tinycc/tccgen.c

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/*
* TCC - Tiny C Compiler
*
* Copyright (c) 2001-2004 Fabrice Bellard
*
* 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
*/
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void swap(int *p, int *q)
{
int t;
t = *p;
*p = *q;
*q = t;
}
void vsetc(CType *type, int r, CValue *vc)
{
int v;
if (vtop >= vstack + (VSTACK_SIZE - 1))
error("memory full");
/* cannot let cpu flags if other instruction are generated. Also
avoid leaving VT_JMP anywhere except on the top of the stack
because it would complicate the code generator. */
if (vtop >= vstack) {
v = vtop->r & VT_VALMASK;
if (v == VT_CMP || (v & ~1) == VT_JMP)
gv(RC_INT);
}
vtop++;
vtop->type = *type;
vtop->r = r;
vtop->r2 = VT_CONST;
vtop->c = *vc;
}
/* push integer constant */
void vpushi(int v)
{
CValue cval;
cval.i = v;
vsetc(&int_type, VT_CONST, &cval);
}
/* push long long constant */
void vpushll(long long v)
{
CValue cval;
CType ctype;
ctype.t = VT_LLONG;
cval.ull = v;
vsetc(&ctype, VT_CONST, &cval);
}
/* Return a static symbol pointing to a section */
static Sym *get_sym_ref(CType *type, Section *sec,
unsigned long offset, unsigned long size)
{
int v;
Sym *sym;
v = anon_sym++;
sym = global_identifier_push(v, type->t | VT_STATIC, 0);
sym->type.ref = type->ref;
sym->r = VT_CONST | VT_SYM;
put_extern_sym(sym, sec, offset, size);
return sym;
}
/* push a reference to a section offset by adding a dummy symbol */
static void vpush_ref(CType *type, Section *sec, unsigned long offset, unsigned long size)
{
CValue cval;
cval.ul = 0;
vsetc(type, VT_CONST | VT_SYM, &cval);
vtop->sym = get_sym_ref(type, sec, offset, size);
}
/* define a new external reference to a symbol 'v' of type 'u' */
static Sym *external_global_sym(int v, CType *type, int r)
{
Sym *s;
s = sym_find(v);
if (!s) {
/* push forward reference */
s = global_identifier_push(v, type->t | VT_EXTERN, 0);
s->type.ref = type->ref;
s->r = r | VT_CONST | VT_SYM;
}
return s;
}
/* define a new external reference to a symbol 'v' of type 'u' */
static Sym *external_sym(int v, CType *type, int r)
{
Sym *s;
s = sym_find(v);
if (!s) {
/* push forward reference */
s = sym_push(v, type, r | VT_CONST | VT_SYM, 0);
s->type.t |= VT_EXTERN;
} else if (s->type.ref == func_old_type.ref) {
s->type.ref = type->ref;
s->r = r | VT_CONST | VT_SYM;
s->type.t |= VT_EXTERN;
} else if (!is_compatible_types(&s->type, type)) {
error("incompatible types for redefinition of '%s'",
get_tok_str(v, NULL));
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}
return s;
}
/* push a reference to global symbol v */
static void vpush_global_sym(CType *type, int v)
{
Sym *sym;
CValue cval;
sym = external_global_sym(v, type, 0);
cval.ul = 0;
vsetc(type, VT_CONST | VT_SYM, &cval);
vtop->sym = sym;
}
void vset(CType *type, int r, int v)
{
CValue cval;
cval.i = v;
vsetc(type, r, &cval);
}
void vseti(int r, int v)
{
CType type;
type.t = VT_INT;
vset(&type, r, v);
}
void vswap(void)
{
SValue tmp;
tmp = vtop[0];
vtop[0] = vtop[-1];
vtop[-1] = tmp;
}
void vpushv(SValue *v)
{
if (vtop >= vstack + (VSTACK_SIZE - 1))
error("memory full");
vtop++;
*vtop = *v;
}
void vdup(void)
{
vpushv(vtop);
}
/* save r to the memory stack, and mark it as being free */
void save_reg(int r)
{
int l, saved, size, align;
SValue *p, sv;
CType *type;
/* modify all stack values */
saved = 0;
l = 0;
for(p=vstack;p<=vtop;p++) {
if ((p->r & VT_VALMASK) == r ||
((p->type.t & VT_BTYPE) == VT_LLONG && (p->r2 & VT_VALMASK) == r)) {
/* must save value on stack if not already done */
if (!saved) {
/* NOTE: must reload 'r' because r might be equal to r2 */
r = p->r & VT_VALMASK;
/* store register in the stack */
type = &p->type;
if ((p->r & VT_LVAL) ||
(!is_float(type->t) && (type->t & VT_BTYPE) != VT_LLONG))
#ifdef TCC_TARGET_X86_64
type = &char_pointer_type;
#else
type = &int_type;
#endif
size = type_size(type, &align);
loc = (loc - size) & -align;
sv.type.t = type->t;
sv.r = VT_LOCAL | VT_LVAL;
sv.c.ul = loc;
store(r, &sv);
#if defined(TCC_TARGET_I386) || defined(TCC_TARGET_X86_64)
/* x86 specific: need to pop fp register ST0 if saved */
if (r == TREG_ST0) {
trying to fix the bug of unclean FPU st(0) Date: Mon, 8 Jun 2009 19:06:56 +0800 From: Soloist Deng <soloist.deng-gmail-com> Subject: [Tinycc-devel] trying to fix the bug of unclean FPU st(0) Hi all: I am using tcc-0.9.25, and the FPU bug brought a big trouble to me. I read the source and tried to fix it. Below is my solution. There are two places where program(`o(0xd9dd)') will generates `fstp %st(1)': vpop() in tccgen.c:689 and save_reg() in tccgen.c:210. We should first change both of them to `o(0xd8dd) // fstp %st(0)'. But these changes are not enough. Let's check the following code. void foo() { double var = 2.7; var++; } Using the changed tcc will generate following machine code: .text:08000000 public foo .text:08000000 foo proc near .text:08000000 .text:08000000 var_18 = qword ptr -18h .text:08000000 var_10 = qword ptr -10h .text:08000000 var_8 = qword ptr -8 .text:08000000 .