#include #include #include #include #include #include #include #include #include #include #include //#define DEBUG_PRINT_PROCESS #ifdef DEBUG_PRINT_PROCESS #define dkprintf(...) kprintf(__VA_ARGS__) #define ekprintf(...) kprintf(__VA_ARGS__) #else #define dkprintf(...) #define ekprintf(...) kprintf(__VA_ARGS__) #endif #define USER_STACK_NR_PAGES 8192 #define KERNEL_STACK_NR_PAGES 24 extern long do_arch_prctl(unsigned long code, unsigned long address); static int init_process_vm(struct process *owner, struct process_vm *vm) { void *pt = ihk_mc_pt_create(IHK_MC_AP_NOWAIT); if(pt == NULL) return -ENOMEM; ihk_mc_spinlock_init(&vm->memory_range_lock); ihk_mc_spinlock_init(&vm->page_table_lock); ihk_atomic_set(&vm->refcount, 1); INIT_LIST_HEAD(&vm->vm_range_list); vm->page_table = pt; hold_process(owner); vm->owner_process = owner; return 0; } struct process *create_process(unsigned long user_pc) { struct process *proc; proc = ihk_mc_alloc_pages(KERNEL_STACK_NR_PAGES, IHK_MC_AP_NOWAIT); if (!proc) return NULL; memset(proc, 0, sizeof(struct process)); ihk_atomic_set(&proc->refcount, 2); /* one for exit, another for wait */ proc->sighandler = kmalloc(sizeof(struct sig_handler), IHK_MC_AP_NOWAIT); if(!proc->sighandler){ ihk_mc_free_pages(proc, KERNEL_STACK_NR_PAGES); return NULL; } memset(proc->sighandler, '\0', sizeof(struct sig_handler)); ihk_atomic_set(&proc->sighandler->use, 1); ihk_mc_spinlock_init(&proc->sighandler->lock); ihk_mc_init_user_process(&proc->ctx, &proc->uctx, ((char *)proc) + KERNEL_STACK_NR_PAGES * PAGE_SIZE, user_pc, 0); proc->vm = (struct process_vm *)(proc + 1); if(init_process_vm(proc, proc->vm) != 0){ kfree(proc->sighandler); ihk_mc_free_pages(proc, KERNEL_STACK_NR_PAGES); return NULL; } ihk_mc_spinlock_init(&proc->spin_sleep_lock); proc->spin_sleep = 0; return proc; } struct process *clone_process(struct process *org, unsigned long pc, unsigned long sp) { struct process *proc; if((proc = ihk_mc_alloc_pages(KERNEL_STACK_NR_PAGES, IHK_MC_AP_NOWAIT)) == NULL){ return NULL; } memset(proc, 0, sizeof(struct process)); ihk_atomic_set(&proc->refcount, 2); /* one for exit, another for wait */ /* NOTE: sp is the user mode stack! */ ihk_mc_init_user_process(&proc->ctx, &proc->uctx, ((char *)proc) + KERNEL_STACK_NR_PAGES * PAGE_SIZE, pc, sp); memcpy(proc->uctx, org->uctx, sizeof(*org->uctx)); ihk_mc_modify_user_context(proc->uctx, IHK_UCR_STACK_POINTER, sp); ihk_mc_modify_user_context(proc->uctx, IHK_UCR_PROGRAM_COUNTER, pc); ihk_atomic_inc(&org->vm->refcount); proc->vm = org->vm; proc->sighandler = org->sighandler; ihk_atomic_inc(&org->sighandler->use); ihk_mc_spinlock_init(&proc->spin_sleep_lock); proc->spin_sleep = 0; return proc; } int update_process_page_table(struct process *process, struct vm_range *range, uint64_t phys, enum ihk_mc_pt_attribute flag) { unsigned long p, pa = phys; unsigned long pp; unsigned long flags = ihk_mc_spinlock_lock(&process->vm->page_table_lock); enum ihk_mc_pt_attribute attr; attr = flag | PTATTR_USER | PTATTR_FOR_USER; attr |= (range->flag & VR_PROT_WRITE)? PTATTR_WRITABLE: 0; p = range->start; while (p < range->end) { #ifdef USE_LARGE_PAGES /* Use large PTE if both virtual and physical addresses are large page * aligned and more than LARGE_PAGE_SIZE is left from the range */ if ((p & (LARGE_PAGE_SIZE - 1)) == 0 && (pa & (LARGE_PAGE_SIZE - 1)) == 0 && (range->end - p) >= LARGE_PAGE_SIZE) { if (ihk_mc_pt_set_large_page(process->vm->page_table, (void *)p, pa, attr) != 0) { goto err; } dkprintf("large page set for 0x%lX -> 0x%lX\n", p, pa); pa += LARGE_PAGE_SIZE; p += LARGE_PAGE_SIZE; } else { #endif if(ihk_mc_pt_set_page(process->vm->page_table, (void *)p, pa, attr) != 0){ goto err; } pa += PAGE_SIZE; p += PAGE_SIZE; #ifdef USE_LARGE_PAGES } #endif } ihk_mc_spinlock_unlock(&process->vm->page_table_lock, flags); return 0; err: pp = range->start; pa = phys; while(pp < p){ #ifdef USE_LARGE_PAGES if ((p & (LARGE_PAGE_SIZE - 1)) == 0 && (pa & (LARGE_PAGE_SIZE - 1)) == 0 && (range->end - p) >= LARGE_PAGE_SIZE) { ihk_mc_pt_clear_large_page(process->vm->page_table, (void *)pp); pa += LARGE_PAGE_SIZE; pp += LARGE_PAGE_SIZE; } else{ #endif ihk_mc_pt_clear_page(process->vm->page_table, (void *)pp); pa += PAGE_SIZE; pp += PAGE_SIZE; #ifdef USE_LARGE_PAGES } #endif } ihk_mc_spinlock_unlock(&process->vm->page_table_lock, flags); return -ENOMEM; } int split_process_memory_range(struct process *proc, struct vm_range *range, uintptr_t addr, struct vm_range **splitp) { int error; struct vm_range *newrange = NULL; dkprintf("split_process_memory_range(%p,%lx-%lx,%lx,%p)\n", proc, range->start, range->end, addr, splitp); newrange = kmalloc(sizeof(struct vm_range), IHK_MC_AP_NOWAIT); if (!newrange) { ekprintf("split_process_memory_range(%p,%lx-%lx,%lx,%p):" "kmalloc failed\n", proc, range->start, range->end, addr, splitp); error = -ENOMEM; goto out; } newrange->start = addr; newrange->end = range->end; newrange->flag = range->flag; range->end = addr; list_add(&newrange->list, &range->list); error = 0; if (splitp != NULL) { *splitp = newrange; } out: dkprintf("split_process_memory_range(%p,%lx-%lx,%lx,%p): %d %p %lx-%lx\n", proc, range->start, range->end, addr, splitp, error, newrange, newrange? newrange->start: 0, newrange? newrange->end: 0); return error; } int join_process_memory_range(struct process *proc, struct vm_range *surviving, struct vm_range *merging) { int error; dkprintf("join_process_memory_range(%p,%lx-%lx,%lx-%lx)\n", proc, surviving->start, surviving->end, merging->start, merging->end); if ((surviving->end != merging->start) || (surviving->flag != merging->flag)) { error = -EINVAL; goto out; } surviving->end = merging->end; list_del(&merging->list); ihk_mc_free(merging); error = 0; out: dkprintf("join_process_memory_range(%p,%lx-%lx,%p): %d\n", proc, surviving->start, surviving->end, merging, error); return error; } int free_process_memory_range(struct process_vm *vm, struct vm_range *range) { const intptr_t start0 = range->start; const intptr_t end0 = range->end; int error; intptr_t start; intptr_t end; #ifdef USE_LARGE_PAGES struct vm_range *neighbor; intptr_t lpstart; intptr_t lpend; #endif /* USE_LARGE_PAGES */ dkprintf("free_process_memory_range(%p,%lx-%lx)\n", vm, start0, end0); start = range->start; end = range->end; if (!(range->flag & (VR_REMOTE | VR_IO_NOCACHE | VR_RESERVED))) { #ifdef USE_LARGE_PAGES lpstart = start & LARGE_PAGE_MASK; lpend = (end + LARGE_PAGE_SIZE - 1) & LARGE_PAGE_MASK; if (lpstart < start) { neighbor = previous_process_memory_range(vm, range); if ((neighbor == NULL) || (neighbor->end <= lpstart)) { start = lpstart; } } if (end < lpend) { neighbor = next_process_memory_range(vm, range); if ((neighbor == NULL) || (lpend <= neighbor->start)) { end = lpend; } } #endif /* USE_LARGE_PAGES */ ihk_mc_spinlock_lock_noirq(&vm->page_table_lock); error = ihk_mc_pt_free_range(vm->page_table, (void *)start, (void *)end); ihk_mc_spinlock_unlock_noirq(&vm->page_table_lock); if (error && (error != -ENOENT)) { ekprintf("free_process_memory_range(%p,%lx-%lx):" "ihk_mc_pt_free_range(%lx-%lx) failed. %d\n", vm, start0, end0, start, end, error); /* through */ } } else { ihk_mc_spinlock_lock_noirq(&vm->page_table_lock); error = ihk_mc_pt_clear_range(vm->page_table, (void *)start, (void *)end); ihk_mc_spinlock_unlock_noirq(&vm->page_table_lock); if (error && (error != -ENOENT)) { ekprintf("free_process_memory_range(%p,%lx-%lx):" "ihk_mc_pt_clear_range(%lx-%lx) failed. %d\n", vm, start0, end0, start, end, error); /* through */ } } list_del(&range->list); ihk_mc_free(range); dkprintf("free_process_memory_range(%p,%lx-%lx): 0\n", vm, start0, end0); return 0; } int remove_process_memory_range(struct process *process, unsigned long start, unsigned long end) { struct process_vm * const vm = process->vm; struct vm_range *range; struct vm_range *next; int error; struct vm_range *freerange; dkprintf("remove_process_memory_range(%p,%lx,%lx)\n", process, start, end); list_for_each_entry_safe(range, next, &vm->vm_range_list, list) { if ((range->end <= start) || (end <= range->start)) { /* no overlap */ continue; } freerange = range; if (freerange->start < start) { error = split_process_memory_range(process, freerange, start, &freerange); if (error) { ekprintf("remove_process_memory_range(%p,%lx,%lx):" "split failed %d\n", process, start, end, error); return error; } } if (end < freerange->end) { error = split_process_memory_range(process, freerange, end, NULL); if (error) { ekprintf("remove_process_memory_range(%p,%lx,%lx):" "split failed %d\n", process, start, end, error); return error; } } error = free_process_memory_range(process->vm, freerange); if (error) { ekprintf("remove_process_memory_range(%p,%lx,%lx):" "free failed %d\n", process, start, end, error); return error; } } dkprintf("remove_process_memory_range(%p,%lx,%lx): 0\n", process, start, end); return 0; } static void insert_vm_range_list(struct process_vm *vm, struct vm_range *newrange) { struct list_head *next; struct vm_range *range; next = &vm->vm_range_list; list_for_each_entry(range, &vm->vm_range_list, list) { if ((newrange->start < range->end) && (range->start < newrange->end)) { ekprintf("insert_vm_range_list(%p,%lx-%lx %lx):overlap %lx-%lx %lx\n", vm, newrange->start, newrange->end, newrange->flag, range->start, range->end, range->flag); panic("insert_vm_range_list\n"); } if (newrange->end <= range->start) { next = &range->list; break; } } list_add_tail(&newrange->list, next); return; } enum ihk_mc_pt_attribute vrflag_to_ptattr(unsigned long flag) { enum ihk_mc_pt_attribute attr; attr = PTATTR_USER | PTATTR_FOR_USER; if (flag & VR_REMOTE) { attr |= IHK_PTA_REMOTE; } else if (flag & VR_IO_NOCACHE) { attr |= PTATTR_UNCACHABLE; } if ((flag & VR_PROT_MASK) != VR_PROT_NONE) { attr |= PTATTR_ACTIVE; } if (flag & VR_PROT_WRITE) { attr |= PTATTR_WRITABLE; } return attr; } int add_process_memory_range(struct process *process, unsigned long start, unsigned long end, unsigned long phys, unsigned long flag) { struct vm_range *range; int rc; #if 0 extern void __host_update_process_range(struct process *process, struct vm_range *range); #endif if ((start < process->vm->region.user_start) || (process->vm->region.user_end < end)) { kprintf("range(%#lx - %#lx) is not in user avail(%#lx - %#lx)\n", start, end, process->vm->region.user_start, process->vm->region.user_end); return -EINVAL; } range = kmalloc(sizeof(struct vm_range), IHK_MC_AP_NOWAIT); if (!range) { return -ENOMEM; } INIT_LIST_HEAD(&range->list); range->start = start; range->end = end; range->flag = flag; if(range->flag & VR_DEMAND_PAGING) { dkprintf("range: 0x%lX - 0x%lX => physicall memory area is allocated on demand (%ld) [%lx]\n", range->start, range->end, range->end - range->start, range->flag); } else { dkprintf("range: 0x%lX - 0x%lX => 0x%lX - 0x%lX (%ld) [%lx]\n", range->start, range->end, range->phys, range->phys + range->end - range->start, range->end - range->start, range->flag); } if (flag & VR_REMOTE) { rc = update_process_page_table(process, range, phys, IHK_PTA_REMOTE); } else if (flag & VR_IO_NOCACHE) { rc = update_process_page_table(process, range, phys, PTATTR_UNCACHABLE); } else if(flag & VR_DEMAND_PAGING){ //demand paging no need to update process table now kprintf("demand paging do not update process page table\n"); rc = 0; } else if ((range->flag & VR_PROT_MASK) == VR_PROT_NONE) { rc = 0; } else { rc = update_process_page_table(process, range, phys, 0); } if(rc != 0){ kfree(range); return rc; } #if 0 // disable __host_update_process_range() in add_process_memory_range(), because it has no effect on the actual mapping on the MICs side. if (!