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mirror of https://github.com/hashcat/hashcat synced 2024-11-28 05:21:38 +01:00

Use a more conservative mechanic in the last step of the autotune

This commit is contained in:
Jens Steube 2018-02-03 19:01:11 +01:00
parent fb00b528c4
commit 665a514977

View File

@ -187,53 +187,36 @@ static int autotune (hashcat_ctx_t *hashcat_ctx, hc_device_param_t *device_param
}
}
// at this point we want to know the actual runtime for the following reason:
// we need a reference for the balancing loop following up, and this
// the balancing loop can have an effect that the creates a new opportunity, for example:
// if the target is 95 ms and the current runtime is 48ms the above loop
// stopped the execution because the previous exec_msec was > 95ms
// due to the rebalance it's possible that the runtime reduces from 48ms to 47ms
// and this creates the possibility to double the workload -> 47 * 2 = 95ms, which is < 96ms
// now find the middle balance between kernel_accel and kernel_loops
// while respecting allowed ranges at the same time
double exec_msec_pre_final = try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
u32 diff = kernel_loops - kernel_accel;
if ((kernel_loops_min < kernel_loops_max) && (kernel_accel_min < kernel_accel_max))
if (kernel_accel < kernel_loops)
{
u32 kernel_accel_orig = kernel_accel;
u32 kernel_loops_orig = kernel_loops;
const u32 kernel_accel_orig = kernel_accel;
const u32 kernel_loops_orig = kernel_loops;
for (u32 f = 1; f < 1024; f++)
for (int i = 1; i < STEPS_CNT; i++)
{
const u32 kernel_accel_try = kernel_accel_orig * f;
const u32 kernel_loops_try = kernel_loops_orig / f;
const u32 kernel_accel_try = kernel_accel_orig * (1u << i);
const u32 kernel_loops_try = kernel_loops_orig / (1u << i);
if (kernel_accel_try < kernel_accel_min) continue;
if (kernel_accel_try > kernel_accel_max) break;
if (kernel_loops_try > kernel_loops_max) continue;
if (kernel_loops_try < kernel_loops_min) break;
u32 diff_new = 0;
if (kernel_accel_try > kernel_loops_try)
{
diff_new = kernel_accel_try - kernel_loops_try;
}
else
{
diff_new = kernel_loops_try - kernel_accel_try;
}
if (diff_new > diff) break;
double exec_msec = try_run (hashcat_ctx, device_param, kernel_accel_try, kernel_loops_try);
exec_msec_pre_final = exec_msec;
kernel_accel = kernel_accel_try;
kernel_loops = kernel_loops_try;
// too much if the next test is true
if (kernel_loops_try < kernel_accel_try) break;
}
}
double exec_msec_pre_final = try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
const u32 exec_left = target_msec / exec_msec_pre_final;
const u32 accel_left = kernel_accel_max / kernel_accel;
@ -249,13 +232,6 @@ static int autotune (hashcat_ctx_t *hashcat_ctx, hc_device_param_t *device_param
// reset them fake words
/*
memset (device_param->pws_buf, 0, kernel_power_max * sizeof (pw_t));
hc_clEnqueueWriteBuffer (hashcat_ctx, device_param->command_queue, device_param->d_pws_buf, CL_TRUE, 0, kernel_power_max * sizeof (pw_t), device_param->pws_buf, 0, NULL, NULL);
hc_clEnqueueWriteBuffer (hashcat_ctx, device_param->command_queue, device_param->d_pws_amp_buf, CL_TRUE, 0, kernel_power_max * sizeof (pw_t), device_param->pws_buf, 0, NULL, NULL);
*/
CL_rc = run_kernel_memset (hashcat_ctx, device_param, device_param->d_pws_buf, 0, device_param->size_pws);
if (CL_rc == -1) return -1;