Library rt.restructuring.behavior.facts.arrivals
From rt.restructuring.behavior Require Export arrival_sequence schedule.
From rt.util Require Import all.
(* In this section, we relate job readiness to [has_arrived]. *)
Section Arrived.
(* Consider any kinds of jobs and any kind of processor state. *)
Context {Job : JobType} {PState : Type}.
Context `{ProcessorState Job PState}.
(* Consider any schedule... *)
Variable sched : schedule PState.
(* ...and suppose that jobs have a cost, an arrival time, and a notion of
readiness. *)
Context `{JobCost Job}.
Context `{JobArrival Job}.
Context `{JobReady Job PState}.
(* We observe that a given job must have arrived to be ready... *)
Lemma ready_implies_arrived:
∀ j t, job_ready sched j t → has_arrived j t.
Proof.
move⇒ j t READY.
move: (any_ready_job_is_pending sched j t READY).
by rewrite /pending ⇒ /andP [ARR _].
Qed.
(* ...and lift this observation also to the level of whole schedules. *)
Lemma jobs_must_arrive_to_be_ready:
jobs_must_be_ready_to_execute sched →
jobs_must_arrive_to_execute sched.
Proof.
rewrite /jobs_must_be_ready_to_execute /jobs_must_arrive_to_execute.
move⇒ READY_IF_SCHED j t SCHED.
move: (READY_IF_SCHED j t SCHED) ⇒ READY.
by apply ready_implies_arrived.
Qed.
End Arrived.
(* In this section, we establish useful facts about arrival sequence prefixes. *)
Section ArrivalSequencePrefix.
(* Assume that job arrival times are known. *)
Context {Job: JobType}.
Context `{JobArrival Job}.
(* Consider any job arrival sequence. *)
Variable arr_seq: arrival_sequence Job.
(* In this section, we prove some lemmas about arrival sequence prefixes. *)
Section Lemmas.
(* We begin with basic lemmas for manipulating the sequences. *)
Section Composition.
(* First, we show that the set of arriving jobs can be split
into disjoint intervals. *)
Lemma arrivals_between_cat:
∀ t1 t t2,
t1 ≤ t →
t ≤ t2 →
arrivals_between arr_seq t1 t2 = arrivals_between arr_seq t1 t ++ arrivals_between arr_seq t t2.
Proof.
unfold arrivals_between; intros t1 t t2 GE LE.
by rewrite (@big_cat_nat _ _ _ t).
Qed.
(* Second, the same observation applies to membership in the set of
arrived jobs. *)
Lemma arrivals_between_mem_cat:
∀ j t1 t t2,
t1 ≤ t →
t ≤ t2 →
j \in arrivals_between arr_seq t1 t2 =
(j \in arrivals_between arr_seq t1 t ++ arrivals_between arr_seq t t2).
Proof.
by intros j t1 t t2 GE LE; rewrite (arrivals_between_cat _ t).
Qed.
(* Third, we observe that we can grow the considered interval without
"losing" any arrived jobs, i.e., membership in the set of arrived jobs
is monotonic. *)
Lemma arrivals_between_sub:
∀ j t1 t1' t2 t2',
t1' ≤ t1 →
t2 ≤ t2' →
j \in arrivals_between arr_seq t1 t2 →
j \in arrivals_between arr_seq t1' t2'.
Proof.
intros j t1 t1' t2 t2' GE1 LE2 IN.
move: (leq_total t1 t2) ⇒ /orP [BEFORE | AFTER];
last by rewrite /arrivals_between big_geq // in IN.
rewrite /arrivals_between.
rewrite → big_cat_nat with (n := t1); [simpl | by done | by apply: (leq_trans BEFORE)].
rewrite mem_cat; apply/orP; right.
rewrite → big_cat_nat with (n := t2); [simpl | by done | by done].
by rewrite mem_cat; apply/orP; left.
Qed.
End Composition.
(* Next, we relate the arrival prefixes with job arrival times. *)
Section ArrivalTimes.
(* Assume that job arrival times are consistent. *)
Hypothesis H_consistent_arrival_times:
consistent_arrival_times arr_seq.
(* First, we prove that if a job belongs to the prefix
(jobs_arrived_before t), then it arrives in the arrival sequence. *)
Lemma in_arrivals_implies_arrived:
∀ j t1 t2,
j \in arrivals_between arr_seq t1 t2 →
arrives_in arr_seq j.
Proof.
rename H_consistent_arrival_times into CONS.
intros j t1 t2 IN.
apply mem_bigcat_nat_exists in IN.
move: IN ⇒ [arr [IN _]].
by ∃ arr.
