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[Xen-devel] [PATCH RFC V2 21/45] xen/sched: make credit2 scheduler vcpu agnostic.



Switch credit2 scheduler completely from vcpu to sched_item usage.

As we are touching lots of lines remove some white space at the end of
the line, too.

Signed-off-by: Juergen Gross <jgross@xxxxxxxx>
---
 xen/common/sched_credit2.c | 820 ++++++++++++++++++++++-----------------------
 1 file changed, 403 insertions(+), 417 deletions(-)

diff --git a/xen/common/sched_credit2.c b/xen/common/sched_credit2.c
index 0f0d6a3801..7918d46a23 100644
--- a/xen/common/sched_credit2.c
+++ b/xen/common/sched_credit2.c
@@ -45,7 +45,7 @@
 #define TRC_CSCHED2_SCHED_TASKLET    TRC_SCHED_CLASS_EVT(CSCHED2, 8)
 #define TRC_CSCHED2_UPDATE_LOAD      TRC_SCHED_CLASS_EVT(CSCHED2, 9)
 #define TRC_CSCHED2_RUNQ_ASSIGN      TRC_SCHED_CLASS_EVT(CSCHED2, 10)
-#define TRC_CSCHED2_UPDATE_VCPU_LOAD TRC_SCHED_CLASS_EVT(CSCHED2, 11)
+#define TRC_CSCHED2_UPDATE_ITEM_LOAD TRC_SCHED_CLASS_EVT(CSCHED2, 11)
 #define TRC_CSCHED2_UPDATE_RUNQ_LOAD TRC_SCHED_CLASS_EVT(CSCHED2, 12)
 #define TRC_CSCHED2_TICKLE_NEW       TRC_SCHED_CLASS_EVT(CSCHED2, 13)
 #define TRC_CSCHED2_RUNQ_MAX_WEIGHT  TRC_SCHED_CLASS_EVT(CSCHED2, 14)
@@ -74,13 +74,13 @@
  * Design:
  *
  * VMs "burn" credits based on their weight; higher weight means
- * credits burn more slowly.  The highest weight vcpu burns credits at
+ * credits burn more slowly.  The highest weight item burns credits at
  * a rate of 1 credit per nanosecond.  Others burn proportionally
  * more.
  *
- * vcpus are inserted into the runqueue by credit order.
+ * items are inserted into the runqueue by credit order.
  *
- * Credits are "reset" when the next vcpu in the runqueue is less than
+ * Credits are "reset" when the next item in the runqueue is less than
  * or equal to zero.  At that point, everyone's credits are "clipped"
  * to a small value, and a fixed credit is added to everyone.
  */
@@ -95,33 +95,33 @@
  *   be given a cap of 25%; a domain that must not use more than 1+1/2 of
  *   physical CPU time, will be given a cap of 150%;
  *
- * - caps are per-domain (not per-vCPU). If a domain has only 1 vCPU, and
- *   a 40% cap, that one vCPU will use 40% of one pCPU. If a somain has 4
- *   vCPUs, and a 200% cap, the equivalent of 100% time on 2 pCPUs will be
- *   split among the v vCPUs. How much each of the vCPUs will actually get,
+ * - caps are per-domain (not per-item). If a domain has only 1 item, and
+ *   a 40% cap, that one item will use 40% of one pCPU. If a somain has 4
+ *   items, and a 200% cap, the equivalent of 100% time on 2 pCPUs will be
+ *   split among the v items. How much each of the items will actually get,
  *   during any given interval of time, is unspecified (as it depends on
  *   various aspects: workload, system load, etc.). For instance, it is
- *   possible that, during a given time interval, 2 vCPUs use 100% each,
+ *   possible that, during a given time interval, 2 items use 100% each,
  *   and the other two use nothing; while during another time interval,
- *   two vCPUs use 80%, one uses 10% and the other 30%; or that each use
+ *   two items use 80%, one uses 10% and the other 30%; or that each use
  *   50% (and so on and so forth).
  *
  * For implementing this, we use the following approach:
  *
  * - each domain is given a 'budget', an each domain has a timer, which
  *   replenishes the domain's budget periodically. The budget is the amount
- *   of time the vCPUs of the domain can use every 'period';
+ *   of time the items of the domain can use every 'period';
  *
  * - the period is CSCHED2_BDGT_REPL_PERIOD, and is the same for all domains
  *   (but each domain has its own timer; so the all are periodic by the same
  *   period, but replenishment of the budgets of the various domains, at
  *   periods boundaries, are not synchronous);
  *
- * - when vCPUs run, they consume budget. When they don't run, they don't
- *   consume budget. If there is no budget left for the domain, no vCPU of
- *   that domain can run. If a vCPU tries to run and finds that there is no
+ * - when items run, they consume budget. When they don't run, they don't
+ *   consume budget. If there is no budget left for the domain, no item of
+ *   that domain can run. If an item tries to run and finds that there is no
  *   budget, it blocks.
- *   At whatever time a vCPU wants to run, it must check the domain's budget,
+ *   At whatever time an item wants to run, it must check the domain's budget,
  *   and if there is some, it can use it.
  *
  * - budget is replenished to the top of the capacity for the domain once
@@ -129,39 +129,39 @@
  *   though, the budget after a replenishment will always be at most equal
  *   to the total capacify of the domain ('tot_budget');
  *
- * - when a budget replenishment occurs, if there are vCPUs that had been
+ * - when a budget replenishment occurs, if there are items that had been
  *   blocked because of lack of budget, they'll be unblocked, and they will
  *   (potentially) be able to run again.
  *
  * Finally, some even more implementation related detail:
  *
- * - budget is stored in a domain-wide pool. vCPUs of the domain that want
+ * - budget is stored in a domain-wide pool. Items of the domain that want
  *   to run go to such pool, and grub some. When they do so, the amount
  *   they grabbed is _immediately_ removed from the pool. This happens in
- *   vcpu_grab_budget();
+ *   item_grab_budget();
  *
- * - when vCPUs stop running, if they've not consumed all the budget they
+ * - when items stop running, if they've not consumed all the budget they
  *   took, the leftover is put back in the pool. This happens in
- *   vcpu_return_budget();
+ *   item_return_budget();
  *
- * - the above means that a vCPU can find out that there is no budget and
+ * - the above means that an item can find out that there is no budget and
  *   block, not only if the cap has actually been reached (for this period),
- *   but also if some other vCPUs, in order to run, have grabbed a certain
+ *   but also if some other items, in order to run, have grabbed a certain
  *   quota of budget, no matter whether they've already used it all or not.
- *   A vCPU blocking because (any form of) lack of budget is said to be
- *   "parked", and such blocking happens in park_vcpu();
+ *   An item blocking because (any form of) lack of budget is said to be
+ *   "parked", and such blocking happens in park_item();
  *
- * - when a vCPU stops running, and puts back some budget in the domain pool,
+ * - when an item stops running, and puts back some budget in the domain pool,
  *   we need to check whether there is someone which has been parked and that
- *   can be unparked. This happens in unpark_parked_vcpus(), called from
+ *   can be unparked. This happens in unpark_parked_items(), called from
  *   csched2_context_saved();
  *
  * - of course, unparking happens also as a consequence of the domain's budget
  *   being replenished by the periodic timer. This also occurs by means of
  *   calling csched2_context_saved() (but from replenish_domain_budget());
  *
- * - parked vCPUs of a domain are kept in a (per-domain) list, called
- *   'parked_vcpus'). Manipulation of the list and of the domain-wide budget
+ * - parked items of a domain are kept in a (per-domain) list, called
+ *   'parked_items'). Manipulation of the list and of the domain-wide budget
  *   pool, must occur only when holding the 'budget_lock'.
  */
 
@@ -174,9 +174,9 @@
  *     pcpu_schedule_lock() / item_schedule_lock() (and friends),
  *   * a cpu may (try to) take a "remote" runqueue lock, e.g., for
  *     load balancing;
- *  + serializes runqueue operations (removing and inserting vcpus);
+ *  + serializes runqueue operations (removing and inserting items);
  *  + protects runqueue-wide data in csched2_runqueue_data;
- *  + protects vcpu parameters in csched2_item for the vcpu in the
+ *  + protects item parameters in csched2_item for the item in the
  *    runqueue.
  *
  * - Private scheduler lock
@@ -190,8 +190,8 @@
  *  + it is per-domain;
  *  + protects, in domains that have an utilization cap;
  *   * manipulation of the total budget of the domain (as it is shared
- *     among all vCPUs of the domain),
- *   * manipulation of the list of vCPUs that are blocked waiting for
+ *     among all items of the domain),
+ *   * manipulation of the list of items that are blocked waiting for
  *     some budget to be available.
  *
  * - Type:
@@ -228,9 +228,9 @@
  */
 #define CSCHED2_CREDIT_INIT          MILLISECS(10)
 /*
- * Amount of credit the idle vcpus have. It never changes, as idle
- * vcpus does not consume credits, and it must be lower than whatever
- * amount of credit 'regular' vcpu would end up with.
+ * Amount of credit the idle items have. It never changes, as idle
+ * items does not consume credits, and it must be lower than whatever
+ * amount of credit 'regular' item would end up with.
  */
 #define CSCHED2_IDLE_CREDIT          (-(1U<<30))
 /*
@@ -243,9 +243,9 @@
  * MIN_TIMER.
  */
 #define CSCHED2_MIGRATE_RESIST       ((opt_migrate_resist)*MICROSECS(1))
-/* How much to "compensate" a vcpu for L2 migration. */
+/* How much to "compensate" an item for L2 migration. */
 #define CSCHED2_MIGRATE_COMPENSATION MICROSECS(50)
-/* How tolerant we should be when peeking at runtime of vcpus on other cpus */
+/* How tolerant we should be when peeking at runtime of items on other cpus */
 #define CSCHED2_RATELIMIT_TICKLE_TOLERANCE MICROSECS(50)
 /* Reset: Value below which credit will be reset. */
 #define CSCHED2_CREDIT_RESET         0
@@ -258,7 +258,7 @@
  * Flags
  */
 /*
- * CSFLAG_scheduled: Is this vcpu either running on, or context-switching off,
+ * CSFLAG_scheduled: Is this item either running on, or context-switching off,
  * a physical cpu?
  * + Accessed only with runqueue lock held
  * + Set when chosen as next in csched2_schedule().
@@ -280,21 +280,21 @@
 #define __CSFLAG_delayed_runq_add 2
 #define CSFLAG_delayed_runq_add (1U<<__CSFLAG_delayed_runq_add)
 /*
- * CSFLAG_runq_migrate_request: This vcpu is being migrated as a result of a
+ * CSFLAG_runq_migrate_request: This item is being migrated as a result of a
  * credit2-initiated runq migrate request; migrate it to the runqueue indicated
- * in the svc struct. 
+ * in the svc struct.
  */
 #define __CSFLAG_runq_migrate_request 3
 #define CSFLAG_runq_migrate_request (1U<<__CSFLAG_runq_migrate_request)
 /*
- * CSFLAG_vcpu_yield: this vcpu was running, and has called vcpu_yield(). The
+ * CSFLAG_item_yield: this item was running, and has called vcpu_yield(). The
  * scheduler is invoked to see if we can give the cpu to someone else, and
- * get back to the yielding vcpu in a while.
+ * get back to the yielding item in a while.
  */
-#define __CSFLAG_vcpu_yield 4
-#define CSFLAG_vcpu_yield (1U<<__CSFLAG_vcpu_yield)
+#define __CSFLAG_item_yield 4
+#define CSFLAG_item_yield (1U<<__CSFLAG_item_yield)
 /*
- * CSFLAGS_pinned: this vcpu is currently 'pinned', i.e., has its hard
+ * CSFLAGS_pinned: this item is currently 'pinned', i.e., has its hard
  * affinity set to one and only 1 cpu (and, hence, can only run there).
  */
 #define __CSFLAG_pinned 5
@@ -306,7 +306,7 @@ integer_param("sched_credit2_migrate_resist", 
opt_migrate_resist);
 /*
  * Load tracking and load balancing
  *
- * Load history of runqueues and vcpus is accounted for by using an
+ * Load history of runqueues and items is accounted for by using an
  * exponential weighted moving average algorithm. However, instead of using
  * fractions,we shift everything to left by the number of bits we want to
  * use for representing the fractional part (Q-format).
@@ -326,7 +326,7 @@ integer_param("sched_credit2_migrate_resist", 
opt_migrate_resist);
  *
  * where W is the length of the window, P the multiplier for transitiong into
  * Q-format fixed point arithmetic and load is the instantaneous load of a
- * runqueue, which basically is the number of runnable vcpus there are on the
+ * runqueue, which basically is the number of runnable items there are on the
  * runqueue (for the meaning of the other terms, look at the doc comment to
  *  update_runq_load()).
  *
@@ -338,7 +338,7 @@ integer_param("sched_credit2_migrate_resist", 
opt_migrate_resist);
  * The maximum possible value for the average load, which we want to store in
  * s_time_t type variables (i.e., we have 63 bits available) is load*P. This
  * means that, with P 18 bits wide, load can occupy 45 bits. This in turn
- * means we can have 2^45 vcpus in each runqueue, before overflow occurs!
+ * means we can have 2^45 items in each runqueue, before overflow occurs!
  *
  * However, it can happen that, at step j+1, if:
  *
@@ -354,13 +354,13 @@ integer_param("sched_credit2_migrate_resist", 
opt_migrate_resist);
  *
  *  2^(63 - 30 - 18) = 2^15 = 32768
  *
- * So 32768 is the maximum number of vcpus the we can have in a runqueue,
+ * So 32768 is the maximum number of items the we can have in a runqueue,
  * at any given time, and still not have problems with the load tracking
  * calculations... and this is more than fine.
  *
  * As a matter of fact, since we are using microseconds granularity, we have
  * W=2^20. So, still with 18 fractional bits and a 1 second long window, there
- * may be 2^25 = 33554432 vcpus in a runq before we have to start thinking
+ * may be 2^25 = 33554432 items in a runq before we have to start thinking
  * about overflow.
  */
 
