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go / go / 596e6f390b6a9a63a6b05399b4a0ef0dc26e26f7 / . / src / cmd / ld / lib.c
blob: 4a100cac3a1e48a514347a00e662572c8990b24b [file] [log] [blame]
// Derived from Inferno utils/6l/obj.c and utils/6l/span.c
// http://code.google.com/p/inferno-os/source/browse/utils/6l/obj.c
// http://code.google.com/p/inferno-os/source/browse/utils/6l/span.c
//
// Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved.
// Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net)
// Portions Copyright © 1997-1999 Vita Nuova Limited
// Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com)
// Portions Copyright © 2004,2006 Bruce Ellis
// Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net)
// Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others
// Portions Copyright © 2009 The Go Authors. All rights reserved.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
#include "l.h"
#include "lib.h"
#include "../../pkg/runtime/stack.h"
#include <ar.h>
int iconv(Fmt*);
char symname[] = SYMDEF;
char pkgname[] = "__.PKGDEF";
char** libdir;
int nlibdir = 0;
static int maxlibdir = 0;
static int cout = -1;
char* goroot;
char* goarch;
char* goos;
char* theline;
void
Lflag(char *arg)
{
char **p;
if(nlibdir >= maxlibdir) {
if (maxlibdir == 0)
maxlibdir = 8;
else
maxlibdir *= 2;
p = realloc(libdir, maxlibdir * sizeof(*p));
if (p == nil) {
print("too many -L's: %d\n", nlibdir);
usage();
}
libdir = p;
}
libdir[nlibdir++] = arg;
}
void
libinit(void)
{
fmtinstall('i', iconv);
fmtinstall('Y', Yconv);
fmtinstall('Z', Zconv);
mywhatsys(); // get goroot, goarch, goos
if(strcmp(goarch, thestring) != 0)
print("goarch is not known: %s\n", goarch);
// add goroot to the end of the libdir list.
Lflag(smprint("%s/pkg/%s_%s", goroot, goos, goarch));
// Unix doesn't like it when we write to a running (or, sometimes,
// recently run) binary, so remove the output file before writing it.
// On Windows 7, remove() can force the following create() to fail.
#ifndef _WIN32
remove(outfile);
#endif
cout = create(outfile, 1, 0775);
if(cout < 0) {
diag("cannot create %s", outfile);
errorexit();
}
if(INITENTRY == nil) {
INITENTRY = mal(strlen(goarch)+strlen(goos)+10);
sprint(INITENTRY, "_rt0_%s_%s", goarch, goos);
}
lookup(INITENTRY, 0)->type = SXREF;
}
void
errorexit(void)
{
if(nerrors) {
if(cout >= 0)
remove(outfile);
exits("error");
}
exits(0);
}
void
addlib(char *src, char *obj)
{
char name[1024], pname[1024], comp[256], *p;
int i, search;
if(histfrogp <= 0)
return;
search = 0;
if(histfrog[0]->name[1] == '/') {
sprint(name, "");
i = 1;
} else
if(isalpha((uchar)histfrog[0]->name[1]) && histfrog[0]->name[2] == ':') {
strcpy(name, histfrog[0]->name+1);
i = 1;
} else
if(histfrog[0]->name[1] == '.') {
sprint(name, ".");
i = 0;
} else {
sprint(name, "");
i = 0;
search = 1;
}
for(; i<histfrogp; i++) {
snprint(comp, sizeof comp, "%s", histfrog[i]->name+1);
for(;;) {
p = strstr(comp, "$O");
if(p == 0)
break;
memmove(p+1, p+2, strlen(p+2)+1);
p[0] = thechar;
}
for(;;) {
p = strstr(comp, "$M");
if(p == 0)
break;
if(strlen(comp)+strlen(thestring)-2+1 >= sizeof comp) {
diag("library component too long");
return;
}
memmove(p+strlen(thestring), p+2, strlen(p+2)+1);
memmove(p, thestring, strlen(thestring));
}
if(strlen(name) + strlen(comp) + 3 >= sizeof(name)) {
diag("library component too long");
return;
}
if(i > 0 || !search)
strcat(name, "/");
strcat(name, comp);
}
cleanname(name);
// runtime.a -> runtime
p = nil;
if(strlen(name) > 2 && name[strlen(name)-2] == '.') {
p = name+strlen(name)-2;
*p = '\0';
}
// already loaded?
for(i=0; i<libraryp; i++)
if(strcmp(library[i].pkg, name) == 0)
return;
// runtime -> runtime.a for search
if(p != nil)
*p = '.';
if(search) {
// try dot, -L "libdir", and then goroot.
for(i=0; i<nlibdir; i++) {
snprint(pname, sizeof pname, "%s/%s", libdir[i], name);
if(access(pname, AEXIST) >= 0)
break;
}
}else
strcpy(pname, name);
cleanname(pname);
/* runtime.a -> runtime */
if(p != nil)
*p = '\0';
if(debug['v'])
Bprint(&bso, "%5.2f addlib: %s %s pulls in %s\n", cputime(), obj, src, pname);
addlibpath(src, obj, pname, name);
}
/*
* add library to library list.
