static bool load (const char *cmdline, void (**eip) (void), void **esp);
/* Starts a new thread running a user program loaded from
- FILENAME. The new thread may be scheduled before
- process_execute() returns.*/
+ FILENAME. The new thread may be scheduled (and may even exit)
+ before process_execute() returns. Returns the new process's
+ thread id, or TID_ERROR if the thread cannot be created. */
tid_t
process_execute (const char *filename)
{
/* Initialize interrupt frame and load executable. */
memset (&if_, 0, sizeof if_);
- if_.es = SEL_UDSEG;
- if_.ds = SEL_UDSEG;
+ if_.gs = if_.fs = if_.es = if_.ds = if_.ss = SEL_UDSEG;
if_.cs = SEL_UCSEG;
if_.eflags = FLAG_IF | FLAG_MBS;
- if_.ss = SEL_UDSEG;
success = load (filename, &if_.eip, &if_.esp);
/* If load failed, quit. */
if (!success)
thread_exit ();
- /* Switch page tables. */
- process_activate ();
-
/* Start the user process by simulating a return from an
interrupt, implemented by intr_exit (in
- threads/intr-stubs.pl). Because intr_exit takes all of its
+ threads/intr-stubs.S). Because intr_exit takes all of its
arguments on the stack in the form of a `struct intr_frame',
we just point the stack pointer (%esp) to our stack frame
and jump to it. */
- asm ("mov %%esp, %0; jmp intr_exit" :: "g" (&if_));
+ asm ("movl %0, %%esp; jmp intr_exit" :: "g" (&if_));
NOT_REACHED ();
}
+/* Waits for thread TID to die and returns its exit status. If
+ it was terminated by the kernel (i.e. killed due to an
+ exception), returns -1. If TID is invalid or if it was not a
+ child of the calling process, or if process_wait() has already
+ been successfully called for the given TID, returns -1
+ immediately, without waiting.
+
+ This function will be implemented in problem 2-2. For now, it
+ does nothing. */
+int
+process_wait (tid_t child_tid UNUSED)
+{
+ return -1;
+}
+
/* Free the current process's resources. */
void
process_exit (void)
uint32_t *pd;
/* Destroy the current process's page directory and switch back
- to the kernel-only page directory. We have to set
- cur->pagedir to NULL before switching page directories, or a
- timer interrupt might switch back to the process page
- directory. */
+ to the kernel-only page directory. */
pd = cur->pagedir;
if (pd != NULL)
{
+ /* Correct ordering here is crucial. We must set
+ cur->pagedir to NULL before switching page directories,
+ so that a timer interrupt can't switch back to the
+ process page directory. We must activate the base page
+ directory before destroying the process's page
+ directory, or our active page directory will be one
+ that's been freed (and cleared). */
cur->pagedir = NULL;
pagedir_activate (NULL);
pagedir_destroy (pd);
static bool load_segment (struct file *, const struct Elf32_Phdr *);
static bool setup_stack (void **esp);
-/* Aborts loading an executable, with an error message. */
-#define LOAD_ERROR(MSG) \
- do { \
- printf ("load: %s: ", filename); \
- printf MSG; \
- printf ("\n"); \
- goto done; \
- } while (0)
-
/* Loads an ELF executable from FILENAME into the current thread.
Stores the executable's entry point into *EIP
and its initial stack pointer into *ESP.
