static int autok_thread_func(void *data) { struct sdio_autok_thread_data *autok_thread_data; //struct sched_param param = { .sched_priority = 99 }; unsigned int vcore_uv = 0; struct msdc_host *host; struct mmc_host *mmc; char stage = 0; int i,j; int res = 0; int doStg2 = 0; void __iomem *base; u32 dma; struct timeval t0,t1; int time_in_s, time_in_ms; // unsigned long flags; autok_thread_data = (struct sdio_autok_thread_data *)data; //sched_setscheduler(current, SCHED_FIFO, ¶m); // preempt_disable(); host = autok_thread_data->host; mmc = host->mmc; stage = autok_thread_data->stage; base = host->base; dma = msdc_dma_status(); // Inform msdc_set_mclk() auto-K is going to process sdio_autok_processed = 1; // Set clock to card max clock mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); msdc_ungate_clock(host); // Set PIO mode msdc_dma_off(); vcore_uv = autok_get_current_vcore_offset(); // End of initialize do_gettimeofday(&t0); if(autok_thread_data->log != NULL) log_info = autok_thread_data->log; if(stage == 1) { // call stage 1 auto-K callback function autok_thread_data->is_autok_done[host->id] = 0; res = msdc_autok_stg1_cal(host, vcore_uv, autok_thread_data->p_autok_predata); if(res){ pr_debug("[%s] Auto-K stage 1 fail, res = %d, set msdc parameter settings stored in nvram to 0\n", __func__, res); memset(autok_thread_data->p_autok_predata->ai_data[0], 0, autok_thread_data->p_autok_predata->param_count * sizeof(unsigned int)); autok_thread_data->is_autok_done[host->id] = 2; } // For Abort function if(atomic_read(&autok_is_abort) == 1){ autok_thread_data->is_autok_done[host->id] = 3; } } else if(stage == 2) { // call stage 2 auto-K callback function // check if msdc params of different volt are all 0, if so, that means auto-K stg1 failed for(i=0; i<autok_thread_data->p_autok_predata->vol_count; i++){ for(j=0; j<autok_thread_data->p_autok_predata->param_count; j++){ if(autok_thread_data->p_autok_predata->ai_data[i][j].data.sel != 0){ doStg2 = 1; break; } } if(doStg2) break; } if(doStg2){ res = msdc_autok_stg2_cal(host, autok_thread_data->p_autok_predata, vcore_uv); if(res){ pr_debug("[%s] Auto-K stage 2 fail, res = %d, downgrade SDIO freq to 50MHz\n", __func__, res); mmc->ios.clock = 50*1000*1000; mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); sdio_autok_processed = 0; for (i = 0; i < HOST_MAX_NUM; i++) { if (autok_thread_data->p_autok_progress[i].host_id == -1) { break; } else if (autok_thread_data->p_autok_progress[i].host_id == host->id) { autok_thread_data->p_autok_progress[i].fail = 1; } } } } else { // Auto-K stg1 failed pr_debug("[%s] Auto-K stage 1 fail, downgrade SDIO freq to 50MHz\n", __func__); mmc->ios.clock = 50*1000*1000; mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); sdio_autok_processed = 0; for (i = 0; i < HOST_MAX_NUM; i++) { if (autok_thread_data->p_autok_progress[i].host_id == -1) { break; } else if (autok_thread_data->p_autok_progress[i].host_id == host->id) { autok_thread_data->p_autok_progress[i].fail = 1; } } } log_info = NULL; } else { pr_debug("[%s] stage %d doesn't support in auto-K\n", __func__, stage); //return -EFAULT; } do_gettimeofday(&t1); if(dma == DMA_ON) msdc_dma_on(); msdc_gate_clock(host,1); // [FIXDONE] Tell native module that auto-K has finished if(stage == 1) autok_calibration_done(host->id, autok_thread_data); else if(stage == 2){ for(i=0; i<HOST_MAX_NUM; i++){ if(autok_thread_data->p_autok_progress[i].host_id == -1){ break; } else if(autok_thread_data->p_autok_progress[i].host_id == host->id){ autok_thread_data->p_autok_progress[i].done = 1; if(autok_thread_data->p_autok_progress[i].done > 0) complete(&autok_thread_data->autok_completion[i]); } } } time_in_s = (t1.tv_sec - t0.tv_sec); time_in_ms = (t1.tv_usec - t0.tv_usec)>>10; pr_err("\n[AUTOKK][Stage%d] Timediff is %d.%d(s)\n", (int)stage, time_in_s, time_in_ms ); // preempt_enable(); return 0; }
