iBoot/drivers/apple/csi/csi.c

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2023-07-08 13:03:17 -07:00
/*
* Copyright (C) 2011-2012 Apple Computer, Inc. All rights reserved.
*
* This document is the property of Apple Computer, Inc.
* It is considered confidential and proprietary.
*
* This document may not be reproduced or transmitted in any form,
* in whole or in part, without the express written permission of
* Apple Computer, Inc.
*/
#include <platform.h>
#include <platform/memmap.h>
#include <arch.h>
#include <debug.h>
#include <sys/task.h>
#include <sys/boot.h>
#include <lib/env.h>
#include <platform/timer.h>
#include <drivers/a7iop/a7iop.h>
#include <drivers/csi.h>
#include "csi_private.h"
// protocol files
#include <csi_system.h>
#include "endpoints/management_ep.h"
#include "endpoints/syslog_ep.h"
#include "endpoints/console_ep.h"
#include "endpoints/crashlog_ep.h"
#include <platform/soc/hwclocks.h>
#include <platform/clocks.h>
#include <platform/soc/pmgr.h>
// XXX <rdar://problem/10422340> addresses the need for a common copy of this file
#include "queue.h"
static const MailboxEndpointConfig endpoint_config[] = MAILBOX_ENDPOINT_INITIALIZERS;
#define MAILBOX_ENDPOINT_INITIALIZER_COUNT (int)(sizeof(endpoint_config)/sizeof(*endpoint_config))
#define EP_QUEUE_ADVANCE(_index, _size) ((_index) = ((((_index) + 1) >= _size) ? 0 : ((_index) + 1)))
// A simple mechanism to put a governor on potentially high volume log scenarios
#define LOG_GOV_PERIOD_USEC 5000000
typedef struct {
int occ_count;
u_int64_t last_log;
} log_governor_t;
typedef struct {
bool registered;
csi_coproc_t coproc;
uint32_t index;
const char *name;
uint32_t rcv_queue_size;
msg_payload_t *rcv_queue;
uint32_t next_in;
uint32_t next_out;
uint32_t sm_alignment;
struct task_event *rcv_not_empty_event;
} endpoint_desc_t;
typedef enum {
COPROC_STATE_RESET = 0,
COPROC_STATE_ERROR_FW,
COPROC_STATE_ERROR_STARTING,
COPROC_STATE_RUNNING,
COPROC_STATE_STOPPED,
} coproc_state_t;
typedef struct {
csi_coproc_t coproc;
coproc_state_t state;
coproc_feature_t feature;
uint32_t send_timeout;
uint32_t endpoint_count;
endpoint_desc_t endpoints[CSI_MAX_ENDPOINTS];
fw_desc_t fw_desc;
struct task_event power_state_event;
log_governor_t gov_ep_queue_ovflw;
log_governor_t gov_ep_not_reg;
} csi_desc_t;
static csi_desc_t *csi_descs[CSI_COPROC_MAX] = {NULL};
//
// Private functions
//
static endpoint_desc_t *find_endpoint(csi_coproc_t which_coproc, ipc_endpoint_t which_ep);
static int inbox_not_empty_task(void *arg);
static void message_dispatcher(endpoint_desc_t *ep, msg_payload_t msg_payload);
static void *allocate_shared_memory(uint32_t capacity, uint32_t alignment);
static bool check_log_gov(log_governor_t *gov, csi_coproc_t which_coproc);
//
// csi_init
//
csi_status_t
csi_init (csi_coproc_t which_coproc)
{
int j;
csi_desc_t *csi;
csi_status_t status;
endpoint_desc_t *next_ep;
if (which_coproc >= CSI_COPROC_MAX) {
return CSI_STATUS_UNSUPPORTED;
}
// enforce single instance
REQUIRE(csi_descs[which_coproc]==NULL);
csi_descs[which_coproc] = malloc(sizeof(csi_desc_t));
REQUIRE(csi_descs[which_coproc]!=NULL);
csi = csi_descs[which_coproc];
csi->coproc = which_coproc;
csi->state = COPROC_STATE_RESET;
csi->send_timeout = CSI_SEND_MESSAGE_TIMEOUT;
csi->gov_ep_queue_ovflw.occ_count = 0;
csi->gov_ep_not_reg.occ_count = 0;
csi->feature = COPROC_FEATURE_NONE;
// Create all endpoint structures - all are inactive until registered.