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 18h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fst [ebp+var_18] .text:08000020 fstp st(0) .text:08000022 fld L_1 .text:08000028 fadd [ebp+var_10] .text:0800002B fst [ebp+var_8] .text:0800002E fstp st(0) .text:08000030 leave .text:08000031 retn .text:08000031 foo endp .text:08000031 .text:08000031 _text ends -------------------------------------------------- .data:08000040 ; Segment type: Pure data .data:08000040 ; Segment permissions: Read/Write .data:08000040 ; Segment alignment '32byte' can not be represented in assembly .data:08000040 _data segment page public 'DATA' use32 .data:08000040 assume cs:_data .data:08000040 ;org 8000040h .data:08000040 L_0 dq 400599999999999Ah .data:08000048 L_1 dq 3FF0000000000000h .data:08000048 _data ends Please notice the code snippet from 0800000A to 08000020 // double var = 2.7; load constant to st(0) .text:0800000A fld L_0 // double var = 2.7; store st(0) to `var' .text:08000010 fst [ebp+var_8] // double var = 2.7; poping st(0) will empty the floating registers stack .text:08000013 fstp st(0) After that ,tcc will call `void inc(int post, int c)" in tccgen.c:2150, and produce 08000015 to 0800001B through the calling chain (inc ->gv_dup) // load from `var' to st(0) .text:08000015 fld [ebp+var_8] // store st(0) to a temporary location .text:08000018 fst [ebp+var_10] // poping st(0) will empty the floating registers stack .text:0800001B fstp st(0) And the calling chain (gen_op('+')->gen_opif('+')->gen_opf('+')->gv(rc=2)->get_reg(rc=2)->save_reg(r=3)) will produce 0800001D to 08000020 . // store st(0) to a temporary location, but floating stack is empty! .text:0800001D fst [ebp+var_18] // poping st(0) will empty the floating registers stack .text:08000020 fstp st(0) The `0800001D fst [ebp+var_18]' will store st(0) to a memory location, but st(0) is empty. That will cause FPU invalid operation exception(#IE). Why does tcc do that? Please read `gv_dup' called by `inc' carefully. Notice these lines: (1): r = gv(rc); (2): r1 = get_reg(rc); (3): sv.r = r; sv.c.ul = 0; (4) load(r1, &sv); /* move r to r1 */ (5) vdup(); /* duplicates value */ (6) vtop->r = r1; (1) let the vtop occupy TREG_ST0, and `r' will be TREG_ST0. (2) try to get a free floating register,but tcc assume there is only one, so it wil force vtop goto memory and assign `r1' with TREG_ST0. When executing (3), it will do nothing because `r' equals `r1'. (5) duplicates vtop. Then (6) let the new vtop occupy TREG_ST0, but this will cause problem because the old vtop has been moved to memory, so the new duplicated vtop does not reside in TREG_ST0 but also in memory after that. TREG_ST0 is not occupied but freely availabe now. `gen_op('+')' need at least one oprand in register, so it will incorrectly think TREG_ST0 is occupied by vtop and produce instructions(0800001D and 08000020) to store it to a temporary memory location. According program above, if `r' == `r1' it is impossible for the old vtop to still occupy the `r' register . And `load' will do nothing too at this condition. So the `gv_dup' can not promise the semantics that old vtop in one register and the new duplicated vtop in another register at the same time. I changed (6) to if (r != r1) { vtop->r = r1; } Then the new generated machine code will be : .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 10h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fld L_1 .text:08000023 fadd [ebp+var_10] .text:08000026 fst [ebp+var_8] .text:08000029 fstp st(0) .text:0800002B leave .text:0800002C retn It works well, and will clean the floating registers stack when return. Finally, I want to know there is any potential problem of this fixing ? soloist
2009-06-08 21:26:19 +04:00
o(0xd8dd); /* fstp %st(0) */
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}
#endif
#ifndef TCC_TARGET_X86_64
/* special long long case */
if ((type->t & VT_BTYPE) == VT_LLONG) {
sv.c.ul += 4;
store(p->r2, &sv);
}
#endif
l = loc;
saved = 1;
}
/* mark that stack entry as being saved on the stack */
if (p->r & VT_LVAL) {
/* also clear the bounded flag because the
relocation address of the function was stored in
p->c.ul */
p->r = (p->r & ~(VT_VALMASK | VT_BOUNDED)) | VT_LLOCAL;
} else {
p->r = lvalue_type(p->type.t) | VT_LOCAL;
}
p->r2 = VT_CONST;
p->c.ul = l;
}
}
}
/* find a register of class 'rc2' with at most one reference on stack.
* If none, call get_reg(rc) */
int get_reg_ex(int rc, int rc2)
{
int r;
SValue *p;
for(r=0;r<NB_REGS;r++) {
if (reg_classes[r] & rc2) {
int n;
n=0;
for(p = vstack; p <= vtop; p++) {
if ((p->r & VT_VALMASK) == r ||
(p->r2 & VT_VALMASK) == r)
n++;
}
if (n <= 1)
return r;
}
}
return get_reg(rc);
}
/* find a free register of class 'rc'. If none, save one register */
int get_reg(int rc)
{
int r;
SValue *p;
/* find a free register */
for(r=0;r<NB_REGS;r++) {
if (reg_classes[r] & rc) {
for(p=vstack;p<=vtop;p++) {
if ((p->r & VT_VALMASK) == r ||
(p->r2 & VT_VALMASK) == r)
goto notfound;
}
return r;
}
notfound: ;
}
/* no register left : free the first one on the stack (VERY
IMPORTANT to start from the bottom to ensure that we don't
spill registers used in gen_opi()) */
for(p=vstack;p<=vtop;p++) {
r = p->r & VT_VALMASK;
if (r < VT_CONST && (reg_classes[r] & rc))
goto save_found;
/* also look at second register (if long long) */
r = p->r2 & VT_VALMASK;
if (r < VT_CONST && (reg_classes[r] & rc)) {
save_found:
save_reg(r);
return r;
}
}
/* Should never comes here */
return -1;
}
/* save registers up to (vtop - n) stack entry */
void save_regs(int n)
{
int r;
SValue *p, *p1;
p1 = vtop - n;
for(p = vstack;p <= p1; p++) {
r = p->r & VT_VALMASK;
if (r < VT_CONST) {
save_reg(r);
}
}
}
/* move register 's' to 'r', and flush previous value of r to memory
if needed */
void move_reg(int r, int s)
{
SValue sv;
if (r != s) {
save_reg(r);
sv.type.t = VT_INT;
sv.r = s;
sv.c.ul = 0;
load(r, &sv);
}
}
/* get address of vtop (vtop MUST BE an lvalue) */
void gaddrof(void)
{
vtop->r &= ~VT_LVAL;
/* tricky: if saved lvalue, then we can go back to lvalue */
if ((vtop->r & VT_VALMASK) == VT_LLOCAL)
vtop->r = (vtop->r & ~(VT_VALMASK | VT_LVAL_TYPE)) | VT_LOCAL | VT_LVAL;
}
#ifdef CONFIG_TCC_BCHECK
/* generate lvalue bound code */
void gbound(void)
{
int lval_type;
CType type1;
vtop->r &= ~VT_MUSTBOUND;
/* if lvalue, then use checking code before dereferencing */
if (vtop->r & VT_LVAL) {
/* if not VT_BOUNDED value, then make one */
if (!(vtop->r & VT_BOUNDED)) {
lval_type = vtop->r & (VT_LVAL_TYPE | VT_LVAL);
/* must save type because we must set it to int to get pointer */