(flag & VR_REMOTE)) { __host_update_process_range(process, range); } #endif insert_vm_range_list(process->vm, range); /* Clear content! */ if (!(flag & (VR_REMOTE | VR_DEMAND_PAGING)) && ((flag & VR_PROT_MASK) != VR_PROT_NONE)) { memset((void*)phys_to_virt(phys), 0, end - start); } return 0; } struct vm_range *lookup_process_memory_range( struct process_vm *vm, uintptr_t start, uintptr_t end) { struct vm_range *range = NULL; dkprintf("lookup_process_memory_range(%p,%lx,%lx)\n", vm, start, end); if (end <= start) { goto out; } list_for_each_entry(range, &vm->vm_range_list, list) { if (end <= range->start) { break; } if ((start < range->end) && (range->start < end)) { goto out; } } range = NULL; out: dkprintf("lookup_process_memory_range(%p,%lx,%lx): %p %lx-%lx\n", vm, start, end, range, range? range->start: 0, range? range->end: 0); return range; } struct vm_range *next_process_memory_range( struct process_vm *vm, struct vm_range *range) { struct vm_range *next; dkprintf("next_process_memory_range(%p,%lx-%lx)\n", vm, range->start, range->end); if (list_is_last(&range->list, &vm->vm_range_list)) { next = NULL; } else { next = list_entry(range->list.next, struct vm_range, list); } dkprintf("next_process_memory_range(%p,%lx-%lx): %p %lx-%lx\n", vm, range->start, range->end, next, next? next->start: 0, next? next->end: 0); return next; } struct vm_range *previous_process_memory_range( struct process_vm *vm, struct vm_range *range) { struct vm_range *prev; dkprintf("previous_process_memory_range(%p,%lx-%lx)\n", vm, range->start, range->end); if (list_first_entry(&vm->vm_range_list, struct vm_range, list) == range) { prev = NULL; } else { prev = list_entry(range->list.prev, struct vm_range, list); } dkprintf("previous_process_memory_range(%p,%lx-%lx): %p %lx-%lx\n", vm, range->start, range->end, prev, prev? prev->start: 0, prev? prev->end: 0); return prev; } int change_prot_process_memory_range(struct process *proc, struct vm_range *range, unsigned long protflag) { unsigned long newflag; int error; enum ihk_mc_pt_attribute oldattr; enum ihk_mc_pt_attribute newattr; enum ihk_mc_pt_attribute clrattr; enum ihk_mc_pt_attribute setattr; dkprintf("change_prot_process_memory_range(%p,%lx-%lx,%lx)\n", proc, range->start, range->end, protflag); newflag = (range->flag & ~VR_PROT_MASK) | (protflag & VR_PROT_MASK); if (range->flag == newflag) { /* nothing to do */ error = 0; goto out; } oldattr = vrflag_to_ptattr(range->flag); newattr = vrflag_to_ptattr(newflag); clrattr = oldattr & ~newattr; setattr = newattr & ~oldattr; ihk_mc_spinlock_lock_noirq(&proc->vm->page_table_lock); error = ihk_mc_pt_change_attr_range(proc->vm->page_table, (void *)range->start, (void *)range->end, clrattr, setattr); ihk_mc_spinlock_unlock_noirq(&proc->vm->page_table_lock); if (error && (error != -ENOENT)) { ekprintf("change_prot_process_memory_range(%p,%lx-%lx,%lx):" "ihk_mc_pt_change_attr_range failed: %d\n", proc, range->start, range->end, protflag, error); goto out; } if (((range->flag & VR_PROT_MASK) == PROT_NONE) && !