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https://github.com/edk2-porting/linux-next.git
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96a388de5d
Move the headers to include/asm-x86 and fixup the header install make rules Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Signed-off-by: Ingo Molnar <mingo@elte.hu>
1525 lines
52 KiB
C
1525 lines
52 KiB
C
/*P:100 This is the Launcher code, a simple program which lays out the
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* "physical" memory for the new Guest by mapping the kernel image and the
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* virtual devices, then reads repeatedly from /dev/lguest to run the Guest.
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*
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* The only trick: the Makefile links it at a high address so it will be clear
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* of the guest memory region. It means that each Guest cannot have more than
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* about 2.5G of memory on a normally configured Host. :*/
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#define _LARGEFILE64_SOURCE
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#define _GNU_SOURCE
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#include <stdio.h>
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#include <string.h>
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#include <unistd.h>
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#include <err.h>
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#include <stdint.h>
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#include <stdlib.h>
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#include <elf.h>
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#include <sys/mman.h>
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#include <sys/types.h>
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#include <sys/stat.h>
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#include <sys/wait.h>
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#include <fcntl.h>
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#include <stdbool.h>
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#include <errno.h>
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#include <ctype.h>
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#include <sys/socket.h>
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#include <sys/ioctl.h>
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#include <sys/time.h>
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#include <time.h>
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#include <netinet/in.h>
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#include <net/if.h>
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#include <linux/sockios.h>
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#include <linux/if_tun.h>
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#include <sys/uio.h>
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#include <termios.h>
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#include <getopt.h>
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#include <zlib.h>
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/*L:110 We can ignore the 28 include files we need for this program, but I do
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* want to draw attention to the use of kernel-style types.
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*
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* As Linus said, "C is a Spartan language, and so should your naming be." I
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* like these abbreviations and the header we need uses them, so we define them
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* here.
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*/
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typedef unsigned long long u64;
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typedef uint32_t u32;
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typedef uint16_t u16;
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typedef uint8_t u8;
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#include "../../include/linux/lguest_launcher.h"
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#include "../../include/asm-x86/e820_32.h"
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/*:*/
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#define PAGE_PRESENT 0x7 /* Present, RW, Execute */
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#define NET_PEERNUM 1
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#define BRIDGE_PFX "bridge:"
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#ifndef SIOCBRADDIF
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#define SIOCBRADDIF 0x89a2 /* add interface to bridge */
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#endif
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/*L:120 verbose is both a global flag and a macro. The C preprocessor allows
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* this, and although I wouldn't recommend it, it works quite nicely here. */
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static bool verbose;
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#define verbose(args...) \
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do { if (verbose) printf(args); } while(0)
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/*:*/
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/* The pipe to send commands to the waker process */
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static int waker_fd;
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/* The top of guest physical memory. */
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static u32 top;
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/* This is our list of devices. */
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struct device_list
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{
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/* Summary information about the devices in our list: ready to pass to
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* select() to ask which need servicing.*/
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fd_set infds;
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int max_infd;
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/* The descriptor page for the devices. */
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struct lguest_device_desc *descs;
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/* A single linked list of devices. */
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struct device *dev;
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/* ... And an end pointer so we can easily append new devices */
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struct device **lastdev;
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};
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/* The device structure describes a single device. */
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struct device
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{
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/* The linked-list pointer. */
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struct device *next;
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/* The descriptor for this device, as mapped into the Guest. */
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struct lguest_device_desc *desc;
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/* The memory page(s) of this device, if any. Also mapped in Guest. */
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void *mem;
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/* If handle_input is set, it wants to be called when this file
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* descriptor is ready. */
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int fd;
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bool (*handle_input)(int fd, struct device *me);
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/* If handle_output is set, it wants to be called when the Guest sends
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* DMA to this key. */
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unsigned long watch_key;
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u32 (*handle_output)(int fd, const struct iovec *iov,
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unsigned int num, struct device *me);
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/* Device-specific data. */
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void *priv;
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};
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/*L:130
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* Loading the Kernel.
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*
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* We start with couple of simple helper routines. open_or_die() avoids
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* error-checking code cluttering the callers: */
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static int open_or_die(const char *name, int flags)
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{
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int fd = open(name, flags);
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if (fd < 0)
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err(1, "Failed to open %s", name);
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return fd;
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}
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/* map_zeroed_pages() takes a (page-aligned) address and a number of pages. */
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static void *map_zeroed_pages(unsigned long addr, unsigned int num)
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{
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/* We cache the /dev/zero file-descriptor so we only open it once. */
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static int fd = -1;
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if (fd == -1)
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fd = open_or_die("/dev/zero", O_RDONLY);
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/* We use a private mapping (ie. if we write to the page, it will be
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* copied), and obviously we insist that it be mapped where we ask. */
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if (mmap((void *)addr, getpagesize() * num,
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PROT_READ|PROT_WRITE|PROT_EXEC, MAP_FIXED|MAP_PRIVATE, fd, 0)
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!= (void *)addr)
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err(1, "Mmaping %u pages of /dev/zero @%p", num, (void *)addr);
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/* Returning the address is just a courtesy: can simplify callers. */
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return (void *)addr;
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}
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/* To find out where to start we look for the magic Guest string, which marks
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* the code we see in lguest_asm.S. This is a hack which we are currently
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* plotting to replace with the normal Linux entry point. */
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static unsigned long entry_point(void *start, void *end,
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unsigned long page_offset)
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{
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void *p;
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/* The scan gives us the physical starting address. We want the
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* virtual address in this case, and fortunately, we already figured
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* out the physical-virtual difference and passed it here in
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* "page_offset". */
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for (p = start; p < end; p++)
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if (memcmp(p, "GenuineLguest", strlen("GenuineLguest")) == 0)
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return (long)p + strlen("GenuineLguest") + page_offset;
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err(1, "Is this image a genuine lguest?");
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}
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/* This routine takes an open vmlinux image, which is in ELF, and maps it into
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* the Guest memory. ELF = Embedded Linking Format, which is the format used
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* by all modern binaries on Linux including the kernel.
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*
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* The ELF headers give *two* addresses: a physical address, and a virtual
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* address. The Guest kernel expects to be placed in memory at the physical
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* address, and the page tables set up so it will correspond to that virtual
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* address. We return the difference between the virtual and physical
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* addresses in the "page_offset" pointer.
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*
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* We return the starting address. */
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static unsigned long map_elf(int elf_fd, const Elf32_Ehdr *ehdr,
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unsigned long *page_offset)
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{
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void *addr;
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Elf32_Phdr phdr[ehdr->e_phnum];
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unsigned int i;
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unsigned long start = -1UL, end = 0;
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/* Sanity checks on the main ELF header: an x86 executable with a
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* reasonable number of correctly-sized program headers. */
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if (ehdr->e_type != ET_EXEC
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|| ehdr->e_machine != EM_386
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|| ehdr->e_phentsize != sizeof(Elf32_Phdr)
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|| ehdr->e_phnum < 1 || ehdr->e_phnum > 65536U/sizeof(Elf32_Phdr))
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errx(1, "Malformed elf header");
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/* An ELF executable contains an ELF header and a number of "program"
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* headers which indicate which parts ("segments") of the program to
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* load where. */
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/* We read in all the program headers at once: */
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if (lseek(elf_fd, ehdr->e_phoff, SEEK_SET) < 0)
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err(1, "Seeking to program headers");
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if (read(elf_fd, phdr, sizeof(phdr)) != sizeof(phdr))
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err(1, "Reading program headers");
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/* We don't know page_offset yet. */
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*page_offset = 0;
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/* Try all the headers: there are usually only three. A read-only one,
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* a read-write one, and a "note" section which isn't loadable. */
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for (i = 0; i < ehdr->e_phnum; i++) {
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/* If this isn't a loadable segment, we ignore it */
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if (phdr[i].p_type != PT_LOAD)
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continue;
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verbose("Section %i: size %i addr %p\n",
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i, phdr[i].p_memsz, (void *)phdr[i].p_paddr);
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/* We expect a simple linear address space: every segment must
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* have the same difference between virtual (p_vaddr) and
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* physical (p_paddr) address. */
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if (!*page_offset)
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*page_offset = phdr[i].p_vaddr - phdr[i].p_paddr;
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else if (*page_offset != phdr[i].p_vaddr - phdr[i].p_paddr)
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errx(1, "Page offset of section %i different", i);
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/* We track the first and last address we mapped, so we can
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* tell entry_point() where to scan. */
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if (phdr[i].p_paddr < start)
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start = phdr[i].p_paddr;
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if (phdr[i].p_paddr + phdr[i].p_filesz > end)
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end = phdr[i].p_paddr + phdr[i].p_filesz;
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/* We map this section of the file at its physical address. We
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* map it read & write even if the header says this segment is
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* read-only. The kernel really wants to be writable: it
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* patches its own instructions which would normally be
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* read-only.
