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c265e976f4
Set cpu->running without taking the cpu_list lock, only requiring it if there is a concurrent exclusive section. This requires adding a new field to CPUState, which records whether a running CPU is being counted in pending_cpus. When an exclusive section is started concurrently with cpu_exec_start, cpu_exec_start can use the new field to determine if it has to wait for the end of the exclusive section. Likewise, cpu_exec_end can use it to see if start_exclusive is waiting for that CPU. This a separate patch for easier bisection of issues. Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
226 lines
9.3 KiB
Promela
226 lines
9.3 KiB
Promela
/*
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* This model describes the implementation of exclusive sections in
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* cpus-common.c (start_exclusive, end_exclusive, cpu_exec_start,
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* cpu_exec_end).
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*
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* Author: Paolo Bonzini <pbonzini@redhat.com>
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*
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* This file is in the public domain. If you really want a license,
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* the WTFPL will do.
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*
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* To verify it:
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* spin -a docs/tcg-exclusive.promela
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* gcc pan.c -O2
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* ./a.out -a
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*
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* Tunable processor macros: N_CPUS, N_EXCLUSIVE, N_CYCLES, USE_MUTEX,
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* TEST_EXPENSIVE.
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*/
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// Define the missing parameters for the model
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#ifndef N_CPUS
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#define N_CPUS 2
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#warning defaulting to 2 CPU processes
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#endif
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// the expensive test is not so expensive for <= 2 CPUs
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// If the mutex is used, it's also cheap (300 MB / 4 seconds) for 3 CPUs
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// For 3 CPUs and the lock-free option it needs 1.5 GB of RAM
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#if N_CPUS <= 2 || (N_CPUS <= 3 && defined USE_MUTEX)
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#define TEST_EXPENSIVE
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#endif
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#ifndef N_EXCLUSIVE
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# if !defined N_CYCLES || N_CYCLES <= 1 || defined TEST_EXPENSIVE
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# define N_EXCLUSIVE 2
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# warning defaulting to 2 concurrent exclusive sections
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# else
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# define N_EXCLUSIVE 1
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# warning defaulting to 1 concurrent exclusive sections
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# endif
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#endif
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#ifndef N_CYCLES
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# if N_EXCLUSIVE <= 1 || defined TEST_EXPENSIVE
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# define N_CYCLES 2
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# warning defaulting to 2 CPU cycles
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# else
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# define N_CYCLES 1
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# warning defaulting to 1 CPU cycles
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# endif
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#endif
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// synchronization primitives. condition variables require a
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// process-local "cond_t saved;" variable.
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#define mutex_t byte
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#define MUTEX_LOCK(m) atomic { m == 0 -> m = 1 }
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#define MUTEX_UNLOCK(m) m = 0
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#define cond_t int
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#define COND_WAIT(c, m) { \
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saved = c; \
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MUTEX_UNLOCK(m); \
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c != saved -> MUTEX_LOCK(m); \
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}
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#define COND_BROADCAST(c) c++
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// this is the logic from cpus-common.c
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mutex_t mutex;
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cond_t exclusive_cond;
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cond_t exclusive_resume;
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byte pending_cpus;
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byte running[N_CPUS];
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byte has_waiter[N_CPUS];
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#define exclusive_idle() \
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do \
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:: pending_cpus -> COND_WAIT(exclusive_resume, mutex); \
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:: else -> break; \
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od
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#define start_exclusive() \
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MUTEX_LOCK(mutex); \
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exclusive_idle(); \
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pending_cpus = 1; \
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\
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i = 0; \
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do \
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:: i < N_CPUS -> { \
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if \
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:: running[i] -> has_waiter[i] = 1; pending_cpus++; \
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:: else -> skip; \
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fi; \
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i++; \
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} \
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:: else -> break; \
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od; \
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\
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do \
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:: pending_cpus > 1 -> COND_WAIT(exclusive_cond, mutex); \
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:: else -> break; \
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od; \
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MUTEX_UNLOCK(mutex);
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#define end_exclusive() \
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MUTEX_LOCK(mutex); \
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pending_cpus = 0; \
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COND_BROADCAST(exclusive_resume); \
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MUTEX_UNLOCK(mutex);
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#ifdef USE_MUTEX
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// Simple version using mutexes
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#define cpu_exec_start(id) \
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MUTEX_LOCK(mutex); \
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exclusive_idle(); \
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running[id] = 1; \
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MUTEX_UNLOCK(mutex);
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#define cpu_exec_end(id) \
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MUTEX_LOCK(mutex); \
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running[id] = 0; \
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if \
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:: pending_cpus -> { \
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pending_cpus--; \
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if \
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:: pending_cpus == 1 -> COND_BROADCAST(exclusive_cond); \
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:: else -> skip; \
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fi; \
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} \
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:: else -> skip; \
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fi; \
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MUTEX_UNLOCK(mutex);
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#else
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// Wait-free fast path, only needs mutex when concurrent with
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// an exclusive section
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#define cpu_exec_start(id) \
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running[id] = 1; \
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if \
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:: pending_cpus -> { \
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MUTEX_LOCK(mutex); \
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if \
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:: !has_waiter[id] -> { \
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running[id] = 0; \
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exclusive_idle(); \
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running[id] = 1; \
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} \
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:: else -> skip; \
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fi; \
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MUTEX_UNLOCK(mutex); \
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} \
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:: else -> skip; \
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fi;
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#define cpu_exec_end(id) \
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running[id] = 0; \
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if \
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:: pending_cpus -> { \
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MUTEX_LOCK(mutex); \
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if \
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:: has_waiter[id] -> { \
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has_waiter[id] = 0; \
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pending_cpus--; \
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if \
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:: pending_cpus == 1 -> COND_BROADCAST(exclusive_cond); \
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:: else -> skip; \
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fi; \
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} \
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:: else -> skip; \
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fi; \
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MUTEX_UNLOCK(mutex); \
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} \
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:: else -> skip; \
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fi
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#endif
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// Promela processes
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byte done_cpu;
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byte in_cpu;
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active[N_CPUS] proctype cpu()
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{
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byte id = _pid % N_CPUS;
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byte cycles = 0;
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cond_t saved;
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do
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:: cycles == N_CYCLES -> break;
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:: else -> {
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cycles++;
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cpu_exec_start(id)
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in_cpu++;
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done_cpu++;
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in_cpu--;
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cpu_exec_end(id)
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}
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od;
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}
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byte done_exclusive;
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byte in_exclusive;
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active[N_EXCLUSIVE] proctype exclusive()
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{
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cond_t saved;
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byte i;
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start_exclusive();
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in_exclusive = 1;
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done_exclusive++;
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in_exclusive = 0;
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end_exclusive();
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}
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#define LIVENESS (done_cpu == N_CPUS * N_CYCLES && done_exclusive == N_EXCLUSIVE)
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#define SAFETY !(in_exclusive && in_cpu)
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never { /* ! ([] SAFETY && <> [] LIVENESS) */
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do
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// once the liveness property is satisfied, this is not executable
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// and the never clause is not accepted
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:: ! LIVENESS -> accept_liveness: skip
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:: 1 -> assert(SAFETY)
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od;
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}
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