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[Update] xv6-la init

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This commit is contained in:
bLueriVerLHR
2023-07-20 18:06:22 +08:00
parent f683f3bed1
commit 29abfe4101
5 changed files with 330 additions and 49 deletions
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7
Makefile
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@@ -1,5 +1,6 @@
default:
@echo "Hello World!"
@echo $(CURDIR)
submodue-update-init:
git submodule update --init
@@ -27,3 +28,9 @@ $(LA_TOOLS): unpk-gcc
# prepare loongarch source code
xv6:
TOOLPREFIX=$(CURDIR)/$(LA) $(MAKE) -C lasoft/xv6-la build
xv6-clean:
$(MAKE) -C lasoft/xv6-la clean

1
lasoft/xv6-la/.gitignore vendored
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@@ -11,7 +11,6 @@ entryother
initcode
initcode.out
kernelmemfs
mkfs
kernel/kernel
user/usys.S
.gdbinit

2
lasoft/xv6-la/Makefile
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@@ -161,6 +161,8 @@ QEMUOPTS += -global virtio-mmio.force-legacy=false
QEMUOPTS += -drive file=fs.img,if=none,format=raw,id=x0
QEMUOPTS += -device virtio-blk-device,drive=x0,bus=virtio-mmio-bus.0
build: $K/kernel fs.img
qemu: $K/kernel fs.img
$(QEMU) $(QEMUOPTS)

68
lasoft/xv6-la/README
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@@ -1,49 +1,21 @@
xv6 is a re-implementation of Dennis Ritchie's and Ken Thompson's Unix
Version 6 (v6). xv6 loosely follows the structure and style of v6,
but is implemented for a modern RISC-V multiprocessor using ANSI C.
# vscode config
ACKNOWLEDGMENTS
xv6 is inspired by John Lions's Commentary on UNIX 6th Edition (Peer
to Peer Communications; ISBN: 1-57398-013-7; 1st edition (June 14,
2000)). See also https://pdos.csail.mit.edu/6.1810/, which provides
pointers to on-line resources for v6.
The following people have made contributions: Russ Cox (context switching,
locking), Cliff Frey (MP), Xiao Yu (MP), Nickolai Zeldovich, and Austin
Clements.
We are also grateful for the bug reports and patches contributed by
Takahiro Aoyagi, Silas Boyd-Wickizer, Anton Burtsev, carlclone, Ian
Chen, Dan Cross, Cody Cutler, Mike CAT, Tej Chajed, Asami Doi,
eyalz800, Nelson Elhage, Saar Ettinger, Alice Ferrazzi, Nathaniel
Filardo, flespark, Peter Froehlich, Yakir Goaron, Shivam Handa, Matt
Harvey, Bryan Henry, jaichenhengjie, Jim Huang, Matúš Jókay, John
Jolly, Alexander Kapshuk, Anders Kaseorg, kehao95, Wolfgang Keller,
Jungwoo Kim, Jonathan Kimmitt, Eddie Kohler, Vadim Kolontsov, Austin
Liew, l0stman, Pavan Maddamsetti, Imbar Marinescu, Yandong Mao, Matan
Shabtay, Hitoshi Mitake, Carmi Merimovich, Mark Morrissey, mtasm, Joel
Nider, Hayato Ohhashi, OptimisticSide, Harry Porter, Greg Price, Jude
Rich, segfault, Ayan Shafqat, Eldar Sehayek, Yongming Shen, Fumiya
Shigemitsu, Cam Tenny, tyfkda, Warren Toomey, Stephen Tu, Rafael Ubal,
Amane Uehara, Pablo Ventura, Xi Wang, WaheedHafez, Keiichi Watanabe,
Nicolas Wolovick, wxdao, Grant Wu, Jindong Zhang, Icenowy Zheng,
ZhUyU1997, and Zou Chang Wei.
The code in the files that constitute xv6 is
Copyright 2006-2022 Frans Kaashoek, Robert Morris, and Russ Cox.
ERROR REPORTS
Please send errors and suggestions to Frans Kaashoek and Robert Morris
(kaashoek,rtm@mit.edu). The main purpose of xv6 is as a teaching
operating system for MIT's 6.1810, so we are more interested in
simplifications and clarifications than new features.
BUILDING AND RUNNING XV6
You will need a RISC-V "newlib" tool chain from
https://github.com/riscv/riscv-gnu-toolchain, and qemu compiled for
riscv64-softmmu. Once they are installed, and in your shell
search path, you can run "make qemu".
``` json
// c_cpp_properties
{
"configurations": [
{
"name": "Linux",
"includePath": [
"${workspaceFolder}/**",
"${workspaceFolder}/../../ext/toolchain-loongarch64-linux-gnu-gcc8-host-x86_64-2022-07-18/lib/gcc/loongarch64-linux-gnu/8.3.0/include"
],
"defines": [],
"compilerPath": "${workspaceFolder}/../../ext/toolchain-loongarch64-linux-gnu-gcc8-host-x86_64-2022-07-18/bin/loongarch64-linux-gnu-gcc",
"cStandard": "c99",
"intelliSenseMode": "linux-gcc-x64"
}
],
"version": 4
}
```