* srcref: src file referring to package
* objref: object file referring to package
* file: object file, e.g., /home/rsc/go/pkg/container/vector.a
* pkg: package import path, e.g. container/vector
*/
void
addlibpath(char *srcref, char *objref, char *file, char *pkg)
{
int i;
Library *l;
char *p;
for(i=0; i<libraryp; i++)
if(strcmp(file, library[i].file) == 0)
return;
if(debug['v'] > 1)
Bprint(&bso, "%5.2f addlibpath: srcref: %s objref: %s file: %s pkg: %s\n",
cputime(), srcref, objref, file, pkg);
if(libraryp == nlibrary){
nlibrary = 50 + 2*libraryp;
library = realloc(library, sizeof library[0] * nlibrary);
}
l = &library[libraryp++];
p = mal(strlen(objref) + 1);
strcpy(p, objref);
l->objref = p;
p = mal(strlen(srcref) + 1);
strcpy(p, srcref);
l->srcref = p;
p = mal(strlen(file) + 1);
strcpy(p, file);
l->file = p;
p = mal(strlen(pkg) + 1);
strcpy(p, pkg);
l->pkg = p;
}
void
loadinternal(char *name)
{
char pname[1024];
int i, found;
found = 0;
for(i=0; i<nlibdir; i++) {
snprint(pname, sizeof pname, "%s/%s.a", libdir[i], name);
if(debug['v'])
Bprint(&bso, "searching for %s.a in %s\n", name, pname);
if(access(pname, AEXIST) >= 0) {
addlibpath("internal", "internal", pname, name);
found = 1;
break;
}
}
if(!found)
Bprint(&bso, "warning: unable to find %s.a\n", name);
}
void
loadlib(void)
{
int i;
loadinternal("runtime");
if(thechar == '5')
loadinternal("math");
for(i=0; i<libraryp; i++) {
if(debug['v'])
Bprint(&bso, "%5.2f autolib: %s (from %s)\n", cputime(), library[i].file, library[i].objref);
iscgo |= strcmp(library[i].pkg, "runtime/cgo") == 0;
objfile(library[i].file, library[i].pkg);
}
// We've loaded all the code now.
// If there are no dynamic libraries needed, gcc disables dynamic linking.
// Because of this, glibc's dynamic ELF loader occasionally (like in version 2.13)
// assumes that a dynamic binary always refers to at least one dynamic library.
// Rather than be a source of test cases for glibc, disable dynamic linking
// the same way that gcc would.
//
// Exception: on OS X, programs such as Shark only work with dynamic
// binaries, so leave it enabled on OS X (Mach-O) binaries.
if(!havedynamic && HEADTYPE != Hdarwin)
debug['d'] = 1;
importcycles();
}
/*
* look for the next file in an archive.
* adapted from libmach.
*/
int
nextar(Biobuf *bp, int off, struct ar_hdr *a)
{
int r;
int32 arsize;
char *buf;
if (off&01)
off++;
Bseek(bp, off, 0);
buf = Brdline(bp, '\n');
r = Blinelen(bp);
if(buf == nil) {
if(r == 0)
return 0;
return -1;
}
if(r != SAR_HDR)
return -1;
memmove(a, buf, SAR_HDR);
if(strncmp(a->fmag, ARFMAG, sizeof a->fmag))
return -1;
arsize = strtol(a->size, 0, 0);
if (arsize&1)
arsize++;
return arsize + r;
}
void
objfile(char *file, char *pkg)
{
int32 off, l;
Biobuf *f;
char magbuf[SARMAG];
char pname[150];
struct ar_hdr arhdr;
pkg = smprint("%i", pkg);
if(debug['v'])
Bprint(&bso, "%5.2f ldobj: %s (%s)\n", cputime(), file, pkg);
Bflush(&bso);
f = Bopen(file, 0);
if(f == nil) {
diag("cannot open file: %s", file);
errorexit();
}
l = Bread(f, magbuf, SARMAG);
if(l != SARMAG || strncmp(magbuf, ARMAG, SARMAG)){
/* load it as a regular file */
l = Bseek(f, 0L, 2);
Bseek(f, 0L, 0);
ldobj(f, pkg, l, file, FileObj);
Bterm(f);
free(pkg);
return;
}
/* skip over __.SYMDEF */
off = Boffset(f);
if((l = nextar(f, off, &arhdr)) <= 0) {
diag("%s: short read on archive file symbol header", file);
goto out;
}
if(strncmp(arhdr.name, symname, strlen(symname))) {
diag("%s: first entry not symbol header", file);
goto out;
}
off += l;
/* skip over (or process) __.PKGDEF */
if((l = nextar(f, off, &arhdr)) <= 0) {
diag("%s: short read on archive file symbol header", file);
goto out;
}
if(strncmp(arhdr.name, pkgname, strlen(pkgname))) {
diag("%s: second entry not package header", file);
goto out;
}
off += l;
if(debug['u'])
ldpkg(f, pkg, atolwhex(arhdr.size), file, Pkgdef);
/*
* load all the object files from the archive now.
