/* control.c COPYRIGHT FUJITSU LIMITED 2016-2017 */ /** * \file executer/kernel/control.c * License details are found in the file LICENSE. * \brief * kernel module control * \author Taku Shimosawa \par * Copyright (C) 2011 - 2012 Taku Shimosawa * \author Balazs Gerofi \par * Copyright (C) 2012 RIKEN AICS * \author Gou Nakamura \par * Copyright (C) 2012 - 2013 Hitachi, Ltd. * \author Tomoki Shirasawa \par * Copyright (C) 2012 - 2013 Hitachi, Ltd. * \author Balazs Gerofi \par * Copyright (C) 2013 The University of Tokyo */ /* * HISTORY: * 2013/09/02 shirasawa add terminate thread * 2013/08/19 shirasawa mcexec forward signal to MIC process * 2013/08/07 nakamura add page fault forwarding * 2013/07/05 shirasawa propagate error code for prepare image * 2013/07/02 shirasawa add error handling for prepare_process * 2013/04/17 nakamura add generic system call forwarding */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mcctrl.h" #include #include #include //#define DEBUG #ifdef DEBUG #define dprintk printk #else #define dprintk(...) #endif #ifdef MCCTRL_KSYM_sys_unshare #if MCCTRL_KSYM_sys_unshare typedef int (*int_star_fn_ulong_t)(unsigned long); int (*mcctrl_sys_unshare)(unsigned long unshare_flags) = (int_star_fn_ulong_t) MCCTRL_KSYM_sys_unshare; #else // exported int (*mcctrl_sys_unshare)(unsigned long unshare_flags) = NULL; #endif #endif #ifdef MCCTRL_KSYM_sys_mount #if MCCTRL_KSYM_sys_mount typedef int (*int_star_fn_char_char_char_ulong_void_t)(char *, char *, char *, unsigned long, void *); int (*mcctrl_sys_mount)(char *dev_name,char *dir_name, char *type, unsigned long flags, void *data) = (int_star_fn_char_char_char_ulong_void_t) MCCTRL_KSYM_sys_mount; #else // exported int (*mcctrl_sys_mount)(char *dev_name,char *dir_name, char *type, unsigned long flags, void *data) = sys_mount; #endif #endif #ifdef MCCTRL_KSYM_sys_umount #if MCCTRL_KSYM_sys_umount typedef int (*int_fn_char_star_int_t)(char *, int); int (*mcctrl_sys_umount)(char *dir_name, int flags) = (int_fn_char_star_int_t) MCCTRL_KSYM_sys_umount; #else // exported int (*mcctrl_sys_umount)(char *dir_name, int flags) = sys_umount; #endif #endif //extern struct mcctrl_channel *channels; int mcctrl_ikc_set_recv_cpu(ihk_os_t os, int cpu); int syscall_backward(struct mcctrl_usrdata *, int, unsigned long, unsigned long, unsigned long, unsigned long, unsigned long, unsigned long, unsigned long *); static long mcexec_prepare_image(ihk_os_t os, struct program_load_desc * __user udesc) { struct program_load_desc *desc = NULL; struct program_load_desc *pdesc = NULL; struct ikc_scd_packet isp; void *args = NULL; void *envs = NULL; int ret = 0; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd = NULL; int num_sections; desc = kmalloc(sizeof(*desc), GFP_KERNEL); if (!desc) { printk("%s: error: allocating program_load_desc\n", __FUNCTION__); return -ENOMEM; } if (copy_from_user(desc, udesc, sizeof(struct program_load_desc))) { printk("%s: error: copying program_load_desc\n", __FUNCTION__); ret = -EFAULT; goto free_out; } ppd = mcctrl_get_per_proc_data(usrdata, desc->pid); if (!ppd) { printk("%s: ERROR: no per process data for PID %d\n", __FUNCTION__, desc->pid); ret = -EINVAL; goto free_out; } num_sections = desc->num_sections; if (num_sections <= 0 || num_sections > 16) { printk("%s: ERROR: # of sections: %d\n", __FUNCTION__, num_sections); ret = -EINVAL; goto put_and_free_out; } pdesc = kmalloc(sizeof(struct program_load_desc) + sizeof(struct program_image_section) * num_sections, GFP_KERNEL); memcpy(pdesc, desc, sizeof(struct program_load_desc)); if (copy_from_user(pdesc->sections, udesc->sections, sizeof(struct program_image_section) * num_sections)) { ret = -EFAULT; goto put_and_free_out; } kfree(desc); desc = NULL; pdesc->pid = task_tgid_vnr(current); if (reserve_user_space(usrdata, &pdesc->user_start, &pdesc->user_end)) { ret = -ENOMEM; goto put_and_free_out; } args = kmalloc(pdesc->args_len, GFP_KERNEL); if (copy_from_user(args, pdesc->args, pdesc->args_len)) { ret = -EFAULT; goto put_and_free_out; } envs = kmalloc(pdesc->envs_len, GFP_KERNEL); if (copy_from_user(envs, pdesc->envs, pdesc->envs_len)) { ret = -EFAULT; goto put_and_free_out; } pdesc->args = (void*)virt_to_phys(args); dprintk("args: 0x%lX\n", (unsigned long)pdesc->args); dprintk("argc: %ld\n", *(long *)args); pdesc->envs = (void*)virt_to_phys(envs); dprintk("envs: 0x%lX\n", (unsigned long)pdesc->envs); dprintk("envc: %ld\n", *(long *)envs); isp.msg = SCD_MSG_PREPARE_PROCESS; isp.ref = pdesc->cpu; isp.arg = virt_to_phys(pdesc); dprintk("# of sections: %d\n", pdesc->num_sections); dprintk("%p (%lx)\n", pdesc, isp.arg); pdesc->status = 0; mb(); ret = mcctrl_ikc_send(os, pdesc->cpu, &isp); if(ret < 0) { printk("%s: ERROR mcctrl_ikc_send: %d\n", __FUNCTION__, ret); goto put_and_free_out; } ret = wait_event_interruptible(ppd->wq_prepare, pdesc->status); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); goto put_and_free_out; } if (pdesc->err < 0) { ret = pdesc->err; goto put_and_free_out; } /* Update rpgtable */ ppd->rpgtable = pdesc->rpgtable; if (copy_to_user(udesc, pdesc, sizeof(struct program_load_desc) + sizeof(struct program_image_section) * num_sections)) { ret = -EFAULT; goto put_and_free_out; } dprintk("%s: pid %d, rpgtable: 0x%lx added\n", __FUNCTION__, ppd->pid, ppd->rpgtable); ret = 0; put_and_free_out: mcctrl_put_per_proc_data(ppd); free_out: kfree(args); kfree(pdesc); kfree(envs); kfree(desc); return ret; } int mcexec_transfer_image(ihk_os_t os, struct remote_transfer *__user upt) { struct remote_transfer pt; unsigned long phys, ret = 0; void *rpm; #if 0 unsigned long dma_status = 0; ihk_dma_channel_t channel; struct ihk_dma_request request; void *p; channel = ihk_device_get_dma_channel(ihk_os_to_dev(os), 0); if (!channel) { return -EINVAL; } #endif if (copy_from_user(&pt, upt, sizeof(pt))) { return -EFAULT; } if (pt.size > PAGE_SIZE) { printk("mcexec_transfer_image(): ERROR: size exceeds PAGE_SIZE\n"); return -EFAULT; } phys = ihk_device_map_memory(ihk_os_to_dev(os), pt.rphys, PAGE_SIZE); #ifdef CONFIG_MIC rpm = ioremap_wc(phys, PAGE_SIZE); #else rpm = ihk_device_map_virtual(ihk_os_to_dev(os), phys, PAGE_SIZE, NULL, 0); #endif if (pt.direction == MCEXEC_UP_TRANSFER_TO_REMOTE) { if (copy_from_user(rpm, pt.userp, pt.size)) { ret = -EFAULT; } } else if (pt.direction == MCEXEC_UP_TRANSFER_FROM_REMOTE) { if (copy_to_user(pt.userp, rpm, pt.size)) { ret = -EFAULT; } } else { printk("mcexec_transfer_image(): ERROR: invalid direction\n"); ret = -EINVAL; } #ifdef CONFIG_MIC iounmap(rpm); #else ihk_device_unmap_virtual(ihk_os_to_dev(os), rpm, PAGE_SIZE); #endif ihk_device_unmap_memory(ihk_os_to_dev(os), phys, PAGE_SIZE); return ret; #if 0 p = (void *)__get_free_page(GFP_KERNEL); if (copy_from_user(p, pt.src, PAGE_SIZE)) { return -EFAULT; } memset(&request, 0, sizeof(request)); request.src_os = NULL; request.src_phys = virt_to_phys(p); request.dest_os = os; request.dest_phys = pt.dest; request.size = PAGE_SIZE; request.notify = (void *)virt_to_phys(&dma_status); request.priv = (void *)1; ihk_dma_request(channel, &request); while (!dma_status) { mb(); udelay(1); } free_page((unsigned long)p); return 0; #endif } struct mcos_handler_info { int pid; int cpu; struct mcctrl_usrdata *ud; struct file *file; }; struct mcos_handler_info; static struct host_thread *host_threads; DEFINE_RWLOCK(host_thread_lock); struct host_thread { struct host_thread *next; struct mcos_handler_info *handler; int pid; int tid; unsigned long usp; unsigned long lfs; unsigned long rfs; }; struct mcos_handler_info *new_mcos_handler_info(ihk_os_t os, struct file *file) { struct mcos_handler_info *info; info = kmalloc(sizeof(struct mcos_handler_info), GFP_KERNEL); #ifdef POSTK_DEBUG_TEMP_FIX_64 /* host process is SIGKILLed fix. */ if (info == NULL) { return NULL; } #endif /* POSTK_DEBUG_TEMP_FIX_64 */ memset(info, '\0', sizeof(struct mcos_handler_info)); info->ud = ihk_host_os_get_usrdata(os); info->file = file; return info; } static long mcexec_debug_log(ihk_os_t os, unsigned long arg) { struct ikc_scd_packet isp; memset(&isp, '\0', sizeof isp); isp.msg = SCD_MSG_DEBUG_LOG; isp.arg = arg; mcctrl_ikc_send(os, 0, &isp); return 0; } int mcexec_close_exec(ihk_os_t os); int mcexec_destroy_per_process_data(ihk_os_t os, int pid); static void release_handler(ihk_os_t os, void *param) { struct mcos_handler_info *info = param; struct ikc_scd_packet isp; int os_ind = ihk_host_os_get_index(os); unsigned long flags; struct host_thread *thread; write_lock_irqsave(&host_thread_lock, flags); for (thread = host_threads; thread; thread = thread->next) { if (thread->handler == info) { thread->handler = NULL; } } write_unlock_irqrestore(&host_thread_lock, flags); mcexec_close_exec(os); mcexec_destroy_per_process_data(os, info->pid); memset(&isp, '\0', sizeof isp); isp.msg = SCD_MSG_CLEANUP_PROCESS; isp.pid = info->pid; dprintk("%s: SCD_MSG_CLEANUP_PROCESS, info: %p, cpu: %d\n", __FUNCTION__, info, info->cpu); mcctrl_ikc_send(os, info->cpu, &isp); if (os_ind >= 0) { delete_pid_entry(os_ind, info->pid); } kfree(param); dprintk("%s: SCD_MSG_CLEANUP_PROCESS, info: %p