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*
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* MAP_PRIVATE means that the page won't be copied until a
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* write is done to it. This allows us to share much of the
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* kernel memory between Guests. */
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addr = mmap((void *)phdr[i].p_paddr,
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phdr[i].p_filesz,
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PROT_READ|PROT_WRITE|PROT_EXEC,
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MAP_FIXED|MAP_PRIVATE,
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elf_fd, phdr[i].p_offset);
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if (addr != (void *)phdr[i].p_paddr)
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err(1, "Mmaping vmlinux seg %i gave %p not %p",
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i, addr, (void *)phdr[i].p_paddr);
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}
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return entry_point((void *)start, (void *)end, *page_offset);
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}
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/*L:170 Prepare to be SHOCKED and AMAZED. And possibly a trifle nauseated.
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*
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* We know that CONFIG_PAGE_OFFSET sets what virtual address the kernel expects
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* to be. We don't know what that option was, but we can figure it out
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* approximately by looking at the addresses in the code. I chose the common
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* case of reading a memory location into the %eax register:
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*
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* movl <some-address>, %eax
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*
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* This gets encoded as five bytes: "0xA1 <4-byte-address>". For example,
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* "0xA1 0x18 0x60 0x47 0xC0" reads the address 0xC0476018 into %eax.
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*
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* In this example can guess that the kernel was compiled with
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* CONFIG_PAGE_OFFSET set to 0xC0000000 (it's always a round number). If the
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* kernel were larger than 16MB, we might see 0xC1 addresses show up, but our
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* kernel isn't that bloated yet.
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*
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* Unfortunately, x86 has variable-length instructions, so finding this
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* particular instruction properly involves writing a disassembler. Instead,
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* we rely on statistics. We look for "0xA1" and tally the different bytes
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* which occur 4 bytes later (the "0xC0" in our example above). When one of
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* those bytes appears three times, we can be reasonably confident that it
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* forms the start of CONFIG_PAGE_OFFSET.
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*
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* This is amazingly reliable. */
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static unsigned long intuit_page_offset(unsigned char *img, unsigned long len)
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{
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unsigned int i, possibilities[256] = { 0 };
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for (i = 0; i + 4 < len; i++) {
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/* mov 0xXXXXXXXX,%eax */
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if (img[i] == 0xA1 && ++possibilities[img[i+4]] > 3)
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return (unsigned long)img[i+4] << 24;
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}
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errx(1, "could not determine page offset");
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}
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/*L:160 Unfortunately the entire ELF image isn't compressed: the segments
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* which need loading are extracted and compressed raw. This denies us the
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* information we need to make a fully-general loader. */
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static unsigned long unpack_bzimage(int fd, unsigned long *page_offset)
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{
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gzFile f;
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int ret, len = 0;
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/* A bzImage always gets loaded at physical address 1M. This is
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* actually configurable as CONFIG_PHYSICAL_START, but as the comment
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* there says, "Don't change this unless you know what you are doing".
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* Indeed. */
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void *img = (void *)0x100000;
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/* gzdopen takes our file descriptor (carefully placed at the start of
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* the GZIP header we found) and returns a gzFile. */
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f = gzdopen(fd, "rb");
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/* We read it into memory in 64k chunks until we hit the end. */
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while ((ret = gzread(f, img + len, 65536)) > 0)
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len += ret;
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if (ret < 0)
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err(1, "reading image from bzImage");
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verbose("Unpacked size %i addr %p\n", len, img);
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/* Without the ELF header, we can't tell virtual-physical gap. This is
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* CONFIG_PAGE_OFFSET, and people do actually change it. Fortunately,
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* I have a clever way of figuring it out from the code itself. */
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*page_offset = intuit_page_offset(img, len);
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return entry_point(img, img + len, *page_offset);
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}
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/*L:150 A bzImage, unlike an ELF file, is not meant to be loaded. You're
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* supposed to jump into it and it will unpack itself. We can't do that
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* because the Guest can't run the unpacking code, and adding features to
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* lguest kills puppies, so we don't want to.
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*
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* The bzImage is formed by putting the decompressing code in front of the
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* compressed kernel code. So we can simple scan through it looking for the
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* first "gzip" header, and start decompressing from there. */
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static unsigned long load_bzimage(int fd, unsigned long *page_offset)
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{
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unsigned char c;
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int state = 0;
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/* GZIP header is 0x1F 0x8B <method> <flags>... <compressed-by>. */
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while (read(fd, &c, 1) == 1) {
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switch (state) {
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case 0:
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if (c == 0x1F)
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state++;
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break;
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case 1:
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if (c == 0x8B)
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state++;
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else
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state = 0;
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break;
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case 2 ... 8:
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state++;
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break;
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case 9:
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/* Seek back to the start of the gzip header. */
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lseek(fd, -10, SEEK_CUR);
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/* One final check: "compressed under UNIX". */
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if (c != 0x03)
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state = -1;
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else
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return unpack_bzimage(fd, page_offset);
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}
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}
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errx(1, "Could not find kernel in bzImage");
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}
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/*L:140 Loading the kernel is easy when it's a "vmlinux", but most kernels
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* come wrapped up in the self-decompressing "bzImage" format. With some funky
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* coding, we can load those, too. */
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static unsigned long load_kernel(int fd, unsigned long *page_offset)
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{
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Elf32_Ehdr hdr;
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/* Read in the first few bytes. */
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if (read(fd, &hdr, sizeof(hdr)) != sizeof(hdr))
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err(1, "Reading kernel");
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/* If it's an ELF file, it starts with "\177ELF" */
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if (memcmp(hdr.e_ident, ELFMAG, SELFMAG) == 0)
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return map_elf(fd, &hdr, page_offset);
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/* Otherwise we assume it's a bzImage, and try to unpack it */
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return load_bzimage(fd, page_offset);
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}
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/* This is a trivial little helper to align pages. Andi Kleen hated it because
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* it calls getpagesize() twice: "it's dumb code."
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*
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* Kernel guys get really het up about optimization, even when it's not
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* necessary. I leave this code as a reaction against that. */
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static inline unsigned long page_align(unsigned long addr)
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{
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/* Add upwards and truncate downwards. */
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return ((addr + getpagesize()-1) & ~(getpagesize()-1));
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}
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/*L:180 An "initial ram disk" is a disk image loaded into memory along with
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* the kernel which the kernel can use to boot from without needing any
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* drivers. Most distributions now use this as standard: the initrd contains
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* the code to load the appropriate driver modules for the current machine.
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*
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* Importantly, James Morris works for RedHat, and Fedora uses initrds for its
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* kernels. He sent me this (and tells me when I break it). */
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static unsigned long load_initrd(const char *name, unsigned long mem)
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{
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int ifd;
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struct stat st;
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unsigned long len;
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void *iaddr;
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ifd = open_or_die(name, O_RDONLY);
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/* fstat() is needed to get the file size. */
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if (fstat(ifd, &st) < 0)
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err(1, "fstat() on initrd '%s'", name);
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/* The length needs to be rounded up to a page size: mmap needs the
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* address to be page aligned. */
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len = page_align(st.st_size);
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/* We map the initrd at the top of memory. */
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iaddr = mmap((void *)mem - len, st.st_size,
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PROT_READ|PROT_EXEC|PROT_WRITE,
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MAP_FIXED|MAP_PRIVATE, ifd, 0);
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if (iaddr != (void *)mem - len)
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err(1, "Mmaping initrd '%s' returned %p not %p",
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name, iaddr, (void *)mem - len);
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/* Once a file is mapped, you can close the file descriptor. It's a
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* little odd, but quite useful. */
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close(ifd);
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verbose("mapped initrd %s size=%lu @ %p\n", name, st.st_size, iaddr);
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/* We return the initrd size. */
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return len;
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}
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/* Once we know how much memory we have, and the address the Guest kernel
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* expects, we can construct simple linear page tables which will get the Guest
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* far enough into the boot to create its own.