* this gives us sequential file access and keeps us
* from needing to come back later to pick up more
* objects. it breaks the usual C archive model, but
* this is Go, not C. the common case in Go is that
* we need to load all the objects, and then we throw away
* the individual symbols that are unused.
*
* loading every object will also make it possible to
* load foreign objects not referenced by __.SYMDEF.
*/
for(;;) {
l = nextar(f, off, &arhdr);
if(l == 0)
break;
if(l < 0) {
diag("%s: malformed archive", file);
goto out;
}
off += l;
l = SARNAME;
while(l > 0 && arhdr.name[l-1] == ' ')
l--;
snprint(pname, sizeof pname, "%s(%.*s)", file, utfnlen(arhdr.name, l), arhdr.name);
l = atolwhex(arhdr.size);
ldobj(f, pkg, l, pname, ArchiveObj);
}
out:
Bterm(f);
free(pkg);
}
void
ldobj(Biobuf *f, char *pkg, int64 len, char *pn, int whence)
{
char *line;
int n, c1, c2, c3, c4;
uint32 magic;
vlong import0, import1, eof;
char *t;
eof = Boffset(f) + len;
pn = strdup(pn);
c1 = Bgetc(f);
c2 = Bgetc(f);
c3 = Bgetc(f);
c4 = Bgetc(f);
Bungetc(f);
Bungetc(f);
Bungetc(f);
Bungetc(f);
magic = c1<<24 | c2<<16 | c3<<8 | c4;
if(magic == 0x7f454c46) { // \x7F E L F
ldelf(f, pkg, len, pn);
free(pn);
return;
}
if((magic&~1) == 0xfeedface || (magic&~0x01000000) == 0xcefaedfe) {
ldmacho(f, pkg, len, pn);
free(pn);
return;
}
if(c1 == 0x4c && c2 == 0x01 || c1 == 0x64 && c2 == 0x86) {
ldpe(f, pkg, len, pn);
free(pn);
return;
}
/* check the header */
line = Brdline(f, '\n');
if(line == nil) {
if(Blinelen(f) > 0) {
diag("%s: not an object file", pn);
return;
}
goto eof;
}
n = Blinelen(f) - 1;
line[n] = '\0';
if(strncmp(line, "go object ", 10) != 0) {
if(strlen(pn) > 3 && strcmp(pn+strlen(pn)-3, ".go") == 0) {
print("%cl: input %s is not .%c file (use %cg to compile .go files)\n", thechar, pn, thechar, thechar);
errorexit();
}
if(strcmp(line, thestring) == 0) {
// old header format: just $GOOS
diag("%s: stale object file", pn);
return;
}
diag("%s: not an object file", pn);
free(pn);
return;
}
// First, check that the basic goos, string, and version match.
t = smprint("%s %s %s ", goos, thestring, getgoversion());
line[n] = ' ';
if(strncmp(line+10, t, strlen(t)) != 0 && !debug['f']) {
line[n] = '\0';
diag("%s: object is [%s] expected [%s]", pn, line+10, t);
free(t);
free(pn);
return;
}
// Second, check that longer lines match each other exactly,
// so that the Go compiler and write additional information
// that must be the same from run to run.
