(* TEST
flags = "-g"
*)
open Gc.Memprof
let root = ref []
let[@inline never] allocate_arrays lo hi cnt keep =
assert (lo >= 300); (* Will be allocated in major heap. *)
for j = 0 to cnt-1 do
for i = lo to hi do
root := Array.make i 0 :: !root
done;
if not keep then root := []
done
let check_nosample () =
Printf.printf "check_nosample\n%!";
let alloc _ =
Printf.printf "Callback called with sampling_rate = 0\n";
assert(false)
in
start ~callstack_size:10 ~sampling_rate:0.
{ null_tracker with alloc_minor = alloc; alloc_major = alloc; };
allocate_arrays 300 3000 1 false;
stop ()
let () = check_nosample ()
let check_counts_full_major force_promote =
Printf.printf "check_counts_full_major\n%!";
let nalloc_minor = ref 0 in
let nalloc_major = ref 0 in
let enable = ref true in
let npromote = ref 0 in
let ndealloc_minor = ref 0 in
let ndealloc_major = ref 0 in
start ~callstack_size:10 ~sampling_rate:0.01
{
alloc_minor = (fun _ ->
if not !enable then None
else Some (incr nalloc_minor)
);
alloc_major = (fun _ ->
if not !enable then None
else Some (incr nalloc_major)
);
promote = (fun _ ->
Some (incr npromote)
);
dealloc_minor = (fun _ ->
incr ndealloc_minor
);
dealloc_major = (fun _ ->
incr ndealloc_major
);
};
allocate_arrays 300 3000 1 true;
enable := false;
assert (!ndealloc_minor = 0 && !ndealloc_major = 0);
if force_promote then begin
Gc.full_major ();
assert (!ndealloc_minor = 0 && !ndealloc_major = 0 &&
!npromote = !nalloc_minor);
root := [];
Gc.full_major ();
assert (!ndealloc_minor = 0 &&
!ndealloc_major = !nalloc_minor + !nalloc_major);
end else begin
root := [];
Gc.minor ();
Gc.full_major ();
Gc.full_major ();
assert (!nalloc_minor = !ndealloc_minor + !npromote &&
!ndealloc_major = !npromote + !nalloc_major)
end;
stop ()
let () =
check_counts_full_major false;
check_counts_full_major true
let check_no_nested () =
Printf.printf "check_no_nested\n%!";
let in_callback = ref false in
let cb _ =
assert (not !in_callback);
in_callback := true;
allocate_arrays 300 300 100 false;
in_callback := false;
()
in
let cb' _ = cb (); Some () in
start ~callstack_size:10 ~sampling_rate:1.
{
alloc_minor = cb';
alloc_major = cb';
promote = cb';
dealloc_minor = cb;
dealloc_major = cb;
};
allocate_arrays 300 300 100 false;
stop ()
let () = check_no_nested ()
let check_distrib lo hi cnt rate =
Printf.printf "check_distrib %d %d %d %f\n%!" lo hi cnt rate;
let smp = ref 0 in
start ~callstack_size:10 ~sampling_rate:rate
{ null_tracker with
alloc_major = (fun info ->
assert (info.size >= lo && info.size <= hi);
assert (info.n_samples > 0);
assert (info.source = Normal);
smp := !smp + info.n_samples;
None
);
};
allocate_arrays lo hi cnt false;
stop ();
(* The probability distribution of the number of samples follows a
binomial distribution of parameters tot_alloc and rate. Given
that tot_alloc*rate and tot_alloc*(1-rate) are large (i.e., >
100), this distribution is approximately equal to a normal
distribution. We compute a 1e-8 confidence interval for !smp
using quantiles of the normal distribution, and check that we are
in this confidence interval. *)
let tot_alloc = cnt*(lo+hi+2)*(hi-lo+1)/2 in
assert (float tot_alloc *. rate > 100. &&
float tot_alloc *. (1. -. rate) > 100.);
let mean = float tot_alloc *. rate in
let stddev = sqrt (float tot_alloc *. rate *. (1. -. rate)) in
(* This assertion has probability to fail close to 1e-8. *)
assert (abs_float (mean -. float !smp) <= stddev *. 5.7)
let () =
check_distrib 300 3000 3 0.00001;
check_distrib 300 3000 1 0.0001;
check_distrib 300 3000 1 0.01;
check_distrib 300 3000 1 0.9;
check_distrib 300 300 100000 0.1;
check_distrib 300000 300000 30 0.1
let () =
Printf.printf "OK !\n"