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// |jit-test| skip-if: !wasmGcEnabled() || getBuildConfiguration("simulator")
// This test is intended to test what was committed in
//
// and
// using a thread-private cache
//
// and in particular the latter. The patches in these bugs reduce the cost of
// wasm-gc struct/array allocation and collection, in part by better
// integrating those objects with our generational GC facility.
//
// Existing tests do not cover all of those paths. In particular they do not
// exercise both set-subtraction algorithms in Nursery::freeTrailerBlocks.
// This test does, though.
//
// The test first creates an "primary" array of 1500 elements. Each element
// is a reference to a secondary array of between 1 and 50 int32s. These
// secondary arrays have size chosen randomly, and the elements are also
// random.
//
// Then, elements of the primary array are replaced. An index in the range 0
// .. N - 1 is randomly chosen, and the element there is replaced by a
// randomly-created secondary array. This is repeated 500,000 times with
// N = 800.
//
// Finally, all of the above is repeated, but with N = 1200.
//
// As a result just over a million arrays and their trailer blocks, of various
// sizes, are allocated and deallocated. With N = 800, in
// js::Nursery::freeTrailerBlocks, we end up with trailersRemovedUsed_ of
// around 800, so one of the set-subtraction algorithms is exercised.
// With N = 1200, the other is exercised. It's not entirely clear why changing
// N causes trailersRemovedUsed_ to have more or less the same value during
// nursery collection, but the correlation does seem fairly robust.
//
// The test is skipped on the simulator because it takes too long to run, and
// triggers timeouts.
let t =
`(module
;; A simple pseudo-random number generator.
;; Produces numbers in the range 0 .. 2^16-1.
(global $rngState
(mut i32) (i32.const 1)
)
(func $rand (export "rand") (result i32)
(local $t i32)
;; update $rngState
(local.set $t (global.get $rngState))
(local.set $t (i32.mul (local.get $t) (i32.const 1103515245)))
(local.set $t (i32.add (local.get $t) (i32.const 12345)))
(global.set $rngState (local.get $t))
;; pull 16 random bits out of it
(local.set $t (i32.shr_u (local.get $t) (i32.const 15)))
(local.set $t (i32.and (local.get $t) (i32.const 0xFFFF)))
(local.get $t)
)
;; Array types
(type $tArrayI32 (array (mut i32))) ;; "secondary array" above
(type $tArrayArrayI32 (array (mut (ref null $tArrayI32)))) ;; "primary array"
;; Create an array ("secondary array") containing random numbers, with a
;; size between 1 and 50, also randomly chosen.
(func $createSecondaryArray (export "createSecondaryArray")
(result (ref $tArrayI32))
(local $i i32)
(local $nElems i32)
(local $arr (ref $tArrayI32))
(local.set $nElems (call $rand))
(local.set $nElems (i32.rem_u (local.get $nElems) (i32.const 50)))
(local.set $nElems (i32.add (local.get $nElems) (i32.const 1)))
(local.set $arr (array.new $tArrayI32 (i32.const 0) (local.get $nElems)))
(loop $cont
(array.set $tArrayI32 (local.get $arr) (local.get $i) (call $rand))
(local.set $i (i32.add (local.get $i) (i32.const 1)))
(br_if $cont (i32.lt_u (local.get $i) (local.get $nElems)))
)
(local.get $arr)
)
;; Create an array (the "primary array") of 1500 elements of
;; type ref-of-tArrayI32.
(func $createPrimaryArray (export "createPrimaryArray")
(result (ref $tArrayArrayI32))
(local $i i32)
(local $arrarr (ref $tArrayArrayI32))
(local.set $arrarr (array.new $tArrayArrayI32 (ref.null $tArrayI32)
(i32.const 1500)))
(loop $cont
(array.set $tArrayArrayI32 (local.get $arrarr)
(local.get $i) (call $createSecondaryArray))
(local.set $i (i32.add (local.get $i) (i32.const 1)))
(br_if $cont (i32.lt_u (local.get $i) (i32.const 1500)))
)
(local.get $arrarr)
)
;; Use $createPrimaryArray to create an initial array. Then randomly replace
;; elements for a while.
(func $churn (export "churn") (param $thresh i32) (result i32)
(local $i i32)
(local $j i32)
(local $finalSum i32)
(local $arrarr (ref $tArrayArrayI32))
(local $arr (ref null $tArrayI32))
(local $arrLen i32)
(local.set $arrarr (call $createPrimaryArray))
;; This loop iterates 500,000 times. Each iteration, it chooses
;; a randomly element in $arrarr and replaces it with a new
;; random array of 32-bit ints.
(loop $cont
;; make $j be a random number in 0 .. $thresh-1.
;; Then replace that index in $arrarr with a new random arrayI32.
(local.set $j (i32.rem_u (call $rand) (local.get $thresh)))
(array.set $tArrayArrayI32 (local.get $arrarr)
(local.get $j) (call $createSecondaryArray))
(local.set $i (i32.add (local.get $i) (i32.const 1)))
(br_if $cont (i32.lt_u (local.get $i) (i32.const 500000)))
)
;; Finally, compute a checksum by summing all the numbers
;; in all secondary arrays. This simply assumes that all of the refs to
;; secondary arrays are non-null, which isn't per-se guaranteed by the
;; previous loop, but it works in this case because the RNG
;; produces each index value to overwrite at least once.
(local.set $finalSum (i32.const 0))
(local.set $i (i32.const 0)) ;; loop var for the outer loop
(loop $outer
;; body of outer loop
;; $arr = $arrarr[i]
(local.set $arr (array.get $tArrayArrayI32 (local.get $arrarr)
(local.get $i)))
;; iterate over $arr
(local.set $arrLen (array.len (local.get $arr)))
(local.set $j (i32.const 0)) ;; loop var for the inner loop
(loop $inner
;; body of inner loop
(local.set $finalSum
(i32.rotl (local.get $finalSum) (i32.const 1)))
(local.set $finalSum
(i32.xor (local.get $finalSum)
(array.get $tArrayI32 (local.get $arr)
(local.get $j))))
;; loop control for the inner loop
(local.set $j (i32.add (local.get $j) (i32.const 1)))
(br_if $inner (i32.lt_u (local.get $j) (local.get $arrLen)))
)
;; loop control for the outer loop
(local.set $i (i32.add (local.get $i) (i32.const 1)))
(br_if $outer (i32.lt_u (local.get $i) (i32.const 1500)))
)
;; finally, roll in the final value of the RNG state
(i32.xor (local.get $finalSum) (global.get $rngState))
)
)`;
let i = wasmEvalText(t);
let fns = i.exports;
assertEq(fns.churn(800), -575895114);
assertEq(fns.churn(1200), -1164697516);