line[n] = '\0';
if(n-10 > strlen(t)) {
if(theline == nil)
theline = strdup(line+10);
else if(strcmp(theline, line+10) != 0) {
line[n] = '\0';
diag("%s: object is [%s] expected [%s]", pn, line+10, theline);
free(t);
free(pn);
return;
}
}
free(t);
line[n] = '\n';
/* skip over exports and other info -- ends with \n!\n */
import0 = Boffset(f);
c1 = '\n'; // the last line ended in \n
c2 = Bgetc(f);
c3 = Bgetc(f);
while(c1 != '\n' || c2 != '!' || c3 != '\n') {
c1 = c2;
c2 = c3;
c3 = Bgetc(f);
if(c3 == Beof)
goto eof;
}
import1 = Boffset(f);
Bseek(f, import0, 0);
ldpkg(f, pkg, import1 - import0 - 2, pn, whence); // -2 for !\n
Bseek(f, import1, 0);
ldobj1(f, pkg, eof - Boffset(f), pn);
free(pn);
return;
eof:
diag("truncated object file: %s", pn);
free(pn);
}
static Sym*
_lookup(char *symb, int v, int creat)
{
Sym *s;
char *p;
int32 h;
int l, c;
h = v;
for(p=symb; c = *p; p++)
h = h+h+h + c;
l = (p - symb) + 1;
// not if(h < 0) h = ~h, because gcc 4.3 -O2 miscompiles it.
h &= 0xffffff;
h %= NHASH;
for(s = hash[h]; s != S; s = s->hash)
if(memcmp(s->name, symb, l) == 0)
return s;
if(!creat)
return nil;
s = mal(sizeof(*s));
if(debug['v'] > 1)
Bprint(&bso, "lookup %s\n", symb);
s->dynid = -1;
s->plt = -1;
s->got = -1;
s->name = mal(l + 1);
memmove(s->name, symb, l);
s->hash = hash[h];
s->type = 0;
s->version = v;
s->value = 0;
s->sig = 0;
s->size = 0;
hash[h] = s;
nsymbol++;
s->allsym = allsym;
allsym = s;
return s;
}
Sym*
lookup(char *name, int v)
{
return _lookup(name, v, 1);
}
// read-only lookup
Sym*
rlookup(char *name, int v)
{
return _lookup(name, v, 0);
}
void
copyhistfrog(char *buf, int nbuf)
{
char *p, *ep;
int i;
p = buf;
ep = buf + nbuf;
for(i=0; i<histfrogp; i++) {
p = seprint(p, ep, "%s", histfrog[i]->name+1);
if(i+1<histfrogp && (p == buf || p[-1] != '/'))
p = seprint(p, ep, "/");
}
}
void
addhist(int32 line, int type)
{
Auto *u;
Sym *s;
int i, j, k;
u = mal(sizeof(Auto));
s = mal(sizeof(Sym));
s->name = mal(2*(histfrogp+1) + 1);
u->asym = s;
u->type = type;
u->aoffset = line;
u->link = curhist;
curhist = u;
s->name[0] = 0;
j = 1;
for(i=0; i<histfrogp; i++) {
k = histfrog[i]->value;
s->name[j+0] = k>>8;
s->name[j+1] = k;
j += 2;
}
s->name[j] = 0;
s->name[j+1] = 0;
}
void
histtoauto(void)
{
Auto *l;
while(l = curhist) {
curhist = l->link;
l->link = curauto;
curauto = l;
}
}
void
collapsefrog(Sym *s)
{
int i;
/*
* bad encoding of path components only allows
* MAXHIST components. if there is an overflow,
* first try to collapse xxx/..
*/
for(i=1; i<histfrogp; i++)
if(strcmp(histfrog[i]->name+1, "..") == 0) {
memmove(histfrog+i-1, histfrog+i+1,
(histfrogp-i-1)*sizeof(histfrog[0]));
histfrogp--;
goto out;
}
/*
* next try to collapse .