@@ -468,7 +468,7 @@ struct csched2_runqueue_data {
     struct list_head runq;     /* Ordered list of runnable vms               */
     int id;                    /* ID of this runqueue (-1 if invalid)        */
 
-    int load;                  /* Instantaneous load (num of non-idle vcpus) */
+    int load;                  /* Instantaneous load (num of non-idle items) */
     s_time_t load_last_update; /* Last time average was updated              */
     s_time_t avgload;          /* Decaying queue load                        */
     s_time_t b_avgload;        /* Decaying queue load modified by balancing  */
@@ -478,8 +478,8 @@ struct csched2_runqueue_data {
         tickled,               /* Have been asked to go through schedule     */
         idle;                  /* Currently idle pcpus                       */
 
-    struct list_head svc;      /* List of all vcpus assigned to the runqueue */
-    unsigned int max_weight;   /* Max weight of the vcpus in this runqueue   */
+    struct list_head svc;      /* List of all items assigned to the runqueue */
+    unsigned int max_weight;   /* Max weight of the items in this runqueue   */
     unsigned int pick_bias;    /* Last picked pcpu. Start from it next time  */
 };
 
@@ -509,20 +509,20 @@ struct csched2_pcpu {
 };
 
 /*
- * Virtual CPU
+ * Schedule Item
  */
 struct csched2_item {
     struct csched2_dom *sdom;          /* Up-pointer to domain                
*/
-    struct vcpu *vcpu;                 /* Up-pointer, to vcpu                 
*/
+    struct sched_item *item;           /* Up-pointer, to schedule item        
*/
     struct csched2_runqueue_data *rqd; /* Up-pointer to the runqueue          
*/
 
     int credit;                        /* Current amount of credit            
*/
-    unsigned int weight;               /* Weight of this vcpu                 
*/
+    unsigned int weight;               /* Weight of this item                 
*/
     unsigned int residual;             /* Reminder of div(max_weight/weight)  
*/
     unsigned flags;                    /* Status flags (16 bits would be ok,  
*/
     s_time_t budget;                   /* Current budget (if domains has cap) 
*/
                                        /* but clear_bit() does not like that) 
*/
-    s_time_t budget_quota;             /* Budget to which vCPU is entitled    
*/
+    s_time_t budget_quota;             /* Budget to which item is entitled    
*/
 
     s_time_t start_time;               /* Time we were scheduled (for credit) 
*/
 
@@ -531,7 +531,7 @@ struct csched2_item {
     s_time_t avgload;                  /* Decaying queue load                 
*/
 
     struct list_head runq_elem;        /* On the runqueue (rqd->runq)         
*/
-    struct list_head parked_elem;      /* On the parked_vcpus list            
*/
+    struct list_head parked_elem;      /* On the parked_items list            
*/
     struct list_head rqd_elem;         /* On csched2_runqueue_data's svc list 
*/
     struct csched2_runqueue_data *migrate_rqd; /* Pre-determined migr. target 
*/
     int tickled_cpu;                   /* Cpu that will pick us (-1 if none)  
*/
@@ -549,12 +549,12 @@ struct csched2_dom {
 
     struct timer repl_timer;    /* Timer for periodic replenishment of budget 
*/
     s_time_t next_repl;         /* Time at which next replenishment occurs    
*/
-    struct list_head parked_vcpus; /* List of CPUs waiting for budget         
*/
+    struct list_head parked_items; /* List of CPUs waiting for budget         
*/
 
     struct list_head sdom_elem; /* On csched2_runqueue_data's sdom list       
*/
     uint16_t weight;            /* User specified weight                      
*/
     uint16_t cap;               /* User specified cap                         
*/
-    uint16_t nr_vcpus;          /* Number of vcpus of this domain             
*/
+    uint16_t nr_items;          /* Number of items of this domain             
*/
 };
 
 /*
@@ -593,7 +593,7 @@ static inline struct csched2_runqueue_data *c2rqd(const 
struct scheduler *ops,
     return &csched2_priv(ops)->rqd[c2r(cpu)];
 }
 
-/* Does the domain of this vCPU have a cap? */
+/* Does the domain of this item have a cap? */
 static inline bool has_cap(const struct csched2_item *svc)
 {
     return svc->budget != STIME_MAX;
@@ -611,24 +611,24 @@ static inline bool has_cap(const struct csched2_item *svc)
  *    smt_idle mask.
  *
  * Once we have such a mask, it is easy to implement a policy that, either:
- *  - uses fully idle cores first: it is enough to try to schedule the vcpus
+ *  - uses fully idle cores first: it is enough to try to schedule the items
  *    on pcpus from smt_idle mask first. This is what happens if
  *    sched_smt_power_savings was not set at boot (default), and it maximizes
  *    true parallelism, and hence performance;
- *  - uses already busy cores first: it is enough to try to schedule the vcpus
+ *  - uses already busy cores first: it is enough to try to schedule the items
  *    on pcpus that are idle, but are not in smt_idle. This is what happens if
  *    sched_smt_power_savings is set at boot, and it allows as more cores as
  *    possible to stay in low power states, minimizing power consumption.
  *
  * This logic is entirely implemented in runq_tickle(), and that is enough.
- * In fact, in this scheduler, placement of a vcpu on one of the pcpus of a
+ * In fact, in this scheduler, placement of an item on one of the pcpus of a
  * runq, _always_ happens by means of tickling:
- *  - when a vcpu wakes up, it calls csched2_item_wake(), which calls
+ *  - when an item wakes up, it calls csched2_item_wake(), which calls
  *    runq_tickle();
  *  - when a migration is initiated in schedule.c, we call csched2_res_pick(),
  *    csched2_item_migrate() (which calls migrate()) and csched2_item_wake().
  *    csched2_res_pick() looks for the least loaded runq and return just any
- *    of its processors. Then, csched2_item_migrate() just moves the vcpu to
+ *    of its processors. Then, csched2_item_migrate() just moves the item to
  *    the chosen runq, and it is again runq_tickle(), called by
  *    csched2_item_wake() that actually decides what pcpu to use within the
  *    chosen runq;
@@ -643,7 +643,7 @@ static inline bool has_cap(const struct csched2_item *svc)
  *
  * NB that rqd->smt_idle is different than rqd->idle.  rqd->idle
  * records pcpus that at are merely idle (i.e., at the moment do not
- * have a vcpu running on them).  But you have to manually filter out
+ * have an item running on them).  But you have to manually filter out
  * which pcpus have been tickled in order to find cores that are not
  * going to be busy soon.  Filtering out tickled cpus pairwise is a
  * lot of extra pain; so for rqd->smt_idle, we explicitly make so that
@@ -690,24 +690,24 @@ void smt_idle_mask_clear(unsigned int cpu, cpumask_t 
*mask)
  */
 static int get_fallback_cpu(struct csched2_item *svc)
 {
-    struct vcpu *v = svc->vcpu;
+    struct sched_item *item = svc->item;
     unsigned int bs;
 
     SCHED_STAT_CRANK(need_fallback_cpu);
 
     for_each_affinity_balance_step( bs )
     {
-        int cpu = v->processor;
+        int cpu = sched_item_cpu(item);
 
-        if ( bs == BALANCE_SOFT_AFFINITY && !has_soft_affinity(v->sched_item) )
+        if ( bs == BALANCE_SOFT_AFFINITY && !has_soft_affinity(item) )
             continue;
 
-        affinity_balance_cpumask(v->sched_item, bs, cpumask_scratch_cpu(cpu));
+        affinity_balance_cpumask(item, bs, cpumask_scratch_cpu(cpu));
         cpumask_and(cpumask_scratch_cpu(cpu), cpumask_scratch_cpu(cpu),
-                    cpupool_domain_cpumask(v->domain));
+                    cpupool_domain_cpumask(item->domain));
 
         /*
-         * This is cases 1 or 3 (depending on bs): if v->processor is (still)
+         * This is cases 1 or 3 (depending on bs): if processor is (still)
          * in our affinity, go for it, for cache betterness.
          */
         if ( likely(cpumask_test_cpu(cpu, cpumask_scratch_cpu(cpu))) )
@@ -729,7 +729,7 @@ static int get_fallback_cpu(struct csched2_item *svc)
          * We may well pick any valid pcpu from our soft-affinity, outside
          * of our current runqueue, but we decide not to. In fact, changing
          * runqueue is slow, affects load distribution, and is a source of
-         * overhead for the vcpus running on the other runqueue (we need the
+         * overhead for the items running on the other runqueue (we need the
          * lock). So, better do that as a consequence of a well informed
          * decision (or if we really don't have any other chance, as we will,
          * at step 5, if we get to there).
@@ -761,7 +761,7 @@ static int get_fallback_cpu(struct csched2_item *svc)
      * We can't be here.  But if that somehow happen (in non-debug builds),
      * at least return something which both online and in our hard-affinity.
      */
-    return cpumask_any(cpumask_scratch_cpu(v->processor));
+    return cpumask_any(cpumask_scratch_cpu(sched_item_cpu(item)));
 }
 
 /*
@@ -790,7 +790,7 @@ static s_time_t c2t(struct csched2_runqueue_data *rqd, 
s_time_t credit, struct c
  * Runqueue related code.
  */
 
-static inline int vcpu_on_runq(struct csched2_item *svc)
+static inline int item_on_runq(struct csched2_item *svc)
 {
     return !list_empty(&svc->runq_elem);
 }
@@ -948,17 +948,17 @@ _runq_assign(struct csched2_item *svc, struct 
csched2_runqueue_data *rqd)
 
     update_max_weight(svc->rqd, svc->weight, 0);
 
-    /* Expected new load based on adding this vcpu */
+    /* Expected new load based on adding this item */
     rqd->b_avgload += svc->avgload;
 
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned rqi:16;
         } d;
-        d.dom = svc->vcpu->domain->domain_id;
-        d.vcpu = svc->vcpu->vcpu_id;
+        d.dom = svc->item->domain->domain_id;
+        d.item = svc->item->item_id;
         d.rqi=rqd->id;
         __trace_var(TRC_CSCHED2_RUNQ_ASSIGN, 1,
                     sizeof(d),
@@ -968,13 +968,13 @@ _runq_assign(struct csched2_item *svc, struct 
csched2_runqueue_data *rqd)
 }
 
 static void
-runq_assign(const struct scheduler *ops, struct vcpu *vc)
+runq_assign(const struct scheduler *ops, struct sched_item *item)
 {
-    struct csched2_item *svc = vc->sched_item->priv;
+    struct csched2_item *svc = item->priv;
 
     ASSERT(svc->rqd == NULL);
 
-    _runq_assign(svc, c2rqd(ops, vc->processor));
+    _runq_assign(svc, c2rqd(ops, sched_item_cpu(item)));
 }
 
 static void
@@ -982,24 +982,24 @@ _runq_deassign(struct csched2_item *svc)
 {
     struct csched2_runqueue_data *rqd = svc->rqd;
 
-    ASSERT(!vcpu_on_runq(svc));
+    ASSERT(!item_on_runq(svc));
     ASSERT(!(svc->flags & CSFLAG_scheduled));
 
     list_del_init(&svc->rqd_elem);
     update_max_weight(rqd, 0, svc->weight);
 
