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[akaros.git] / kern / src / process.c

/* Copyright (c) 2009, 2010 The Regents of the University of California
 * Barret Rhoden <brho@cs.berkeley.edu>
 * See LICENSE for details. */

#include <event.h>
#include <arch/arch.h>
#include <bitmask.h>
#include <process.h>
#include <atomic.h>
#include <smp.h>
#include <pmap.h>
#include <trap.h>
#include <umem.h>
#include <schedule.h>
#include <manager.h>
#include <stdio.h>
#include <assert.h>
#include <time.h>
#include <hashtable.h>
#include <slab.h>
#include <sys/queue.h>
#include <frontend.h>
#include <monitor.h>
#include <elf.h>
#include <arsc_server.h>
#include <kmalloc.h>
#include <ros/procinfo.h>

struct kmem_cache *proc_cache;

/* Other helpers, implemented later. */
static bool is_mapped_vcore(struct proc *p, uint32_t pcoreid);
static uint32_t get_vcoreid(struct proc *p, uint32_t pcoreid);
static uint32_t try_get_pcoreid(struct proc *p, uint32_t vcoreid);
static uint32_t get_pcoreid(struct proc *p, uint32_t vcoreid);
static void __proc_free(struct kref *kref);
static bool scp_is_vcctx_ready(struct preempt_data *vcpd);
static void save_vc_fp_state(struct preempt_data *vcpd);
static void restore_vc_fp_state(struct preempt_data *vcpd);

/* PID management. */
#define PID_MAX 32767 // goes from 0 to 32767, with 0 reserved
static DECL_BITMASK(pid_bmask, PID_MAX + 1);
spinlock_t pid_bmask_lock = SPINLOCK_INITIALIZER;
struct hashtable *pid_hash;
spinlock_t pid_hash_lock; // initialized in proc_init

/* Finds the next free entry (zero) entry in the pid_bitmask.  Set means busy.
 * PID 0 is reserved (in proc_init).  A return value of 0 is a failure (and
 * you'll also see a warning, for now).  Consider doing this with atomics. */
static pid_t get_free_pid(void)
{
        static pid_t next_free_pid = 1;
        pid_t my_pid = 0;

        spin_lock(&pid_bmask_lock);
        // atomically (can lock for now, then change to atomic_and_return
        FOR_CIRC_BUFFER(next_free_pid, PID_MAX + 1, i) {
                // always points to the next to test
                next_free_pid = (next_free_pid + 1) % (PID_MAX + 1);
                if (!GET_BITMASK_BIT(pid_bmask, i)) {
                        SET_BITMASK_BIT(pid_bmask, i);
                        my_pid = i;
                        break;
                }
        }
        spin_unlock(&pid_bmask_lock);
        if (!my_pid)
                warn("Shazbot!  Unable to find a PID!  You need to deal with this!\n");
        return my_pid;
}

/* Return a pid to the pid bitmask */
static void put_free_pid(pid_t pid)
{
        spin_lock(&pid_bmask_lock);
        CLR_BITMASK_BIT(pid_bmask, pid);
        spin_unlock(&pid_bmask_lock);
}

/* 'resume' is the time int ticks of the most recent onlining.  'total' is the
 * amount of time in ticks consumed up to and including the current offlining.
 *
 * We could move these to the map and unmap of vcores, though not every place
 * uses that (SCPs, in particular).  However, maps/unmaps happen remotely;
 * something to consider.  If we do it remotely, we can batch them up and do one
 * rdtsc() for all of them.  For now, I want to do them on the core, around when
 * we do the context change.  It'll also parallelize the accounting a bit. */
void vcore_account_online(struct proc *p, uint32_t vcoreid)
{
        struct vcore *vc = &p->procinfo->vcoremap[vcoreid];
        vc->resume_ticks = read_tsc();
}

void vcore_account_offline(struct proc *p, uint32_t vcoreid)
{
        struct vcore *vc = &p->procinfo->vcoremap[vcoreid];
        vc->total_ticks += read_tsc() - vc->resume_ticks;
}

uint64_t vcore_account_gettotal(struct proc *p, uint32_t vcoreid)
{
        struct vcore *vc = &p->procinfo->vcoremap[vcoreid];
        return vc->total_ticks;
}

/* While this could be done with just an assignment, this gives us the
 * opportunity to check for bad transitions.  Might compile these out later, so
 * we shouldn't rely on them for sanity checking from userspace.  */
int __proc_set_state(struct proc *p, uint32_t state)
{
        uint32_t curstate = p->state;
        /* Valid transitions:
         * C   -> RBS
         * C   -> D
         * RBS -> RGS
         * RGS -> RBS
         * RGS -> W
         * RGM -> W
         * W   -> RBS
         * W   -> RGS
         * W   -> RBM
         * W   -> D
         * RGS -> RBM
         * RBM -> RGM
         * RGM -> RBM
         * RGM -> RBS
         * RGS -> D
         * RGM -> D
         * D   -> DA
         *
         * These ought to be implemented later (allowed, not thought through yet).
         * RBS -> D
         * RBM -> D
         */
        #if 1 // some sort of correctness flag
        switch (curstate) {
                case PROC_CREATED:
                        if (!(state & (PROC_RUNNABLE_S | PROC_DYING)))
                                panic("Invalid State Transition! PROC_CREATED to %02x", state);
                        break;
                case PROC_RUNNABLE_S:
                        if (!(state & (PROC_RUNNING_S | PROC_DYING)))
                                panic("Invalid State Transition! PROC_RUNNABLE_S to %02x", state);
                        break;
                case PROC_RUNNING_S:
                        if (!(state & (PROC_RUNNABLE_S | PROC_RUNNABLE_M | PROC_WAITING |
                                       PROC_DYING)))
                                panic("Invalid State Transition! PROC_RUNNING_S to %02x", state);
                        break;
                case PROC_WAITING:
                        if (!(state & (PROC_RUNNABLE_S | PROC_RUNNING_S | PROC_RUNNABLE_M |
                                       PROC_DYING)))
                                panic("Invalid State Transition! PROC_WAITING to %02x", state);
                        break;
                case PROC_DYING:
                        if (state != PROC_DYING_ABORT)
                                panic("Invalid State Transition! PROC_DYING to %02x", state);
                        break;
                case PROC_DYING_ABORT:
                        panic("Invalid State Transition! PROC_DYING to %02x", state);
                        break;
                case PROC_RUNNABLE_M:
                        if (!(state & (PROC_RUNNING_M | PROC_DYING)))
                                panic("Invalid State Transition! PROC_RUNNABLE_M to %02x", state);
                        break;
                case PROC_RUNNING_M:
                        if (!(state & (PROC_RUNNABLE_S | PROC_RUNNABLE_M | PROC_WAITING |
                                       PROC_DYING)))
                                panic("Invalid State Transition! PROC_RUNNING_M to %02x", state);
                        break;
        }
        #endif
        p->state = state;
        return 0;
}

/* Returns a pointer to the proc with the given pid, or 0 if there is none.
 * This uses get_not_zero, since it is possible the refcnt is 0, which means the
 * process is dying and we should not have the ref (and thus return 0).  We need
 * to lock to protect us from getting p, (someone else removes and frees p),
 * then get_not_zero() on p.
 * Don't push the locking into the hashtable without dealing with this. */
struct proc *pid2proc(pid_t pid)
{
        spin_lock(&pid_hash_lock);
        struct proc *p = hashtable_search(pid_hash, (void*)(long)pid);
        if (p)
                if (!kref_get_not_zero(&p->p_kref, 1))
                        p = 0;
        spin_unlock(&pid_hash_lock);
        return p;
}

/* Used by devproc for successive reads of the proc table.
 * Returns a pointer to the nth proc, or 0 if there is none.
 * This uses get_not_zero, since it is possible the refcnt is 0, which means the
 * process is dying and we should not have the ref (and thus return 0).  We need
 * to lock to protect us from getting p, (someone else removes and frees p),
 * then get_not_zero() on p.
 * Don't push the locking into the hashtable without dealing with this. */
struct proc *pid_nth(unsigned int n)
{
        struct proc *p;
        spin_lock(&pid_hash_lock);
        if (!hashtable_count(pid_hash)) {
                spin_unlock(&pid_hash_lock);
                return NULL;
        }
        struct hashtable_itr *iter = hashtable_iterator(pid_hash);
        p = hashtable_iterator_value(iter);

        while (p) {
                /* if this process is not valid, it doesn't count,
                 * so continue
                 */

                if (kref_get_not_zero(&p->p_kref, 1)) {
                        /* this one counts */
                        if (! n){
                                printd("pid_nth: at end, p %p\n", p);
                                break;
                        }
                        kref_put(&p->p_kref);
                        n--;
                }
                if (!hashtable_iterator_advance(iter)) {
                        p = NULL;
                        break;
                }
                p = hashtable_iterator_value(iter);
        }

        spin_unlock(&pid_hash_lock);
        kfree(iter);
        return p;
}

/* Performs any initialization related to processes, such as create the proc
 * cache, prep the scheduler, etc.  When this returns, we should be ready to use
 * any process related function. */
void proc_init(void)
{
        /* Catch issues with the vcoremap and TAILQ_ENTRY sizes */
        static_assert(sizeof(TAILQ_ENTRY(vcore)) == sizeof(void*) * 2);
        proc_cache = kmem_cache_create("proc", sizeof(struct proc),
                     MAX(ARCH_CL_SIZE, __alignof__(struct proc)), 0, 0, 0);
        /* Init PID mask and hash.  pid 0 is reserved. */
        SET_BITMASK_BIT(pid_bmask, 0);
        spinlock_init(&pid_hash_lock);
        spin_lock(&pid_hash_lock);
        pid_hash = create_hashtable(100, __generic_hash, __generic_eq);
        spin_unlock(&pid_hash_lock);
        schedule_init();

        atomic_init(&num_envs, 0);
}

void proc_set_progname(struct proc *p, char *name)
{
        if (name == NULL)
                name = DEFAULT_PROGNAME;

        /* might have an issue if a dentry name isn't null terminated, and we'd get
         * extra junk up to progname_sz. Or crash. */
        strlcpy(p->progname, name, PROC_PROGNAME_SZ);
}

void proc_replace_binary_path(struct proc *p, char *path)
{
        if (p->binary_path)
                free_path(p, p->binary_path);
        p->binary_path = path;
}

/* Be sure you init'd the vcore lists before calling this. */
void proc_init_procinfo(struct proc* p)
{
        p->procinfo->pid = p->pid;
        p->procinfo->ppid = p->ppid;
        p->procinfo->max_vcores = max_vcores(p);
        p->procinfo->tsc_freq = __proc_global_info.tsc_freq;
        p->procinfo->timing_overhead = __proc_global_info.tsc_overhead;
        p->procinfo->program_end = 0;
        /* 0'ing the arguments.  Some higher function will need to set them */
        memset(p->procinfo->res_grant, 0, sizeof(p->procinfo->res_grant));
        /* 0'ing the vcore/pcore map.  Will link the vcores later. */
        memset(&p->procinfo->vcoremap, 0, sizeof(p->procinfo->vcoremap));
        memset(&p->procinfo->pcoremap, 0, sizeof(p->procinfo->pcoremap));
        p->procinfo->num_vcores = 0;
        p->procinfo->is_mcp = FALSE;
        p->procinfo->coremap_seqctr = SEQCTR_INITIALIZER;
        /* It's a bug in the kernel if we let them ask for more than max */
        for (int i = 0; i < p->procinfo->max_vcores; i++) {
                TAILQ_INSERT_TAIL(&p->inactive_vcs, &p->procinfo->vcoremap[i], list);
        }
}

void proc_init_procdata(struct proc *p)
{
        memset(p->procdata, 0, sizeof(struct procdata));
        /* processes can't go into vc context on vc 0 til they unset this.  This is
         * for processes that block before initing uthread code (like rtld). */
        atomic_set(&p->procdata->vcore_preempt_data[0].flags, VC_SCP_NOVCCTX);
}

static void proc_open_stdfds(struct proc *p)
{
        int fd;
        struct proc *old_current = current;

        /* Due to the way the syscall helpers assume the target process is current,
         * we need to set current temporarily.  We don't use switch_to, since that
         * actually loads the process's address space, which might be empty or
         * incomplete.  These syscalls shouldn't access user memory, especially
         * considering how we're probably in the boot pgdir. */
        current = p;
        fd = sysopenat(AT_FDCWD, "#cons/stdin", O_READ);
        assert(fd == 0);
        fd = sysopenat(AT_FDCWD, "#cons/stdout", O_WRITE);
        assert(fd == 1);
        fd = sysopenat(AT_FDCWD, "#cons/stderr", O_WRITE);
        assert(fd == 2);
        current = old_current;
}

/* Allocates and initializes a process, with the given parent.  Currently
 * writes the *p into **pp, and returns 0 on success, < 0 for an error.
 * Errors include:
 *  - ENOFREEPID if it can't get a PID
 *  - ENOMEM on memory exhaustion */
error_t proc_alloc(struct proc **pp, struct proc *parent, int flags)
{
        error_t r;
        struct proc *p;

        if (!(p = kmem_cache_alloc(proc_cache, 0)))
                return -ENOMEM;
        /* zero everything by default, other specific items are set below */
        memset(p, 0, sizeof(*p));