*/
for(i=0; i<histfrogp; i++)
if(strcmp(histfrog[i]->name+1, ".") == 0) {
memmove(histfrog+i, histfrog+i+1,
(histfrogp-i-1)*sizeof(histfrog[0]));
goto out;
}
/*
* last chance, just truncate from front
*/
memmove(histfrog+0, histfrog+1,
(histfrogp-1)*sizeof(histfrog[0]));
out:
histfrog[histfrogp-1] = s;
}
void
nuxiinit(void)
{
int i, c;
for(i=0; i<4; i++) {
c = find1(0x04030201L, i+1);
if(i < 2)
inuxi2[i] = c;
if(i < 1)
inuxi1[i] = c;
inuxi4[i] = c;
if(c == i) {
inuxi8[i] = c;
inuxi8[i+4] = c+4;
} else {
inuxi8[i] = c+4;
inuxi8[i+4] = c;
}
fnuxi4[i] = c;
fnuxi8[i] = c;
fnuxi8[i+4] = c+4;
}
if(debug['v']) {
Bprint(&bso, "inuxi = ");
for(i=0; i<1; i++)
Bprint(&bso, "%d", inuxi1[i]);
Bprint(&bso, " ");
for(i=0; i<2; i++)
Bprint(&bso, "%d", inuxi2[i]);
Bprint(&bso, " ");
for(i=0; i<4; i++)
Bprint(&bso, "%d", inuxi4[i]);
Bprint(&bso, " ");
for(i=0; i<8; i++)
Bprint(&bso, "%d", inuxi8[i]);
Bprint(&bso, "\nfnuxi = ");
for(i=0; i<4; i++)
Bprint(&bso, "%d", fnuxi4[i]);
Bprint(&bso, " ");
for(i=0; i<8; i++)
Bprint(&bso, "%d", fnuxi8[i]);
Bprint(&bso, "\n");
}
Bflush(&bso);
}
int
find1(int32 l, int c)
{
char *p;
int i;
p = (char*)&l;
for(i=0; i<4; i++)
if(*p++ == c)
return i;
return 0;
}
int
find2(int32 l, int c)
{
union {
int32 l;
short p[2];
} u;
short *p;
int i;
u.l = l;
p = u.p;
for(i=0; i<4; i+=2) {
if(((*p >> 8) & 0xff) == c)
return i;
if((*p++ & 0xff) == c)
return i+1;
}
return 0;
}
int32
ieeedtof(Ieee *e)
{
int exp;
int32 v;
if(e->h == 0)
return 0;
exp = (e->h>>20) & ((1L<<11)-1L);
exp -= (1L<<10) - 2L;
v = (e->h & 0xfffffL) << 3;
v |= (e->l >> 29) & 0x7L;
if((e->l >> 28) & 1) {
v++;
if(v & 0x800000L) {
v = (v & 0x7fffffL) >> 1;
exp++;
}
}
if(-148 <= exp && exp <= -126) {
v |= 1<<23;
v >>= -125 - exp;
exp = -126;
}
else if(exp < -148 || exp >= 130)
diag("double fp to single fp overflow: %.17g", ieeedtod(e));
v |= ((exp + 126) & 0xffL) << 23;
v |= e->h & 0x80000000L;
return v;
}
double
ieeedtod(Ieee *ieeep)
{
Ieee e;
double fr;
int exp;
if(ieeep->h & (1L<<31)) {
e.h = ieeep->h & ~(1L<<31);
e.l = ieeep->l;
return -ieeedtod(&e);
}
if(ieeep->l == 0 && ieeep->h == 0)
return 0;
exp = (ieeep->h>>20) & ((1L<<11)-1L);
exp -= (1L<<10) - 2L;
fr = ieeep->l & ((1L<<16)-1L);
fr /= 1L<<16;
fr += (ieeep->l>>16) & ((1L<<16)-1L);
fr /= 1L<<16;
if(exp == -(1L<<10) - 2L) {
fr += (ieeep->h & (1L<<20)-1L);
exp++;
} else
fr += (ieeep->h & (1L<<20)-1L) | (1L<<20);
fr /= 1L<<21;
return ldexp(fr, exp);
}
void
zerosig(char *sp)
{
Sym *s;
s = lookup(sp, 0);
s->sig = 0;
}
int32
Bget4(Biobuf *f)
{
uchar p[4];
if(Bread(f, p, 4) != 4)
return 0;
return p[0] | (p[1] << 8) | (p[2] << 16) | (p[3] << 24);
}
void
mywhatsys(void)
{
goroot = getgoroot();
goos = getgoos();
goarch = thestring; // ignore $GOARCH - we know who we are
}
int
pathchar(void)
{
return '/';
}
static uchar* hunk;
static uint32 nhunk;
#define NHUNK (10UL<<20)
void*
mal(uint32 n)
{
void *v;
n = (n+7)&~7;
if(n > NHUNK) {
v = malloc(n);
if(v == nil) {
diag("out of memory");
errorexit();
}
memset(v, 0, n);
return v;
}
if(n > nhunk) {
hunk = malloc(NHUNK);
if(hunk == nil) {
diag("out of memory");
errorexit();
}
nhunk = NHUNK;
}
v = hunk;
nhunk -= n;
hunk += n;
memset(v, 0, n);
return v;
}
void
unmal(void *v, uint32 n)
{
n = (n+7)&~7;
if(hunk - n == v) {
hunk -= n;
nhunk += n;
}
}
// Copied from ../gc/subr.c:/^pathtoprefix; must stay in sync.