type1 = vtop->type;
vtop->type.t = VT_INT;
gaddrof();
vpushi(0);
gen_bounded_ptr_add();
vtop->r |= lval_type;
vtop->type = type1;
}
/* then check for dereferencing */
gen_bounded_ptr_deref();
}
}
#endif
/* store vtop a register belonging to class 'rc'. lvalues are
converted to values. Cannot be used if cannot be converted to
register value (such as structures). */
int gv(int rc)
{
int r, rc2, bit_pos, bit_size, size, align, i;
/* NOTE: get_reg can modify vstack[] */
if (vtop->type.t & VT_BITFIELD) {
CType type;
int bits = 32;
bit_pos = (vtop->type.t >> VT_STRUCT_SHIFT) & 0x3f;
bit_size = (vtop->type.t >> (VT_STRUCT_SHIFT + 6)) & 0x3f;
/* remove bit field info to avoid loops */
vtop->type.t &= ~(VT_BITFIELD | (-1 << VT_STRUCT_SHIFT));
/* cast to int to propagate signedness in following ops */
if ((vtop->type.t & VT_BTYPE) == VT_LLONG) {
type.t = VT_LLONG;
bits = 64;
} else
type.t = VT_INT;
if((vtop->type.t & VT_UNSIGNED) ||
(vtop->type.t & VT_BTYPE) == VT_BOOL)
type.t |= VT_UNSIGNED;
gen_cast(&type);
/* generate shifts */
vpushi(bits - (bit_pos + bit_size));
gen_op(TOK_SHL);
vpushi(bits - bit_size);
/* NOTE: transformed to SHR if unsigned */
gen_op(TOK_SAR);
r = gv(rc);
} else {
if (is_float(vtop->type.t) &&
(vtop->r & (VT_VALMASK | VT_LVAL)) == VT_CONST) {
Sym *sym;
int *ptr;
unsigned long offset;
#if defined(TCC_TARGET_ARM) && !defined(TCC_ARM_VFP)
CValue check;
#endif
/* XXX: unify with initializers handling ? */
/* CPUs usually cannot use float constants, so we store them
generically in data segment */
size = type_size(&vtop->type, &align);
offset = (data_section->data_offset + align - 1) & -align;
data_section->data_offset = offset;
/* XXX: not portable yet */
#if defined(__i386__) || defined(__x86_64__)
/* Zero pad x87 tenbyte long doubles */
if (size == LDOUBLE_SIZE)
vtop->c.tab[2] &= 0xffff;
#endif
ptr = section_ptr_add(data_section, size);
size = size >> 2;
#if defined(TCC_TARGET_ARM) && !defined(TCC_ARM_VFP)
check.d = 1;
if(check.tab[0])
for(i=0;i<size;i++)
ptr[i] = vtop->c.tab[size-1-i];
else
#endif
for(i=0;i<size;i++)
ptr[i] = vtop->c.tab[i];
sym = get_sym_ref(&vtop->type, data_section, offset, size << 2);
vtop->r |= VT_LVAL | VT_SYM;
vtop->sym = sym;
vtop->c.ul = 0;
}
#ifdef CONFIG_TCC_BCHECK
if (vtop->r & VT_MUSTBOUND)
gbound();
#endif
r = vtop->r & VT_VALMASK;
rc2 = RC_INT;
if (rc == RC_IRET)
rc2 = RC_LRET;
/* need to reload if:
- constant
- lvalue (need to dereference pointer)
- already a register, but not in the right class */
if (r >= VT_CONST
|| (vtop->r & VT_LVAL)
|| !(reg_classes[r] & rc)
#ifndef TCC_TARGET_X86_64
|| ((vtop->type.t & VT_BTYPE) == VT_LLONG && !(reg_classes[vtop->r2] & rc2))
#endif
)
{
2009-05-05 22:18:10 +04:00
r = get_reg(rc);
#ifndef TCC_TARGET_X86_64
if ((vtop->type.t & VT_BTYPE) == VT_LLONG) {
int r2;
unsigned long long ll;
/* two register type load : expand to two words
temporarily */
if ((vtop->r & (VT_VALMASK | VT_LVAL)) == VT_CONST) {
/* load constant */
ll = vtop->c.ull;
vtop->c.ui = ll; /* first word */
load(r, vtop);
vtop->r = r; /* save register value */
vpushi(ll >> 32); /* second word */
} else if (r >= VT_CONST || /* XXX: test to VT_CONST incorrect ? */
(vtop->r & VT_LVAL)) {
/* We do not want to modifier the long long
pointer here, so the safest (and less
efficient) is to save all the other registers
in the stack. XXX: totally inefficient. */
save_regs(1);
/* load from memory */
load(r, vtop);
vdup();
vtop[-1].r = r; /* save register value */
/* increment pointer to get second word */
vtop->type.t = VT_INT;
gaddrof();
vpushi(4);
gen_op('+');
vtop->r |= VT_LVAL;
} else {
/* move registers */
load(r, vtop);
vdup();
vtop[-1].r = r; /* save register value */
vtop->r = vtop[-1].r2;
}
/* allocate second register */
r2 = get_reg(rc2);
load(r2, vtop);
vpop();
/* write second register */
vtop->r2 = r2;
} else
#endif
if ((vtop->r & VT_LVAL) && !is_float(vtop->type.t)) {
int t1, t;
/* lvalue of scalar type : need to use lvalue type
because of possible cast */
t = vtop->type.t;
t1 = t;
/* compute memory access type */
if (vtop->r & VT_LVAL_BYTE)
t = VT_BYTE;
else if (vtop->r & VT_LVAL_SHORT)
t = VT_SHORT;
if (vtop->r & VT_LVAL_UNSIGNED)
t |= VT_UNSIGNED;
vtop->type.t = t;
load(r, vtop);
/* restore wanted type */
vtop->type.t = t1;
} else {
/* one register type load */
load(r, vtop);
}
}
vtop->r = r;
#ifdef TCC_TARGET_C67
/* uses register pairs for doubles */
if ((vtop->type.t & VT_BTYPE) == VT_DOUBLE)
vtop->r2 = r+1;
#endif
}
return r;
}
/* generate vtop[-1] and vtop[0] in resp. classes rc1 and rc2 */
void gv2(int rc1, int rc2)
{
int v;
/* generate more generic register first. But VT_JMP or VT_CMP
values must be generated first in all cases to avoid possible
reload errors */
v = vtop[0].r & VT_VALMASK;
if (v != VT_CMP && (v & ~1) != VT_JMP && rc1 <= rc2) {
vswap();
gv(rc1);
vswap();
gv(rc2);
/* test if reload is needed for first register */
if ((vtop[-1].r & VT_VALMASK) >= VT_CONST) {
vswap();
gv(rc1);
vswap();
}
} else {
gv(rc2);
vswap();
gv(rc1);
vswap();
/* test if reload is needed for first register */
if ((vtop[0].r & VT_VALMASK) >= VT_CONST) {
gv(rc2);
}
}
}
/* wrapper around RC_FRET to return a register by type */
int rc_fret(int t)
{
#ifdef TCC_TARGET_X86_64
if (t == VT_LDOUBLE) {
return RC_ST0;
}
#endif
return RC_FRET;
}
/* wrapper around REG_FRET to return a register by type */
int reg_fret(int t)
{
#ifdef TCC_TARGET_X86_64
if (t == VT_LDOUBLE) {
return TREG_ST0;
}
#endif
return REG_FRET;
}
/* expand long long on stack in two int registers */
void lexpand(void)
{
int u;
u = vtop->type.t & VT_UNSIGNED;
gv(RC_INT);
vdup();
vtop[0].r = vtop[-1].r2;
vtop[0].r2 = VT_CONST;
vtop[-1].r2 = VT_CONST;
vtop[0].type.t = VT_INT | u;
vtop[-1].type.t = VT_INT | u;
}
#ifdef TCC_TARGET_ARM
/* expand long long on stack */
void lexpand_nr(void)
