Implement parts A and B.
This commit is contained in:
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@ -356,6 +356,7 @@ load_icode(struct Env *e, uint8_t *binary)
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// LAB 3: Your code here.
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// TODO validate the headers
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lcr3(PADDR(e->env_pgdir));
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struct Elf* elf = (struct Elf*) binary;
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struct Proghdr* ph = (struct Proghdr*) (binary + elf->e_phoff);
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struct Proghdr* phend = ph + elf->e_phnum;
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@ -363,11 +364,10 @@ load_icode(struct Env *e, uint8_t *binary)
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if(ph->p_type != ELF_PROG_LOAD) continue;
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region_alloc(e, (void*) ph->p_va, ph->p_memsz);
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lcr3(PADDR(e->env_pgdir));
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memcpy((void*) ph->p_va, binary + ph->p_offset, ph->p_filesz);
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memset((void*) ph->p_va + ph->p_filesz, 0, ph->p_memsz - ph->p_filesz);
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lcr3(PADDR(kern_pgdir));
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}
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lcr3(PADDR(kern_pgdir));
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e->env_tf.tf_eip = elf->e_entry;
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// Now map one page for the program's initial stack
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@ -528,6 +528,7 @@ env_run(struct Env *e)
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e->env_status = ENV_RUNNING;
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e->env_runs++;
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lcr3(PADDR(e->env_pgdir));
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unlock_kernel();
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env_pop_tf(&e->env_tf);
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}
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@ -55,6 +55,7 @@ i386_init(void)
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// Acquire the big kernel lock before waking up APs
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// Your code here:
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lock_kernel();
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// Starting non-boot CPUs
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boot_aps();
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@ -64,7 +65,10 @@ i386_init(void)
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ENV_CREATE(TEST, ENV_TYPE_USER);
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#else
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// Touch all you want.
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ENV_CREATE(user_primes, ENV_TYPE_USER);
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ENV_CREATE(user_yield, ENV_TYPE_USER);
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ENV_CREATE(user_yield, ENV_TYPE_USER);
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ENV_CREATE(user_yield, ENV_TYPE_USER);
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ENV_CREATE(user_yield, ENV_TYPE_USER);
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#endif // TEST*
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// Schedule and run the first user environment!
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@ -121,6 +125,8 @@ mp_main(void)
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// only one CPU can enter the scheduler at a time!
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//
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// Your code here:
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lock_kernel();
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sched_yield();
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// Remove this after you finish Exercise 6
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for (;;);
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17
kern/pmap.c
17
kern/pmap.c
@ -195,6 +195,7 @@ mem_init(void)
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// - the new image at UENVS -- kernel R, user R
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// - envs itself -- kernel RW, user NONE
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// LAB 3: Your code here.
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cprintf("Mapping envs from %p to %p\n", UENVS, ROUNDUP(envs_size, PGSIZE));
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boot_map_region(kern_pgdir,
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UENVS, ROUNDUP(envs_size, PGSIZE),
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PADDR(envs), PTE_U);
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@ -276,6 +277,11 @@ mem_init_mp(void)
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// Permissions: kernel RW, user NONE
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//
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// LAB 4: Your code here:
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for(int i = 0; i < NCPU; i++) {
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uintptr_t kstacktop = KSTACKTOP - i * (KSTKSIZE + KSTKGAP);
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boot_map_region(kern_pgdir, kstacktop - KSTKSIZE,
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KSTKSIZE, PADDR(percpu_kstacks[i]), PTE_W);
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}
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}
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@ -289,6 +295,7 @@ is_reserved(size_t pagenum) {
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if(pagenum == 0) return true;
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if(pagenum >= PGNUM(IOPHYSMEM) &&
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pagenum < PGNUM(PADDR(boot_alloc(0)))) return true;
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if(pagenum == PGNUM(MPENTRY_PADDR)) return true;
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return false;
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}
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@ -596,7 +603,15 @@ mmio_map_region(physaddr_t pa, size_t size)
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// Hint: The staff solution uses boot_map_region.
