
if (msg->cc != IPMI_CC_NO_ERROR) {
prlog(PR_ERR, "Mihawk: IPMI riser query returned error. cmd=0x%02x,"
" netfn=0x%02x, rc=0x%x\n", msg->cmd, msg->netfn, msg->cc);
bmc_query_waiting = false;
ipmi_free_msg(msg);
return;
}
prlog(PR_DEBUG, "Mihawk: IPMI Got riser query result. p0:%02x, p1:%02x\n"
, msg->data[0], msg->data[1]);
riser_state = (uint8_t*)msg->user_data;
lwsync();
*riser_state = msg->data[0] << 4 | msg->data[1];
bmc_query_waiting = false;
ipmi_free_msg(msg);
}
static void mihawk_init(void)
{
struct ipmi_msg *ipmi_msg;
uint8_t riser_state = 0;
int timeout_ms = 3000;
astbmc_init();
/*
* We use IPMI to ask BMC if Riser-F is installed and set up the
* corresponding slot table.
*/
ipmi_msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE,
IPMI_RISERF_QUERY,
mihawk_riser_query_complete,
&riser_state, NULL, 0, 2);
if (!ipmi_msg) {
prlog(PR_ERR, "Mihawk: Couldn't create ipmi msg.");
} else {
ipmi_msg->error = mihawk_riser_query_complete;
ipmi_queue_msg(ipmi_msg);
bmc_query_waiting = true;
prlog(PR_DEBUG, "Mihawk: Requesting IPMI_RISERF_QUERY (netfn "
"%02x, cmd %02x)\n", ipmi_msg->netfn, ipmi_msg->cmd);
while (bmc_query_waiting) {
time_wait_ms(10);
timeout_ms -= 10;
if (timeout_ms == 0)
break;
}
}
prlog(PR_DEBUG, "Mihawk: IPMI_RISERF_QUERY finish. riser_state: %02x"
", waiting: %d\n", riser_state, bmc_query_waiting);
if (riser_state != 0) {
mihawk_riserF_found = true;
slot_table_init(mihawk_riserF_phb_table);
prlog(PR_DEBUG, "Mihawk: Detect Riser-F via IPMI\n");
} else {
slot_table_init(mihawk_riserA_phb_table);
prlog(PR_DEBUG, "Mihawk: No Riser-F found, use Riser-A table\n");
}
}
DECLARE_PLATFORM(mihawk) = {
.name = "Mihawk",
.probe = mihawk_probe,
.init = mihawk_init,
.start_preload_resource = flash_start_preload_resource,
.resource_loaded = flash_resource_loaded,
.bmc = &bmc_plat_ast2500_openbmc,
.pci_get_slot_info = mihawk_get_slot_info,
.pci_probe_complete = check_all_slot_table,
.cec_power_down = astbmc_ipmi_power_down,
.cec_reboot = astbmc_ipmi_reboot,
.elog_commit = ipmi_elog_commit,
.exit = astbmc_exit,
.terminate = ipmi_terminate,
.ocapi = &mihawk_ocapi,
.npu2_device_detect = npu2_i2c_presence_detect,
};