kolibrios/programs/develop/ktcc/trunk/source/tccmeos.c
Magomed Kostoev (mkostoevr) 521bee47b1 Make TCC write ".imp.@." section at the end of the file.
Now it's possible to write import table at the end of file without need to put linking of autoimporting libraries at the very end of command line.

git-svn-id: svn://kolibrios.org@8604 a494cfbc-eb01-0410-851d-a64ba20cac60
2021-02-23 16:37:49 +00:00

523 lines
14 KiB
C

/*
* TCCMEOS.C - KolibriOS/MenuetOS file output for the TinyC Compiler
*
* Copyright (c) 2006 Andrey Khalyavin
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
typedef struct {
char magic[8];
int version;
int entry_point;
int image_size;
int memory_size;
int stack;
int params;
int argv;
} IMAGE_MEOS_FILE_HEADER,*PIMAGE_MEOS_FILE_HEADER;
typedef struct _meos_section_info{
int sh_addr;
void* data;
int data_size;
int sec_num;
struct _meos_section_info* next;
} meos_section_info;
typedef struct {
TCCState* s1;
IMAGE_MEOS_FILE_HEADER header;
meos_section_info* code_sections;
meos_section_info* data_sections;
meos_section_info* bss_sections;
meos_section_info* imp_sections; // Pointers to imported libraries and functions
} me_info;
int tcc_output_dbgme(const char *filename, me_info* me);
meos_section_info* findsection(me_info* me,int num)
{
meos_section_info* si;
for(si=me->code_sections;si;si=si->next)
{
if (si->sec_num==num)
return si;
}
for (si=me->data_sections;si;si=si->next)
{
if (si->sec_num==num)
return si;
}
for (si=me->bss_sections;si;si=si->next)
{
if (si->sec_num==num)
return si;
}
for (si=me->imp_sections;si;si=si->next)
{
if (si->sec_num==num)
return si;
}
return (meos_section_info*)0;
}
void build_reloc(me_info* me)
{
int flag;
Elf32_Rel *rel = 0, *rel_ = 0, *rel_end = 0;
Section *sr;
meos_section_info* s;
meos_section_info* ss;
s=me->code_sections;
rel=0;
rel_end=0;
flag=0;
for(;;)
{
sr=me->s1->sections[s->sec_num]->reloc;
if (sr)
{
rel = (Elf32_Rel *) sr->data;
rel_end = (Elf32_Rel *) (sr->data + sr->data_offset);
}
rel_=rel;
while (rel_<rel_end){
rel=rel_;
int type = ELF32_R_TYPE(rel->r_info);
rel_=rel+1;
if (type != R_386_PC32 && type != R_386_32)
continue;
int sym = ELF32_R_SYM(rel->r_info);
if (sym>symtab_section->data_offset/sizeof(Elf32_Sym))
continue;
Elf32_Sym* esym = ((Elf32_Sym *)symtab_section->data)+sym;
int sect=esym->st_shndx;
ss=findsection(me,sect);
if (ss==0)
{
const char *sym_name = strtab_section->data + esym->st_name;
tcc_error_noabort("undefined symbol '%s'", sym_name);
continue;
}
if (rel->r_offset>s->data_size)
continue;
if (type==R_386_PC32)
*(int*)(rel->r_offset+s->data)+=ss->sh_addr+esym->st_value-rel->r_offset-s->sh_addr;
else if (type==R_386_32)
*(int*)(rel->r_offset+s->data)+=ss->sh_addr+esym->st_value;
}
rel=rel_;
s=s->next;
if (s==0) // what about multiple BSS sections ?
