core/ipmi.c - skiboot - Git at Google

 // SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
 /*
  * in-band IPMI, probably over bt (or via FSP mbox on FSP)
  *
  * Copyright 2013-2019 IBM Corp.
  */

 #include <stdio.h>
 #include <string.h>
 #include <bt.h>
 #include <ipmi.h>
 #include <opal.h>
 #include <device.h>
 #include <skiboot.h>
 #include <lock.h>
 #include <cpu.h>
 #include <timebase.h>
 #include <debug_descriptor.h>

 struct ipmi_backend *ipmi_backend = NULL;
 static struct lock sync_lock = LOCK_UNLOCKED;
 static struct ipmi_msg *sync_msg = NULL;

 void ipmi_free_msg(struct ipmi_msg *msg)
 {
 	/* ipmi_free_msg frees messages allocated by the
 	 * backend. Without a backend we couldn't have allocated
 	 * messages to free (we don't support removing backends
 	 * yet). */
 	if (!ipmi_present()) {
 		prerror("IPMI: Trying to free message without backend\n");
 		return;
 	}

 	msg->backend->free_msg(msg);
 }

 void ipmi_init_msg(struct ipmi_msg *msg, int interface,
 		   uint32_t code, void (*complete)(struct ipmi_msg *),
 		   void *user_data, size_t req_size, size_t resp_size)
 {
 	/* We don't actually support multiple interfaces at the moment. */
 	assert(interface == IPMI_DEFAULT_INTERFACE);

 	msg->backend = ipmi_backend;
 	msg->cmd = IPMI_CMD(code);
 	msg->netfn = IPMI_NETFN(code) << 2;
 	msg->req_size = req_size;
 	msg->resp_size = resp_size;
 	msg->complete = complete;
 	msg->user_data = user_data;
 }

 struct ipmi_msg *ipmi_mkmsg_simple(uint32_t code, void *req_data, size_t req_size)
 {
 	return ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, code, ipmi_free_msg, NULL,
 			  req_data, req_size, 0);
 }

 struct ipmi_msg *ipmi_mkmsg(int interface, uint32_t code,
 			    void (*complete)(struct ipmi_msg *),
 			    void *user_data, void *req_data, size_t req_size,
 			    size_t resp_size)
 {
 	struct ipmi_msg *msg;

 	if (!ipmi_present())
 		return NULL;

 	msg = ipmi_backend->alloc_msg(req_size, resp_size);
 	if (!msg)
 		return NULL;

 	ipmi_init_msg(msg, interface, code, complete, user_data, req_size,
 		      resp_size);

 	/* Commands are free to over ride this if they want to handle errors */
 	msg->error = ipmi_free_msg;

 	if (req_data)
 		memcpy(msg->data, req_data, req_size);

 	return msg;
 }

 int ipmi_queue_msg_head(struct ipmi_msg *msg)
 {
 	if (!ipmi_present())
 		return OPAL_HARDWARE;

 	if (!msg) {
 		prerror("%s: Attempting to queue NULL message\n", __func__);
 		return OPAL_PARAMETER;
 	}

 	return msg->backend->queue_msg_head(msg);
 }

 int ipmi_queue_msg(struct ipmi_msg *msg)
 {
 	/* Here we could choose which interface to use if we want to support
 	   multiple interfaces. */
 	if (!ipmi_present())
 		return OPAL_HARDWARE;

 	if (!msg) {
 		prerror("%s: Attempting to queue NULL message\n", __func__);
 		return OPAL_PARAMETER;
 	}

 	return msg->backend->queue_msg(msg);
 }

 int ipmi_dequeue_msg(struct ipmi_msg *msg)
 {
 	if (!ipmi_present())
 		return OPAL_HARDWARE;

 	if (!msg) {
 		prerror("%s: Attempting to dequeue NULL message\n", __func__);
 		return OPAL_PARAMETER;
 	}

 	return msg->backend->dequeue_msg(msg);
 }

 void ipmi_cmd_done(uint8_t cmd, uint8_t netfn, uint8_t cc, struct ipmi_msg *msg)
 {
 	msg->cc = cc;
 	if (msg->cmd != cmd) {
 		prerror("IPMI: Incorrect cmd 0x%02x in response\n", cmd);
 		cc = IPMI_ERR_UNSPECIFIED;
 	}