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*
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* We lay them out of the way, just below the initrd (which is why we need to
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* know its size). */
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static unsigned long setup_pagetables(unsigned long mem,
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unsigned long initrd_size,
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unsigned long page_offset)
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{
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u32 *pgdir, *linear;
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unsigned int mapped_pages, i, linear_pages;
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unsigned int ptes_per_page = getpagesize()/sizeof(u32);
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/* Ideally we map all physical memory starting at page_offset.
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* However, if page_offset is 0xC0000000 we can only map 1G of physical
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* (0xC0000000 + 1G overflows). */
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if (mem <= -page_offset)
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mapped_pages = mem/getpagesize();
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else
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mapped_pages = -page_offset/getpagesize();
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|
|
/* Each PTE page can map ptes_per_page pages: how many do we need? */
|
|
linear_pages = (mapped_pages + ptes_per_page-1)/ptes_per_page;
|
|
|
|
/* We put the toplevel page directory page at the top of memory. */
|
|
pgdir = (void *)mem - initrd_size - getpagesize();
|
|
|
|
/* Now we use the next linear_pages pages as pte pages */
|
|
linear = (void *)pgdir - linear_pages*getpagesize();
|
|
|
|
/* Linear mapping is easy: put every page's address into the mapping in
|
|
* order. PAGE_PRESENT contains the flags Present, Writable and
|
|
* Executable. */
|
|
for (i = 0; i < mapped_pages; i++)
|
|
linear[i] = ((i * getpagesize()) | PAGE_PRESENT);
|
|
|
|
/* The top level points to the linear page table pages above. The
|
|
* entry representing page_offset points to the first one, and they
|
|
* continue from there. */
|
|
for (i = 0; i < mapped_pages; i += ptes_per_page) {
|
|
pgdir[(i + page_offset/getpagesize())/ptes_per_page]
|
|
= (((u32)linear + i*sizeof(u32)) | PAGE_PRESENT);
|
|
}
|
|
|
|
verbose("Linear mapping of %u pages in %u pte pages at %p\n",
|
|
mapped_pages, linear_pages, linear);
|
|
|
|
/* We return the top level (guest-physical) address: the kernel needs
|
|
* to know where it is. */
|
|
return (unsigned long)pgdir;
|
|
}
|
|
|
|
/* Simple routine to roll all the commandline arguments together with spaces
|
|
* between them. */
|
|
static void concat(char *dst, char *args[])
|
|
{
|
|
unsigned int i, len = 0;
|
|
|
|
for (i = 0; args[i]; i++) {
|
|
strcpy(dst+len, args[i]);
|
|
strcat(dst+len, " ");
|
|
len += strlen(args[i]) + 1;
|
|
}
|
|
/* In case it's empty. */
|
|
dst[len] = '\0';
|
|
}
|
|
|
|
/* This is where we actually tell the kernel to initialize the Guest. We saw
|
|
* the arguments it expects when we looked at initialize() in lguest_user.c:
|
|
* the top physical page to allow, the top level pagetable, the entry point and
|
|
* the page_offset constant for the Guest. */
|
|
static int tell_kernel(u32 pgdir, u32 start, u32 page_offset)
|
|
{
|
|
u32 args[] = { LHREQ_INITIALIZE,
|
|
top/getpagesize(), pgdir, start, page_offset };
|
|
int fd;
|
|
|
|
fd = open_or_die("/dev/lguest", O_RDWR);
|
|
if (write(fd, args, sizeof(args)) < 0)
|
|
err(1, "Writing to /dev/lguest");
|
|
|
|
/* We return the /dev/lguest file descriptor to control this Guest */
|
|
return fd;
|
|
}
|
|
/*:*/
|
|
|
|
static void set_fd(int fd, struct device_list *devices)
|
|
{
|
|
FD_SET(fd, &devices->infds);
|
|
if (fd > devices->max_infd)
|
|
devices->max_infd = fd;
|
|
}
|
|
|
|
/*L:200
|
|
* The Waker.
|
|
*
|
|
* With a console and network devices, we can have lots of input which we need
|
|
* to process. We could try to tell the kernel what file descriptors to watch,
|
|
* but handing a file descriptor mask through to the kernel is fairly icky.
|
|
*
|
|
* Instead, we fork off a process which watches the file descriptors and writes
|
|
* the LHREQ_BREAK command to the /dev/lguest filedescriptor to tell the Host
|
|
* loop to stop running the Guest. This causes it to return from the
|
|
* /dev/lguest read with -EAGAIN, where it will write to /dev/lguest to reset
|
|
* the LHREQ_BREAK and wake us up again.
|
|
*
|
|
* This, of course, is merely a different *kind* of icky.
|
|
*/
|
|
static void wake_parent(int pipefd, int lguest_fd, struct device_list *devices)
|
|
{
|
|
/* Add the pipe from the Launcher to the fdset in the device_list, so
|
|
* we watch it, too. */
|
|
set_fd(pipefd, devices);
|
|
|
|
for (;;) {
|
|
fd_set rfds = devices->infds;
|
|
u32 args[] = { LHREQ_BREAK, 1 };
|
|
|
|
/* Wait until input is ready from one of the devices. */
|
|
select(devices->max_infd+1, &rfds, NULL, NULL, NULL);
|
|
/* Is it a message from the Launcher? */
|
|
if (FD_ISSET(pipefd, &rfds)) {
|
|
int ignorefd;
|
|
/* If read() returns 0, it means the Launcher has
|
|
* exited. We silently follow. */
|
|
if (read(pipefd, &ignorefd, sizeof(ignorefd)) == 0)
|
|
exit(0);
|
|
/* Otherwise it's telling us there's a problem with one
|
|
* of the devices, and we should ignore that file
|
|
* descriptor from now on. */
|
|
FD_CLR(ignorefd, &devices->infds);
|
|
} else /* Send LHREQ_BREAK command. */
|
|
write(lguest_fd, args, sizeof(args));
|
|
}
|
|
}
|
|
|
|
/* This routine just sets up a pipe to the Waker process. */
|
|
static int setup_waker(int lguest_fd, struct device_list *device_list)
|
|
{
|
|
int pipefd[2], child;
|
|
|
|
/* We create a pipe to talk to the waker, and also so it knows when the
|
|
* Launcher dies (and closes pipe). */
|
|
pipe(pipefd);
|
|
child = fork();
|
|
if (child == -1)
|
|
err(1, "forking");
|
|
|
|
if (child == 0) {
|
|
/* Close the "writing" end of our copy of the pipe */
|
|
close(pipefd[1]);
|
|
wake_parent(pipefd[0], lguest_fd, device_list);
|
|
}
|
|
/* Close the reading end of our copy of the pipe. */
|
|
close(pipefd[0]);
|
|
|
|
/* Here is the fd used to talk to the waker. */
|
|
return pipefd[1];
|
|
}
|
|
|
|
/*L:210
|
|
* Device Handling.
|
|
*
|
|
* When the Guest sends DMA to us, it sends us an array of addresses and sizes.