-    /* Expected new load based on removing this vcpu */
+    /* Expected new load based on removing this item */
     rqd->b_avgload = max_t(s_time_t, rqd->b_avgload - svc->avgload, 0);
 
     svc->rqd = NULL;
 }
 
 static void
-runq_deassign(const struct scheduler *ops, struct vcpu *vc)
+runq_deassign(const struct scheduler *ops, struct sched_item *item)
 {
-    struct csched2_item *svc = vc->sched_item->priv;
+    struct csched2_item *svc = item->priv;
 
-    ASSERT(svc->rqd == c2rqd(ops, vc->processor));
+    ASSERT(svc->rqd == c2rqd(ops, sched_item_cpu(item)));
 
     _runq_deassign(svc);
 }
@@ -1202,15 +1202,15 @@ update_svc_load(const struct scheduler *ops,
                 struct csched2_item *svc, int change, s_time_t now)
 {
     struct csched2_private *prv = csched2_priv(ops);
-    s_time_t delta, vcpu_load;
+    s_time_t delta, item_load;
     unsigned int P, W;
 
     if ( change == -1 )
-        vcpu_load = 1;
+        item_load = 1;
     else if ( change == 1 )
-        vcpu_load = 0;
+        item_load = 0;
     else
-        vcpu_load = vcpu_runnable(svc->vcpu);
+        item_load = item_runnable(svc->item);
 
     W = prv->load_window_shift;
     P = prv->load_precision_shift;
@@ -1218,7 +1218,7 @@ update_svc_load(const struct scheduler *ops,
 
     if ( svc->load_last_update + (1ULL << W) < now )
     {
-        svc->avgload = vcpu_load << P;
+        svc->avgload = item_load << P;
     }
     else
     {
@@ -1231,7 +1231,7 @@ update_svc_load(const struct scheduler *ops,
         }
 
         svc->avgload = svc->avgload +
-                       ((delta * (vcpu_load << P)) >> W) -
+                       ((delta * (item_load << P)) >> W) -
                        ((delta * svc->avgload) >> W);
     }
     svc->load_last_update = now;
@@ -1243,14 +1243,14 @@ update_svc_load(const struct scheduler *ops,
     {
         struct {
             uint64_t v_avgload;
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned shift;
         } d;
-        d.dom = svc->vcpu->domain->domain_id;
-        d.vcpu = svc->vcpu->vcpu_id;
+        d.dom = svc->item->domain->domain_id;
+        d.item = svc->item->item_id;
         d.v_avgload = svc->avgload;
         d.shift = P;
-        __trace_var(TRC_CSCHED2_UPDATE_VCPU_LOAD, 1,
+        __trace_var(TRC_CSCHED2_UPDATE_ITEM_LOAD, 1,
                     sizeof(d),
                     (unsigned char *)&d);
     }
@@ -1272,18 +1272,18 @@ static void
 runq_insert(const struct scheduler *ops, struct csched2_item *svc)
 {
     struct list_head *iter;
-    unsigned int cpu = svc->vcpu->processor;
+    unsigned int cpu = sched_item_cpu(svc->item);
     struct list_head * runq = &c2rqd(ops, cpu)->runq;
     int pos = 0;
 
     ASSERT(spin_is_locked(per_cpu(sched_res, cpu)->schedule_lock));
 
-    ASSERT(!vcpu_on_runq(svc));
-    ASSERT(c2r(cpu) == c2r(svc->vcpu->processor));
+    ASSERT(!item_on_runq(svc));
+    ASSERT(c2r(cpu) == c2r(sched_item_cpu(svc->item)));
 
     ASSERT(&svc->rqd->runq == runq);
-    ASSERT(!is_idle_vcpu(svc->vcpu));
-    ASSERT(!svc->vcpu->sched_item->is_running);
+    ASSERT(!is_idle_item(svc->item));
+    ASSERT(!svc->item->is_running);
     ASSERT(!(svc->flags & CSFLAG_scheduled));
 
     list_for_each( iter, runq )
@@ -1300,11 +1300,11 @@ runq_insert(const struct scheduler *ops, struct 
csched2_item *svc)
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned pos;
         } d;
-        d.dom = svc->vcpu->domain->domain_id;
-        d.vcpu = svc->vcpu->vcpu_id;
+        d.dom = svc->item->domain->domain_id;
+        d.item = svc->item->item_id;
         d.pos = pos;
         __trace_var(TRC_CSCHED2_RUNQ_POS, 1,
                     sizeof(d),
@@ -1314,7 +1314,7 @@ runq_insert(const struct scheduler *ops, struct 
csched2_item *svc)
 
 static inline void runq_remove(struct csched2_item *svc)
 {
-    ASSERT(vcpu_on_runq(svc));
+    ASSERT(item_on_runq(svc));
     list_del_init(&svc->runq_elem);
 }
 
@@ -1340,8 +1340,8 @@ static inline bool is_preemptable(const struct 
csched2_item *svc,
     if ( ratelimit <= CSCHED2_RATELIMIT_TICKLE_TOLERANCE )
         return true;
 
-    ASSERT(svc->vcpu->sched_item->is_running);
-    return now - svc->vcpu->sched_item->state_entry_time >
+    ASSERT(svc->item->is_running);
+    return now - svc->item->state_entry_time >
            ratelimit - CSCHED2_RATELIMIT_TICKLE_TOLERANCE;
 }
 
@@ -1369,17 +1369,17 @@ static s_time_t tickle_score(const struct scheduler 
*ops, s_time_t now,
 
     /*
      * We are dealing with cpus that are marked non-idle (i.e., that are not
-     * in rqd->idle). However, some of them may be running their idle vcpu,
+     * in rqd->idle). However, some of them may be running their idle item,
      * if taking care of tasklets. In that case, we want to leave it alone.
      */
-    if ( unlikely(is_idle_vcpu(cur->vcpu) ||
+    if ( unlikely(is_idle_item(cur->item) ||
          !is_preemptable(cur, now, MICROSECS(prv->ratelimit_us))) )
         return -1;
 
     burn_credits(rqd, cur, now);
 
     score = new->credit - cur->credit;
-    if ( new->vcpu->processor != cpu )
+    if ( sched_item_cpu(new->item) != cpu )
         score -= CSCHED2_MIGRATE_RESIST;
 
     /*
@@ -1390,21 +1390,21 @@ static s_time_t tickle_score(const struct scheduler 
*ops, s_time_t now,
      */
     if ( score > 0 )
     {
-        if ( cpumask_test_cpu(cpu, new->vcpu->sched_item->cpu_soft_affinity) )
+        if ( cpumask_test_cpu(cpu, new->item->cpu_soft_affinity) )
             score += CSCHED2_CREDIT_INIT;
 
-        if ( !cpumask_test_cpu(cpu, cur->vcpu->sched_item->cpu_soft_affinity) )
+        if ( !cpumask_test_cpu(cpu, cur->item->cpu_soft_affinity) )
             score += CSCHED2_CREDIT_INIT;
     }
 
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             int credit, score;
         } d;
-        d.dom = cur->vcpu->domain->domain_id;
-        d.vcpu = cur->vcpu->vcpu_id;
+        d.dom = cur->item->domain->domain_id;
+        d.item = cur->item->item_id;
         d.credit = cur->credit;
         d.score = score;
         __trace_var(TRC_CSCHED2_TICKLE_CHECK, 1,
@@ -1416,14 +1416,14 @@ static s_time_t tickle_score(const struct scheduler 
*ops, s_time_t now,
 }
 
 /*
- * Check what processor it is best to 'wake', for picking up a vcpu that has
+ * Check what processor it is best to 'wake', for picking up an item that has
  * just been put (back) in the runqueue. Logic is as follows:
  *  1. if there are idle processors in the runq, wake one of them;
- *  2. if there aren't idle processor, check the one were the vcpu was
+ *  2. if there aren't idle processor, check the one were the item was
  *     running before to see if we can preempt what's running there now
  *     (and hence doing just one migration);
- *  3. last stand: check all processors and see if the vcpu is in right
- *     of preempting any of the other vcpus running on them (this requires
+ *  3. last stand: check all processors and see if the item is in right
+ *     of preempting any of the other items running on them (this requires
  *     two migrations, and that's indeed why it is left as the last stand).
  *
  * Note that when we say 'idle processors' what we really mean is (pretty
@@ -1436,10 +1436,10 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
 {
     int i, ipid = -1;
     s_time_t max = 0;
-    struct sched_item *item = new->vcpu->sched_item;
-    unsigned int bs, cpu = new->vcpu->processor;
+    struct sched_item *item = new->item;
+    unsigned int bs, cpu = sched_item_cpu(item);
     struct csched2_runqueue_data *rqd = c2rqd(ops, cpu);
-    cpumask_t *online = cpupool_domain_cpumask(new->vcpu->domain);
+    cpumask_t *online = cpupool_domain_cpumask(item->domain);
     cpumask_t mask;
 
     ASSERT(new->rqd == rqd);
@@ -1447,13 +1447,13 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned processor;
             int credit;
         } d;
-        d.dom = new->vcpu->domain->domain_id;
-        d.vcpu = new->vcpu->vcpu_id;
-        d.processor = new->vcpu->processor;
+        d.dom = item->domain->domain_id;
+        d.item = item->item_id;
+        d.processor = cpu;
         d.credit = new->credit;
         __trace_var(TRC_CSCHED2_TICKLE_NEW, 1,
                     sizeof(d),
@@ -1461,11 +1461,11 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
     }
 
     /*
-     * Exclusive pinning is when a vcpu has hard-affinity with only one
-     * cpu, and there is no other vcpu that has hard-affinity with that
+     * Exclusive pinning is when an item has hard-affinity with only one
+     * cpu, and there is no other item that has hard-affinity with that
      * same cpu. This is infrequent, but if it happens, is for achieving
      * the most possible determinism, and least possible overhead for
-     * the vcpus in question.
+     * the items in question.
      *
      * Try to identify the vast majority of these situations, and deal
      * with them quickly.
@@ -1532,7 +1532,7 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
     /*
      * Note that, if we are here, it means we have done the hard-affinity
      * balancing step of the loop, and hence what we have in cpumask_scratch
-     * is what we put there for last, i.e., new's vcpu_hard_affinity & online
+     * is what we put there for last, i.e., new's item_hard_affinity & online
      * which is exactly what we need for the next part of the function.
      */
 
@@ -1543,7 +1543,7 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
      *
      * For deciding which cpu to tickle, we use tickle_score(), which will
      * factor in both new's soft-affinity, and the soft-affinity of the
-     * vcpu running on each cpu that we consider.
+     * item running on each cpu that we consider.
      */
     cpumask_andnot(&mask, &rqd->active, &rqd->idle);
     cpumask_andnot(&mask, &mask, &rqd->tickled);
@@ -1588,7 +1588,7 @@ runq_tickle(const struct scheduler *ops, struct 
csched2_item *new, s_time_t now)
         return;
     }
 
-    ASSERT(!is_idle_vcpu(curr_on_cpu(ipid)->vcpu));
+    ASSERT(!is_idle_item(curr_on_cpu(ipid)));
     SCHED_STAT_CRANK(tickled_busy_cpu);
  tickle:
     BUG_ON(ipid == -1);
@@ -1623,16 +1623,16 @@ static void reset_credit(const struct scheduler *ops, 
int cpu, s_time_t now,
 
     /*
      * Under normal circumstances, snext->credit should never be less
-     * than -CSCHED2_MIN_TIMER.  However, under some circumstances, a
-     * vcpu with low credits may be allowed to run long enough that
+     * than -CSCHED2_MIN_TIMER.  However, under some circumstances, an
+     * item with low credits may be allowed to run long enough that
      * its credits are actually less than -CSCHED2_CREDIT_INIT.
-     * (Instances have been observed, for example, where a vcpu with
+     * (Instances have been observed, for example, where an item with
      * 200us of credit was allowed to run for 11ms, giving it -10.8ms
      * of credit.  Thus it was still negative even after the reset.)
      *
      * If this is the case for snext, we simply want to keep moving
      * everyone up until it is in the black again.  This fair because
-     * none of the other vcpus want to run at the moment.
+     * none of the other items want to run at the moment.
      *
      * Rather than looping, however, we just calculate a multiplier,
      * avoiding an integer division and multiplication in the common
@@ -1649,16 +1649,16 @@ static void reset_credit(const struct scheduler *ops, 
int cpu, s_time_t now,
         int start_credit;
 
         svc = list_entry(iter, struct csched2_item, rqd_elem);
-        svc_cpu = svc->vcpu->processor;
+        svc_cpu = sched_item_cpu(svc->item);
 
-        ASSERT(!is_idle_vcpu(svc->vcpu));
+        ASSERT(!is_idle_item(svc->item));
         ASSERT(svc->rqd == rqd);
 