/*
* Convert raw string to the prefix that will be used in the symbol table.
* Invalid bytes turn into %xx. Right now the only bytes that need
* escaping are %, ., and ", but we escape all control characters too.
*
* Must be same as ../gc/subr.c:/^pathtoprefix.
*/
static char*
pathtoprefix(char *s)
{
static char hex[] = "0123456789abcdef";
char *p, *r, *w, *l;
int n;
// find first character past the last slash, if any.
l = s;
for(r=s; *r; r++)
if(*r == '/')
l = r+1;
// check for chars that need escaping
n = 0;
for(r=s; *r; r++)
if(*r <= ' ' || (*r == '.' && r >= l) || *r == '%' || *r == '"' || *r >= 0x7f)
n++;
// quick exit
if(n == 0)
return s;
// escape
p = mal((r-s)+1+2*n);
for(r=s, w=p; *r; r++) {
if(*r <= ' ' || (*r == '.' && r >= l) || *r == '%' || *r == '"' || *r >= 0x7f) {
*w++ = '%';
*w++ = hex[(*r>>4)&0xF];
*w++ = hex[*r&0xF];
} else
*w++ = *r;
}
*w = '\0';
return p;
}
int
iconv(Fmt *fp)
{
char *p;
p = va_arg(fp->args, char*);
if(p == nil) {
fmtstrcpy(fp, "<nil>");
return 0;
}
p = pathtoprefix(p);
fmtstrcpy(fp, p);
return 0;
}
void
mangle(char *file)
{
fprint(2, "%s: mangled input file\n", file);
errorexit();
}
Section*
addsection(Segment *seg, char *name, int rwx)
{
Section **l;
Section *sect;
for(l=&seg->sect; *l; l=&(*l)->next)
;
sect = mal(sizeof *sect);
sect->rwx = rwx;
sect->name = name;
sect->seg = seg;
*l = sect;
return sect;
}
void
pclntab(void)
{
vlong oldpc;
Prog *p;
int32 oldlc, v, s;
Sym *sym;
uchar *bp;
sym = lookup("pclntab", 0);
sym->type = SPCLNTAB;
sym->reachable = 1;
if(debug['s'])
return;
oldpc = INITTEXT;
oldlc = 0;
for(cursym = textp; cursym != nil; cursym = cursym->next) {
for(p = cursym->text; p != P; p = p->link) {
if(p->line == oldlc || p->as == ATEXT || p->as == ANOP) {
if(debug['O'])
Bprint(&bso, "%6llux %P\n",
(vlong)p->pc, p);
continue;
}
if(debug['O'])
Bprint(&bso, "\t\t%6d", lcsize);
v = (p->pc - oldpc) / MINLC;
while(v) {
s = 127;
if(v < 127)
s = v;
symgrow(sym, lcsize+1);
bp = sym->p + lcsize;
*bp = s+128; /* 129-255 +pc */
if(debug['O'])
Bprint(&bso, " pc+%d*%d(%d)", s, MINLC, s+128);
v -= s;
lcsize++;
}
s = p->line - oldlc;
oldlc = p->line;
oldpc = p->pc + MINLC;
if(s > 64 || s < -64) {
symgrow(sym, lcsize+5);
bp = sym->p + lcsize;
*bp++ = 0; /* 0 vv +lc */
*bp++ = s>>24;
*bp++ = s>>16;
*bp++ = s>>8;
*bp = s;
if(debug['O']) {
if(s > 0)
Bprint(&bso, " lc+%d(%d,%d)\n",
s, 0, s);
else
Bprint(&bso, " lc%d(%d,%d)\n",
s, 0, s);
Bprint(&bso, "%6llux %P\n",
(vlong)p->pc, p);
}
lcsize += 5;
continue;
}
symgrow(sym, lcsize+1);
bp = sym->p + lcsize;
if(s > 0) {
*bp = 0+s; /* 1-64 +lc */
if(debug['O']) {
Bprint(&bso, " lc+%d(%d)\n", s, 0+s);
Bprint(&bso, "%6llux %P\n",
(vlong)p->pc, p);
}
} else {
*bp = 64-s; /* 65-128 -lc */
if(debug['O']) {
Bprint(&bso, " lc%d(%d)\n", s, 64-s);
Bprint(&bso, "%6llux %P\n",
(vlong)p->pc, p);
}
}
lcsize++;
}
}
if(lcsize & 1) {
symgrow(sym, lcsize+1);
sym->p[lcsize] = 129;
lcsize++;
}
sym->size = lcsize;
lcsize = 0;
if(debug['v'] || debug['O'])
Bprint(&bso, "lcsize = %d\n", lcsize);
Bflush(&bso);
}
#define LOG 5
void
mkfwd(void)
{
Prog *p;
int i;
int32 dwn[LOG], cnt[LOG];
Prog *lst[LOG];
for(i=0; i<LOG; i++) {
if(i == 0)
