3 * Copyright (C) 2010 - 2015 UNISYS CORPORATION
6 * This program is free software; you can redistribute it and/or modify it
7 * under the terms and conditions of the GNU General Public License,
8 * version 2, as published by the Free Software Foundation.
10 * This program is distributed in the hope that it will be useful, but
11 * WITHOUT ANY WARRANTY; without even the implied warranty of
12 * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
13 * NON INFRINGEMENT. See the GNU General Public License for more
17 #include <linux/acpi.h>
18 #include <linux/cdev.h>
19 #include <linux/ctype.h>
22 #include <linux/nls.h>
23 #include <linux/netdevice.h>
24 #include <linux/platform_device.h>
25 #include <linux/uuid.h>
26 #include <linux/crash_dump.h>
28 #include "channel_guid.h"
29 #include "controlvmchannel.h"
30 #include "controlvmcompletionstatus.h"
31 #include "guestlinuxdebug.h"
32 #include "periodic_work.h"
35 #include "visorbus_private.h"
36 #include "vmcallinterface.h"
38 #define CURRENT_FILE_PC VISOR_CHIPSET_PC_visorchipset_main_c
40 #define MAX_NAME_SIZE 128
41 #define MAX_IP_SIZE 50
42 #define MAXOUTSTANDINGCHANNELCOMMAND 256
43 #define POLLJIFFIES_CONTROLVMCHANNEL_FAST 1
44 #define POLLJIFFIES_CONTROLVMCHANNEL_SLOW 100
46 #define MAX_CONTROLVM_PAYLOAD_BYTES (1024*128)
48 #define VISORCHIPSET_MMAP_CONTROLCHANOFFSET 0x00000000
51 #define UNISYS_SPAR_LEAF_ID 0x40000000
53 /* The s-Par leaf ID returns "UnisysSpar64" encoded across ebx, ecx, edx */
54 #define UNISYS_SPAR_ID_EBX 0x73696e55
55 #define UNISYS_SPAR_ID_ECX 0x70537379
56 #define UNISYS_SPAR_ID_EDX 0x34367261
61 static int visorchipset_major;
62 static int visorchipset_visorbusregwait = 1; /* default is on */
63 static int visorchipset_holdchipsetready;
64 static unsigned long controlvm_payload_bytes_buffered;
67 visorchipset_open(struct inode *inode, struct file *file)
69 unsigned minor_number = iminor(inode);
73 file->private_data = NULL;
78 visorchipset_release(struct inode *inode, struct file *file)
83 /* When the controlvm channel is idle for at least MIN_IDLE_SECONDS,
84 * we switch to slow polling mode. As soon as we get a controlvm
85 * message, we switch back to fast polling mode.
87 #define MIN_IDLE_SECONDS 10
88 static unsigned long poll_jiffies = POLLJIFFIES_CONTROLVMCHANNEL_FAST;
89 static unsigned long most_recent_message_jiffies; /* when we got our last
90 * controlvm message */
91 static int visorbusregistered;
93 #define MAX_CHIPSET_EVENTS 2
94 static u8 chipset_events[MAX_CHIPSET_EVENTS] = { 0, 0 };
96 struct parser_context {
97 unsigned long allocbytes;
98 unsigned long param_bytes;
100 unsigned long bytes_remaining;
105 static struct delayed_work periodic_controlvm_work;
106 static struct workqueue_struct *periodic_controlvm_workqueue;
107 static DEFINE_SEMAPHORE(notifier_lock);
109 static struct cdev file_cdev;
110 static struct visorchannel **file_controlvm_channel;
111 static struct controlvm_message_header g_chipset_msg_hdr;
112 static struct controlvm_message_packet g_devicechangestate_packet;
114 static LIST_HEAD(bus_info_list);
115 static LIST_HEAD(dev_info_list);
117 static struct visorchannel *controlvm_channel;
119 /* Manages the request payload in the controlvm channel */
120 struct visor_controlvm_payload_info {
121 u8 *ptr; /* pointer to base address of payload pool */
122 u64 offset; /* offset from beginning of controlvm
123 * channel to beginning of payload * pool */
124 u32 bytes; /* number of bytes in payload pool */
127 static struct visor_controlvm_payload_info controlvm_payload_info;
129 /* The following globals are used to handle the scenario where we are unable to
130 * offload the payload from a controlvm message due to memory requirements. In
131 * this scenario, we simply stash the controlvm message, then attempt to
132 * process it again the next time controlvm_periodic_work() runs.
134 static struct controlvm_message controlvm_pending_msg;
135 static bool controlvm_pending_msg_valid;
137 /* This identifies a data buffer that has been received via a controlvm messages
138 * in a remote --> local CONTROLVM_TRANSMIT_FILE conversation.
140 struct putfile_buffer_entry {
141 struct list_head next; /* putfile_buffer_entry list */
142 struct parser_context *parser_ctx; /* points to input data buffer */
145 /* List of struct putfile_request *, via next_putfile_request member.
146 * Each entry in this list identifies an outstanding TRANSMIT_FILE
149 static LIST_HEAD(putfile_request_list);
151 /* This describes a buffer and its current state of transfer (e.g., how many
152 * bytes have already been supplied as putfile data, and how many bytes are
153 * remaining) for a putfile_request.
155 struct putfile_active_buffer {
156 /* a payload from a controlvm message, containing a file data buffer */
157 struct parser_context *parser_ctx;
158 /* points within data area of parser_ctx to next byte of data */
160 /* # bytes left from <pnext> to the end of this data buffer */
161 size_t bytes_remaining;
164 #define PUTFILE_REQUEST_SIG 0x0906101302281211
165 /* This identifies a single remote --> local CONTROLVM_TRANSMIT_FILE
166 * conversation. Structs of this type are dynamically linked into
167 * <Putfile_request_list>.
169 struct putfile_request {
170 u64 sig; /* PUTFILE_REQUEST_SIG */
172 /* header from original TransmitFile request */
173 struct controlvm_message_header controlvm_header;
174 u64 file_request_number; /* from original TransmitFile request */
176 /* link to next struct putfile_request */
177 struct list_head next_putfile_request;
179 /* most-recent sequence number supplied via a controlvm message */
180 u64 data_sequence_number;
182 /* head of putfile_buffer_entry list, which describes the data to be
183 * supplied as putfile data;
184 * - this list is added to when controlvm messages come in that supply
186 * - this list is removed from via the hotplug program that is actually
187 * consuming these buffers to write as file data */
188 struct list_head input_buffer_list;
189 spinlock_t req_list_lock; /* lock for input_buffer_list */
191 /* waiters for input_buffer_list to go non-empty */
192 wait_queue_head_t input_buffer_wq;
194 /* data not yet read within current putfile_buffer_entry */
195 struct putfile_active_buffer active_buf;
197 /* <0 = failed, 0 = in-progress, >0 = successful; */
198 /* note that this must be set with req_list_lock, and if you set <0, */
199 /* it is your responsibility to also free up all of the other objects */
200 /* in this struct (like input_buffer_list, active_buf.parser_ctx) */
201 /* before releasing the lock */
202 int completion_status;
205 struct parahotplug_request {
206 struct list_head list;
208 unsigned long expiration;
209 struct controlvm_message msg;
212 static LIST_HEAD(parahotplug_request_list);
213 static DEFINE_SPINLOCK(parahotplug_request_list_lock); /* lock for above */
214 static void parahotplug_process_list(void);
216 /* Manages the info for a CONTROLVM_DUMP_CAPTURESTATE /
217 * CONTROLVM_REPORTEVENT.