301
lasoft/xv6-la/mkfs/mkfs.c Normal file
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@@ -0,0 +1,301 @@
#include <stdio.h>
#include <unistd.h>
#include <stdlib.h>
#include <string.h>
#include <fcntl.h>
#include <assert.h>
#define stat xv6_stat // avoid clash with host struct stat
#include "kernel/types.h"
#include "kernel/fs.h"
#include "kernel/stat.h"
#include "kernel/param.h"
#ifndef static_assert
#define static_assert(a, b) do { switch (0) case 0: case (a): ; } while (0)
#endif
#define NINODES 200
// Disk layout:
// [ boot block | sb block | log | inode blocks | free bit map | data blocks ]
int nbitmap = FSSIZE/(BSIZE*8) + 1;
int ninodeblocks = NINODES / IPB + 1;
int nlog = LOGSIZE;
int nmeta; // Number of meta blocks (boot, sb, nlog, inode, bitmap)
int nblocks; // Number of data blocks
int fsfd;
struct superblock sb;
char zeroes[BSIZE];
uint freeinode = 1;
uint freeblock;
void balloc(int);
void wsect(uint, void*);
void winode(uint, struct dinode*);
void rinode(uint inum, struct dinode *ip);
void rsect(uint sec, void *buf);
uint ialloc(ushort type);
void iappend(uint inum, void *p, int n);
void die(const char *);
// convert to riscv byte order
ushort
xshort(ushort x)
{
ushort y;
uchar *a = (uchar*)&y;
a[0] = x;
a[1] = x >> 8;
return y;
}
uint
xint(uint x)
{
uint y;
uchar *a = (uchar*)&y;
a[0] = x;
a[1] = x >> 8;
a[2] = x >> 16;
a[3] = x >> 24;
return y;
}
int
main(int argc, char *argv[])
{
int i, cc, fd;
uint rootino, inum, off;
struct dirent de;
char buf[BSIZE];
struct dinode din;
static_assert(sizeof(int) == 4, "Integers must be 4 bytes!");
if(argc < 2){
fprintf(stderr, "Usage: mkfs fs.img files...\n");
exit(1);
}
assert((BSIZE % sizeof(struct dinode)) == 0);
assert((BSIZE % sizeof(struct dirent)) == 0);
fsfd = open(argv[1], O_RDWR|O_CREAT|O_TRUNC, 0666);
if(fsfd < 0)
die(argv[1]);
// 1 fs block = 1 disk sector
nmeta = 2 + nlog + ninodeblocks + nbitmap;
nblocks = FSSIZE - nmeta;
sb.magic = FSMAGIC;
sb.size = xint(FSSIZE);
sb.nblocks = xint(nblocks);
sb.ninodes = xint(NINODES);
sb.nlog = xint(nlog);
sb.logstart = xint(2);
sb.inodestart = xint(2+nlog);
sb.bmapstart = xint(2+nlog+ninodeblocks);
printf("nmeta %d (boot, super, log blocks %u inode blocks %u, bitmap blocks %u) blocks %d total %d\n",
nmeta, nlog, ninodeblocks, nbitmap, nblocks, FSSIZE);
freeblock = nmeta; // the first free block that we can allocate
for(i = 0; i < FSSIZE; i++)
wsect(i, zeroes);
memset(buf, 0, sizeof(buf));
memmove(buf, &sb, sizeof(sb));
wsect(1, buf);
rootino = ialloc(T_DIR);
assert(rootino == ROOTINO);
bzero(&de, sizeof(de));
de.inum = xshort(rootino);
strcpy(de.name, ".");
iappend(rootino, &de, sizeof(de));
bzero(&de, sizeof(de));
de.inum = xshort(rootino);
strcpy(de.name, "..");
iappend(rootino, &de, sizeof(de));
for(i = 2; i < argc; i++){
// get rid of "user/"
char *shortname;
if(strncmp(argv[i], "user/", 5) == 0)
shortname = argv[i] + 5;
else
shortname = argv[i];