OK\n", __FUNCTION__, info); } static long mcexec_newprocess(ihk_os_t os, struct newprocess_desc *__user udesc, struct file *file) { struct newprocess_desc desc; struct mcos_handler_info *info; if (copy_from_user(&desc, udesc, sizeof(struct newprocess_desc))) { return -EFAULT; } info = new_mcos_handler_info(os, file); #ifdef POSTK_DEBUG_TEMP_FIX_64 /* host process is SIGKILLed fix. */ if (info == NULL) { return -ENOMEM; } #endif /* POSTK_DEBUG_TEMP_FIX_64 */ info->pid = desc.pid; ihk_os_register_release_handler(file, release_handler, info); ihk_os_set_mcos_private_data(file, info); return 0; } static long mcexec_start_image(ihk_os_t os, struct program_load_desc * __user udesc, struct file *file) { struct program_load_desc *desc; struct ikc_scd_packet isp; struct mcctrl_channel *c; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcos_handler_info *info; int ret = 0; desc = kmalloc(sizeof(*desc), GFP_KERNEL); if (!desc) { printk("%s: error: allocating program_load_desc\n", __FUNCTION__); return -ENOMEM; } if (copy_from_user(desc, udesc, sizeof(struct program_load_desc))) { ret = -EFAULT; goto out; } info = new_mcos_handler_info(os, file); #ifdef POSTK_DEBUG_TEMP_FIX_64 /* host process is SIGKILLed fix. */ if (info == NULL) { ret = -ENOMEM; goto out; } #endif /* POSTK_DEBUG_TEMP_FIX_64 */ info->pid = desc->pid; info->cpu = desc->cpu; ihk_os_register_release_handler(file, release_handler, info); ihk_os_set_mcos_private_data(file, info); c = usrdata->channels + desc->cpu; mcctrl_ikc_set_recv_cpu(os, desc->cpu); usrdata->last_thread_exec = desc->cpu; isp.msg = SCD_MSG_SCHEDULE_PROCESS; isp.ref = desc->cpu; isp.arg = desc->rprocess; ret = mcctrl_ikc_send(os, desc->cpu, &isp); if (ret < 0) { printk("%s: error: sending IKC msg\n", __FUNCTION__); } out: kfree(desc); return ret; } static DECLARE_WAIT_QUEUE_HEAD(signalq); static long mcexec_send_signal(ihk_os_t os, struct signal_desc *sigparam) { struct ikc_scd_packet isp; struct mcctrl_channel *c; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct signal_desc sig; struct mcctrl_signal msig[2]; struct mcctrl_signal *msigp; int rc; if (copy_from_user(&sig, sigparam, sizeof(struct signal_desc))) { return -EFAULT; } msigp = msig; if(((unsigned long)msig & 0xfffffffffffff000L) != ((unsigned long)(msig + 1) & 0xfffffffffffff000L)) msigp++; memset(msigp, '\0', sizeof msig); msigp->sig = sig.sig; msigp->pid = sig.pid; msigp->tid = sig.tid; memcpy(&msigp->info, &sig.info, 128); c = usrdata->channels; isp.msg = SCD_MSG_SEND_SIGNAL; isp.ref = sig.cpu; isp.pid = sig.pid; isp.arg = virt_to_phys(msigp); if ((rc = mcctrl_ikc_send(os, sig.cpu, &isp)) < 0) { printk("mcexec_send_signal: mcctrl_ikc_send ret=%d\n", rc); return rc; } wait_event_interruptible(signalq, msigp->cond != 0); return 0; } void sig_done(unsigned long arg, int err) { struct mcctrl_signal *msigp; msigp = phys_to_virt(arg); msigp->cond = 1; wake_up_interruptible(&signalq); } static long mcexec_get_cpu(ihk_os_t os) { struct ihk_cpu_info *info; info = ihk_os_get_cpu_info(os); if (!info) { printk("Error: cannot retrieve CPU info.\n"); return -EINVAL; } if (info->n_cpus < 1) { printk("Error: # of cpu is invalid.\n"); return -EINVAL; } return info->n_cpus; } static long mcexec_get_nodes(ihk_os_t os) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); if (!usrdata || !usrdata->mem_info) return -EINVAL; return usrdata->mem_info->n_numa_nodes; } extern int linux_numa_2_mckernel_numa(struct mcctrl_usrdata *udp, int numa_id); extern int mckernel_cpu_2_linux_cpu(struct mcctrl_usrdata *udp, int cpu_id); static long mcexec_get_cpuset(ihk_os_t os, unsigned long arg) { struct mcctrl_usrdata *udp = ihk_host_os_get_usrdata(os); struct mcctrl_part_exec *pe; struct get_cpu_set_arg req; #ifdef POSTK_DEBUG_ARCH_DEP_40 /* cpu_topology name change */ struct mcctrl_cpu_topology *cpu_top, *cpu_top_i; #else /* POSTK_DEBUG_ARCH_DEP_40 */ struct cpu_topology *cpu_top, *cpu_top_i; #endif /* POSTK_DEBUG_ARCH_DEP_40 */ struct cache_topology *cache_top; int cpu, cpus_assigned, cpus_to_assign, cpu_prev; int ret = 0; int mcexec_linux_numa; cpumask_t *mcexec_cpu_set = NULL; cpumask_t *cpus_used = NULL; cpumask_t *cpus_to_use = NULL; struct mcctrl_per_proc_data *ppd; struct process_list_item *pli; struct process_list_item *pli_next = NULL; struct process_list_item *pli_iter; if (!udp) { return -EINVAL; } /* Look up per-process structure */ ppd = mcctrl_get_per_proc_data(udp, task_tgid_vnr(current)); if (!ppd) { return -EINVAL; } pe = &udp->part_exec; mutex_lock(&pe->lock); if (copy_from_user(&req, (void *)arg, sizeof(req))) { printk("%s: error copying user request\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* First process to enter CPU partitioning */ if (pe->nr_processes == -1) { pe->nr_processes = req.nr_processes; pe->nr_processes_left = req.nr_processes; dprintk("%s: nr_processes: %d (partitioned exec starts)\n", __FUNCTION__, pe->nr_processes); } if (pe->nr_processes != req.nr_processes) { printk("%s: error: requested number of processes" " doesn't match current partitioned execution\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } --pe->nr_processes_left; dprintk("%s: nr_processes: %d, nr_processes_left: %d\n", __FUNCTION__, pe->nr_processes, pe->nr_processes_left); /* Wait for all processes */ pli = kmalloc(sizeof(*pli), GFP_KERNEL); if (!pli) { printk("%s: error: allocating pli\n", __FUNCTION__); goto put_and_unlock_out; } pli->task = current; pli->ready = 0; pli->timeout = 0; init_waitqueue_head(&pli->pli_wq); pli_next = NULL; /* Add ourself to the list in order of start time */ list_for_each_entry(pli_iter, &pe->pli_list, list) { #ifdef POSTK_DEBUG_ARCH_DEP_74 /* Fix HOST-Linux version dependent code (task_struct.start_time) */ #if LINUX_VERSION_CODE >= KERNEL_VERSION(3,17,0) if (pli_iter->task->start_time > current->start_time) { pli_next = pli_iter; break; } #else /* LINUX_VERSION_CODE >= KERNEL_VERSION(3,17,0) */ if ((pli_iter->task->start_time.tv_sec > current->start_time.tv_sec) || ((pli_iter->task->start_time.tv_sec == current->start_time.tv_sec) && ((pli_iter->task->start_time.tv_nsec > current->start_time.tv_nsec)))) { pli_next = pli_iter; break; } #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3,17,0) */ #else /* POSTK_DEBUG_ARCH_DEP_74 */ if ((pli_iter->task->start_time.tv_sec > current->start_time.tv_sec) || ((pli_iter->task->start_time.tv_sec == current->start_time.tv_sec) && ((pli_iter->task->start_time.tv_nsec > current->start_time.tv_nsec)))) { pli_next = pli_iter; break; } #endif /* POSTK_DEBUG_ARCH_DEP_74 */ } /* Add in front of next */ if (pli_next) { list_add_tail(&pli->list, &pli_next->list); } else { list_add_tail(&pli->list, &pe->pli_list); } pli_next = NULL; /* Last process? Wake up first in list */ if (pe->nr_processes_left == 0) { pli_next = list_first_entry(&pe->pli_list, struct process_list_item, list); list_del(&pli_next->list); pli_next->ready = 1; wake_up_interruptible(&pli_next->pli_wq); /* Reset process counter */ pe->nr_processes_left = pe->nr_processes; pe->process_rank = 0; } /* Wait for the rest if not the last or if the last but * the woken process is different than the last */ if (pe->nr_processes_left || (pli_next && pli_next != pli)) { dprintk("%s: pid: %d, waiting in list\n", __FUNCTION__, task_tgid_vnr(current)); mutex_unlock(&pe->lock); /* Timeout period: 10 secs + (#procs * 0.1sec) */ ret = wait_event_interruptible_timeout(pli->pli_wq, pli->ready, msecs_to_jiffies(10000 + req.nr_processes * 100)); mutex_lock(&pe->lock); /* First timeout task? Wake up everyone else, * but tell them we timed out */ if (ret == 0) { printk("%s: error: pid: %d, timed out, waking everyone\n", __FUNCTION__, task_tgid_vnr(current)); while (!list_empty(&pe->pli_list)) { pli_next = list_first_entry(&pe->pli_list, struct process_list_item, list); list_del(&pli_next->list); pli_next->ready = 1; pli_next->timeout = 1; wake_up_interruptible(&pli_next->pli_wq); } /* Reset process counter to start state */ pe->nr_processes = -1; ret = -ETIMEDOUT; goto put_and_unlock_out; } /* Interrupted or woken up by someone else due to time out? */ if (ret < 0 || pli->timeout) { if (ret > 0) { printk("%s: error: pid: %d, job startup timed out\n", __FUNCTION__, task_tgid_vnr(current)); ret = -ETIMEDOUT; } goto put_and_unlock_out; } /* Incorrect wakeup state? */ if (!pli->ready) { printk("%s: error: pid: %d, not ready but woken?