mirror of
https://github.com/hashcat/hashcat.git
synced 2024-11-28 02:49:18 +00:00
337 lines
11 KiB
C
337 lines
11 KiB
C
/**
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* Author......: See docs/credits.txt
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* License.....: MIT
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*/
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#include "common.h"
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#include "types.h"
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#include "event.h"
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#include "opencl.h"
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#include "status.h"
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#include "terminal.h"
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#include "autotune.h"
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static double try_run (hashcat_ctx_t *hashcat_ctx, hc_device_param_t *device_param, const u32 kernel_accel, const u32 kernel_loops)
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{
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hashconfig_t *hashconfig = hashcat_ctx->hashconfig;
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device_param->kernel_params_buf32[28] = 0;
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device_param->kernel_params_buf32[29] = kernel_loops; // not a bug, both need to be set
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device_param->kernel_params_buf32[30] = kernel_loops; // because there's two variables for inner iters for slow and fast hashes
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if (hashconfig->attack_exec == ATTACK_EXEC_INSIDE_KERNEL)
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{
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const u32 kernel_power_try = device_param->device_processors * device_param->kernel_threads_by_wgs_kernel1 * kernel_accel;
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run_kernel (hashcat_ctx, device_param, KERN_RUN_1, kernel_power_try, true, 0);
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}
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else
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{
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const u32 kernel_power_try = device_param->device_processors * device_param->kernel_threads_by_wgs_kernel2 * kernel_accel;
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run_kernel (hashcat_ctx, device_param, KERN_RUN_2, kernel_power_try, true, 0);
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}
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const double exec_msec_prev = get_avg_exec_time (device_param, 1);
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return exec_msec_prev;
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}
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static int autotune (hashcat_ctx_t *hashcat_ctx, hc_device_param_t *device_param)
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{
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hashconfig_t *hashconfig = hashcat_ctx->hashconfig;
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opencl_ctx_t *opencl_ctx = hashcat_ctx->opencl_ctx;
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straight_ctx_t *straight_ctx = hashcat_ctx->straight_ctx;
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user_options_extra_t *user_options_extra = hashcat_ctx->user_options_extra;
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const double target_msec = opencl_ctx->target_msec;
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const u32 kernel_accel_min = device_param->kernel_accel_min;
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const u32 kernel_accel_max = device_param->kernel_accel_max;
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const u32 kernel_loops_min = device_param->kernel_loops_min;
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const u32 kernel_loops_max = device_param->kernel_loops_max;
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u32 kernel_accel = kernel_accel_min;
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u32 kernel_loops = kernel_loops_min;
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// in this case the user specified a fixed -n and -u on the commandline
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// no way to tune anything
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// but we need to run a few caching rounds
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if ((kernel_accel_min == kernel_accel_max) && (kernel_loops_min == kernel_loops_max))
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{
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#if defined (DEBUG)
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// don't do any autotune in debug mode in this case
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// we're propably during kernel development
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#else
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if (hashconfig->hash_mode != 2000)
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{
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try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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}
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#endif
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device_param->kernel_accel = kernel_accel;
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device_param->kernel_loops = kernel_loops;
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const u32 kernel_power = device_param->device_processors * device_param->kernel_threads_by_user * device_param->kernel_accel;
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device_param->kernel_power = kernel_power;
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return 0;
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}
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// from here it's clear we are allowed to autotune
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// so let's init some fake words
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const u32 kernel_power_max = device_param->device_processors * device_param->kernel_threads_by_user * kernel_accel_max;
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int CL_rc;
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if (user_options_extra->attack_kern == ATTACK_KERN_BF)
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{
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CL_rc = run_kernel_memset (hashcat_ctx, device_param, device_param->d_pws_buf, 7, kernel_power_max * sizeof (pw_t));
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if (CL_rc == -1) return -1;
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}
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else
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{
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for (u32 i = 0; i < kernel_power_max; i++)
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{
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device_param->pws_buf[i].i[0] = i;