 	if ((msg->netfn >> 2) + 1 != (netfn >> 2)) {
 		prerror("IPMI: Incorrect netfn 0x%02x in response\n", netfn >> 2);
 		cc = IPMI_ERR_UNSPECIFIED;
 	}
 	msg->netfn = netfn;

 	if (cc != IPMI_CC_NO_ERROR) {
 		prlog(PR_DEBUG, "IPMI: Got error response. cmd=0x%x, netfn=0x%x,"
 		      " rc=0x%02x\n", msg->cmd, msg->netfn >> 2, msg->cc);

 		assert(msg->error);
 		msg->error(msg);
 	} else if (msg->complete)
 		msg->complete(msg);

 	/* At this point the message has should have been freed by the
 	   completion functions. */

 	/* If this is a synchronous message flag that we are done */
 	if (msg == sync_msg) {
 		sync_msg = NULL;
 		barrier();
 	}
 }

 void ipmi_queue_msg_sync(struct ipmi_msg *msg)
 {
 	bool (*poll)(void) = msg->backend->poll;

 	if (!ipmi_present())
 		return;

 	if (!msg) {
 		prerror("%s: Attempting to queue NULL message\n", __func__);
 		return;
 	}

 	lock(&sync_lock);
 	while (sync_msg)
 		cpu_relax();
 	sync_msg = msg;
 	if (msg->backend->disable_retry && !opal_booting())
 		msg->backend->disable_retry(msg);
 	ipmi_queue_msg_head(msg);
 	unlock(&sync_lock);

 	/*
 	 * BT response handling relies on a timer. We can't just run all
 	 * timers because we may have been called with a lock that a timer
 	 * wants, and they're generally not written to cope with that.
 	 * So, just run whatever the IPMI backend needs to make forward
 	 * progress.
 	 */
 	while (sync_msg == msg) {
 		if (poll)
 			poll();
 		time_wait_ms(10);
 	}
 }

 void ipmi_flush(void)
 {
 	if (!ipmi_present())
 		return;

 	while (ipmi_backend->poll())
 		time_wait_ms(10);
 }

 static void ipmi_read_event_complete(struct ipmi_msg *msg)
 {
 	prlog(PR_DEBUG, "IPMI read event %02x complete: %d bytes. cc: %02x\n",
 	      msg->cmd, msg->resp_size, msg->cc);

 	/* Handle power control & PNOR handshake events */
 	ipmi_parse_sel(msg);

 	ipmi_free_msg(msg);
 }

 static void ipmi_get_message_flags_complete(struct ipmi_msg *msg)
 {
 	uint8_t flags = msg->data[0];

 	ipmi_free_msg(msg);

 	prlog(PR_DEBUG, "IPMI Get Message Flags: %02x\n", flags);

 	/* Once we see an interrupt we assume the payload has
 	 * booted. We disable the wdt and let the OS setup its own
 	 * wdt.
 	 *
 	 * This is also where we consider the OS to be booted, so we set
 	 * the boot count sensor */
 	if (flags & IPMI_MESSAGE_FLAGS_WATCHDOG_PRE_TIMEOUT) {
 		ipmi_wdt_stop();
 		ipmi_set_boot_count();
 	}

 	/* Message available in the event buffer? Queue a Read Event command
 	 * to retrieve it. The flag is cleared by performing a read */
 	if (flags & IPMI_MESSAGE_FLAGS_EVENT_BUFFER) {
 		msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_READ_EVENT,
 				ipmi_read_event_complete, NULL, NULL, 0, 16);
 		ipmi_queue_msg(msg);
 	}
 }

 void ipmi_sms_attention(void)
 {
 	struct ipmi_msg *msg;

 	if (!ipmi_present())
 		return;

 	/* todo: when we handle multiple IPMI interfaces, we'll need to
 	 * ensure that this message is associated with the appropriate
 	 * backend. */
 	msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_GET_MESSAGE_FLAGS,
 			ipmi_get_message_flags_complete, NULL, NULL, 0, 1);

 	ipmi_queue_msg(msg);
 }

 void ipmi_register_backend(struct ipmi_backend *backend)
 {
 	/* We only support one backend at the moment */
 	assert(backend->alloc_msg);
 	assert(backend->free_msg);
 	assert(backend->queue_msg);
 	assert(backend->dequeue_msg);
 	ipmi_backend = backend;
 	ipmi_backend->opal_event_ipmi_recv = opal_dynamic_event_alloc();
 }

 bool ipmi_present(void)
 {
 	return ipmi_backend != NULL;
 }
	// SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
	/*
	* in-band IPMI, probably over bt (or via FSP mbox on FSP)
	*
	* Copyright 2013-2019 IBM Corp.
	*/

