// Copyright 2015 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Overwrite the random seed provided by the test runner to make this test less // flaky. Due to flag contradiction checking, this requires // --allow-overwriting-for-next-flag to avoid an error. // Flags: --allow-overwriting-for-next-flag --random-seed=20 // Flags: --nostress-opt --noalways-turbofan --predictable (function() { var kHistory = 2; var kRepeats = 100; var history = new Uint32Array(kHistory); function random() { return (Math.random() * Math.pow(2, 32)) >>> 0; } function ChiSquared(m, n) { var ys_minus_np1 = (m - n / 2.0); var chi_squared_1 = ys_minus_np1 * ys_minus_np1 * 2.0 / n; var ys_minus_np2 = ((n - m) - n / 2.0); var chi_squared_2 = ys_minus_np2 * ys_minus_np2 * 2.0 / n; return chi_squared_1 + chi_squared_2; } for (var predictor_bit = -2; predictor_bit < 32; predictor_bit++) { // The predicted bit is one of the bits from the PRNG. for (var random_bit = 0; random_bit < 32; random_bit++) { for (var ago = 0; ago < kHistory; ago++) { // We don't want to check whether each bit predicts itself. if (ago == 0 && predictor_bit == random_bit) continue; // Enter the new random value into the history for (var i = ago; i >= 0; i--) { history[i] = random(); } // Find out how many of the bits are the same as the prediction bit. var m = 0; for (var i = 0; i < kRepeats; i++) { for (var j = ago - 1; j >= 0; j--) history[j + 1] = history[j]; history[0] = random(); var predicted; if (predictor_bit >= 0) { predicted = (history[ago] >> predictor_bit) & 1; } else { predicted = predictor_bit == -2 ? 0 : 1; } var bit = (history[0] >> random_bit) & 1; if (bit == predicted) m++; } // Chi squared analysis for k = 2 (2, states: same/not-same) and one // degree of freedom (k - 1). var chi_squared = ChiSquared(m, kRepeats); if (chi_squared > 24) { var percent = Math.floor(m * 100.0 / kRepeats); if (predictor_bit < 0) { var bit_value = predictor_bit == -2 ? 0 : 1; print(`Bit ${random_bit} is ${bit_value} ${percent}% of the time`); } else { print(`Bit ${random_bit} is the same as bit ${predictor_bit} ` + `${ago} ago ${percent}% of the time`); } } // For 1 degree of freedom this corresponds to 1 in a million. We are // running ~8000 tests, so that would be surprising. assertTrue(chi_squared <= 24); // If the predictor bit is a fixed 0 or 1 then it makes no sense to // repeat the test with a different age. if (predictor_bit < 0) break; } } } })();