219 static struct visorchipset_busdev_notifiers busdev_notifiers;
221 static void bus_create_response(struct visor_device *p, int response);
222 static void bus_destroy_response(struct visor_device *p, int response);
223 static void device_create_response(struct visor_device *p, int response);
224 static void device_destroy_response(struct visor_device *p, int response);
225 static void device_resume_response(struct visor_device *p, int response);
227 static void visorchipset_device_pause_response(struct visor_device *p,
230 static struct visorchipset_busdev_responders busdev_responders = {
231 .bus_create = bus_create_response,
232 .bus_destroy = bus_destroy_response,
233 .device_create = device_create_response,
234 .device_destroy = device_destroy_response,
235 .device_pause = visorchipset_device_pause_response,
236 .device_resume = device_resume_response,
239 /* info for /dev/visorchipset */
240 static dev_t major_dev = -1; /**< indicates major num for device */
242 /* prototypes for attributes */
243 static ssize_t toolaction_show(struct device *dev,
244 struct device_attribute *attr, char *buf);
245 static ssize_t toolaction_store(struct device *dev,
246 struct device_attribute *attr,
247 const char *buf, size_t count);
248 static DEVICE_ATTR_RW(toolaction);
250 static ssize_t boottotool_show(struct device *dev,
251 struct device_attribute *attr, char *buf);
252 static ssize_t boottotool_store(struct device *dev,
253 struct device_attribute *attr, const char *buf,
255 static DEVICE_ATTR_RW(boottotool);
257 static ssize_t error_show(struct device *dev, struct device_attribute *attr,
259 static ssize_t error_store(struct device *dev, struct device_attribute *attr,
260 const char *buf, size_t count);
261 static DEVICE_ATTR_RW(error);
263 static ssize_t textid_show(struct device *dev, struct device_attribute *attr,
265 static ssize_t textid_store(struct device *dev, struct device_attribute *attr,
266 const char *buf, size_t count);
267 static DEVICE_ATTR_RW(textid);
269 static ssize_t remaining_steps_show(struct device *dev,
270 struct device_attribute *attr, char *buf);
271 static ssize_t remaining_steps_store(struct device *dev,
272 struct device_attribute *attr,
273 const char *buf, size_t count);
274 static DEVICE_ATTR_RW(remaining_steps);
276 static ssize_t chipsetready_store(struct device *dev,
277 struct device_attribute *attr,
278 const char *buf, size_t count);
279 static DEVICE_ATTR_WO(chipsetready);
281 static ssize_t devicedisabled_store(struct device *dev,
282 struct device_attribute *attr,
283 const char *buf, size_t count);
284 static DEVICE_ATTR_WO(devicedisabled);
286 static ssize_t deviceenabled_store(struct device *dev,
287 struct device_attribute *attr,
288 const char *buf, size_t count);
289 static DEVICE_ATTR_WO(deviceenabled);
291 static struct attribute *visorchipset_install_attrs[] = {
292 &dev_attr_toolaction.attr,
293 &dev_attr_boottotool.attr,
294 &dev_attr_error.attr,
295 &dev_attr_textid.attr,
296 &dev_attr_remaining_steps.attr,
300 static struct attribute_group visorchipset_install_group = {
302 .attrs = visorchipset_install_attrs
305 static struct attribute *visorchipset_guest_attrs[] = {
306 &dev_attr_chipsetready.attr,
310 static struct attribute_group visorchipset_guest_group = {
312 .attrs = visorchipset_guest_attrs
315 static struct attribute *visorchipset_parahotplug_attrs[] = {
316 &dev_attr_devicedisabled.attr,
317 &dev_attr_deviceenabled.attr,
321 static struct attribute_group visorchipset_parahotplug_group = {
322 .name = "parahotplug",
323 .attrs = visorchipset_parahotplug_attrs
326 static const struct attribute_group *visorchipset_dev_groups[] = {
327 &visorchipset_install_group,
328 &visorchipset_guest_group,
329 &visorchipset_parahotplug_group,
333 static void visorchipset_dev_release(struct device *dev)
337 /* /sys/devices/platform/visorchipset */
338 static struct platform_device visorchipset_platform_device = {
339 .name = "visorchipset",
341 .dev.groups = visorchipset_dev_groups,
342 .dev.release = visorchipset_dev_release,
345 /* Function prototypes */
346 static void controlvm_respond(struct controlvm_message_header *msg_hdr,
348 static void controlvm_respond_chipset_init(
349 struct controlvm_message_header *msg_hdr, int response,
350 enum ultra_chipset_feature features);
351 static void controlvm_respond_physdev_changestate(
352 struct controlvm_message_header *msg_hdr, int response,
353 struct spar_segment_state state);
356 static void parser_done(struct parser_context *ctx);
358 static struct parser_context *
359 parser_init_byte_stream(u64 addr, u32 bytes, bool local, bool *retry)
361 int allocbytes = sizeof(struct parser_context) + bytes;
362 struct parser_context *rc = NULL;
363 struct parser_context *ctx = NULL;
369 * alloc an 0 extra byte to ensure payload is
373 if ((controlvm_payload_bytes_buffered + bytes)
374 > MAX_CONTROLVM_PAYLOAD_BYTES) {
380 ctx = kzalloc(allocbytes, GFP_KERNEL|__GFP_NORETRY);
388 ctx->allocbytes = allocbytes;
389 ctx->param_bytes = bytes;
391 ctx->bytes_remaining = 0;
392 ctx->byte_stream = false;
396 if (addr > virt_to_phys(high_memory - 1)) {
400 p = __va((unsigned long) (addr));
401 memcpy(ctx->data, p, bytes);
405 if (!request_mem_region(addr, bytes, "visorchipset")) {
410 mapping = memremap(addr, bytes, MEMREMAP_WB);
412 release_mem_region(addr, bytes);
416 memcpy(ctx->data, mapping, bytes);
417 release_mem_region(addr, bytes);
421 ctx->byte_stream = true;
425 controlvm_payload_bytes_buffered += ctx->param_bytes;
436 parser_id_get(struct parser_context *ctx)
438 struct spar_controlvm_parameters_header *phdr = NULL;
442 phdr = (struct spar_controlvm_parameters_header *)(ctx->data);
446 /** Describes the state from the perspective of which controlvm messages have
447 * been received for a bus or device.
450 enum PARSER_WHICH_STRING {
451 PARSERSTRING_INITIATOR,
453 PARSERSTRING_CONNECTION,
454 PARSERSTRING_NAME, /* TODO: only PARSERSTRING_NAME is used ? */
458 parser_param_start(struct parser_context *ctx,
459 enum PARSER_WHICH_STRING which_string)
461 struct spar_controlvm_parameters_header *phdr = NULL;
465 phdr = (struct spar_controlvm_parameters_header *)(ctx->data);
466 switch (which_string) {
467 case PARSERSTRING_INITIATOR:
468 ctx->curr = ctx->data + phdr->initiator_offset;
469 ctx->bytes_remaining = phdr->initiator_length;
471 case PARSERSTRING_TARGET:
472 ctx->curr = ctx->data + phdr->target_offset;
473 ctx->bytes_remaining = phdr->target_length;
475 case PARSERSTRING_CONNECTION:
476 ctx->curr = ctx->data + phdr->connection_offset;
477 ctx->bytes_remaining = phdr->connection_length;
479 case PARSERSTRING_NAME:
480 ctx->curr = ctx->data + phdr->name_offset;
481 ctx->bytes_remaining = phdr->name_length;
491 static void parser_done(struct parser_context *ctx)
495 controlvm_payload_bytes_buffered -= ctx->param_bytes;
500 parser_string_get(struct parser_context *ctx)
504 int value_length = -1;
511 nscan = ctx->bytes_remaining;
516 for (i = 0, value_length = -1; i < nscan; i++)
517 if (pscan[i] == '\0') {
521 if (value_length < 0) /* '\0' was not included in the length */
522 value_length = nscan;
523 value = kmalloc(value_length + 1, GFP_KERNEL|__GFP_NORETRY);
526 if (value_length > 0)
527 memcpy(value, pscan, value_length);
528 ((u8 *) (value))[value_length] = '\0';
533 static ssize_t toolaction_show(struct device *dev,
534 struct device_attribute *attr,
539 visorchannel_read(controlvm_channel,
540 offsetof(struct spar_controlvm_channel_protocol,
541 tool_action), &tool_action, sizeof(u8));
542 return scnprintf(buf, PAGE_SIZE, "%u\n", tool_action);
545 static ssize_t toolaction_store(struct device *dev,
546 struct device_attribute *attr,
547 const char *buf, size_t count)
552 if (kstrtou8(buf, 10, &tool_action))
555 ret = visorchannel_write(controlvm_channel,
556 offsetof(struct spar_controlvm_channel_protocol,
558 &tool_action, sizeof(u8));
565 static ssize_t boottotool_show(struct device *dev,
566 struct device_attribute *attr,
569 struct efi_spar_indication efi_spar_indication;
571 visorchannel_read(controlvm_channel,
572 offsetof(struct spar_controlvm_channel_protocol,
573 efi_spar_ind), &efi_spar_indication,
574 sizeof(struct efi_spar_indication));
575 return scnprintf(buf, PAGE_SIZE, "%u\n",
576 efi_spar_indication.boot_to_tool);
579 static ssize_t boottotool_store(struct device *dev,
580 struct device_attribute *attr,
581 const char *buf, size_t count)
584 struct efi_spar_indication efi_spar_indication;
586 if (kstrtoint(buf, 10, &val))
589 efi_spar_indication.boot_to_tool = val;
590 ret = visorchannel_write(controlvm_channel,