|
|
* We need to make sure it's not trying to reach into the Launcher itself, so
|
|
* we have a convenient routine which check it and exits with an error message
|
|
* if something funny is going on:
|
|
*/
|
|
static void *_check_pointer(unsigned long addr, unsigned int size,
|
|
unsigned int line)
|
|
{
|
|
/* We have to separately check addr and addr+size, because size could
|
|
* be huge and addr + size might wrap around. */
|
|
if (addr >= top || addr + size >= top)
|
|
errx(1, "%s:%i: Invalid address %li", __FILE__, line, addr);
|
|
/* We return a pointer for the caller's convenience, now we know it's
|
|
* safe to use. */
|
|
return (void *)addr;
|
|
}
|
|
/* A macro which transparently hands the line number to the real function. */
|
|
#define check_pointer(addr,size) _check_pointer(addr, size, __LINE__)
|
|
|
|
/* The Guest has given us the address of a "struct lguest_dma". We check it's
|
|
* OK and convert it to an iovec (which is a simple array of ptr/size
|
|
* pairs). */
|
|
static u32 *dma2iov(unsigned long dma, struct iovec iov[], unsigned *num)
|
|
{
|
|
unsigned int i;
|
|
struct lguest_dma *udma;
|
|
|
|
/* First we make sure that the array memory itself is valid. */
|
|
udma = check_pointer(dma, sizeof(*udma));
|
|
/* Now we check each element */
|
|
for (i = 0; i < LGUEST_MAX_DMA_SECTIONS; i++) {
|
|
/* A zero length ends the array. */
|
|
if (!udma->len[i])
|
|
break;
|
|
|
|
iov[i].iov_base = check_pointer(udma->addr[i], udma->len[i]);
|
|
iov[i].iov_len = udma->len[i];
|
|
}
|
|
*num = i;
|
|
|
|
/* We return the pointer to where the caller should write the amount of
|
|
* the buffer used. */
|
|
return &udma->used_len;
|
|
}
|
|
|
|
/* This routine gets a DMA buffer from the Guest for a given key, and converts
|
|
* it to an iovec array. It returns the interrupt the Guest wants when we're
|
|
* finished, and a pointer to the "used_len" field to fill in. */
|
|
static u32 *get_dma_buffer(int fd, void *key,
|
|
struct iovec iov[], unsigned int *num, u32 *irq)
|
|
{
|
|
u32 buf[] = { LHREQ_GETDMA, (u32)key };
|
|
unsigned long udma;
|
|
u32 *res;
|
|
|
|
/* Ask the kernel for a DMA buffer corresponding to this key. */
|
|
udma = write(fd, buf, sizeof(buf));
|
|
/* They haven't registered any, or they're all used? */
|
|
if (udma == (unsigned long)-1)
|
|
return NULL;
|
|
|
|
/* Convert it into our iovec array */
|
|
res = dma2iov(udma, iov, num);
|
|
/* The kernel stashes irq in ->used_len to get it out to us. */
|
|
*irq = *res;
|
|
/* Return a pointer to ((struct lguest_dma *)udma)->used_len. */
|
|
return res;
|
|
}
|
|
|
|
/* This is a convenient routine to send the Guest an interrupt. */
|
|
static void trigger_irq(int fd, u32 irq)
|
|
{
|
|
u32 buf[] = { LHREQ_IRQ, irq };
|
|
if (write(fd, buf, sizeof(buf)) != 0)
|
|
err(1, "Triggering irq %i", irq);
|
|
}
|
|
|
|
/* This simply sets up an iovec array where we can put data to be discarded.
|
|
* This happens when the Guest doesn't want or can't handle the input: we have
|
|
* to get rid of it somewhere, and if we bury it in the ceiling space it will
|
|
* start to smell after a week. */
|
|
static void discard_iovec(struct iovec *iov, unsigned int *num)
|
|
{
|
|
static char discard_buf[1024];
|
|
*num = 1;
|
|
iov->iov_base = discard_buf;
|
|
iov->iov_len = sizeof(discard_buf);
|
|
}
|
|
|
|
/* Here is the input terminal setting we save, and the routine to restore them
|
|
* on exit so the user can see what they type next. */
|
|
static struct termios orig_term;
|
|
static void restore_term(void)
|
|
{
|
|
tcsetattr(STDIN_FILENO, TCSANOW, &orig_term);
|
|
}
|
|
|
|
/* We associate some data with the console for our exit hack. */
|
|
struct console_abort
|
|
{
|
|
/* How many times have they hit ^C? */
|
|
int count;
|
|
/* When did they start? */
|
|
struct timeval start;
|
|
};
|
|
|
|
/* This is the routine which handles console input (ie. stdin). */
|
|
static bool handle_console_input(int fd, struct device *dev)
|
|
{
|
|
u32 irq = 0, *lenp;
|
|
int len;
|
|
unsigned int num;
|
|
struct iovec iov[LGUEST_MAX_DMA_SECTIONS];
|
|
struct console_abort *abort = dev->priv;
|
|
|
|
/* First we get the console buffer from the Guest. The key is dev->mem
|
|
* which was set to 0 in setup_console(). */
|
|
lenp = get_dma_buffer(fd, dev->mem, iov, &num, &irq);
|
|
if (!lenp) {
|
|
/* If it's not ready for input, warn and set up to discard. */
|
|
warn("console: no dma buffer!");
|
|
discard_iovec(iov, &num);
|
|
}
|
|
|
|
/* This is why we convert to iovecs: the readv() call uses them, and so
|
|
* it reads straight into the Guest's buffer. */
|
|
len = readv(dev->fd, iov, num);
|
|
if (len <= 0) {
|
|
/* This implies that the console is closed, is /dev/null, or
|
|
* something went terribly wrong. We still go through the rest
|
|
* of the logic, though, especially the exit handling below. */
|
|
warnx("Failed to get console input, ignoring console.");
|
|
len = 0;
|
|
}
|
|
|
|
/* If we read the data into the Guest, fill in the length and send the
|
|
* interrupt. */
|
|
if (lenp) {
|
|
*lenp = len;
|
|
trigger_irq(fd, irq);
|
|
}
|
|
|
|
/* Three ^C within one second? Exit.
|
|
*
|
|
* This is such a hack, but works surprisingly well. Each ^C has to be
|
|
* in a buffer by itself, so they can't be too fast. But we check that
|
|
* we get three within about a second, so they can't be too slow. */
|
|
if (len == 1 && ((char *)iov[0].iov_base)[0] == 3) {
|
|
if (!abort->count++)
|
|
gettimeofday(&abort->start, NULL);
|
|
else if (abort->count == 3) {
|
|
struct timeval now;
|
|
gettimeofday(&now, NULL);
|
|
if (now.tv_sec <= abort->start.tv_sec+1) {
|
|
u32 args[] = { LHREQ_BREAK, 0 };
|
|
/* Close the fd so Waker will know it has to
|
|
* exit. */
|
|
close(waker_fd);
|
|
/* Just in case waker is blocked in BREAK, send
|
|
* unbreak now. */
|
|
write(fd, args, sizeof(args));
|
|
exit(2);
|
|
}
|
|
abort->count = 0;
|
|
}
|
|
} else
|
|
/* Any other key resets the abort counter. */
|
|
abort->count = 0;
|
|
|
|
/* Now, if we didn't read anything, put the input terminal back and
|
|
* return failure (meaning, don't call us again). */
|
|
if (!len) {
|
|
restore_term();
|
|
return false;
|
|
}
|
|
/* Everything went OK! */
|
|
return true;
|
|
}
|
|
|
|
/* Handling console output is much simpler than input. */
|
|
static u32 handle_console_output(int fd, const struct iovec *iov,
|
|
unsigned num, struct device*dev)
|
|
{
|
|
/* Whatever the Guest sends, write it to standard output. Return the
|
|
* number of bytes written. */
|
|
return writev(STDOUT_FILENO, iov, num);
|
|
}
|
|
|
|
/* Guest->Host network output is also pretty easy. */
|
|
static u32 handle_tun_output(int fd, const struct iovec *iov,
|
|
unsigned num, struct device *dev)
|
|
{
|
|
/* We put a flag in the "priv" pointer of the network device, and set
|
|
* it as soon as we see output. We'll see why in handle_tun_input() */
|
|
*(bool *)dev->priv = true;
|
|
/* Whatever packet the Guest sent us, write it out to the tun
|
|
* device. */
|
|
return writev(dev->fd, iov, num);
|
|
}
|
|
|
|
/* This matches the peer_key() in lguest_net.c. The key for any given slot
|
|
* is the address of the network device's page plus 4 * the slot number. */
|
|
static unsigned long peer_offset(unsigned int peernum)
|
|
{
|
|
return 4 * peernum;
|
|
}
|
|
|
|
/* This is where we handle a packet coming in from the tun device */
|
|
static bool handle_tun_input(int fd, struct device *dev)
|
|
{
|
|
u32 irq = 0, *lenp;
|
|
int len;
|
|
unsigned num;
|
|
struct iovec iov[LGUEST_MAX_DMA_SECTIONS];
|
|
|
|
/* First we get a buffer the Guest has bound to its key. */
|
|
lenp = get_dma_buffer(fd, dev->mem+peer_offset(NET_PEERNUM), iov, &num,
|
|
&irq);
|
|
if (!lenp) {
|
|
/* Now, it's expected that if we try to send a packet too
|
|
* early, the Guest won't be ready yet. This is why we set a
|
|
* flag when the Guest sends its first packet. If it's sent a
|
|
* packet we assume it should be ready to receive them.
