int[][] burst() { int[][] result = new int[4][]; result[WALLCLOCK_TIME_INDEX] = progressWallclockTime.getValues(); result[CPU_TIME_INDEX] = progressCPUTime.getValues(); result[VIRTUAL_MEMORY_KBYTES_INDEX] = progressVirtualMemoryKbytes.getValues(); result[PHYSICAL_MEMORY_KBYTES_INDEX] = progressPhysicalMemoryKbytes.getValues(); return result; }
public void extend(double newProgress, int newValue) { real.extend(newProgress, newValue); } }
= (int)interpolationValueDistance + originalOldValue; extendInternal(interpolationProgress, interpolationValue); advanceState(interpolationProgress, interpolationValue); initializeInterval(); extendInternal(newProgress, newValue); advanceState(newProgress, newValue);
PeriodicStatsAccumulator status = new StatePeriodicStats(8); cumulative.extend(0.0D, 0); cumulative.extend(0.4375D, 700); // 200 per octant cumulative.extend(0.5625D, 1100); // 0.5 = 900 cumulative.extend(0.625D, 1300); cumulative.extend(1.0D, 7901); int[] results = cumulative.getValues(); assertEquals("Bad interpolation in cumulative segment 7", 2201, results[7]); status.extend(0.0D, 0); status.extend(1.0D/16.0D, 300); // + 75 for bucket 0 status.extend(3.0D/16.0D, 700); // + 200 for 0, +300 for 1 status.extend(7.0D/16.0D, 2300); // + 450 for 1, + 1500 for 2, + 1050 for 3 status.extend(1.0D, 1400); // +1125 for 3, +2100 for 4, +1900 for 5, results = status.getValues();
= (int)interpolationValueDistance + originalOldValue; extendInternal(interpolationProgress, interpolationValue); advanceState(interpolationProgress, interpolationValue); initializeInterval(); extendInternal(newProgress, newValue); advanceState(newProgress, newValue);
= (int)interpolationValueDistance + originalOldValue; extendInternal(interpolationProgress, interpolationValue); advanceState(interpolationProgress, interpolationValue); initializeInterval(); extendInternal(newProgress, newValue); advanceState(newProgress, newValue);
int[][] burst() { int[][] result = new int[4][]; result[WALLCLOCK_TIME_INDEX] = progressWallclockTime.getValues(); result[CPU_TIME_INDEX] = progressCPUTime.getValues(); result[VIRTUAL_MEMORY_KBYTES_INDEX] = progressVirtualMemoryKbytes.getValues(); result[PHYSICAL_MEMORY_KBYTES_INDEX] = progressPhysicalMemoryKbytes.getValues(); return result; }
public void extend(double newProgress, int newValue) { real.extend(newProgress, newValue); } }
= (int)interpolationValueDistance + originalOldValue; extendInternal(interpolationProgress, interpolationValue); advanceState(interpolationProgress, interpolationValue); initializeInterval(); extendInternal(newProgress, newValue); advanceState(newProgress, newValue);
int[][] burst() { int[][] result = new int[4][]; result[WALLCLOCK_TIME_INDEX] = progressWallclockTime.getValues(); result[CPU_TIME_INDEX] = progressCPUTime.getValues(); result[VIRTUAL_MEMORY_KBYTES_INDEX] = progressVirtualMemoryKbytes.getValues(); result[PHYSICAL_MEMORY_KBYTES_INDEX] = progressPhysicalMemoryKbytes.getValues(); return result; }
public void extend(double newProgress, int newValue) { real.extend(newProgress, newValue); } }
int[][] burst() { int[][] result = new int[4][]; result[WALLCLOCK_TIME_INDEX] = progressWallclockTime.getValues(); result[CPU_TIME_INDEX] = progressCPUTime.getValues(); result[VIRTUAL_MEMORY_KBYTES_INDEX] = progressVirtualMemoryKbytes.getValues(); result[PHYSICAL_MEMORY_KBYTES_INDEX] = progressPhysicalMemoryKbytes.getValues(); return result; }