Qed.
(* Next, we prove that if a job belongs to the prefix
(jobs_arrived_between t1 t2), then it indeed arrives between t1 and
t2. *)
Lemma in_arrivals_implies_arrived_between:
∀ j t1 t2,
j \in arrivals_between arr_seq t1 t2 →
arrived_between j t1 t2.
Proof.
rename H_consistent_arrival_times into CONS.
intros j t1 t2 IN.
apply mem_bigcat_nat_exists in IN.
move: IN ⇒ [t0 [IN /= LT]].
by apply CONS in IN; rewrite /arrived_between IN.
Qed.
(* Similarly, if a job belongs to the prefix (jobs_arrived_before t),
then it indeed arrives before time t. *)
Lemma in_arrivals_implies_arrived_before:
∀ j t,
j \in arrivals_before arr_seq t →
arrived_before j t.
Proof.
intros j t IN.
have: arrived_between j 0 t by apply in_arrivals_implies_arrived_between.
by rewrite /arrived_between /=.
Qed.
(* Similarly, we prove that if a job from the arrival sequence arrives
before t, then it belongs to the sequence (jobs_arrived_before t). *)
Lemma arrived_between_implies_in_arrivals:
∀ j t1 t2,
arrives_in arr_seq j →
arrived_between j t1 t2 →
j \in arrivals_between arr_seq t1 t2.
Proof.
rename H_consistent_arrival_times into CONS.
move ⇒ j t1 t2 [a_j ARRj] BEFORE.
have SAME := ARRj; apply CONS in SAME; subst a_j.
by apply mem_bigcat_nat with (j := (job_arrival j)).
Qed.
(* Next, we prove that if the arrival sequence doesn't contain duplicate
jobs, the same applies for any of its prefixes. *)
Lemma arrivals_uniq :
arrival_sequence_uniq arr_seq →
∀ t1 t2, uniq (arrivals_between arr_seq t1 t2).
Proof.
rename H_consistent_arrival_times into CONS.
unfold arrivals_up_to; intros SET t1 t2.
apply bigcat_nat_uniq; first by done.
intros x t t' IN1 IN2.
by apply CONS in IN1; apply CONS in IN2; subst.
Qed.
End ArrivalTimes.
End Lemmas.
End ArrivalSequencePrefix.
From rt.util Require Import all.
(* In this section, we relate job readiness to [has_arrived]. *)
Section Arrived.
(* Consider any kinds of jobs and any kind of processor state. *)
Context {Job : JobType} {PState : Type}.
Context `{ProcessorState Job PState}.
(* Consider any schedule... *)
Variable sched : schedule PState.
(* ...and suppose that jobs have a cost, an arrival time, and a notion of
readiness. *)
Context `{JobCost Job}.
Context `{JobArrival Job}.
Context `{JobReady Job PState}.
(* We observe that a given job must have arrived to be ready... *)
Lemma ready_implies_arrived:
∀ j t, job_ready sched j t → has_arrived j t.
Proof.
move⇒ j t READY.
move: (any_ready_job_is_pending sched j t READY).
by rewrite /pending ⇒ /andP [ARR _].
Qed.
(* ...and lift this observation also to the level of whole schedules. *)
Lemma jobs_must_arrive_to_be_ready:
jobs_must_be_ready_to_execute sched →
jobs_must_arrive_to_execute sched.
Proof.
rewrite /jobs_must_be_ready_to_execute /jobs_must_arrive_to_execute.
move⇒ READY_IF_SCHED j t SCHED.
move: (READY_IF_SCHED j t SCHED) ⇒ READY.
by apply ready_implies_arrived.
Qed.
End Arrived.
(* In this section, we establish useful facts about arrival sequence prefixes. *)
Section ArrivalSequencePrefix.
(* Assume that job arrival times are known. *)
Context {Job: JobType}.
Context `{JobArrival Job}.
(* Consider any job arrival sequence. *)
Variable arr_seq: arrival_sequence Job.
(* In this section, we prove some lemmas about arrival sequence prefixes. *)
Section Lemmas.
(* We begin with basic lemmas for manipulating the sequences. *)
Section Composition.
(* First, we show that the set of arriving jobs can be split
into disjoint intervals. *)
Lemma arrivals_between_cat:
∀ t1 t t2,
t1 ≤ t →
t ≤ t2 →
arrivals_between arr_seq t1 t2 = arrivals_between arr_seq t1 t ++ arrivals_between arr_seq t t2.