|
|
*
|
|
* Actually, this is what the status bits in the descriptor are
|
|
* for: we should *use* them. FIXME! */
|
|
if (*(bool *)dev->priv)
|
|
warn("network: no dma buffer!");
|
|
discard_iovec(iov, &num);
|
|
}
|
|
|
|
/* Read the packet from the device directly into the Guest's buffer. */
|
|
len = readv(dev->fd, iov, num);
|
|
if (len <= 0)
|
|
err(1, "reading network");
|
|
|
|
/* Write the used_len, and trigger the interrupt for the Guest */
|
|
if (lenp) {
|
|
*lenp = len;
|
|
trigger_irq(fd, irq);
|
|
}
|
|
verbose("tun input packet len %i [%02x %02x] (%s)\n", len,
|
|
((u8 *)iov[0].iov_base)[0], ((u8 *)iov[0].iov_base)[1],
|
|
lenp ? "sent" : "discarded");
|
|
/* All good. */
|
|
return true;
|
|
}
|
|
|
|
/* The last device handling routine is block output: the Guest has sent a DMA
|
|
* to the block device. It will have placed the command it wants in the
|
|
* "struct lguest_block_page". */
|
|
static u32 handle_block_output(int fd, const struct iovec *iov,
|
|
unsigned num, struct device *dev)
|
|
{
|
|
struct lguest_block_page *p = dev->mem;
|
|
u32 irq, *lenp;
|
|
unsigned int len, reply_num;
|
|
struct iovec reply[LGUEST_MAX_DMA_SECTIONS];
|
|
off64_t device_len, off = (off64_t)p->sector * 512;
|
|
|
|
/* First we extract the device length from the dev->priv pointer. */
|
|
device_len = *(off64_t *)dev->priv;
|
|
|
|
/* We first check that the read or write is within the length of the
|
|
* block file. */
|
|
if (off >= device_len)
|
|
err(1, "Bad offset %llu vs %llu", off, device_len);
|
|
/* Move to the right location in the block file. This shouldn't fail,
|
|
* but best to check. */
|
|
if (lseek64(dev->fd, off, SEEK_SET) != off)
|
|
err(1, "Bad seek to sector %i", p->sector);
|
|
|
|
verbose("Block: %s at offset %llu\n", p->type ? "WRITE" : "READ", off);
|
|
|
|
/* They were supposed to bind a reply buffer at key equal to the start
|
|
* of the block device memory. We need this to tell them when the
|
|
* request is finished. */
|
|
lenp = get_dma_buffer(fd, dev->mem, reply, &reply_num, &irq);
|
|
if (!lenp)
|
|
err(1, "Block request didn't give us a dma buffer");
|
|
|
|
if (p->type) {
|
|
/* A write request. The DMA they sent contained the data, so
|
|
* write it out. */
|
|
len = writev(dev->fd, iov, num);
|
|
/* Grr... Now we know how long the "struct lguest_dma" they
|
|
* sent was, we make sure they didn't try to write over the end
|
|
* of the block file (possibly extending it). */
|
|
if (off + len > device_len) {
|
|
/* Trim it back to the correct length */
|
|
ftruncate64(dev->fd, device_len);
|
|
/* Die, bad Guest, die. */
|
|
errx(1, "Write past end %llu+%u", off, len);
|
|
}
|
|
/* The reply length is 0: we just send back an empty DMA to
|
|
* interrupt them and tell them the write is finished. */
|
|
*lenp = 0;
|
|
} else {
|
|
/* A read request. They sent an empty DMA to start the
|
|
* request, and we put the read contents into the reply
|
|
* buffer. */
|
|
len = readv(dev->fd, reply, reply_num);
|
|
*lenp = len;
|
|
}
|
|
|
|
/* The result is 1 (done), 2 if there was an error (short read or
|
|
* write). */
|
|
p->result = 1 + (p->bytes != len);
|
|
/* Now tell them we've used their reply buffer. */
|
|
trigger_irq(fd, irq);
|
|
|
|
/* We're supposed to return the number of bytes of the output buffer we
|
|
* used. But the block device uses the "result" field instead, so we
|
|
* don't bother. */
|
|
return 0;
|
|
}
|
|
|
|
/* This is the generic routine we call when the Guest sends some DMA out. */
|
|
static void handle_output(int fd, unsigned long dma, unsigned long key,
|
|
struct device_list *devices)
|
|
{
|
|
struct device *i;
|
|
u32 *lenp;
|
|
struct iovec iov[LGUEST_MAX_DMA_SECTIONS];
|
|
unsigned num = 0;
|
|
|
|
/* Convert the "struct lguest_dma" they're sending to a "struct
|
|
* iovec". */
|
|
lenp = dma2iov(dma, iov, &num);
|
|
|
|
/* Check each device: if they expect output to this key, tell them to
|
|
* handle it. */
|
|
for (i = devices->dev; i; i = i->next) {
|
|
if (i->handle_output && key == i->watch_key) {
|
|
/* We write the result straight into the used_len field
|
|
* for them. */
|
|
*lenp = i->handle_output(fd, iov, num, i);
|
|
return;
|
|
}
|
|
}
|
|
|
|
/* This can happen: the kernel sends any SEND_DMA which doesn't match
|
|
* another Guest to us. It could be that another Guest just left a
|
|
* network, for example. But it's unusual. */
|
|
warnx("Pending dma %p, key %p", (void *)dma, (void *)key);
|
|
}
|
|
|
|
/* This is called when the waker wakes us up: check for incoming file
|
|
* descriptors. */
|
|
static void handle_input(int fd, struct device_list *devices)
|
|
{
|
|
/* select() wants a zeroed timeval to mean "don't wait". */
|
|
struct timeval poll = { .tv_sec = 0, .tv_usec = 0 };
|
|
|
|
for (;;) {
|
|
struct device *i;
|
|
fd_set fds = devices->infds;
|
|
|
|
/* If nothing is ready, we're done. */
|
|
if (select(devices->max_infd+1, &fds, NULL, NULL, &poll) == 0)
|
|
break;
|
|
|
|
/* Otherwise, call the device(s) which have readable
|
|
* file descriptors and a method of handling them. */
|
|
for (i = devices->dev; i; i = i->next) {
|
|
if (i->handle_input && FD_ISSET(i->fd, &fds)) {
|
|
/* If handle_input() returns false, it means we
|
|
* should no longer service it.
|
|
* handle_console_input() does this. */
|
|
if (!i->handle_input(fd, i)) {
|
|
/* Clear it from the set of input file
|
|
* descriptors kept at the head of the
|
|
* device list. */
|
|
FD_CLR(i->fd, &devices->infds);
|
|
/* Tell waker to ignore it too... */
|
|
write(waker_fd, &i->fd, sizeof(i->fd));
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
/*L:190
|
|
* Device Setup
|
|
*
|
|
* All devices need a descriptor so the Guest knows it exists, and a "struct
|
|
* device" so the Launcher can keep track of it. We have common helper
|
|
* routines to allocate them.