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//
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// Your code here:
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panic("mmio_map_region not implemented");
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size = ROUNDUP(size, PGSIZE);
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if((base + size) > MMIOLIM)
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panic("Not enough memory-mapped IO space!");
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boot_map_region(kern_pgdir, base, size, pa, PTE_PCD | PTE_PWT | PTE_W);
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uintptr_t to_return = base;
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base += size;
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return (void*) to_return;
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}
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static uintptr_t user_mem_check_addr;
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17
kern/sched.c
17
kern/sched.c
@ -29,6 +29,23 @@ sched_yield(void)
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// below to halt the cpu.
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// LAB 4: Your code here.
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struct Env* next_env = curenv ? curenv + 1 : envs;
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struct Env* end_env = envs + NENV;
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struct Env* to_run = NULL;
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for(int i = 0; i < NENV; i++, next_env++) {
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if(next_env == end_env) next_env = envs;
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if(next_env->env_status == ENV_RUNNABLE) {
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to_run = next_env;
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break;
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}
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}
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if(!to_run && curenv && curenv->env_status == ENV_RUNNING) {
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to_run = curenv;
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}
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if(to_run) env_run(to_run);
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// sched_halt never returns
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sched_halt();
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@ -80,9 +80,16 @@ sys_exofork(void)
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// status is set to ENV_NOT_RUNNABLE, and the register set is copied
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// from the current environment -- but tweaked so sys_exofork
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// will appear to return 0.
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struct Env* new_env;
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int error_code;
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error_code = env_alloc(&new_env, curenv->env_id);
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if(error_code < 0) return error_code;
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// LAB 4: Your code here.
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panic("sys_exofork not implemented");
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new_env->env_tf = curenv->env_tf;
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new_env->env_tf.tf_regs.reg_eax = 0;
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new_env->env_status = ENV_NOT_RUNNABLE;
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return new_env->env_id;
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}
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// Set envid's env_status to status, which must be ENV_RUNNABLE
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@ -100,9 +107,17 @@ sys_env_set_status(envid_t envid, int status)
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// You should set envid2env's third argument to 1, which will
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// check whether the current environment has permission to set
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// envid's status.
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struct Env* env;
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int error_code;
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// LAB 4: Your code here.
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panic("sys_env_set_status not implemented");
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error_code = envid2env(envid, &env, 1);
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if(error_code < 0) return error_code;
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if(status != ENV_RUNNABLE && status != ENV_NOT_RUNNABLE)
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return -E_INVAL;
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env->env_status = status;
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return 0;
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}
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// Set the page fault upcall for 'envid' by modifying the corresponding struct
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@ -116,10 +131,18 @@ sys_env_set_status(envid_t envid, int status)
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static int
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sys_env_set_pgfault_upcall(envid_t envid, void *func)
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{
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// LAB 4: Your code here.
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panic("sys_env_set_pgfault_upcall not implemented");
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struct Env* env;
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int return_code;
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if((return_code = envid2env(envid, &env, 1)) < 0) return return_code;
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env->env_pgfault_upcall = func;
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return 0;
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}
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#define SYS_CHECKPERMS(perm) \
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((((perm) & (PTE_P | PTE_U)) == (PTE_P | PTE_U)) && \
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(((perm) & ~(PTE_P | PTE_U | PTE_W | PTE_AVAIL)) == 0))
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#define SYS_CHECKADDR(addr) (((uintptr_t) (addr) < UTOP) && ((uintptr_t) (addr) % PGSIZE == 0))
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// Allocate a page of memory and map it at 'va' with permission
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// 'perm' in the address space of 'envid'.
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// The page's contents are set to 0.
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@ -145,9 +168,22 @@ sys_page_alloc(envid_t envid, void *va, int perm)
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// parameters for correctness.
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// If page_insert() fails, remember to free the page you
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// allocated!
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struct Env* env;
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int return_code;
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if((return_code = envid2env(envid, &env, 1)) < 0) return return_code;
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if(!SYS_CHECKPERMS(perm)) return -E_INVAL;
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if(!SYS_CHECKADDR(va)) return -E_INVAL;
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// LAB 4: Your code here.
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panic("sys_page_alloc not implemented");
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struct PageInfo* page = page_alloc(1);
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if(!page) return -E_NO_MEM;
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if((return_code = page_insert(env->env_pgdir, page, va, perm)) < 0) {
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page_free(page);
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return return_code;
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}
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return 0;
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}
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// Map the page of memory at 'srcva' in srcenvid's address space
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@ -176,9 +212,24 @@ sys_page_map(envid_t srcenvid, void *srcva,
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// parameters for correctness.