{
int u,v;
u = vtop->type.t & VT_UNSIGNED;
vdup();
vtop->r2 = VT_CONST;
vtop->type.t = VT_INT | u;
v=vtop[-1].r & (VT_VALMASK | VT_LVAL);
if (v == VT_CONST) {
vtop[-1].c.ui = vtop->c.ull;
vtop->c.ui = vtop->c.ull >> 32;
vtop->r = VT_CONST;
} else if (v == (VT_LVAL|VT_CONST) || v == (VT_LVAL|VT_LOCAL)) {
vtop->c.ui += 4;
vtop->r = vtop[-1].r;
} else if (v > VT_CONST) {
vtop--;
lexpand();
} else
vtop->r = vtop[-1].r2;
vtop[-1].r2 = VT_CONST;
vtop[-1].type.t = VT_INT | u;
}
#endif
/* build a long long from two ints */
void lbuild(int t)
{
gv2(RC_INT, RC_INT);
vtop[-1].r2 = vtop[0].r;
vtop[-1].type.t = t;
vpop();
}
/* rotate n first stack elements to the bottom
I1 ... In -> I2 ... In I1 [top is right]
*/
void vrotb(int n)
{
int i;
SValue tmp;
tmp = vtop[-n + 1];
for(i=-n+1;i!=0;i++)
vtop[i] = vtop[i+1];
vtop[0] = tmp;
}
/* rotate n first stack elements to the top
I1 ... In -> In I1 ... I(n-1) [top is right]
*/
void vrott(int n)
{
int i;
SValue tmp;
tmp = vtop[0];
for(i = 0;i < n - 1; i++)
vtop[-i] = vtop[-i - 1];
vtop[-n + 1] = tmp;
}
#ifdef TCC_TARGET_ARM
/* like vrott but in other direction
In ... I1 -> I(n-1) ... I1 In [top is right]
*/
void vnrott(int n)
{
int i;
SValue tmp;
tmp = vtop[-n + 1];
for(i = n - 1; i > 0; i--)
vtop[-i] = vtop[-i + 1];
vtop[0] = tmp;
}
#endif
/* pop stack value */
void vpop(void)
{
int v;
v = vtop->r & VT_VALMASK;
#if defined(TCC_TARGET_I386) || defined(TCC_TARGET_X86_64)
/* for x86, we need to pop the FP stack */
if (v == TREG_ST0 && !nocode_wanted) {
trying to fix the bug of unclean FPU st(0) Date: Mon, 8 Jun 2009 19:06:56 +0800 From: Soloist Deng <soloist.deng-gmail-com> Subject: [Tinycc-devel] trying to fix the bug of unclean FPU st(0) Hi all: I am using tcc-0.9.25, and the FPU bug brought a big trouble to me. I read the source and tried to fix it. Below is my solution. There are two places where program(`o(0xd9dd)') will generates `fstp %st(1)': vpop() in tccgen.c:689 and save_reg() in tccgen.c:210. We should first change both of them to `o(0xd8dd) // fstp %st(0)'. But these changes are not enough. Let's check the following code. void foo() { double var = 2.7; var++; } Using the changed tcc will generate following machine code: .text:08000000 public foo .text:08000000 foo proc near .text:08000000 .text:08000000 var_18 = qword ptr -18h .text:08000000 var_10 = qword ptr -10h .text:08000000 var_8 = qword ptr -8 .text:08000000 .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 18h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fst [ebp+var_18] .text:08000020 fstp st(0) .text:08000022 fld L_1 .text:08000028 fadd [ebp+var_10] .text:0800002B fst [ebp+var_8] .text:0800002E fstp st(0) .text:08000030 leave .text:08000031 retn .text:08000031 foo endp .text:08000031 .text:08000031 _text ends -------------------------------------------------- .data:08000040 ; Segment type: Pure data .data:08000040 ; Segment permissions: Read/Write .data:08000040 ; Segment alignment '32byte' can not be represented in assembly .data:08000040 _data segment page public 'DATA' use32 .data:08000040 assume cs:_data .data:08000040 ;org 8000040h .data:08000040 L_0 dq 400599999999999Ah .data:08000048 L_1 dq 3FF0000000000000h .data:08000048 _data ends Please notice the code snippet from 0800000A to 08000020 // double var = 2.7; load constant to st(0) .text:0800000A fld L_0 // double var = 2.7; store st(0) to `var' .text:08000010 fst [ebp+var_8] // double var = 2.7; poping st(0) will empty the floating registers stack .text:08000013 fstp st(0) After that ,tcc will call `void inc(int post, int c)" in tccgen.c:2150, and produce 08000015 to 0800001B through the calling chain (inc ->gv_dup) // load from `var' to st(0) .text:08000015 fld [ebp+var_8] // store st(0) to a temporary location .text:08000018 fst [ebp+var_10] // poping st(0) will empty the floating registers stack .text:0800001B fstp st(0) And the calling chain (gen_op('+')->gen_opif('+')->gen_opf('+')->gv(rc=2)->get_reg(rc=2)->save_reg(r=3)) will produce 0800001D to 08000020 . // store st(0) to a temporary location, but floating stack is empty! .text:0800001D fst [ebp+var_18] // poping st(0) will empty the floating registers stack .text:08000020 fstp st(0) The `0800001D fst [ebp+var_18]' will store st(0) to a memory location, but st(0) is empty. That will cause FPU invalid operation exception(#IE). Why does tcc do that? Please read `gv_dup' called by `inc' carefully. Notice these lines: (1): r = gv(rc); (2): r1 = get_reg(rc); (3): sv.r = r; sv.c.ul = 0; (4) load(r1, &sv); /* move r to r1 */ (5) vdup(); /* duplicates value */ (6) vtop->r = r1; (1) let the vtop occupy TREG_ST0, and `r' will be TREG_ST0. (2) try to get a free floating register,but tcc assume there is only one, so it wil force vtop goto memory and assign `r1' with TREG_ST0. When executing (3), it will do nothing because `r' equals `r1'. (5) duplicates vtop. Then (6) let the new vtop occupy TREG_ST0, but this will cause problem because the old vtop has been moved to memory, so the new duplicated vtop does not reside in TREG_ST0 but also in memory after that. TREG_ST0 is not occupied but freely availabe now. `gen_op('+')' need at least one oprand in register, so it will incorrectly think TREG_ST0 is occupied by vtop and produce instructions(0800001D and 08000020) to store it to a temporary memory location. According program above, if `r' == `r1' it is impossible for the old vtop to still occupy the `r' register . And `load' will do nothing too at this condition. So the `gv_dup' can not promise the semantics that old vtop in one register and the new duplicated vtop in another register at the same time. I changed (6) to if (r != r1) { vtop->r = r1; } Then the new generated machine code will be : .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 10h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fld L_1 .text:08000023 fadd [ebp+var_10] .text:08000026 fst [ebp+var_8] .text:08000029 fstp st(0) .text:0800002B leave .text:0800002C retn It works well, and will clean the floating registers stack when return. Finally, I want to know there is any potential problem of this fixing ? soloist