        /* only one ref, which we pass back.  the old 'existence' ref is managed by
         * the ksched */
        kref_init(&p->p_kref, __proc_free, 1);
        /* Initialize the address space */
        if ((r = env_setup_vm(p)) < 0) {
                kmem_cache_free(proc_cache, p);
                return r;
        }
        if (!(p->pid = get_free_pid())) {
                kmem_cache_free(proc_cache, p);
                return -ENOFREEPID;
        }
        if (parent && parent->binary_path)
                kstrdup(&p->binary_path, parent->binary_path);
        /* Set the basic status variables. */
        spinlock_init(&p->proc_lock);
        p->exitcode = 1337;     /* so we can see processes killed by the kernel */
        if (parent) {
                p->ppid = parent->pid;
                proc_incref(p, 1);      /* storing a ref in the parent */
                /* using the CV's lock to protect anything related to child waiting */
                cv_lock(&parent->child_wait);
                TAILQ_INSERT_TAIL(&parent->children, p, sibling_link);
                cv_unlock(&parent->child_wait);
        } else {
                p->ppid = 0;
        }
        TAILQ_INIT(&p->children);
        cv_init(&p->child_wait);
        p->state = PROC_CREATED; /* shouldn't go through state machine for init */
        p->env_flags = 0;
        spinlock_init(&p->vmr_lock);
        spinlock_init(&p->pte_lock);
        TAILQ_INIT(&p->vm_regions); /* could init this in the slab */
        p->vmr_history = 0;
        /* Initialize the vcore lists, we'll build the inactive list so that it
         * includes all vcores when we initialize procinfo.  Do this before initing
         * procinfo. */
        TAILQ_INIT(&p->online_vcs);
        TAILQ_INIT(&p->bulk_preempted_vcs);
        TAILQ_INIT(&p->inactive_vcs);
        /* Init procinfo/procdata.  Procinfo's argp/argb are 0'd */
        proc_init_procinfo(p);
        proc_init_procdata(p);

        /* Initialize the generic sysevent ring buffer */
        SHARED_RING_INIT(&p->procdata->syseventring);
        /* Initialize the frontend of the sysevent ring buffer */
        FRONT_RING_INIT(&p->syseventfrontring,
                        &p->procdata->syseventring,
                        SYSEVENTRINGSIZE);

        /* Init FS structures TODO: cleanup (might pull this out) */
        kref_get(&default_ns.kref, 1);
        p->ns = &default_ns;
        spinlock_init(&p->fs_env.lock);
        p->fs_env.umask = parent ? parent->fs_env.umask : S_IWGRP | S_IWOTH;
        p->fs_env.root = p->ns->root->mnt_root;
        kref_get(&p->fs_env.root->d_kref, 1);
        p->fs_env.pwd = parent ? parent->fs_env.pwd : p->fs_env.root;
        kref_get(&p->fs_env.pwd->d_kref, 1);
        memset(&p->open_files, 0, sizeof(p->open_files));       /* slightly ghetto */
        spinlock_init(&p->open_files.lock);
        p->open_files.max_files = NR_OPEN_FILES_DEFAULT;
        p->open_files.max_fdset = NR_FILE_DESC_DEFAULT;
        p->open_files.fd = p->open_files.fd_array;
        p->open_files.open_fds = (struct fd_set*)&p->open_files.open_fds_init;
        if (parent) {
                if (flags & PROC_DUP_FGRP)
                        clone_fdt(&parent->open_files, &p->open_files);
        } else {
                /* no parent, we're created from the kernel */
                proc_open_stdfds(p);
        }
        /* Init the ucq hash lock */
        p->ucq_hashlock = (struct hashlock*)&p->ucq_hl_noref;
        hashlock_init_irqsave(p->ucq_hashlock, HASHLOCK_DEFAULT_SZ);

        atomic_inc(&num_envs);
        frontend_proc_init(p);
        plan9setup(p, parent, flags);
        devalarm_init(p);
        TAILQ_INIT(&p->abortable_sleepers);
        spinlock_init_irqsave(&p->abort_list_lock);
        memset(&p->vmm, 0, sizeof(struct vmm));
        spinlock_init(&p->vmm.lock);
        qlock_init(&p->vmm.qlock);
        printd("[%08x] new process %08x\n", current ? current->pid : 0, p->pid);
        *pp = p;
        return 0;
}

/* We have a bunch of different ways to make processes.  Call this once the
 * process is ready to be used by the rest of the system.  For now, this just
 * means when it is ready to be named via the pidhash.  In the future, we might
 * push setting the state to CREATED into here. */
void __proc_ready(struct proc *p)
{
        /* Tell the ksched about us.  TODO: do we need to worry about the ksched
         * doing stuff to us before we're added to the pid_hash? */
        __sched_proc_register(p);
        spin_lock(&pid_hash_lock);
        hashtable_insert(pid_hash, (void*)(long)p->pid, p);
        spin_unlock(&pid_hash_lock);
}

/* Creates a process from the specified file, argvs, and envps. */
struct proc *proc_create(struct file *prog, char **argv, char **envp)
{
        struct proc *p;
        error_t r;
        if ((r = proc_alloc(&p, current, 0 /* flags */)) < 0)
                panic("proc_create: %d", r);
        int argc = 0, envc = 0;
        if(argv) while(argv[argc]) argc++;
        if(envp) while(envp[envc]) envc++;
        proc_set_progname(p, argc ? argv[0] : NULL);
        assert(load_elf(p, prog, argc, argv, envc, envp) == 0);
        __proc_ready(p);
        return p;
}

static int __cb_assert_no_pg(struct proc *p, pte_t pte, void *va, void *arg)
{
        assert(pte_is_unmapped(pte));
        return 0;
}

/* This is called by kref_put(), once the last reference to the process is
 * gone.  Don't call this otherwise (it will panic).  It will clean up the
 * address space and deallocate any other used memory. */
static void __proc_free(struct kref *kref)
{
        struct proc *p = container_of(kref, struct proc, p_kref);
        void *hash_ret;
        physaddr_t pa;

        printd("[PID %d] freeing proc: %d\n", current ? current->pid : 0, p->pid);
        // All parts of the kernel should have decref'd before __proc_free is called
        assert(kref_refcnt(&p->p_kref) == 0);
        assert(TAILQ_EMPTY(&p->alarmset.list));

        if (p->strace) {
                kref_put(&p->strace->procs);
                kref_put(&p->strace->users);
        }
        __vmm_struct_cleanup(p);
        p->progname[0] = 0;
        free_path(p, p->binary_path);
        cclose(p->dot);
        cclose(p->slash);
        p->dot = p->slash = 0; /* catch bugs */
        kref_put(&p->fs_env.root->d_kref);
        kref_put(&p->fs_env.pwd->d_kref);
        /* now we'll finally decref files for the file-backed vmrs */
        unmap_and_destroy_vmrs(p);
        frontend_proc_free(p);  /* TODO: please remove me one day */
        /* Remove us from the pid_hash and give our PID back (in that order). */
        spin_lock(&pid_hash_lock);
        hash_ret = hashtable_remove(pid_hash, (void*)(long)p->pid);
        spin_unlock(&pid_hash_lock);
        /* might not be in the hash/ready, if we failed during proc creation */
        if (hash_ret)
                put_free_pid(p->pid);
        else
                printd("[kernel] pid %d not in the PID hash in %s\n", p->pid,
                       __FUNCTION__);
        /* All memory below UMAPTOP should have been freed via the VMRs.  The stuff
         * above is the global info/page and procinfo/procdata.  We free procinfo
         * and procdata, but not the global memory - that's system wide.  We could
         * clear the PTEs of the upper stuff (UMAPTOP to UVPT), but we shouldn't
         * need to. */
        env_user_mem_walk(p, 0, UMAPTOP, __cb_assert_no_pg, 0);
        free_cont_pages(p->procinfo, LOG2_UP(PROCINFO_NUM_PAGES));
        free_cont_pages(p->procdata, LOG2_UP(PROCDATA_NUM_PAGES));

        env_pagetable_free(p);
        arch_pgdir_clear(&p->env_pgdir);
        p->env_cr3 = 0;

        atomic_dec(&num_envs);

        /* Dealloc the struct proc */
        kmem_cache_free(proc_cache, p);
}

/* Whether or not actor can control target.  TODO: do something reasonable here.
 * Just checking for the parent is a bit limiting.  Could walk the parent-child
 * tree, check user ids, or some combination.  Make sure actors can always
 * control themselves. */
bool proc_controls(struct proc *actor, struct proc *target)
{
        return TRUE;
        #if 0 /* Example: */
        return ((actor == target) || (target->ppid == actor->pid));
        #endif
}

/* Helper to incref by val.  Using the helper to help debug/interpose on proc
 * ref counting.  Note that pid2proc doesn't use this interface. */
void proc_incref(struct proc *p, unsigned int val)
{
        kref_get(&p->p_kref, val);
}

/* Helper to decref for debugging.  Don't directly kref_put() for now. */
void proc_decref(struct proc *p)
{
        kref_put(&p->p_kref);
}

/* Helper, makes p the 'current' process, dropping the old current/cr3.  This no
 * longer assumes the passed in reference already counted 'current'.  It will
 * incref internally when needed. */
static void __set_proc_current(struct proc *p)
{
        /* We use the pcpui to access 'current' to cut down on the core_id() calls,
         * though who know how expensive/painful they are. */
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        /* If the process wasn't here, then we need to load its address space. */
        if (p != pcpui->cur_proc) {
                proc_incref(p, 1);
                lcr3(p->env_cr3);
                /* This is "leaving the process context" of the previous proc.  The
                 * previous lcr3 unloaded the previous proc's context.  This should
                 * rarely happen, since we usually proactively leave process context,
                 * but this is the fallback. */
                if (pcpui->cur_proc)
                        proc_decref(pcpui->cur_proc);
                pcpui->cur_proc = p;
        }
}

/* Flag says if vcore context is not ready, which is set in init_procdata.  The
 * process must turn off this flag on vcore0 at some point.  It's off by default
 * on all other vcores. */
static bool scp_is_vcctx_ready(struct preempt_data *vcpd)
{
        return !(atomic_read(&vcpd->flags) & VC_SCP_NOVCCTX);
}

/* Dispatches a _S process to run on the current core.  This should never be
 * called to "restart" a core.
 *
 * This will always return, regardless of whether or not the calling core is
 * being given to a process. (it used to pop the tf directly, before we had
 * cur_ctx).
 *
 * Since it always returns, it will never "eat" your reference (old
 * documentation talks about this a bit). */
void proc_run_s(struct proc *p)
{
        uint32_t coreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
        spin_lock(&p->proc_lock);
        switch (p->state) {
                case (PROC_DYING):
                case (PROC_DYING_ABORT):
                        spin_unlock(&p->proc_lock);
                        printk("[kernel] _S %d not starting due to async death\n", p->pid);
                        return;
                case (PROC_RUNNABLE_S):
                        __proc_set_state(p, PROC_RUNNING_S);
                        /* SCPs don't have full vcores, but they act like they have vcore 0.
                         * We map the vcore, since we will want to know where this process
                         * is running, even if it is only in RUNNING_S.  We can use the
                         * vcoremap, which makes death easy.  num_vcores is still 0, and we
                         * do account the time online and offline. */
                        __seq_start_write(&p->procinfo->coremap_seqctr);
                        p->procinfo->num_vcores = 0;
                        __map_vcore(p, 0, coreid);
                        vcore_account_online(p, 0);
                        __seq_end_write(&p->procinfo->coremap_seqctr);
                        /* incref, since we're saving a reference in owning proc later */
                        proc_incref(p, 1);
                        /* lock was protecting the state and VC mapping, not pcpui stuff */
                        spin_unlock(&p->proc_lock);
                        /* redundant with proc_startcore, might be able to remove that one*/
                        __set_proc_current(p);
                        /* set us up as owning_proc.  ksched bug if there is already one,
                         * for now.  can simply clear_owning if we want to. */
                        assert(!pcpui->owning_proc);
                        pcpui->owning_proc = p;
                        pcpui->owning_vcoreid = 0;
                        restore_vc_fp_state(vcpd);
                        /* similar to the old __startcore, start them in vcore context if
                         * they have notifs and aren't already in vcore context.  o/w, start
                         * them wherever they were before (could be either vc ctx or not) */
                        if (!vcpd->notif_disabled && vcpd->notif_pending
                                                  && scp_is_vcctx_ready(vcpd)) {
                                vcpd->notif_disabled = TRUE;
                                /* save the _S's ctx in the uthread slot, build and pop a new
                                 * one in actual/cur_ctx. */
                                vcpd->uthread_ctx = p->scp_ctx;
                                pcpui->cur_ctx = &pcpui->actual_ctx;
                                memset(pcpui->cur_ctx, 0, sizeof(struct user_context));
                                proc_init_ctx(pcpui->cur_ctx, 0, vcpd->vcore_entry,
                                              vcpd->vcore_stack, vcpd->vcore_tls_desc);
                        } else {
                                /* If they have no transition stack, then they can't receive
                                 * events.  The most they are getting is a wakeup from the
                                 * kernel.  They won't even turn off notif_pending, so we'll do
                                 * that for them. */
                                if (!scp_is_vcctx_ready(vcpd))
                                        vcpd->notif_pending = FALSE;
                                /* this is one of the few times cur_ctx != &actual_ctx */
                                pcpui->cur_ctx = &p->scp_ctx;
                        }
                        /* When the calling core idles, it'll call restartcore and run the
                         * _S process's context. */
                        return;
                default:
                        spin_unlock(&p->proc_lock);
                        panic("Invalid process state %p in %s()!!", p->state, __FUNCTION__);
        }
}

