#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct proc* proc_from_elf(uint8_t* elf_contents) { struct limine_hhdm_response* hhdm = limine_hhdm_request.response; struct proc* proc = malloc(sizeof(*proc)); if (proc == NULL) return NULL; memset(proc, 0, sizeof(*proc)); proc->state = PROC_READY; proc->pid = proc_alloc_pid(); if (proc->pid < 0) { free(proc); return NULL; } proc->procgroup = procgroup_create(); if (proc->procgroup == NULL) { free(proc); return NULL; } procgroup_attach(proc->procgroup, proc); uintptr_t kstack_paddr = pmm_alloc(KSTACK_SIZE / PAGE_SIZE); proc->pdata.kernel_stack = kstack_paddr + (uintptr_t)hhdm->offset + KSTACK_SIZE; procgroup_map(proc->procgroup, PROC_USTACK_TOP - USTACK_SIZE, USTACK_SIZE / PAGE_SIZE, MM_PG_USER | MM_PG_PRESENT | MM_PG_RW, NULL); proc->flags |= PROC_USTK_PREALLOC; struct elf_aux aux = proc_load_segments(proc, elf_contents); proc->pdata.regs.ss = GDT_UDATA | 0x03; proc->pdata.regs.rsp = (uint64_t)PROC_USTACK_TOP; proc->pdata.regs.rflags = 0x202; proc->pdata.regs.cs = GDT_UCODE | 0x03; proc->pdata.regs.rip = aux.entry; fx_init(proc->pdata.fx_env); proc->exec_pid = -1; return proc; } struct proc* proc_clone(struct proc* proto, uintptr_t vstack_top, uintptr_t entry, uintptr_t argument_ptr) { struct limine_hhdm_response* hhdm = limine_hhdm_request.response; struct proc* proc = malloc(sizeof(*proc)); if (proc == NULL) return NULL; memset(proc, 0, sizeof(*proc)); proc->state = PROC_READY; proc->pid = proc_alloc_pid(); if (proc->pid < 0) { free(proc); return NULL; } memcpy(proc->name, proto->name, sizeof(proto->name)); proc->procgroup = proto->procgroup; procgroup_attach(proc->procgroup, proc); uintptr_t kstack_paddr = pmm_alloc(KSTACK_SIZE / PAGE_SIZE); proc->pdata.kernel_stack = kstack_paddr + (uintptr_t)hhdm->offset + KSTACK_SIZE; proc->pdata.regs.ss = GDT_UDATA | 0x03; proc->pdata.regs.rsp = (uint64_t)vstack_top; proc->pdata.regs.rflags = 0x202; proc->pdata.regs.cs = GDT_UCODE | 0x03; proc->pdata.regs.rip = (uint64_t)entry; fx_init(proc->pdata.fx_env); proc->uvaddr_argument = argument_ptr; proc_init_tls(proc); proc->exec_pid = -1; return proc; } void proc_cleanup(struct proc* proc, struct reschedule_ctx* rctx) { while (proc->done_sq.proc_list != NULL) { struct list_node_link* node = proc->done_sq.proc_list; struct proc_sq_entry* sq_entry = list_entry(node, struct proc_sq_entry, sq_link); struct proc* suspended_proc = sq_entry->proc; proc_sq_resume(suspended_proc, sq_entry, rctx, (uintptr_t)proc->pid); } proc_sqs_cleanup(proc); proc_mutexes_cleanup(proc, rctx); pmm_free(proc->pdata.kernel_stack, KSTACK_SIZE / PAGE_SIZE); procgroup_unmap(proc->procgroup, proc->pdata.tls_vaddr, proc->procgroup->tls.tls_tmpl_pages); procgroup_detach(proc->procgroup, proc, rctx); proc_free_pid(proc->pid); /* clean the process */ free(proc); } void proc_init_tls(struct proc* proc) { struct limine_hhdm_response* hhdm = limine_hhdm_request.response; if (proc->procgroup->tls.tls_tmpl == NULL) return; size_t tls_size = proc->procgroup->tls.tls_tmpl_size; size_t pages = proc->procgroup->tls.tls_tmpl_pages; uintptr_t tls_paddr; uint32_t flags = MM_PG_USER | MM_PG_PRESENT | MM_PG_RW; uintptr_t tls_vaddr = procgroup_map(proc->procgroup, 0, pages, flags, &tls_paddr); uintptr_t k_tls_addr = (uintptr_t)hhdm->offset + tls_paddr; memset((void*)k_tls_addr, 0, pages * PAGE_SIZE); memcpy((void*)k_tls_addr, (void*)proc->procgroup->tls.tls_tmpl, tls_size); uintptr_t ktcb = k_tls_addr + tls_size; uintptr_t utcb = tls_vaddr + tls_size; *(uintptr_t*)ktcb = utcb; proc->pdata.fs_base = utcb; proc->pdata.tls_vaddr = tls_vaddr; } void proc_set_syscall_value(struct proc* proc, uintptr_t value) { proc->pdata.regs.rax = value; }