cnt[i] = 1;
else
cnt[i] = LOG * cnt[i-1];
dwn[i] = 1;
lst[i] = P;
}
i = 0;
for(cursym = textp; cursym != nil; cursym = cursym->next) {
for(p = cursym->text; p != P; p = p->link) {
if(p->link == P) {
if(cursym->next)
p->forwd = cursym->next->text;
break;
}
i--;
if(i < 0)
i = LOG-1;
p->forwd = P;
dwn[i]--;
if(dwn[i] <= 0) {
dwn[i] = cnt[i];
if(lst[i] != P)
lst[i]->forwd = p;
lst[i] = p;
}
}
}
}
uint16
le16(uchar *b)
{
return b[0] | b[1]<<8;
}
uint32
le32(uchar *b)
{
return b[0] | b[1]<<8 | b[2]<<16 | b[3]<<24;
}
uint64
le64(uchar *b)
{
return le32(b) | (uint64)le32(b+4)<<32;
}
uint16
be16(uchar *b)
{
return b[0]<<8 | b[1];
}
uint32
be32(uchar *b)
{
return b[0]<<24 | b[1]<<16 | b[2]<<8 | b[3];
}
uint64
be64(uchar *b)
{
return (uvlong)be32(b)<<32 | be32(b+4);
}
Endian be = { be16, be32, be64 };
Endian le = { le16, le32, le64 };
typedef struct Chain Chain;
struct Chain
{
Sym *sym;
Chain *up;
int limit; // limit on entry to sym
};
static int stkcheck(Chain*, int);
static void stkprint(Chain*, int);
static void stkbroke(Chain*, int);
static Sym *morestack;
static Sym *newstack;
enum
{
HasLinkRegister = (thechar == '5'),
CallSize = (!HasLinkRegister)*PtrSize, // bytes of stack required for a call
};
void
dostkcheck(void)
{
Chain ch;
Sym *s;
morestack = lookup("runtime.morestack", 0);
newstack = lookup("runtime.newstack", 0);
// First the nosplits on their own.
for(s = textp; s != nil; s = s->next) {
if(s->text == nil || s->text->link == nil || (s->text->textflag & NOSPLIT) == 0)
continue;
cursym = s;
ch.up = nil;
ch.sym = s;
ch.limit = StackLimit - CallSize;
stkcheck(&ch, 0);
s->stkcheck = 1;
}
// Check calling contexts.
// Some nosplits get called a little further down,
// like newproc and deferproc. We could hard-code
// that knowledge but it's more robust to look at
// the actual call sites.
for(s = textp; s != nil; s = s->next) {
if(s->text == nil || s->text->link == nil || (s->text->textflag & NOSPLIT) != 0)
continue;
cursym = s;
ch.up = nil;
ch.sym = s;
ch.limit = StackLimit - CallSize;
stkcheck(&ch, 0);
}
}
static int
stkcheck(Chain *up, int depth)
{
Chain ch, ch1;
Prog *p;
Sym *s;
int limit, prolog;
limit = up->limit;
s = up->sym;
p = s->text;
// Small optimization: don't repeat work at top.
if(s->stkcheck && limit == StackLimit-CallSize)
return 0;
if(depth > 100) {
diag("nosplit stack check too deep");
stkbroke(up, 0);
return -1;
}
if(p == nil || p->link == nil) {
// external function.
// should never be called directly.
// only diagnose the direct caller.
if(depth == 1)
diag("call to external function %s", s->name);
return -1;
}
if(limit < 0) {
stkbroke(up, limit);
return -1;
}
// morestack looks like it calls functions,
// but it switches the stack pointer first.
if(s == morestack)
return 0;
ch.up = up;
prolog = (s->text->textflag & NOSPLIT) == 0;
for(p = s->text; p != P; p = p->link) {
limit -= p->spadj;
if(prolog && p->spadj != 0) {
// The first stack adjustment in a function with a
// split-checking prologue marks the end of the
// prologue. Assuming the split check is correct,
// after the adjustment there should still be at least
// StackLimit bytes available below the stack pointer.