static int autok_thread_func(void *data) { struct sdio_autok_thread_data *autok_thread_data; struct sched_param param = { .sched_priority = 99 }; unsigned int vcore_uv = 0; struct msdc_host *host; struct mmc_host *mmc; char stage = 0; int i,j; int res = 0; int doStg2 = 0; void __iomem *base; u32 dma; struct timeval t0,t1; int time_in_s, time_in_ms; // unsigned long flags; autok_thread_data = (struct sdio_autok_thread_data *)data; sched_setscheduler(current, SCHED_FIFO, ¶m); // preempt_disable(); host = autok_thread_data->host; mmc = host->mmc; stage = autok_thread_data->stage; base = host->base; dma = msdc_dma_status(); // Inform msdc_set_mclk() auto-K is going to process sdio_autok_processed = 1; // Set clock to card max clock mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); msdc_ungate_clock(host); // Set PIO mode msdc_dma_off(); vcore_uv = autok_get_current_vcore_offset(); // End of initialize do_gettimeofday(&t0); if(autok_thread_data->log != NULL) log_info = autok_thread_data->log; if(stage == 1) { // call stage 1 auto-K callback function autok_thread_data->is_autok_done[host->id] = 0; res = msdc_autok_stg1_cal(host, vcore_uv, autok_thread_data->p_autok_predata); if(res){ printk(KERN_INFO "[%s] Auto-K stage 1 fail, res = %d, set msdc parameter settings stored in nvram to 0\n", __func__, res); memset(autok_thread_data->p_autok_predata->ai_data[0], 0, autok_thread_data->p_autok_predata->param_count * sizeof(unsigned int)); autok_thread_data->is_autok_done[host->id] = 2; } } else if(stage == 2) { // call stage 2 auto-K callback function // check if msdc params of different volt are all 0, if so, that means auto-K stg1 failed for(i=0; i<autok_thread_data->p_autok_predata->vol_count; i++){ for(j=0; j<autok_thread_data->p_autok_predata->param_count; j++){ if(autok_thread_data->p_autok_predata->ai_data[i][j].data.sel != 0){ doStg2 = 1; break; } } if(doStg2) break; } if(doStg2){ res = msdc_autok_stg2_cal(host, autok_thread_data->p_autok_predata, vcore_uv); if(res){ printk(KERN_INFO "[%s] Auto-K stage 2 fail, res = %d, downgrade SDIO freq to 50MHz\n", __func__, res); mmc->ios.clock = 50*1000*1000; mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); sdio_autok_processed = 0; for (i = 0; i < HOST_MAX_NUM; i++) { if (autok_thread_data->p_autok_progress[i].host_id == -1) { break; } else if (autok_thread_data->p_autok_progress[i].host_id == host->id) { autok_thread_data->p_autok_progress[i].fail = 1; } } } } else { // Auto-K stg1 failed printk(KERN_INFO "[%s] Auto-K stage 1 fail, downgrade SDIO freq to 50MHz\n", __func__); mmc->ios.clock = 50*1000*1000; mmc_set_clock(mmc, mmc->ios.clock); msdc_sdio_set_long_timing_delay_by_freq(host, mmc->ios.clock); sdio_autok_processed = 0; for (i = 0; i < HOST_MAX_NUM; i++) { if (autok_thread_data->p_autok_progress[i].host_id == -1) { break; } else if (autok_thread_data->p_autok_progress[i].host_id == host->id) { autok_thread_data->p_autok_progress[i].fail = 1; } } } log_info = NULL; } else { printk(KERN_INFO "[%s] stage %d doesn't support in auto-K\n", __func__, stage); //return -EFAULT; } do_gettimeofday(&t1); if(dma == DMA_ON) msdc_dma_on(); msdc_gate_clock(host,1); // [FIXDONE] Tell native module that auto-K has finished if(stage == 1) autok_calibration_done(host->id, autok_thread_data); else if(stage == 2){ for(i=0; i<HOST_MAX_NUM; i++){ if(autok_thread_data->p_autok_progress[i].host_id == -1){ break; } else if(autok_thread_data->p_autok_progress[i].host_id == host->id){ autok_thread_data->p_autok_progress[i].done = 1; if(autok_thread_data->p_autok_progress[i].done > 0) complete(&autok_thread_data->autok_completion[i]); } } } time_in_s = (t1.tv_sec - t0.tv_sec); time_in_ms = (t1.tv_usec - t0.tv_usec)>>10; printk(KERN_ERR "\n[AUTOKK][Stage%d] Timediff is %d.