(range->flag & VR_DEMAND_PAGING)) { ihk_mc_spinlock_lock_noirq(&proc->vm->page_table_lock); error = ihk_mc_pt_alloc_range(proc->vm->page_table, (void *)range->start, (void *)range->end, newattr); ihk_mc_spinlock_unlock_noirq(&proc->vm->page_table_lock); if (error) { ekprintf("change_prot_process_memory_range(%p,%lx-%lx,%lx):" "ihk_mc_pt_alloc_range failed: %d\n", proc, range->start, range->end, protflag, error); goto out; } } range->flag = newflag; error = 0; out: dkprintf("change_prot_process_memory_range(%p,%lx-%lx,%lx): %d\n", proc, range->start, range->end, protflag, error); return error; } static int page_fault_process_memory_range(struct process_vm *vm, struct vm_range *range, uintptr_t fault_addr) { int error; int npages; void *virt = NULL; void *ptepgaddr; size_t ptepgsize; int ptep2align; void *pgaddr; size_t pgsize; int p2align; uintptr_t phys; enum ihk_mc_pt_attribute attr; pte_t *ptep; dkprintf("[%d]page_fault_process_memory_range(%p,%lx-%lx %lx,%lx)\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr); ihk_mc_spinlock_lock_noirq(&vm->page_table_lock); /* (1) check PTE */ ptep = ihk_mc_pt_lookup_pte(vm->page_table, (void *)fault_addr, &ptepgaddr, &ptepgsize, &ptep2align); if (ptep && (*ptep != PTE_NULL)) { if (!(*ptep & PF_PRESENT)) { error = -EFAULT; kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):" "disabled page. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } error = 0; kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):already mapped. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } /* (2) select page size */ #ifdef USE_LARGE_PAGES if (!ptep) { /* get largest page size */ error = arch_get_smaller_page_size(NULL, -1, &ptepgsize, &ptep2align); if (error) { kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):" "get pgsize failed. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } } #else if (!ptep || (ptepgsize != PAGE_SIZE)) { ptep = NULL; ptepgsize = PAGE_SIZE; ptep2align = PAGE_P2ALIGN; } #endif pgsize = ptepgsize; p2align = ptep2align; /* (3) get physical page */ for (;;) { pgaddr = (void *)(fault_addr & ~(pgsize - 1)); if ((range->start <= (uintptr_t)pgaddr) && (((uintptr_t)pgaddr + pgsize) <= range->end)) { npages = pgsize / PAGE_SIZE; virt = ihk_mc_alloc_aligned_pages(npages, p2align, IHK_MC_AP_NOWAIT); if (virt) { phys = virt_to_phys(virt); memset(virt, 0, pgsize); break; } } /* (4) if failed, select smaller page size, and retry */ ptep = NULL; error = arch_get_smaller_page_size( vm, pgsize, &pgsize, &p2align); if (error) { kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):" "get pgsize failed. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } } /* (5) mapping */ attr = vrflag_to_ptattr(range->flag); if (ptep) { error = ihk_mc_pt_set_pte(vm->page_table, ptep, pgsize, phys, attr); if (error) { kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):" "set pte failed. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } } else { error = ihk_mc_pt_set_range(vm->page_table, pgaddr, pgaddr+pgsize, phys, attr); if (error) { kprintf("[%d]page_fault_process_memory_range" "(%p,%lx-%lx %lx,%lx):" "set range failed. %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); goto out; } } virt = NULL; error = 0; out: ihk_mc_spinlock_unlock_noirq(&vm->page_table_lock); if (virt != NULL) { ihk_mc_free_pages(virt, npages); } dkprintf("[%d]page_fault_process_memory_range(%p,%lx-%lx %lx,%lx): %d\n", ihk_mc_get_processor_id(), vm, range->start, range->end, range->flag, fault_addr, error); return error; } int page_fault_process(struct process *proc, void *fault_addr0, uint64_t reason) { struct process_vm *vm = proc->vm; int error; const uintptr_t fault_addr = (uintptr_t)fault_addr0; struct vm_range *range; dkprintf("[%d]page_fault_process(%p,%lx,%lx)\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason); ihk_mc_spinlock_lock_noirq(&vm->memory_range_lock); /* NYI: page proctection fault */ if (reason & PF_PROT) { error = -EFAULT; kprintf("[%d]page_fault_process(%p,%lx,%lx):" "protection fault. %d\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason, error); goto out; } range = lookup_process_memory_range(vm, fault_addr, fault_addr+1); if (range == NULL) { error = -EFAULT; kprintf("[%d]page_fault_process(%p,%lx,%lx):" "out of range. %d\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason, error); goto out; } if (((range->flag & VR_PROT_MASK) == VR_PROT_NONE) || ((reason & PF_WRITE) && !