|
|
*
|
|
* This routine allocates a new "struct lguest_device_desc" from descriptor
|
|
* table in the devices array just above the Guest's normal memory. */
|
|
static struct lguest_device_desc *
|
|
new_dev_desc(struct lguest_device_desc *descs,
|
|
u16 type, u16 features, u16 num_pages)
|
|
{
|
|
unsigned int i;
|
|
|
|
for (i = 0; i < LGUEST_MAX_DEVICES; i++) {
|
|
if (!descs[i].type) {
|
|
descs[i].type = type;
|
|
descs[i].features = features;
|
|
descs[i].num_pages = num_pages;
|
|
/* If they said the device needs memory, we allocate
|
|
* that now, bumping up the top of Guest memory. */
|
|
if (num_pages) {
|
|
map_zeroed_pages(top, num_pages);
|
|
descs[i].pfn = top/getpagesize();
|
|
top += num_pages*getpagesize();
|
|
}
|
|
return &descs[i];
|
|
}
|
|
}
|
|
errx(1, "too many devices");
|
|
}
|
|
|
|
/* This monster routine does all the creation and setup of a new device,
|
|
* including caling new_dev_desc() to allocate the descriptor and device
|
|
* memory. */
|
|
static struct device *new_device(struct device_list *devices,
|
|
u16 type, u16 num_pages, u16 features,
|
|
int fd,
|
|
bool (*handle_input)(int, struct device *),
|
|
unsigned long watch_off,
|
|
u32 (*handle_output)(int,
|
|
const struct iovec *,
|
|
unsigned,
|
|
struct device *))
|
|
{
|
|
struct device *dev = malloc(sizeof(*dev));
|
|
|
|
/* Append to device list. Prepending to a single-linked list is
|
|
* easier, but the user expects the devices to be arranged on the bus
|
|
* in command-line order. The first network device on the command line
|
|
* is eth0, the first block device /dev/lgba, etc. */
|
|
*devices->lastdev = dev;
|
|
dev->next = NULL;
|
|
devices->lastdev = &dev->next;
|
|
|
|
/* Now we populate the fields one at a time. */
|
|
dev->fd = fd;
|
|
/* If we have an input handler for this file descriptor, then we add it
|
|
* to the device_list's fdset and maxfd. */
|
|
if (handle_input)
|
|
set_fd(dev->fd, devices);
|
|
dev->desc = new_dev_desc(devices->descs, type, features, num_pages);
|
|
dev->mem = (void *)(dev->desc->pfn * getpagesize());
|
|
dev->handle_input = handle_input;
|
|
dev->watch_key = (unsigned long)dev->mem + watch_off;
|
|
dev->handle_output = handle_output;
|
|
return dev;
|
|
}
|
|
|
|
/* Our first setup routine is the console. It's a fairly simple device, but
|
|
* UNIX tty handling makes it uglier than it could be. */
|
|
static void setup_console(struct device_list *devices)
|
|
{
|
|
struct device *dev;
|
|
|
|
/* If we can save the initial standard input settings... */
|
|
if (tcgetattr(STDIN_FILENO, &orig_term) == 0) {
|
|
struct termios term = orig_term;
|
|
/* Then we turn off echo, line buffering and ^C etc. We want a
|
|
* raw input stream to the Guest. */
|
|
term.c_lflag &= ~(ISIG|ICANON|ECHO);
|
|
tcsetattr(STDIN_FILENO, TCSANOW, &term);
|
|
/* If we exit gracefully, the original settings will be
|
|
* restored so the user can see what they're typing. */
|
|
atexit(restore_term);
|
|
}
|
|
|
|
/* We don't currently require any memory for the console, so we ask for
|
|
* 0 pages. */
|
|
dev = new_device(devices, LGUEST_DEVICE_T_CONSOLE, 0, 0,
|
|
STDIN_FILENO, handle_console_input,
|
|
LGUEST_CONSOLE_DMA_KEY, handle_console_output);
|
|
/* We store the console state in dev->priv, and initialize it. */
|
|
dev->priv = malloc(sizeof(struct console_abort));
|
|
((struct console_abort *)dev->priv)->count = 0;
|
|
verbose("device %p: console\n",
|
|
(void *)(dev->desc->pfn * getpagesize()));
|
|
}
|
|
|
|
/* Setting up a block file is also fairly straightforward. */
|
|
static void setup_block_file(const char *filename, struct device_list *devices)
|
|
{
|
|
int fd;
|
|
struct device *dev;
|
|
off64_t *device_len;
|
|
struct lguest_block_page *p;
|
|
|
|
/* We open with O_LARGEFILE because otherwise we get stuck at 2G. We
|
|
* open with O_DIRECT because otherwise our benchmarks go much too
|
|
* fast. */
|
|
fd = open_or_die(filename, O_RDWR|O_LARGEFILE|O_DIRECT);
|
|
|
|
/* We want one page, and have no input handler (the block file never
|
|
* has anything interesting to say to us). Our timing will be quite
|
|
* random, so it should be a reasonable randomness source. */
|
|
dev = new_device(devices, LGUEST_DEVICE_T_BLOCK, 1,
|
|
LGUEST_DEVICE_F_RANDOMNESS,
|
|
fd, NULL, 0, handle_block_output);
|
|
|
|
/* We store the device size in the private area */
|
|
device_len = dev->priv = malloc(sizeof(*device_len));
|
|
/* This is the safe way of establishing the size of our device: it
|
|
* might be a normal file or an actual block device like /dev/hdb. */
|
|
*device_len = lseek64(fd, 0, SEEK_END);
|
|
|
|
/* The device memory is a "struct lguest_block_page". It's zeroed
|
|
* already, we just need to put in the device size. Block devices
|
|
* think in sectors (ie. 512 byte chunks), so we translate here. */
|
|
p = dev->mem;
|
|
p->num_sectors = *device_len/512;
|
|
verbose("device %p: block %i sectors\n",
|
|
(void *)(dev->desc->pfn * getpagesize()), p->num_sectors);
|
|
}
|
|
|
|
/*
|
|
* Network Devices.
|
|
*
|
|
* Setting up network devices is quite a pain, because we have three types.
|
|
* First, we have the inter-Guest network. This is a file which is mapped into
|
|
* the address space of the Guests who are on the network. Because it is a
|
|
* shared mapping, the same page underlies all the devices, and they can send
|
|
* DMA to each other.
|
|
*
|
|
* Remember from our network driver, the Guest is told what slot in the page it
|
|
* is to use. We use exclusive fnctl locks to reserve a slot. If another
|
|
* Guest is using a slot, the lock will fail and we try another. Because fnctl
|
|
* locks are cleaned up automatically when we die, this cleverly means that our
|
|
* reservation on the slot will vanish if we crash. */
|
|
static unsigned int find_slot(int netfd, const char *filename)
|
|
{
|
|
struct flock fl;
|
|
|
|
fl.l_type = F_WRLCK;
|
|
fl.l_whence = SEEK_SET;
|
|
fl.l_len = 1;
|
|
/* Try a 1 byte lock in each possible position number */
|
|
for (fl.l_start = 0;
|
|
fl.l_start < getpagesize()/sizeof(struct lguest_net);
|
|
fl.l_start++) {
|
|
/* If we succeed, return the slot number. */
|
|
if (fcntl(netfd, F_SETLK, &fl) == 0)
|
|
return fl.l_start;
|
|
}
|
|
errx(1, "No free slots in network file %s", filename);
|
|
}
|
|
|
|
/* This function sets up the network file */
|
|
static void setup_net_file(const char *filename,
|
|
struct device_list *devices)
|
|
{
|
|
int netfd;
|
|
struct device *dev;
|
|
|
|
/* We don't use open_or_die() here: for friendliness we create the file
|
|
* if it doesn't already exist. */
|
|
netfd = open(filename, O_RDWR, 0);
|
|
if (netfd < 0) {
|
|
if (errno == ENOENT) {
|
|
netfd = open(filename, O_RDWR|O_CREAT, 0600);
|
|
if (netfd >= 0) {
|
|
/* If we succeeded, initialize the file with a
|
|
* blank page. */
|
|
char page[getpagesize()];
|
|
memset(page, 0, sizeof(page));
|
|
write(netfd, page, sizeof(page));
|
|
}
|
|
}
|
|
if (netfd < 0)
|
|
err(1, "cannot open net file '%s'", filename);
|
|
}
|
|
|
|
/* We need 1 page, and the features indicate the slot to use and that
|
|
* no checksum is needed. We never touch this device again; it's
|
|
* between the Guests on the network, so we don't register input or
|
|
* output handlers. */
|
|
dev = new_device(devices, LGUEST_DEVICE_T_NET, 1,
|
|
find_slot(netfd, filename)|LGUEST_NET_F_NOCSUM,
|
|
-1, NULL, 0, NULL);
|
|
|
|
/* Map the shared file. */
|
|
if (mmap(dev->mem, getpagesize(), PROT_READ|PROT_WRITE,
|
|
MAP_FIXED|MAP_SHARED, netfd, 0) != dev->mem)
|
|
err(1, "could not mmap '%s'", filename);
|
|
verbose("device %p: shared net %s, peer %i\n",
|
|
(void *)(dev->desc->pfn * getpagesize()), filename,
|
|
dev->desc->features & ~LGUEST_NET_F_NOCSUM);
|
|
}
|
|
/*:*/
|
|
|
|
static u32 str2ip(const char *ipaddr)
|
|
{
|
|
unsigned int byte[4];
|
|
|
|
sscanf(ipaddr, "%u.%u.%u.%u", &byte[0], &byte[1], &byte[2], &byte[3]);
|
|
return (byte[0] << 24) | (byte[1] << 16) | (byte[2] << 8) | byte[3];
|
|
}
|
|
|
|
/* This code is "adapted" from libbridge: it attaches the Host end of the
|
|
* network device to the bridge device specified by the command line.