591 offsetof(struct spar_controlvm_channel_protocol,
592 efi_spar_ind), &(efi_spar_indication),
593 sizeof(struct efi_spar_indication));
600 static ssize_t error_show(struct device *dev, struct device_attribute *attr,
605 visorchannel_read(controlvm_channel,
606 offsetof(struct spar_controlvm_channel_protocol,
608 &error, sizeof(u32));
609 return scnprintf(buf, PAGE_SIZE, "%i\n", error);
612 static ssize_t error_store(struct device *dev, struct device_attribute *attr,
613 const char *buf, size_t count)
618 if (kstrtou32(buf, 10, &error))
621 ret = visorchannel_write(controlvm_channel,
622 offsetof(struct spar_controlvm_channel_protocol,
624 &error, sizeof(u32));
630 static ssize_t textid_show(struct device *dev, struct device_attribute *attr,
635 visorchannel_read(controlvm_channel,
636 offsetof(struct spar_controlvm_channel_protocol,
637 installation_text_id),
638 &text_id, sizeof(u32));
639 return scnprintf(buf, PAGE_SIZE, "%i\n", text_id);
642 static ssize_t textid_store(struct device *dev, struct device_attribute *attr,
643 const char *buf, size_t count)
648 if (kstrtou32(buf, 10, &text_id))
651 ret = visorchannel_write(controlvm_channel,
652 offsetof(struct spar_controlvm_channel_protocol,
653 installation_text_id),
654 &text_id, sizeof(u32));
660 static ssize_t remaining_steps_show(struct device *dev,
661 struct device_attribute *attr, char *buf)
665 visorchannel_read(controlvm_channel,
666 offsetof(struct spar_controlvm_channel_protocol,
667 installation_remaining_steps),
668 &remaining_steps, sizeof(u16));
669 return scnprintf(buf, PAGE_SIZE, "%hu\n", remaining_steps);
672 static ssize_t remaining_steps_store(struct device *dev,
673 struct device_attribute *attr,
674 const char *buf, size_t count)
679 if (kstrtou16(buf, 10, &remaining_steps))
682 ret = visorchannel_write(controlvm_channel,
683 offsetof(struct spar_controlvm_channel_protocol,
684 installation_remaining_steps),
685 &remaining_steps, sizeof(u16));
691 struct visor_busdev {
696 static int match_visorbus_dev_by_id(struct device *dev, void *data)
698 struct visor_device *vdev = to_visor_device(dev);
699 struct visor_busdev *id = (struct visor_busdev *)data;
700 u32 bus_no = id->bus_no;
701 u32 dev_no = id->dev_no;
703 if ((vdev->chipset_bus_no == bus_no) &&
704 (vdev->chipset_dev_no == dev_no))
709 struct visor_device *visorbus_get_device_by_id(u32 bus_no, u32 dev_no,
710 struct visor_device *from)
713 struct device *dev_start = NULL;
714 struct visor_device *vdev = NULL;
715 struct visor_busdev id = {
721 dev_start = &from->device;
722 dev = bus_find_device(&visorbus_type, dev_start, (void *)&id,
723 match_visorbus_dev_by_id);
725 vdev = to_visor_device(dev);
728 EXPORT_SYMBOL(visorbus_get_device_by_id);
731 check_chipset_events(void)
735 /* Check events to determine if response should be sent */
736 for (i = 0; i < MAX_CHIPSET_EVENTS; i++)
737 send_msg &= chipset_events[i];
742 clear_chipset_events(void)
745 /* Clear chipset_events */
746 for (i = 0; i < MAX_CHIPSET_EVENTS; i++)
747 chipset_events[i] = 0;
751 visorchipset_register_busdev(
752 struct visorchipset_busdev_notifiers *notifiers,
753 struct visorchipset_busdev_responders *responders,
754 struct ultra_vbus_deviceinfo *driver_info)
756 down(¬ifier_lock);
758 memset(&busdev_notifiers, 0,
759 sizeof(busdev_notifiers));
760 visorbusregistered = 0; /* clear flag */
762 busdev_notifiers = *notifiers;
763 visorbusregistered = 1; /* set flag */
766 *responders = busdev_responders;
768 bus_device_info_init(driver_info, "chipset", "visorchipset",
773 EXPORT_SYMBOL_GPL(visorchipset_register_busdev);
776 chipset_init(struct controlvm_message *inmsg)
778 static int chipset_inited;
779 enum ultra_chipset_feature features = 0;
780 int rc = CONTROLVM_RESP_SUCCESS;
782 POSTCODE_LINUX_2(CHIPSET_INIT_ENTRY_PC, POSTCODE_SEVERITY_INFO);
783 if (chipset_inited) {
784 rc = -CONTROLVM_RESP_ERROR_ALREADY_DONE;
788 POSTCODE_LINUX_2(CHIPSET_INIT_EXIT_PC, POSTCODE_SEVERITY_INFO);
790 /* Set features to indicate we support parahotplug (if Command
791 * also supports it). */
793 inmsg->cmd.init_chipset.
794 features & ULTRA_CHIPSET_FEATURE_PARA_HOTPLUG;
796 /* Set the "reply" bit so Command knows this is a
797 * features-aware driver. */
798 features |= ULTRA_CHIPSET_FEATURE_REPLY;
801 if (inmsg->hdr.flags.response_expected)
802 controlvm_respond_chipset_init(&inmsg->hdr, rc, features);
806 controlvm_init_response(struct controlvm_message *msg,
807 struct controlvm_message_header *msg_hdr, int response)
809 memset(msg, 0, sizeof(struct controlvm_message));
810 memcpy(&msg->hdr, msg_hdr, sizeof(struct controlvm_message_header));
811 msg->hdr.payload_bytes = 0;
812 msg->hdr.payload_vm_offset = 0;
813 msg->hdr.payload_max_bytes = 0;
815 msg->hdr.flags.failed = 1;
816 msg->hdr.completion_status = (u32) (-response);
821 controlvm_respond(struct controlvm_message_header *msg_hdr, int response)
823 struct controlvm_message outmsg;
825 controlvm_init_response(&outmsg, msg_hdr, response);
826 if (outmsg.hdr.flags.test_message == 1)
829 if (!visorchannel_signalinsert(controlvm_channel,
830 CONTROLVM_QUEUE_REQUEST, &outmsg)) {
836 controlvm_respond_chipset_init(struct controlvm_message_header *msg_hdr,
838 enum ultra_chipset_feature features)
840 struct controlvm_message outmsg;
842 controlvm_init_response(&outmsg, msg_hdr, response);
843 outmsg.cmd.init_chipset.features = features;
844 if (!visorchannel_signalinsert(controlvm_channel,
845 CONTROLVM_QUEUE_REQUEST, &outmsg)) {
850 static void controlvm_respond_physdev_changestate(
851 struct controlvm_message_header *msg_hdr, int response,
852 struct spar_segment_state state)
854 struct controlvm_message outmsg;
856 controlvm_init_response(&outmsg, msg_hdr, response);
857 outmsg.cmd.device_change_state.state = state;
858 outmsg.cmd.device_change_state.flags.phys_device = 1;
859 if (!visorchannel_signalinsert(controlvm_channel,
860 CONTROLVM_QUEUE_REQUEST, &outmsg)) {
865 enum crash_obj_type {
871 bus_responder(enum controlvm_id cmd_id,
872 struct controlvm_message_header *pending_msg_hdr,
875 if (pending_msg_hdr == NULL)
876 return; /* no controlvm response needed */
878 if (pending_msg_hdr->id != (u32)cmd_id)
881 controlvm_respond(pending_msg_hdr, response);
885 device_changestate_responder(enum controlvm_id cmd_id,
886 struct visor_device *p, int response,
887 struct spar_segment_state response_state)
889 struct controlvm_message outmsg;
890 u32 bus_no = p->chipset_bus_no;
891 u32 dev_no = p->chipset_dev_no;
893 if (p->pending_msg_hdr == NULL)
894 return; /* no controlvm response needed */
895 if (p->pending_msg_hdr->id != cmd_id)
898 controlvm_init_response(&outmsg, p->pending_msg_hdr, response);
900 outmsg.cmd.device_change_state.bus_no = bus_no;
901 outmsg.cmd.device_change_state.dev_no = dev_no;
902 outmsg.cmd.device_change_state.state = response_state;
904 if (!visorchannel_signalinsert(controlvm_channel,
905 CONTROLVM_QUEUE_REQUEST, &outmsg))
910 device_responder(enum controlvm_id cmd_id,
911 struct controlvm_message_header *pending_msg_hdr,
914 if (pending_msg_hdr == NULL)
915 return; /* no controlvm response needed */
917 if (pending_msg_hdr->id != (u32)cmd_id)
920 controlvm_respond(pending_msg_hdr, response);
924 bus_epilog(struct visor_device *bus_info,
925 u32 cmd, struct controlvm_message_header *msg_hdr,
926 int response, bool need_response)
928 bool notified = false;
929 struct controlvm_message_header *pmsg_hdr = NULL;
932 /* relying on a valid passed in response code */
933 /* be lazy and re-use msg_hdr for this failure, is this ok?? */
938 if (bus_info->pending_msg_hdr) {
939 /* only non-NULL if dev is still waiting on a response */
940 response = -CONTROLVM_RESP_ERROR_MESSAGE_ID_INVALID_FOR_CLIENT;
941 pmsg_hdr = bus_info->pending_msg_hdr;
946 pmsg_hdr = kzalloc(sizeof(*pmsg_hdr), GFP_KERNEL);
948 response = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
952 memcpy(pmsg_hdr, msg_hdr,
953 sizeof(struct controlvm_message_header));
954 bus_info->pending_msg_hdr = pmsg_hdr;
957 down(¬ifier_lock);
958 if (response == CONTROLVM_RESP_SUCCESS) {
960 case CONTROLVM_BUS_CREATE:
961 if (busdev_notifiers.bus_create) {
962 (*busdev_notifiers.bus_create) (bus_info);
966 case CONTROLVM_BUS_DESTROY:
967 if (busdev_notifiers.bus_destroy) {
968 (*busdev_notifiers.bus_destroy) (bus_info);
976 /* The callback function just called above is responsible
977 * for calling the appropriate visorchipset_busdev_responders
978 * function, which will call bus_responder()
983 * Do not kfree(pmsg_hdr) as this is the failure path.
984 * The success path ('notified') will call the responder
985 * directly and kfree() there.