2009-06-08 21:26:19 +04:00
o(0xd8dd); /* fstp %st(0) */
2009-05-05 22:18:10 +04:00
} else
#endif
if (v == VT_JMP || v == VT_JMPI) {
/* need to put correct jump if && or || without test */
gsym(vtop->c.ul);
}
vtop--;
}
/* convert stack entry to register and duplicate its value in another
register */
void gv_dup(void)
{
int rc, t, r, r1;
SValue sv;
t = vtop->type.t;
if ((t & VT_BTYPE) == VT_LLONG) {
lexpand();
gv_dup();
vswap();
vrotb(3);
gv_dup();
vrotb(4);
/* stack: H L L1 H1 */
lbuild(t);
vrotb(3);
vrotb(3);
vswap();
lbuild(t);
vswap();
} else {
/* duplicate value */
rc = RC_INT;
sv.type.t = VT_INT;
if (is_float(t)) {
rc = RC_FLOAT;
#ifdef TCC_TARGET_X86_64
if ((t & VT_BTYPE) == VT_LDOUBLE) {
rc = RC_ST0;
}
#endif
sv.type.t = t;
}
r = gv(rc);
r1 = get_reg(rc);
sv.r = r;
sv.c.ul = 0;
load(r1, &sv); /* move r to r1 */
vdup();
/* duplicates value */
trying to fix the bug of unclean FPU st(0) Date: Mon, 8 Jun 2009 19:06:56 +0800 From: Soloist Deng <soloist.deng-gmail-com> Subject: [Tinycc-devel] trying to fix the bug of unclean FPU st(0) Hi all: I am using tcc-0.9.25, and the FPU bug brought a big trouble to me. I read the source and tried to fix it. Below is my solution. There are two places where program(`o(0xd9dd)') will generates `fstp %st(1)': vpop() in tccgen.c:689 and save_reg() in tccgen.c:210. We should first change both of them to `o(0xd8dd) // fstp %st(0)'. But these changes are not enough. Let's check the following code. void foo() { double var = 2.7; var++; } Using the changed tcc will generate following machine code: .text:08000000 public foo .text:08000000 foo proc near .text:08000000 .text:08000000 var_18 = qword ptr -18h .text:08000000 var_10 = qword ptr -10h .text:08000000 var_8 = qword ptr -8 .text:08000000 .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 18h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fst [ebp+var_18] .text:08000020 fstp st(0) .text:08000022 fld L_1 .text:08000028 fadd [ebp+var_10] .text:0800002B fst [ebp+var_8] .text:0800002E fstp st(0) .text:08000030 leave .text:08000031 retn .text:08000031 foo endp .text:08000031 .text:08000031 _text ends -------------------------------------------------- .data:08000040 ; Segment type: Pure data .data:08000040 ; Segment permissions: Read/Write .data:08000040 ; Segment alignment '32byte' can not be represented in assembly .data:08000040 _data segment page public 'DATA' use32 .data:08000040 assume cs:_data .data:08000040 ;org 8000040h .data:08000040 L_0 dq 400599999999999Ah .data:08000048 L_1 dq 3FF0000000000000h .data:08000048 _data ends Please notice the code snippet from 0800000A to 08000020 // double var = 2.7; load constant to st(0) .text:0800000A fld L_0 // double var = 2.7; store st(0) to `var' .text:08000010 fst [ebp+var_8] // double var = 2.7; poping st(0) will empty the floating registers stack .text:08000013 fstp st(0) After that ,tcc will call `void inc(int post, int c)" in tccgen.c:2150, and produce 08000015 to 0800001B through the calling chain (inc ->gv_dup) // load from `var' to st(0) .text:08000015 fld [ebp+var_8] // store st(0) to a temporary location .text:08000018 fst [ebp+var_10] // poping st(0) will empty the floating registers stack .text:0800001B fstp st(0) And the calling chain (gen_op('+')->gen_opif('+')->gen_opf('+')->gv(rc=2)->get_reg(rc=2)->save_reg(r=3)) will produce 0800001D to 08000020 . // store st(0) to a temporary location, but floating stack is empty! .text:0800001D fst [ebp+var_18] // poping st(0) will empty the floating registers stack .text:08000020 fstp st(0) The `0800001D fst [ebp+var_18]' will store st(0) to a memory location, but st(0) is empty. That will cause FPU invalid operation exception(#IE). Why does tcc do that? Please read `gv_dup' called by `inc' carefully. Notice these lines: (1): r = gv(rc); (2): r1 = get_reg(rc); (3): sv.r = r; sv.c.ul = 0; (4) load(r1, &sv); /* move r to r1 */ (5) vdup(); /* duplicates value */ (6) vtop->r = r1; (1) let the vtop occupy TREG_ST0, and `r' will be TREG_ST0. (2) try to get a free floating register,but tcc assume there is only one, so it wil force vtop goto memory and assign `r1' with TREG_ST0. When executing (3), it will do nothing because `r' equals `r1'. (5) duplicates vtop. Then (6) let the new vtop occupy TREG_ST0, but this will cause problem because the old vtop has been moved to memory, so the new duplicated vtop does not reside in TREG_ST0 but also in memory after that. TREG_ST0 is not occupied but freely availabe now. `gen_op('+')' need at least one oprand in register, so it will incorrectly think TREG_ST0 is occupied by vtop and produce instructions(0800001D and 08000020) to store it to a temporary memory location. According program above, if `r' == `r1' it is impossible for the old vtop to still occupy the `r' register . And `load' will do nothing too at this condition. So the `gv_dup' can not promise the semantics that old vtop in one register and the new duplicated vtop in another register at the same time. I changed (6) to if (r != r1) { vtop->r = r1; } Then the new generated machine code will be : .text:08000000 push ebp .text:08000001 mov ebp, esp .text:08000003 sub esp, 10h .text:08000009 nop .text:0800000A fld L_0 .text:08000010 fst [ebp+var_8] .text:08000013 fstp st(0) .text:08000015 fld [ebp+var_8] .text:08000018 fst [ebp+var_10] .text:0800001B fstp st(0) .text:0800001D fld L_1 .text:08000023 fadd [ebp+var_10] .text:08000026 fst [ebp+var_8] .text:08000029 fstp st(0) .text:0800002B leave .text:0800002C retn It works well, and will clean the floating registers stack when return. Finally, I want to know there is any potential problem of this fixing ? soloist