/* Helper: sends preempt messages to all vcores on the bulk preempt list, and
 * moves them to the inactive list. */
static void __send_bulkp_events(struct proc *p)
{
        struct vcore *vc_i, *vc_temp;
        struct event_msg preempt_msg = {0};
        /* Whenever we send msgs with the proc locked, we need at least 1 online */
        assert(!TAILQ_EMPTY(&p->online_vcs));
        /* Send preempt messages for any left on the BP list.  No need to set any
         * flags, it all was done on the real preempt.  Now we're just telling the
         * process about any that didn't get restarted and are still preempted. */
        TAILQ_FOREACH_SAFE(vc_i, &p->bulk_preempted_vcs, list, vc_temp) {
                /* Note that if there are no active vcores, send_k_e will post to our
                 * own vcore, the last of which will be put on the inactive list and be
                 * the first to be started.  We could have issues with deadlocking,
                 * since send_k_e() could grab the proclock (if there are no active
                 * vcores) */
                preempt_msg.ev_type = EV_VCORE_PREEMPT;
                preempt_msg.ev_arg2 = vcore2vcoreid(p, vc_i);   /* arg2 is 32 bits */
                send_kernel_event(p, &preempt_msg, 0);
                /* TODO: we may want a TAILQ_CONCAT_HEAD, or something that does that.
                 * We need a loop for the messages, but not necessarily for the list
                 * changes.  */
                TAILQ_REMOVE(&p->bulk_preempted_vcs, vc_i, list);
                TAILQ_INSERT_HEAD(&p->inactive_vcs, vc_i, list);
        }
}

/* Run an _M.  Can be called safely on one that is already running.  Hold the
 * lock before calling.  Other than state checks, this just starts up the _M's
 * vcores, much like the second part of give_cores_running.  More specifically,
 * give_cores_runnable puts cores on the online list, which this then sends
 * messages to.  give_cores_running immediately puts them on the list and sends
 * the message.  the two-step style may go out of fashion soon.
 *
 * This expects that the "instructions" for which core(s) to run this on will be
 * in the vcoremap, which needs to be set externally (give_cores()). */
void __proc_run_m(struct proc *p)
{
        struct vcore *vc_i;
        switch (p->state) {
                case (PROC_WAITING):
                case (PROC_DYING):
                case (PROC_DYING_ABORT):
                        warn("ksched tried to run proc %d in state %s\n", p->pid,
                             procstate2str(p->state));
                        return;
                case (PROC_RUNNABLE_M):
                        /* vcoremap[i] holds the coreid of the physical core allocated to
                         * this process.  It is set outside proc_run. */
                        if (p->procinfo->num_vcores) {
                                __send_bulkp_events(p);
                                __proc_set_state(p, PROC_RUNNING_M);
                                /* Up the refcnt, to avoid the n refcnt upping on the
                                 * destination cores.  Keep in sync with __startcore */
                                proc_incref(p, p->procinfo->num_vcores * 2);
                                /* Send kernel messages to all online vcores (which were added
                                 * to the list and mapped in __proc_give_cores()), making them
                                 * turn online */
                                TAILQ_FOREACH(vc_i, &p->online_vcs, list) {
                                        send_kernel_message(vc_i->pcoreid, __startcore, (long)p,
                                                            (long)vcore2vcoreid(p, vc_i),
                                                            (long)vc_i->nr_preempts_sent,
                                                            KMSG_ROUTINE);
                                }
                        } else {
                                warn("Tried to proc_run() an _M with no vcores!");
                        }
                        /* There a subtle race avoidance here (when we unlock after sending
                         * the message).  __proc_startcore can handle a death message, but
                         * we can't have the startcore come after the death message.
                         * Otherwise, it would look like a new process.  So we hold the lock
                         * til after we send our message, which prevents a possible death
                         * message.
                         * - Note there is no guarantee this core's interrupts were on, so
                         *   it may not get the message for a while... */
                        return;
                case (PROC_RUNNING_M):
                        return;
                default:
                        /* unlock just so the monitor can call something that might lock*/
                        spin_unlock(&p->proc_lock);
                        panic("Invalid process state %p in %s()!!", p->state, __FUNCTION__);
        }
}

/* You must disable IRQs and PRKM before calling this.
 *
 * Actually runs the given context (trapframe) of process p on the core this
 * code executes on.  This is called directly by __startcore, which needs to
 * bypass the routine_kmsg check.  Interrupts should be off when you call this.
 *
 * A note on refcnting: this function will not return, and your proc reference
 * will end up stored in current.  This will make no changes to p's refcnt, so
 * do your accounting such that there is only the +1 for current.  This means if
 * it is already in current (like in the trap return path), don't up it.  If
 * it's already in current and you have another reference (like pid2proc or from
 * an IPI), then down it (which is what happens in __startcore()).  If it's not
 * in current and you have one reference, like proc_run(non_current_p), then
 * also do nothing.  The refcnt for your *p will count for the reference stored
 * in current. */
void __proc_startcore(struct proc *p, struct user_context *ctx)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        assert(!irq_is_enabled());
        /* Should never have ktask still set.  If we do, future syscalls could try
         * to block later and lose track of our address space. */
        assert(!is_ktask(pcpui->cur_kthread));
        __set_proc_current(p);
        __set_cpu_state(pcpui, CPU_STATE_USER);
        proc_pop_ctx(ctx);
}

/* Restarts/runs the current_ctx, which must be for the current process, on the
 * core this code executes on.  Calls an internal function to do the work.
 *
 * In case there are pending routine messages, like __death, __preempt, or
 * __notify, we need to run them.  Alternatively, if there are any, we could
 * self_ipi, and run the messages immediately after popping back to userspace,
 * but that would have crappy overhead. */
void proc_restartcore(void)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];

        assert(!pcpui->cur_kthread->sysc);
        process_routine_kmsg();
        /* If there is no owning process, just idle, since we don't know what to do.
         * This could be because the process had been restarted a long time ago and
         * has since left the core, or due to a KMSG like __preempt or __death. */
        if (!pcpui->owning_proc) {
                abandon_core();
                smp_idle();
        }
        assert(pcpui->cur_ctx);
        __proc_startcore(pcpui->owning_proc, pcpui->cur_ctx);
}

/* Destroys the process.  It will destroy the process and return any cores
 * to the ksched via the __sched_proc_destroy() CB.
 *
 * Here's the way process death works:
 * 0. grab the lock (protects state transition and core map)
 * 1. set state to dying.  that keeps the kernel from doing anything for the
 * process (like proc_running it).
 * 2. figure out where the process is running (cross-core/async or RUNNING_M)
 * 3. IPI to clean up those cores (decref, etc).
 * 4. Unlock
 * 5. Clean up your core, if applicable
 * (Last core/kernel thread to decref cleans up and deallocates resources.)
 *
 * Note that some cores can be processing async calls, but will eventually
 * decref.  Should think about this more, like some sort of callback/revocation.
 *
 * This function will now always return (it used to not return if the calling
 * core was dying).  However, when it returns, a kernel message will eventually
 * come in, making you abandon_core, as if you weren't running.  It may be that
 * the only reference to p is the one you passed in, and when you decref, it'll
 * get __proc_free()d. */
void proc_destroy(struct proc *p)
{
        uint32_t nr_cores_revoked = 0;
        struct kthread *sleeper;
        struct proc *child_i, *temp;

        spin_lock(&p->proc_lock);
        /* storage for pc_arr is alloced at decl, which is after grabbing the lock*/
        uint32_t pc_arr[p->procinfo->num_vcores];
        switch (p->state) {
                case PROC_DYING: /* someone else killed this already. */
                case (PROC_DYING_ABORT):
                        spin_unlock(&p->proc_lock);
                        return;
                case PROC_CREATED:
                case PROC_RUNNABLE_S:
                case PROC_WAITING:
                        break;
                case PROC_RUNNABLE_M:
                case PROC_RUNNING_M:
                        /* Need to reclaim any cores this proc might have, even if it's not
                         * running yet.  Those running will receive a __death */
                        nr_cores_revoked = __proc_take_allcores(p, pc_arr, FALSE);
                        break;
                case PROC_RUNNING_S:
                        #if 0
                        // here's how to do it manually
                        if (current == p) {
                                lcr3(boot_cr3);
                                proc_decref(p);         /* this decref is for the cr3 */
                                current = NULL;
                        }
                        #endif
                        send_kernel_message(get_pcoreid(p, 0), __death, 0, 0, 0,
                                            KMSG_ROUTINE);
                        __seq_start_write(&p->procinfo->coremap_seqctr);
                        __unmap_vcore(p, 0);
                        __seq_end_write(&p->procinfo->coremap_seqctr);
                        /* If we ever have RUNNING_S run on non-mgmt cores, we'll need to
                         * tell the ksched about this now-idle core (after unlocking) */
                        break;
                default:
                        warn("Weird state(%s) in %s()", procstate2str(p->state),
                             __FUNCTION__);
                        spin_unlock(&p->proc_lock);
                        return;
        }
        /* At this point, a death IPI should be on its way, either from the
         * RUNNING_S one, or from proc_take_cores with a __death.  in general,
         * interrupts should be on when you call proc_destroy locally, but currently
         * aren't for all things (like traphandlers). */
        __proc_set_state(p, PROC_DYING);
        /* Disown any children.  If we want to have init inherit or something,
         * change __disown to set the ppid accordingly and concat this with init's
         * list (instead of emptying it like disown does).  Careful of lock ordering
         * between procs (need to lock to protect lists) */
        TAILQ_FOREACH_SAFE(child_i, &p->children, sibling_link, temp) {
                int ret = __proc_disown_child(p, child_i);
                /* should never fail, lock should cover the race.  invariant: any child
                 * on the list should have us as a parent */
                assert(!ret);
        }
        spin_unlock(&p->proc_lock);
        /* Wake any of our kthreads waiting on children, so they can abort */
        cv_broadcast(&p->child_wait);
        /* we need to close files here, and not in free, since we could have a
         * refcnt indirectly related to one of our files.  specifically, if we have
         * a parent sleeping on our pipe, that parent won't wake up to decref until
         * the pipe closes.  And if the parent doesnt decref, we don't free.
         * Even if we send a SIGCHLD to the parent, that would require that the
         * parent to never ignores that signal (or we risk never reaping).
         *
         * Also note that any mmap'd files will still be mmapped.  You can close the
         * file after mmapping, with no effect. */
        close_fdt(&p->open_files, FALSE);
        /* Abort any abortable syscalls.  This won't catch every sleeper, but future
         * abortable sleepers are already prevented via the DYING_ABORT state.
         * (signalled DYING_ABORT, no new sleepers will block, and now we wake all
         * old sleepers). */
        __proc_set_state(p, PROC_DYING_ABORT);
        abort_all_sysc(p);
        /* Tell the ksched about our death, and which cores we freed up */
        __sched_proc_destroy(p, pc_arr, nr_cores_revoked);
        /* Tell our parent about our state change (to DYING) */
        proc_signal_parent(p);
}

/* Can use this to signal anything that might cause a parent to wait on the
 * child, such as termination, or signals.  Change the state or whatever before
 * calling. */
void proc_signal_parent(struct proc *child)
{
        struct kthread *sleeper;
        struct proc *parent = pid2proc(child->ppid);
        if (!parent)
                return;
        send_posix_signal(parent, SIGCHLD);
        /* there could be multiple kthreads sleeping for various reasons.  even an
         * SCP could have multiple async syscalls. */
        cv_broadcast(&parent->child_wait);
        /* if the parent was waiting, there's a __launch kthread KMSG out there */
        proc_decref(parent);
}

/* Called when a parent is done with its child, and no longer wants to track the
 * child, nor to allow the child to track it.  Call with a lock (cv) held.
 * Returns 0 if we disowned, -1 on failure. */
int __proc_disown_child(struct proc *parent, struct proc *child)
{
        /* Bail out if the child has already been reaped */
        if (!child->ppid)
                return -1;
        assert(child->ppid == parent->pid);
        /* lock protects from concurrent inserts / removals from the list */
        TAILQ_REMOVE(&parent->children, child, sibling_link);
        /* After this, the child won't be able to get more refs to us, but it may
         * still have some references in running code. */
        child->ppid = 0;
        proc_decref(child);     /* ref that was keeping the child alive on the list */
        return 0;
}