	#include <stdio.h>
	#include <string.h>
	#include <bt.h>
	#include <ipmi.h>
	#include <opal.h>
	#include <device.h>
	#include <skiboot.h>
	#include <lock.h>
	#include <cpu.h>
	#include <timebase.h>
	#include <debug_descriptor.h>

	struct ipmi_backend *ipmi_backend = NULL;
	static struct lock sync_lock = LOCK_UNLOCKED;
	static struct ipmi_msg *sync_msg = NULL;

	void ipmi_free_msg(struct ipmi_msg *msg)
	{
	/* ipmi_free_msg frees messages allocated by the
	* backend. Without a backend we couldn't have allocated
	* messages to free (we don't support removing backends
	* yet). */
	if (!ipmi_present()) {
	prerror("IPMI: Trying to free message without backend\n");
	return;
	}

	msg->backend->free_msg(msg);
	}

	void ipmi_init_msg(struct ipmi_msg *msg, int interface,
	uint32_t code, void (complete)(struct ipmi_msg ),
	void *user_data, size_t req_size, size_t resp_size)
	{
	/* We don't actually support multiple interfaces at the moment. */
	assert(interface == IPMI_DEFAULT_INTERFACE);

	msg->backend = ipmi_backend;
	msg->cmd = IPMI_CMD(code);
	msg->netfn = IPMI_NETFN(code) << 2;
	msg->req_size = req_size;
	msg->resp_size = resp_size;
	msg->complete = complete;
	msg->user_data = user_data;
	}

	struct ipmi_msg ipmi_mkmsg_simple(uint32_t code, void req_data, size_t req_size)
	{
	return ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, code, ipmi_free_msg, NULL,
	req_data, req_size, 0);
	}

	struct ipmi_msg *ipmi_mkmsg(int interface, uint32_t code,
	void (complete)(struct ipmi_msg ),
	void user_data, void req_data, size_t req_size,
	size_t resp_size)
	{
	struct ipmi_msg *msg;

	if (!ipmi_present())
	return NULL;

	msg = ipmi_backend->alloc_msg(req_size, resp_size);
	if (!msg)
	return NULL;

	ipmi_init_msg(msg, interface, code, complete, user_data, req_size,
	resp_size);

	/* Commands are free to over ride this if they want to handle errors */
	msg->error = ipmi_free_msg;

	if (req_data)
	memcpy(msg->data, req_data, req_size);

	return msg;
	}

	int ipmi_queue_msg_head(struct ipmi_msg *msg)
	{
	if (!ipmi_present())
	return OPAL_HARDWARE;

	if (!msg) {
	prerror("%s: Attempting to queue NULL message\n", __func__);
	return OPAL_PARAMETER;
	}

	return msg->backend->queue_msg_head(msg);
	}

	int ipmi_queue_msg(struct ipmi_msg *msg)
	{
	/* Here we could choose which interface to use if we want to support
	multiple interfaces. */
	if (!ipmi_present())
	return OPAL_HARDWARE;

	if (!msg) {
	prerror("%s: Attempting to queue NULL message\n", __func__);
	return OPAL_PARAMETER;
	}

	return msg->backend->queue_msg(msg);
	}

	int ipmi_dequeue_msg(struct ipmi_msg *msg)
	{
	if (!ipmi_present())
	return OPAL_HARDWARE;

	if (!msg) {
	prerror("%s: Attempting to dequeue NULL message\n", __func__);
	return OPAL_PARAMETER;
	}

	return msg->backend->dequeue_msg(msg);
	}

	void ipmi_cmd_done(uint8_t cmd, uint8_t netfn, uint8_t cc, struct ipmi_msg *msg)
	{
	msg->cc = cc;
	if (msg->cmd != cmd) {
	prerror("IPMI: Incorrect cmd 0x%02x in response\n", cmd);
	cc = IPMI_ERR_UNSPECIFIED;
	}