2009-06-08 21:26:19 +04:00
if (r != r1)
vtop->r = r1;
2009-05-05 22:18:10 +04:00
}
}
#ifndef TCC_TARGET_X86_64
/* generate CPU independent (unsigned) long long operations */
void gen_opl(int op)
{
int t, a, b, op1, c, i;
int func;
unsigned short reg_iret = REG_IRET;
unsigned short reg_lret = REG_LRET;
SValue tmp;
switch(op) {
case '/':
case TOK_PDIV:
func = TOK___divdi3;
goto gen_func;
case TOK_UDIV:
func = TOK___udivdi3;
goto gen_func;
case '%':
func = TOK___moddi3;
goto gen_mod_func;
case TOK_UMOD:
func = TOK___umoddi3;
gen_mod_func:
#ifdef TCC_ARM_EABI
reg_iret = TREG_R2;
reg_lret = TREG_R3;
#endif
gen_func:
/* call generic long long function */
vpush_global_sym(&func_old_type, func);
vrott(3);
gfunc_call(2);
vpushi(0);
vtop->r = reg_iret;
vtop->r2 = reg_lret;
break;
case '^':
case '&':
case '|':
case '*':
case '+':
case '-':
t = vtop->type.t;
vswap();
lexpand();
vrotb(3);
lexpand();
/* stack: L1 H1 L2 H2 */
tmp = vtop[0];
vtop[0] = vtop[-3];
vtop[-3] = tmp;
tmp = vtop[-2];
vtop[-2] = vtop[-3];
vtop[-3] = tmp;
vswap();
/* stack: H1 H2 L1 L2 */
if (op == '*') {
vpushv(vtop - 1);
vpushv(vtop - 1);
gen_op(TOK_UMULL);
lexpand();
/* stack: H1 H2 L1 L2 ML MH */
for(i=0;i<4;i++)
vrotb(6);
/* stack: ML MH H1 H2 L1 L2 */
tmp = vtop[0];
vtop[0] = vtop[-2];
vtop[-2] = tmp;
/* stack: ML MH H1 L2 H2 L1 */
gen_op('*');
vrotb(3);
vrotb(3);
gen_op('*');
/* stack: ML MH M1 M2 */
gen_op('+');
gen_op('+');
} else if (op == '+' || op == '-') {
/* XXX: add non carry method too (for MIPS or alpha) */
if (op == '+')
op1 = TOK_ADDC1;
else
op1 = TOK_SUBC1;
gen_op(op1);
/* stack: H1 H2 (L1 op L2) */
vrotb(3);
vrotb(3);
gen_op(op1 + 1); /* TOK_xxxC2 */
} else {
gen_op(op);
/* stack: H1 H2 (L1 op L2) */
vrotb(3);
vrotb(3);
/* stack: (L1 op L2) H1 H2 */
gen_op(op);
/* stack: (L1 op L2) (H1 op H2) */
}
/* stack: L H */
lbuild(t);
break;
case TOK_SAR:
case TOK_SHR:
case TOK_SHL:
if ((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST) {
t = vtop[-1].type.t;
vswap();
lexpand();
vrotb(3);
/* stack: L H shift */
c = (int)vtop->c.i;
/* constant: simpler */
/* NOTE: all comments are for SHL. the other cases are
done by swaping words */
vpop();
if (op != TOK_SHL)
vswap();
if (c >= 32) {
/* stack: L H */
vpop();
if (c > 32) {
vpushi(c - 32);
gen_op(op);
}
if (op != TOK_SAR) {
vpushi(0);
} else {
gv_dup();
vpushi(31);
gen_op(TOK_SAR);
}
vswap();
} else {
vswap();
gv_dup();
/* stack: H L L */
vpushi(c);
gen_op(op);
vswap();
vpushi(32 - c);
if (op == TOK_SHL)
gen_op(TOK_SHR);
else
gen_op(TOK_SHL);
vrotb(3);
/* stack: L L H */
vpushi(c);
if (op == TOK_SHL)
gen_op(TOK_SHL);
else
gen_op(TOK_SHR);
gen_op('|');
}
if (op != TOK_SHL)
vswap();
lbuild(t);
} else {
/* XXX: should provide a faster fallback on x86 ? */
switch(op) {
case TOK_SAR:
func = TOK___ashrdi3;
goto gen_func;
case TOK_SHR:
func = TOK___lshrdi3;
goto gen_func;
case TOK_SHL:
func = TOK___ashldi3;
goto gen_func;
}
}
break;
default:
/* compare operations */
t = vtop->type.t;
vswap();
lexpand();
vrotb(3);
lexpand();
/* stack: L1 H1 L2 H2 */
tmp = vtop[-1];
vtop[-1] = vtop[-2];
vtop[-2] = tmp;
/* stack: L1 L2 H1 H2 */
/* compare high */
op1 = op;
/* when values are equal, we need to compare low words. since
the jump is inverted, we invert the test too. */
if (op1 == TOK_LT)
op1 = TOK_LE;
else if (op1 == TOK_GT)
op1 = TOK_GE;
else if (op1 == TOK_ULT)
op1 = TOK_ULE;
else if (op1 == TOK_UGT)
op1 = TOK_UGE;
a = 0;
b = 0;
gen_op(op1);
if (op1 != TOK_NE) {
a = gtst(1, 0);
}
if (op != TOK_EQ) {
/* generate non equal test */
/* XXX: NOT PORTABLE yet */
if (a == 0) {
b = gtst(0, 0);
} else {
#if defined(TCC_TARGET_I386)
b = psym(0x850f, 0);
#elif defined(TCC_TARGET_ARM)
b = ind;
o(0x1A000000 | encbranch(ind, 0, 1));
#elif defined(TCC_TARGET_C67)
error("not implemented");
#else
#error not supported
#endif
}
}
/* compare low. Always unsigned */
op1 = op;
if (op1 == TOK_LT)
op1 = TOK_ULT;
else if (op1 == TOK_LE)
op1 = TOK_ULE;
else if (op1 == TOK_GT)
op1 = TOK_UGT;
else if (op1 == TOK_GE)
op1 = TOK_UGE;
gen_op(op1);
a = gtst(1, a);
gsym(b);
vseti(VT_JMPI, a);
break;
}
}
#endif
/* handle integer constant optimizations and various machine
independent opt */
void gen_opic(int op)
{
int c1, c2, t1, t2, n;
SValue *v1, *v2;
long long l1, l2;
typedef unsigned long long U;
v1 = vtop - 1;
v2 = vtop;
t1 = v1->type.t & VT_BTYPE;
t2 = v2->type.t & VT_BTYPE;
if (t1 == VT_LLONG)
l1 = v1->c.ll;
else if (v1->type.t & VT_UNSIGNED)
l1 = v1->c.ui;
else
l1 = v1->c.i;
if (t2 == VT_LLONG)
l2 = v2->c.ll;
else if (v2->type.t & VT_UNSIGNED)
l2 = v2->c.ui;
else
l2 = v2->c.i;
/* currently, we cannot do computations with forward symbols */
c1 = (v1->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
c2 = (v2->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
if (c1 && c2) {
switch(op) {
case '+': l1 += l2; break;
case '-': l1 -= l2; break;
case '&': l1 &= l2; break;
case '^': l1 ^= l2; break;
case '|': l1 |= l2; break;
case '*': l1 *= l2; break;
case TOK_PDIV:
case '/':
case '%':
case TOK_UDIV:
case TOK_UMOD:
/* if division by zero, generate explicit division */
if (l2 == 0) {
if (const_wanted)
error("division by zero in constant");
goto general_case;
}
switch(op) {
default: l1 /= l2; break;
case '%': l1 %= l2; break;
case TOK_UDIV: l1 = (U)l1 / l2; break;
case TOK_UMOD: l1 = (U)l1 % l2; break;
}
break;
case TOK_SHL: l1 <<= l2; break;
case TOK_SHR: l1 = (U)l1 >> l2; break;
case TOK_SAR: l1 >>= l2; break;
/* tests */
case TOK_ULT: l1 = (U)l1 < (U)l2; break;
case TOK_UGE: l1 = (U)l1 >= (U)l2; break;
case TOK_EQ: l1 = l1 == l2; break;
case TOK_NE: l1 = l1 != l2; break;
case TOK_ULE: l1 = (U)l1 <= (U)l2; break;