987 bus_responder(cmd, pmsg_hdr, response);
992 device_epilog(struct visor_device *dev_info,
993 struct spar_segment_state state, u32 cmd,
994 struct controlvm_message_header *msg_hdr, int response,
995 bool need_response, bool for_visorbus)
997 struct visorchipset_busdev_notifiers *notifiers;
998 bool notified = false;
999 struct controlvm_message_header *pmsg_hdr = NULL;
1001 notifiers = &busdev_notifiers;
1004 /* relying on a valid passed in response code */
1005 /* be lazy and re-use msg_hdr for this failure, is this ok?? */
1010 if (dev_info->pending_msg_hdr) {
1011 /* only non-NULL if dev is still waiting on a response */
1012 response = -CONTROLVM_RESP_ERROR_MESSAGE_ID_INVALID_FOR_CLIENT;
1013 pmsg_hdr = dev_info->pending_msg_hdr;
1017 if (need_response) {
1018 pmsg_hdr = kzalloc(sizeof(*pmsg_hdr), GFP_KERNEL);
1020 response = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
1024 memcpy(pmsg_hdr, msg_hdr,
1025 sizeof(struct controlvm_message_header));
1026 dev_info->pending_msg_hdr = pmsg_hdr;
1029 down(¬ifier_lock);
1030 if (response >= 0) {
1032 case CONTROLVM_DEVICE_CREATE:
1033 if (notifiers->device_create) {
1034 (*notifiers->device_create) (dev_info);
1038 case CONTROLVM_DEVICE_CHANGESTATE:
1039 /* ServerReady / ServerRunning / SegmentStateRunning */
1040 if (state.alive == segment_state_running.alive &&
1042 segment_state_running.operating) {
1043 if (notifiers->device_resume) {
1044 (*notifiers->device_resume) (dev_info);
1048 /* ServerNotReady / ServerLost / SegmentStateStandby */
1049 else if (state.alive == segment_state_standby.alive &&
1051 segment_state_standby.operating) {
1052 /* technically this is standby case
1053 * where server is lost
1055 if (notifiers->device_pause) {
1056 (*notifiers->device_pause) (dev_info);
1061 case CONTROLVM_DEVICE_DESTROY:
1062 if (notifiers->device_destroy) {
1063 (*notifiers->device_destroy) (dev_info);
1071 /* The callback function just called above is responsible
1072 * for calling the appropriate visorchipset_busdev_responders
1073 * function, which will call device_responder()
1078 * Do not kfree(pmsg_hdr) as this is the failure path.
1079 * The success path ('notified') will call the responder
1080 * directly and kfree() there.
1082 device_responder(cmd, pmsg_hdr, response);
1087 bus_create(struct controlvm_message *inmsg)
1089 struct controlvm_message_packet *cmd = &inmsg->cmd;
1090 u32 bus_no = cmd->create_bus.bus_no;
1091 int rc = CONTROLVM_RESP_SUCCESS;
1092 struct visor_device *bus_info;
1093 struct visorchannel *visorchannel;
1095 bus_info = visorbus_get_device_by_id(bus_no, BUS_ROOT_DEVICE, NULL);
1096 if (bus_info && (bus_info->state.created == 1)) {
1097 POSTCODE_LINUX_3(BUS_CREATE_FAILURE_PC, bus_no,
1098 POSTCODE_SEVERITY_ERR);
1099 rc = -CONTROLVM_RESP_ERROR_ALREADY_DONE;
1102 bus_info = kzalloc(sizeof(*bus_info), GFP_KERNEL);
1104 POSTCODE_LINUX_3(BUS_CREATE_FAILURE_PC, bus_no,
1105 POSTCODE_SEVERITY_ERR);
1106 rc = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
1110 INIT_LIST_HEAD(&bus_info->list_all);
1111 bus_info->chipset_bus_no = bus_no;
1112 bus_info->chipset_dev_no = BUS_ROOT_DEVICE;
1114 POSTCODE_LINUX_3(BUS_CREATE_ENTRY_PC, bus_no, POSTCODE_SEVERITY_INFO);
1116 visorchannel = visorchannel_create(cmd->create_bus.channel_addr,
1117 cmd->create_bus.channel_bytes,
1119 cmd->create_bus.bus_data_type_uuid);
1121 if (!visorchannel) {
1122 POSTCODE_LINUX_3(BUS_CREATE_FAILURE_PC, bus_no,
1123 POSTCODE_SEVERITY_ERR);
1124 rc = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
1129 bus_info->visorchannel = visorchannel;
1131 POSTCODE_LINUX_3(BUS_CREATE_EXIT_PC, bus_no, POSTCODE_SEVERITY_INFO);
1134 bus_epilog(bus_info, CONTROLVM_BUS_CREATE, &inmsg->hdr,
1135 rc, inmsg->hdr.flags.response_expected == 1);
1139 bus_destroy(struct controlvm_message *inmsg)
1141 struct controlvm_message_packet *cmd = &inmsg->cmd;
1142 u32 bus_no = cmd->destroy_bus.bus_no;
1143 struct visor_device *bus_info;
1144 int rc = CONTROLVM_RESP_SUCCESS;
1146 bus_info = visorbus_get_device_by_id(bus_no, BUS_ROOT_DEVICE, NULL);
1148 rc = -CONTROLVM_RESP_ERROR_BUS_INVALID;
1149 else if (bus_info->state.created == 0)
1150 rc = -CONTROLVM_RESP_ERROR_ALREADY_DONE;
1152 bus_epilog(bus_info, CONTROLVM_BUS_DESTROY, &inmsg->hdr,
1153 rc, inmsg->hdr.flags.response_expected == 1);
1155 /* bus_info is freed as part of the busdevice_release function */
1159 bus_configure(struct controlvm_message *inmsg,
1160 struct parser_context *parser_ctx)
1162 struct controlvm_message_packet *cmd = &inmsg->cmd;
1164 struct visor_device *bus_info;
1165 int rc = CONTROLVM_RESP_SUCCESS;
1167 bus_no = cmd->configure_bus.bus_no;
1168 POSTCODE_LINUX_3(BUS_CONFIGURE_ENTRY_PC, bus_no,
1169 POSTCODE_SEVERITY_INFO);
1171 bus_info = visorbus_get_device_by_id(bus_no, BUS_ROOT_DEVICE, NULL);
1173 POSTCODE_LINUX_3(BUS_CONFIGURE_FAILURE_PC, bus_no,
1174 POSTCODE_SEVERITY_ERR);
1175 rc = -CONTROLVM_RESP_ERROR_BUS_INVALID;
1176 } else if (bus_info->state.created == 0) {
1177 POSTCODE_LINUX_3(BUS_CONFIGURE_FAILURE_PC, bus_no,
1178 POSTCODE_SEVERITY_ERR);
1179 rc = -CONTROLVM_RESP_ERROR_BUS_INVALID;
1180 } else if (bus_info->pending_msg_hdr != NULL) {
1181 POSTCODE_LINUX_3(BUS_CONFIGURE_FAILURE_PC, bus_no,
1182 POSTCODE_SEVERITY_ERR);
1183 rc = -CONTROLVM_RESP_ERROR_MESSAGE_ID_INVALID_FOR_CLIENT;
1185 visorchannel_set_clientpartition(bus_info->visorchannel,
1186 cmd->configure_bus.guest_handle);
1187 bus_info->partition_uuid = parser_id_get(parser_ctx);
1188 parser_param_start(parser_ctx, PARSERSTRING_NAME);
1189 bus_info->name = parser_string_get(parser_ctx);
1191 POSTCODE_LINUX_3(BUS_CONFIGURE_EXIT_PC, bus_no,
1192 POSTCODE_SEVERITY_INFO);
1194 bus_epilog(bus_info, CONTROLVM_BUS_CONFIGURE, &inmsg->hdr,
1195 rc, inmsg->hdr.flags.response_expected == 1);
1199 my_device_create(struct controlvm_message *inmsg)
1201 struct controlvm_message_packet *cmd = &inmsg->cmd;
1202 u32 bus_no = cmd->create_device.bus_no;
1203 u32 dev_no = cmd->create_device.dev_no;
1204 struct visor_device *dev_info = NULL;
1205 struct visor_device *bus_info;
1206 struct visorchannel *visorchannel;
1207 int rc = CONTROLVM_RESP_SUCCESS;
1209 bus_info = visorbus_get_device_by_id(bus_no, BUS_ROOT_DEVICE, NULL);
1211 POSTCODE_LINUX_4(DEVICE_CREATE_FAILURE_PC, dev_no, bus_no,
1212 POSTCODE_SEVERITY_ERR);
1213 rc = -CONTROLVM_RESP_ERROR_BUS_INVALID;
1217 if (bus_info->state.created == 0) {
1218 POSTCODE_LINUX_4(DEVICE_CREATE_FAILURE_PC, dev_no, bus_no,
1219 POSTCODE_SEVERITY_ERR);
1220 rc = -CONTROLVM_RESP_ERROR_BUS_INVALID;
1224 dev_info = visorbus_get_device_by_id(bus_no, dev_no, NULL);
1225 if (dev_info && (dev_info->state.created == 1)) {
1226 POSTCODE_LINUX_4(DEVICE_CREATE_FAILURE_PC, dev_no, bus_no,
1227 POSTCODE_SEVERITY_ERR);
1228 rc = -CONTROLVM_RESP_ERROR_ALREADY_DONE;
1232 dev_info = kzalloc(sizeof(*dev_info), GFP_KERNEL);
1234 POSTCODE_LINUX_4(DEVICE_CREATE_FAILURE_PC, dev_no, bus_no,
1235 POSTCODE_SEVERITY_ERR);
1236 rc = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
1240 dev_info->chipset_bus_no = bus_no;
1241 dev_info->chipset_dev_no = dev_no;
1242 dev_info->inst = cmd->create_device.dev_inst_uuid;
1244 /* not sure where the best place to set the 'parent' */
1245 dev_info->device.parent = &bus_info->device;
1247 POSTCODE_LINUX_4(DEVICE_CREATE_ENTRY_PC, dev_no, bus_no,
1248 POSTCODE_SEVERITY_INFO);
1251 visorchannel_create_with_lock(cmd->create_device.channel_addr,
1252 cmd->create_device.channel_bytes,
1254 cmd->create_device.data_type_uuid);
1256 if (!visorchannel) {
1257 POSTCODE_LINUX_4(DEVICE_CREATE_FAILURE_PC, dev_no, bus_no,
1258 POSTCODE_SEVERITY_ERR);