(range->flag & VR_PROT_WRITE))) { error = -EFAULT; kprintf("[%d]page_fault_process(%p,%lx,%lx):" "access denied. %d\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason, error); goto out; } error = page_fault_process_memory_range(vm, range, fault_addr); if (error) { kprintf("[%d]page_fault_process(%p,%lx,%lx):" "fault range failed. %d\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason, error); goto out; } error = 0; out: ihk_mc_spinlock_unlock_noirq(&vm->memory_range_lock); dkprintf("[%d]page_fault_process(%p,%lx,%lx): %d\n", ihk_mc_get_processor_id(), proc, fault_addr0, reason, error); return error; } int init_process_stack(struct process *process, struct program_load_desc *pn, int argc, char **argv, int envc, char **env) { int s_ind = 0; int arg_ind; unsigned long size = USER_STACK_NR_PAGES * PAGE_SIZE; char *stack = ihk_mc_alloc_pages(USER_STACK_NR_PAGES, IHK_MC_AP_NOWAIT); unsigned long *p = (unsigned long *)(stack + size); unsigned long end = process->vm->region.user_end; unsigned long start = end - size; int rc; if(stack == NULL) return -ENOMEM; memset(stack, 0, size); if ((rc = add_process_memory_range(process, start, end, virt_to_phys(stack), VR_STACK|VR_PROT_READ|VR_PROT_WRITE)) != 0) { ihk_mc_free_pages(stack, USER_STACK_NR_PAGES); return rc; } s_ind = -1; p[s_ind--] = 0; /* AT_NULL */ p[s_ind--] = 0; p[s_ind--] = pn->at_phnum; /* AT_PHNUM */ p[s_ind--] = AT_PHNUM; p[s_ind--] = pn->at_phent; /* AT_PHENT */ p[s_ind--] = AT_PHENT; p[s_ind--] = pn->at_phdr; /* AT_PHDR */ p[s_ind--] = AT_PHDR; p[s_ind--] = 0; /* envp terminating NULL */ /* envp */ for (arg_ind = envc - 1; arg_ind > -1; --arg_ind) { p[s_ind--] = (unsigned long)env[arg_ind]; } p[s_ind--] = 0; /* argv terminating NULL */ /* argv */ for (arg_ind = argc - 1; arg_ind > -1; --arg_ind) { p[s_ind--] = (unsigned long)argv[arg_ind]; } /* argc */ p[s_ind] = argc; ihk_mc_modify_user_context(process->uctx, IHK_UCR_STACK_POINTER, end + sizeof(unsigned long) * s_ind); process->vm->region.stack_end = end; process->vm->region.stack_start = start; return 0; } unsigned long extend_process_region(struct process *proc, unsigned long start, unsigned long end, unsigned long address, unsigned long flag) { unsigned long aligned_end, aligned_new_end; void *p; int rc; if (!address || address < start || address >= USER_END) { return end; } aligned_end = ((end + PAGE_SIZE - 1) & PAGE_MASK); if (aligned_end >= address) { return address; } aligned_new_end = (address + PAGE_SIZE - 1) & PAGE_MASK; #ifdef USE_LARGE_PAGES if (aligned_new_end - aligned_end >= LARGE_PAGE_SIZE) { if(flag & VR_DEMAND_PAGING){panic("demand paging for large page is not available!");} unsigned long p_aligned; unsigned long old_aligned_end = aligned_end; if ((aligned_end & (LARGE_PAGE_SIZE - 1)) != 0) { aligned_end = (aligned_end + (LARGE_PAGE_SIZE - 1)) & LARGE_PAGE_MASK; /* Fill in the gap between old_aligned_end and aligned_end * with regular pages */ if((p = allocate_pages((aligned_end - old_aligned_end) >> PAGE_SHIFT, IHK_MC_AP_NOWAIT)) == NULL){ return end; } if((rc = add_process_memory_range(proc, old_aligned_end, aligned_end, virt_to_phys(p), flag)) != 0){ free_pages(p, (aligned_end - old_aligned_end) >> PAGE_SHIFT); return end; } dkprintf("filled in gap for LARGE_PAGE_SIZE aligned start: 0x%lX -> 0x%lX\n", old_aligned_end, aligned_end); } /* Add large region for the actual mapping */ aligned_new_end = (aligned_new_end + (aligned_end - old_aligned_end) + (LARGE_PAGE_SIZE - 