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// Use the third argument to page_lookup() to
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// check the current permissions on the page.
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struct Env *srcenv, *dstenv;
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pte_t* srcpte;
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int return_code;
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// LAB 4: Your code here.
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panic("sys_page_map not implemented");
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if((return_code = envid2env(srcenvid, &srcenv, 1)) < 0) return return_code;
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if((return_code = envid2env(dstenvid, &dstenv, 1)) < 0) return return_code;
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if(!SYS_CHECKADDR(srcva)) return -E_INVAL;
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if(!SYS_CHECKADDR(dstva)) return -E_INVAL;
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if(!SYS_CHECKPERMS(perm)) return -E_INVAL;
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struct PageInfo* page = page_lookup(srcenv->env_pgdir, srcva, &srcpte);
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if(page == NULL) return -E_INVAL;
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if(perm & PTE_W && !(*srcpte & PTE_W)) return -E_INVAL;
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if((return_code = page_insert(dstenv->env_pgdir, page, dstva, perm)) < 0)
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return return_code;
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return 0;
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}
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// Unmap the page of memory at 'va' in the address space of 'envid'.
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@ -192,9 +243,14 @@ static int
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sys_page_unmap(envid_t envid, void *va)
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{
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// Hint: This function is a wrapper around page_remove().
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struct Env* env;
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int return_code;
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// LAB 4: Your code here.
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panic("sys_page_unmap not implemented");
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if((return_code = envid2env(envid, &env, 1)) < 0) return return_code;
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if(!SYS_CHECKADDR(va)) return -E_INVAL;
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page_remove(env->env_pgdir, va);
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return 0;
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}
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// Try to send 'value' to the target env 'envid'.
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@ -279,6 +335,21 @@ syscall(uint32_t syscallno, uint32_t a1, uint32_t a2, uint32_t a3, uint32_t a4,
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return sys_getenvid();
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case SYS_env_destroy:
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return sys_env_destroy(a1);
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case SYS_yield:
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sys_yield();
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return 0;
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case SYS_exofork:
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return sys_exofork();
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case SYS_env_set_status:
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return sys_env_set_status(a1, a2);
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case SYS_env_set_pgfault_upcall:
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return sys_env_set_pgfault_upcall(a1, (void*) a2);
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case SYS_page_alloc:
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return sys_page_alloc(a1, (void*) a2, a3);
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case SYS_page_map:
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return sys_page_map(a1, (void*) a2, a3, (void*) a4, a5);
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case SYS_page_unmap:
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return sys_page_unmap(a1, (void*) a2);
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default:
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return -E_INVAL;
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}
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51
kern/trap.c
51
kern/trap.c
@ -160,18 +160,18 @@ trap_init_percpu(void)
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// Setup a TSS so that we get the right stack
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// when we trap to the kernel.
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ts.ts_esp0 = KSTACKTOP;
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ts.ts_ss0 = GD_KD;
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ts.ts_iomb = sizeof(struct Taskstate);
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thiscpu->cpu_ts.ts_esp0 = KSTACKTOP - thiscpu->cpu_id * (KSTKSIZE + KSTKGAP);
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thiscpu->cpu_ts.ts_ss0 = GD_KD;
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thiscpu->cpu_ts.ts_iomb = sizeof(struct Taskstate);
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// Initialize the TSS slot of the gdt.
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gdt[GD_TSS0 >> 3] = SEG16(STS_T32A, (uint32_t) (&ts),
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gdt[(GD_TSS0 >> 3) + cpunum()] = SEG16(STS_T32A, (uint32_t) (&thiscpu->cpu_ts),
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sizeof(struct Taskstate) - 1, 0);
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gdt[GD_TSS0 >> 3].sd_s = 0;
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gdt[(GD_TSS0 >> 3) + cpunum()].sd_s = 0;
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// Load the TSS selector (like other segment selectors, the
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// bottom three bits are special; we leave them 0)
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ltr(GD_TSS0);
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ltr(GD_TSS0 + (cpunum() << 3));
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// Load the IDT
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lidt(&idt_pd);
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@ -294,6 +294,7 @@ trap(struct Trapframe *tf)
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// Acquire the big kernel lock before doing any
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// serious kernel work.
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// LAB 4: Your code here.