1259 rc = -CONTROLVM_RESP_ERROR_KMALLOC_FAILED;
1264 dev_info->visorchannel = visorchannel;
1265 dev_info->channel_type_guid = cmd->create_device.data_type_uuid;
1266 POSTCODE_LINUX_4(DEVICE_CREATE_EXIT_PC, dev_no, bus_no,
1267 POSTCODE_SEVERITY_INFO);
1269 device_epilog(dev_info, segment_state_running,
1270 CONTROLVM_DEVICE_CREATE, &inmsg->hdr, rc,
1271 inmsg->hdr.flags.response_expected == 1, 1);
1275 my_device_changestate(struct controlvm_message *inmsg)
1277 struct controlvm_message_packet *cmd = &inmsg->cmd;
1278 u32 bus_no = cmd->device_change_state.bus_no;
1279 u32 dev_no = cmd->device_change_state.dev_no;
1280 struct spar_segment_state state = cmd->device_change_state.state;
1281 struct visor_device *dev_info;
1282 int rc = CONTROLVM_RESP_SUCCESS;
1284 dev_info = visorbus_get_device_by_id(bus_no, dev_no, NULL);
1286 POSTCODE_LINUX_4(DEVICE_CHANGESTATE_FAILURE_PC, dev_no, bus_no,
1287 POSTCODE_SEVERITY_ERR);
1288 rc = -CONTROLVM_RESP_ERROR_DEVICE_INVALID;
1289 } else if (dev_info->state.created == 0) {
1290 POSTCODE_LINUX_4(DEVICE_CHANGESTATE_FAILURE_PC, dev_no, bus_no,
1291 POSTCODE_SEVERITY_ERR);
1292 rc = -CONTROLVM_RESP_ERROR_DEVICE_INVALID;
1294 if ((rc >= CONTROLVM_RESP_SUCCESS) && dev_info)
1295 device_epilog(dev_info, state,
1296 CONTROLVM_DEVICE_CHANGESTATE, &inmsg->hdr, rc,
1297 inmsg->hdr.flags.response_expected == 1, 1);
1301 my_device_destroy(struct controlvm_message *inmsg)
1303 struct controlvm_message_packet *cmd = &inmsg->cmd;
1304 u32 bus_no = cmd->destroy_device.bus_no;
1305 u32 dev_no = cmd->destroy_device.dev_no;
1306 struct visor_device *dev_info;
1307 int rc = CONTROLVM_RESP_SUCCESS;
1309 dev_info = visorbus_get_device_by_id(bus_no, dev_no, NULL);
1311 rc = -CONTROLVM_RESP_ERROR_DEVICE_INVALID;
1312 else if (dev_info->state.created == 0)
1313 rc = -CONTROLVM_RESP_ERROR_ALREADY_DONE;
1315 if ((rc >= CONTROLVM_RESP_SUCCESS) && dev_info)
1316 device_epilog(dev_info, segment_state_running,
1317 CONTROLVM_DEVICE_DESTROY, &inmsg->hdr, rc,
1318 inmsg->hdr.flags.response_expected == 1, 1);
1321 /* When provided with the physical address of the controlvm channel
1322 * (phys_addr), the offset to the payload area we need to manage
1323 * (offset), and the size of this payload area (bytes), fills in the
1324 * controlvm_payload_info struct. Returns true for success or false
1328 initialize_controlvm_payload_info(u64 phys_addr, u64 offset, u32 bytes,
1329 struct visor_controlvm_payload_info *info)
1332 int rc = CONTROLVM_RESP_SUCCESS;
1335 rc = -CONTROLVM_RESP_ERROR_PAYLOAD_INVALID;
1338 memset(info, 0, sizeof(struct visor_controlvm_payload_info));
1339 if ((offset == 0) || (bytes == 0)) {
1340 rc = -CONTROLVM_RESP_ERROR_PAYLOAD_INVALID;
1343 payload = memremap(phys_addr + offset, bytes, MEMREMAP_WB);
1345 rc = -CONTROLVM_RESP_ERROR_IOREMAP_FAILED;
1349 info->offset = offset;
1350 info->bytes = bytes;
1351 info->ptr = payload;
1364 destroy_controlvm_payload_info(struct visor_controlvm_payload_info *info)
1367 memunmap(info->ptr);
1370 memset(info, 0, sizeof(struct visor_controlvm_payload_info));
1374 initialize_controlvm_payload(void)
1376 u64 phys_addr = visorchannel_get_physaddr(controlvm_channel);
1377 u64 payload_offset = 0;
1378 u32 payload_bytes = 0;
1380 if (visorchannel_read(controlvm_channel,
1381 offsetof(struct spar_controlvm_channel_protocol,
1382 request_payload_offset),
1383 &payload_offset, sizeof(payload_offset)) < 0) {
1384 POSTCODE_LINUX_2(CONTROLVM_INIT_FAILURE_PC,
1385 POSTCODE_SEVERITY_ERR);
1388 if (visorchannel_read(controlvm_channel,
1389 offsetof(struct spar_controlvm_channel_protocol,
1390 request_payload_bytes),
1391 &payload_bytes, sizeof(payload_bytes)) < 0) {
1392 POSTCODE_LINUX_2(CONTROLVM_INIT_FAILURE_PC,
1393 POSTCODE_SEVERITY_ERR);
1396 initialize_controlvm_payload_info(phys_addr,
1397 payload_offset, payload_bytes,
1398 &controlvm_payload_info);
1401 /* Send ACTION=online for DEVPATH=/sys/devices/platform/visorchipset.
1402 * Returns CONTROLVM_RESP_xxx code.
1405 visorchipset_chipset_ready(void)
1407 kobject_uevent(&visorchipset_platform_device.dev.kobj, KOBJ_ONLINE);
1408 return CONTROLVM_RESP_SUCCESS;
1412 visorchipset_chipset_selftest(void)
1414 char env_selftest[20];
1415 char *envp[] = { env_selftest, NULL };
1417 sprintf(env_selftest, "SPARSP_SELFTEST=%d", 1);
1418 kobject_uevent_env(&visorchipset_platform_device.dev.kobj, KOBJ_CHANGE,
1420 return CONTROLVM_RESP_SUCCESS;
1423 /* Send ACTION=offline for DEVPATH=/sys/devices/platform/visorchipset.
1424 * Returns CONTROLVM_RESP_xxx code.
1427 visorchipset_chipset_notready(void)
1429 kobject_uevent(&visorchipset_platform_device.dev.kobj, KOBJ_OFFLINE);
1430 return CONTROLVM_RESP_SUCCESS;
1434 chipset_ready(struct controlvm_message_header *msg_hdr)
1436 int rc = visorchipset_chipset_ready();
1438 if (rc != CONTROLVM_RESP_SUCCESS)
1440 if (msg_hdr->flags.response_expected && !visorchipset_holdchipsetready)
1441 controlvm_respond(msg_hdr, rc);
1442 if (msg_hdr->flags.response_expected && visorchipset_holdchipsetready) {
1443 /* Send CHIPSET_READY response when all modules have been loaded
1444 * and disks mounted for the partition
1446 g_chipset_msg_hdr = *msg_hdr;
1451 chipset_selftest(struct controlvm_message_header *msg_hdr)
1453 int rc = visorchipset_chipset_selftest();
1455 if (rc != CONTROLVM_RESP_SUCCESS)
1457 if (msg_hdr->flags.response_expected)
1458 controlvm_respond(msg_hdr, rc);
1462 chipset_notready(struct controlvm_message_header *msg_hdr)
1464 int rc = visorchipset_chipset_notready();
1466 if (rc != CONTROLVM_RESP_SUCCESS)
1468 if (msg_hdr->flags.response_expected)
1469 controlvm_respond(msg_hdr, rc);
1472 /* This is your "one-stop" shop for grabbing the next message from the
1473 * CONTROLVM_QUEUE_EVENT queue in the controlvm channel.
1476 read_controlvm_event(struct controlvm_message *msg)
1478 if (visorchannel_signalremove(controlvm_channel,
1479 CONTROLVM_QUEUE_EVENT, msg)) {
1481 if (msg->hdr.flags.test_message == 1)
1489 * The general parahotplug flow works as follows. The visorchipset
1490 * driver receives a DEVICE_CHANGESTATE message from Command
1491 * specifying a physical device to enable or disable. The CONTROLVM
1492 * message handler calls parahotplug_process_message, which then adds
1493 * the message to a global list and kicks off a udev event which
1494 * causes a user level script to enable or disable the specified
1495 * device. The udev script then writes to
1496 * /proc/visorchipset/parahotplug, which causes parahotplug_proc_write
1497 * to get called, at which point the appropriate CONTROLVM message is
1498 * retrieved from the list and responded to.
1501 #define PARAHOTPLUG_TIMEOUT_MS 2000
1504 * Generate unique int to match an outstanding CONTROLVM message with a
1505 * udev script /proc response
1508 parahotplug_next_id(void)
1510 static atomic_t id = ATOMIC_INIT(0);
1512 return atomic_inc_return(&id);
1516 * Returns the time (in jiffies) when a CONTROLVM message on the list
1517 * should expire -- PARAHOTPLUG_TIMEOUT_MS in the future
1519 static unsigned long
1520 parahotplug_next_expiration(void)
1522 return jiffies + msecs_to_jiffies(PARAHOTPLUG_TIMEOUT_MS);
1526 * Create a parahotplug_request, which is basically a wrapper for a
1527 * CONTROLVM_MESSAGE that we can stick on a list
1529 static struct parahotplug_request *
1530 parahotplug_request_create(struct controlvm_message *msg)
1532 struct parahotplug_request *req;
1534 req = kmalloc(sizeof(*req), GFP_KERNEL | __GFP_NORETRY);
1538 req->id = parahotplug_next_id();
1539 req->expiration = parahotplug_next_expiration();
1546 * Free a parahotplug_request.