%d(s)\n", (int)stage, time_in_s, time_in_ms ); // preempt_enable(); return 0; } #endif int send_autok_uevent(char *text, struct msdc_host *host) { int err = 0; char *envp[3]; char *host_buf; char *what_buf; //struct msdc_host *host = mtk_msdc_host[id]; host_buf = kzalloc(sizeof(char)*128, GFP_KERNEL); what_buf = kzalloc(sizeof(char)*128, GFP_KERNEL); snprintf(host_buf, MAX_ARGS_BUF-1, "HOST=%d", host->id); snprintf(what_buf, MAX_ARGS_BUF-1, "WHAT=%s", text); envp[0] = host_buf; envp[1] = what_buf; envp[2] = NULL; if(host != NULL){ err = kobject_uevent_env(&host->mmc->class_dev.kobj, KOBJ_CHANGE, envp); } kfree(host_buf); kfree(what_buf); if(err < 0) printk(KERN_INFO "[%s] kobject_uevent_env error = %d\n", __func__, err); return err; }
static void autok_thread_func(struct work_struct *data) #endif // USE_KERNEL_THREAD { int err = 0; #ifdef USE_KERNEL_THREAD struct sdio_autok_thread_data *autok_thread_data = (struct sdio_autok_thread_data *)data; #else // USE_KERNEL_THREAD struct sdio_autok_workqueue_data *autok_thread_data = (struct sdio_autok_workqueue_data *)data; #endif // USE_KERNEL_THREAD struct msdc_host *host = autok_thread_data->host; char stage = autok_thread_data->stage; char *envp[2]; char *lteprocenvp[2]; #ifdef CHANGE_SCHED_POLICY struct sched_param param; int sched_policy; #ifdef SCHED_POLICY_INFO sched_policy = sys_sched_getscheduler(0); printk("[%s] orig. sched policy: %d\n", __func__, sched_policy); param.sched_priority = sys_sched_get_priority_max(SCHED_FIFO); if( sys_sched_setscheduler( 0, SCHED_FIFO, ¶m ) == -1 ) { printk("[%s] sched_setscheduler fail\n", __func__); } sched_policy = sys_sched_getscheduler(0); printk("[%s] sched policy FIFO: %d\n", __func__, sched_policy); #endif //param.sched_priority = sched_get_priority_max(SCHED_RR); param.sched_priority = 1; if( sys_sched_setscheduler( 0, SCHED_RR, ¶m ) == -1 ) { printk("[%s] sched_setscheduler fail\n", __func__); } #ifdef SCHED_POLICY_INFO sched_policy = sys_sched_getscheduler(0); printk("[%s] modified sched policy: %d\n", __func__, sched_policy); #endif #endif if(stage == 1) { // call stage 1 auto-K callback function msdc_autok_stg1_cal(host); envp[0] = "FROM=sdio_autok"; envp[1] = NULL; err = kobject_uevent_env(&host->mmc->class_dev.kobj, KOBJ_ONLINE, envp); if(err < 0) printk(KERN_INFO "[%s] kobject_uevent_env error = %d\n", __func__, err); } else if(stage == 2) { // call stage 2 auto-K callback function msdc_autok_stg2_cal(host, autok_thread_data->autok_stage1_result, autok_thread_data->len); } else { printk(KERN_INFO "[%s] stage %d doesn't support in auto-K\n", __func__, stage); #ifdef USE_KERNEL_THREAD return -EFAULT; #else // USE_KERNEL_THREAD return; #endif // USE_KERNEL_THREAD } lteprocenvp[0] = "FROM=autok_done"; lteprocenvp[1] = NULL; err = kobject_uevent_env(&host->mmc->class_dev.kobj, KOBJ_ONLINE, lteprocenvp); if(err < 0) printk(KERN_INFO "[%s] kobject_uevent_env error = %d\n", __func__, err); #ifdef USE_KERNEL_THREAD return 0; #else // USE_KERNEL_THREAD return; #endif // USE_KERNEL_THREAD }