csi->endpoint_count = 0;
next_ep = csi->endpoints;
for (j=CSI_MAX_ENDPOINTS; --j>=0;) {
next_ep->registered = false;
next_ep->coproc = csi->coproc;
next_ep->index = 0;
next_ep->name = "none";
next_ep->rcv_queue_size = 0;
next_ep->rcv_queue = NULL;
next_ep->next_in = 0;
next_ep->next_out = 0;
next_ep->rcv_not_empty_event = NULL;
next_ep++;
}
next_ep = csi->endpoints;
for (j=0; (j<MAILBOX_ENDPOINT_INITIALIZER_COUNT) && (csi->endpoint_count<CSI_MAX_ENDPOINTS); j++) {
if (endpoint_config[j].rcv_queue_size != 0) {
next_ep->index = endpoint_config[j].index;
next_ep->name = endpoint_config[j].name;
next_ep->rcv_queue_size = endpoint_config[j].rcv_queue_size;
next_ep->rcv_queue = malloc(sizeof(*next_ep->rcv_queue) * endpoint_config[j].rcv_queue_size);
REQUIRE(next_ep->rcv_queue!=NULL);
next_ep->next_in = 0;
next_ep->next_out = ~(0);
next_ep++;
csi->endpoint_count++;
}
}
// create built-in endpoints
bi_ep_mgmt_create(csi->coproc, &(csi->power_state_event));
bi_ep_crashlog_create(csi->coproc);
bi_ep_console_create(csi->coproc);
bi_ep_syslog_create(csi->coproc);
// Find the firmware, prep it, start the coprocessor.
if (CSI_COPROC_ANS == which_coproc) {
// region is provided by iBoot
csi->fw_desc.region_base = ASP_BASE;
csi->fw_desc.region_size = (uint32_t)(ASP_SIZE);
} else {
// Allocate region for all other corpoc
// XXX: what size is needed - to be added later when/if other coproc are supported.
csi->fw_desc.region_base = 0x00;
csi->fw_desc.region_size = 0x00;
return CSI_STATUS_UNSUPPORTED;
}
status = fw_fixup_and_relocate(csi->coproc, &csi->fw_desc);
if (status != CSI_STATUS_OK) {
CSI_LOG(CRITICAL, which_coproc, "fw_fixup_and_relocate() error (%s)\n", CSI_STATUS_STR(status));
csi->state = COPROC_STATE_ERROR_FW;
return status;
}
status = csi_start (which_coproc);
if (status != CSI_STATUS_OK) {
return status;
}
// create the power state event
event_init(&(csi->power_state_event), EVENT_FLAG_AUTO_UNSIGNAL, false);
return CSI_STATUS_OK;
}
csi_status_t
csi_start (csi_coproc_t which_coproc)
{
csi_desc_t *csi;
addr_t remap_base;
uint64_t remap_size;
int status;
csi = csi_descs[which_coproc];
remap_base = (const addr_t)csi->fw_desc.region_base;
remap_size = (const uint64_t)csi->fw_desc.region_size;
status = akf_start(KFW(csi->coproc), remap_base, remap_size);
if (status != 0) {
CSI_LOG(CRITICAL, which_coproc, "akf_start() error: %d\n", status);
csi->state = COPROC_STATE_ERROR_STARTING;
return CSI_STATUS_ERROR;
}
csi_clr_feature (which_coproc, COPROC_FEATURE_SHUTDOWN_IN_PROGRESS);
CSI_LOG(DEBUG_SPEW, which_coproc, "coproc started: remap base = %p, size = 0x%llx (feature=%x)\n", (void *)remap_base, remap_size, csi_get_feature(which_coproc));
csi->state = COPROC_STATE_RUNNING;
// start the message reading task
task_start(task_create("csi inbox_not_empty_task", inbox_not_empty_task, (void*)csi, kTaskStackSize_inbox_not_empty));
task_yield(); // give them a chance to run
return CSI_STATUS_OK;
}
csi_status_t
csi_panic_recover (csi_coproc_t which_coproc)
{
csi_desc_t *csi;
csi_status_t status;
csi = csi_descs[which_coproc];
// stop the AKF to reset it.
csi_stop (which_coproc);
// destroy all the allocated shared memory
// force a power state change to off.