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device_param->pws_buf[i].i[1] = 0x01234567;
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device_param->pws_buf[i].pw_len = 7 + (i & 7);
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}
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CL_rc = 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);
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if (CL_rc == -1) return -1;
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}
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if (hashconfig->attack_exec == ATTACK_EXEC_INSIDE_KERNEL)
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{
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if (straight_ctx->kernel_rules_cnt > 1)
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{
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CL_rc = hc_clEnqueueCopyBuffer (hashcat_ctx, device_param->command_queue, device_param->d_rules, device_param->d_rules_c, 0, 0, MIN (kernel_loops_max, KERNEL_RULES) * sizeof (kernel_rule_t), 0, NULL, NULL);
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if (CL_rc == -1) return -1;
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}
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}
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else
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{
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CL_rc = run_kernel_amp (hashcat_ctx, device_param, kernel_power_max);
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if (CL_rc == -1) return -1;
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}
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#define VERIFIER_CNT 1
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// first find out highest kernel-loops that stays below target_msec
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if (kernel_loops_min < kernel_loops_max)
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{
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for (kernel_loops = kernel_loops_max; kernel_loops > kernel_loops_min; kernel_loops >>= 1)
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{
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double exec_msec = try_run (hashcat_ctx, device_param, kernel_accel_min, kernel_loops);
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for (int i = 0; i < VERIFIER_CNT; i++)
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{
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double exec_msec_v = try_run (hashcat_ctx, device_param, kernel_accel_min, kernel_loops);
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exec_msec = MIN (exec_msec, exec_msec_v);
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}
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if (exec_msec < target_msec) break;
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}
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}
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// now the same for kernel-accel but with the new kernel-loops from previous loop set
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#define STEPS_CNT 10
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if (kernel_accel_min < kernel_accel_max)
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{
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for (int i = 0; i < STEPS_CNT; i++)
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{
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const u32 kernel_accel_try = 1u << i;
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if (kernel_accel_try < kernel_accel_min) continue;
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if (kernel_accel_try > kernel_accel_max) break;
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double exec_msec = try_run (hashcat_ctx, device_param, kernel_accel_try, kernel_loops);
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for (int verifier_idx = 0; verifier_idx < VERIFIER_CNT; verifier_idx++)
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{
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double exec_msec_v = try_run (hashcat_ctx, device_param, kernel_accel_try, kernel_loops);
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exec_msec = MIN (exec_msec, exec_msec_v);
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}
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if (exec_msec > target_msec) break;
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kernel_accel = kernel_accel_try;
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}
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}
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// at this point we want to know the actual runtime for the following reason:
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// we need a reference for the balancing loop following up, and this
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// the balancing loop can have an effect that the creates a new opportunity, for example:
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// if the target is 95 ms and the current runtime is 48ms the above loop
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// stopped the execution because the previous exec_msec was > 95ms
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// due to the rebalance it's possible that the runtime reduces from 48ms to 47ms
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// and this creates the possibility to double the workload -> 47 * 2 = 95ms, which is < 96ms
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double exec_msec_pre_final = try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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for (int verifier_idx = 0; verifier_idx < VERIFIER_CNT; verifier_idx++)
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{
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double exec_msec_pre_final_v = try_run (hashcat_ctx, device_param, kernel_accel, kernel_loops);
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exec_msec_pre_final = MIN (exec_msec_pre_final, exec_msec_pre_final_v);
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}
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u32 diff = kernel_loops - kernel_accel;
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if ((kernel_loops_min < kernel_loops_max) && (kernel_accel_min < kernel_accel_max))
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{
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u32 kernel_accel_orig = kernel_accel;
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u32 kernel_loops_orig = kernel_loops;
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for (u32 f = 1; f < 1024; f++)
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{
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const u32 kernel_accel_try = kernel_accel_orig * f;
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const u32 kernel_loops_try = kernel_loops_orig / f;
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if (kernel_accel_try > kernel_accel_max) break;
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if (kernel_loops_try < kernel_loops_min) break;