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lock_kernel();
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assert(curenv);
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// Garbage collect if current enviroment is a zombie
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@ -373,11 +374,39 @@ page_fault_handler(struct Trapframe *tf)
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// (the 'tf' variable points at 'curenv->env_tf').
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// LAB 4: Your code here.
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if(!curenv->env_pgfault_upcall) {
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// Destroy the environment that caused the fault.
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cprintf("[%08x] user fault va %08x ip %08x\n",
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curenv->env_id, fault_va, tf->tf_eip);
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print_trapframe(tf);
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env_destroy(curenv);
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}
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user_mem_assert(curenv, curenv->env_pgfault_upcall, 1, PTE_U | PTE_P);
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user_mem_assert(curenv, (void*) UXSTACKTOP - 1, 1, PTE_U | PTE_P | PTE_W);
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// Destroy the environment that caused the fault.
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cprintf("[%08x] user fault va %08x ip %08x\n",
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curenv->env_id, fault_va, tf->tf_eip);
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print_trapframe(tf);
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env_destroy(curenv);
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uintptr_t top_addr = UXSTACKTOP;
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if(tf->tf_esp <= UXSTACKTOP && tf->tf_esp >= (UXSTACKTOP - PGSIZE)) {
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top_addr = tf->tf_esp - 4;
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}
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struct UTrapframe utf;
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utf.utf_eflags = tf->tf_eflags;
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utf.utf_eip = tf->tf_eip;
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utf.utf_err = tf->tf_err;
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utf.utf_esp = tf->tf_esp;
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utf.utf_fault_va = fault_va;
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utf.utf_regs = tf->tf_regs;
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struct UTrapframe* push_to = (struct UTrapframe*) top_addr - 1;
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if((uintptr_t) push_to < USTACKTOP - PGSIZE) {
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cprintf("[%08x] stack overflow in page fault handler\n",
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curenv->env_id);
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env_destroy(curenv);
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}
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*push_to = utf;
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curenv->env_tf.tf_eip = (uintptr_t) curenv->env_pgfault_upcall;
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curenv->env_tf.tf_esp = (uintptr_t) push_to;
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env_run(curenv);
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}
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75
lib/fork.c
75
lib/fork.c
@ -23,18 +23,22 @@ pgfault(struct UTrapframe *utf)
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// Hint:
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// Use the read-only page table mappings at uvpt
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// (see <inc/memlayout.h>).
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// LAB 4: Your code here.
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if(!((err & FEC_WR) && (uvpt[(uintptr_t) addr >> PGSHIFT] & PTE_COW)))
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panic("page fault (addr %p)! %c", addr, (err & FEC_WR) ? 'w' : 'r');
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// Allocate a new page, map it at a temporary location (PFTEMP),
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// copy the data from the old page to the new page, then move the new
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// page to the old page's address.
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// Hint:
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// You should make three system calls.
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void* temp_addr = (void*) PFTEMP;
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void* fault_addr = ROUNDDOWN(addr, PGSIZE);
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if(sys_page_alloc(0, temp_addr, PTE_P | PTE_W | PTE_U) < 0)
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panic("failed to allocate new page");
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// LAB 4: Your code here.
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panic("pgfault not implemented");
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memcpy(temp_addr, fault_addr, PGSIZE);
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sys_page_map(0, temp_addr, 0, fault_addr, PTE_P | PTE_U | PTE_W);
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sys_page_unmap(0, temp_addr);
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}
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//
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@ -52,9 +56,27 @@ static int
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duppage(envid_t envid, unsigned pn)
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{
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int r;
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bool change_own = false;
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pte_t new_pte = uvpt[pn];
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pte_t perms = new_pte & (PTE_P | PTE_U | PTE_W | PTE_AVAIL);
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void* addr = (void*) (pn * PGSIZE);
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// If we're writable, remove write permission
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if((new_pte & PTE_W) || (new_pte & PTE_COW)) {
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perms = (perms & ~PTE_W) | PTE_COW;
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change_own = true;
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}
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// Map either with the same permissions or with COW.
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if((r = sys_page_map(0, addr, envid, addr, perms)) < 0)
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return r;
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// Update our own permissions if necessary
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if(change_own) {
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if((r = sys_page_map(0, addr, 0, addr, perms)) < 0)
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return r;
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}
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// LAB 4: Your code here.