1549 parahotplug_request_destroy(struct parahotplug_request *req)
1555 * Cause uevent to run the user level script to do the disable/enable
1556 * specified in (the CONTROLVM message in) the specified
1557 * parahotplug_request
1560 parahotplug_request_kickoff(struct parahotplug_request *req)
1562 struct controlvm_message_packet *cmd = &req->msg.cmd;
1563 char env_cmd[40], env_id[40], env_state[40], env_bus[40], env_dev[40],
1566 env_cmd, env_id, env_state, env_bus, env_dev, env_func, NULL
1569 sprintf(env_cmd, "SPAR_PARAHOTPLUG=1");
1570 sprintf(env_id, "SPAR_PARAHOTPLUG_ID=%d", req->id);
1571 sprintf(env_state, "SPAR_PARAHOTPLUG_STATE=%d",
1572 cmd->device_change_state.state.active);
1573 sprintf(env_bus, "SPAR_PARAHOTPLUG_BUS=%d",
1574 cmd->device_change_state.bus_no);
1575 sprintf(env_dev, "SPAR_PARAHOTPLUG_DEVICE=%d",
1576 cmd->device_change_state.dev_no >> 3);
1577 sprintf(env_func, "SPAR_PARAHOTPLUG_FUNCTION=%d",
1578 cmd->device_change_state.dev_no & 0x7);
1580 kobject_uevent_env(&visorchipset_platform_device.dev.kobj, KOBJ_CHANGE,
1585 * Remove any request from the list that's been on there too long and
1586 * respond with an error.
1589 parahotplug_process_list(void)
1591 struct list_head *pos;
1592 struct list_head *tmp;
1594 spin_lock(¶hotplug_request_list_lock);
1596 list_for_each_safe(pos, tmp, ¶hotplug_request_list) {
1597 struct parahotplug_request *req =
1598 list_entry(pos, struct parahotplug_request, list);
1600 if (!time_after_eq(jiffies, req->expiration))
1604 if (req->msg.hdr.flags.response_expected)
1605 controlvm_respond_physdev_changestate(
1607 CONTROLVM_RESP_ERROR_DEVICE_UDEV_TIMEOUT,
1608 req->msg.cmd.device_change_state.state);
1609 parahotplug_request_destroy(req);
1612 spin_unlock(¶hotplug_request_list_lock);
1616 * Called from the /proc handler, which means the user script has
1617 * finished the enable/disable. Find the matching identifier, and
1618 * respond to the CONTROLVM message with success.
1621 parahotplug_request_complete(int id, u16 active)
1623 struct list_head *pos;
1624 struct list_head *tmp;
1626 spin_lock(¶hotplug_request_list_lock);
1628 /* Look for a request matching "id". */
1629 list_for_each_safe(pos, tmp, ¶hotplug_request_list) {
1630 struct parahotplug_request *req =
1631 list_entry(pos, struct parahotplug_request, list);
1632 if (req->id == id) {
1633 /* Found a match. Remove it from the list and
1637 spin_unlock(¶hotplug_request_list_lock);
1638 req->msg.cmd.device_change_state.state.active = active;
1639 if (req->msg.hdr.flags.response_expected)
1640 controlvm_respond_physdev_changestate(
1641 &req->msg.hdr, CONTROLVM_RESP_SUCCESS,
1642 req->msg.cmd.device_change_state.state);
1643 parahotplug_request_destroy(req);
1648 spin_unlock(¶hotplug_request_list_lock);
1653 * Enables or disables a PCI device by kicking off a udev script
1656 parahotplug_process_message(struct controlvm_message *inmsg)
1658 struct parahotplug_request *req;
1660 req = parahotplug_request_create(inmsg);
1665 if (inmsg->cmd.device_change_state.state.active) {
1666 /* For enable messages, just respond with success
1667 * right away. This is a bit of a hack, but there are
1668 * issues with the early enable messages we get (with
1669 * either the udev script not detecting that the device
1670 * is up, or not getting called at all). Fortunately
1671 * the messages that get lost don't matter anyway, as
1672 * devices are automatically enabled at
1675 parahotplug_request_kickoff(req);
1676 controlvm_respond_physdev_changestate(&inmsg->hdr,
1677 CONTROLVM_RESP_SUCCESS,
1678 inmsg->cmd.device_change_state.state);
1679 parahotplug_request_destroy(req);
1681 /* For disable messages, add the request to the
1682 * request list before kicking off the udev script. It
1683 * won't get responded to until the script has
1684 * indicated it's done.
1686 spin_lock(¶hotplug_request_list_lock);
1687 list_add_tail(&req->list, ¶hotplug_request_list);
1688 spin_unlock(¶hotplug_request_list_lock);
1690 parahotplug_request_kickoff(req);
1694 /* Process a controlvm message.
1696 * false - this function will return false only in the case where the
1697 * controlvm message was NOT processed, but processing must be
1698 * retried before reading the next controlvm message; a
1699 * scenario where this can occur is when we need to throttle
1700 * the allocation of memory in which to copy out controlvm
1702 * true - processing of the controlvm message completed,
1703 * either successfully or with an error.
1706 handle_command(struct controlvm_message inmsg, u64 channel_addr)
1708 struct controlvm_message_packet *cmd = &inmsg.cmd;
1711 struct parser_context *parser_ctx = NULL;
1713 struct controlvm_message ackmsg;
1715 /* create parsing context if necessary */
1716 local_addr = (inmsg.hdr.flags.test_message == 1);
1717 if (channel_addr == 0)
1719 parm_addr = channel_addr + inmsg.hdr.payload_vm_offset;
1720 parm_bytes = inmsg.hdr.payload_bytes;
1722 /* Parameter and channel addresses within test messages actually lie
1723 * within our OS-controlled memory. We need to know that, because it
1724 * makes a difference in how we compute the virtual address.
1726 if (parm_addr && parm_bytes) {
1730 parser_init_byte_stream(parm_addr, parm_bytes,
1731 local_addr, &retry);
1732 if (!parser_ctx && retry)
1737 controlvm_init_response(&ackmsg, &inmsg.hdr,
1738 CONTROLVM_RESP_SUCCESS);
1739 if (controlvm_channel)
1740 visorchannel_signalinsert(controlvm_channel,
1741 CONTROLVM_QUEUE_ACK,
1744 switch (inmsg.hdr.id) {
1745 case CONTROLVM_CHIPSET_INIT:
1746 chipset_init(&inmsg);
1748 case CONTROLVM_BUS_CREATE:
1751 case CONTROLVM_BUS_DESTROY:
1752 bus_destroy(&inmsg);
1754 case CONTROLVM_BUS_CONFIGURE:
1755 bus_configure(&inmsg, parser_ctx);
1757 case CONTROLVM_DEVICE_CREATE:
1758 my_device_create(&inmsg);
1760 case CONTROLVM_DEVICE_CHANGESTATE:
1761 if (cmd->device_change_state.flags.phys_device) {
1762 parahotplug_process_message(&inmsg);
1764 /* save the hdr and cmd structures for later use */
1765 /* when sending back the response to Command */
1766 my_device_changestate(&inmsg);
1767 g_devicechangestate_packet = inmsg.cmd;
1771 case CONTROLVM_DEVICE_DESTROY:
1772 my_device_destroy(&inmsg);
1774 case CONTROLVM_DEVICE_CONFIGURE:
1775 /* no op for now, just send a respond that we passed */
1776 if (inmsg.hdr.flags.response_expected)
1777 controlvm_respond(&inmsg.hdr, CONTROLVM_RESP_SUCCESS);
1779 case CONTROLVM_CHIPSET_READY:
1780 chipset_ready(&inmsg.hdr);
1782 case CONTROLVM_CHIPSET_SELFTEST:
1783 chipset_selftest(&inmsg.hdr);
1785 case CONTROLVM_CHIPSET_STOP:
1786 chipset_notready(&inmsg.hdr);
1789 if (inmsg.hdr.flags.response_expected)
1790 controlvm_respond(&inmsg.hdr,
1791 -CONTROLVM_RESP_ERROR_MESSAGE_ID_UNKNOWN);
1796 parser_done(parser_ctx);
1802 static inline unsigned int
1803 issue_vmcall_io_controlvm_addr(u64 *control_addr, u32 *control_bytes)
1805 struct vmcall_io_controlvm_addr_params params;
1806 int result = VMCALL_SUCCESS;
1809 physaddr = virt_to_phys(¶ms);
1810 ISSUE_IO_VMCALL(VMCALL_IO_CONTROLVM_ADDR, physaddr, result);
1811 if (VMCALL_SUCCESSFUL(result)) {
1812 *control_addr = params.address;
1813 *control_bytes = params.channel_bytes;
1818 static u64 controlvm_get_channel_address(void)
1823 if (!VMCALL_SUCCESSFUL(issue_vmcall_io_controlvm_addr(&addr, &size)))
1830 controlvm_periodic_work(struct work_struct *work)