/* Turns *p into an MCP.  Needs to be called from a local syscall of a RUNNING_S
 * process.  Returns 0 if it succeeded, an error code otherwise. */
int proc_change_to_m(struct proc *p)
{
        int retval = 0;
        spin_lock(&p->proc_lock);
        /* in case userspace erroneously tries to change more than once */
        if (__proc_is_mcp(p))
                goto error_out;
        switch (p->state) {
                case (PROC_RUNNING_S):
                        /* issue with if we're async or not (need to preempt it)
                         * either of these should trip it. TODO: (ACR) async core req */
                        if ((current != p) || (get_pcoreid(p, 0) != core_id()))
                                panic("We don't handle async RUNNING_S core requests yet.");
                        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
                        assert(current_ctx);
                        /* Copy uthread0's context to VC 0's uthread slot */
                        copy_current_ctx_to(&vcpd->uthread_ctx);
                        clear_owning_proc(core_id());   /* so we don't restart */
                        save_vc_fp_state(vcpd);
                        /* Userspace needs to not fuck with notif_disabled before
                         * transitioning to _M. */
                        if (vcpd->notif_disabled) {
                                printk("[kernel] user bug: notifs disabled for vcore 0\n");
                                vcpd->notif_disabled = FALSE;
                        }
                        /* in the async case, we'll need to remotely stop and bundle
                         * vcore0's TF.  this is already done for the sync case (local
                         * syscall). */
                        /* this process no longer runs on its old location (which is
                         * this core, for now, since we don't handle async calls) */
                        __seq_start_write(&p->procinfo->coremap_seqctr);
                        // TODO: (ACR) will need to unmap remotely (receive-side)
                        __unmap_vcore(p, 0);
                        vcore_account_offline(p, 0);
                        __seq_end_write(&p->procinfo->coremap_seqctr);
                        /* change to runnable_m (it's TF is already saved) */
                        __proc_set_state(p, PROC_RUNNABLE_M);
                        p->procinfo->is_mcp = TRUE;
                        spin_unlock(&p->proc_lock);
                        /* Tell the ksched that we're a real MCP now! */
                        __sched_proc_change_to_m(p);
                        return 0;
                case (PROC_RUNNABLE_S):
                        /* Issues: being on the runnable_list, proc_set_state not liking
                         * it, and not clearly thinking through how this would happen.
                         * Perhaps an async call that gets serviced after you're
                         * descheduled? */
                        warn("Not supporting RUNNABLE_S -> RUNNABLE_M yet.\n");
                        goto error_out;
                case (PROC_DYING):
                case (PROC_DYING_ABORT):
                        warn("Dying, core request coming from %d\n", core_id());
                        goto error_out;
                default:
                        goto error_out;
        }
error_out:
        spin_unlock(&p->proc_lock);
        return -EINVAL;
}

/* Old code to turn a RUNNING_M to a RUNNING_S, with the calling context
 * becoming the new 'thread0'.  Don't use this.  Caller needs to send in a
 * pc_arr big enough for all vcores.  Will return the number of cores given up
 * by the proc. */
uint32_t __proc_change_to_s(struct proc *p, uint32_t *pc_arr)
{
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
        uint32_t num_revoked;
        /* Not handling vcore accounting.  Do so if we ever use this */
        printk("[kernel] trying to transition _M -> _S (deprecated)!\n");
        assert(p->state == PROC_RUNNING_M); // TODO: (ACR) async core req
        /* save the context, to be restarted in _S mode */
        assert(current_ctx);
        copy_current_ctx_to(&p->scp_ctx);
        clear_owning_proc(core_id());   /* so we don't restart */
        save_vc_fp_state(vcpd);
        /* sending death, since it's not our job to save contexts or anything in
         * this case. */
        num_revoked = __proc_take_allcores(p, pc_arr, FALSE);
        __proc_set_state(p, PROC_RUNNABLE_S);
        return num_revoked;
}

/* Helper function.  Is the given pcore a mapped vcore?  No locking involved, be
 * careful. */
static bool is_mapped_vcore(struct proc *p, uint32_t pcoreid)
{
        return p->procinfo->pcoremap[pcoreid].valid;
}

/* Helper function.  Find the vcoreid for a given physical core id for proc p.
 * No locking involved, be careful.  Panics on failure. */
static uint32_t get_vcoreid(struct proc *p, uint32_t pcoreid)
{
        assert(is_mapped_vcore(p, pcoreid));
        return p->procinfo->pcoremap[pcoreid].vcoreid;
}

/* Helper function.  Try to find the pcoreid for a given virtual core id for
 * proc p.  No locking involved, be careful.  Use this when you can tolerate a
 * stale or otherwise 'wrong' answer. */
static uint32_t try_get_pcoreid(struct proc *p, uint32_t vcoreid)
{
        return p->procinfo->vcoremap[vcoreid].pcoreid;
}

/* Helper function.  Find the pcoreid for a given virtual core id for proc p.
 * No locking involved, be careful.  Panics on failure. */
static uint32_t get_pcoreid(struct proc *p, uint32_t vcoreid)
{
        assert(vcore_is_mapped(p, vcoreid));
        return try_get_pcoreid(p, vcoreid);
}

/* Saves the FP state of the calling core into VCPD.  Pairs with
 * restore_vc_fp_state().  On x86, the best case overhead of the flags:
 *              FNINIT: 36 ns
 *              FXSAVE: 46 ns
 *              FXRSTR: 42 ns
 *              Flagged FXSAVE: 50 ns
 *              Flagged FXRSTR: 66 ns
 *              Excess flagged FXRSTR: 42 ns
 * If we don't do it, we'll need to initialize every VCPD at process creation
 * time with a good FPU state (x86 control words are initialized as 0s, like the
 * rest of VCPD). */
static void save_vc_fp_state(struct preempt_data *vcpd)
{
        save_fp_state(&vcpd->preempt_anc);
        vcpd->rflags |= VC_FPU_SAVED;
}

/* Conditionally restores the FP state from VCPD.  If the state was not valid,
 * we don't bother restoring and just initialize the FPU. */
static void restore_vc_fp_state(struct preempt_data *vcpd)
{
        if (vcpd->rflags & VC_FPU_SAVED) {
                restore_fp_state(&vcpd->preempt_anc);
                vcpd->rflags &= ~VC_FPU_SAVED;
        } else {
                init_fp_state();
        }
}

/* Helper for SCPs, saves the core's FPU state into the VCPD vc0 slot */
void __proc_save_fpu_s(struct proc *p)
{
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
        save_vc_fp_state(vcpd);
}

/* Helper: saves the SCP's GP tf state and unmaps vcore 0.  This does *not* save
 * the FPU state.
 *
 * In the future, we'll probably use vc0's space for scp_ctx and the silly
 * state.  If we ever do that, we'll need to stop using scp_ctx (soon to be in
 * VCPD) as a location for pcpui->cur_ctx to point (dangerous) */
void __proc_save_context_s(struct proc *p)
{
        copy_current_ctx_to(&p->scp_ctx);
        __seq_start_write(&p->procinfo->coremap_seqctr);
        __unmap_vcore(p, 0);
        __seq_end_write(&p->procinfo->coremap_seqctr);
        vcore_account_offline(p, 0);
}

/* Yields the calling core.  Must be called locally (not async) for now.
 * - If RUNNING_S, you just give up your time slice and will eventually return,
 *   possibly after WAITING on an event.
 * - If RUNNING_M, you give up the current vcore (which never returns), and
 *   adjust the amount of cores wanted/granted.
 * - If you have only one vcore, you switch to WAITING.  There's no 'classic
 *   yield' for MCPs (at least not now).  When you run again, you'll have one
 *   guaranteed core, starting from the entry point.
 *
 * If the call is being nice, it means different things for SCPs and MCPs.  For
 * MCPs, it means that it is in response to a preemption (which needs to be
 * checked).  If there is no preemption pending, just return.  For SCPs, it
 * means the proc wants to give up the core, but still has work to do.  If not,
 * the proc is trying to wait on an event.  It's not being nice to others, it
 * just has no work to do.
 *
 * This usually does not return (smp_idle()), so it will eat your reference.
 * Also note that it needs a non-current/edible reference, since it will abandon
 * and continue to use the *p (current == 0, no cr3, etc).
 *
 * We disable interrupts for most of it too, since we need to protect
 * current_ctx and not race with __notify (which doesn't play well with
 * concurrent yielders). */
void proc_yield(struct proc *p, bool being_nice)
{
        uint32_t vcoreid, pcoreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[pcoreid];
        struct vcore *vc;
        struct preempt_data *vcpd;
        /* Need to lock to prevent concurrent vcore changes (online, inactive, the
         * mapping, etc).  This plus checking the nr_preempts is enough to tell if
         * our vcoreid and cur_ctx ought to be here still or if we should abort */
        spin_lock(&p->proc_lock); /* horrible scalability.  =( */
        switch (p->state) {
                case (PROC_RUNNING_S):
                        if (!being_nice) {
                                /* waiting for an event to unblock us */
                                vcpd = &p->procdata->vcore_preempt_data[0];
                                /* syncing with event's SCP code.  we set waiting, then check
                                 * pending.  they set pending, then check waiting.  it's not
                                 * possible for us to miss the notif *and* for them to miss
                                 * WAITING.  one (or both) of us will see and make sure the proc
                                 * wakes up.  */
                                __proc_set_state(p, PROC_WAITING);
                                wrmb(); /* don't let the state write pass the notif read */
                                if (vcpd->notif_pending) {
                                        __proc_set_state(p, PROC_RUNNING_S);
                                        /* they can't handle events, just need to prevent a yield.
                                         * (note the notif_pendings are collapsed). */
                                        if (!scp_is_vcctx_ready(vcpd))
                                                vcpd->notif_pending = FALSE;
                                        goto out_failed;
                                }
                                /* if we're here, we want to sleep.  a concurrent event that
                                 * hasn't already written notif_pending will have seen WAITING,
                                 * and will be spinning while we do this. */
                                __proc_save_context_s(p);
                                spin_unlock(&p->proc_lock);
                        } else {
                                /* yielding to allow other processes to run.  we're briefly
                                 * WAITING, til we are woken up */
                                __proc_set_state(p, PROC_WAITING);
                                __proc_save_context_s(p);
                                spin_unlock(&p->proc_lock);
                                /* immediately wake up the proc (makes it runnable) */
                                proc_wakeup(p);
                        }
                        goto out_yield_core;
                case (PROC_RUNNING_M):
                        break;                          /* will handle this stuff below */
                case (PROC_DYING):              /* incoming __death */
                case (PROC_DYING_ABORT):
                case (PROC_RUNNABLE_M): /* incoming (bulk) preempt/myield TODO:(BULK) */
                        goto out_failed;
                default:
                        panic("Weird state(%s) in %s()", procstate2str(p->state),
                              __FUNCTION__);
        }
        /* This is which vcore this pcore thinks it is, regardless of any unmappings
         * that may have happened remotely (with __PRs waiting to run) */
        vcoreid = pcpui->owning_vcoreid;
        vc = vcoreid2vcore(p, vcoreid);
        vcpd = &p->procdata->vcore_preempt_data[vcoreid];
        /* This is how we detect whether or not a __PR happened. */
        if (vc->nr_preempts_sent != vc->nr_preempts_done)
                goto out_failed;
        /* Sanity checks.  If we were preempted or are dying, we should have noticed
         * by now. */
        assert(is_mapped_vcore(p, pcoreid));
        assert(vcoreid == get_vcoreid(p, pcoreid));
        /* no reason to be nice, return */
        if (being_nice && !vc->preempt_pending)
                goto out_failed;
        /* At this point, AFAIK there should be no preempt/death messages on the
         * way, and we're on the online list.  So we'll go ahead and do the yielding
         * business. */
        /* If there's a preempt pending, we don't need to preempt later since we are
         * yielding (nice or otherwise).  If not, this is just a regular yield. */
        if (vc->preempt_pending) {
                vc->preempt_pending = 0;
        } else {
                /* Optional: on a normal yield, check to see if we are putting them
                 * below amt_wanted (help with user races) and bail. */
                if (p->procdata->res_req[RES_CORES].amt_wanted >=
                                       p->procinfo->num_vcores)
                        goto out_failed;
        }
        /* Don't let them yield if they are missing a notification.  Userspace must
         * not leave vcore context without dealing with notif_pending.
         * pop_user_ctx() handles leaving via uthread context.  This handles leaving
         * via a yield.
         *
         * This early check is an optimization.  The real check is below when it
         * works with the online_vcs list (syncing with event.c and INDIR/IPI
         * posting). */
        if (vcpd->notif_pending)
                goto out_failed;
        /* Now we'll actually try to yield */
        printd("[K] Process %d (%p) is yielding on vcore %d\n", p->pid, p,
               get_vcoreid(p, pcoreid));
        /* Remove from the online list, add to the yielded list, and unmap
         * the vcore, which gives up the core. */
        TAILQ_REMOVE(&p->online_vcs, vc, list);
        /* Now that we're off the online list, check to see if an alert made
         * it through (event.c sets this) */
        wrmb(); /* prev write must hit before reading notif_pending */
        /* Note we need interrupts disabled, since a __notify can come in
         * and set pending to FALSE */
        if (vcpd->notif_pending) {
                /* We lost, put it back on the list and abort the yield.  If we ever
                 * build an myield, we'll need a way to deal with this for all vcores */
                TAILQ_INSERT_TAIL(&p->online_vcs, vc, list); /* could go HEAD */
                goto out_failed;
        }
        /* Not really a kmsg, but it acts like one w.r.t. proc mgmt */
        pcpui_trace_kmsg(pcpui, (uintptr_t)proc_yield);
        /* We won the race with event sending, we can safely yield */
        TAILQ_INSERT_HEAD(&p->inactive_vcs, vc, list);
        /* Note this protects stuff userspace should look at, which doesn't
         * include the TAILQs. */
        __seq_start_write(&p->procinfo->coremap_seqctr);
        /* Next time the vcore starts, it starts fresh */
        vcpd->notif_disabled = FALSE;
        __unmap_vcore(p, vcoreid);
        p->procinfo->num_vcores--;
        p->procinfo->res_grant[RES_CORES] = p->procinfo->num_vcores;
        __seq_end_write(&p->procinfo->coremap_seqctr);
        vcore_account_offline(p, vcoreid);
        /* No more vcores?  Then we wait on an event */
        if (p->procinfo->num_vcores == 0) {
                /* consider a ksched op to tell it about us WAITING */
                __proc_set_state(p, PROC_WAITING);
        }
        spin_unlock(&p->proc_lock);
        /* We discard the current context, but we still need to restore the core */
        arch_finalize_ctx(pcpui->cur_ctx);
        /* Hand the now-idle core to the ksched */
        __sched_put_idle_core(p, pcoreid);
        goto out_yield_core;
out_failed:
        /* for some reason we just want to return, either to take a KMSG that cleans
         * us up, or because we shouldn't yield (ex: notif_pending). */
        spin_unlock(&p->proc_lock);
        return;
out_yield_core:                         /* successfully yielded the core */
        proc_decref(p);                 /* need to eat the ref passed in */
        /* Clean up the core and idle. */
        clear_owning_proc(pcoreid);     /* so we don't restart */
        abandon_core();
        smp_idle();
}