case TOK_UGT: l1 = (U)l1 > (U)l2; break;
case TOK_LT: l1 = l1 < l2; break;
case TOK_GE: l1 = l1 >= l2; break;
case TOK_LE: l1 = l1 <= l2; break;
case TOK_GT: l1 = l1 > l2; break;
/* logical */
case TOK_LAND: l1 = l1 && l2; break;
case TOK_LOR: l1 = l1 || l2; break;
default:
goto general_case;
}
v1->c.ll = l1;
vtop--;
} else {
/* if commutative ops, put c2 as constant */
if (c1 && (op == '+' || op == '&' || op == '^' ||
op == '|' || op == '*')) {
vswap();
c2 = c1; //c = c1, c1 = c2, c2 = c;
l2 = l1; //l = l1, l1 = l2, l2 = l;
}
/* Filter out NOP operations like x*1, x-0, x&-1... */
if (c2 && (((op == '*' || op == '/' || op == TOK_UDIV ||
op == TOK_PDIV) &&
l2 == 1) ||
((op == '+' || op == '-' || op == '|' || op == '^' ||
op == TOK_SHL || op == TOK_SHR || op == TOK_SAR) &&
l2 == 0) ||
(op == '&' &&
l2 == -1))) {
/* nothing to do */
vtop--;
} else if (c2 && (op == '*' || op == TOK_PDIV || op == TOK_UDIV)) {
/* try to use shifts instead of muls or divs */
if (l2 > 0 && (l2 & (l2 - 1)) == 0) {
n = -1;
while (l2) {
l2 >>= 1;
n++;
}
vtop->c.ll = n;
if (op == '*')
op = TOK_SHL;
else if (op == TOK_PDIV)
op = TOK_SAR;
else
op = TOK_SHR;
}
goto general_case;
} else if (c2 && (op == '+' || op == '-') &&
2009-11-13 19:14:05 +03:00
(((vtop[-1].r & (VT_VALMASK | VT_LVAL | VT_SYM)) == (VT_CONST | VT_SYM)
&& !(vtop[-1].sym->type.t & VT_IMPORT))
||
2009-05-05 22:18:10 +04:00
(vtop[-1].r & (VT_VALMASK | VT_LVAL)) == VT_LOCAL)) {
/* symbol + constant case */
if (op == '-')
l2 = -l2;
vtop--;
vtop->c.ll += l2;
} else {
general_case:
if (!nocode_wanted) {
/* call low level op generator */
if (t1 == VT_LLONG || t2 == VT_LLONG)
gen_opl(op);
else
gen_opi(op);
} else {
vtop--;
}
}
}
}
/* generate a floating point operation with constant propagation */
void gen_opif(int op)
{
int c1, c2;
SValue *v1, *v2;
long double f1, f2;
v1 = vtop - 1;
v2 = vtop;
/* currently, we cannot do computations with forward symbols */
c1 = (v1->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
c2 = (v2->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
if (c1 && c2) {
if (v1->type.t == VT_FLOAT) {
f1 = v1->c.f;
f2 = v2->c.f;
} else if (v1->type.t == VT_DOUBLE) {
f1 = v1->c.d;
f2 = v2->c.d;
} else {
f1 = v1->c.ld;
f2 = v2->c.ld;
}
/* NOTE: we only do constant propagation if finite number (not
NaN or infinity) (ANSI spec) */
if (!ieee_finite(f1) || !ieee_finite(f2))
goto general_case;
switch(op) {
case '+': f1 += f2; break;
case '-': f1 -= f2; break;
case '*': f1 *= f2; break;
case '/':
if (f2 == 0.0) {
if (const_wanted)
error("division by zero in constant");
goto general_case;
}
f1 /= f2;
break;
/* XXX: also handles tests ? */
default:
goto general_case;
}
/* XXX: overflow test ? */
if (v1->type.t == VT_FLOAT) {
v1->c.f = f1;
} else if (v1->type.t == VT_DOUBLE) {
v1->c.d = f1;
} else {
v1->c.ld = f1;
}
vtop--;
} else {
general_case:
if (!nocode_wanted) {
gen_opf(op);
} else {
vtop--;
}
}
}
static int pointed_size(CType *type)
{
int align;
return type_size(pointed_type(type), &align);
}
static inline int is_null_pointer(SValue *p)
{
if ((p->r & (VT_VALMASK | VT_LVAL | VT_SYM)) != VT_CONST)
return 0;
return ((p->type.t & VT_BTYPE) == VT_INT && p->c.i == 0) ||
((p->type.t & VT_BTYPE) == VT_LLONG && p->c.ll == 0);
}
static inline int is_integer_btype(int bt)
{
return (bt == VT_BYTE || bt == VT_SHORT ||
bt == VT_INT || bt == VT_LLONG);
}
/* check types for comparison or substraction of pointers */
static void check_comparison_pointer_types(SValue *p1, SValue *p2, int op)
{
CType *type1, *type2, tmp_type1, tmp_type2;
int bt1, bt2;
/* null pointers are accepted for all comparisons as gcc */
if (is_null_pointer(p1) || is_null_pointer(p2))
return;
type1 = &p1->type;
type2 = &p2->type;
bt1 = type1->t & VT_BTYPE;
bt2 = type2->t & VT_BTYPE;
/* accept comparison between pointer and integer with a warning */
if ((is_integer_btype(bt1) || is_integer_btype(bt2)) && op != '-') {
if (op != TOK_LOR && op != TOK_LAND )
warning("comparison between pointer and integer");
return;
}
/* both must be pointers or implicit function pointers */
if (bt1 == VT_PTR) {
type1 = pointed_type(type1);
} else if (bt1 != VT_FUNC)
goto invalid_operands;
if (bt2 == VT_PTR) {
type2 = pointed_type(type2);
} else if (bt2 != VT_FUNC) {
invalid_operands:
error("invalid operands to binary %s", get_tok_str(op, NULL));
}
if ((type1->t & VT_BTYPE) == VT_VOID ||
(type2->t & VT_BTYPE) == VT_VOID)
return;
tmp_type1 = *type1;
tmp_type2 = *type2;
tmp_type1.t &= ~(VT_UNSIGNED | VT_CONSTANT | VT_VOLATILE);
tmp_type2.t &= ~(VT_UNSIGNED | VT_CONSTANT | VT_VOLATILE);
if (!is_compatible_types(&tmp_type1, &tmp_type2)) {
/* gcc-like error if '-' is used */
if (op == '-')
goto invalid_operands;
else
warning("comparison of distinct pointer types lacks a cast");
}
}
/* generic gen_op: handles types problems */
void gen_op(int op)
{
int u, t1, t2, bt1, bt2, t;
CType type1;
t1 = vtop[-1].type.t;
t2 = vtop[0].type.t;
bt1 = t1 & VT_BTYPE;
bt2 = t2 & VT_BTYPE;
if (bt1 == VT_PTR || bt2 == VT_PTR) {
/* at least one operand is a pointer */
/* relationnal op: must be both pointers */
if (op >= TOK_ULT && op <= TOK_LOR) {
check_comparison_pointer_types(vtop - 1, vtop, op);
/* pointers are handled are unsigned */
#ifdef TCC_TARGET_X86_64
t = VT_LLONG | VT_UNSIGNED;
#else
t = VT_INT | VT_UNSIGNED;
#endif
goto std_op;
}
/* if both pointers, then it must be the '-' op */
if (bt1 == VT_PTR && bt2 == VT_PTR) {
if (op != '-')
error("cannot use pointers here");
check_comparison_pointer_types(vtop - 1, vtop, op);
/* XXX: check that types are compatible */
u = pointed_size(&vtop[-1].type);
gen_opic(op);
/* set to integer type */
#ifdef TCC_TARGET_X86_64
vtop->type.t = VT_LLONG;
#else
vtop->type.t = VT_INT;
#endif
vpushi(u);
gen_op(TOK_PDIV);
} else {
/* exactly one pointer : must be '+' or '-'. */
if (op != '-' && op != '+')