1832 struct controlvm_message inmsg;
1833 bool got_command = false;
1834 bool handle_command_failed = false;
1835 static u64 poll_count;
1837 /* make sure visorbus server is registered for controlvm callbacks */
1838 if (visorchipset_visorbusregwait && !visorbusregistered)
1842 if (poll_count >= 250)
1847 /* Check events to determine if response to CHIPSET_READY
1850 if (visorchipset_holdchipsetready &&
1851 (g_chipset_msg_hdr.id != CONTROLVM_INVALID)) {
1852 if (check_chipset_events() == 1) {
1853 controlvm_respond(&g_chipset_msg_hdr, 0);
1854 clear_chipset_events();
1855 memset(&g_chipset_msg_hdr, 0,
1856 sizeof(struct controlvm_message_header));
1860 while (visorchannel_signalremove(controlvm_channel,
1861 CONTROLVM_QUEUE_RESPONSE,
1865 if (controlvm_pending_msg_valid) {
1866 /* we throttled processing of a prior
1867 * msg, so try to process it again
1868 * rather than reading a new one
1870 inmsg = controlvm_pending_msg;
1871 controlvm_pending_msg_valid = false;
1874 got_command = read_controlvm_event(&inmsg);
1878 handle_command_failed = false;
1879 while (got_command && (!handle_command_failed)) {
1880 most_recent_message_jiffies = jiffies;
1881 if (handle_command(inmsg,
1882 visorchannel_get_physaddr
1883 (controlvm_channel)))
1884 got_command = read_controlvm_event(&inmsg);
1886 /* this is a scenario where throttling
1887 * is required, but probably NOT an
1888 * error...; we stash the current
1889 * controlvm msg so we will attempt to
1890 * reprocess it on our next loop
1892 handle_command_failed = true;
1893 controlvm_pending_msg = inmsg;
1894 controlvm_pending_msg_valid = true;
1898 /* parahotplug_worker */
1899 parahotplug_process_list();
1903 if (time_after(jiffies,
1904 most_recent_message_jiffies + (HZ * MIN_IDLE_SECONDS))) {
1905 /* it's been longer than MIN_IDLE_SECONDS since we
1906 * processed our last controlvm message; slow down the
1909 if (poll_jiffies != POLLJIFFIES_CONTROLVMCHANNEL_SLOW)
1910 poll_jiffies = POLLJIFFIES_CONTROLVMCHANNEL_SLOW;
1912 if (poll_jiffies != POLLJIFFIES_CONTROLVMCHANNEL_FAST)
1913 poll_jiffies = POLLJIFFIES_CONTROLVMCHANNEL_FAST;
1916 queue_delayed_work(periodic_controlvm_workqueue,
1917 &periodic_controlvm_work, poll_jiffies);
1921 setup_crash_devices_work_queue(struct work_struct *work)
1923 struct controlvm_message local_crash_bus_msg;
1924 struct controlvm_message local_crash_dev_msg;
1925 struct controlvm_message msg;
1926 u32 local_crash_msg_offset;
1927 u16 local_crash_msg_count;
1929 /* make sure visorbus is registered for controlvm callbacks */
1930 if (visorchipset_visorbusregwait && !visorbusregistered)
1933 POSTCODE_LINUX_2(CRASH_DEV_ENTRY_PC, POSTCODE_SEVERITY_INFO);
1935 /* send init chipset msg */
1936 msg.hdr.id = CONTROLVM_CHIPSET_INIT;
1937 msg.cmd.init_chipset.bus_count = 23;
1938 msg.cmd.init_chipset.switch_count = 0;
1942 /* get saved message count */
1943 if (visorchannel_read(controlvm_channel,
1944 offsetof(struct spar_controlvm_channel_protocol,
1945 saved_crash_message_count),
1946 &local_crash_msg_count, sizeof(u16)) < 0) {
1947 POSTCODE_LINUX_2(CRASH_DEV_CTRL_RD_FAILURE_PC,
1948 POSTCODE_SEVERITY_ERR);
1952 if (local_crash_msg_count != CONTROLVM_CRASHMSG_MAX) {
1953 POSTCODE_LINUX_3(CRASH_DEV_COUNT_FAILURE_PC,
1954 local_crash_msg_count,
1955 POSTCODE_SEVERITY_ERR);
1959 /* get saved crash message offset */
1960 if (visorchannel_read(controlvm_channel,
1961 offsetof(struct spar_controlvm_channel_protocol,
1962 saved_crash_message_offset),
1963 &local_crash_msg_offset, sizeof(u32)) < 0) {
1964 POSTCODE_LINUX_2(CRASH_DEV_CTRL_RD_FAILURE_PC,
1965 POSTCODE_SEVERITY_ERR);
1969 /* read create device message for storage bus offset */
1970 if (visorchannel_read(controlvm_channel,
1971 local_crash_msg_offset,
1972 &local_crash_bus_msg,
1973 sizeof(struct controlvm_message)) < 0) {
1974 POSTCODE_LINUX_2(CRASH_DEV_RD_BUS_FAIULRE_PC,
1975 POSTCODE_SEVERITY_ERR);
1979 /* read create device message for storage device */
1980 if (visorchannel_read(controlvm_channel,
1981 local_crash_msg_offset +
1982 sizeof(struct controlvm_message),
1983 &local_crash_dev_msg,
1984 sizeof(struct controlvm_message)) < 0) {
1985 POSTCODE_LINUX_2(CRASH_DEV_RD_DEV_FAIULRE_PC,
1986 POSTCODE_SEVERITY_ERR);
1990 /* reuse IOVM create bus message */
1991 if (local_crash_bus_msg.cmd.create_bus.channel_addr) {
1992 bus_create(&local_crash_bus_msg);
1994 POSTCODE_LINUX_2(CRASH_DEV_BUS_NULL_FAILURE_PC,
1995 POSTCODE_SEVERITY_ERR);
1999 /* reuse create device message for storage device */
2000 if (local_crash_dev_msg.cmd.create_device.channel_addr) {
2001 my_device_create(&local_crash_dev_msg);
2003 POSTCODE_LINUX_2(CRASH_DEV_DEV_NULL_FAILURE_PC,
2004 POSTCODE_SEVERITY_ERR);
2007 POSTCODE_LINUX_2(CRASH_DEV_EXIT_PC, POSTCODE_SEVERITY_INFO);
2012 poll_jiffies = POLLJIFFIES_CONTROLVMCHANNEL_SLOW;
2014 queue_delayed_work(periodic_controlvm_workqueue,
2015 &periodic_controlvm_work, poll_jiffies);
2019 bus_create_response(struct visor_device *bus_info, int response)
2022 bus_info->state.created = 1;
2024 bus_responder(CONTROLVM_BUS_CREATE, bus_info->pending_msg_hdr,
2027 kfree(bus_info->pending_msg_hdr);
2028 bus_info->pending_msg_hdr = NULL;
2032 bus_destroy_response(struct visor_device *bus_info, int response)
2034 bus_responder(CONTROLVM_BUS_DESTROY, bus_info->pending_msg_hdr,
2037 kfree(bus_info->pending_msg_hdr);
2038 bus_info->pending_msg_hdr = NULL;
2042 device_create_response(struct visor_device *dev_info, int response)
2045 dev_info->state.created = 1;
2047 device_responder(CONTROLVM_DEVICE_CREATE, dev_info->pending_msg_hdr,
2050 kfree(dev_info->pending_msg_hdr);
2051 dev_info->pending_msg_hdr = NULL;
2055 device_destroy_response(struct visor_device *dev_info, int response)
2057 device_responder(CONTROLVM_DEVICE_DESTROY, dev_info->pending_msg_hdr,
2060 kfree(dev_info->pending_msg_hdr);
2061 dev_info->pending_msg_hdr = NULL;
2065 visorchipset_device_pause_response(struct visor_device *dev_info,
2068 device_changestate_responder(CONTROLVM_DEVICE_CHANGESTATE,
2070 segment_state_standby);
2072 kfree(dev_info->pending_msg_hdr);
2073 dev_info->pending_msg_hdr = NULL;
2077 device_resume_response(struct visor_device *dev_info, int response)
2079 device_changestate_responder(CONTROLVM_DEVICE_CHANGESTATE,
2081 segment_state_running);
2083 kfree(dev_info->pending_msg_hdr);
2084 dev_info->pending_msg_hdr = NULL;
2087 static ssize_t chipsetready_store(struct device *dev,
2088 struct device_attribute *attr,
2089 const char *buf, size_t count)
2093 if (sscanf(buf, "%63s", msgtype) != 1)
2096 if (!strcmp(msgtype, "CALLHOMEDISK_MOUNTED")) {
2097 chipset_events[0] = 1;
2099 } else if (!strcmp(msgtype, "MODULES_LOADED")) {
2100 chipset_events[1] = 1;
2106 /* The parahotplug/devicedisabled interface gets called by our support script
2107 * when an SR-IOV device has been shut down. The ID is passed to the script
2108 * and then passed back when the device has been removed.
2110 static ssize_t devicedisabled_store(struct device *dev,
2111 struct device_attribute *attr,
2112 const char *buf, size_t count)
2116 if (kstrtouint(buf, 10, &id))
2119 parahotplug_request_complete(id, 0);
2123 /* The parahotplug/deviceenabled interface gets called by our support script
2124 * when an SR-IOV device has been recovered. The ID is passed to the script
2125 * and then passed back when the device has been brought back up.