/* Sends a notification (aka active notification, aka IPI) to p's vcore.  We
 * only send a notification if one they are enabled.  There's a bunch of weird
 * cases with this, and how pending / enabled are signals between the user and
 * kernel - check the documentation.  Note that pending is more about messages.
 * The process needs to be in vcore_context, and the reason is usually a
 * message.  We set pending here in case we were called to prod them into vcore
 * context (like via a sys_self_notify).  Also note that this works for _S
 * procs, if you send to vcore 0 (and the proc is running). */
void proc_notify(struct proc *p, uint32_t vcoreid)
{
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[vcoreid];

        /* If you're thinking about checking notif_pending and then returning if it
         * is already set, note that some callers (e.g. the event system) set
         * notif_pending when they deliver a message, regardless of whether there is
         * an IPI or not.  Those callers assume that we don't care about
         * notif_pending, only notif_disabled.  So don't change this without
         * changing them (probably can't without a lot of thought - that
         * notif_pending is about missing messages.  It might be possible to say "no
         * IPI, but don't let me miss messages that were delivered." */
        vcpd->notif_pending = TRUE;
        wrmb(); /* must write notif_pending before reading notif_disabled */
        if (!vcpd->notif_disabled) {
                /* GIANT WARNING: we aren't using the proc-lock to protect the
                 * vcoremap.  We want to be able to use this from interrupt context,
                 * and don't want the proc_lock to be an irqsave.  Spurious
                 * __notify() kmsgs are okay (it checks to see if the right receiver
                 * is current). */
                if (vcore_is_mapped(p, vcoreid)) {
                        printd("[kernel] sending notif to vcore %d\n", vcoreid);
                        /* This use of try_get_pcoreid is racy, might be unmapped */
                        send_kernel_message(try_get_pcoreid(p, vcoreid), __notify, (long)p,
                                            0, 0, KMSG_ROUTINE);
                }
        }
}

/* Makes sure p is runnable.  Callers may spam this, so it needs to handle
 * repeated calls for the same event.  Callers include event delivery, SCP
 * yield, and new SCPs.  Will trigger __sched_.cp_wakeup() CBs.  Will only
 * trigger the CB once, regardless of how many times we are called, *until* the
 * proc becomes WAITING again, presumably because of something the ksched did.*/
void proc_wakeup(struct proc *p)
{
        spin_lock(&p->proc_lock);
        if (__proc_is_mcp(p)) {
                /* we only wake up WAITING mcps */
                if (p->state != PROC_WAITING) {
                        spin_unlock(&p->proc_lock);
                        return;
                }
                __proc_set_state(p, PROC_RUNNABLE_M);
                spin_unlock(&p->proc_lock);
                __sched_mcp_wakeup(p);
                return;
        } else {
                /* SCPs can wake up for a variety of reasons.  the only times we need
                 * to do something is if it was waiting or just created.  other cases
                 * are either benign (just go out), or potential bugs (_Ms) */
                switch (p->state) {
                        case (PROC_CREATED):
                        case (PROC_WAITING):
                                __proc_set_state(p, PROC_RUNNABLE_S);
                                break;
                        case (PROC_RUNNABLE_S):
                        case (PROC_RUNNING_S):
                        case (PROC_DYING):
                        case (PROC_DYING_ABORT):
                                spin_unlock(&p->proc_lock);
                                return;
                        case (PROC_RUNNABLE_M):
                        case (PROC_RUNNING_M):
                                warn("Weird state(%s) in %s()", procstate2str(p->state),
                                     __FUNCTION__);
                                spin_unlock(&p->proc_lock);
                                return;
                }
                printd("[kernel] FYI, waking up an _S proc\n"); /* thanks, past brho! */
                spin_unlock(&p->proc_lock);
                __sched_scp_wakeup(p);
        }
}

/* Is the process in multi_mode / is an MCP or not?  */
bool __proc_is_mcp(struct proc *p)
{
        /* in lieu of using the amount of cores requested, or having a bunch of
         * states (like PROC_WAITING_M and _S), I'll just track it with a bool. */
        return p->procinfo->is_mcp;
}

bool proc_is_vcctx_ready(struct proc *p)
{
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[0];
        return scp_is_vcctx_ready(vcpd);
}

/************************  Preemption Functions  ******************************
 * Don't rely on these much - I'll be sure to change them up a bit.
 *
 * Careful about what takes a vcoreid and what takes a pcoreid.  Also, there may
 * be weird glitches with setting the state to RUNNABLE_M.  It is somewhat in
 * flux.  The num_vcores is changed after take_cores, but some of the messages
 * (or local traps) may not yet be ready to handle seeing their future state.
 * But they should be, so fix those when they pop up.
 *
 * Another thing to do would be to make the _core functions take a pcorelist,
 * and not just one pcoreid. */

/* Sets a preempt_pending warning for p's vcore, to go off 'when'.  If you care
 * about locking, do it before calling.  Takes a vcoreid! */
void __proc_preempt_warn(struct proc *p, uint32_t vcoreid, uint64_t when)
{
        struct event_msg local_msg = {0};
        /* danger with doing this unlocked: preempt_pending is set, but never 0'd,
         * since it is unmapped and not dealt with (TODO)*/
        p->procinfo->vcoremap[vcoreid].preempt_pending = when;

        /* Send the event (which internally checks to see how they want it) */
        local_msg.ev_type = EV_PREEMPT_PENDING;
        local_msg.ev_arg1 = vcoreid;
        /* Whenever we send msgs with the proc locked, we need at least 1 online.
         * Caller needs to make sure the core was online/mapped. */
        assert(!TAILQ_EMPTY(&p->online_vcs));
        send_kernel_event(p, &local_msg, vcoreid);

        /* TODO: consider putting in some lookup place for the alarm to find it.
         * til then, it'll have to scan the vcoremap (O(n) instead of O(m)) */
}

/* Warns all active vcores of an impending preemption.  Hold the lock if you
 * care about the mapping (and you should). */
void __proc_preempt_warnall(struct proc *p, uint64_t when)
{
        struct vcore *vc_i;
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                __proc_preempt_warn(p, vcore2vcoreid(p, vc_i), when);
        /* TODO: consider putting in some lookup place for the alarm to find it.
         * til then, it'll have to scan the vcoremap (O(n) instead of O(m)) */
}

// TODO: function to set an alarm, if none is outstanding

/* Raw function to preempt a single core.  If you care about locking, do it
 * before calling. */
void __proc_preempt_core(struct proc *p, uint32_t pcoreid)
{
        uint32_t vcoreid = get_vcoreid(p, pcoreid);
        struct event_msg preempt_msg = {0};
        /* works with nr_preempts_done to signal completion of a preemption */
        p->procinfo->vcoremap[vcoreid].nr_preempts_sent++;
        // expects a pcorelist.  assumes pcore is mapped and running_m
        __proc_take_corelist(p, &pcoreid, 1, TRUE);
        /* Only send the message if we have an online core.  o/w, it would fuck
         * us up (deadlock), and hey don't need a message.  the core we just took
         * will be the first one to be restarted.  It will look like a notif.  in
         * the future, we could send the event if we want, but the caller needs to
         * do that (after unlocking). */
        if (!TAILQ_EMPTY(&p->online_vcs)) {
                preempt_msg.ev_type = EV_VCORE_PREEMPT;
                preempt_msg.ev_arg2 = vcoreid;
                send_kernel_event(p, &preempt_msg, 0);
        }
}

/* Raw function to preempt every vcore.  If you care about locking, do it before
 * calling. */
uint32_t __proc_preempt_all(struct proc *p, uint32_t *pc_arr)
{
        struct vcore *vc_i;
        /* TODO:(BULK) PREEMPT - don't bother with this, set a proc wide flag, or
         * just make us RUNNABLE_M.  Note this is also used by __map_vcore. */
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                vc_i->nr_preempts_sent++;
        return __proc_take_allcores(p, pc_arr, TRUE);
}

/* Warns and preempts a vcore from p.  No delaying / alarming, or anything.  The
 * warning will be for u usec from now.  Returns TRUE if the core belonged to
 * the proc (and thus preempted), False if the proc no longer has the core. */
bool proc_preempt_core(struct proc *p, uint32_t pcoreid, uint64_t usec)
{
        uint64_t warn_time = read_tsc() + usec2tsc(usec);
        bool retval = FALSE;
        if (p->state != PROC_RUNNING_M) {
                /* more of an FYI for brho.  should be harmless to just return. */
                warn("Tried to preempt from a non RUNNING_M proc!");
                return FALSE;
        }
        spin_lock(&p->proc_lock);
        if (is_mapped_vcore(p, pcoreid)) {
                __proc_preempt_warn(p, get_vcoreid(p, pcoreid), warn_time);
                __proc_preempt_core(p, pcoreid);
                /* we might have taken the last core */
                if (!p->procinfo->num_vcores)
                        __proc_set_state(p, PROC_RUNNABLE_M);
                retval = TRUE;
        }
        spin_unlock(&p->proc_lock);
        return retval;
}

/* Warns and preempts all from p.  No delaying / alarming, or anything.  The
 * warning will be for u usec from now. */
void proc_preempt_all(struct proc *p, uint64_t usec)
{
        uint64_t warn_time = read_tsc() + usec2tsc(usec);
        uint32_t num_revoked = 0;
        spin_lock(&p->proc_lock);
        /* storage for pc_arr is alloced at decl, which is after grabbing the lock*/
        uint32_t pc_arr[p->procinfo->num_vcores];
        /* DYING could be okay */
        if (p->state != PROC_RUNNING_M) {
                warn("Tried to preempt from a non RUNNING_M proc!");
                spin_unlock(&p->proc_lock);
                return;
        }
        __proc_preempt_warnall(p, warn_time);
        num_revoked = __proc_preempt_all(p, pc_arr);
        assert(!p->procinfo->num_vcores);
        __proc_set_state(p, PROC_RUNNABLE_M);
        spin_unlock(&p->proc_lock);
        /* TODO: when we revise this func, look at __put_idle */
        /* Return the cores to the ksched */
        if (num_revoked)
                __sched_put_idle_cores(p, pc_arr, num_revoked);
}

/* Give the specific pcore to proc p.  Lots of assumptions, so don't really use
 * this.  The proc needs to be _M and prepared for it.  the pcore needs to be
 * free, etc. */
void proc_give(struct proc *p, uint32_t pcoreid)
{
        warn("Your idlecoremap is now screwed up");     /* TODO (IDLE) */
        spin_lock(&p->proc_lock);
        // expects a pcorelist, we give it a list of one
        __proc_give_cores(p, &pcoreid, 1);
        spin_unlock(&p->proc_lock);
}

/* Global version of the helper, for sys_get_vcoreid (might phase that syscall
 * out). */
uint32_t proc_get_vcoreid(struct proc *p)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        if (pcpui->owning_proc == p) {
                return pcpui->owning_vcoreid;
        } else {
                warn("Asked for vcoreid for %p, but %p is pwns", p, pcpui->owning_proc);
                return (uint32_t)-1;
        }
}

/* TODO: make all of these static inlines when we gut the env crap */
bool vcore_is_mapped(struct proc *p, uint32_t vcoreid)
{
        return p->procinfo->vcoremap[vcoreid].valid;
}

/* Can do this, or just create a new field and save it in the vcoremap */
uint32_t vcore2vcoreid(struct proc *p, struct vcore *vc)
{
        return (vc - p->procinfo->vcoremap);
}

struct vcore *vcoreid2vcore(struct proc *p, uint32_t vcoreid)
{
        return &p->procinfo->vcoremap[vcoreid];
}