{
if (flag) break;
s=me->data_sections;
if (s==0) break;
flag=1;
continue;
}
}
}
void assign_addresses(me_info* me)
{
int i;
meos_section_info* si;
for (i=1;i<me->s1->nb_sections;i++)
{
Section* s=me->s1->sections[i];
if (strcmp(".text",s->name)==0)
{
si=tcc_malloc(sizeof(meos_section_info));
si->data=s->data;
si->data_size=s->data_offset;
si->next=me->code_sections;
si->sec_num=i;
me->code_sections=si;
continue;
}
if (strcmp(".data",s->name)==0)
{
si=tcc_malloc(sizeof(meos_section_info));
si->data=s->data;
si->data_size=s->data_offset;
si->next=me->data_sections;
si->sec_num=i;
me->data_sections=si;
continue;
}
if (strcmp(".bss",s->name)==0)
{
si=tcc_malloc(sizeof(meos_section_info));
si->data=s->data;
si->data_size=s->data_offset;
si->next=me->bss_sections;
si->sec_num=i;
me->bss_sections=si;
continue;
}
if (strcmp(".imp.@.",s->name)==0)
{
si=tcc_malloc(sizeof(meos_section_info));
si->data=s->data;
si->data_size=s->data_offset;
si->next=me->imp_sections;
si->sec_num=i;
me->imp_sections=si;
continue;
}
}
int addr;
addr=sizeof(IMAGE_MEOS_FILE_HEADER);
for (si=me->code_sections;si;si=si->next)
{
si->sh_addr=addr;
addr+=si->data_size;
}
for (si=me->data_sections;si;si=si->next)
{
si->sh_addr=addr;
addr+=si->data_size;
}
for (si=me->imp_sections;si;si=si->next)
{
si->sh_addr=addr;
addr+=si->data_size;
}
me->header.image_size=addr;
for (si=me->bss_sections;si;si=si->next)
{
si->sh_addr=addr;
addr+=si->data_size;
}
if (me->s1->pe_stack_size < 4096)
addr+=4096;
else
addr += me->s1->pe_stack_size;
addr=(addr+4)&(~3);
me->header.stack=addr;
me->header.memory_size=addr;
build_reloc(me);
}
const char *tcc_get_symbol_name(int st_name)
// return string by index from stringtable section
{
const char *sym_name = strtab_section->data + st_name;
return sym_name;
}
int tcc_find_symbol_me(me_info* me, const char *sym_name)
{
int i;
int symtab;
int strtab;
symtab=0;
strtab=0;
for (i=1;i<me->s1->nb_sections;i++)
{
Section* s;
s=me->s1->sections[i];
if (strcmp(s->name,".symtab")==0)
{
symtab=i;
}
if (strcmp(s->name,".strtab")==0)
{
strtab=i;
}
}
if (symtab==0 || strtab==0)
{
tcc_error_noabort("undefined sections .symtab or .strtab on linking '%s'", sym_name);
return 0;
}
Elf32_Sym* s,*se;
char* name;
s=(Elf32_Sym*)me->s1->sections[symtab]->data;
se=(Elf32_Sym*)(((void*)s)+me->s1->sections[symtab]->data_offset);
name=(char*)me->s1->sections[strtab]->data;
while (s<se)
{
if (strcmp(name+s->st_name,sym_name)==0)
{
return s->st_value+findsection(me,s->st_shndx)->sh_addr;
}
s++;
}
tcc_error_noabort("undefined symbol '%s'", sym_name);
return 0;
}
const char* me_magic="MENUET01";
int tcc_output_me(TCCState* s1,const char *filename)
{
me_info me;
int i;
FILE* f;
//printf("%d\n",s1->nb_sections);
memset(&me,0,sizeof(me));
me.s1=s1;
relocate_common_syms();
assign_addresses(&me);
if (s1->do_debug)
tcc_output_dbgme(filename, &me);
me.header.entry_point=tcc_find_symbol_me(&me,"start");
me.header.params= tcc_find_symbol_me(&me,"__argv"); // <--
me.header.argv= tcc_find_symbol_me(&me,"__path"); // <--
f=fopen(filename,"wb");
for (i=0;i<8;i++)
me.header.magic[i]=me_magic[i];
fwrite(&me.header,1,sizeof(IMAGE_MEOS_FILE_HEADER),f);
meos_section_info* si;
for(si=me.code_sections;si;si=si->next)
fwrite(si->data,1,si->data_size,f);
for (si=me.data_sections;si;si=si->next)
fwrite(si->data,1,si->data_size,f);
// IMPORTANT: Write ".imp.@." sections at the very end!
// BSS sections don't count, they should not be in the file at all
// Cause MENUET header filled assuming that file size does not include BSS
// We just emit it for smaller entrophia, sometimes
// it makes the kex file being packed better
for (si=me.imp_sections;si;si=si->next)
fwrite(si->data,1,si->data_size,f);
if (!s1->nobss)
{
for (si=me.bss_sections;si;si=si->next)
{
if (si->data == NULL)
{
// printf("\nError! BSS data is NULL! size:%i",(int)si->data_size);
si->data = calloc(si->data_size, 1);
}
fwrite(si->data, 1, si->data_size, f);
}
}
/*
if (me.bss_sections) // Siemargl testin, what we lose
{
tcc_error_noabort("We lose .BSS section when linking KOS32 executable");
}
*/
fclose(f);
return 0;
}
#ifndef _WIN32
static inline int get_current_folder(char* buf, int bufsize){
register int val;
asm volatile ("int $0x40":"=a"(val):"a"(30), "b"(2), "c"(buf), "d"(bufsize));
return val;
}
char *getcwd(char *buf, size_t size)
{
int rc = get_current_folder(buf, size);
if (rc > size)