2127 static ssize_t deviceenabled_store(struct device *dev,
2128 struct device_attribute *attr,
2129 const char *buf, size_t count)
2133 if (kstrtouint(buf, 10, &id))
2136 parahotplug_request_complete(id, 1);
2141 visorchipset_mmap(struct file *file, struct vm_area_struct *vma)
2143 unsigned long physaddr = 0;
2144 unsigned long offset = vma->vm_pgoff << PAGE_SHIFT;
2147 /* sv_enable_dfp(); */
2148 if (offset & (PAGE_SIZE - 1))
2149 return -ENXIO; /* need aligned offsets */
2152 case VISORCHIPSET_MMAP_CONTROLCHANOFFSET:
2153 vma->vm_flags |= VM_IO;
2154 if (!*file_controlvm_channel)
2157 visorchannel_read(*file_controlvm_channel,
2158 offsetof(struct spar_controlvm_channel_protocol,
2159 gp_control_channel),
2160 &addr, sizeof(addr));
2164 physaddr = (unsigned long)addr;
2165 if (remap_pfn_range(vma, vma->vm_start,
2166 physaddr >> PAGE_SHIFT,
2167 vma->vm_end - vma->vm_start,
2168 /*pgprot_noncached */
2169 (vma->vm_page_prot))) {
2179 static inline s64 issue_vmcall_query_guest_virtual_time_offset(void)
2181 u64 result = VMCALL_SUCCESS;
2184 ISSUE_IO_VMCALL(VMCALL_QUERY_GUEST_VIRTUAL_TIME_OFFSET, physaddr,
2189 static inline int issue_vmcall_update_physical_time(u64 adjustment)
2191 int result = VMCALL_SUCCESS;
2193 ISSUE_IO_VMCALL(VMCALL_UPDATE_PHYSICAL_TIME, adjustment, result);
2197 static long visorchipset_ioctl(struct file *file, unsigned int cmd,
2204 case VMCALL_QUERY_GUEST_VIRTUAL_TIME_OFFSET:
2205 /* get the physical rtc offset */
2206 vrtc_offset = issue_vmcall_query_guest_virtual_time_offset();
2207 if (copy_to_user((void __user *)arg, &vrtc_offset,
2208 sizeof(vrtc_offset))) {
2212 case VMCALL_UPDATE_PHYSICAL_TIME:
2213 if (copy_from_user(&adjustment, (void __user *)arg,
2214 sizeof(adjustment))) {
2217 return issue_vmcall_update_physical_time(adjustment);
2223 static const struct file_operations visorchipset_fops = {
2224 .owner = THIS_MODULE,
2225 .open = visorchipset_open,
2228 .unlocked_ioctl = visorchipset_ioctl,
2229 .release = visorchipset_release,
2230 .mmap = visorchipset_mmap,
2234 visorchipset_file_init(dev_t major_dev, struct visorchannel **controlvm_channel)
2238 file_controlvm_channel = controlvm_channel;
2239 cdev_init(&file_cdev, &visorchipset_fops);
2240 file_cdev.owner = THIS_MODULE;
2241 if (MAJOR(major_dev) == 0) {
2242 rc = alloc_chrdev_region(&major_dev, 0, 1, "visorchipset");
2243 /* dynamic major device number registration required */
2247 /* static major device number registration required */
2248 rc = register_chrdev_region(major_dev, 1, "visorchipset");
2252 rc = cdev_add(&file_cdev, MKDEV(MAJOR(major_dev), 0), 1);
2254 unregister_chrdev_region(major_dev, 1);
2261 visorchipset_init(struct acpi_device *acpi_device)
2265 int tmp_sz = sizeof(struct spar_controlvm_channel_protocol);
2266 uuid_le uuid = SPAR_CONTROLVM_CHANNEL_PROTOCOL_UUID;
2268 addr = controlvm_get_channel_address();
2272 memset(&busdev_notifiers, 0, sizeof(busdev_notifiers));
2273 memset(&controlvm_payload_info, 0, sizeof(controlvm_payload_info));
2275 controlvm_channel = visorchannel_create_with_lock(addr, tmp_sz,
2277 if (SPAR_CONTROLVM_CHANNEL_OK_CLIENT(
2278 visorchannel_get_header(controlvm_channel))) {
2279 initialize_controlvm_payload();
2281 visorchannel_destroy(controlvm_channel);
2282 controlvm_channel = NULL;
2286 major_dev = MKDEV(visorchipset_major, 0);
2287 rc = visorchipset_file_init(major_dev, &controlvm_channel);
2289 POSTCODE_LINUX_2(CHIPSET_INIT_FAILURE_PC, DIAG_SEVERITY_ERR);
2293 memset(&g_chipset_msg_hdr, 0, sizeof(struct controlvm_message_header));
2295 /* if booting in a crash kernel */
2296 if (is_kdump_kernel())
2297 INIT_DELAYED_WORK(&periodic_controlvm_work,
2298 setup_crash_devices_work_queue);
2300 INIT_DELAYED_WORK(&periodic_controlvm_work,
2301 controlvm_periodic_work);
2302 periodic_controlvm_workqueue =
2303 create_singlethread_workqueue("visorchipset_controlvm");
2305 if (!periodic_controlvm_workqueue) {
2306 POSTCODE_LINUX_2(CREATE_WORKQUEUE_FAILED_PC,
2311 most_recent_message_jiffies = jiffies;
2312 poll_jiffies = POLLJIFFIES_CONTROLVMCHANNEL_FAST;
2313 rc = queue_delayed_work(periodic_controlvm_workqueue,
2314 &periodic_controlvm_work, poll_jiffies);
2316 POSTCODE_LINUX_2(QUEUE_DELAYED_WORK_PC,
2321 visorchipset_platform_device.dev.devt = major_dev;
2322 if (platform_device_register(&visorchipset_platform_device) < 0) {
2323 POSTCODE_LINUX_2(DEVICE_REGISTER_FAILURE_PC, DIAG_SEVERITY_ERR);
2327 POSTCODE_LINUX_2(CHIPSET_INIT_SUCCESS_PC, POSTCODE_SEVERITY_INFO);
2329 rc = visorbus_init();
2332 POSTCODE_LINUX_3(CHIPSET_INIT_FAILURE_PC, rc,
2333 POSTCODE_SEVERITY_ERR);
2339 visorchipset_file_cleanup(dev_t major_dev)
2342 cdev_del(&file_cdev);
2343 file_cdev.ops = NULL;
2344 unregister_chrdev_region(major_dev, 1);
2348 visorchipset_exit(struct acpi_device *acpi_device)
2350 POSTCODE_LINUX_2(DRIVER_EXIT_PC, POSTCODE_SEVERITY_INFO);
2354 cancel_delayed_work(&periodic_controlvm_work);
2355 flush_workqueue(periodic_controlvm_workqueue);
2356 destroy_workqueue(periodic_controlvm_workqueue);
2357 periodic_controlvm_workqueue = NULL;
2358 destroy_controlvm_payload_info(&controlvm_payload_info);
2360 memset(&g_chipset_msg_hdr, 0, sizeof(struct controlvm_message_header));
2362 visorchannel_destroy(controlvm_channel);
2364 visorchipset_file_cleanup(visorchipset_platform_device.dev.devt);
2365 platform_device_unregister(&visorchipset_platform_device);
2366 POSTCODE_LINUX_2(DRIVER_EXIT_PC, POSTCODE_SEVERITY_INFO);
2371 static const struct acpi_device_id unisys_device_ids[] = {
2376 static struct acpi_driver unisys_acpi_driver = {
2377 .name = "unisys_acpi",
2378 .class = "unisys_acpi_class",
2379 .owner = THIS_MODULE,
2380 .ids = unisys_device_ids,
2382 .add = visorchipset_init,
2383 .remove = visorchipset_exit,
2387 MODULE_DEVICE_TABLE(acpi, unisys_device_ids);
2389 static __init uint32_t visorutil_spar_detect(void)
2391 unsigned int eax, ebx, ecx, edx;
2393 if (cpu_has_hypervisor) {
2395 cpuid(UNISYS_SPAR_LEAF_ID, &eax, &ebx, &ecx, &edx);
2396 return (ebx == UNISYS_SPAR_ID_EBX) &&
2397 (ecx == UNISYS_SPAR_ID_ECX) &&
2398 (edx == UNISYS_SPAR_ID_EDX);
2404 static int init_unisys(void)
2408 if (!visorutil_spar_detect())
2411 result = acpi_bus_register_driver(&unisys_acpi_driver);
2415 pr_info("Unisys Visorchipset Driver Loaded.\n");
2419 static void exit_unisys(void)
2421 acpi_bus_unregister_driver(&unisys_acpi_driver);
2424 module_param_named(major, visorchipset_major, int, S_IRUGO);
2425 MODULE_PARM_DESC(visorchipset_major,
2426 "major device number to use for the device node");
2427 module_param_named(visorbusregwait, visorchipset_visorbusregwait, int, S_IRUGO);
2428 MODULE_PARM_DESC(visorchipset_visorbusreqwait,
2429 "1 to have the module wait for the visor bus to register");
2430 module_param_named(holdchipsetready, visorchipset_holdchipsetready,
2432 MODULE_PARM_DESC(visorchipset_holdchipsetready,
2433 "1 to hold response to CHIPSET_READY");
2435 module_init(init_unisys);
2436 module_exit(exit_unisys);
2438 MODULE_AUTHOR("Unisys");
2439 MODULE_LICENSE("GPL");
2440 MODULE_DESCRIPTION("Supervisor chipset driver for service partition: ver "
2442 MODULE_VERSION(VERSION);