         /*
          * If svc is running, it is our responsibility to make sure, here,
          * that the credit it has spent so far get accounted.
          */
-        if ( svc->vcpu == curr_on_cpu(svc_cpu)->vcpu )
+        if ( svc->item == curr_on_cpu(svc_cpu) )
         {
             burn_credits(rqd, svc, now);
             /*
@@ -1689,12 +1689,12 @@ static void reset_credit(const struct scheduler *ops, 
int cpu, s_time_t now,
         if ( unlikely(tb_init_done) )
         {
             struct {
-                unsigned vcpu:16, dom:16;
+                unsigned item:16, dom:16;
                 int credit_start, credit_end;
                 unsigned multiplier;
             } d;
-            d.dom = svc->vcpu->domain->domain_id;
-            d.vcpu = svc->vcpu->vcpu_id;
+            d.dom = svc->item->domain->domain_id;
+            d.item = svc->item->item_id;
             d.credit_start = start_credit;
             d.credit_end = svc->credit;
             d.multiplier = m;
@@ -1714,9 +1714,9 @@ void burn_credits(struct csched2_runqueue_data *rqd,
 {
     s_time_t delta;
 
-    ASSERT(svc == csched2_item(curr_on_cpu(svc->vcpu->processor)));
+    ASSERT(svc == csched2_item(curr_on_cpu(sched_item_cpu(svc->item))));
 
-    if ( unlikely(is_idle_vcpu(svc->vcpu)) )
+    if ( unlikely(is_idle_item(svc->item)) )
     {
         ASSERT(svc->credit == CSCHED2_IDLE_CREDIT);
         return;
@@ -1745,12 +1745,12 @@ void burn_credits(struct csched2_runqueue_data *rqd,
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             int credit, budget;
             int delta;
         } d;
-        d.dom = svc->vcpu->domain->domain_id;
-        d.vcpu = svc->vcpu->vcpu_id;
+        d.dom = svc->item->domain->domain_id;
+        d.item = svc->item->item_id;
         d.credit = svc->credit;
         d.budget = has_cap(svc) ?  svc->budget : INT_MIN;
         d.delta = delta;
@@ -1764,39 +1764,39 @@ void burn_credits(struct csched2_runqueue_data *rqd,
  * Budget-related code.
  */
 
-static void park_vcpu(struct csched2_item *svc)
+static void park_item(struct csched2_item *svc)
 {
-    struct vcpu *v = svc->vcpu;
+    struct sched_item *item = svc->item;
 
     ASSERT(spin_is_locked(&svc->sdom->budget_lock));
 
     /*
-     * It was impossible to find budget for this vCPU, so it has to be
+     * It was impossible to find budget for this item, so it has to be
      * "parked". This implies it is not runnable, so we mark it as such in
-     * its pause_flags. If the vCPU is currently scheduled (which means we
+     * its pause_flags. If the item is currently scheduled (which means we
      * are here after being called from within csched_schedule()), flagging
      * is enough, as we'll choose someone else, and then context_saved()
      * will take care of updating the load properly.
      *
-     * If, OTOH, the vCPU is sitting in the runqueue (which means we are here
+     * If, OTOH, the item is sitting in the runqueue (which means we are here
      * after being called from within runq_candidate()), we must go all the
      * way down to taking it out of there, and updating the load accordingly.
      *
-     * In both cases, we also add it to the list of parked vCPUs of the domain.
+     * In both cases, we also add it to the list of parked items of the domain.
      */
-    __set_bit(_VPF_parked, &v->pause_flags);
-    if ( vcpu_on_runq(svc) )
+    sched_set_pause_flags(item, _VPF_parked);
+    if ( item_on_runq(svc) )
     {
         runq_remove(svc);
         update_load(svc->sdom->dom->cpupool->sched, svc->rqd, svc, -1, NOW());
     }
-    list_add(&svc->parked_elem, &svc->sdom->parked_vcpus);
+    list_add(&svc->parked_elem, &svc->sdom->parked_items);
 }
 
-static bool vcpu_grab_budget(struct csched2_item *svc)
+static bool item_grab_budget(struct csched2_item *svc)
 {
     struct csched2_dom *sdom = svc->sdom;
-    unsigned int cpu = svc->vcpu->processor;
+    unsigned int cpu = sched_item_cpu(svc->item);
 
     ASSERT(spin_is_locked(per_cpu(sched_res, cpu)->schedule_lock));
 
@@ -1808,9 +1808,9 @@ static bool vcpu_grab_budget(struct csched2_item *svc)
 
     /*
      * Here, svc->budget is <= 0 (as, if it was > 0, we'd have taken the if
-     * above!). That basically means the vCPU has overrun a bit --because of
+     * above!). That basically means the item has overrun a bit --because of
      * various reasons-- and we want to take that into account. With the +=,
-     * we are actually subtracting the amount of budget the vCPU has
+     * we are actually subtracting the amount of budget the item has
      * overconsumed, from the total domain budget.
      */
     sdom->budget += svc->budget;
@@ -1831,7 +1831,7 @@ static bool vcpu_grab_budget(struct csched2_item *svc)
     else
     {
         svc->budget = 0;
-        park_vcpu(svc);
+        park_item(svc);
     }
 
     spin_unlock(&sdom->budget_lock);
@@ -1840,10 +1840,10 @@ static bool vcpu_grab_budget(struct csched2_item *svc)
 }
 
 static void
-vcpu_return_budget(struct csched2_item *svc, struct list_head *parked)
+item_return_budget(struct csched2_item *svc, struct list_head *parked)
 {
     struct csched2_dom *sdom = svc->sdom;
-    unsigned int cpu = svc->vcpu->processor;
+    unsigned int cpu = sched_item_cpu(svc->item);
 
     ASSERT(spin_is_locked(per_cpu(sched_res, cpu)->schedule_lock));
     ASSERT(list_empty(parked));
@@ -1852,7 +1852,7 @@ vcpu_return_budget(struct csched2_item *svc, struct 
list_head *parked)
     spin_lock(&sdom->budget_lock);
 
     /*
-     * The vCPU is stopping running (e.g., because it's blocking, or it has
+     * The item is stopping running (e.g., because it's blocking, or it has
      * been preempted). If it hasn't consumed all the budget it got when,
      * starting to run, put that remaining amount back in the domain's budget
      * pool.
@@ -1861,58 +1861,58 @@ vcpu_return_budget(struct csched2_item *svc, struct 
list_head *parked)
     svc->budget = 0;
 
     /*
-     * Making budget available again to the domain means that parked vCPUs
-     * may be unparked and run. They are, if any, in the domain's parked_vcpus
+     * Making budget available again to the domain means that parked items
+     * may be unparked and run. They are, if any, in the domain's parked_items
      * list, so we want to go through that and unpark them (so they can try
      * to get some budget).
      *
      * Touching the list requires the budget_lock, which we hold. Let's
      * therefore put everyone in that list in another, temporary list, which
-     * then the caller will traverse, unparking the vCPUs it finds there.
+     * then the caller will traverse, unparking the items it finds there.
      *
      * In fact, we can't do the actual unparking here, because that requires
-     * taking the runqueue lock of the vCPUs being unparked, and we can't
+     * taking the runqueue lock of the items being unparked, and we can't
      * take any runqueue locks while we hold a budget_lock.
      */
     if ( sdom->budget > 0 )
-        list_splice_init(&sdom->parked_vcpus, parked);
+        list_splice_init(&sdom->parked_items, parked);
 
     spin_unlock(&sdom->budget_lock);
 }
 
 static void
-unpark_parked_vcpus(const struct scheduler *ops, struct list_head *vcpus)
+unpark_parked_items(const struct scheduler *ops, struct list_head *items)
 {
     struct csched2_item *svc, *tmp;
     spinlock_t *lock;
 
-    list_for_each_entry_safe(svc, tmp, vcpus, parked_elem)
+    list_for_each_entry_safe(svc, tmp, items, parked_elem)
     {
         unsigned long flags;
         s_time_t now;
 
-        lock = item_schedule_lock_irqsave(svc->vcpu->sched_item, &flags);
+        lock = item_schedule_lock_irqsave(svc->item, &flags);
 
-        __clear_bit(_VPF_parked, &svc->vcpu->pause_flags);
+        sched_clear_pause_flags(svc->item, _VPF_parked);
         if ( unlikely(svc->flags & CSFLAG_scheduled) )
         {
             /*
              * We end here if a budget replenishment arrived between
              * csched2_schedule() (and, in particular, after a call to
-             * vcpu_grab_budget() that returned false), and
+             * item_grab_budget() that returned false), and
              * context_saved(). By setting __CSFLAG_delayed_runq_add,
-             * we tell context_saved() to put the vCPU back in the
+             * we tell context_saved() to put the item back in the
              * runqueue, from where it will compete with the others
              * for the newly replenished budget.
              */
             ASSERT( svc->rqd != NULL );
-            ASSERT( c2rqd(ops, svc->vcpu->processor) == svc->rqd );
+            ASSERT( c2rqd(ops, sched_item_cpu(svc->item)) == svc->rqd );
             __set_bit(__CSFLAG_delayed_runq_add, &svc->flags);
         }
-        else if ( vcpu_runnable(svc->vcpu) )
+        else if ( item_runnable(svc->item) )
         {
             /*
-             * The vCPU should go back to the runqueue, and compete for
+             * The item should go back to the runqueue, and compete for
              * the newly replenished budget, but only if it is actually
              * runnable (and was therefore offline only because of the
              * lack of budget).
@@ -1924,7 +1924,7 @@ unpark_parked_vcpus(const struct scheduler *ops, struct 
list_head *vcpus)
         }
         list_del_init(&svc->parked_elem);
 
-        item_schedule_unlock_irqrestore(lock, flags, svc->vcpu->sched_item);
+        item_schedule_unlock_irqrestore(lock, flags, svc->item);
     }
 }
 
@@ -1954,7 +1954,7 @@ static void replenish_domain_budget(void* data)
      *
      * Even in cases of overrun or delay, however, we expect that in 99% of
      * cases, doing just one replenishment will be good enough for being able
-     * to unpark the vCPUs that are waiting for some budget.
+     * to unpark the items that are waiting for some budget.
      */
     do_replenish(sdom);
 
@@ -1974,7 +1974,7 @@ static void replenish_domain_budget(void* data)
     }
     /*
      * 2) if we overrun by more than tot_budget, then budget+tot_budget is
-     * still < 0, which means that we can't unpark the vCPUs. Let's bail,
+     * still < 0, which means that we can't unpark the items. Let's bail,
      * and wait for future replenishments.
      */
     if ( unlikely(sdom->budget <= 0) )
@@ -1988,14 +1988,14 @@ static void replenish_domain_budget(void* data)
 
     /*
      * As above, let's prepare the temporary list, out of the domain's
-     * parked_vcpus list, now that we hold the budget_lock. Then, drop such
+     * parked_items list, now that we hold the budget_lock. Then, drop such
      * lock, and pass the list to the unparking function.
      */
-    list_splice_init(&sdom->parked_vcpus, &parked);
+    list_splice_init(&sdom->parked_items, &parked);
 
     spin_unlock_irqrestore(&sdom->budget_lock, flags);
 
-    unpark_parked_vcpus(sdom->dom->cpupool->sched, &parked);
+    unpark_parked_items(sdom->dom->cpupool->sched, &parked);
 
  out:
     set_timer(&sdom->repl_timer, sdom->next_repl);
@@ -2003,37 +2003,36 @@ static void replenish_domain_budget(void* data)
 
 #ifndef NDEBUG
 static inline void
-csched2_vcpu_check(struct vcpu *vc)
+csched2_item_check(struct sched_item *item)
 {
-    struct csched2_item * const svc = csched2_item(vc->sched_item);
+    struct csched2_item * const svc = csched2_item(item);
     struct csched2_dom * const sdom = svc->sdom;
 
-    BUG_ON( svc->vcpu != vc );
-    BUG_ON( sdom != csched2_dom(vc->domain) );
+    BUG_ON( svc->item != item );
+    BUG_ON( sdom != csched2_dom(item->domain) );
     if ( sdom )
     {
-        BUG_ON( is_idle_vcpu(vc) );
-        BUG_ON( sdom->dom != vc->domain );
+        BUG_ON( is_idle_item(item) );
+        BUG_ON( sdom->dom != item->domain );
     }
     else
     {
-        BUG_ON( !is_idle_vcpu(vc) );
+        BUG_ON( !is_idle_item(item) );
     }
     SCHED_STAT_CRANK(item_check);
 }
-#define CSCHED2_VCPU_CHECK(_vc)  (csched2_vcpu_check(_vc))
+#define CSCHED2_ITEM_CHECK(item)  (csched2_item_check(item))
 #else
-#define CSCHED2_VCPU_CHECK(_vc)
+#define CSCHED2_ITEM_CHECK(item)
 #endif
 
 static void *
 csched2_alloc_vdata(const struct scheduler *ops, struct sched_item *item,
                     void *dd)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item *svc;
 