/********** Core granting (bulk and single) ***********/

/* Helper: gives pcore to the process, mapping it to the next available vcore
 * from list vc_list.  Returns TRUE if we succeeded (non-empty).  If you pass in
 * **vc, we'll tell you which vcore it was. */
static bool __proc_give_a_pcore(struct proc *p, uint32_t pcore,
                                struct vcore_tailq *vc_list, struct vcore **vc)
{
        struct vcore *new_vc;
        new_vc = TAILQ_FIRST(vc_list);
        if (!new_vc)
                return FALSE;
        printd("setting vcore %d to pcore %d\n", vcore2vcoreid(p, new_vc),
               pcore);
        TAILQ_REMOVE(vc_list, new_vc, list);
        TAILQ_INSERT_TAIL(&p->online_vcs, new_vc, list);
        __map_vcore(p, vcore2vcoreid(p, new_vc), pcore);
        if (vc)
                *vc = new_vc;
        return TRUE;
}

static void __proc_give_cores_runnable(struct proc *p, uint32_t *pc_arr,
                                       uint32_t num)
{
        assert(p->state == PROC_RUNNABLE_M);
        assert(num);    /* catch bugs */
        /* add new items to the vcoremap */
        __seq_start_write(&p->procinfo->coremap_seqctr);/* unncessary if offline */
        p->procinfo->num_vcores += num;
        for (int i = 0; i < num; i++) {
                /* Try from the bulk list first */
                if (__proc_give_a_pcore(p, pc_arr[i], &p->bulk_preempted_vcs, 0))
                        continue;
                /* o/w, try from the inactive list.  at one point, i thought there might
                 * be a legit way in which the inactive list could be empty, but that i
                 * wanted to catch it via an assert. */
                assert(__proc_give_a_pcore(p, pc_arr[i], &p->inactive_vcs, 0));
        }
        __seq_end_write(&p->procinfo->coremap_seqctr);
}

static void __proc_give_cores_running(struct proc *p, uint32_t *pc_arr,
                                      uint32_t num)
{
        struct vcore *vc_i;
        /* Up the refcnt, since num cores are going to start using this
         * process and have it loaded in their owning_proc and 'current'. */
        proc_incref(p, num * 2);        /* keep in sync with __startcore */
        __seq_start_write(&p->procinfo->coremap_seqctr);
        p->procinfo->num_vcores += num;
        assert(TAILQ_EMPTY(&p->bulk_preempted_vcs));
        for (int i = 0; i < num; i++) {
                assert(__proc_give_a_pcore(p, pc_arr[i], &p->inactive_vcs, &vc_i));
                send_kernel_message(pc_arr[i], __startcore, (long)p,
                                    (long)vcore2vcoreid(p, vc_i),
                                    (long)vc_i->nr_preempts_sent, KMSG_ROUTINE);
        }
        __seq_end_write(&p->procinfo->coremap_seqctr);
}

/* Gives process p the additional num cores listed in pcorelist.  If the proc is
 * not RUNNABLE_M or RUNNING_M, this will fail and allocate none of the core
 * (and return -1).  If you're RUNNING_M, this will startup your new cores at
 * the entry point with their virtual IDs (or restore a preemption).  If you're
 * RUNNABLE_M, you should call __proc_run_m after this so that the process can
 * start to use its cores.  In either case, this returns 0.
 *
 * If you're *_S, make sure your core0's TF is set (which is done when coming in
 * via arch/trap.c and we are RUNNING_S), change your state, then call this.
 * Then call __proc_run_m().
 *
 * The reason I didn't bring the _S cases from core_request over here is so we
 * can keep this family of calls dealing with only *_Ms, to avoiding caring if
 * this is called from another core, and to avoid the _S -> _M transition.
 *
 * WARNING: You must hold the proc_lock before calling this! */
int __proc_give_cores(struct proc *p, uint32_t *pc_arr, uint32_t num)
{
        /* should never happen: */
        assert(num + p->procinfo->num_vcores <= MAX_NUM_CORES);
        switch (p->state) {
                case (PROC_RUNNABLE_S):
                case (PROC_RUNNING_S):
                        warn("Don't give cores to a process in a *_S state!\n");
                        return -1;
                case (PROC_DYING):
                case (PROC_DYING_ABORT):
                case (PROC_WAITING):
                        /* can't accept, just fail */
                        return -1;
                case (PROC_RUNNABLE_M):
                        __proc_give_cores_runnable(p, pc_arr, num);
                        break;
                case (PROC_RUNNING_M):
                        __proc_give_cores_running(p, pc_arr, num);
                        break;
                default:
                        panic("Weird state(%s) in %s()", procstate2str(p->state),
                              __FUNCTION__);
        }
        /* TODO: considering moving to the ksched (hard, due to yield) */
        p->procinfo->res_grant[RES_CORES] += num;
        return 0;
}

/********** Core revocation (bulk and single) ***********/

/* Revokes a single vcore from a process (unmaps or sends a KMSG to unmap). */
static void __proc_revoke_core(struct proc *p, uint32_t vcoreid, bool preempt)
{
        uint32_t pcoreid = get_pcoreid(p, vcoreid);
        struct preempt_data *vcpd;
        if (preempt) {
                /* Lock the vcore's state (necessary for preemption recovery) */
                vcpd = &p->procdata->vcore_preempt_data[vcoreid];
                atomic_or(&vcpd->flags, VC_K_LOCK);
                send_kernel_message(pcoreid, __preempt, (long)p, 0, 0, KMSG_ROUTINE);
        } else {
                send_kernel_message(pcoreid, __death, 0, 0, 0, KMSG_ROUTINE);
        }
}

/* Revokes all cores from the process (unmaps or sends a KMSGS). */
static void __proc_revoke_allcores(struct proc *p, bool preempt)
{
        struct vcore *vc_i;
        /* TODO: if we ever get broadcast messaging, use it here (still need to lock
         * the vcores' states for preemption) */
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                __proc_revoke_core(p, vcore2vcoreid(p, vc_i), preempt);
}

/* Might be faster to scan the vcoremap than to walk the list... */
static void __proc_unmap_allcores(struct proc *p)
{
        struct vcore *vc_i;
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                __unmap_vcore(p, vcore2vcoreid(p, vc_i));
}

/* Takes (revoke via kmsg or unmap) from process p the num cores listed in
 * pc_arr.  Will preempt if 'preempt' is set.  o/w, no state will be saved, etc.
 * Don't use this for taking all of a process's cores.
 *
 * Make sure you hold the lock when you call this, and make sure that the pcore
 * actually belongs to the proc, non-trivial due to other __preempt messages. */
void __proc_take_corelist(struct proc *p, uint32_t *pc_arr, uint32_t num,
                          bool preempt)
{
        struct vcore *vc;
        uint32_t vcoreid;
        assert(p->state & (PROC_RUNNING_M | PROC_RUNNABLE_M));
        __seq_start_write(&p->procinfo->coremap_seqctr);
        for (int i = 0; i < num; i++) {
                vcoreid = get_vcoreid(p, pc_arr[i]);
                /* Sanity check */
                assert(pc_arr[i] == get_pcoreid(p, vcoreid));
                /* Revoke / unmap core */
                if (p->state == PROC_RUNNING_M)
                        __proc_revoke_core(p, vcoreid, preempt);
                __unmap_vcore(p, vcoreid);
                /* Change lists for the vcore.  Note, the vcore is already unmapped
                 * and/or the messages are already in flight.  The only code that looks
                 * at the lists without holding the lock is event code. */
                vc = vcoreid2vcore(p, vcoreid);
                TAILQ_REMOVE(&p->online_vcs, vc, list);
                /* even for single preempts, we use the inactive list.  bulk preempt is
                 * only used for when we take everything. */
                TAILQ_INSERT_HEAD(&p->inactive_vcs, vc, list);
        }
        p->procinfo->num_vcores -= num;
        __seq_end_write(&p->procinfo->coremap_seqctr);
        p->procinfo->res_grant[RES_CORES] -= num;
}

/* Takes all cores from a process (revoke via kmsg or unmap), putting them on
 * the appropriate vcore list, and fills pc_arr with the pcores revoked, and
 * returns the number of entries in pc_arr.
 *
 * Make sure pc_arr is big enough to handle num_vcores().
 * Make sure you hold the lock when you call this. */
uint32_t __proc_take_allcores(struct proc *p, uint32_t *pc_arr, bool preempt)
{
        struct vcore *vc_i, *vc_temp;
        uint32_t num = 0;
        assert(p->state & (PROC_RUNNING_M | PROC_RUNNABLE_M));
        __seq_start_write(&p->procinfo->coremap_seqctr);
        /* Write out which pcores we're going to take */
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                pc_arr[num++] = vc_i->pcoreid;
        /* Revoke if they are running, and unmap.  Both of these need the online
         * list to not be changed yet. */
        if (p->state == PROC_RUNNING_M)
                __proc_revoke_allcores(p, preempt);
        __proc_unmap_allcores(p);
        /* Move the vcores from online to the head of the appropriate list */
        TAILQ_FOREACH_SAFE(vc_i, &p->online_vcs, list, vc_temp) {
                /* TODO: we may want a TAILQ_CONCAT_HEAD, or something that does that */
                TAILQ_REMOVE(&p->online_vcs, vc_i, list);
                /* Put the cores on the appropriate list */
                if (preempt)
                        TAILQ_INSERT_HEAD(&p->bulk_preempted_vcs, vc_i, list);
                else
                        TAILQ_INSERT_HEAD(&p->inactive_vcs, vc_i, list);
        }
        assert(TAILQ_EMPTY(&p->online_vcs));
        assert(num == p->procinfo->num_vcores);
        p->procinfo->num_vcores = 0;
        __seq_end_write(&p->procinfo->coremap_seqctr);
        p->procinfo->res_grant[RES_CORES] = 0;
        return num;
}

/* Helper to do the vcore->pcore and inverse mapping.  Hold the lock when
 * calling. */
void __map_vcore(struct proc *p, uint32_t vcoreid, uint32_t pcoreid)
{
        p->procinfo->vcoremap[vcoreid].pcoreid = pcoreid;
        p->procinfo->vcoremap[vcoreid].valid = TRUE;
        p->procinfo->pcoremap[pcoreid].vcoreid = vcoreid;
        p->procinfo->pcoremap[pcoreid].valid = TRUE;
}

/* Helper to unmap the vcore->pcore and inverse mapping.  Hold the lock when
 * calling. */
void __unmap_vcore(struct proc *p, uint32_t vcoreid)
{
        p->procinfo->pcoremap[p->procinfo->vcoremap[vcoreid].pcoreid].valid = FALSE;
        p->procinfo->vcoremap[vcoreid].valid = FALSE;
}

/* Stop running whatever context is on this core and load a known-good cr3.
 * Note this leaves no trace of what was running. This "leaves the process's
 * context.
 *
 * This does not clear the owning proc.  Use the other helper for that. */
void abandon_core(void)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        /* Syscalls that don't return will ultimately call abadon_core(), so we need
         * to make sure we don't think we are still working on a syscall. */
        pcpui->cur_kthread->sysc = 0;
        pcpui->cur_kthread->errbuf = 0; /* just in case */
        if (pcpui->cur_proc)
                __abandon_core();
}

/* Helper to clear the core's owning processor and manage refcnting.  Pass in
 * core_id() to save a couple core_id() calls. */
void clear_owning_proc(uint32_t coreid)
{
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct proc *p = pcpui->owning_proc;
        pcpui->owning_proc = 0;
        pcpui->owning_vcoreid = 0xdeadbeef;
        pcpui->cur_ctx = 0;                     /* catch bugs for now (may go away) */
        if (p)
                proc_decref(p);
}

/* Switches to the address space/context of new_p, doing nothing if we are
 * already in new_p.  This won't add extra refcnts or anything, and needs to be
 * paired with switch_back() at the end of whatever function you are in.
 * Specifically, the uncounted refs are one for the old_proc, which is passed
 * back to the caller, and new_p is getting placed in cur_proc. */
uintptr_t switch_to(struct proc *new_p)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        struct kthread *kth = pcpui->cur_kthread;
        struct proc *old_proc;
        uintptr_t ret;

        old_proc = pcpui->cur_proc;                                     /* uncounted ref */
        /* If we aren't the proc already, then switch to it */
        if (old_proc != new_p) {
                pcpui->cur_proc = new_p;                                /* uncounted ref */
                if (new_p)
                        lcr3(new_p->env_cr3);
                else
                        lcr3(boot_cr3);
        }
        ret = (uintptr_t)old_proc;
        if (is_ktask(kth)) {
                if (!(kth->flags & KTH_SAVE_ADDR_SPACE)) {
                        kth->flags |= KTH_SAVE_ADDR_SPACE;
                        /* proc pointers are aligned; we can use the lower bit as a signal
                         * to turn off SAVE_ADDR_SPACE. */
                        ret |= 0x1;
                }
        }
        return ret;
}

/* This switches back from new_p to the original process.  Pair it with
 * switch_to(), and pass in its return value for old_ret. */
void switch_back(struct proc *new_p, uintptr_t old_ret)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        struct kthread *kth = pcpui->cur_kthread;
        struct proc *old_proc;

        if (is_ktask(kth)) {
                if (old_ret & 0x1) {
                        kth->flags &= ~KTH_SAVE_ADDR_SPACE;
                        old_ret &= ~0x1;
                }
        }
        old_proc = (struct proc*)old_ret;
        if (old_proc != new_p) {
                pcpui->cur_proc = old_proc;
                if (old_proc)
                        lcr3(old_proc->env_cr3);
                else
                        lcr3(boot_cr3);
        }
}

/* Will send a TLB shootdown message to every vcore in the main address space
 * (aka, all vcores for now).  The message will take the start and end virtual
 * addresses as well, in case we want to be more clever about how much we
 * shootdown and batching our messages.  Should do the sanity about rounding up
 * and down in this function too.
 *
 * Would be nice to have a broadcast kmsg at this point.  Note this may send a
 * message to the calling core (interrupting it, possibly while holding the
 * proc_lock).  We don't need to process routine messages since it's an
 * immediate message. */
void proc_tlbshootdown(struct proc *p, uintptr_t start, uintptr_t end)
{
        /* TODO: need a better way to find cores running our address space.  we can
         * have kthreads running syscalls, async calls, processes being created. */
        struct vcore *vc_i;
        /* TODO: we might be able to avoid locking here in the future (we must hit
         * all online, and we can check __mapped).  it'll be complicated. */
        spin_lock(&p->proc_lock);
        switch (p->state) {
                case (PROC_RUNNING_S):
                        tlbflush();
                        break;
                case (PROC_RUNNING_M):
                        /* TODO: (TLB) sanity checks and rounding on the ranges */
                        TAILQ_FOREACH(vc_i, &p->online_vcs, list) {
                                send_kernel_message(vc_i->pcoreid, __tlbshootdown, start, end,
                                                    0, KMSG_IMMEDIATE);
                        }
                        break;
                default:
                        /* TODO: til we fix shootdowns, there are some odd cases where we
                         * have the address space loaded, but the state is in transition. */
                        if (p == current)
                                tlbflush();
        }
        spin_unlock(&p->proc_lock);
}