handle_power_state_ack (mgmt_descs[which_coproc], CSI_PS_OFF);
clock_reset_device(CLK_ANS);
// give a chance to all other task to terminate
task_yield();
// reset the memory
status = fw_fixup_and_relocate (csi->coproc, &csi->fw_desc);
if (status != CSI_STATUS_OK) {
CSI_LOG(CRITICAL, which_coproc, "panic recovery failed: fw_fixup_and_relocate() error (%s)\n", CSI_STATUS_STR(status));
csi->state = COPROC_STATE_ERROR_FW;
return status;
}
// restart the AKF
return csi_start (which_coproc);
}
csi_status_t
csi_late_init (void) {
#if APPLICATION_IBOOT
const char *boot_args;
char *arg_str;
uint32_t verbosity;
verbosity = 9999;
boot_args = env_get("boot-args");
if (boot_args != NULL) {
arg_str = strstr(boot_args, "csi_syslog_verbosity=");
if (arg_str != NULL) {
verbosity = arg_str[strlen("csi_syslog_verbosity=")] - '0';
}
}
for (int j = 0; j < CSI_COPROC_MAX; j++) {
bi_ep_syslog_verbosity(j, verbosity);
}
#endif
return CSI_STATUS_OK;
}
csi_status_t
csi_stop (csi_coproc_t which_coproc)
{
csi_desc_t *csi;
csi = csi_descs[which_coproc];
akf_stop (KFW(csi->coproc));
csi->state = COPROC_STATE_STOPPED;
return CSI_STATUS_OK;
}
csi_status_t
csi_quiesce (enum boot_target target)
{
csi_status_t status = CSI_STATUS_OK;
for (int j = 0; j < CSI_COPROC_MAX; j++) {
csi_desc_t *csi = csi_descs[j];
if (NULL != csi) {
if (csi->state == COPROC_STATE_RUNNING) {
// put the coproc in suspend to ram for all state
status = hibernate_iop (csi->coproc);
}
}
}
return status;
}
csi_status_t
request_iop_power_state (csi_coproc_t which_coproc, csi_power_state_t ps)
{
csi_desc_t *csi;
csi = csi_descs[which_coproc];
// if the power state event was previously signaled (panic recovery for example)
// unsignal it was we need to wait for a new transition
event_unsignal (&(csi->power_state_event));
// Request the IOP to transition to the specified power state
// power message are always send thru the management channel
bi_ep_mgmt_send_ps (which_coproc, ps);
// Wait for the acknowledge message.
event_wait (&(csi->power_state_event));
// make sure the power state is the one we want
if (bi_ep_mgmt_get_power_state(csi->coproc) != ps) {
return CSI_STATUS_ERROR;
}
return CSI_STATUS_OK;
}
csi_status_t
quiesce_iop (csi_coproc_t which_coproc)
{
csi_desc_t *csi;
csi_status_t status;
csi = csi_descs[which_coproc];
// Request the new power state
status = request_iop_power_state (which_coproc, CSI_PS_QUIESCE);
if (CSI_STATUS_OK != status) {
CSI_LOG(CRITICAL, csi->coproc, "Failed to quiesce\n");
return CSI_STATUS_ERROR;
}
CSI_LOG(CRITICAL, csi->coproc, "quiesced\n");
return CSI_STATUS_OK;
}
csi_status_t
hibernate_iop (csi_coproc_t which_coproc)
{
csi_desc_t *csi;
csi_status_t status;
csi = csi_descs[which_coproc];
// Request the new power state
csi_set_feature (which_coproc, COPROC_FEATURE_SHUTDOWN_IN_PROGRESS);
status = request_iop_power_state (which_coproc, CSI_PS_SLEEP);
if (CSI_STATUS_OK != status) {
CSI_LOG(CRITICAL, csi->coproc, "Failed to hibernate\n");
return CSI_STATUS_ERROR;
}
CSI_LOG(CRITICAL, csi->coproc, "in suspend to RAM\n");
// now turn off the iop
return csi_stop (which_coproc);
}
csi_status_t
set_send_timeout (csi_coproc_t which_coproc, uint32_t timeout)
{
csi_desc_t *csi = csi_descs[which_coproc];
csi->send_timeout = timeout;
return CSI_STATUS_OK;
}
uint32_t
get_send_timeout (csi_coproc_t which_coproc)
{
csi_desc_t *csi = csi_descs[which_coproc];
return csi->send_timeout;
}
csi_status_t