-    /* Allocate per-VCPU info */
+    /* Allocate per-ITEM info */
     svc = xzalloc(struct csched2_item);
     if ( svc == NULL )
         return NULL;
@@ -2042,10 +2041,10 @@ csched2_alloc_vdata(const struct scheduler *ops, struct 
sched_item *item,
     INIT_LIST_HEAD(&svc->runq_elem);
 
     svc->sdom = dd;
-    svc->vcpu = vc;
+    svc->item = item;
     svc->flags = 0U;
 
-    if ( ! is_idle_vcpu(vc) )
+    if ( ! is_idle_item(item) )
     {
         ASSERT(svc->sdom != NULL);
         svc->credit = CSCHED2_CREDIT_INIT;
@@ -2074,19 +2073,18 @@ csched2_alloc_vdata(const struct scheduler *ops, struct 
sched_item *item,
 static void
 csched2_item_sleep(const struct scheduler *ops, struct sched_item *item)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item * const svc = csched2_item(item);
 
-    ASSERT(!is_idle_vcpu(vc));
+    ASSERT(!is_idle_item(item));
     SCHED_STAT_CRANK(item_sleep);
 
-    if ( curr_on_cpu(vc->processor) == item )
+    if ( curr_on_cpu(sched_item_cpu(item)) == item )
     {
-        tickle_cpu(vc->processor, svc->rqd);
+        tickle_cpu(sched_item_cpu(item), svc->rqd);
     }
-    else if ( vcpu_on_runq(svc) )
+    else if ( item_on_runq(svc) )
     {
-        ASSERT(svc->rqd == c2rqd(ops, vc->processor));
+        ASSERT(svc->rqd == c2rqd(ops, sched_item_cpu(item)));
         update_load(ops, svc->rqd, svc, -1, NOW());
         runq_remove(svc);
     }
@@ -2097,14 +2095,13 @@ csched2_item_sleep(const struct scheduler *ops, struct 
sched_item *item)
 static void
 csched2_item_wake(const struct scheduler *ops, struct sched_item *item)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item * const svc = csched2_item(item);
-    unsigned int cpu = vc->processor;
+    unsigned int cpu = sched_item_cpu(item);
     s_time_t now;
 
     ASSERT(spin_is_locked(per_cpu(sched_res, cpu)->schedule_lock));
 
-    ASSERT(!is_idle_vcpu(vc));
+    ASSERT(!is_idle_item(item));
 
     if ( unlikely(curr_on_cpu(cpu) == item) )
     {
@@ -2112,18 +2109,18 @@ csched2_item_wake(const struct scheduler *ops, struct 
sched_item *item)
         goto out;
     }
 
-    if ( unlikely(vcpu_on_runq(svc)) )
+    if ( unlikely(item_on_runq(svc)) )
     {
         SCHED_STAT_CRANK(item_wake_onrunq);
         goto out;
     }
 
-    if ( likely(vcpu_runnable(vc)) )
+    if ( likely(item_runnable(item)) )
         SCHED_STAT_CRANK(item_wake_runnable);
     else
         SCHED_STAT_CRANK(item_wake_not_runnable);
 
-    /* If the context hasn't been saved for this vcpu yet, we can't put it on
+    /* If the context hasn't been saved for this item yet, we can't put it on
      * another runqueue.  Instead, we set a flag so that it will be put on the 
runqueue
      * after the context has been saved. */
     if ( unlikely(svc->flags & CSFLAG_scheduled) )
@@ -2134,15 +2131,15 @@ csched2_item_wake(const struct scheduler *ops, struct 
sched_item *item)
 
     /* Add into the new runqueue if necessary */
     if ( svc->rqd == NULL )
-        runq_assign(ops, vc);
+        runq_assign(ops, item);
     else
-        ASSERT(c2rqd(ops, vc->processor) == svc->rqd );
+        ASSERT(c2rqd(ops, sched_item_cpu(item)) == svc->rqd );
 
     now = NOW();
 
     update_load(ops, svc->rqd, svc, 1, now);
-        
-    /* Put the VCPU on the runq */
+
+    /* Put the ITEM on the runq */
     runq_insert(ops, svc);
     runq_tickle(ops, svc, now);
 
@@ -2155,49 +2152,48 @@ csched2_item_yield(const struct scheduler *ops, struct 
sched_item *item)
 {
     struct csched2_item * const svc = csched2_item(item);
 
-    __set_bit(__CSFLAG_vcpu_yield, &svc->flags);
+    __set_bit(__CSFLAG_item_yield, &svc->flags);
 }
 
 static void
 csched2_context_saved(const struct scheduler *ops, struct sched_item *item)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item * const svc = csched2_item(item);
     spinlock_t *lock = item_schedule_lock_irq(item);
     s_time_t now = NOW();
     LIST_HEAD(were_parked);
 
-    BUG_ON( !is_idle_vcpu(vc) && svc->rqd != c2rqd(ops, vc->processor));
-    ASSERT(is_idle_vcpu(vc) || svc->rqd == c2rqd(ops, vc->processor));
+    BUG_ON( !is_idle_item(item) && svc->rqd != c2rqd(ops, 
sched_item_cpu(item)));
+    ASSERT(is_idle_item(item) || svc->rqd == c2rqd(ops, sched_item_cpu(item)));
 
-    /* This vcpu is now eligible to be put on the runqueue again */
+    /* This item is now eligible to be put on the runqueue again */
     __clear_bit(__CSFLAG_scheduled, &svc->flags);
 
     if ( unlikely(has_cap(svc) && svc->budget > 0) )
-        vcpu_return_budget(svc, &were_parked);
+        item_return_budget(svc, &were_parked);
 
     /* If someone wants it on the runqueue, put it there. */
     /*
      * NB: We can get rid of CSFLAG_scheduled by checking for
-     * vc->is_running and vcpu_on_runq(svc) here.  However,
+     * vc->is_running and item_on_runq(svc) here.  However,
      * since we're accessing the flags cacheline anyway,
      * it seems a bit pointless; especially as we have plenty of
      * bits free.
      */
     if ( __test_and_clear_bit(__CSFLAG_delayed_runq_add, &svc->flags)
-         && likely(vcpu_runnable(vc)) )
+         && likely(item_runnable(item)) )
     {
-        ASSERT(!vcpu_on_runq(svc));
+        ASSERT(!item_on_runq(svc));
 
         runq_insert(ops, svc);
         runq_tickle(ops, svc, now);
     }
-    else if ( !is_idle_vcpu(vc) )
+    else if ( !is_idle_item(item) )
         update_load(ops, svc->rqd, svc, -1, now);
 
     item_schedule_unlock_irq(lock, item);
 
-    unpark_parked_vcpus(ops, &were_parked);
+    unpark_parked_items(ops, &were_parked);
 }
 
 #define MAX_LOAD (STIME_MAX)
@@ -2205,9 +2201,8 @@ static struct sched_resource *
 csched2_res_pick(const struct scheduler *ops, struct sched_item *item)
 {
     struct csched2_private *prv = csched2_priv(ops);
-    struct vcpu *vc = item->vcpu;
     int i, min_rqi = -1, min_s_rqi = -1;
-    unsigned int new_cpu, cpu = vc->processor;
+    unsigned int new_cpu, cpu = sched_item_cpu(item);
     struct csched2_item *svc = csched2_item(item);
     s_time_t min_avgload = MAX_LOAD, min_s_avgload = MAX_LOAD;
     bool has_soft;
@@ -2245,7 +2240,7 @@ csched2_res_pick(const struct scheduler *ops, struct 
sched_item *item)
     }
 
     cpumask_and(cpumask_scratch_cpu(cpu), item->cpu_hard_affinity,
-                cpupool_domain_cpumask(vc->domain));
+                cpupool_domain_cpumask(item->domain));
 
     /*
      * First check to see if we're here because someone else suggested a place
@@ -2356,7 +2351,7 @@ csched2_res_pick(const struct scheduler *ops, struct 
sched_item *item)
          * We have soft affinity, and we have a candidate runq, so go for it.
          *
          * Note that, to obtain the soft-affinity mask, we "just" put what we
-         * have in cpumask_scratch in && with vc->cpu_soft_affinity. This is
+         * have in cpumask_scratch in && with item->cpu_soft_affinity. This is
          * ok because:
          * - we know that item->cpu_hard_affinity and ->cpu_soft_affinity have
          *   a non-empty intersection (because has_soft is true);
@@ -2379,7 +2374,7 @@ csched2_res_pick(const struct scheduler *ops, struct 
sched_item *item)
          * any suitable runq. But we did find one when considering hard
          * affinity, so go for it.
          *
-         * cpumask_scratch already has vc->cpu_hard_affinity &
+         * cpumask_scratch already has item->cpu_hard_affinity &
          * cpupool_domain_cpumask() in it, so it's enough that we filter
          * with the cpus of the runq.
          */
@@ -2410,11 +2405,11 @@ csched2_res_pick(const struct scheduler *ops, struct 
sched_item *item)
     {
         struct {
             uint64_t b_avgload;
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned rq_id:16, new_cpu:16;
         } d;
-        d.dom = vc->domain->domain_id;
-        d.vcpu = vc->vcpu_id;
+        d.dom = item->domain->domain_id;
+        d.item = item->item_id;
         d.rq_id = min_rqi;
         d.b_avgload = min_avgload;
         d.new_cpu = new_cpu;
@@ -2433,10 +2428,10 @@ typedef struct {
     struct csched2_item * best_push_svc, *best_pull_svc;
     /* NB: Read by consider() */
     struct csched2_runqueue_data *lrqd;
-    struct csched2_runqueue_data *orqd;                  
+    struct csched2_runqueue_data *orqd;
 } balance_state_t;
 
-static void consider(balance_state_t *st, 
+static void consider(balance_state_t *st,
                      struct csched2_item *push_svc,
                      struct csched2_item *pull_svc)
 {
@@ -2475,17 +2470,17 @@ static void migrate(const struct scheduler *ops,
                     struct csched2_runqueue_data *trqd,
                     s_time_t now)
 {
-    int cpu = svc->vcpu->processor;
-    struct sched_item *item = svc->vcpu->sched_item;
+    struct sched_item *item = svc->item;
+    int cpu = sched_item_cpu(item);
 
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned rqi:16, trqi:16;
         } d;
-        d.dom = svc->vcpu->domain->domain_id;
-        d.vcpu = svc->vcpu->vcpu_id;
+        d.dom = item->domain->domain_id;
+        d.item = item->item_id;
         d.rqi = svc->rqd->id;
         d.trqi = trqd->id;
         __trace_var(TRC_CSCHED2_MIGRATE, 1,
@@ -2497,7 +2492,7 @@ static void migrate(const struct scheduler *ops,
     {
         /* It's running; mark it to migrate. */
         svc->migrate_rqd = trqd;
-        __set_bit(_VPF_migrating, &svc->vcpu->pause_flags);
+        sched_set_pause_flags(item, _VPF_migrating);
         __set_bit(__CSFLAG_runq_migrate_request, &svc->flags);
         SCHED_STAT_CRANK(migrate_requested);
         tickle_cpu(cpu, svc->rqd);
@@ -2506,7 +2501,7 @@ static void migrate(const struct scheduler *ops,
     {
         int on_runq = 0;
         /* It's not running; just move it */
-        if ( vcpu_on_runq(svc) )
+        if ( item_on_runq(svc) )
         {
             runq_remove(svc);
             update_load(ops, svc->rqd, NULL, -1, now);
@@ -2515,14 +2510,14 @@ static void migrate(const struct scheduler *ops,
         _runq_deassign(svc);
 
         cpumask_and(cpumask_scratch_cpu(cpu), item->cpu_hard_affinity,
-                    cpupool_domain_cpumask(svc->vcpu->domain));
+                    cpupool_domain_cpumask(item->domain));
         cpumask_and(cpumask_scratch_cpu(cpu), cpumask_scratch_cpu(cpu),
                     &trqd->active);
-        svc->vcpu->processor = cpumask_cycle(trqd->pick_bias,
-                                             cpumask_scratch_cpu(cpu));
-        svc->vcpu->sched_item->res = per_cpu(sched_res, svc->vcpu->processor);
-        trqd->pick_bias = svc->vcpu->processor;
-        ASSERT(svc->vcpu->processor < nr_cpu_ids);
+        sched_set_res(item, per_cpu(sched_res,
+                                    cpumask_cycle(trqd->pick_bias,
+                                                  cpumask_scratch_cpu(cpu))));
+        trqd->pick_bias = sched_item_cpu(item);
+        ASSERT(sched_item_cpu(item) < nr_cpu_ids);
 