1)) & LARGE_PAGE_MASK; address = aligned_new_end; if((p = allocate_pages((aligned_new_end - aligned_end + LARGE_PAGE_SIZE) >> PAGE_SHIFT, IHK_MC_AP_NOWAIT)) == NULL){ return end; } p_aligned = ((unsigned long)p + (LARGE_PAGE_SIZE - 1)) & LARGE_PAGE_MASK; if (p_aligned > (unsigned long)p) { free_pages(p, (p_aligned - (unsigned long)p) >> PAGE_SHIFT); } free_pages( (void *)(p_aligned + aligned_new_end - aligned_end), (LARGE_PAGE_SIZE - (p_aligned - (unsigned long)p)) >> PAGE_SHIFT); if((rc = add_process_memory_range(proc, aligned_end, aligned_new_end, virt_to_phys((void *)p_aligned), flag)) != 0){ free_pages(p, (aligned_new_end - aligned_end + LARGE_PAGE_SIZE) >> PAGE_SHIFT); return end; } dkprintf("largePTE area: 0x%lX - 0x%lX (s: %lu) -> 0x%lX - \n", aligned_end, aligned_new_end, (aligned_new_end - aligned_end), virt_to_phys((void *)p_aligned)); return address; } #endif if(flag & VR_DEMAND_PAGING){ // demand paging no need to allocate page now kprintf("demand page do not allocate page\n"); p=0; }else{ p = allocate_pages((aligned_new_end - aligned_end) >> PAGE_SHIFT, IHK_MC_AP_NOWAIT); if (!p) { return end; } } if((rc = add_process_memory_range(proc, aligned_end, aligned_new_end, (p==0?0:virt_to_phys(p)), flag)) != 0){ free_pages(p, (aligned_new_end - aligned_end) >> PAGE_SHIFT); return end; } return address; } // Original version retained because dcfa (src/mccmd/client/ibmic/main.c) calls this int remove_process_region(struct process *proc, unsigned long start, unsigned long end) { if ((start & (PAGE_SIZE - 1)) || (end & (PAGE_SIZE - 1))) { return -EINVAL; } ihk_mc_spinlock_lock_noirq(&proc->vm->page_table_lock); /* We defer freeing to the time of exit */ // XXX: check error ihk_mc_pt_clear_range(proc->vm->page_table, (void *)start, (void *)end); ihk_mc_spinlock_unlock_noirq(&proc->vm->page_table_lock); return 0; } void free_process_memory(struct process *proc) { struct vm_range *range, *next; struct process_vm *vm = proc->vm; int error; if (vm == NULL) { return; } proc->vm = NULL; if (!ihk_atomic_dec_and_test(&vm->refcount)) { return; } ihk_mc_spinlock_lock_noirq(&vm->memory_range_lock); list_for_each_entry_safe(range, next, &vm->vm_range_list, list) { error = free_process_memory_range(vm, range); if (error) { ekprintf("free_process_memory(%p):" "free range failed. %lx-%lx %d\n", proc, range->start, range->end, error); /* through */ } } ihk_mc_spinlock_unlock_noirq(&vm->memory_range_lock); ihk_mc_pt_destroy(vm->page_table); free_process(vm->owner_process); } void hold_process(struct process *proc) { if (proc->status & (PS_ZOMBIE | PS_EXITED)) { panic("hold_process: already exited process"); } ihk_atomic_inc(&proc->refcount); return; } void destroy_process(struct process *proc) { if(ihk_atomic_dec_and_test(&proc->sighandler->use)){ kfree(proc->sighandler); } ihk_mc_free_pages(proc, KERNEL_STACK_NR_PAGES); } void free_process(struct process *proc) { if (!ihk_atomic_dec_and_test(&proc->refcount)) { return; } destroy_process(proc); } static void idle(void) { //unsigned int flags; //flags = ihk_mc_spinlock_lock(&cpu_status_lock); //ihk_mc_spinlock_unlock(&cpu_status_lock, flags); cpu_local_var(status) = CPU_STATUS_IDLE; while (1) { cpu_enable_interrupt(); schedule(); //cpu_local_var(status) = CPU_STATUS_IDLE; cpu_halt(); } } void sched_init(void) { struct process *idle_process = &cpu_local_var(idle); memset(idle_process, 0, sizeof(struct process)); memset(&cpu_local_var(idle_vm), 0, sizeof(struct process_vm)); idle_process->vm = &cpu_local_var(idle_vm); ihk_mc_init_context(&idle_process->ctx, NULL, idle); idle_process->pid = ihk_mc_get_processor_id(); INIT_LIST_HEAD(&cpu_local_var(runq)); cpu_local_var(runq_len) = 0; ihk_mc_spinlock_init(&cpu_local_var(runq_lock)); #ifdef TIMER_CPU_ID if (ihk_mc_get_processor_id() == TIMER_CPU_ID) { init_timers(); wake_timers_loop(); } #endif } void schedule(void) { struct cpu_local_var *v = get_this_cpu_local_var(); struct process *next, *prev, *proc, *tmp = NULL; int switch_ctx = 0; unsigned long irqstate; struct process *last; irqstate = ihk_mc_spinlock_lock(&(v->runq_lock)); next = NULL; prev = v->current; /* All runnable processes are on the runqueue */ if (prev && prev != &cpu_local_var(idle)) { list_del(&prev->sched_list); --v->runq_len; /* Round-robin if not exited yet */ if (!