\n", __FUNCTION__, task_tgid_vnr(current)); ret = -EINVAL; goto put_and_unlock_out; } dprintk("%s: pid: %d, woken up\n", __FUNCTION__, task_tgid_vnr(current)); } --pe->nr_processes_left; kfree(pli); cpus_to_assign = udp->cpu_info->n_cpus / req.nr_processes; cpus_used = kmalloc(sizeof(cpumask_t), GFP_KERNEL); cpus_to_use = kmalloc(sizeof(cpumask_t), GFP_KERNEL); mcexec_cpu_set = kmalloc(sizeof(cpumask_t), GFP_KERNEL); if (!cpus_used || !cpus_to_use || !mcexec_cpu_set) { printk("%s: error: allocating cpu masks\n", __FUNCTION__); ret = -ENOMEM; goto put_and_unlock_out; } memcpy(cpus_used, &pe->cpus_used, sizeof(cpumask_t)); memset(cpus_to_use, 0, sizeof(cpumask_t)); memset(mcexec_cpu_set, 0, sizeof(cpumask_t)); /* Find the first unused CPU */ cpu = cpumask_next_zero(-1, cpus_used); if (cpu >= udp->cpu_info->n_cpus) { printk("%s: error: no more CPUs available\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) cpumask_set_cpu(cpu, cpus_used); cpumask_set_cpu(cpu, cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpumask_set_cpu(udp->cpu_info->ikc_map[cpu], mcexec_cpu_set); } #else cpu_set(cpu, *cpus_used); cpu_set(cpu, *cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpu_set(udp->cpu_info->ikc_map[cpu], *mcexec_cpu_set); } #endif cpu_prev = cpu; dprintk("%s: CPU %d assigned (first)\n", __FUNCTION__, cpu); for (cpus_assigned = 1; cpus_assigned < cpus_to_assign; ++cpus_assigned) { int node; cpu_top = NULL; /* Find the topology object of the last core assigned */ list_for_each_entry(cpu_top_i, &udp->cpu_topology_list, chain) { if (cpu_top_i->mckernel_cpu_id == cpu_prev) { cpu_top = cpu_top_i; break; } } if (!cpu_top) { printk("%s: error: couldn't find CPU topology info\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* Find a core sharing the same cache iterating caches from * the most inner one outwards */ list_for_each_entry(cache_top, &cpu_top->cache_list, chain) { for_each_cpu(cpu, &cache_top->shared_cpu_map) { #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) if (!cpumask_test_cpu(cpu, cpus_used)) { #else if (!cpu_isset(cpu, *cpus_used)) { #endif #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) cpumask_set_cpu(cpu, cpus_used); cpumask_set_cpu(cpu, cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpumask_set_cpu(udp->cpu_info->ikc_map[cpu], mcexec_cpu_set); } #else cpu_set(cpu, *cpus_used); cpu_set(cpu, *cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpu_set(udp->cpu_info->ikc_map[cpu], *mcexec_cpu_set); } #endif cpu_prev = cpu; dprintk("%s: CPU %d assigned (same cache L%lu)\n", __FUNCTION__, cpu, cache_top->saved->level); goto next_cpu; } } } /* No CPU? Find a core from the same NUMA node */ node = linux_numa_2_mckernel_numa(udp, cpu_to_node(mckernel_cpu_2_linux_cpu(udp, cpu_prev))); for_each_cpu_not(cpu, cpus_used) { /* Invalid CPU? */ if (cpu >= udp->cpu_info->n_cpus) break; /* Found one */ if (node == linux_numa_2_mckernel_numa(udp, cpu_to_node(mckernel_cpu_2_linux_cpu(udp, cpu)))) { #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) cpumask_set_cpu(cpu, cpus_used); cpumask_set_cpu(cpu, cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpumask_set_cpu(udp->cpu_info->ikc_map[cpu], mcexec_cpu_set); } #else cpu_set(cpu, *cpus_used); cpu_set(cpu, *cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpu_set(udp->cpu_info->ikc_map[cpu], *mcexec_cpu_set); } #endif cpu_prev = cpu; dprintk("%s: CPU %d assigned (same NUMA)\n", __FUNCTION__, cpu); goto next_cpu; } } /* No CPU? Simply find the next unused one */ cpu = cpumask_next_zero(-1, cpus_used); if (cpu >= udp->cpu_info->n_cpus) { printk("%s: error: no more CPUs available\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) cpumask_set_cpu(cpu, cpus_used); cpumask_set_cpu(cpu, cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpumask_set_cpu(udp->cpu_info->ikc_map[cpu], mcexec_cpu_set); } #else cpu_set(cpu, *cpus_used); cpu_set(cpu, *cpus_to_use); if (udp->cpu_info->ikc_mapped) { cpu_set(udp->cpu_info->ikc_map[cpu], *mcexec_cpu_set); } #endif cpu_prev = cpu; dprintk("%s: CPU %d assigned (unused)\n", __FUNCTION__, cpu); next_cpu: continue; } /* Found all cores, let user know */ if (copy_to_user(req.cpu_set, cpus_to_use, (req.cpu_set_size < sizeof(cpumask_t) ? req.cpu_set_size : sizeof(cpumask_t)))) { printk("%s: error copying mask to user\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* Copy IKC target core */ cpu = cpumask_next(-1, cpus_to_use); if (copy_to_user(req.target_core, &cpu, sizeof(cpu))) { printk("%s: error copying target core to user\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* Copy rank */ if (copy_to_user(req.process_rank, &pe->process_rank, sizeof(int))) { printk("%s: error copying process rank to user\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* mcexec NUMA to bind to */ mcexec_linux_numa = cpu_to_node(mckernel_cpu_2_linux_cpu(udp, cpu)); if (copy_to_user(req.mcexec_linux_numa, &mcexec_linux_numa, sizeof(mcexec_linux_numa))) { printk("%s: error copying mcexec Linux NUMA id\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } /* mcexec cpu_set to bind to if user requested */ if (req.mcexec_cpu_set && udp->cpu_info->ikc_mapped) { int ikc_mapped = 1; if (copy_to_user(req.mcexec_cpu_set, mcexec_cpu_set, (req.mcexec_cpu_set_size < sizeof(cpumask_t) ? req.mcexec_cpu_set_size : sizeof(cpumask_t)))) { printk("%s: error copying mcexec CPU set to user\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } if (copy_to_user(req.ikc_mapped, &ikc_mapped, sizeof(ikc_mapped))) { printk("%s: error copying ikc_mapped\n", __FUNCTION__); ret = -EINVAL; goto put_and_unlock_out; } } /* Save in per-process structure */ memcpy(&ppd->cpu_set, cpus_to_use, sizeof(cpumask_t)); ppd->ikc_target_cpu = cpu; /* Commit used cores to OS structure */ memcpy(&pe->cpus_used, cpus_used, sizeof(*cpus_used)); /* Reset if last process */ if (pe->nr_processes_left == 0) { dprintk("%s: nr_processes: %d (partitioned exec ends)\n", __FUNCTION__, pe->nr_processes); pe->nr_processes = -1; memset(&pe->cpus_used, 0, sizeof(pe->cpus_used)); } /* Otherwise wake up next process in list */ else { ++pe->process_rank; pli_next = list_first_entry(&pe->pli_list, struct process_list_item, list); list_del(&pli_next->list); pli_next->ready = 1; wake_up_interruptible(&pli_next->pli_wq); } dprintk("%s: pid: %d, ret: 0\n", __FUNCTION__, task_tgid_vnr(current)); ret = 0; put_and_unlock_out: kfree(cpus_to_use); kfree(cpus_used); kfree(mcexec_cpu_set); mcctrl_put_per_proc_data(ppd); mutex_unlock(&pe->lock); return ret; } #define THREAD_POOL_PER_CPU_THRESHOLD (128) int mcctrl_get_num_pool_threads(ihk_os_t os) { struct mcctrl_usrdata *ud = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd = NULL; int hash; unsigned long flags; int nr_threads = 0; if (!ud) { return -EINVAL; } for (hash = 0; hash < MCCTRL_PER_PROC_DATA_HASH_SIZE; ++hash) { read_lock_irqsave(&ud->per_proc_data_hash_lock[hash], flags); list_for_each_entry(ppd, &ud->per_proc_data_hash[hash], hash) { struct pid *vpid; struct task_struct *ppd_task; vpid = find_vpid(ppd->pid); if (!vpid) { printk("%s: WARNING: couldn't find vpid with PID number %d?\n", __FUNCTION__, ppd->pid); continue; } ppd_task = get_pid_task(vpid, PIDTYPE_PID); if (!ppd_task) { printk("%s: WARNING: couldn't find task with PID %d?\n", __FUNCTION__, ppd->pid); continue; } nr_threads += get_nr_threads(ppd_task); put_task_struct(ppd_task); } read_unlock_irqrestore(&ud->per_proc_data_hash_lock[hash], flags); } dprintk("%s: nr_threads: %d, num_online_cpus: %d\n", __FUNCTION__, nr_threads, num_online_cpus()); return (nr_threads > (num_online_cpus() * THREAD_POOL_PER_CPU_THRESHOLD)); } int mcctrl_add_per_proc_data(struct mcctrl_usrdata *ud, int pid, struct mcctrl_per_proc_data *ppd) { struct mcctrl_per_proc_data *ppd_iter; int hash = (pid & MCCTRL_PER_PROC_DATA_HASH_MASK); int ret = 0; unsigned long flags; /* Check if data for this thread exists and add if not */ write_lock_irqsave(&ud->per_proc_data_hash_lock[hash], flags); list_for_each_entry(ppd_iter, &ud->per_proc_data_hash[hash], hash) { if (ppd_iter->pid == pid) { ret = -EBUSY; goto out; } } list_add_tail(&ppd->hash, &ud->per_proc_data_hash[hash]); out: write_unlock_irqrestore(&ud->per_proc_data_hash_lock[hash], flags); return ret; } /* NOTE: per-process data is refcounted. * For every get call the user should call put. */ struct mcctrl_per_proc_data *mcctrl_get_per_proc_data( struct mcctrl_usrdata *ud, int pid) { struct mcctrl_per_proc_data *ppd_iter, *ppd = NULL; int hash = (pid & MCCTRL_PER_PROC_DATA_HASH_MASK); unsigned long flags; /* Check if data for this process exists and return it */ read_lock_irqsave(&ud->per_proc_data_hash_lock[hash], flags); list_for_each_entry(ppd_iter, &ud->per_proc_data_hash[hash], hash) { if (ppd_iter->pid == pid) { ppd = ppd_iter; break; } } if (ppd) { atomic_inc(&ppd->refcount); } read_unlock_irqrestore(&ud->per_proc_data_hash_lock[hash], flags); return ppd; } /* Drop reference. If zero, remove and deallocate */ void mcctrl_put_per_proc_data(struct mcctrl_per_proc_data *ppd) { int hash; unsigned long flags; int i; struct wait_queue_head_list_node *wqhln; struct wait_queue_head_list_node *wqhln_next; struct ikc_scd_packet *packet; if (!ppd) return; hash = (ppd->pid & MCCTRL_PER_PROC_DATA_HASH_MASK); /* Removal from hash table and the refcount reaching zero * have to happen atomically */ write_lock_irqsave(&ppd->ud->per_proc_data_hash_lock[hash], flags); if (!atomic_dec_and_test(&ppd->refcount)) { write_unlock_irqrestore(&ppd->ud->per_proc_data_hash_lock[hash], flags); return; } list_del(&ppd->hash); write_unlock_irqrestore(&ppd->ud->per_proc_data_hash_lock[hash], flags); dprintk("%s: deallocating PPD for pid %d\n", __FUNCTION__, ppd->pid); for (i = 0; i < MCCTRL_PER_THREAD_DATA_HASH_SIZE; i++) { struct mcctrl_per_thread_data *ptd; struct mcctrl_per_thread_data *next; list_for_each_entry_safe(ptd, next, ppd->per_thread_data_hash + i, hash) { packet = ptd->data; list_del(&ptd->hash); kfree(ptd); /* We use ERESTARTSYS to tell the LWK that the proxy * process is gone and the application should be terminated */ __return_syscall(ppd->ud->os, packet, -ERESTARTSYS, packet->req.rtid); ihk_ikc_release_packet( (struct ihk_ikc_free_packet *)packet, (ppd->ud->ikc2linux[smp_processor_id()] ? ppd->ud->ikc2linux[smp_processor_id()] : ppd->ud->ikc2linux[0])); } } flags = ihk_ikc_spinlock_lock(&ppd->wq_list_lock); list_for_each_entry_safe(wqhln, wqhln_next, &ppd->wq_req_list, list) { list_del(&wqhln->list); packet = wqhln->packet; kfree(wqhln); /* We use ERESTARTSYS to tell the LWK that the proxy * process is gone and the application should be terminated */ __return_syscall(ppd->ud->os, packet, -ERESTARTSYS, packet->req.rtid); ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (ppd->ud->ikc2linux[smp_processor_id()] ? ppd->ud->ikc2linux[smp_processor_id()] : ppd->ud->ikc2linux[0])); } ihk_ikc_spinlock_unlock(&ppd->wq_list_lock, flags); pager_remove_process(ppd); kfree(ppd); } /* * Called indirectly from the IKC message handler. */ int mcexec_syscall(struct mcctrl_usrdata *ud, struct ikc_scd_packet *packet) { struct wait_queue_head_list_node *wqhln = NULL; struct wait_queue_head_list_node *wqhln_iter; struct wait_queue_head_list_node *wqhln_alloc = NULL; int pid = packet->pid; unsigned long flags; struct mcctrl_per_proc_data *ppd; /* Get a reference to per-process structure */ ppd = mcctrl_get_per_proc_data(ud, pid); if (unlikely(!ppd)) { kprintf("%s: ERROR: no per-process structure for PID %d, " "syscall nr: %lu\n", __FUNCTION__, pid, packet->req.number); /* We use ERESTARTSYS to tell the LWK that the proxy * process is gone and the application should be terminated */ __return_syscall(ud->os, packet, -ERESTARTSYS, packet->req.rtid); ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (ud->ikc2linux[smp_processor_id()] ? ud->ikc2linux[smp_processor_id()] : ud->ikc2linux[0])); return -1; } dprintk("%s: (packet_handler) rtid: %d, ttid: %d, sys nr: %lu\n", __FUNCTION__, packet->req.rtid, packet->req.ttid, packet->req.number); /* * Three scenarios are possible: * - Find the designated thread if req->ttid is specified. * - Find any available thread if req->ttid is zero. * - Add a request element if no threads are available. */ flags = ihk_ikc_spinlock_lock(&ppd->wq_list_lock); /* Is this a request for a specific thread? See if it's waiting */ if (unlikely(packet->req.ttid)) { list_for_each_entry(wqhln_iter, &ppd->wq_list_exact, list) { if (packet->req.ttid != wqhln_iter->rtid) continue; wqhln = wqhln_iter; break; } if (!wqhln) { printk("%s: WARNING: no target thread found for exact request??\n", __FUNCTION__); } } /* Is there any thread available? */ else { list_for_each_entry(wqhln_iter, &ppd->wq_list, list) { if (wqhln_iter->task && !wqhln_iter->req) { wqhln = wqhln_iter; break; } } } /* If no match found, add request to pending request list */ if (unlikely(!wqhln)) { retry_alloc: wqhln_alloc = kmalloc(sizeof(*wqhln), GFP_ATOMIC); if (!wqhln_alloc) { printk("WARNING: coudln't alloc wait queue head, retrying..\n"); goto retry_alloc; } wqhln = wqhln_alloc; wqhln->req = 0; wqhln->task = NULL; init_waitqueue_head(&wqhln->wq_syscall); list_add_tail(&wqhln->list, &ppd->wq_req_list); } wqhln->packet = packet; wqhln->req = 1; wake_up(&wqhln->wq_syscall); ihk_ikc_spinlock_unlock(&ppd->wq_list_lock, flags); mcctrl_put_per_proc_data(ppd); return 0; } /* * Called from an mcexec thread via ioctl(). */ int mcexec_wait_syscall(ihk_os_t os, struct syscall_wait_desc *__user req) { struct ikc_scd_packet *packet; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct wait_queue_head_list_node *wqhln = NULL; struct wait_queue_head_list_node *wqhln_iter; int ret = 0; unsigned long irqflags; struct mcctrl_per_proc_data *ppd; /* Get a reference to per-process structure */ ppd = mcctrl_get_per_proc_data(usrdata, task_tgid_vnr(current)); if (unlikely(!ppd)) { kprintf("%s: ERROR: no per-process structure for PID %d??\n", __FUNCTION__, task_tgid_vnr(current)); return -EINVAL; } packet = (struct ikc_scd_packet *)mcctrl_get_per_thread_data(ppd, current); if (packet) { printk("%s: ERROR: packet %p is already registered for thread %d\n", __FUNCTION__, packet, task_pid_vnr(current)); ret = -EBUSY; goto put_ppd_out; } retry: /* Prepare per-thread wait queue head or find a valid request */ irqflags = ihk_ikc_spinlock_lock(&ppd->wq_list_lock); /* First see if there is a valid request already that is not yet taken */ list_for_each_entry(wqhln_iter, &ppd->wq_req_list, list) { if (wqhln_iter->task == NULL && wqhln_iter->req) { wqhln = wqhln_iter; wqhln->task = current; list_del(&wqhln->list); break; } } if (!wqhln) { retry_alloc: wqhln = kmalloc(sizeof(*wqhln), GFP_ATOMIC); if (!wqhln) { printk("WARNING: coudln't alloc wait queue head, retrying..\n"); goto retry_alloc; } wqhln->task = current; wqhln->req = 0; wqhln->packet = NULL; init_waitqueue_head(&wqhln->wq_syscall); list_add(&wqhln->list, &ppd->wq_list); ihk_ikc_spinlock_unlock(&ppd->wq_list_lock, irqflags); /* Wait for a request.. */ ret = wait_event_interruptible(wqhln->wq_syscall, wqhln->req); /* Remove per-thread wait queue head */ irqflags = ihk_ikc_spinlock_lock(&ppd->wq_list_lock); list_del(&wqhln->list); } ihk_ikc_spinlock_unlock(&ppd->wq_list_lock, irqflags); if (ret == -ERESTARTSYS) { /* Is the request valid? */ if (wqhln->req) { packet = wqhln->packet; kfree(wqhln); wqhln = NULL; ret = -EINTR; goto put_ppd_out; } else { kfree(wqhln); wqhln = NULL; ret = -EINTR; goto put_ppd_out; } } packet = wqhln->packet; kfree(wqhln); wqhln = NULL; dprintk("%s: tid: %d request from CPU %d\n", __FUNCTION__, task_pid_vnr(current), packet->ref); mb(); if (!packet->req.valid) { printk("%s: ERROR: stray wakeup pid: %d, tid: %d: SC %lu\n", __FUNCTION__, task_tgid_vnr(current), task_pid_vnr(current), packet->req.number); ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (usrdata->ikc2linux[smp_processor_id()] ? usrdata->ikc2linux[smp_processor_id()] : usrdata->ikc2linux[0])); goto retry; } packet->req.valid = 0; /* ack */ dprintk("%s: system call: %lu, args[0]: %lu, args[1]: %lu, args[2]: %lu, " "args[3]: %lu, args[4]: %lu, args[5]: %lu\n", __FUNCTION__, packet->req.number, packet->req.args[0], packet->req.args[1], packet->req.args[2], packet->req.args[3], packet->req.args[4], packet->req.args[5]); if (mcctrl_add_per_thread_data(ppd, current, packet) < 0) { kprintf("%s: error adding per-thread data\n", __FUNCTION__); ret = -EINVAL;; goto put_ppd_out; } if (__do_in_kernel_syscall(os, packet)) { if (copy_to_user(&req->sr, &packet->req, sizeof(struct syscall_request))) { if (mcctrl_delete_per_thread_data(ppd, current) < 0) { kprintf("%s: error deleting per-thread data\n", __FUNCTION__); } ret = -EINVAL;; goto put_ppd_out; } if (copy_to_user(&req->cpu, &packet->ref, sizeof(req->cpu))) { if (mcctrl_delete_per_thread_data(ppd, current) < 0) { kprintf("%s: error deleting per-thread data\n", __FUNCTION__); } ret = -EINVAL; goto put_ppd_out; } ret = 0; goto put_ppd_out; } ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (usrdata->ikc2linux[smp_processor_id()] ? usrdata->ikc2linux[smp_processor_id()] : usrdata->ikc2linux[0])); if (mcctrl_delete_per_thread_data(ppd, current) < 0) { kprintf("%s: error deleting per-thread data\n", __FUNCTION__); ret = -EINVAL;; goto put_ppd_out; } goto retry; put_ppd_out: mcctrl_put_per_proc_data(ppd); return ret; } long mcexec_pin_region(ihk_os_t os, unsigned long *__user arg) { struct prepare_dma_desc desc; int pin_shift = 16; int order; unsigned long a; if (copy_from_user(&desc, arg, sizeof(struct prepare_dma_desc))) { return -EFAULT; } order = pin_shift - PAGE_SHIFT; if(desc.size > 0){ order = get_order (desc.size); } a = __get_free_pages(GFP_KERNEL, order); if (!a) { return -ENOMEM; } a = virt_to_phys((void *)a); if (copy_to_user((void*)desc.pa, &a, sizeof(unsigned long))) { return -EFAULT; } return 0; } long mcexec_free_region(ihk_os_t os, unsigned long *__user arg) { struct free_dma_desc desc; int pin_shift = 16; int order; if (copy_from_user(&desc, arg, sizeof(struct free_dma_desc))) { return -EFAULT; } order = pin_shift - PAGE_SHIFT; if(desc.size > 0){ order = get_order (desc.size); } if(desc.pa > 0){ free_pages((unsigned long)phys_to_virt(desc.pa), order); } return 0; } long mcexec_load_syscall(ihk_os_t os, struct syscall_load_desc *__user arg) { struct syscall_load_desc desc; unsigned long phys; void *rpm; if (copy_from_user(&desc, arg, sizeof(struct syscall_load_desc))) { return -EFAULT; } phys = ihk_device_map_memory(ihk_os_to_dev(os), desc.src, desc.size); #ifdef CONFIG_MIC rpm = ioremap_wc(phys, desc.size); #else rpm = ihk_device_map_virtual(ihk_os_to_dev(os), phys, desc.size, NULL, 0); #endif dprintk("mcexec_load_syscall: %p (desc.size: %lu)\n", rpm, desc.size); if (copy_to_user((void *__user)desc.dest, rpm, desc.size)) { return -EFAULT; } #ifdef CONFIG_MIC iounmap(rpm); #else ihk_device_unmap_virtual(ihk_os_to_dev(os), rpm, desc.size); #endif ihk_device_unmap_memory(ihk_os_to_dev(os), phys, desc.size); return 0; } long mcexec_ret_syscall(ihk_os_t os, struct syscall_ret_desc *__user arg) { struct syscall_ret_desc ret; struct ikc_scd_packet *packet; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd; int error = 0; if (copy_from_user(&ret, arg, sizeof(struct syscall_ret_desc))) { return -EFAULT; } /* Look up per-process structure */ ppd = mcctrl_get_per_proc_data(usrdata, task_tgid_vnr(current)); if (!ppd) { kprintf("%s: ERROR: no per-process structure for PID %d??