csi_set_feature (csi_coproc_t which_coproc, coproc_feature_t feature)
{
csi_desc_t *csi = csi_descs[which_coproc];
csi->feature = feature;
return CSI_STATUS_OK;
}
coproc_feature_t
csi_get_feature (csi_coproc_t which_coproc)
{
csi_desc_t *csi = csi_descs[which_coproc];
return csi->feature;
}
csi_status_t
csi_clr_feature (csi_coproc_t which_coproc, coproc_feature_t feature)
{
csi_desc_t *csi = csi_descs[which_coproc];
csi->feature &= ~(feature);
return CSI_STATUS_OK;
}
void
csi_info (csi_coproc_t which_coproc)
{
fw_print_version (which_coproc, &(csi_descs[which_coproc]->fw_desc));
}
////////////////////////////////////////////////////////////////////////////////
// allocate shared memory
//
static void *
allocate_shared_memory(uint32_t capacity, uint32_t alignment)
{
uint32_t actual_capacity;
void *sm;
// We always allocate page-aligned and with multiples of the page size for alignment
actual_capacity = roundup(capacity, PAGE_SIZE);
alignment = roundup(alignment, PAGE_SIZE);
// allocate
sm = memalign(actual_capacity, alignment);
maybe_do_cache_operation(CACHE_CLEAN, sm, actual_capacity);
return sm;
}
static void
free_shared_memory(void *sm)
{
free(sm);
}
static endpoint_desc_t *
find_endpoint(csi_coproc_t which_coproc, ipc_endpoint_t which_ep)
{
int j;
csi_desc_t *this_csi;
endpoint_desc_t *next_ep;
if (which_coproc < CSI_COPROC_MAX) {
this_csi = csi_descs[which_coproc];
if (this_csi != NULL) {
next_ep = this_csi->endpoints;
for (j=this_csi->endpoint_count; --j>=0; next_ep++) {
if (next_ep->index == which_ep) {
return next_ep;
}
}
}
}
return NULL;
}
////////////////////////////////////////////////////////////////////////////////
// inbox_not_empty_task
//
// Wait for and dispatch incoming messages from the IOP.
// Get all the pending message in the mailbox and dispatch them to the appropriate
// endpoint. Message to non existent endpoint are silently discarded.
//
static int
inbox_not_empty_task(void *token)
{
volatile csi_desc_t *csi;
int status;
msg_payload_t msg;
endpoint_desc_t *ep;
REQUIRE (NULL != (csi = (csi_desc_t*)token));
if (csi->state != COPROC_STATE_RUNNING) {
CSI_LOG(CRITICAL, (csi_coproc_t)csi->coproc, "error: inbox_not_empty_task() coproc not running\n");
return 1;
}
// we should only be trying to read message when the AKF is running otherwise data abort can happen.
while (COPROC_STATE_RUNNING == csi->state) {
// check the coproc status every 100ms
while ((status = akf_recv_mbox(KFW(csi->coproc), &msg, 100000)) == 0) {
// queue the message, the endpoint will ignore it if disabled.
ep = find_endpoint(csi->coproc, ipc_msg_get_endpoint(&msg));
if (ep) {
message_dispatcher(ep, (msg&IPC_MSG_PAYLOAD_MASK));
} else {
CSI_LOG(CRITICAL, (csi_coproc_t)csi->coproc, "error: message received for unknown endpoint => message discarded (%d, 0x%llx)\n", ipc_msg_get_endpoint(&msg), msg);
}
}
}
// coproc has stopped running, terminate task
return 0;
}
static void
message_dispatcher(endpoint_desc_t *ep, msg_payload_t msg)
{
// do some basic filtering before signaling
if (!ep->registered) {
if (check_log_gov(&csi_descs[ep->coproc]->gov_ep_not_reg, ep->coproc)) {
CSI_LOG(CRITICAL, ep->coproc, "error: %s endpoint not registered => message discarded\n", ep->name);
}
} else {
// add the message to the queue
ep->rcv_queue[ep->next_in] = msg;
EP_QUEUE_ADVANCE(ep->next_in, ep->rcv_queue_size);
// check for overflow. discard oldest message if it happens.