|
|
*
|
|
* This is yet another James Morris contribution (I'm an IP-level guy, so I
|
|
* dislike bridging), and I just try not to break it. */
|
|
static void add_to_bridge(int fd, const char *if_name, const char *br_name)
|
|
{
|
|
int ifidx;
|
|
struct ifreq ifr;
|
|
|
|
if (!*br_name)
|
|
errx(1, "must specify bridge name");
|
|
|
|
ifidx = if_nametoindex(if_name);
|
|
if (!ifidx)
|
|
errx(1, "interface %s does not exist!", if_name);
|
|
|
|
strncpy(ifr.ifr_name, br_name, IFNAMSIZ);
|
|
ifr.ifr_ifindex = ifidx;
|
|
if (ioctl(fd, SIOCBRADDIF, &ifr) < 0)
|
|
err(1, "can't add %s to bridge %s", if_name, br_name);
|
|
}
|
|
|
|
/* This sets up the Host end of the network device with an IP address, brings
|
|
* it up so packets will flow, the copies the MAC address into the hwaddr
|
|
* pointer (in practice, the Host's slot in the network device's memory). */
|
|
static void configure_device(int fd, const char *devname, u32 ipaddr,
|
|
unsigned char hwaddr[6])
|
|
{
|
|
struct ifreq ifr;
|
|
struct sockaddr_in *sin = (struct sockaddr_in *)&ifr.ifr_addr;
|
|
|
|
/* Don't read these incantations. Just cut & paste them like I did! */
|
|
memset(&ifr, 0, sizeof(ifr));
|
|
strcpy(ifr.ifr_name, devname);
|
|
sin->sin_family = AF_INET;
|
|
sin->sin_addr.s_addr = htonl(ipaddr);
|
|
if (ioctl(fd, SIOCSIFADDR, &ifr) != 0)
|
|
err(1, "Setting %s interface address", devname);
|
|
ifr.ifr_flags = IFF_UP;
|
|
if (ioctl(fd, SIOCSIFFLAGS, &ifr) != 0)
|
|
err(1, "Bringing interface %s up", devname);
|
|
|
|
/* SIOC stands for Socket I/O Control. G means Get (vs S for Set
|
|
* above). IF means Interface, and HWADDR is hardware address.
|
|
* Simple! */
|
|
if (ioctl(fd, SIOCGIFHWADDR, &ifr) != 0)
|
|
err(1, "getting hw address for %s", devname);
|
|
memcpy(hwaddr, ifr.ifr_hwaddr.sa_data, 6);
|
|
}
|
|
|
|
/*L:195 The other kind of network is a Host<->Guest network. This can either
|
|
* use briding or routing, but the principle is the same: it uses the "tun"
|
|
* device to inject packets into the Host as if they came in from a normal
|
|
* network card. We just shunt packets between the Guest and the tun
|
|
* device. */
|
|
static void setup_tun_net(const char *arg, struct device_list *devices)
|
|
{
|
|
struct device *dev;
|
|
struct ifreq ifr;
|
|
int netfd, ipfd;
|
|
u32 ip;
|
|
const char *br_name = NULL;
|
|
|
|
/* We open the /dev/net/tun device and tell it we want a tap device. A
|
|
* tap device is like a tun device, only somehow different. To tell
|
|
* the truth, I completely blundered my way through this code, but it
|
|
* works now! */
|
|
netfd = open_or_die("/dev/net/tun", O_RDWR);
|
|
memset(&ifr, 0, sizeof(ifr));
|
|
ifr.ifr_flags = IFF_TAP | IFF_NO_PI;
|
|
strcpy(ifr.ifr_name, "tap%d");
|
|
if (ioctl(netfd, TUNSETIFF, &ifr) != 0)
|
|
err(1, "configuring /dev/net/tun");
|
|
/* We don't need checksums calculated for packets coming in this
|
|
* device: trust us! */
|
|
ioctl(netfd, TUNSETNOCSUM, 1);
|
|
|
|
/* We create the net device with 1 page, using the features field of
|
|
* the descriptor to tell the Guest it is in slot 1 (NET_PEERNUM), and
|
|
* that the device has fairly random timing. We do *not* specify
|
|
* LGUEST_NET_F_NOCSUM: these packets can reach the real world.
|
|
*
|
|
* We will put our MAC address is slot 0 for the Guest to see, so
|
|
* it will send packets to us using the key "peer_offset(0)": */
|
|
dev = new_device(devices, LGUEST_DEVICE_T_NET, 1,
|
|
NET_PEERNUM|LGUEST_DEVICE_F_RANDOMNESS, netfd,
|
|
handle_tun_input, peer_offset(0), handle_tun_output);
|
|
|
|
/* We keep a flag which says whether we've seen packets come out from
|
|
* this network device. */
|
|
dev->priv = malloc(sizeof(bool));
|
|
*(bool *)dev->priv = false;
|
|
|
|
/* We need a socket to perform the magic network ioctls to bring up the
|
|
* tap interface, connect to the bridge etc. Any socket will do! */
|
|
ipfd = socket(PF_INET, SOCK_DGRAM, IPPROTO_IP);
|
|
if (ipfd < 0)
|
|
err(1, "opening IP socket");
|
|
|
|
/* If the command line was --tunnet=bridge:<name> do bridging. */
|
|
if (!strncmp(BRIDGE_PFX, arg, strlen(BRIDGE_PFX))) {
|
|
ip = INADDR_ANY;
|
|
br_name = arg + strlen(BRIDGE_PFX);
|
|
add_to_bridge(ipfd, ifr.ifr_name, br_name);
|
|
} else /* It is an IP address to set up the device with */
|
|
ip = str2ip(arg);
|
|
|
|
/* We are peer 0, ie. first slot, so we hand dev->mem to this routine
|
|
* to write the MAC address at the start of the device memory. */
|
|
configure_device(ipfd, ifr.ifr_name, ip, dev->mem);
|
|
|
|
/* Set "promisc" bit: we want every single packet if we're going to
|
|
* bridge to other machines (and otherwise it doesn't matter). */
|
|
*((u8 *)dev->mem) |= 0x1;
|
|
|
|
close(ipfd);
|
|
|
|
verbose("device %p: tun net %u.%u.%u.%u\n",
|
|
(void *)(dev->desc->pfn * getpagesize()),
|
|
(u8)(ip>>24), (u8)(ip>>16), (u8)(ip>>8), (u8)ip);
|
|
if (br_name)
|
|
verbose("attached to bridge: %s\n", br_name);
|
|
}
|
|
/* That's the end of device setup. */
|
|
|
|
/*L:220 Finally we reach the core of the Launcher, which runs the Guest, serves
|
|
* its input and output, and finally, lays it to rest. */
|
|
static void __attribute__((noreturn))
|
|
run_guest(int lguest_fd, struct device_list *device_list)
|
|
{
|
|
for (;;) {
|
|
u32 args[] = { LHREQ_BREAK, 0 };
|
|
unsigned long arr[2];
|
|
int readval;
|
|
|
|
/* We read from the /dev/lguest device to run the Guest. */
|
|
readval = read(lguest_fd, arr, sizeof(arr));
|
|
|
|
/* The read can only really return sizeof(arr) (the Guest did a
|
|
* SEND_DMA to us), or an error. */
|
|
|
|
/* For a successful read, arr[0] is the address of the "struct
|
|
* lguest_dma", and arr[1] is the key the Guest sent to. */
|
|
if (readval == sizeof(arr)) {
|
|
handle_output(lguest_fd, arr[0], arr[1], device_list);
|
|
continue;
|
|
/* ENOENT means the Guest died. Reading tells us why. */
|
|
} else if (errno == ENOENT) {
|
|
char reason[1024] = { 0 };
|
|
read(lguest_fd, reason, sizeof(reason)-1);
|
|
errx(1, "%s", reason);
|
|
/* EAGAIN means the waker wanted us to look at some input.