\n", __FUNCTION__, task_tgid_vnr(current)); return -EINVAL; } packet = (struct ikc_scd_packet *)mcctrl_get_per_thread_data(ppd, current); if (!packet) { kprintf("%s: ERROR: no packet registered for TID %d\n", __FUNCTION__, task_pid_vnr(current)); error = -EINVAL; goto out; } mcctrl_delete_per_thread_data(ppd, current); if (ret.size > 0) { /* Host => Accel. Write is fast. */ unsigned long phys; void *rpm; phys = ihk_device_map_memory(ihk_os_to_dev(os), ret.dest, ret.size); #ifdef CONFIG_MIC rpm = ioremap_wc(phys, ret.size); #else rpm = ihk_device_map_virtual(ihk_os_to_dev(os), phys, ret.size, NULL, 0); #endif if (copy_from_user(rpm, (void *__user)ret.src, ret.size)) { error = -EFAULT; goto out; } #ifdef CONFIG_MIC iounmap(rpm); #else ihk_device_unmap_virtual(ihk_os_to_dev(os), rpm, ret.size); #endif ihk_device_unmap_memory(ihk_os_to_dev(os), phys, ret.size); } __return_syscall(os, packet, ret.ret, task_pid_vnr(current)); error = 0; out: /* Free packet */ ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (usrdata->ikc2linux[smp_processor_id()] ? usrdata->ikc2linux[smp_processor_id()] : usrdata->ikc2linux[0])); mcctrl_put_per_proc_data(ppd); return error; } LIST_HEAD(mckernel_exec_files); DEFINE_SEMAPHORE(mckernel_exec_file_lock); struct mckernel_exec_file { ihk_os_t os; pid_t pid; struct file *fp; struct list_head list; }; #if LINUX_VERSION_CODE < KERNEL_VERSION(3,5,0) #define GUIDVAL(x) (x) #else #define GUIDVAL(x) ((x).val) #endif int mcexec_getcred(unsigned long phys) { int *virt = phys_to_virt(phys); #ifdef POSTK_DEBUG_TEMP_FIX_45 /* setfsgid()/setfsuid() mismatch fix. */ int ret = -EINVAL; if (virt[0] == 0 || virt[0] == task_pid_vnr(current)) { virt[0] = GUIDVAL(current_uid()); virt[1] = GUIDVAL(current_euid()); virt[2] = GUIDVAL(current_suid()); virt[3] = GUIDVAL(current_fsuid()); virt[4] = GUIDVAL(current_gid()); virt[5] = GUIDVAL(current_egid()); virt[6] = GUIDVAL(current_sgid()); virt[7] = GUIDVAL(current_fsgid()); ret = 0; } else { const struct task_struct *task_p = pid_task(find_get_pid(virt[0]), PIDTYPE_PID); if (task_p) { const struct cred *t_cred = __task_cred(task_p); rcu_read_lock(); virt[0] = GUIDVAL(t_cred->uid); virt[1] = GUIDVAL(t_cred->euid); virt[2] = GUIDVAL(t_cred->suid); virt[3] = GUIDVAL(t_cred->fsuid); virt[4] = GUIDVAL(t_cred->gid); virt[5] = GUIDVAL(t_cred->egid); virt[6] = GUIDVAL(t_cred->sgid); virt[7] = GUIDVAL(t_cred->fsgid); rcu_read_unlock(); ret = 0; } } return ret; #else /* POSTK_DEBUG_TEMP_FIX_45 */ virt[0] = GUIDVAL(current_uid()); virt[1] = GUIDVAL(current_euid()); virt[2] = GUIDVAL(current_suid()); virt[3] = GUIDVAL(current_fsuid()); virt[4] = GUIDVAL(current_gid()); virt[5] = GUIDVAL(current_egid()); virt[6] = GUIDVAL(current_sgid()); virt[7] = GUIDVAL(current_fsgid()); return 0; #endif /* POSTK_DEBUG_TEMP_FIX_45 */ } int mcexec_getcredv(int __user *virt) { int wk[8]; wk[0] = GUIDVAL(current_uid()); wk[1] = GUIDVAL(current_euid()); wk[2] = GUIDVAL(current_suid()); wk[3] = GUIDVAL(current_fsuid()); wk[4] = GUIDVAL(current_gid()); wk[5] = GUIDVAL(current_egid()); wk[6] = GUIDVAL(current_sgid()); wk[7] = GUIDVAL(current_fsgid()); if(copy_to_user(virt, wk, sizeof(int) * 8)) return -EFAULT; return 0; } int mcexec_create_per_process_data(ihk_os_t os) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd = NULL; int i; ppd = mcctrl_get_per_proc_data(usrdata, task_tgid_vnr(current)); if (ppd) { printk("%s: WARNING: per-process data for pid %d already exists\n", __FUNCTION__, task_tgid_vnr(current)); mcctrl_put_per_proc_data(ppd); return -EINVAL; } ppd = kmalloc(sizeof(*ppd), GFP_KERNEL); if (!ppd) { printk("%s: ERROR: allocating per-process data\n", __FUNCTION__); return -ENOMEM; } ppd->ud = usrdata; ppd->pid = task_tgid_vnr(current); /* * XXX: rpgtable will be updated in __do_in_kernel_syscall() * under case __NR_munmap */ INIT_LIST_HEAD(&ppd->wq_list); INIT_LIST_HEAD(&ppd->wq_req_list); INIT_LIST_HEAD(&ppd->wq_list_exact); init_waitqueue_head(&ppd->wq_prepare); init_waitqueue_head(&ppd->wq_procfs); spin_lock_init(&ppd->wq_list_lock); memset(&ppd->cpu_set, 0, sizeof(cpumask_t)); ppd->ikc_target_cpu = 0; /* Final ref will be dropped in release_handler() through * mcexec_destroy_per_process_data() */ atomic_set(&ppd->refcount, 1); for (i = 0; i < MCCTRL_PER_THREAD_DATA_HASH_SIZE; ++i) { INIT_LIST_HEAD(&ppd->per_thread_data_hash[i]); rwlock_init(&ppd->per_thread_data_hash_lock[i]); } INIT_LIST_HEAD(&ppd->devobj_pager_list); sema_init(&ppd->devobj_pager_lock, 1); if (mcctrl_add_per_proc_data(usrdata, ppd->pid, ppd) < 0) { printk("%s: error adding per process data\n", __FUNCTION__); kfree(ppd); return -EINVAL; } pager_add_process(); dprintk("%s: PID: %d, counter: %d\n", __FUNCTION__, ppd->pid, atomic_read(&ppd->refcount)); return 0; } int mcexec_destroy_per_process_data(ihk_os_t os, int pid) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd = NULL; ppd = mcctrl_get_per_proc_data(usrdata, pid); if (ppd) { /* One for the reference and one for deallocation. * XXX: actual deallocation may not happen here */ mcctrl_put_per_proc_data(ppd); mcctrl_put_per_proc_data(ppd); } else { printk("WARNING: no per process data for PID %d ?\n", task_tgid_vnr(current)); } return 0; } int mcexec_open_exec(ihk_os_t os, char * __user filename) { struct file *file; struct mckernel_exec_file *mcef; struct mckernel_exec_file *mcef_iter; int retval; int os_ind = ihk_host_os_get_index(os); char *pathbuf = NULL; char *fullpath = NULL; char *kfilename = NULL; int len; if (os_ind < 0) { return -EINVAL; } pathbuf = kmalloc(PATH_MAX, GFP_TEMPORARY); if (!pathbuf) { retval = -ENOMEM; goto out; } kfilename = kmalloc(PATH_MAX, GFP_TEMPORARY); if (!kfilename) { retval = -ENOMEM; kfree(pathbuf); goto out; } len = strncpy_from_user(kfilename, filename, PATH_MAX); if (unlikely(len < 0)) { retval = -EINVAL; goto out_free; } file = open_exec(kfilename); retval = PTR_ERR(file); if (IS_ERR(file)) { goto out_free; } fullpath = d_path(&file->f_path, pathbuf, PATH_MAX); if (IS_ERR(fullpath)) { retval = PTR_ERR(fullpath); goto out_free; } mcef = kmalloc(sizeof(*mcef), GFP_KERNEL); if (!mcef) { retval = -ENOMEM; goto out_put_file; } down(&mckernel_exec_file_lock); /* Find previous file (if exists) and drop it */ list_for_each_entry(mcef_iter, &mckernel_exec_files, list) { if (mcef_iter->os == os && mcef_iter->pid == task_tgid_vnr(current)) { allow_write_access(mcef_iter->fp); fput(mcef_iter->fp); list_del(&mcef_iter->list); kfree(mcef_iter); break; } } /* Add new exec file to the list */ mcef->os = os; mcef->pid = task_tgid_vnr(current); mcef->fp = file; list_add_tail(&mcef->list, &mckernel_exec_files); /* Create /proc/self/exe entry */ add_pid_entry(os_ind, task_tgid_vnr(current)); proc_exe_link(os_ind, task_tgid_vnr(current), fullpath); up(&mckernel_exec_file_lock); dprintk("%d open_exec and holding file: %s\n", (int)task_tgid_vnr(current), kfilename); kfree(kfilename); kfree(pathbuf); return 0; out_put_file: fput(file); out_free: kfree(pathbuf); kfree(kfilename); out: return retval; } int mcexec_close_exec(ihk_os_t os) { struct mckernel_exec_file *mcef = NULL; int found = 0; int os_ind = ihk_host_os_get_index(os); if (os_ind < 0) { return EINVAL; } down(&mckernel_exec_file_lock); list_for_each_entry(mcef, &mckernel_exec_files, list) { if (mcef->os == os && mcef->pid == task_tgid_vnr(current)) { allow_write_access(mcef->fp); fput(mcef->fp); list_del(&mcef->list); kfree(mcef); found = 1; dprintk("%d close_exec dropped executable \n", (int)task_tgid_vnr(current)); break; } } up(&mckernel_exec_file_lock); return (found ? 