if (ep->next_in == ep->next_out) {
if (check_log_gov(&csi_descs[ep->coproc]->gov_ep_queue_ovflw, ep->coproc)) {
CSI_LOG(CRITICAL, ep->coproc, "error: %s endpoint queue overflow\n", ep->name);
}
EP_QUEUE_ADVANCE(ep->next_out, ep->rcv_queue_size);
}
// if this was the first message move the _nextOut pointer to the newly received message
if ((uint32_t)~(0) == ep->next_out) {
ep->next_out = 0;
}
// signal the endpoint that its rcv queue is not empty
REQUIRE(ep->rcv_not_empty_event!=NULL);
event_signal(ep->rcv_not_empty_event);
}
}
// endpoint support
// NOTE: an unregister method could be added if necessary
csi_status_t
csi_register_endpoint(csi_coproc_t which_coproc, uint32_t which_ep, struct task_event *event, void **return_token, const char **name)
{
endpoint_desc_t *ep;
ep = find_endpoint(which_coproc, (ipc_endpoint_t)which_ep);
if (ep==NULL) {
CSI_LOG(CRITICAL, which_coproc, "csi_register_endpoint(): no knowledge of endpoint #%d\n", which_ep);
return CSI_STATUS_UNSUPPORTED;
}
if (ep->registered) {
CSI_LOG(CRITICAL, which_coproc, "csi_register_endpoint(): %s endpoint already registered\n", ep->name);
return CSI_STATUS_ERROR;
}
if (name != NULL) {
*name = ep->name;
}
ep->rcv_not_empty_event = event;
ep->registered = true;
ep->sm_alignment = csi_descs[which_coproc]->fw_desc.alignment_req;
*return_token = (void*)ep;
return CSI_STATUS_OK;
}
void *
csi_allocate_shared_memory(void *token, uint32_t capacity)
{
endpoint_desc_t *ep = (endpoint_desc_t*)token;
void *sm;
sm = allocate_shared_memory(capacity, ep->sm_alignment);
return sm;
}
void
csi_free_shared_memory(void *sm)
{
free_shared_memory (sm);
// remove element from the list
}
csi_status_t
csi_receive_message(void *token, msg_payload_t *msg_payload)
{
endpoint_desc_t *ep = (endpoint_desc_t*)token;
REQUIRE(ep != NULL);
if (!ep->registered) {
return CSI_STATUS_ERROR;
}
// make sure we have a message available
if (((uint32_t)~(0) == ep->next_out) || (ep->next_out == ep->next_in)) {
return CSI_STATUS_UNAVAILABLE;
}
// get the message from ep input queue and return it.
*msg_payload = ep->rcv_queue[ep->next_out];
EP_QUEUE_ADVANCE(ep->next_out, ep->rcv_queue_size);
return CSI_STATUS_OK;
}
csi_status_t
csi_send_message (void *token, msg_payload_t msg_payload)
{
endpoint_desc_t *ep;
ipc_msg_t msg_out;
int status;
csi_desc_t *csi;
REQUIRE(token != NULL);
ep = (endpoint_desc_t*)token;
msg_out = (ipc_msg_t)msg_payload;
if (!ep->registered) {
return CSI_STATUS_ERROR;
}
// FixMe - some clients already put in the endpoint field - others expect it to be done for them
if ((msg_out & IPC_MSG_ENDPOINT_MASK) == 0) {
ipc_msg_set_endpoint(&msg_out, ep->index);
}
if (ipc_msg_get_endpoint(&msg_out) != ep->index) {
return CSI_STATUS_ERROR;
}
ipc_msg_set_endpoint(&msg_out, ep->index);
csi = csi_descs[ep->coproc];
status = akf_send_mbox(KFW(ep->coproc), msg_out, csi->send_timeout);
if (-2 == status) {
// timeout
CSI_LOG(CRITICAL, ep->coproc, "csi_send_message(): failed to send message %llx in %dus, AKF hanged?\n", msg_payload, csi->send_timeout);
return CSI_STATUS_TIMEOUT;
}
// all other errors are non fatal
if (0 != status) {
return CSI_STATUS_ERROR;
}
return CSI_STATUS_OK;
}
static bool
check_log_gov(log_governor_t *gov, csi_coproc_t which_coproc)
{
gov->occ_count++;
if ((gov->occ_count == 1) || (timer_ticks_to_usecs(timer_get_ticks() - gov->last_log) >= LOG_GOV_PERIOD_USEC)) {
if (gov->occ_count > 2) {
CSI_LOG(CRITICAL, which_coproc, "WARNING: The condition logged below has occurred %d times\n", (gov->occ_count-1));
}
gov->occ_count = 1;
gov->last_log = timer_get_ticks();
return true;
}
return false;
}
void maybe_do_cache_operation(int operation, void *address, u_int32_t length)
{
#if WITH_NON_COHERENT_DMA
void *aligned_address;
u_int32_t aligned_length;
aligned_address = (void*)((uintptr_t)address & ~(CPU_CACHELINE_SIZE-1));
aligned_length = roundup((length + (address - aligned_address)), CPU_CACHELINE_SIZE);
platform_cache_operation(operation, aligned_address, aligned_length);
#endif
}