         _runq_assign(svc, trqd);
         if ( on_runq )
@@ -2542,14 +2537,14 @@ static void migrate(const struct scheduler *ops,
  *  - svc is not already flagged to migrate,
  *  - if svc is allowed to run on at least one of the pcpus of rqd.
  */
-static bool vcpu_is_migrateable(struct csched2_item *svc,
+static bool item_is_migrateable(struct csched2_item *svc,
                                   struct csched2_runqueue_data *rqd)
 {
-    struct vcpu *v = svc->vcpu;
-    int cpu = svc->vcpu->processor;
+    struct sched_item *item = svc->item;
+    int cpu = sched_item_cpu(item);
 
-    cpumask_and(cpumask_scratch_cpu(cpu), v->sched_item->cpu_hard_affinity,
-                cpupool_domain_cpumask(v->domain));
+    cpumask_and(cpumask_scratch_cpu(cpu), item->cpu_hard_affinity,
+                cpupool_domain_cpumask(item->domain));
 
     return !(svc->flags & CSFLAG_runq_migrate_request) &&
            cpumask_intersects(cpumask_scratch_cpu(cpu), &rqd->active);
@@ -2586,7 +2581,7 @@ retry:
     for_each_cpu(i, &prv->active_queues)
     {
         s_time_t delta;
-        
+
         st.orqd = prv->rqd + i;
 
         if ( st.orqd == st.lrqd
@@ -2594,7 +2589,7 @@ retry:
             continue;
 
         update_runq_load(ops, st.orqd, 0, now);
-    
+
         delta = st.lrqd->b_avgload - st.orqd->b_avgload;
         if ( delta < 0 )
             delta = -delta;
@@ -2617,7 +2612,7 @@ retry:
         s_time_t load_max;
         int cpus_max;
 
-        
+
         load_max = st.lrqd->b_avgload;
         if ( st.orqd->b_avgload > load_max )
             load_max = st.orqd->b_avgload;
@@ -2656,7 +2651,7 @@ retry:
                                            opt_overload_balance_tolerance)) )
                 goto out;
     }
-             
+
     /* Try to grab the other runqueue lock; if it's been taken in the
      * meantime, try the process over again.  This can't deadlock
      * because if it doesn't get any other rqd locks, it will simply
@@ -2696,17 +2691,17 @@ retry:
 
         update_svc_load(ops, push_svc, 0, now);
 
-        if ( !vcpu_is_migrateable(push_svc, st.orqd) )
+        if ( !item_is_migrateable(push_svc, st.orqd) )
             continue;
 
         list_for_each( pull_iter, &st.orqd->svc )
         {
             struct csched2_item * pull_svc = list_entry(pull_iter, struct 
csched2_item, rqd_elem);
-            
+
             if ( !inner_load_updated )
                 update_svc_load(ops, pull_svc, 0, now);
-        
-            if ( !vcpu_is_migrateable(pull_svc, st.lrqd) )
+
+            if ( !item_is_migrateable(pull_svc, st.lrqd) )
                 continue;
 
             consider(&st, push_svc, pull_svc);
@@ -2721,8 +2716,8 @@ retry:
     list_for_each( pull_iter, &st.orqd->svc )
     {
         struct csched2_item * pull_svc = list_entry(pull_iter, struct 
csched2_item, rqd_elem);
-        
-        if ( !vcpu_is_migrateable(pull_svc, st.lrqd) )
+
+        if ( !item_is_migrateable(pull_svc, st.lrqd) )
             continue;
 
         /* Consider pull only */
@@ -2745,8 +2740,7 @@ static void
 csched2_item_migrate(
     const struct scheduler *ops, struct sched_item *item, unsigned int new_cpu)
 {
-    struct vcpu *vc = item->vcpu;
-    struct domain *d = vc->domain;
+    struct domain *d = item->domain;
     struct csched2_item * const svc = csched2_item(item);
     struct csched2_runqueue_data *trqd;
     s_time_t now = NOW();
@@ -2758,25 +2752,24 @@ csched2_item_migrate(
      * cpupool.
      *
      * And since there indeed is the chance that it is not part of it, all
-     * we must do is remove _and_ unassign the vCPU from any runqueue, as
+     * we must do is remove _and_ unassign the item from any runqueue, as
      * well as updating v->processor with the target, so that the suspend
      * process can continue.
      *
      * It will then be during resume that a new, meaningful, value for
      * v->processor will be chosen, and during actual domain unpause that
-     * the vCPU will be assigned to and added to the proper runqueue.
+     * the item will be assigned to and added to the proper runqueue.
      */
     if ( unlikely(!cpumask_test_cpu(new_cpu, cpupool_domain_cpumask(d))) )
     {
         ASSERT(system_state == SYS_STATE_suspend);
-        if ( vcpu_on_runq(svc) )
+        if ( item_on_runq(svc) )
         {
             runq_remove(svc);
             update_load(ops, svc->rqd, NULL, -1, now);
         }
         _runq_deassign(svc);
-        vc->processor = new_cpu;
-        item->res = per_cpu(sched_res, new_cpu);
+        sched_set_res(item, per_cpu(sched_res, new_cpu));
         return;
     }
 
@@ -2790,17 +2783,14 @@ csched2_item_migrate(
      * Do the actual movement toward new_cpu, and update vc->processor.
      * If we are changing runqueue, migrate() takes care of everything.
      * If we are not changing runqueue, we need to update vc->processor
-     * here. In fact, if, for instance, we are here because the vcpu's
+     * here. In fact, if, for instance, we are here because the item's
      * hard affinity changed, we don't want to risk leaving vc->processor
      * pointing to a pcpu where we can't run any longer.
      */
     if ( trqd != svc->rqd )
         migrate(ops, svc, trqd, now);
     else
-    {
-        vc->processor = new_cpu;
-        item->res = per_cpu(sched_res, new_cpu);
-    }
+        sched_set_res(item, per_cpu(sched_res, new_cpu));
 }
 
 static int
@@ -2812,18 +2802,18 @@ csched2_dom_cntl(
     struct csched2_dom * const sdom = csched2_dom(d);
     struct csched2_private *prv = csched2_priv(ops);
     unsigned long flags;
-    struct vcpu *v;
+    struct sched_item *item;
     int rc = 0;
 
     /*
      * Locking:
      *  - we must take the private lock for accessing the weights of the
-     *    vcpus of d, and/or the cap;
+     *    items of d, and/or the cap;
      *  - in the putinfo case, we also need the runqueue lock(s), for
      *    updating the max waight of the runqueue(s).
      *    If changing the cap, we also need the budget_lock, for updating
      *    the value of the domain budget pool (and the runqueue lock,
-     *    for adjusting the parameters and rescheduling any vCPU that is
+     *    for adjusting the parameters and rescheduling any item that is
      *    running at the time of the change).
      */
     switch ( op->cmd )
@@ -2845,18 +2835,18 @@ csched2_dom_cntl(
 
             sdom->weight = op->u.credit2.weight;
 
-            /* Update weights for vcpus, and max_weight for runqueues on which 
they reside */
-            for_each_vcpu ( d, v )
+            /* Update weights for items, and max_weight for runqueues on which 
they reside */
+            for_each_sched_item ( d, item )
             {
-                struct csched2_item *svc = csched2_item(v->sched_item);
-                spinlock_t *lock = item_schedule_lock(svc->vcpu->sched_item);
+                struct csched2_item *svc = csched2_item(item);
+                spinlock_t *lock = item_schedule_lock(item);
 
-                ASSERT(svc->rqd == c2rqd(ops, svc->vcpu->processor));
+                ASSERT(svc->rqd == c2rqd(ops, sched_item_cpu(item)));
 
                 svc->weight = sdom->weight;
                 update_max_weight(svc->rqd, svc->weight, old_weight);
 
-                item_schedule_unlock(lock, svc->vcpu->sched_item);
+                item_schedule_unlock(lock, item);
             }
         }
         /* Cap */
@@ -2865,8 +2855,8 @@ csched2_dom_cntl(
             struct csched2_item *svc;
             spinlock_t *lock;
 
-            /* Cap is only valid if it's below 100 * nr_of_vCPUS */
-            if ( op->u.credit2.cap > 100 * sdom->nr_vcpus )
+            /* Cap is only valid if it's below 100 * nr_of_items */
+            if ( op->u.credit2.cap > 100 * sdom->nr_items )
             {
                 rc = -EINVAL;
                 write_unlock_irqrestore(&prv->lock, flags);
@@ -2879,23 +2869,23 @@ csched2_dom_cntl(
             spin_unlock(&sdom->budget_lock);
 
             /*
-             * When trying to get some budget and run, each vCPU will grab
-             * from the pool 1/N (with N = nr of vCPUs of the domain) of
-             * the total budget. Roughly speaking, this means each vCPU will
+             * When trying to get some budget and run, each item will grab
+             * from the pool 1/N (with N = nr of items of the domain) of
+             * the total budget. Roughly speaking, this means each item will
              * have at least one chance to run during every period.
              */
-            for_each_vcpu ( d, v )
+            for_each_sched_item ( d, item )
             {
-                svc = csched2_item(v->sched_item);
-                lock = item_schedule_lock(svc->vcpu->sched_item);
+                svc = csched2_item(item);
+                lock = item_schedule_lock(item);
                 /*
                  * Too small quotas would in theory cause a lot of overhead,
                  * which then won't happen because, in csched2_runtime(),
                  * CSCHED2_MIN_TIMER is what would be used anyway.
                  */
-                svc->budget_quota = max(sdom->tot_budget / sdom->nr_vcpus,
+                svc->budget_quota = max(sdom->tot_budget / sdom->nr_items,
                                         CSCHED2_MIN_TIMER);
-                item_schedule_unlock(lock, svc->vcpu->sched_item);
+                item_schedule_unlock(lock, item);
             }
 
             if ( sdom->cap == 0 )
@@ -2905,7 +2895,7 @@ csched2_dom_cntl(
                  * and queue its first replenishment event.
                  *
                  * Since cap is currently disabled for this domain, we
-                 * know no vCPU is messing with the domain's budget, and
+                 * know no item is messing with the domain's budget, and
                  * the replenishment timer is still off.
                  * For these reasons, it is safe to do the following without
                  * taking the budget_lock.
@@ -2915,42 +2905,42 @@ csched2_dom_cntl(
                 set_timer(&sdom->repl_timer, sdom->next_repl);
 
                 /*
-                 * Now, let's enable budget accounting for all the vCPUs.
+                 * Now, let's enable budget accounting for all the items.
                  * For making sure that they will start to honour the domain's
                  * cap, we set their budget to 0.
                  * This way, as soon as they will try to run, they will have
                  * to get some budget.
                  *
-                 * For the vCPUs that are already running, we trigger the
+                 * For the items that are already running, we trigger the
                  * scheduler on their pCPU. When, as a consequence of this,
                  * csched2_schedule() will run, it will figure out there is
-                 * no budget, and the vCPU will try to get some (and be parked,
+                 * no budget, and the item will try to get some (and be parked,
                  * if there's none, and we'll switch to someone else).
                  */
-                for_each_vcpu ( d, v )
+                for_each_sched_item ( d, item )
                 {
-                    svc = csched2_item(v->sched_item);
-                    lock = item_schedule_lock(svc->vcpu->sched_item);
-                    if ( v->sched_item->is_running )
+                    svc = csched2_item(item);
+                    lock = item_schedule_lock(item);
+                    if ( item->is_running )
                     {
-                        unsigned int cpu = v->processor;
+                        unsigned int cpu = sched_item_cpu(item);
                         struct csched2_runqueue_data *rqd = c2rqd(ops, cpu);
 
-                        ASSERT(curr_on_cpu(cpu)->vcpu == v);
+                        ASSERT(curr_on_cpu(cpu) == item);
 