	if ((msg->netfn >> 2) + 1 != (netfn >> 2)) {
	prerror("IPMI: Incorrect netfn 0x%02x in response\n", netfn >> 2);
	cc = IPMI_ERR_UNSPECIFIED;
	}
	msg->netfn = netfn;

	if (cc != IPMI_CC_NO_ERROR) {
	prlog(PR_DEBUG, "IPMI: Got error response. cmd=0x%x, netfn=0x%x,"
	" rc=0x%02x\n", msg->cmd, msg->netfn >> 2, msg->cc);

	assert(msg->error);
	msg->error(msg);
	} else if (msg->complete)
	msg->complete(msg);

	/* At this point the message has should have been freed by the
	completion functions. */

	/* If this is a synchronous message flag that we are done */
	if (msg == sync_msg) {
	sync_msg = NULL;
	barrier();
	}
	}

	void ipmi_queue_msg_sync(struct ipmi_msg *msg)
	{
	bool (*poll)(void) = msg->backend->poll;

	if (!ipmi_present())
	return;

	if (!msg) {
	prerror("%s: Attempting to queue NULL message\n", __func__);
	return;
	}

	lock(&sync_lock);
	while (sync_msg)
	cpu_relax();
	sync_msg = msg;
	if (msg->backend->disable_retry && !opal_booting())
	msg->backend->disable_retry(msg);
	ipmi_queue_msg_head(msg);
	unlock(&sync_lock);

	/*
	* BT response handling relies on a timer. We can't just run all
	* timers because we may have been called with a lock that a timer
	* wants, and they're generally not written to cope with that.
	* So, just run whatever the IPMI backend needs to make forward
	* progress.
	*/
	while (sync_msg == msg) {
	if (poll)
	poll();
	time_wait_ms(10);
	}
	}

	void ipmi_flush(void)
	{
	if (!ipmi_present())
	return;

	while (ipmi_backend->poll())
	time_wait_ms(10);
	}

	static void ipmi_read_event_complete(struct ipmi_msg *msg)
	{
	prlog(PR_DEBUG, "IPMI read event %02x complete: %d bytes. cc: %02x\n",
	msg->cmd, msg->resp_size, msg->cc);

	/* Handle power control & PNOR handshake events */
	ipmi_parse_sel(msg);

	ipmi_free_msg(msg);
	}

	static void ipmi_get_message_flags_complete(struct ipmi_msg *msg)
	{
	uint8_t flags = msg->data[0];

	ipmi_free_msg(msg);

	prlog(PR_DEBUG, "IPMI Get Message Flags: %02x\n", flags);

	/* Once we see an interrupt we assume the payload has
	* booted. We disable the wdt and let the OS setup its own
	* wdt.
	*
	* This is also where we consider the OS to be booted, so we set
	* the boot count sensor */
	if (flags & IPMI_MESSAGE_FLAGS_WATCHDOG_PRE_TIMEOUT) {
	ipmi_wdt_stop();
	ipmi_set_boot_count();
	}

	/* Message available in the event buffer? Queue a Read Event command
	* to retrieve it. The flag is cleared by performing a read */
	if (flags & IPMI_MESSAGE_FLAGS_EVENT_BUFFER) {
	msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_READ_EVENT,
	ipmi_read_event_complete, NULL, NULL, 0, 16);
	ipmi_queue_msg(msg);
	}
	}

	void ipmi_sms_attention(void)
	{
	struct ipmi_msg *msg;

	if (!ipmi_present())
	return;

	/* todo: when we handle multiple IPMI interfaces, we'll need to
	* ensure that this message is associated with the appropriate
	* backend. */
	msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_GET_MESSAGE_FLAGS,
	ipmi_get_message_flags_complete, NULL, NULL, 0, 1);

	ipmi_queue_msg(msg);
	}

	void ipmi_register_backend(struct ipmi_backend *backend)
	{
	/* We only support one backend at the moment */
	assert(backend->alloc_msg);
	assert(backend->free_msg);
	assert(backend->queue_msg);
	assert(backend->dequeue_msg);
	ipmi_backend = backend;
	ipmi_backend->opal_event_ipmi_recv = opal_dynamic_event_alloc();
	}

	bool ipmi_present(void)
	{
	return ipmi_backend != NULL;
	}