Proof.
unfold arrivals_between; intros t1 t t2 GE LE.
by rewrite (@big_cat_nat _ _ _ t).
Qed.
(* Second, the same observation applies to membership in the set of
arrived jobs. *)
Lemma arrivals_between_mem_cat:
∀ j t1 t t2,
t1 ≤ t →
t ≤ t2 →
j \in arrivals_between arr_seq t1 t2 =
(j \in arrivals_between arr_seq t1 t ++ arrivals_between arr_seq t t2).
Proof.
by intros j t1 t t2 GE LE; rewrite (arrivals_between_cat _ t).
Qed.
(* Third, we observe that we can grow the considered interval without
"losing" any arrived jobs, i.e., membership in the set of arrived jobs
is monotonic. *)
Lemma arrivals_between_sub:
∀ j t1 t1' t2 t2',
t1' ≤ t1 →
t2 ≤ t2' →
j \in arrivals_between arr_seq t1 t2 →
j \in arrivals_between arr_seq t1' t2'.
Proof.
intros j t1 t1' t2 t2' GE1 LE2 IN.
move: (leq_total t1 t2) ⇒ /orP [BEFORE | AFTER];
last by rewrite /arrivals_between big_geq // in IN.
rewrite /arrivals_between.
rewrite → big_cat_nat with (n := t1); [simpl | by done | by apply: (leq_trans BEFORE)].
rewrite mem_cat; apply/orP; right.
rewrite → big_cat_nat with (n := t2); [simpl | by done | by done].
by rewrite mem_cat; apply/orP; left.
Qed.
End Composition.
(* Next, we relate the arrival prefixes with job arrival times. *)
Section ArrivalTimes.
(* Assume that job arrival times are consistent. *)
Hypothesis H_consistent_arrival_times:
consistent_arrival_times arr_seq.
(* First, we prove that if a job belongs to the prefix
(jobs_arrived_before t), then it arrives in the arrival sequence. *)
Lemma in_arrivals_implies_arrived:
∀ j t1 t2,
j \in arrivals_between arr_seq t1 t2 →
arrives_in arr_seq j.
Proof.
rename H_consistent_arrival_times into CONS.
intros j t1 t2 IN.
apply mem_bigcat_nat_exists in IN.
move: IN ⇒ [arr [IN _]].
by ∃ arr.
Qed.
(* Next, we prove that if a job belongs to the prefix
(jobs_arrived_between t1 t2), then it indeed arrives between t1 and
t2. *)
Lemma in_arrivals_implies_arrived_between:
∀ j t1 t2,
j \in arrivals_between arr_seq t1 t2 →
arrived_between j t1 t2.
Proof.
rename H_consistent_arrival_times into CONS.
intros j t1 t2 IN.
apply mem_bigcat_nat_exists in IN.
move: IN ⇒ [t0 [IN /= LT]].
by apply CONS in IN; rewrite /arrived_between IN.
Qed.
(* Similarly, if a job belongs to the prefix (jobs_arrived_before t),
then it indeed arrives before time t. *)
Lemma in_arrivals_implies_arrived_before:
∀ j t,
j \in arrivals_before arr_seq t →
arrived_before j t.
Proof.
intros j t IN.
have: arrived_between j 0 t by apply in_arrivals_implies_arrived_between.
by rewrite /arrived_between /=.
Qed.
(* Similarly, we prove that if a job from the arrival sequence arrives
before t, then it belongs to the sequence (jobs_arrived_before t). *)
Lemma arrived_between_implies_in_arrivals:
∀ j t1 t2,
arrives_in arr_seq j →
arrived_between j t1 t2 →
j \in arrivals_between arr_seq t1 t2.
Proof.
rename H_consistent_arrival_times into CONS.
move ⇒ j t1 t2 [a_j ARRj] BEFORE.
have SAME := ARRj; apply CONS in SAME; subst a_j.
by apply mem_bigcat_nat with (j := (job_arrival j)).
Qed.
(* Next, we prove that if the arrival sequence doesn't contain duplicate
jobs, the same applies for any of its prefixes. *)
Lemma arrivals_uniq :
arrival_sequence_uniq arr_seq →
∀ t1 t2, uniq (arrivals_between arr_seq t1 t2).
Proof.
rename H_consistent_arrival_times into CONS.
unfold arrivals_up_to; intros SET t1 t2.
apply bigcat_nat_uniq; first by done.
intros x t t' IN1 IN2.
by apply CONS in IN1; apply CONS in IN2; subst.
Qed.
End ArrivalTimes.
End Lemmas.
End ArrivalSequencePrefix.