assert(index(shortname, '/') == 0);
if((fd = open(argv[i], 0)) < 0)
die(argv[i]);
// Skip leading _ in name when writing to file system.
// The binaries are named _rm, _cat, etc. to keep the
// build operating system from trying to execute them
// in place of system binaries like rm and cat.
if(shortname[0] == '_')
shortname += 1;
inum = ialloc(T_FILE);
bzero(&de, sizeof(de));
de.inum = xshort(inum);
strncpy(de.name, shortname, DIRSIZ);
iappend(rootino, &de, sizeof(de));
while((cc = read(fd, buf, sizeof(buf))) > 0)
iappend(inum, buf, cc);
close(fd);
}
// fix size of root inode dir
rinode(rootino, &din);
off = xint(din.size);
off = ((off/BSIZE) + 1) * BSIZE;
din.size = xint(off);
winode(rootino, &din);
balloc(freeblock);
exit(0);
}
void
wsect(uint sec, void *buf)
{
if(lseek(fsfd, sec * BSIZE, 0) != sec * BSIZE)
die("lseek");
if(write(fsfd, buf, BSIZE) != BSIZE)
die("write");
}
void
winode(uint inum, struct dinode *ip)
{
char buf[BSIZE];
uint bn;
struct dinode *dip;
bn = IBLOCK(inum, sb);
rsect(bn, buf);
dip = ((struct dinode*)buf) + (inum % IPB);
*dip = *ip;
wsect(bn, buf);
}
void
rinode(uint inum, struct dinode *ip)
{
char buf[BSIZE];
uint bn;
struct dinode *dip;
bn = IBLOCK(inum, sb);
rsect(bn, buf);
dip = ((struct dinode*)buf) + (inum % IPB);
*ip = *dip;
}
void
rsect(uint sec, void *buf)
{
if(lseek(fsfd, sec * BSIZE, 0) != sec * BSIZE)
die("lseek");
if(read(fsfd, buf, BSIZE) != BSIZE)
die("read");
}
uint
ialloc(ushort type)
{
uint inum = freeinode++;
struct dinode din;
bzero(&din, sizeof(din));
din.type = xshort(type);
din.nlink = xshort(1);
din.size = xint(0);
winode(inum, &din);
return inum;
}
void
balloc(int used)
{
uchar buf[BSIZE];
int i;
printf("balloc: first %d blocks have been allocated\n", used);
assert(used < BSIZE*8);
bzero(buf, BSIZE);
for(i = 0; i < used; i++){
buf[i/8] = buf[i/8] | (0x1 << (i%8));
}
printf("balloc: write bitmap block at sector %d\n", sb.bmapstart);
wsect(sb.bmapstart, buf);
}
#define min(a, b) ((a) < (b) ? (a) : (b))
void
iappend(uint inum, void *xp, int n)
{
char *p = (char*)xp;
uint fbn, off, n1;
struct dinode din;
char buf[BSIZE];
uint indirect[NINDIRECT];
uint x;
rinode(inum, &din);
off = xint(din.size);
// printf("append inum %d at off %d sz %d\n", inum, off, n);
while(n > 0){
fbn = off / BSIZE;
assert(fbn < MAXFILE);
if(fbn < NDIRECT){
if(xint(din.addrs[fbn]) == 0){
din.addrs[fbn] = xint(freeblock++);
}
x = xint(din.addrs[fbn]);
} else {
if(xint(din.addrs[NDIRECT]) == 0){
din.addrs[NDIRECT] = xint(freeblock++);
}
rsect(xint(din.addrs[NDIRECT]), (char*)indirect);
if(indirect[fbn - NDIRECT] == 0){
indirect[fbn - NDIRECT] = xint(freeblock++);
wsect(xint(din.addrs[NDIRECT]), (char*)indirect);
}
x = xint(indirect[fbn-NDIRECT]);
}
n1 = min(n, (fbn + 1) * BSIZE - off);
rsect(x, buf);
bcopy(p, buf + off - (fbn * BSIZE), n1);
wsect(x, buf);
n -= n1;
off += n1;
p += n1;
}
din.size = xint(off);
winode(inum, &din);
}
void
die(const char *s)
{
perror(s);
exit(1);
}