0 : EINVAL); } long mcexec_strncpy_from_user(ihk_os_t os, struct strncpy_from_user_desc * __user arg) { struct strncpy_from_user_desc desc; void *buf; void *dest; void *src; unsigned long remain; long want; long copied; if (copy_from_user(&desc, arg, sizeof(desc))) { return -EFAULT; } buf = (void *)__get_free_page(GFP_KERNEL); if (!buf) { return -ENOMEM; } dest = desc.dest; src = desc.src; remain = desc.n; want = 0; copied = 0; while ((remain > 0) && (want == copied)) { want = (remain > PAGE_SIZE)? PAGE_SIZE: remain; copied = strncpy_from_user(buf, src, want); if (copied == want) { if (copy_to_user(dest, buf, copied)) { copied = -EFAULT; } } else if (copied >= 0) { if (copy_to_user(dest, buf, copied+1)) { copied = -EFAULT; } } dest += copied; src += copied; remain -= copied; } desc.result = (copied >= 0)? (desc.n - remain): copied; free_page((unsigned long)buf); if (copy_to_user(arg, &desc, sizeof(*arg))) { return -EFAULT; } return 0; } long mcexec_sys_mount(struct sys_mount_desc *__user arg) { struct sys_mount_desc desc; struct cred *promoted; const struct cred *original; int ret; if (copy_from_user(&desc, arg, sizeof(desc))) { return -EFAULT; } promoted = prepare_creds(); if (!promoted) { return -ENOMEM; } cap_raise(promoted->cap_effective, CAP_SYS_ADMIN); original = override_creds(promoted); #ifdef MCCTRL_KSYM_sys_mount ret = mcctrl_sys_mount(desc.dev_name, desc.dir_name, desc.type, desc.flags, desc.data); #else ret = -EFAULT; #endif revert_creds(original); put_cred(promoted); return ret; } long mcexec_sys_umount(struct sys_mount_desc *__user arg) { struct sys_umount_desc desc; struct cred *promoted; const struct cred *original; int ret; if (copy_from_user(&desc, arg, sizeof(desc))) { return -EFAULT; } promoted = prepare_creds(); if (!promoted) { return -ENOMEM; } cap_raise(promoted->cap_effective, CAP_SYS_ADMIN); original = override_creds(promoted); #ifdef MCCTRL_KSYM_sys_umount ret = mcctrl_sys_umount(desc.dir_name, MNT_FORCE); #else ret = -EFAULT; #endif revert_creds(original); put_cred(promoted); return ret; } long mcexec_sys_unshare(struct sys_unshare_desc *__user arg) { struct sys_unshare_desc desc; struct cred *promoted; const struct cred *original; int ret; if (copy_from_user(&desc, arg, sizeof(desc))) { return -EFAULT; } promoted = prepare_creds(); if (!promoted) { return -ENOMEM; } cap_raise(promoted->cap_effective, CAP_SYS_ADMIN); original = override_creds(promoted); #if MCCTRL_KSYM_sys_unshare ret = mcctrl_sys_unshare(desc.unshare_flags); #else ret = -EFAULT; #endif revert_creds(original); put_cred(promoted); return ret; } static DECLARE_WAIT_QUEUE_HEAD(perfctrlq); long mcctrl_perf_num(ihk_os_t os, unsigned long arg) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); usrdata->perf_event_num = arg; return 0; } long mcctrl_perf_set(ihk_os_t os, struct ihk_perf_event_attr *__user arg) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct ikc_scd_packet isp; struct perf_ctrl_desc *perf_desc = NULL; struct ihk_perf_event_attr attr; struct ihk_cpu_info *info = ihk_os_get_cpu_info(os); int ret = 0; int i = 0, j = 0; for (i = 0; i < usrdata->perf_event_num; i++) { if (copy_from_user(&attr, &arg[i], sizeof(struct ihk_perf_event_attr))) { printk("%s: error: copying ihk_perf_event_attr from user\n", __FUNCTION__); return -EINVAL; } for (j = 0; j < info->n_cpus; j++) { perf_desc = kmalloc(sizeof(struct perf_ctrl_desc), GFP_KERNEL); if (!perf_desc) { printk("%s: error: allocating perf_ctrl_desc\n", __FUNCTION__); return -ENOMEM; } memset(perf_desc, '\0', sizeof(struct perf_ctrl_desc)); perf_desc->ctrl_type = PERF_CTRL_SET; perf_desc->status = 0; perf_desc->target_cntr = i; perf_desc->config = attr.config; perf_desc->exclude_kernel = attr.exclude_kernel; perf_desc->exclude_user = attr.exclude_user; memset(&isp, '\0', sizeof(struct ikc_scd_packet)); isp.msg = SCD_MSG_PERF_CTRL; isp.arg = virt_to_phys(perf_desc); if ((ret = mcctrl_ikc_send(os, j, &isp)) < 0) { printk("%s: mcctrl_ikc_send ret=%d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } ret = wait_event_interruptible(perfctrlq, perf_desc->status); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } kfree(perf_desc); } } return usrdata->perf_event_num; } long mcctrl_perf_get(ihk_os_t os, unsigned long *__user arg) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct ikc_scd_packet isp; struct perf_ctrl_desc *perf_desc = NULL; struct ihk_cpu_info *info = ihk_os_get_cpu_info(os); unsigned long value_sum = 0; int ret = 0; int i = 0, j = 0; for (i = 0; i < usrdata->perf_event_num; i++) { for (j = 0; j < info->n_cpus; j++) { perf_desc = kmalloc(sizeof(struct perf_ctrl_desc), GFP_KERNEL); if (!perf_desc) { printk("%s: error: allocating perf_ctrl_desc\n", __FUNCTION__); return -ENOMEM; } memset(perf_desc, '\0', sizeof(struct perf_ctrl_desc)); perf_desc->ctrl_type = PERF_CTRL_GET; perf_desc->status = 0; perf_desc->target_cntr = i; memset(&isp, '\0', sizeof(struct ikc_scd_packet)); isp.msg = SCD_MSG_PERF_CTRL; isp.arg = virt_to_phys(perf_desc); if ((ret = mcctrl_ikc_send(os, j, &isp)) < 0) { printk("%s: mcctrl_ikc_send ret=%d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } ret = wait_event_interruptible(perfctrlq, perf_desc->status); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } value_sum += perf_desc->read_value; kfree(perf_desc); } if (copy_to_user(&arg[i], &value_sum, sizeof(unsigned long))) { printk("%s: error: copying read_value to user\n", __FUNCTION__); return -EINVAL; } value_sum = 0; } return 0; } long mcctrl_perf_enable(ihk_os_t os) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct ikc_scd_packet isp; struct perf_ctrl_desc *perf_desc = NULL; struct ihk_cpu_info *info = ihk_os_get_cpu_info(os); unsigned int cntr_mask = 0; int ret = 0; int i = 0, j = 0; for (i = 0; i < usrdata->perf_event_num; i++) { cntr_mask |= 1 << i; } for (j = 0; j < info->n_cpus; j++) { perf_desc = kmalloc(sizeof(struct perf_ctrl_desc), GFP_KERNEL); if (!perf_desc) { printk("%s: error: allocating perf_ctrl_desc\n", __FUNCTION__); return -ENOMEM; } memset(perf_desc, '\0', sizeof(struct perf_ctrl_desc)); perf_desc->ctrl_type = PERF_CTRL_ENABLE; perf_desc->status = 0; perf_desc->target_cntr_mask = cntr_mask; memset(&isp, '\0', sizeof(struct ikc_scd_packet)); isp.msg = SCD_MSG_PERF_CTRL; isp.arg = virt_to_phys(perf_desc); if ((ret = mcctrl_ikc_send(os, j, &isp)) < 0) { printk("%s: mcctrl_ikc_send ret=%d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } ret = wait_event_interruptible(perfctrlq, perf_desc->status); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } kfree(perf_desc); } return 0; } long mcctrl_perf_disable(ihk_os_t os) { struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct ikc_scd_packet isp; struct perf_ctrl_desc *perf_desc = NULL; struct ihk_cpu_info *info = ihk_os_get_cpu_info(os); unsigned int cntr_mask = 0; int ret = 0; int i = 0, j = 0; for (i = 0; i < usrdata->perf_event_num; i++) { cntr_mask |= 1 << i; } for (j = 0; j < info->n_cpus; j++) { perf_desc = kmalloc(sizeof(struct perf_ctrl_desc), GFP_KERNEL); if (!perf_desc) { printk("%s: error: allocating perf_ctrl_desc\n", __FUNCTION__); return -ENOMEM; } memset(perf_desc, '\0', sizeof(struct perf_ctrl_desc)); perf_desc->ctrl_type = PERF_CTRL_DISABLE; perf_desc->status = 0; perf_desc->target_cntr_mask = cntr_mask; memset(&isp, '\0', sizeof(struct ikc_scd_packet)); isp.msg = SCD_MSG_PERF_CTRL; isp.arg = virt_to_phys(perf_desc); if ((ret = mcctrl_ikc_send(os, j, &isp)) < 0) { printk("%s: mcctrl_ikc_send ret=%d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } ret = wait_event_interruptible(perfctrlq, perf_desc->status); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); kfree(perf_desc); return -EINVAL; } kfree(perf_desc); } return 0; } long mcctrl_perf_destroy(ihk_os_t os) { mcctrl_perf_disable(os); mcctrl_perf_num(os, 0); return 0; } void mcctrl_perf_ack(ihk_os_t os, struct ikc_scd_packet *packet) { struct perf_ctrl_desc *perf_desc = phys_to_virt(packet->arg); perf_desc->status = 1; wake_up_interruptible(&perfctrlq); } /* Compose LWK-specific rusage structure */ long mcctrl_getrusage(ihk_os_t ihk_os, struct mcctrl_ioctl_getrusage_desc *__user _desc) { struct mcctrl_ioctl_getrusage_desc desc; struct rusage_global *rusage_global = ihk_os_get_rusage(ihk_os); struct mckernel_rusage *rusage = NULL; int ret = 0; int i; unsigned long ut; unsigned long st; ret = copy_from_user(&desc, _desc, sizeof(struct mcctrl_ioctl_getrusage_desc)); if (ret != 0) { printk("%s: copy_from_user failed\n", __FUNCTION__); goto out; } rusage = kmalloc(sizeof(struct mckernel_rusage), GFP_KERNEL); if (!rusage) { printk("%s: kmalloc failed\n", __FUNCTION__); ret = -ENOMEM; goto out; } memset(rusage, 0, sizeof(struct mckernel_rusage)); /* Compile statistics */ for (i = 0; i < IHK_MAX_NUM_PGSIZES; i++) { rusage->memory_stat_rss[i] = rusage_global->memory_stat_rss[i]; rusage->memory_stat_mapped_file[i] = rusage_global->memory_stat_mapped_file[i]; } rusage->memory_max_usage = rusage_global->memory_max_usage; rusage->memory_kmem_usage = rusage_global->memory_kmem_usage; rusage->memory_kmem_max_usage = rusage_global->memory_kmem_max_usage; for (i = 0; i < rusage_global->num_numa_nodes; i++) { rusage->memory_numa_stat[i] = rusage_global->memory_numa_stat[i]; } for (ut = 0, st = 0, i = 0; i < rusage_global->num_processors; i++) { unsigned long wt; wt = rusage_global->cpu[i].user_tsc * rusage_global->ns_per_tsc / 1000; ut += wt; st += rusage_global->cpu[i].system_tsc * rusage_global->ns_per_tsc / 1000; rusage->cpuacct_usage_percpu[i] = wt; } rusage->cpuacct_stat_system = st / 10000000; rusage->cpuacct_stat_user = ut / 10000000; rusage->cpuacct_usage = ut; rusage->num_threads = rusage_global->num_threads; rusage->max_num_threads = rusage_global->max_num_threads; if (desc.size_rusage > sizeof(struct mckernel_rusage)) { printk("%s: desc.size_rusage=%ld > sizeof(struct mckernel_rusage)=%ld\n", __FUNCTION__, desc.size_rusage, sizeof(struct mckernel_rusage)); ret = -EINVAL; goto out; } ret = copy_to_user(desc.rusage, rusage, desc.size_rusage); if (ret != 0) { printk("%s: copy_to_user failed\n", __FUNCTION__); goto out; } out: if (rusage) { kfree(rusage); } return ret; } extern void *get_user_sp(void); extern void set_user_sp(unsigned long); extern void restore_fs(unsigned long fs); extern void save_fs_ctx(void *); extern unsigned long get_fs_ctx(void *); long mcexec_util_thread1(ihk_os_t os, unsigned long arg, struct file *file) { void **__user uparam = (void ** __user)arg; void *param[6]; unsigned long p_rctx; unsigned long phys; void *__user u_rctx; void *rctx; int rc = 0; unsigned long free_address; unsigned long free_size; unsigned long icurrent = (unsigned long)current; if(copy_from_user(param, uparam, sizeof(void *) * 6)) { return -EFAULT; } p_rctx = (unsigned long)param[0]; u_rctx = (void *__user)param[1]; free_address = (unsigned long)param[4]; free_size = (unsigned long)param[5]; phys = ihk_device_map_memory(ihk_os_to_dev(os), p_rctx, PAGE_SIZE); #ifdef CONFIG_MIC rctx = ioremap_wc(phys, PAGE_SIZE); #else rctx = ihk_device_map_virtual(ihk_os_to_dev(os), phys, PAGE_SIZE, NULL, 0); #endif if(copy_to_user(u_rctx, rctx, PAGE_SIZE) || copy_to_user((unsigned long *)(uparam + 3), &icurrent, sizeof(unsigned long))) rc = -EFAULT; ((unsigned long *)rctx)[0] = free_address; ((unsigned long *)rctx)[1] = free_size; #ifdef CONFIG_MIC iounmap(rctx); #else ihk_device_unmap_virtual(ihk_os_to_dev(os), rctx, PAGE_SIZE); #endif ihk_device_unmap_memory(ihk_os_to_dev(os), phys, PAGE_SIZE); return rc; } static inline struct host_thread *get_host_thread(void) { int pid = task_tgid_vnr(current); int tid = task_pid_vnr(current); unsigned long flags; struct host_thread *thread; read_lock_irqsave(&host_thread_lock, flags); for (thread = host_threads; thread; thread = thread->next) if(thread->pid == pid && thread->tid == tid) break; read_unlock_irqrestore(&host_thread_lock, flags); return thread; } long mcexec_util_thread2(ihk_os_t os, unsigned long arg, struct file *file) { void *usp = get_user_sp(); struct mcos_handler_info *info; struct host_thread *thread; unsigned long flags; void **__user param = (void **__user )arg; void *__user rctx = (void *__user)param[1]; void *__user lctx = (void *__user)param[2]; save_fs_ctx(lctx); info = ihk_os_get_mcos_private_data(file); thread = kmalloc(sizeof(struct host_thread), GFP_KERNEL); memset(thread, '\0', sizeof(struct host_thread)); thread->pid = task_tgid_vnr(current); thread->tid = task_pid_vnr(current); thread->usp = (unsigned long)usp; thread->lfs = get_fs_ctx(lctx); thread->rfs = get_fs_ctx(rctx); thread->handler = info; write_lock_irqsave(&host_thread_lock, flags); thread->next = host_threads; host_threads = thread; write_unlock_irqrestore(&host_thread_lock, flags); return 0; } long mcexec_sig_thread(ihk_os_t os, unsigned long arg, struct file *file) { int tid = task_pid_vnr(current); int pid = task_tgid_vnr(current); unsigned long flags; struct host_thread *thread; read_lock_irqsave(&host_thread_lock, flags); for (thread = host_threads; thread; thread = thread->next) if(thread->pid == pid && thread->tid == tid) break; read_unlock_irqrestore(&host_thread_lock, flags); if (thread) { if (arg) restore_fs(thread->lfs); else restore_fs(thread->rfs); return 0; } return -EINVAL; } long mcexec_terminate_thread(ihk_os_t os, unsigned long *param, struct file *file) { int pid = param[0]; int tid = param[1]; struct task_struct *tsk = (struct task_struct *)param[3]; unsigned long flags; struct host_thread *thread; struct host_thread *prev; struct ikc_scd_packet *packet; struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd; write_lock_irqsave(&host_thread_lock, flags); for (prev = NULL, thread = host_threads; thread; prev = thread, thread = thread->next) { if(thread->tid == tid) break; } if (!thread) { write_unlock_irqrestore(&host_thread_lock, flags); return -EINVAL; } ppd = mcctrl_get_per_proc_data(usrdata, pid); if (!ppd) { kprintf("%s: ERROR: no per-process structure for PID %d??\n", __FUNCTION__, pid); goto err; } packet = (struct ikc_scd_packet *)mcctrl_get_per_thread_data(ppd, tsk); if (!packet) { kprintf("%s: ERROR: no packet registered for TID %d\n", __FUNCTION__, tid); goto err; } mcctrl_delete_per_thread_data(ppd, tsk); __return_syscall(usrdata->os, packet, param[2], tid); ihk_ikc_release_packet((struct ihk_ikc_free_packet *)packet, (usrdata->ikc2linux[smp_processor_id()] ? usrdata->ikc2linux[smp_processor_id()] : usrdata->ikc2linux[0])); err: if(ppd) mcctrl_put_per_proc_data(ppd); if (prev) prev->next = thread->next; else host_threads = thread->next; write_unlock_irqrestore(&host_thread_lock, flags); kfree(thread); return 0; } long mcexec_syscall_thread(ihk_os_t os, unsigned long arg, struct file *file) { struct syscall_struct { int number; unsigned long args[6]; unsigned long ret; }; struct syscall_struct param; struct syscall_struct __user *uparam = (struct syscall_struct __user *)arg; int rc; if (copy_from_user(¶m, uparam, sizeof param)) { return -EFAULT; } rc = syscall_backward(ihk_host_os_get_usrdata(os), param.number, param.args[0], param.args[1], param.args[2], param.args[3], param.args[4], param.args[5], ¶m.ret); if (copy_to_user(&uparam->ret, ¶m.ret, sizeof(unsigned long))) { return -EFAULT; } return rc; } static struct ihk_cache_topology * cache_topo_search(struct ihk_cpu_topology *cpu_topo, int level) { struct ihk_cache_topology *lcache_topo; list_for_each_entry(lcache_topo, &cpu_topo->cache_topology_list, chain) { if (lcache_topo->level == level) return lcache_topo; } return NULL; } static long (*setaffinity)(pid_t pid, const struct cpumask *in_mask); static int (*setscheduler_nocheck)(struct task_struct *p, int policy, const struct sched_param *param); static unsigned int *uti_rr; static int max_cpu; static int uti_attr_init(void) { int i; unsigned int *rr; unsigned int *retval; if (uti_rr) return 0; if (!setaffinity) { setaffinity = (long (*)(pid_t, const struct cpumask *)) kallsyms_lookup_name("sched_setaffinity"); if (!setaffinity) return -ENOSYS; } if (!setscheduler_nocheck) { setscheduler_nocheck = (int (*)(struct task_struct *, int, const struct sched_param *)) kallsyms_lookup_name("sched_setscheduler_nocheck"); if (!setscheduler_nocheck) return -ENOSYS; } for_each_possible_cpu(i) { max_cpu = i; } max_cpu++; rr = (unsigned int *)kmalloc(sizeof(unsigned int) * max_cpu, GFP_KERNEL); if (!rr) return -ENOMEM; memset(rr, '\0', sizeof(unsigned int) * max_cpu); retval = __sync_val_compare_and_swap(&uti_rr, NULL, rr); if (retval != NULL) { kfree(rr); } return 0; } void uti_attr_finalize(void) { if (uti_rr) kfree(uti_rr); } static cpumask_t * uti_cpu_select(cpumask_t *cpumask) { int i; int mincpu; unsigned int minrr; unsigned int newval; unsigned int retval; retry: minrr = (unsigned int)-1; mincpu = -1; for_each_cpu(i, cpumask) { int rr = uti_rr[i]; if (rr < minrr) { mincpu = i; minrr = rr; } } newval = minrr + 1; retval = __sync_val_compare_and_swap(uti_rr + mincpu, minrr, newval); if (retval != minrr) goto retry; for_each_cpu(i, cpumask) { if (i != mincpu) { cpumask_clear_cpu(i, cpumask); } } return cpumask; } static long mcexec_uti_attr(ihk_os_t os, struct uti_attr_desc __user *arg) { struct uti_attr_desc desc; struct kuti_attr *kattr; cpumask_t *cpuset; struct mcctrl_usrdata *ud = ihk_host_os_get_usrdata(os); ihk_device_t dev = ihk_os_to_dev(os); #ifdef POSTK_DEBUG_ARCH_DEP_40 /* cpu_topology name change */ struct mcctrl_cpu_topology *cpu_topo; struct mcctrl_cpu_topology *target_cpu = NULL; #else /* POSTK_DEBUG_ARCH_DEP_40 */ struct cpu_topology *cpu_topo; struct cpu_topology *target_cpu = NULL; #endif /* POSTK_DEBUG_ARCH_DEP_40 */ struct node_topology *node_topo; struct ihk_cache_topology *lcache_topo; struct ihk_node_topology *lnode_topo; cpumask_t *wkmask; int i; int rc = 0; int mask_size = cpumask_size(); if ((rc = uti_attr_init())) { return rc; } if (copy_from_user(&desc, arg, sizeof desc)) return -EFAULT; kattr = phys_to_virt(desc.phys_attr); if (((kattr->attr.flags & UTI_FLAG_SAME_L1) && (kattr->attr.flags & UTI_FLAG_DIFFERENT_L1)) || ((kattr->attr.flags & UTI_FLAG_SAME_L2) && (kattr->attr.flags & UTI_FLAG_DIFFERENT_L2)) || ((kattr->attr.flags & UTI_FLAG_SAME_L3) && (kattr->attr.flags & UTI_FLAG_DIFFERENT_L3)) || ((kattr->attr.flags & UTI_FLAG_SAME_NUMA_DOMAIN) && (kattr->attr.flags & UTI_FLAG_DIFFERENT_NUMA_DOMAIN))) { return -EINVAL; } list_for_each_entry(cpu_topo, &ud->cpu_topology_list, chain) { if (cpu_topo->mckernel_cpu_id == kattr->parent_cpuid) { target_cpu = cpu_topo; } } if (!target_cpu) { return -EINVAL; } if (!