bool success = false;
int i;
- /* Allocate page directory. */
+ /* Allocate and activate page directory. */
t->pagedir = pagedir_create ();
- if (t->pagedir == NULL)
- LOAD_ERROR (("page directory allocation failed"));
+ if (t->pagedir == NULL)
+ goto done;
+ process_activate ();
/* Open executable file. */
file = filesys_open (filename);
- if (file == NULL)
- LOAD_ERROR (("open failed"));
+ if (file == NULL)
+ {
+ printf ("load: %s: open failed\n", filename);
+ goto done;
+ }
/* Read and verify executable header. */
- if (file_read (file, &ehdr, sizeof ehdr) != sizeof ehdr)
- LOAD_ERROR (("error reading executable header"));
- if (memcmp (ehdr.e_ident, "\177ELF\1\1\1", 7) != 0)
- LOAD_ERROR (("file is not ELF"));
- if (ehdr.e_type != 2)
- LOAD_ERROR (("ELF file is not an executable"));
- if (ehdr.e_machine != 3)
- LOAD_ERROR (("ELF executable is not x86"));
- if (ehdr.e_version != 1)
- LOAD_ERROR (("ELF executable has unknown version %d",
- (int) ehdr.e_version));
- if (ehdr.e_phentsize != sizeof (struct Elf32_Phdr))
- LOAD_ERROR (("bad ELF program header size"));
- if (ehdr.e_phnum > 1024)
- LOAD_ERROR (("too many ELF program headers"));
+ if (file_read (file, &ehdr, sizeof ehdr) != sizeof ehdr
+ || memcmp (ehdr.e_ident, "\177ELF\1\1\1", 7)
+ || ehdr.e_type != 2
+ || ehdr.e_machine != 3
+ || ehdr.e_version != 1
+ || ehdr.e_phentsize != sizeof (struct Elf32_Phdr)
+ || ehdr.e_phnum > 1024)
+ {
+ printf ("load: %s: error loading executable\n", filename);
+ goto done;
+ }
/* Read program headers. */
file_ofs = ehdr.e_phoff;
struct Elf32_Phdr phdr;
if (file_ofs < 0 || file_ofs > file_length (file))
- LOAD_ERROR (("bad file offset %ld", (long) file_ofs));
+ goto done;
file_seek (file, file_ofs);
if (file_read (file, &phdr, sizeof phdr) != sizeof phdr)
- LOAD_ERROR (("error reading program header"));
+ goto done;
file_ofs += sizeof phdr;
switch (phdr.p_type)
{
case PT_NOTE:
case PT_PHDR:
case PT_STACK:
+ default:
/* Ignore this segment. */
break;
case PT_DYNAMIC:
case PT_INTERP:
case PT_SHLIB:
- /* Reject the executable. */
- LOAD_ERROR (("unsupported ELF segment type %d\n", phdr.p_type));
- break;
- default:
- printf ("unknown ELF segment type %08x\n", phdr.p_type);
- break;
+ goto done;
case PT_LOAD:
if (!load_segment (file, &phdr))
goto done;
/* [ELF1] 2-2 says that p_offset and p_vaddr must be congruent
modulo PGSIZE. */
if (phdr->p_offset % PGSIZE != phdr->p_vaddr % PGSIZE)
- {
- printf ("%#08"PE32Ox" and %#08"PE32Ax" not congruent modulo %#x\n",
- phdr->p_offset, phdr->p_vaddr, (unsigned) PGSIZE);
- return false;
- }
+ return false;
/* p_offset must point within file. */
if (phdr->p_offset > (Elf32_Off) file_length (file))
- {
- printf ("bad p_offset %"PE32Ox, phdr->p_offset);
- return false;
- }
+ return false;
/* [ELF1] 2-3 says that p_memsz must be at least as big as
p_filesz. */
if (phdr->p_memsz < phdr->p_filesz)
- {
- printf ("p_memsz (%08"PE32Wx") < p_filesz (%08"PE32Wx")\n",
- phdr->p_memsz, phdr->p_filesz);
- return false;
- }
+ return false;
/* Validate virtual memory region to be mapped.
The region must both start and end within the user address
- space range starting at 0 and ending at PHYS_BASE (typically
- 3 GB == 0xc0000000). */
+ space range. We don't allow mapping page 0.*/
start = pg_round_down ((void *) phdr->p_vaddr);
end = pg_round_up ((void *) (phdr->p_vaddr + phdr->p_memsz));
- if (start >= PHYS_BASE || end >= PHYS_BASE || end < start)
- {
- printf ("bad virtual region %08lx...%08lx\n",
- (unsigned long) start, (unsigned long) end);
- return false;
- }
+ if (!is_user_vaddr (start) || !is_user_vaddr (end) || end < start
+ || start == 0)
+ return false;
/* Load the segment page-by-page into memory. */
filesz_left = phdr->p_filesz + (phdr->p_vaddr & PGMASK);
else
palloc_free_page (kpage);
}
- else
- printf ("failed to allocate process stack\n");
-
return success;
}
/* Adds a mapping from user virtual address UPAGE to kernel
- virtual address KPAGE to the page table. Fails if UPAGE is
- already mapped or if memory allocation fails. */
+ virtual address KPAGE to the page table.
+ UPAGE must not already be mapped.
+ KPAGE should probably be a page obtained from the user pool
+ with palloc_get_page().
+ Returns true on success, false if UPAGE is already mapped or
+ if memory allocation fails. */
static bool
install_page (void *upage, void *kpage)
{