|
|
* Anything else means a bug or incompatible change. */
|
|
} else if (errno != EAGAIN)
|
|
err(1, "Running guest failed");
|
|
|
|
/* Service input, then unset the BREAK which releases
|
|
* the Waker. */
|
|
handle_input(lguest_fd, device_list);
|
|
if (write(lguest_fd, args, sizeof(args)) < 0)
|
|
err(1, "Resetting break");
|
|
}
|
|
}
|
|
/*
|
|
* This is the end of the Launcher.
|
|
*
|
|
* But wait! We've seen I/O from the Launcher, and we've seen I/O from the
|
|
* Drivers. If we were to see the Host kernel I/O code, our understanding
|
|
* would be complete... :*/
|
|
|
|
static struct option opts[] = {
|
|
{ "verbose", 0, NULL, 'v' },
|
|
{ "sharenet", 1, NULL, 's' },
|
|
{ "tunnet", 1, NULL, 't' },
|
|
{ "block", 1, NULL, 'b' },
|
|
{ "initrd", 1, NULL, 'i' },
|
|
{ NULL },
|
|
};
|
|
static void usage(void)
|
|
{
|
|
errx(1, "Usage: lguest [--verbose] "
|
|
"[--sharenet=<filename>|--tunnet=(<ipaddr>|bridge:<bridgename>)\n"
|
|
"|--block=<filename>|--initrd=<filename>]...\n"
|
|
"<mem-in-mb> vmlinux [args...]");
|
|
}
|
|
|
|
/*L:100 The Launcher code itself takes us out into userspace, that scary place
|
|
* where pointers run wild and free! Unfortunately, like most userspace
|
|
* programs, it's quite boring (which is why everyone like to hack on the
|
|
* kernel!). Perhaps if you make up an Lguest Drinking Game at this point, it
|
|
* will get you through this section. Or, maybe not.
|
|
*
|
|
* The Launcher binary sits up high, usually starting at address 0xB8000000.
|
|
* Everything below this is the "physical" memory for the Guest. For example,
|
|
* if the Guest were to write a "1" at physical address 0, we would see a "1"
|
|
* in the Launcher at "(int *)0". Guest physical == Launcher virtual.
|
|
*
|
|
* This can be tough to get your head around, but usually it just means that we
|
|
* don't need to do any conversion when the Guest gives us it's "physical"
|
|
* addresses.
|
|
*/
|
|
int main(int argc, char *argv[])
|
|
{
|
|
/* Memory, top-level pagetable, code startpoint, PAGE_OFFSET and size
|
|
* of the (optional) initrd. */
|
|
unsigned long mem = 0, pgdir, start, page_offset, initrd_size = 0;
|
|
/* A temporary and the /dev/lguest file descriptor. */
|
|
int i, c, lguest_fd;
|
|
/* The list of Guest devices, based on command line arguments. */
|
|
struct device_list device_list;
|
|
/* The boot information for the Guest: at guest-physical address 0. */
|
|
void *boot = (void *)0;
|
|
/* If they specify an initrd file to load. */
|
|
const char *initrd_name = NULL;
|
|
|
|
/* First we initialize the device list. Since console and network
|
|
* device receive input from a file descriptor, we keep an fdset
|
|
* (infds) and the maximum fd number (max_infd) with the head of the
|
|
* list. We also keep a pointer to the last device, for easy appending
|
|
* to the list. */
|
|
device_list.max_infd = -1;
|
|
device_list.dev = NULL;
|
|
device_list.lastdev = &device_list.dev;
|
|
FD_ZERO(&device_list.infds);
|
|
|
|
/* We need to know how much memory so we can set up the device
|
|
* descriptor and memory pages for the devices as we parse the command
|
|
* line. So we quickly look through the arguments to find the amount
|
|
* of memory now. */
|
|
for (i = 1; i < argc; i++) {
|
|
if (argv[i][0] != '-') {
|
|
mem = top = atoi(argv[i]) * 1024 * 1024;
|
|
device_list.descs = map_zeroed_pages(top, 1);
|
|
top += getpagesize();
|
|
break;
|
|
}
|
|
}
|
|
|
|
/* The options are fairly straight-forward */
|
|
while ((c = getopt_long(argc, argv, "v", opts, NULL)) != EOF) {
|
|
switch (c) {
|
|
case 'v':
|
|
verbose = true;
|
|
break;
|
|
case 's':
|
|
setup_net_file(optarg, &device_list);
|
|
break;
|
|
case 't':
|
|
setup_tun_net(optarg, &device_list);
|
|
break;
|
|
case 'b':
|
|
setup_block_file(optarg, &device_list);
|
|
break;
|
|
case 'i':
|
|
initrd_name = optarg;
|
|
break;
|
|
default:
|
|
warnx("Unknown argument %s", argv[optind]);
|
|
usage();
|
|
}
|
|
}
|
|
/* After the other arguments we expect memory and kernel image name,
|
|
* followed by command line arguments for the kernel. */
|
|
if (optind + 2 > argc)
|
|
usage();
|
|
|
|
/* We always have a console device */
|
|
setup_console(&device_list);
|
|
|
|
/* We start by mapping anonymous pages over all of guest-physical
|
|
* memory range. This fills it with 0, and ensures that the Guest
|
|
* won't be killed when it tries to access it. */
|
|
map_zeroed_pages(0, mem / getpagesize());
|
|
|
|
/* Now we load the kernel */
|
|
start = load_kernel(open_or_die(argv[optind+1], O_RDONLY),
|
|
&page_offset);
|
|
|
|
/* Map the initrd image if requested (at top of physical memory) */
|
|
if (initrd_name) {
|
|
initrd_size = load_initrd(initrd_name, mem);
|
|
/* These are the location in the Linux boot header where the
|
|
* start and size of the initrd are expected to be found. */
|
|
*(unsigned long *)(boot+0x218) = mem - initrd_size;
|
|
*(unsigned long *)(boot+0x21c) = initrd_size;
|
|
/* The bootloader type 0xFF means "unknown"; that's OK. */
|
|
*(unsigned char *)(boot+0x210) = 0xFF;
|
|
}
|
|
|
|
/* Set up the initial linear pagetables, starting below the initrd. */
|
|
pgdir = setup_pagetables(mem, initrd_size, page_offset);
|
|
|
|
/* The Linux boot header contains an "E820" memory map: ours is a
|
|
* simple, single region. */
|
|
*(char*)(boot+E820NR) = 1;
|
|
*((struct e820entry *)(boot+E820MAP))
|
|
= ((struct e820entry) { 0, mem, E820_RAM });
|
|
/* The boot header contains a command line pointer: we put the command
|
|
* line after the boot header (at address 4096) */
|
|
*(void **)(boot + 0x228) = boot + 4096;
|
|
concat(boot + 4096, argv+optind+2);
|
|
|
|
/* The guest type value of "1" tells the Guest it's under lguest. */
|
|
*(int *)(boot + 0x23c) = 1;
|
|
|
|
/* We tell the kernel to initialize the Guest: this returns the open
|
|
* /dev/lguest file descriptor. */
|
|
lguest_fd = tell_kernel(pgdir, start, page_offset);
|
|
|
|
/* We fork off a child process, which wakes the Launcher whenever one
|
|
* of the input file descriptors needs attention. Otherwise we would
|
|
* run the Guest until it tries to output something. */
|
|
waker_fd = setup_waker(lguest_fd, &device_list);
|
|
|
|
/* Finally, run the Guest. This doesn't return. */
|
|
run_guest(lguest_fd, &device_list);
|
|
}
|
|
/*:*/
|
|
|
|
/*M:999
|
|
* Mastery is done: you now know everything I do.
|
|
*
|
|
* But surely you have seen code, features and bugs in your wanderings which
|
|
* you now yearn to attack? That is the real game, and I look forward to you
|
|
* patching and forking lguest into the Your-Name-Here-visor.
|
|
*
|
|
* Farewell, and good coding!
|
|
* Rusty Russell.
|
|
*/
|