{
errno = ERANGE;
return 0;
}
else
return buf;
}
#endif
static FILE *src_file;
static int next_src_line;
void close_source_file()
{
if (src_file)
fclose(src_file);
src_file = NULL;
}
void load_source_file(char *fname)
{
close_source_file();
src_file = fopen(fname,"rt");
if (!src_file) return;
next_src_line = 1;
}
int get_src_lines(char *buf, int sz, int start, int end)
// 1 if read
{
char line[255], *ch;
strcpy(buf, "");
if (!src_file) return 0;
while (next_src_line < start) // skip
{
ch = fgets(line, sizeof line, src_file);
if (!ch) return 0;
next_src_line++;
}
while (next_src_line <= end)
{
ch = fgets(line, sizeof line, src_file);
if (!ch) return 0;
next_src_line++;
strncat(buf, line, sz - strlen(buf) - 1);
}
// remove newlines
for (ch = buf; *ch; ch++)
if (strchr("\t\n\r", *ch)) *ch = ' ';
return 1;
}
int tcc_output_dbgme(const char *filename, me_info* me)
// by Siemargl. Writes filename.dbg file for source code level debuggin with MTDBG
// return 1 on error
{
FILE *fdbg;
char fname[400],
buf[80]; // no more fits in mtdbg string
strcpy(fname, filename);
strcat(fname, ".dbg");
fdbg = fopen(fname,"wt");
if (!fdbg) return 1;
meos_section_info *si, *ss;
fputs(".text\n", fdbg); // just for mtbg
// print symbol table with resolved addresses
Elf32_Sym* esym;
for (esym = (Elf32_Sym*)symtab_section->data; esym <= (Elf32_Sym*)(symtab_section->data + symtab_section->data_offset); esym++)
{
if (esym->st_info == 0 || esym->st_info == 4) continue;
int sect = esym->st_shndx;
ss = findsection(me, sect);
const char *sym_name = strtab_section->data + esym->st_name;
if (ss == 0)
{
fprintf(fdbg, "undefined symbol '%s' type(%d)\n", sym_name, esym->st_info);
continue;
}
fprintf(fdbg, "0x%X %s\n", ss->sh_addr + esym->st_value, sym_name); // removed type(%d) esym->st_info
}
fputs(".text source code links\n", fdbg); // just for mtbg
// print symbol table with resolved addresses
Stab_Sym *stab;
char *str = "", *cur_file = "???", cur_fun[255];
int cur_line = 0, cur_fun_addr = 0, fun_flag = 0;
strcpy(cur_fun, "fn???");
for (stab = (Stab_Sym*)stab_section->data; stab <= (Stab_Sym*)(stab_section->data + stab_section->data_offset); stab++)
{
str = "";
switch(stab->n_type)
{
case 100: // source file, or path
if (stab->n_strx)
{
cur_file = stabstr_section->data + stab->n_strx;
load_source_file(cur_file);
}
else
cur_file = "???";
strcpy(cur_fun, "fn???");
cur_line = 0;
cur_fun_addr = 0;
fun_flag = 0;
break;
case 36: // func
cur_fun_addr = 0;
if (stab->n_strx)
{
strcpy(cur_fun, stabstr_section->data + stab->n_strx);
str = strchr(cur_fun, ':');
if (str) *str = '\0';
cur_fun_addr = tcc_find_symbol_me(me, cur_fun);
cur_line = stab->n_desc;
fun_flag = 1;
//fprintf(fdbg, "0x%X %s() line(%d)\n", cur_fun_addr, cur_fun, cur_line); // commented as conflicted with direct address
}
else
strcpy(cur_fun, "fn???");
break;
case 68: // N_SLINE
if (stab->n_value == 0 ) continue; // skip zero offset line
if (fun_flag) // skip string {, as duplicates address
{
fun_flag = 0;
continue;
}
int line;
if (stab->n_desc > cur_line)
line = cur_line + 1;
else
line = cur_line;
//fprintf(fdbg, "0x%X LINES %d-%d \n", cur_fun_addr + stab->n_value, line, stab->n_desc);
if (get_src_lines(buf, sizeof buf, line, stab->n_desc))
fprintf(fdbg, "0x%X %s\n", cur_fun_addr + stab->n_value, buf);
cur_line = stab->n_desc;
break;
default:
continue;
}
/*
if (stab->n_strx)
str = stabstr_section->data + stab->n_strx;
fprintf(fdbg, "0x%X type(%d) str(%s) desc(%d)\n", stab->n_value, stab->n_type, str, stab->n_desc);
*/
}
/* for(; si; si = si->next)
{
Section *sr;
Elf32_Rel *rel, *rel_end;
for(sr = me->s1->sections[si->sec_num]->reloc; sr; )
{
for (rel = (Elf32_Rel *) sr->data, rel_end = (Elf32_Rel *) (sr->data + sr->data_offset); rel < rel_end; rel++)
{
int type = ELF32_R_TYPE(rel->r_info);
if (type != R_386_PC32 && type != R_386_32)
continue;
int sym = ELF32_R_SYM(rel->r_info);
if (sym > symtab_section->data_offset / sizeof(Elf32_Sym))
continue;
Elf32_Sym* esym = ((Elf32_Sym*)symtab_section->data) + sym;
int sect = esym->st_shndx;
ss = findsection(me, sect);
const char *sym_name = strtab_section->data + esym->st_name;
if (ss == 0)
{
fprintf(fdbg, "undefined symbol '%s'\n", sym_name);
continue;
}
if (rel->r_offset > si->data_size) continue;
fprintf(fdbg, "\t0x%X %s\n", ss->sh_addr + esym->st_value, sym_name);
}
}
}
*/
close_source_file();
fclose(fdbg);
return 0;
}