                         /*
-                         * We are triggering a reschedule on the vCPU's
+                         * We are triggering a reschedule on the item's
                          * pCPU. That will run burn_credits() and, since
-                         * the vCPU is capped now, it would charge all the
+                         * the item is capped now, it would charge all the
                          * execution time of this last round as budget as
-                         * well. That will make the vCPU budget go negative,
+                         * well. That will make the item budget go negative,
                          * potentially by a large amount, and it's unfair.
                          *
                          * To avoid that, call burn_credit() here, to do the
                          * accounting of this current running instance now,
                          * with budgetting still disabled. This does not
                          * prevent some small amount of budget being charged
-                         * to the vCPU (i.e., the amount of time it runs from
+                         * to the item (i.e., the amount of time it runs from
                          * now, to when scheduling happens). The budget will
                          * also go below 0, but a lot less than how it would
                          * if we don't do this.
@@ -2961,7 +2951,7 @@ csched2_dom_cntl(
                         cpu_raise_softirq(cpu, SCHEDULE_SOFTIRQ);
                     }
                     svc->budget = 0;
-                    item_schedule_unlock(lock, svc->vcpu->sched_item);
+                    item_schedule_unlock(lock, item);
                 }
             }
 
@@ -2973,30 +2963,30 @@ csched2_dom_cntl(
 
             stop_timer(&sdom->repl_timer);
 
-            /* Disable budget accounting for all the vCPUs. */
-            for_each_vcpu ( d, v )
+            /* Disable budget accounting for all the items. */
+            for_each_sched_item ( d, item )
             {
-                struct csched2_item *svc = csched2_item(v->sched_item);
-                spinlock_t *lock = item_schedule_lock(svc->vcpu->sched_item);
+                struct csched2_item *svc = csched2_item(item);
+                spinlock_t *lock = item_schedule_lock(item);
 
                 svc->budget = STIME_MAX;
                 svc->budget_quota = 0;
 
-                item_schedule_unlock(lock, svc->vcpu->sched_item);
+                item_schedule_unlock(lock, item);
             }
             sdom->cap = 0;
             /*
              * We are disabling the cap for this domain, which may have
-             * vCPUs waiting for a replenishment, so we unpark them all.
+             * items waiting for a replenishment, so we unpark them all.
              * Note that, since we have already disabled budget accounting
-             * for all the vCPUs of the domain, no currently running vCPU
-             * will be added to the parked vCPUs list any longer.
+             * for all the items of the domain, no currently running item
+             * will be added to the parked items list any longer.
              */
             spin_lock(&sdom->budget_lock);
-            list_splice_init(&sdom->parked_vcpus, &parked);
+            list_splice_init(&sdom->parked_items, &parked);
             spin_unlock(&sdom->budget_lock);
 
-            unpark_parked_vcpus(ops, &parked);
+            unpark_parked_items(ops, &parked);
         }
         write_unlock_irqrestore(&prv->lock, flags);
         break;
@@ -3073,12 +3063,12 @@ csched2_alloc_domdata(const struct scheduler *ops, 
struct domain *dom)
     sdom->dom = dom;
     sdom->weight = CSCHED2_DEFAULT_WEIGHT;
     sdom->cap = 0U;
-    sdom->nr_vcpus = 0;
+    sdom->nr_items = 0;
 
     init_timer(&sdom->repl_timer, replenish_domain_budget, sdom,
                cpumask_any(cpupool_domain_cpumask(dom)));
     spin_lock_init(&sdom->budget_lock);
-    INIT_LIST_HEAD(&sdom->parked_vcpus);
+    INIT_LIST_HEAD(&sdom->parked_items);
 
     write_lock_irqsave(&prv->lock, flags);
 
@@ -3112,34 +3102,32 @@ csched2_free_domdata(const struct scheduler *ops, void 
*data)
 static void
 csched2_item_insert(const struct scheduler *ops, struct sched_item *item)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item *svc = item->priv;
     struct csched2_dom * const sdom = svc->sdom;
     spinlock_t *lock;
 
-    ASSERT(!is_idle_vcpu(vc));
+    ASSERT(!is_idle_item(item));
     ASSERT(list_empty(&svc->runq_elem));
 
     /* csched2_res_pick() expects the pcpu lock to be held */
     lock = item_schedule_lock_irq(item);
 
-    item->res = csched2_res_pick(ops, item);
-    vc->processor = item->res->processor;
+    sched_set_res(item, csched2_res_pick(ops, item));
 
     spin_unlock_irq(lock);
 
     lock = item_schedule_lock_irq(item);
 
-    /* Add vcpu to runqueue of initial processor */
-    runq_assign(ops, vc);
+    /* Add item to runqueue of initial processor */
+    runq_assign(ops, item);
 
     item_schedule_unlock_irq(lock, item);
 
-    sdom->nr_vcpus++;
+    sdom->nr_items++;
 
     SCHED_STAT_CRANK(item_insert);
 
-    CSCHED2_VCPU_CHECK(vc);
+    CSCHED2_ITEM_CHECK(item);
 }
 
 static void
@@ -3153,11 +3141,10 @@ csched2_free_vdata(const struct scheduler *ops, void 
*priv)
 static void
 csched2_item_remove(const struct scheduler *ops, struct sched_item *item)
 {
-    struct vcpu *vc = item->vcpu;
     struct csched2_item * const svc = csched2_item(item);
     spinlock_t *lock;
 
-    ASSERT(!is_idle_vcpu(vc));
+    ASSERT(!is_idle_item(item));
     ASSERT(list_empty(&svc->runq_elem));
 
     SCHED_STAT_CRANK(item_remove);
@@ -3165,14 +3152,14 @@ csched2_item_remove(const struct scheduler *ops, struct 
sched_item *item)
     /* Remove from runqueue */
     lock = item_schedule_lock_irq(item);
 
-    runq_deassign(ops, vc);
+    runq_deassign(ops, item);
 
     item_schedule_unlock_irq(lock, item);
 
-    svc->sdom->nr_vcpus--;
+    svc->sdom->nr_items--;
 }
 
-/* How long should we let this vcpu run for? */
+/* How long should we let this item run for? */
 static s_time_t
 csched2_runtime(const struct scheduler *ops, int cpu,
                 struct csched2_item *snext, s_time_t now)
@@ -3187,7 +3174,7 @@ csched2_runtime(const struct scheduler *ops, int cpu,
      * If we're idle, just stay so. Others (or external events)
      * will poke us when necessary.
      */
-    if ( is_idle_vcpu(snext->vcpu) )
+    if ( is_idle_item(snext->item) )
         return -1;
 
     /* General algorithm:
@@ -3204,8 +3191,8 @@ csched2_runtime(const struct scheduler *ops, int cpu,
     if ( prv->ratelimit_us )
     {
         s_time_t ratelimit_min = MICROSECS(prv->ratelimit_us);
-        if ( snext->vcpu->sched_item->is_running )
-            ratelimit_min = snext->vcpu->sched_item->state_entry_time +
+        if ( snext->item->is_running )
+            ratelimit_min = snext->item->state_entry_time +
                             MICROSECS(prv->ratelimit_us) - now;
         if ( ratelimit_min > min_time )
             min_time = ratelimit_min;
@@ -3222,7 +3209,7 @@ csched2_runtime(const struct scheduler *ops, int cpu,
     {
         struct csched2_item *swait = runq_elem(runq->next);
 
-        if ( ! is_idle_vcpu(swait->vcpu)
+        if ( ! is_idle_item(swait->item)
              && swait->credit > 0 )
         {
             rt_credit = snext->credit - swait->credit;
@@ -3236,7 +3223,7 @@ csched2_runtime(const struct scheduler *ops, int cpu,
      *
      * FIXME: See if we can eliminate this conversion if we know time
      * will be outside (MIN,MAX).  Probably requires pre-calculating
-     * credit values of MIN,MAX per vcpu, since each vcpu burns credit
+     * credit values of MIN,MAX per item, since each item burns credit
      * at a different rate.
      */
     if ( rt_credit > 0 )
@@ -3284,36 +3271,35 @@ runq_candidate(struct csched2_runqueue_data *rqd,
 
     *skipped = 0;
 
-    if ( unlikely(is_idle_vcpu(scurr->vcpu)) )
+    if ( unlikely(is_idle_item(scurr->item)) )
     {
         snext = scurr;
         goto check_runq;
     }
 
-    yield = __test_and_clear_bit(__CSFLAG_vcpu_yield, &scurr->flags);
+    yield = __test_and_clear_bit(__CSFLAG_item_yield, &scurr->flags);
 
     /*
-     * Return the current vcpu if it has executed for less than ratelimit.
-     * Adjuststment for the selected vcpu's credit and decision
+     * Return the current item if it has executed for less than ratelimit.
+     * Adjuststment for the selected item's credit and decision
      * for how long it will run will be taken in csched2_runtime.
      *
      * Note that, if scurr is yielding, we don't let rate limiting kick in.
      * In fact, it may be the case that scurr is about to spin, and there's
      * no point forcing it to do so until rate limiting expires.
      */
-    if ( !yield && prv->ratelimit_us && vcpu_runnable(scurr->vcpu) &&
-         (now - scurr->vcpu->sched_item->state_entry_time) <
-          MICROSECS(prv->ratelimit_us) )
+    if ( !yield && prv->ratelimit_us && item_runnable(scurr->item) &&
+         (now - scurr->item->state_entry_time) < MICROSECS(prv->ratelimit_us) )
     {
         if ( unlikely(tb_init_done) )
         {
             struct {
-                unsigned vcpu:16, dom:16;
+                unsigned item:16, dom:16;
                 unsigned runtime;
             } d;
-            d.dom = scurr->vcpu->domain->domain_id;
-            d.vcpu = scurr->vcpu->vcpu_id;
-            d.runtime = now - scurr->vcpu->sched_item->state_entry_time;
+            d.dom = scurr->item->domain->domain_id;
+            d.item = scurr->item->item_id;
+            d.runtime = now - scurr->item->state_entry_time;
             __trace_var(TRC_CSCHED2_RATELIMIT, 1,
                         sizeof(d),
                         (unsigned char *)&d);
@@ -3322,13 +3308,13 @@ runq_candidate(struct csched2_runqueue_data *rqd,
     }
 
     /* If scurr has a soft-affinity, let's check whether cpu is part of it */
-    if ( has_soft_affinity(scurr->vcpu->sched_item) )
+    if ( has_soft_affinity(scurr->item) )
     {
-        affinity_balance_cpumask(scurr->vcpu->sched_item, 
BALANCE_SOFT_AFFINITY,
+        affinity_balance_cpumask(scurr->item, BALANCE_SOFT_AFFINITY,
                                  cpumask_scratch);
         if ( unlikely(!cpumask_test_cpu(cpu, cpumask_scratch)) )
         {
-            cpumask_t *online = cpupool_domain_cpumask(scurr->vcpu->domain);
+            cpumask_t *online = cpupool_domain_cpumask(scurr->item->domain);
 
             /* Ok, is any of the pcpus in scurr soft-affinity idle? */
             cpumask_and(cpumask_scratch, cpumask_scratch, &rqd->idle);
@@ -3356,10 +3342,10 @@ runq_candidate(struct csched2_runqueue_data *rqd,
      *
      * Of course, we also default to idle also if scurr is not runnable.
      */
-    if ( vcpu_runnable(scurr->vcpu) && !soft_aff_preempt )
+    if ( item_runnable(scurr->item) && !soft_aff_preempt )
         snext = scurr;
     else
-        snext = csched2_item(idle_vcpu[cpu]->sched_item);
+        snext = csched2_item(sched_idle_item(cpu));
 
  check_runq:
     list_for_each_safe( iter, temp, &rqd->runq )
@@ -3369,24 +3355,24 @@ runq_candidate(struct csched2_runqueue_data *rqd,
         if ( unlikely(tb_init_done) )
         {
             struct {
-                unsigned vcpu:16, dom:16;
+                unsigned item:16, dom:16;
             } d;
-            d.dom = svc->vcpu->domain->domain_id;
-            d.vcpu = svc->vcpu->vcpu_id;
+            d.dom = svc->item->domain->domain_id;
+            d.item = svc->item->item_id;
             __trace_var(TRC_CSCHED2_RUNQ_CAND_CHECK, 1,
                         sizeof(d),
                         (unsigned char *)&d);
         }
 
-        /* Only consider vcpus that are allowed to run on this processor. */
-        if ( !cpumask_test_cpu(cpu, svc->vcpu->sched_item->cpu_hard_affinity) )
+        /* Only consider items that are allowed to run on this processor. */
+        if ( !cpumask_test_cpu(cpu, svc->item->cpu_hard_affinity) )
         {
             (*skipped)++;
             continue;
         }
 