// If this is not the top call in the chain, no need
// to duplicate effort, so just stop.
if(depth > 0)
return 0;
prolog = 0;
limit = StackLimit;
}
if(limit < 0) {
stkbroke(up, limit);
return -1;
}
if(iscall(p)) {
limit -= CallSize;
ch.limit = limit;
if(p->to.type == D_BRANCH) {
// Direct call.
ch.sym = p->to.sym;
if(stkcheck(&ch, depth+1) < 0)
return -1;
} else {
// Indirect call. Assume it is a splitting function,
// so we have to make sure it can call morestack.
limit -= CallSize;
ch.sym = nil;
ch1.limit = limit;
ch1.up = &ch;
ch1.sym = morestack;
if(stkcheck(&ch1, depth+2) < 0)
return -1;
limit += CallSize;
}
limit += CallSize;
}
}
return 0;
}
static void
stkbroke(Chain *ch, int limit)
{
diag("nosplit stack overflow");
stkprint(ch, limit);
}
static void
stkprint(Chain *ch, int limit)
{
char *name;
if(ch->sym)
name = ch->sym->name;
else
name = "function pointer";
if(ch->up == nil) {
// top of chain. ch->sym != nil.
if(ch->sym->text->textflag & NOSPLIT)
print("\t%d\tassumed on entry to %s\n", ch->limit, name);
else
print("\t%d\tguaranteed after split check in %s\n", ch->limit, name);
} else {
stkprint(ch->up, ch->limit + (!HasLinkRegister)*PtrSize);
if(!HasLinkRegister)
print("\t%d\ton entry to %s\n", ch->limit, name);
}
if(ch->limit != limit)
print("\t%d\tafter %s uses %d\n", limit, name, ch->limit - limit);
}
int
headtype(char *name)
{
int i;
for(i=0; headers[i].name; i++)
if(strcmp(name, headers[i].name) == 0) {
headstring = headers[i].name;
return headers[i].val;
}
fprint(2, "unknown header type -H %s\n", name);
errorexit();
return -1; // not reached
}
void
undef(void)
{
Sym *s;
for(s = allsym; s != S; s = s->allsym)
if(s->type == SXREF)
diag("%s(%d): not defined", s->name, s->version);
}
int
Yconv(Fmt *fp)
{
Sym *s;
Fmt fmt;
int i;
char *str;
s = va_arg(fp->args, Sym*);
if (s == S) {
fmtprint(fp, "<nil>");
} else {
fmtstrinit(&fmt);
fmtprint(&fmt, "%s @0x%08llx [%lld]", s->name, (vlong)s->value, (vlong)s->size);
for (i = 0; i < s->size; i++) {
if (!(i%8)) fmtprint(&fmt, "\n\t0x%04x ", i);
fmtprint(&fmt, "%02x ", s->p[i]);
}
fmtprint(&fmt, "\n");
for (i = 0; i < s->nr; i++) {
fmtprint(&fmt, "\t0x%04x[%x] %d %s[%llx]\n",
s->r[i].off,
s->r[i].siz,
s->r[i].type,
s->r[i].sym->name,
(vlong)s->r[i].add);
}
str = fmtstrflush(&fmt);
fmtstrcpy(fp, str);
free(str);
}
return 0;
}
vlong coutpos;
void
cflush(void)
{
int n;
if(cbpmax < cbp)
cbpmax = cbp;
n = cbpmax - buf.cbuf;
if(n) {
if(write(cout, buf.cbuf, n) != n) {
diag("write error: %r");
errorexit();
}
coutpos += n;
}
cbp = buf.cbuf;
cbc = sizeof(buf.cbuf);
cbpmax = cbp;
}
vlong
cpos(void)
{
return coutpos + cbp - buf.cbuf;
}
void
cseek(vlong p)
{
vlong start;
int delta;
if(cbpmax < cbp)
cbpmax = cbp;
start = coutpos;
if(start <= p && p <= start+(cbpmax - buf.cbuf)) {
//print("cseek %lld in [%lld,%lld] (%lld)\n", p, start, start+sizeof(buf.cbuf), cpos());
delta = p - (start + cbp - buf.cbuf);
cbp += delta;
cbc -= delta;
//print("now at %lld\n", cpos());
return;
}
cflush();
seek(cout, p, 0);
coutpos = p;
}
void
cwrite(void *buf, int n)
{
cflush();
if(write(cout, buf, n) != n) {
diag("write error: %r");
errorexit();
}
coutpos += n;
}