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panic("duppage not implemented");
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return 0;
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}
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||||
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||||
@ -77,8 +99,43 @@ duppage(envid_t envid, unsigned pn)
|
||||
envid_t
|
||||
fork(void)
|
||||
{
|
||||
// LAB 4: Your code here.
|
||||
panic("fork not implemented");
|
||||
set_pgfault_handler(pgfault);
|
||||
|
||||
int return_code;
|
||||
envid_t forked;
|
||||
|
||||
forked = sys_exofork();
|
||||
if(forked < 0) return forked;
|
||||
if(forked == 0) { thisenv = &envs[ENVX(sys_getenvid())]; return 0; }
|
||||
|
||||
// Map all accessible page directory entries
|
||||
for(int pde_i = 0; pde_i < PDX(UTOP); pde_i++) {
|
||||
pde_t pde = uvpd[pde_i];
|
||||
if(!(pde & PTE_P)) continue;
|
||||
|
||||
// For each PDE, map all the underlying PTEs
|
||||
for(int pte_i = 0; pte_i < NPTENTRIES; pte_i++) {
|
||||
int pn = pde_i * NPTENTRIES + pte_i;
|
||||
pte_t pte = uvpt[pn];
|
||||
if(!(pte & PTE_P)) continue;
|
||||
|
||||
// Do not map user exception stack, though
|
||||
if(pn == ((UXSTACKTOP - PGSIZE) >> PGSHIFT)) continue;
|
||||
|
||||
if((return_code = duppage(forked, pn)) < 0) return return_code;
|
||||
}
|
||||
}
|
||||
|
||||
// Allocate new page for the exception stack
|
||||
return_code = sys_page_alloc(forked, (void*) UXSTACKTOP - PGSIZE,
|
||||
PTE_P | PTE_U | PTE_W);
|
||||
if(return_code < 0) return return_code;
|
||||
|
||||
// Set the upcall entry point
|
||||
sys_env_set_pgfault_upcall(forked, thisenv->env_pgfault_upcall);
|
||||
sys_env_set_status(forked, ENV_RUNNABLE);
|
||||
|
||||
return forked;
|
||||
}
|
||||
|
||||
// Challenge!
|
||||
|
@ -65,18 +65,29 @@ _pgfault_upcall:
|
||||
// ways as registers become unavailable as scratch space.
|
||||
//
|
||||
// LAB 4: Your code here.
|
||||
mov 40(%esp), %eax // Take the EIP from memory
|
||||
mov 48(%esp), %ebp // Take the ESP from memory
|
||||
sub $4, %ebp // Push onto trap-time ESP
|
||||
mov %eax, (%ebp)
|
||||
mov %ebp, 48(%esp) // Put ESP back
|
||||
|
||||
// Restore the trap-time registers. After you do this, you
|
||||
// can no longer modify any general-purpose registers.
|
||||
// LAB 4: Your code here.
|
||||
add $0x8, %esp
|
||||
popal
|
||||
|
||||
// Restore eflags from the stack. After you do this, you can
|
||||
// no longer use arithmetic operations or anything else that
|
||||
// modifies eflags.
|
||||
// LAB 4: Your code here.
|
||||
add $0x4, %esp
|
||||
popfl
|
||||
|
||||
// Switch back to the adjusted trap-time stack.
|
||||
// LAB 4: Your code here.
|
||||
pop %esp
|
||||
|
||||
// Return to re-execute the instruction that faulted.
|
||||
// LAB 4: Your code here.
|
||||
ret
|
||||
|
@ -27,9 +27,9 @@ set_pgfault_handler(void (*handler)(struct UTrapframe *utf))
|
||||
int r;
|
||||
|
||||
if (_pgfault_handler == 0) {
|
||||
// First time through!
|
||||
// LAB 4: Your code here.
|
||||
panic("set_pgfault_handler not implemented");
|
||||
if(sys_page_alloc(0, (void*) UXSTACKTOP - PGSIZE, PTE_U | PTE_P | PTE_W) < 0)
|
||||
panic("set_pgfault_handler");
|
||||
sys_env_set_pgfault_upcall(0, _pgfault_upcall);
|
||||
}
|
||||
|
||||
// Save handler pointer for assembly to call.
|
||||
|
Loading…
Reference in New Issue
Block a user