/* Helper, used by __startcore and __set_curctx, which sets up cur_ctx to run a
 * given process's vcore.  Caller needs to set up things like owning_proc and
 * whatnot.  Note that we might not have p loaded as current. */
static void __set_curctx_to_vcoreid(struct proc *p, uint32_t vcoreid,
                                    uint32_t old_nr_preempts_sent)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        struct preempt_data *vcpd = &p->procdata->vcore_preempt_data[vcoreid];
        struct vcore *vc = vcoreid2vcore(p, vcoreid);
        /* Spin until our vcore's old preemption is done.  When __SC was sent, we
         * were told what the nr_preempts_sent was at that time.  Once that many are
         * done, it is time for us to run.  This forces a 'happens-before' ordering
         * on a __PR of our VC before this __SC of the VC.  Note the nr_done should
         * not exceed old_nr_sent, since further __PR are behind this __SC in the
         * KMSG queue. */
        while (old_nr_preempts_sent != vc->nr_preempts_done)
                cpu_relax();
        cmb();  /* read nr_done before any other rd or wr.  CPU mb in the atomic. */
        /* Mark that this vcore as no longer preempted.  No danger of clobbering
         * other writes, since this would get turned on in __preempt (which can't be
         * concurrent with this function on this core), and the atomic is just
         * toggling the one bit (a concurrent VC_K_LOCK will work) */
        atomic_and(&vcpd->flags, ~VC_PREEMPTED);
        /* Once the VC is no longer preempted, we allow it to receive msgs.  We
         * could let userspace do it, but handling it here makes it easier for them
         * to handle_indirs (when they turn this flag off).  Note the atomics
         * provide the needed barriers (cmb and mb on flags). */
        atomic_or(&vcpd->flags, VC_CAN_RCV_MSG);
        printd("[kernel] startcore on physical core %d for process %d's vcore %d\n",
               core_id(), p->pid, vcoreid);
        /* If notifs are disabled, the vcore was in vcore context and we need to
         * restart the vcore_ctx.  o/w, we give them a fresh vcore (which is also
         * what happens the first time a vcore comes online).  No matter what,
         * they'll restart in vcore context.  It's just a matter of whether or not
         * it is the old, interrupted vcore context. */
        if (vcpd->notif_disabled) {
                /* copy-in the tf we'll pop, then set all security-related fields */
                pcpui->actual_ctx = vcpd->vcore_ctx;
                proc_secure_ctx(&pcpui->actual_ctx);
        } else { /* not restarting from a preemption, use a fresh vcore */
                assert(vcpd->vcore_stack);
                proc_init_ctx(&pcpui->actual_ctx, vcoreid, vcpd->vcore_entry,
                              vcpd->vcore_stack, vcpd->vcore_tls_desc);
                /* Disable/mask active notifications for fresh vcores */
                vcpd->notif_disabled = TRUE;
        }
        /* Regardless of whether or not we have a 'fresh' VC, we need to restore the
         * FPU state for the VC according to VCPD (which means either a saved FPU
         * state or a brand new init).  Starting a fresh VC is just referring to the
         * GP context we run.  The vcore itself needs to have the FPU state loaded
         * from when it previously ran and was saved (or a fresh FPU if it wasn't
         * saved).  For fresh FPUs, the main purpose is for limiting info leakage.
         * I think VCs that don't need FPU state for some reason (like having a
         * current_uthread) can handle any sort of FPU state, since it gets sorted
         * when they pop their next uthread.
         *
         * Note this can cause a GP fault on x86 if the state is corrupt.  In lieu
         * of reading in the huge FP state and mucking with mxcsr_mask, we should
         * handle this like a KPF on user code. */
        restore_vc_fp_state(vcpd);
        /* cur_ctx was built above (in actual_ctx), now use it */
        pcpui->cur_ctx = &pcpui->actual_ctx;
        /* this cur_ctx will get run when the kernel returns / idles */
        vcore_account_online(p, vcoreid);
}

/* Changes calling vcore to be vcoreid.  enable_my_notif tells us about how the
 * state calling vcore wants to be left in.  It will look like caller_vcoreid
 * was preempted.  Note we don't care about notif_pending.
 *
 * Will return:
 *              0 if we successfully changed to the target vcore.
 *              -EBUSY if the target vcore is already mapped (a good kind of failure)
 *              -EAGAIN if we failed for some other reason and need to try again.  For
 *              example, the caller could be preempted, and we never even attempted to
 *              change.
 *              -EINVAL some userspace bug */
int proc_change_to_vcore(struct proc *p, uint32_t new_vcoreid,
                         bool enable_my_notif)
{
        uint32_t caller_vcoreid, pcoreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[pcoreid];
        struct preempt_data *caller_vcpd;
        struct vcore *caller_vc, *new_vc;
        struct event_msg preempt_msg = {0};
        int retval = -EAGAIN;   /* by default, try again */
        /* Need to not reach outside the vcoremap, which might be smaller in the
         * future, but should always be as big as max_vcores */
        if (new_vcoreid >= p->procinfo->max_vcores)
                return -EINVAL;
        /* Need to lock to prevent concurrent vcore changes, like in yield. */
        spin_lock(&p->proc_lock);
        /* new_vcoreid is already runing, abort */
        if (vcore_is_mapped(p, new_vcoreid)) {
                retval = -EBUSY;
                goto out_locked;
        }
        /* Need to make sure our vcore is allowed to switch.  We might have a
         * __preempt, __death, etc, coming in.  Similar to yield. */
        switch (p->state) {
                case (PROC_RUNNING_M):
                        break;                          /* the only case we can proceed */
                case (PROC_RUNNING_S):  /* user bug, just return */
                case (PROC_DYING):              /* incoming __death */
                case (PROC_DYING_ABORT):
                case (PROC_RUNNABLE_M): /* incoming (bulk) preempt/myield TODO:(BULK) */
                        goto out_locked;
                default:
                        panic("Weird state(%s) in %s()", procstate2str(p->state),
                              __FUNCTION__);
        }
        /* This is which vcore this pcore thinks it is, regardless of any unmappings
         * that may have happened remotely (with __PRs waiting to run) */
        caller_vcoreid = pcpui->owning_vcoreid;
        caller_vc = vcoreid2vcore(p, caller_vcoreid);
        caller_vcpd = &p->procdata->vcore_preempt_data[caller_vcoreid];
        /* This is how we detect whether or not a __PR happened.  If it did, just
         * abort and handle the kmsg.  No new __PRs are coming since we hold the
         * lock.  This also detects a __PR followed by a __SC for the same VC. */
        if (caller_vc->nr_preempts_sent != caller_vc->nr_preempts_done)
                goto out_locked;
        /* Sanity checks.  If we were preempted or are dying, we should have noticed
         * by now. */
        assert(is_mapped_vcore(p, pcoreid));
        assert(caller_vcoreid == get_vcoreid(p, pcoreid));
        /* Should only call from vcore context */
        if (!caller_vcpd->notif_disabled) {
                retval = -EINVAL;
                printk("[kernel] You tried to change vcores from uthread ctx\n");
                goto out_locked;
        }
        /* Ok, we're clear to do the switch.  Lets figure out who the new one is */
        new_vc = vcoreid2vcore(p, new_vcoreid);
        printd("[kernel] changing vcore %d to vcore %d\n", caller_vcoreid,
               new_vcoreid);
        /* enable_my_notif signals how we'll be restarted */
        if (enable_my_notif) {
                /* if they set this flag, then the vcore can just restart from scratch,
                 * and we don't care about either the uthread_ctx or the vcore_ctx. */
                caller_vcpd->notif_disabled = FALSE;
                /* Don't need to save the FPU.  There should be no uthread or other
                 * reason to return to the FPU state.  But we do need to finalize the
                 * context, even though we are throwing it away.  We need to return the
                 * pcore to a state where it can run any context and not be bound to
                 * the old context. */
                arch_finalize_ctx(pcpui->cur_ctx);
        } else {
                /* need to set up the calling vcore's ctx so that it'll get restarted by
                 * __startcore, to make the caller look like it was preempted. */
                copy_current_ctx_to(&caller_vcpd->vcore_ctx);
                save_vc_fp_state(caller_vcpd);
        }
        /* Mark our core as preempted (for userspace recovery).  Userspace checks
         * this in handle_indirs, and it needs to check the mbox regardless of
         * enable_my_notif.  This does mean cores that change-to with no intent to
         * return will be tracked as PREEMPTED until they start back up (maybe
         * forever). */
        atomic_or(&caller_vcpd->flags, VC_PREEMPTED);
        /* Either way, unmap and offline our current vcore */
        /* Move the caller from online to inactive */
        TAILQ_REMOVE(&p->online_vcs, caller_vc, list);
        /* We don't bother with the notif_pending race.  note that notif_pending
         * could still be set.  this was a preempted vcore, and userspace will need
         * to deal with missed messages (preempt_recover() will handle that) */
        TAILQ_INSERT_HEAD(&p->inactive_vcs, caller_vc, list);
        /* Move the new one from inactive to online */
        TAILQ_REMOVE(&p->inactive_vcs, new_vc, list);
        TAILQ_INSERT_TAIL(&p->online_vcs, new_vc, list);
        /* Change the vcore map */
        __seq_start_write(&p->procinfo->coremap_seqctr);
        __unmap_vcore(p, caller_vcoreid);
        __map_vcore(p, new_vcoreid, pcoreid);
        __seq_end_write(&p->procinfo->coremap_seqctr);
        vcore_account_offline(p, caller_vcoreid);
        /* Send either a PREEMPT msg or a CHECK_MSGS msg.  If they said to
         * enable_my_notif, then all userspace needs is to check messages, not a
         * full preemption recovery. */
        preempt_msg.ev_type = (enable_my_notif ? EV_CHECK_MSGS : EV_VCORE_PREEMPT);
        preempt_msg.ev_arg2 = caller_vcoreid;   /* arg2 is 32 bits */
        /* Whenever we send msgs with the proc locked, we need at least 1 online.
         * In this case, it's the one we just changed to. */
        assert(!TAILQ_EMPTY(&p->online_vcs));
        send_kernel_event(p, &preempt_msg, new_vcoreid);
        /* So this core knows which vcore is here. (cur_proc and owning_proc are
         * already correct): */
        pcpui->owning_vcoreid = new_vcoreid;
        /* Until we set_curctx, we don't really have a valid current tf.  The stuff
         * in that old one is from our previous vcore, not the current
         * owning_vcoreid.  This matters for other KMSGS that will run before
         * __set_curctx (like __notify). */
        pcpui->cur_ctx = 0;
        /* Need to send a kmsg to finish.  We can't set_curctx til the __PR is done,
         * but we can't spin right here while holding the lock (can't spin while
         * waiting on a message, roughly) */
        send_kernel_message(pcoreid, __set_curctx, (long)p, (long)new_vcoreid,
                            (long)new_vc->nr_preempts_sent, KMSG_ROUTINE);
        retval = 0;
        /* Fall through to exit */
out_locked:
        spin_unlock(&p->proc_lock);
        return retval;
}

/* Kernel message handler to start a process's context on this core, when the
 * core next considers running a process.  Tightly coupled with __proc_run_m().
 * Interrupts are disabled. */
void __startcore(uint32_t srcid, long a0, long a1, long a2)
{
        uint32_t vcoreid = (uint32_t)a1;
        uint32_t coreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct proc *p_to_run = (struct proc *)a0;
        uint32_t old_nr_preempts_sent = (uint32_t)a2;

        assert(p_to_run);
        /* Can not be any TF from a process here already */
        assert(!pcpui->owning_proc);
        /* the sender of the kmsg increfed already for this saved ref to p_to_run */
        pcpui->owning_proc = p_to_run;
        pcpui->owning_vcoreid = vcoreid;
        /* sender increfed again, assuming we'd install to cur_proc.  only do this
         * if no one else is there.  this is an optimization, since we expect to
         * send these __startcores to idles cores, and this saves a scramble to
         * incref when all of the cores restartcore/startcore later.  Keep in sync
         * with __proc_give_cores() and __proc_run_m(). */
        if (!pcpui->cur_proc) {
                pcpui->cur_proc = p_to_run;     /* install the ref to cur_proc */
                lcr3(p_to_run->env_cr3);        /* load the page tables to match cur_proc */
        } else {
                proc_decref(p_to_run);          /* can't install, decref the extra one */
        }
        /* Note we are not necessarily in the cr3 of p_to_run */
        /* Now that we sorted refcnts and know p / which vcore it should be, set up
         * pcpui->cur_ctx so that it will run that particular vcore */
        __set_curctx_to_vcoreid(p_to_run, vcoreid, old_nr_preempts_sent);
}