(cpuset = kmalloc(mask_size * 2, GFP_KERNEL))) { return -ENOMEM; } wkmask = (cpumask_t *)(((char *)cpuset) + mask_size); memcpy(cpuset, cpu_active_mask, mask_size); if (kattr->attr.flags & UTI_FLAG_NUMA_SET) { nodemask_t *numaset = (nodemask_t *)&kattr->attr.numa_set[0]; memset(wkmask, '\0', mask_size); for_each_node_mask(i, *numaset) { list_for_each_entry(node_topo, &ud->node_topology_list, chain) { if (node_topo->mckernel_numa_id == i) { cpumask_or(wkmask, wkmask, &node_topo->saved->cpumap); break; } } } cpumask_and(cpuset, cpuset, wkmask); } if ((kattr->attr.flags & UTI_FLAG_SAME_NUMA_DOMAIN) || (kattr->attr.flags & UTI_FLAG_DIFFERENT_NUMA_DOMAIN)) { memset(wkmask, '\0', mask_size); for (i = 0; i < UTI_MAX_NUMA_DOMAINS; i++) { lnode_topo = ihk_device_get_node_topology(dev, i); if(!lnode_topo) continue; if(IS_ERR(lnode_topo)) continue; #ifdef POSTK_DEBUG_ARCH_DEP_54 /* cpu_isset() linux version depend fix. */ #if LINUX_VERSION_CODE >= KERNEL_VERSION(4,1,0) if (cpumask_test_cpu(target_cpu->saved->cpu_number, &lnode_topo->cpumap)) { #else if (cpu_isset(target_cpu->saved->cpu_number, lnode_topo->cpumap)) { #endif #else /* POSTK_DEBUG_ARCH_DEP_54 */ if (cpu_isset(target_cpu->saved->cpu_number, lnode_topo->cpumap)) { #endif /* POSTK_DEBUG_ARCH_DEP_54 */ if (kattr->attr.flags & UTI_FLAG_SAME_NUMA_DOMAIN) { cpumask_or(wkmask, wkmask, &lnode_topo->cpumap); } } else { if (kattr->attr.flags & UTI_FLAG_DIFFERENT_NUMA_DOMAIN) { cpumask_or(wkmask, wkmask, &lnode_topo->cpumap); } } } cpumask_and(cpuset, cpuset, wkmask); } if (((kattr->attr.flags & UTI_FLAG_SAME_L1) || (kattr->attr.flags & UTI_FLAG_DIFFERENT_L1)) && (lcache_topo = cache_topo_search(target_cpu->saved, 1))) { if (kattr->attr.flags & UTI_FLAG_SAME_L1) { cpumask_and(cpuset, cpuset, &lcache_topo->shared_cpu_map); } else { cpumask_complement(wkmask, &lcache_topo->shared_cpu_map); cpumask_and(cpuset, cpuset, wkmask); } } if (((kattr->attr.flags & UTI_FLAG_SAME_L2) || (kattr->attr.flags & UTI_FLAG_DIFFERENT_L2)) && (lcache_topo = cache_topo_search(target_cpu->saved, 2))) { if (kattr->attr.flags & UTI_FLAG_SAME_L2) { cpumask_and(cpuset, cpuset, &lcache_topo->shared_cpu_map); } else { cpumask_complement(wkmask, &lcache_topo->shared_cpu_map); cpumask_and(cpuset, cpuset, wkmask); } } if (((kattr->attr.flags & UTI_FLAG_SAME_L3) || (kattr->attr.flags & UTI_FLAG_DIFFERENT_L3)) && (lcache_topo = cache_topo_search(target_cpu->saved, 3))) { if (kattr->attr.flags & UTI_FLAG_SAME_L3) { cpumask_and(cpuset, cpuset, &lcache_topo->shared_cpu_map); } else { cpumask_complement(wkmask, &lcache_topo->shared_cpu_map); cpumask_and(cpuset, cpuset, wkmask); } } rc = cpumask_weight(cpuset); if (!rc); /* do nothing */ else if (kattr->attr.flags & UTI_FLAG_EXCLUSIVE_CPU) { struct sched_param sp; setaffinity(0, uti_cpu_select(cpuset)); sp.sched_priority = 1; setscheduler_nocheck(current, SCHED_FIFO, &sp); rc = 1; } else if (kattr->attr.flags & UTI_FLAG_CPU_INTENSIVE) { setaffinity(0, uti_cpu_select(cpuset)); rc = 1; } else if (kattr->attr.flags & UTI_FLAG_HIGH_PRIORITY) { struct sched_param sp; setaffinity(0, uti_cpu_select(cpuset)); sp.sched_priority = 1; setscheduler_nocheck(current, SCHED_FIFO, &sp); rc = 1; } else if (kattr->attr.flags & UTI_FLAG_NON_COOPERATIVE) { setaffinity(0, uti_cpu_select(cpuset)); rc = 1; } else { setaffinity(0, cpuset); } kfree(cpuset); return rc; } long __mcctrl_control(ihk_os_t os, unsigned int req, unsigned long arg, struct file *file) { switch (req) { case MCEXEC_UP_PREPARE_IMAGE: return mcexec_prepare_image(os, (struct program_load_desc *)arg); case MCEXEC_UP_TRANSFER: return mcexec_transfer_image(os, (struct remote_transfer *)arg); case MCEXEC_UP_START_IMAGE: return mcexec_start_image(os, (struct program_load_desc *)arg, file); case MCEXEC_UP_WAIT_SYSCALL: return mcexec_wait_syscall(os, (struct syscall_wait_desc *)arg); case MCEXEC_UP_RET_SYSCALL: return mcexec_ret_syscall(os, (struct syscall_ret_desc *)arg); case MCEXEC_UP_LOAD_SYSCALL: return mcexec_load_syscall(os, (struct syscall_load_desc *)arg); case MCEXEC_UP_SEND_SIGNAL: return mcexec_send_signal(os, (struct signal_desc *)arg); case MCEXEC_UP_GET_CPU: return mcexec_get_cpu(os); case MCEXEC_UP_CREATE_PPD: return mcexec_create_per_process_data(os); case MCEXEC_UP_GET_NODES: return mcexec_get_nodes(os); case MCEXEC_UP_GET_CPUSET: return mcexec_get_cpuset(os, arg); case MCEXEC_UP_STRNCPY_FROM_USER: return mcexec_strncpy_from_user(os, (struct strncpy_from_user_desc *)arg); case MCEXEC_UP_NEW_PROCESS: return mcexec_newprocess(os, (struct newprocess_desc *)arg, file); case MCEXEC_UP_OPEN_EXEC: return mcexec_open_exec(os, (char *)arg); case MCEXEC_UP_CLOSE_EXEC: return mcexec_close_exec(os); case MCEXEC_UP_PREPARE_DMA: return mcexec_pin_region(os, (unsigned long *)arg); case MCEXEC_UP_FREE_DMA: return mcexec_free_region(os, (unsigned long *)arg); case MCEXEC_UP_GET_CRED: return mcexec_getcred((unsigned long)arg); case MCEXEC_UP_GET_CREDV: return mcexec_getcredv((int *)arg); case MCEXEC_UP_SYS_MOUNT: return mcexec_sys_mount((struct sys_mount_desc *)arg); case MCEXEC_UP_SYS_UMOUNT: return mcexec_sys_umount((struct sys_mount_desc *)arg); case MCEXEC_UP_SYS_UNSHARE: return mcexec_sys_unshare((struct sys_unshare_desc *)arg); case MCEXEC_UP_UTIL_THREAD1: return mcexec_util_thread1(os, arg, file); case MCEXEC_UP_UTIL_THREAD2: return mcexec_util_thread2(os, arg, file); case MCEXEC_UP_SIG_THREAD: return mcexec_sig_thread(os, arg, file); case MCEXEC_UP_SYSCALL_THREAD: return mcexec_syscall_thread(os, arg, file); case MCEXEC_UP_TERMINATE_THREAD: return mcexec_terminate_thread(os, (unsigned long *)arg, file); case MCEXEC_UP_GET_NUM_POOL_THREADS: return mcctrl_get_num_pool_threads(os); case MCEXEC_UP_UTI_ATTR: return mcexec_uti_attr(os, (struct uti_attr_desc __user *)arg); case MCEXEC_UP_DEBUG_LOG: return mcexec_debug_log(os, arg); case IHK_OS_AUX_PERF_NUM: return mcctrl_perf_num(os, arg); case IHK_OS_AUX_PERF_SET: return mcctrl_perf_set(os, (struct ihk_perf_event_attr *)arg); case IHK_OS_AUX_PERF_GET: return mcctrl_perf_get(os, (unsigned long *)arg); case IHK_OS_AUX_PERF_ENABLE: return mcctrl_perf_enable(os); case IHK_OS_AUX_PERF_DISABLE: return mcctrl_perf_disable(os); case IHK_OS_AUX_PERF_DESTROY: return mcctrl_perf_destroy(os); case IHK_OS_GETRUSAGE: return mcctrl_getrusage(os, (struct mcctrl_ioctl_getrusage_desc *)arg); } return -EINVAL; } void mcexec_prepare_ack(ihk_os_t os, unsigned long arg, int err) { struct program_load_desc *desc = phys_to_virt(arg); struct mcctrl_usrdata *usrdata = ihk_host_os_get_usrdata(os); struct mcctrl_per_proc_data *ppd = NULL; ppd = mcctrl_get_per_proc_data(usrdata, desc->pid); if (!ppd) { printk("%s: ERROR: no per process data for PID %d\n", __FUNCTION__, desc->pid); return; } desc->err = err; desc->status = 1; mb(); wake_up_all(&ppd->wq_prepare); mcctrl_put_per_proc_data(ppd); } /* Per-CPU register manipulation functions */ struct mcctrl_os_cpu_response { int done; unsigned long val; wait_queue_head_t wq; }; int mcctrl_get_request_os_cpu(ihk_os_t os, int *ret_cpu) { struct mcctrl_usrdata *usrdata; struct mcctrl_per_proc_data *ppd; struct ikc_scd_packet *packet; struct ihk_ikc_channel_desc *ch; int ret = 0; if (!os) { return -EINVAL; } /* Look up per-OS mcctrl structure */ usrdata = ihk_host_os_get_usrdata(os); if (!usrdata) { printk("%s: ERROR: no usrdata found for OS %p\n", __FUNCTION__, os); return -EINVAL; } /* Look up per-process structure */ ppd = mcctrl_get_per_proc_data(usrdata, task_tgid_vnr(current)); if (!ppd) { kprintf("%s: ERROR: no per-process structure for PID %d??\n", __FUNCTION__, task_tgid_vnr(current)); return -EINVAL; } /* Look up per-thread structure */ packet = (struct ikc_scd_packet *)mcctrl_get_per_thread_data(ppd, current); if (!packet) { ret = -EINVAL; printk("%s: ERROR: no packet registered for TID %d\n", __FUNCTION__, task_pid_vnr(current)); goto out_put_ppd; } /* TODO: define a new IHK query function instead of * accessing internals directly */ ch = (usrdata->channels + packet->ref)->c; *ret_cpu = ch->send.queue->read_cpu; ret = 0; printk("%s: OS: %p, CPU: %d\n", __FUNCTION__, os, *ret_cpu); out_put_ppd: mcctrl_put_per_proc_data(ppd); return ret; } void mcctrl_os_read_write_cpu_response(ihk_os_t os, struct ikc_scd_packet *pisp) { struct mcctrl_os_cpu_response *resp; /* XXX: What if caller thread is unblocked by a signal * before this message arrives? */ resp = pisp->resp; if (!resp) { return; } resp->val = pisp->desc.val; resp->done = 1; wake_up_interruptible(&resp->wq); } int __mcctrl_os_read_write_cpu_register(ihk_os_t os, int cpu, struct ihk_os_cpu_register *desc, enum mcctrl_os_cpu_operation op) { struct ikc_scd_packet isp; struct mcctrl_os_cpu_response resp; int ret = -EINVAL; memset(&isp, '\0', sizeof(struct ikc_scd_packet)); isp.msg = SCD_MSG_CPU_RW_REG; isp.op = op; isp.desc = *desc; isp.resp = &resp; resp.done = 0; init_waitqueue_head(&resp.wq); mb(); ret = mcctrl_ikc_send(os, cpu, &isp); if (ret < 0) { printk("%s: ERROR sending IKC msg: %d\n", __FUNCTION__, ret); goto out; } /* Wait for response */ ret = wait_event_interruptible(resp.wq, resp.done); if (ret < 0) { printk("%s: ERROR after wait: %d\n", __FUNCTION__, ret); goto out; } /* Update if read */ if (ret == 0 && op == MCCTRL_OS_CPU_READ_REGISTER) { desc->val = resp.val; } dprintk("%s: MCCTRL_OS_CPU_%s_REGISTER: reg: 0x%lx, val: 0x%lx\n", __FUNCTION__, (op == MCCTRL_OS_CPU_READ_REGISTER ? "READ" : "WRITE"), desc->addr, desc->val); out: return ret; } int mcctrl_os_read_cpu_register(ihk_os_t os, int cpu, struct ihk_os_cpu_register *desc) { return __mcctrl_os_read_write_cpu_register(os, cpu, desc, MCCTRL_OS_CPU_READ_REGISTER); } int mcctrl_os_write_cpu_register(ihk_os_t os, int cpu, struct ihk_os_cpu_register *desc) { return __mcctrl_os_read_write_cpu_register(os, cpu, desc, MCCTRL_OS_CPU_WRITE_REGISTER); }