         /*
-         * If a vcpu is meant to be picked up by another processor, and such
+         * If an item is meant to be picked up by another processor, and such
          * processor has not scheduled yet, leave it in the runqueue for him.
          */
         if ( svc->tickled_cpu != -1 && svc->tickled_cpu != cpu &&
@@ -3401,7 +3387,7 @@ runq_candidate(struct csched2_runqueue_data *rqd,
          * If this is on a different processor, don't pull it unless
          * its credit is at least CSCHED2_MIGRATE_RESIST higher.
          */
-        if ( svc->vcpu->processor != cpu
+        if ( sched_item_cpu(svc->item) != cpu
              && snext->credit + CSCHED2_MIGRATE_RESIST > svc->credit )
         {
             (*skipped)++;
@@ -3416,7 +3402,7 @@ runq_candidate(struct csched2_runqueue_data *rqd,
          * some budget, then choose it.
          */
         if ( (yield || svc->credit > snext->credit) &&
-             (!has_cap(svc) || vcpu_grab_budget(svc)) )
+             (!has_cap(svc) || item_grab_budget(svc)) )
             snext = svc;
 
         /* In any case, if we got this far, break. */
@@ -3426,12 +3412,12 @@ runq_candidate(struct csched2_runqueue_data *rqd,
     if ( unlikely(tb_init_done) )
     {
         struct {
-            unsigned vcpu:16, dom:16;
+            unsigned item:16, dom:16;
             unsigned tickled_cpu, skipped;
             int credit;
         } d;
-        d.dom = snext->vcpu->domain->domain_id;
-        d.vcpu = snext->vcpu->vcpu_id;
+        d.dom = snext->item->domain->domain_id;
+        d.item = snext->item->item_id;
         d.credit = snext->credit;
         d.tickled_cpu = snext->tickled_cpu;
         d.skipped = *skipped;
@@ -3463,14 +3449,15 @@ csched2_schedule(
 {
     const int cpu = smp_processor_id();
     struct csched2_runqueue_data *rqd;
-    struct csched2_item * const scurr = csched2_item(current->sched_item);
+    struct sched_item *curritem = current->sched_item;
+    struct csched2_item * const scurr = csched2_item(curritem);
     struct csched2_item *snext = NULL;
-    unsigned int skipped_vcpus = 0;
+    unsigned int skipped_items = 0;
     struct task_slice ret;
     bool tickled;
 
     SCHED_STAT_CRANK(schedule);
-    CSCHED2_VCPU_CHECK(current);
+    CSCHED2_ITEM_CHECK(curritem);
 
     BUG_ON(!cpumask_test_cpu(cpu, &csched2_priv(ops)->initialized));
 
@@ -3479,7 +3466,7 @@ csched2_schedule(
 
     ASSERT(spin_is_locked(per_cpu(sched_res, cpu)->schedule_lock));
 
-    BUG_ON(!is_idle_vcpu(scurr->vcpu) && scurr->rqd != rqd);
+    BUG_ON(!is_idle_item(curritem) && scurr->rqd != rqd);
 
     /* Clear "tickled" bit now that we've been scheduled */
     tickled = cpumask_test_cpu(cpu, &rqd->tickled);
@@ -3499,7 +3486,7 @@ csched2_schedule(
         d.cpu = cpu;
         d.rq_id = c2r(cpu);
         d.tasklet = tasklet_work_scheduled;
-        d.idle = is_idle_vcpu(current);
+        d.idle = is_idle_item(curritem);
         d.smt_idle = cpumask_test_cpu(cpu, &rqd->smt_idle);
         d.tickled = tickled;
         __trace_var(TRC_CSCHED2_SCHEDULE, 1,
@@ -3513,55 +3500,55 @@ csched2_schedule(
     /*
      *  Below 0, means that we are capped and we have overrun our  budget.
      *  Let's try to get some more but, if we fail (e.g., because of the
-     *  other running vcpus), we will be parked.
+     *  other running items), we will be parked.
      */
     if ( unlikely(scurr->budget <= 0) )
-        vcpu_grab_budget(scurr);
+        item_grab_budget(scurr);
 
     /*
-     * Select next runnable local VCPU (ie top of local runq).
+     * Select next runnable local ITEM (ie top of local runq).
      *
-     * If the current vcpu is runnable, and has higher credit than
+     * If the current item is runnable, and has higher credit than
      * the next guy on the queue (or there is noone else), we want to
      * run him again.
      *
-     * If there's tasklet work to do, we want to chose the idle vcpu
+     * If there's tasklet work to do, we want to chose the idle item
      * for this processor, and mark the current for delayed runqueue
      * add.
      *
-     * If the current vcpu is runnable, and there's another runnable
+     * If the current item is runnable, and there's another runnable
      * candidate, we want to mark current for delayed runqueue add,
      * and remove the next guy from the queue.
      *
-     * If the current vcpu is not runnable, we want to chose the idle
-     * vcpu for this processor.
+     * If the current item is not runnable, we want to chose the idle
+     * item for this processor.
      */
     if ( tasklet_work_scheduled )
     {
-        __clear_bit(__CSFLAG_vcpu_yield, &scurr->flags);
+        __clear_bit(__CSFLAG_item_yield, &scurr->flags);
         trace_var(TRC_CSCHED2_SCHED_TASKLET, 1, 0, NULL);
-        snext = csched2_item(idle_vcpu[cpu]->sched_item);
+        snext = csched2_item(sched_idle_item(cpu));
     }
     else
-        snext = runq_candidate(rqd, scurr, cpu, now, &skipped_vcpus);
+        snext = runq_candidate(rqd, scurr, cpu, now, &skipped_items);
 
-    /* If switching from a non-idle runnable vcpu, put it
+    /* If switching from a non-idle runnable item, put it
      * back on the runqueue. */
     if ( snext != scurr
-         && !is_idle_vcpu(scurr->vcpu)
-         && vcpu_runnable(current) )
+         && !is_idle_item(curritem)
+         && item_runnable(curritem) )
         __set_bit(__CSFLAG_delayed_runq_add, &scurr->flags);
 
     ret.migrated = 0;
 
     /* Accounting for non-idle tasks */
-    if ( !is_idle_vcpu(snext->vcpu) )
+    if ( !is_idle_item(snext->item) )
     {
         /* If switching, remove this from the runqueue and mark it scheduled */
         if ( snext != scurr )
         {
             ASSERT(snext->rqd == rqd);
-            ASSERT(!snext->vcpu->sched_item->is_running);
+            ASSERT(!snext->item->is_running);
 
             runq_remove(snext);
             __set_bit(__CSFLAG_scheduled, &snext->flags);
@@ -3576,19 +3563,19 @@ csched2_schedule(
 
         /*
          * The reset condition is "has a scheduler epoch come to an end?".
-         * The way this is enforced is checking whether the vcpu at the top
+         * The way this is enforced is checking whether the item at the top
          * of the runqueue has negative credits. This means the epochs have
          * variable length, as in one epoch expores when:
-         *  1) the vcpu at the top of the runqueue has executed for
+         *  1) the item at the top of the runqueue has executed for
          *     around 10 ms (with default parameters);
-         *  2) no other vcpu with higher credits wants to run.
+         *  2) no other item with higher credits wants to run.
          *
          * Here, where we want to check for reset, we need to make sure the
-         * proper vcpu is being used. In fact, runqueue_candidate() may have
-         * not returned the first vcpu in the runqueue, for various reasons
+         * proper item is being used. In fact, runqueue_candidate() may have
+         * not returned the first item in the runqueue, for various reasons
          * (e.g., affinity). Only trigger a reset when it does.
          */
-        if ( skipped_vcpus == 0 && snext->credit <= CSCHED2_CREDIT_RESET )
+        if ( skipped_items == 0 && snext->credit <= CSCHED2_CREDIT_RESET )
         {
             reset_credit(ops, cpu, now, snext);
             balance_load(ops, cpu, now);
@@ -3598,11 +3585,10 @@ csched2_schedule(
         snext->tickled_cpu = -1;
 
         /* Safe because lock for old processor is held */
-        if ( snext->vcpu->processor != cpu )
+        if ( sched_item_cpu(snext->item) != cpu )
         {
             snext->credit += CSCHED2_MIGRATE_COMPENSATION;
-            snext->vcpu->processor = cpu;
-            snext->vcpu->sched_item->res = per_cpu(sched_res, cpu);
+            sched_set_res(snext->item, per_cpu(sched_res, cpu));
             SCHED_STAT_CRANK(migrated);
             ret.migrated = 1;
         }
@@ -3636,20 +3622,20 @@ csched2_schedule(
      * Return task to run next...
      */
     ret.time = csched2_runtime(ops, cpu, snext, now);
-    ret.task = snext->vcpu->sched_item;
+    ret.task = snext->item;
 
-    CSCHED2_VCPU_CHECK(ret.task->vcpu);
+    CSCHED2_ITEM_CHECK(ret.task);
     return ret;
 }
 
 static void
-csched2_dump_vcpu(struct csched2_private *prv, struct csched2_item *svc)
+csched2_dump_item(struct csched2_private *prv, struct csched2_item *svc)
 {
     printk("[%i.%i] flags=%x cpu=%i",
-            svc->vcpu->domain->domain_id,
-            svc->vcpu->vcpu_id,
+            svc->item->domain->domain_id,
+            svc->item->item_id,
             svc->flags,
-            svc->vcpu->processor);
+            sched_item_cpu(svc->item));
 
     printk(" credit=%" PRIi32" [w=%u]", svc->credit, svc->weight);
 
@@ -3674,12 +3660,12 @@ dump_pcpu(const struct scheduler *ops, int cpu)
            nr_cpu_ids, cpumask_bits(per_cpu(cpu_sibling_mask, cpu)),
            nr_cpu_ids, cpumask_bits(per_cpu(cpu_core_mask, cpu)));
 
-    /* current VCPU (nothing to say if that's the idle vcpu) */
+    /* current ITEM (nothing to say if that's the idle item) */
     svc = csched2_item(curr_on_cpu(cpu));
-    if ( svc && !is_idle_vcpu(svc->vcpu) )
+    if ( svc && !is_idle_item(svc->item) )
     {
         printk("\trun: ");
-        csched2_dump_vcpu(prv, svc);
+        csched2_dump_item(prv, svc);
     }
 }
 
@@ -3736,7 +3722,7 @@ csched2_dump(const struct scheduler *ops)
     list_for_each( iter_sdom, &prv->sdom )
     {
         struct csched2_dom *sdom;
-        struct vcpu *v;
+        struct sched_item *item;
 
         sdom = list_entry(iter_sdom, struct csched2_dom, sdom_elem);
 
@@ -3744,19 +3730,19 @@ csched2_dump(const struct scheduler *ops)
                sdom->dom->domain_id,
                sdom->weight,
                sdom->cap,
-               sdom->nr_vcpus);
+               sdom->nr_items);
 
-        for_each_vcpu( sdom->dom, v )
+        for_each_sched_item( sdom->dom, item )
         {
-            struct csched2_item * const svc = csched2_item(v->sched_item);
+            struct csched2_item * const svc = csched2_item(item);
             spinlock_t *lock;
 
-            lock = item_schedule_lock(svc->vcpu->sched_item);
+            lock = item_schedule_lock(item);
 
             printk("\t%3d: ", ++loop);
-            csched2_dump_vcpu(prv, svc);
+            csched2_dump_item(prv, svc);
 
-            item_schedule_unlock(lock, svc->vcpu->sched_item);
+            item_schedule_unlock(lock, item);
         }
     }
 
@@ -3782,7 +3768,7 @@ csched2_dump(const struct scheduler *ops)
             if ( svc )
             {
                 printk("\t%3d: ", loop++);
-                csched2_dump_vcpu(prv, svc);
+                csched2_dump_item(prv, svc);
             }
         }
         spin_unlock(&rqd->lock);
@@ -3882,7 +3868,7 @@ csched2_switch_sched(struct scheduler *new_ops, unsigned 
int cpu,
     struct csched2_item *svc = vdata;
     unsigned rqi;
 
-    ASSERT(pdata && svc && is_idle_vcpu(svc->vcpu));
+    ASSERT(pdata && svc && is_idle_item(svc->item));
 
     /*
      * We own one runqueue lock already (from schedule_cpu_switch()). This
@@ -3895,7 +3881,7 @@ csched2_switch_sched(struct scheduler *new_ops, unsigned 
int cpu,
     ASSERT(!local_irq_is_enabled());
     write_lock(&prv->lock);
 
-    idle_vcpu[cpu]->sched_item->priv = vdata;
+    sched_idle_item(cpu)->priv = vdata;
 
     rqi = init_pdata(prv, pdata, cpu);
 
@@ -3946,7 +3932,7 @@ csched2_deinit_pdata(const struct scheduler *ops, void 
*pcpu, int cpu)
      */
     ASSERT(spc && spc->runq_id != -1);
     ASSERT(cpumask_test_cpu(cpu, &prv->initialized));
-    
+
     /* Find the old runqueue and remove this cpu from it */
     rqd = prv->rqd + spc->runq_id;
 
-- 
2.16.4


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