/* Kernel message handler to load a proc's vcore context on this core.  Similar
 * to __startcore, except it is used when p already controls the core (e.g.
 * change_to).  Since the core is already controlled, pcpui such as owning proc,
 * vcoreid, and cur_proc are all already set. */
void __set_curctx(uint32_t srcid, long a0, long a1, long a2)
{
        struct proc *p = (struct proc*)a0;
        uint32_t vcoreid = (uint32_t)a1;
        uint32_t old_nr_preempts_sent = (uint32_t)a2;
        __set_curctx_to_vcoreid(p, vcoreid, old_nr_preempts_sent);
}

/* Bail out if it's the wrong process, or if they no longer want a notif.  Try
 * not to grab locks or write access to anything that isn't per-core in here. */
void __notify(uint32_t srcid, long a0, long a1, long a2)
{
        uint32_t vcoreid, coreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct preempt_data *vcpd;
        struct proc *p = (struct proc*)a0;

        /* Not the right proc */
        if (p != pcpui->owning_proc)
                return;
        /* the core might be owned, but not have a valid cur_ctx (if we're in the
         * process of changing */
        if (!pcpui->cur_ctx)
                return;
        /* Common cur_ctx sanity checks.  Note cur_ctx could be an _S's scp_ctx */
        vcoreid = pcpui->owning_vcoreid;
        vcpd = &p->procdata->vcore_preempt_data[vcoreid];
        /* for SCPs that haven't (and might never) call vc_event_init, like rtld.
         * this is harmless for MCPS to check this */
        if (!scp_is_vcctx_ready(vcpd))
                return;
        printd("received active notification for proc %d's vcore %d on pcore %d\n",
               p->procinfo->pid, vcoreid, coreid);
        /* sort signals.  notifs are now masked, like an interrupt gate */
        if (vcpd->notif_disabled)
                return;
        vcpd->notif_disabled = TRUE;
        /* save the old ctx in the uthread slot, build and pop a new one.  Note that
         * silly state isn't our business for a notification. */
        copy_current_ctx_to(&vcpd->uthread_ctx);
        memset(pcpui->cur_ctx, 0, sizeof(struct user_context));
        proc_init_ctx(pcpui->cur_ctx, vcoreid, vcpd->vcore_entry,
                      vcpd->vcore_stack, vcpd->vcore_tls_desc);
        /* this cur_ctx will get run when the kernel returns / idles */
}

void __preempt(uint32_t srcid, long a0, long a1, long a2)
{
        uint32_t vcoreid, coreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct preempt_data *vcpd;
        struct proc *p = (struct proc*)a0;

        assert(p);
        if (p != pcpui->owning_proc) {
                panic("__preempt arrived for a process (%p) that was not owning (%p)!",
                      p, pcpui->owning_proc);
        }
        /* Common cur_ctx sanity checks */
        assert(pcpui->cur_ctx);
        assert(pcpui->cur_ctx == &pcpui->actual_ctx);
        vcoreid = pcpui->owning_vcoreid;
        vcpd = &p->procdata->vcore_preempt_data[vcoreid];
        printd("[kernel] received __preempt for proc %d's vcore %d on pcore %d\n",
               p->procinfo->pid, vcoreid, coreid);
        /* if notifs are disabled, the vcore is in vcore context (as far as we're
         * concerned), and we save it in the vcore slot. o/w, we save the process's
         * cur_ctx in the uthread slot, and it'll appear to the vcore when it comes
         * back up the uthread just took a notification. */
        if (vcpd->notif_disabled)
                copy_current_ctx_to(&vcpd->vcore_ctx);
        else
                copy_current_ctx_to(&vcpd->uthread_ctx);
        /* Userspace in a preemption handler on another core might be copying FP
         * state from memory (VCPD) at the moment, and if so we don't want to
         * clobber it.  In this rare case, our current core's FPU state should be
         * the same as whatever is in VCPD, so this shouldn't be necessary, but the
         * arch-specific save function might do something other than write out
         * bit-for-bit the exact same data.  Checking STEALING suffices, since we
         * hold the K_LOCK (preventing userspace from starting a fresh STEALING
         * phase concurrently). */
        if (!(atomic_read(&vcpd->flags) & VC_UTHREAD_STEALING))
                save_vc_fp_state(vcpd);
        /* Mark the vcore as preempted and unlock (was locked by the sender). */
        atomic_or(&vcpd->flags, VC_PREEMPTED);
        atomic_and(&vcpd->flags, ~VC_K_LOCK);
        /* either __preempt or proc_yield() ends the preempt phase. */
        p->procinfo->vcoremap[vcoreid].preempt_pending = 0;
        vcore_account_offline(p, vcoreid);
        wmb();  /* make sure everything else hits before we finish the preempt */
        /* up the nr_done, which signals the next __startcore for this vc */
        p->procinfo->vcoremap[vcoreid].nr_preempts_done++;
        /* We won't restart the process later.  current gets cleared later when we
         * notice there is no owning_proc and we have nothing to do (smp_idle,
         * restartcore, etc) */
        clear_owning_proc(coreid);
}

/* Kernel message handler to clean up the core when a process is dying.
 * Note this leaves no trace of what was running.
 * It's okay if death comes to a core that's already idling and has no current.
 * It could happen if a process decref'd before __proc_startcore could incref. */
void __death(uint32_t srcid, long a0, long a1, long a2)
{
        uint32_t vcoreid, coreid = core_id();
        struct per_cpu_info *pcpui = &per_cpu_info[coreid];
        struct proc *p = pcpui->owning_proc;
        if (p) {
                vcoreid = pcpui->owning_vcoreid;
                printd("[kernel] death on physical core %d for process %d's vcore %d\n",
                       coreid, p->pid, vcoreid);
                vcore_account_offline(p, vcoreid);      /* in case anyone is counting */
                /* We won't restart the process later.  current gets cleared later when
                 * we notice there is no owning_proc and we have nothing to do
                 * (smp_idle, restartcore, etc). */
                arch_finalize_ctx(pcpui->cur_ctx);
                clear_owning_proc(coreid);
        }
}

/* Kernel message handler, usually sent IMMEDIATE, to shoot down virtual
 * addresses from a0 to a1. */
void __tlbshootdown(uint32_t srcid, long a0, long a1, long a2)
{
        /* TODO: (TLB) something more intelligent with the range */
        tlbflush();
}

void print_allpids(void)
{
        void print_proc_state(void *item, void *opaque)
        {
                struct proc *p = (struct proc*)item;
                assert(p);
                /* this actually adds an extra space, since no progname is ever
                 * PROGNAME_SZ bytes, due to the \0 counted in PROGNAME. */
                printk("%8d %-*s %-10s %6d\n", p->pid, PROC_PROGNAME_SZ, p->progname,
                       procstate2str(p->state), p->ppid);
        }
        char dashes[PROC_PROGNAME_SZ];
        memset(dashes, '-', PROC_PROGNAME_SZ);
        dashes[PROC_PROGNAME_SZ - 1] = '\0';
        /* -5, for 'Name ' */
        printk("     PID Name %-*s State      Parent    \n",
               PROC_PROGNAME_SZ - 5, "");
        printk("------------------------------%s\n", dashes);
        spin_lock(&pid_hash_lock);
        hash_for_each(pid_hash, print_proc_state, NULL);
        spin_unlock(&pid_hash_lock);
}

void proc_get_set(struct process_set *pset)
{
        void enum_proc(void *item, void *opaque)
        {
                struct proc *p = (struct proc*) item;
                struct process_set *pset = (struct process_set *) opaque;

                if (pset->num_processes < pset->size) {
                        proc_incref(p, 1);

                        pset->procs[pset->num_processes] = p;
                        pset->num_processes++;
                }
        }

        static const size_t num_extra_alloc = 16;

        pset->procs = NULL;
        do {
                if (pset->procs)
                        proc_free_set(pset);
                pset->size = atomic_read(&num_envs) + num_extra_alloc;
                pset->num_processes = 0;
                pset->procs = (struct proc **)
                        kzmalloc(pset->size * sizeof(struct proc *), MEM_WAIT);
                if (!pset->procs)
                        error(-ENOMEM, ERROR_FIXME);

                spin_lock(&pid_hash_lock);
                hash_for_each(pid_hash, enum_proc, pset);
                spin_unlock(&pid_hash_lock);

        } while (pset->num_processes == pset->size);
}

void proc_free_set(struct process_set *pset)
{
        for (size_t i = 0; i < pset->num_processes; i++)
                proc_decref(pset->procs[i]);
        kfree(pset->procs);
}

void print_proc_info(pid_t pid)
{
        int j = 0;
        uint64_t total_time = 0;
        struct proc *child, *p = pid2proc(pid);
        struct vcore *vc_i;
        if (!p) {
                printk("Bad PID.\n");
                return;
        }
        spinlock_debug(&p->proc_lock);
        //spin_lock(&p->proc_lock); // No locking!!
        printk("struct proc: %p\n", p);
        printk("Program name: %s\n", p->progname);
        printk("PID: %d\n", p->pid);
        printk("PPID: %d\n", p->ppid);
        printk("State: %s (%p)\n", procstate2str(p->state), p->state);
        printk("\tIs %san MCP\n", p->procinfo->is_mcp ? "" : "not ");
        printk("Refcnt: %d\n", atomic_read(&p->p_kref.refcount) - 1);
        printk("Flags: 0x%08x\n", p->env_flags);
        printk("CR3(phys): %p\n", p->env_cr3);
        printk("Num Vcores: %d\n", p->procinfo->num_vcores);
        printk("Vcore Lists (may be in flux w/o locking):\n----------------------\n");
        printk("Online:\n");
        TAILQ_FOREACH(vc_i, &p->online_vcs, list)
                printk("\tVcore %d -> Pcore %d\n", vcore2vcoreid(p, vc_i), vc_i->pcoreid);
        printk("Bulk Preempted:\n");
        TAILQ_FOREACH(vc_i, &p->bulk_preempted_vcs, list)
                printk("\tVcore %d\n", vcore2vcoreid(p, vc_i));
        printk("Inactive / Yielded:\n");
        TAILQ_FOREACH(vc_i, &p->inactive_vcs, list)
                printk("\tVcore %d\n", vcore2vcoreid(p, vc_i));
        printk("Nsec Online, up to the last offlining:\n------------------------");
        for (int i = 0; i < p->procinfo->max_vcores; i++) {
                uint64_t vc_time = tsc2nsec(vcore_account_gettotal(p, i));
                if (i % 4 == 0)
                        printk("\n");
                printk("  VC %3d: %14llu", i, vc_time);
                total_time += vc_time;
        }
        printk("\n");
        printk("Total CPU-NSEC: %llu\n", total_time);
        printk("Resources:\n------------------------\n");
        for (int i = 0; i < MAX_NUM_RESOURCES; i++)
                printk("\tRes type: %02d, amt wanted: %08d, amt granted: %08d\n", i,
                       p->procdata->res_req[i].amt_wanted, p->procinfo->res_grant[i]);
        printk("Open Files:\n");
        struct fd_table *files = &p->open_files;
        if (spin_locked(&files->lock)) {
                spinlock_debug(&files->lock);
                printk("FILE LOCK HELD, ABORTING\n");
                proc_decref(p);
                return;
        }
        spin_lock(&files->lock);
        for (int i = 0; i < files->max_files; i++) {
                if (GET_BITMASK_BIT(files->open_fds->fds_bits, i)) {
                        printk("\tFD: %02d, ", i);
                        if (files->fd[i].fd_file) {
                                printk("File: %p, File name: %s\n", files->fd[i].fd_file,
                                       file_name(files->fd[i].fd_file));
                        } else {
                                assert(files->fd[i].fd_chan);
                                print_chaninfo(files->fd[i].fd_chan);
                        }
                }
        }
        spin_unlock(&files->lock);
        printk("Children: (PID (struct proc *))\n");
        TAILQ_FOREACH(child, &p->children, sibling_link)
                printk("\t%d (%p)\n", child->pid, child);
        /* no locking / unlocking or refcnting */
        // spin_unlock(&p->proc_lock);
        proc_decref(p);
}

/* Debugging function, checks what (process, vcore) is supposed to run on this
 * pcore.  Meant to be called from smp_idle() before halting. */
void check_my_owner(void)
{
        struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
        void shazbot(void *item, void *opaque)
        {
                struct proc *p = (struct proc*)item;
                struct vcore *vc_i;
                assert(p);
                spin_lock(&p->proc_lock);
                TAILQ_FOREACH(vc_i, &p->online_vcs, list) {
                        /* this isn't true, a __startcore could be on the way and we're
                         * already "online" */
                        if (vc_i->pcoreid == core_id()) {
                                /* Immediate message was sent, we should get it when we enable
                                 * interrupts, which should cause us to skip cpu_halt() */
                                if (!STAILQ_EMPTY(&pcpui->immed_amsgs))
                                        continue;
                                printk("Owned pcore (%d) has no owner, by %p, vc %d!\n",
                                       core_id(), p, vcore2vcoreid(p, vc_i));
                                spin_unlock(&p->proc_lock);
                                spin_unlock(&pid_hash_lock);
                                monitor(0);
                        }
                }
                spin_unlock(&p->proc_lock);
        }
        assert(!irq_is_enabled());
        extern int booting;
        if (!booting && !pcpui->owning_proc) {
                spin_lock(&pid_hash_lock);
                hash_for_each(pid_hash, shazbot, NULL);
                spin_unlock(&pid_hash_lock);
        }
}