(prev->status & (PS_ZOMBIE | PS_EXITED))) { list_add_tail(&prev->sched_list, &(v->runq)); ++v->runq_len; } if (!v->runq_len) { v->status = CPU_STATUS_IDLE; } } /* Pick a new running process */ list_for_each_entry_safe(proc, tmp, &(v->runq), sched_list) { if (proc->status == PS_RUNNING) { next = proc; break; } } /* No process? Run idle.. */ if (!next) { next = &cpu_local_var(idle); } if (prev != next) { switch_ctx = 1; v->current = next; } if (switch_ctx) { dkprintf("[%d] schedule: %d => %d \n", ihk_mc_get_processor_id(), prev ? prev->pid : 0, next ? next->pid : 0); ihk_mc_load_page_table(next->vm->page_table); dkprintf("[%d] schedule: tlsblock_base: 0x%lX\n", ihk_mc_get_processor_id(), next->thread.tlsblock_base); /* Set up new TLS.. */ do_arch_prctl(ARCH_SET_FS, next->thread.tlsblock_base); ihk_mc_spinlock_unlock(&(v->runq_lock), irqstate); if (prev) { last = ihk_mc_switch_context(&prev->ctx, &next->ctx, prev); } else { last = ihk_mc_switch_context(NULL, &next->ctx, prev); } if ((last != NULL) && (last->status & (PS_ZOMBIE | PS_EXITED))) { free_process_memory(last); free_process(last); } } else { ihk_mc_spinlock_unlock(&(v->runq_lock), irqstate); } } int sched_wakeup_process(struct process *proc, int valid_states) { int status; int spin_slept = 0; unsigned long irqstate; struct cpu_local_var *v = get_cpu_local_var(proc->cpu_id); irqstate = ihk_mc_spinlock_lock(&(proc->spin_sleep_lock)); if (proc->spin_sleep) { dkprintf("sched_wakeup_process() spin wakeup: cpu_id: %d\n", proc->cpu_id); spin_slept = 1; proc->spin_sleep = 0; status = 0; } ihk_mc_spinlock_unlock(&(proc->spin_sleep_lock), irqstate); if (spin_slept) return status; irqstate = ihk_mc_spinlock_lock(&(v->runq_lock)); if (proc->status & valid_states) { xchg4((int *)(&proc->status), PS_RUNNING); status = 0; } else { status = -EINVAL; } ihk_mc_spinlock_unlock(&(v->runq_lock), irqstate); if (!status && (proc->cpu_id != ihk_mc_get_processor_id())) { ihk_mc_interrupt_cpu(get_x86_cpu_local_variable(proc->cpu_id)->apic_id, 0xd1); } return status; } /* Runq lock must be held here */ void __runq_add_proc(struct process *proc, int cpu_id) { struct cpu_local_var *v = get_cpu_local_var(cpu_id); list_add_tail(&proc->sched_list, &v->runq); ++v->runq_len; proc->cpu_id = cpu_id; proc->status = PS_RUNNING; get_cpu_local_var(cpu_id)->status = CPU_STATUS_RUNNING; dkprintf("runq_add_proc(): pid %d added to CPU[%d]'s runq\n", proc->pid, cpu_id); } void runq_add_proc(struct process *proc, int cpu_id) { struct cpu_local_var *v = get_cpu_local_var(cpu_id); unsigned long irqstate; irqstate = ihk_mc_spinlock_lock(&(v->runq_lock)); __runq_add_proc(proc, cpu_id); ihk_mc_spinlock_unlock(&(v->runq_lock), irqstate); /* Kick scheduler */ if (cpu_id != ihk_mc_get_processor_id()) ihk_mc_interrupt_cpu( get_x86_cpu_local_variable(cpu_id)->apic_id, 0xd1); } /* NOTE: shouldn't remove a running process! */ void runq_del_proc(struct process *proc, int cpu_id) { struct cpu_local_var *v = get_cpu_local_var(cpu_id); unsigned long irqstate; irqstate = ihk_mc_spinlock_lock(&(v->runq_lock)); list_del(&proc->sched_list); --v->runq_len; if (!v->runq_len) get_cpu_local_var(cpu_id)->status = CPU_STATUS_IDLE; ihk_mc_spinlock_unlock(&(v->runq_lock), irqstate); }