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u32 diff_new = kernel_loops_try - kernel_accel_try;
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if (diff_new > diff) break;
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double exec_msec = try_run (hashcat_ctx, device_param, kernel_accel_try, kernel_loops_try);
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for (int verifier_idx = 0; verifier_idx < VERIFIER_CNT; verifier_idx++)
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{
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double exec_msec_v = try_run (hashcat_ctx, device_param, kernel_accel_try, kernel_loops_try);
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exec_msec = MIN (exec_msec, exec_msec_v);
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}
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for (int verifier_idx = 0; verifier_idx < VERIFIER_CNT; verifier_idx++)
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{
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exec_msec_pre_final = exec_msec;
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kernel_accel = kernel_accel_try;
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kernel_loops = kernel_loops_try;
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}
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}
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}
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const double exec_left = target_msec / exec_msec_pre_final;
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const double accel_left = kernel_accel_max / kernel_accel;
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const double exec_accel_min = MIN (exec_left, accel_left); // we want that to be int
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if (exec_accel_min >= 1.0)
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{
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// this is safe to not overflow kernel_accel_max because of accel_left
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kernel_accel *= (u32) exec_accel_min;
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}
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// reset them fake words
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/*
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memset (device_param->pws_buf, 0, kernel_power_max * sizeof (pw_t));
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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);
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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);
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*/
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CL_rc = run_kernel_memset (hashcat_ctx, device_param, device_param->d_pws_buf, 0, kernel_power_max * sizeof (pw_t));
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if (CL_rc == -1) return -1;
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if (hashconfig->attack_exec == ATTACK_EXEC_OUTSIDE_KERNEL)
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{
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CL_rc = run_kernel_memset (hashcat_ctx, device_param, device_param->d_pws_amp_buf, 0, kernel_power_max * sizeof (pw_t));
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if (CL_rc == -1) return -1;
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}
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// reset timer
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device_param->exec_pos = 0;
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memset (device_param->exec_msec, 0, EXEC_CACHE * sizeof (double));
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memset (device_param->exec_us_prev1, 0, EXPECTED_ITERATIONS * sizeof (double));
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memset (device_param->exec_us_prev2, 0, EXPECTED_ITERATIONS * sizeof (double));
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memset (device_param->exec_us_prev3, 0, EXPECTED_ITERATIONS * sizeof (double));
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// store
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device_param->kernel_accel = kernel_accel;
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device_param->kernel_loops = kernel_loops;
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const u32 kernel_power = device_param->device_processors * device_param->kernel_threads_by_user * device_param->kernel_accel;
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device_param->kernel_power = kernel_power;
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#if defined (DEBUG)
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user_options_t *user_options = hashcat_ctx->user_options;
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if (user_options->quiet == false)
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{
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clear_prompt ();
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printf
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(
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"- Device #%u: autotuned kernel-accel to %u" EOL
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"- Device #%u: autotuned kernel-loops to %u" EOL,
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device_param->device_id + 1, kernel_accel,
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device_param->device_id + 1, kernel_loops
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);
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send_prompt ();
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}
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#endif
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return 0;
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}
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void *thread_autotune (void *p)
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{
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thread_param_t *thread_param = (thread_param_t *) p;
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hashcat_ctx_t *hashcat_ctx = thread_param->hashcat_ctx;
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opencl_ctx_t *opencl_ctx = hashcat_ctx->opencl_ctx;
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if (opencl_ctx->enabled == false) return NULL;
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hc_device_param_t *device_param = opencl_ctx->devices_param + thread_param->tid;
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if (device_param->skipped == true) return NULL;
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const int rc_autotune = autotune (hashcat_ctx, device_param);
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if (rc_autotune == -1)
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{
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// we should do something here, tell hashcat main that autotune failed to abort
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}
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return NULL;
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}
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