error("cannot use pointers here");
/* Put pointer as first operand */
if (bt2 == VT_PTR) {
vswap();
swap(&t1, &t2);
}
type1 = vtop[-1].type;
type1.t &= ~VT_ARRAY;
2009-05-05 22:18:10 +04:00
#ifdef TCC_TARGET_X86_64
vpushll(pointed_size(&vtop[-1].type));
#else
/* XXX: cast to int ? (long long case) */
vpushi(pointed_size(&vtop[-1].type));
#endif
gen_op('*');
#ifdef CONFIG_TCC_BCHECK
/* if evaluating constant expression, no code should be
generated, so no bound check */
if (tcc_state->do_bounds_check && !const_wanted) {
2009-05-05 22:18:10 +04:00
/* if bounded pointers, we generate a special code to
test bounds */
if (op == '-') {
vpushi(0);
vswap();
gen_op('-');
}
gen_bounded_ptr_add();
} else
#endif
{
gen_opic(op);
}
/* put again type if gen_opic() swaped operands */
vtop->type = type1;
}
} else if (is_float(bt1) || is_float(bt2)) {
/* compute bigger type and do implicit casts */
if (bt1 == VT_LDOUBLE || bt2 == VT_LDOUBLE) {
t = VT_LDOUBLE;
} else if (bt1 == VT_DOUBLE || bt2 == VT_DOUBLE) {
t = VT_DOUBLE;
} else {
t = VT_FLOAT;
}
/* floats can only be used for a few operations */
if (op != '+' && op != '-' && op != '*' && op != '/' &&
(op < TOK_ULT || op > TOK_GT))
error("invalid operands for binary operation");
goto std_op;
} else if (bt1 == VT_LLONG || bt2 == VT_LLONG) {
/* cast to biggest op */
t = VT_LLONG;
/* convert to unsigned if it does not fit in a long long */
if ((t1 & (VT_BTYPE | VT_UNSIGNED)) == (VT_LLONG | VT_UNSIGNED) ||
(t2 & (VT_BTYPE | VT_UNSIGNED)) == (VT_LLONG | VT_UNSIGNED))
t |= VT_UNSIGNED;
goto std_op;
} else {
/* integer operations */
t = VT_INT;
/* convert to unsigned if it does not fit in an integer */
if ((t1 & (VT_BTYPE | VT_UNSIGNED)) == (VT_INT | VT_UNSIGNED) ||
(t2 & (VT_BTYPE | VT_UNSIGNED)) == (VT_INT | VT_UNSIGNED))
t |= VT_UNSIGNED;
std_op:
/* XXX: currently, some unsigned operations are explicit, so
we modify them here */
if (t & VT_UNSIGNED) {
if (op == TOK_SAR)
op = TOK_SHR;
else if (op == '/')
op = TOK_UDIV;
else if (op == '%')
op = TOK_UMOD;
else if (op == TOK_LT)
op = TOK_ULT;
else if (op == TOK_GT)
op = TOK_UGT;
else if (op == TOK_LE)
op = TOK_ULE;
else if (op == TOK_GE)
op = TOK_UGE;
}
vswap();
type1.t = t;
gen_cast(&type1);
vswap();
/* special case for shifts and long long: we keep the shift as
an integer */
if (op == TOK_SHR || op == TOK_SAR || op == TOK_SHL)
type1.t = VT_INT;
gen_cast(&type1);
if (is_float(t))
gen_opif(op);
else
gen_opic(op);
if (op >= TOK_ULT && op <= TOK_GT) {
/* relationnal op: the result is an int */
vtop->type.t = VT_INT;
} else {
vtop->type.t = t;
}
}
}
#ifndef TCC_TARGET_ARM
/* generic itof for unsigned long long case */
void gen_cvt_itof1(int t)
{
if ((vtop->type.t & (VT_BTYPE | VT_UNSIGNED)) ==
(VT_LLONG | VT_UNSIGNED)) {
if (t == VT_FLOAT)
vpush_global_sym(&func_old_type, TOK___floatundisf);
#if LDOUBLE_SIZE != 8
else if (t == VT_LDOUBLE)
vpush_global_sym(&func_old_type, TOK___floatundixf);
#endif
else
vpush_global_sym(&func_old_type, TOK___floatundidf);
vrott(2);
gfunc_call(1);
vpushi(0);
vtop->r = reg_fret(t);
} else {
gen_cvt_itof(t);
}
}
#endif
/* generic ftoi for unsigned long long case */
void gen_cvt_ftoi1(int t)
{
int st;
if (t == (VT_LLONG | VT_UNSIGNED)) {
/* not handled natively */
st = vtop->type.t & VT_BTYPE;
if (st == VT_FLOAT)
vpush_global_sym(&func_old_type, TOK___fixunssfdi);
#if LDOUBLE_SIZE != 8
else if (st == VT_LDOUBLE)
vpush_global_sym(&func_old_type, TOK___fixunsxfdi);
#endif
else
vpush_global_sym(&func_old_type, TOK___fixunsdfdi);
vrott(2);
gfunc_call(1);
vpushi(0);
vtop->r = REG_IRET;
vtop->r2 = REG_LRET;
} else {
gen_cvt_ftoi(t);
}
}
/* force char or short cast */
void force_charshort_cast(int t)
{
int bits, dbt;
dbt = t & VT_BTYPE;
/* XXX: add optimization if lvalue : just change type and offset */
if (dbt == VT_BYTE)
bits = 8;
else
bits = 16;
if (t & VT_UNSIGNED) {
vpushi((1 << bits) - 1);
gen_op('&');
} else {
bits = 32 - bits;
vpushi(bits);
gen_op(TOK_SHL);
/* result must be signed or the SAR is converted to an SHL
This was not the case when "t" was a signed short
and the last value on the stack was an unsigned int */
vtop->type.t &= ~VT_UNSIGNED;
vpushi(bits);
gen_op(TOK_SAR);
}
}
/* cast 'vtop' to 'type'. Casting to bitfields is forbidden. */
static void gen_cast(CType *type)
{
int sbt, dbt, sf, df, c, p;
/* special delayed cast for char/short */
/* XXX: in some cases (multiple cascaded casts), it may still
be incorrect */
if (vtop->r & VT_MUSTCAST) {
vtop->r &= ~VT_MUSTCAST;
force_charshort_cast(vtop->type.t);
}
/* bitfields first get cast to ints */
if (vtop->type.t & VT_BITFIELD) {
gv(RC_INT);
}
dbt = type->t & (VT_BTYPE | VT_UNSIGNED);
sbt = vtop->type.t & (VT_BTYPE | VT_UNSIGNED);
if (sbt != dbt) {
sf = is_float(sbt);
df = is_float(dbt);
c = (vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
p = (vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == (VT_CONST | VT_SYM);
if (c) {
/* constant case: we can do it now */
/* XXX: in ISOC, cannot do it if error in convert */
if (sbt == VT_FLOAT)
vtop->c.ld = vtop->c.f;
else if (sbt == VT_DOUBLE)
vtop->c.ld = vtop->c.d;
if (df) {
if ((sbt & VT_BTYPE) == VT_LLONG) {
if (sbt & VT_UNSIGNED)
vtop->c.ld = vtop->c.ull;
else
vtop->c.ld = vtop->c.ll;
} else if(!sf) {
if (sbt & VT_UNSIGNED)
vtop->c.ld = vtop->c.ui;
else
vtop->c.ld = vtop->c.i;
}
if (dbt == VT_FLOAT)
vtop->c.f = (float)vtop->c.ld;
else if (dbt == VT_DOUBLE)
vtop->c.d = (double)vtop->c.ld;
} else if (sf && dbt == (VT_LLONG|VT_UNSIGNED)) {
vtop->c.ull = (unsigned long long)vtop->c.ld;
} else if (sf && dbt == VT_BOOL) {
vtop->c.i = (vtop->c.ld != 0);
} else {
if(sf)
vtop->c.ll = (long long)vtop->c.ld;
else if (sbt == (VT_LLONG|VT_UNSIGNED))
vtop->c.ll = vtop->c.ull;
else if (sbt & VT_UNSIGNED)
vtop->c.ll = vtop->c.ui;
#ifdef TCC_TARGET_X86_64
else if (sbt == VT_PTR)
;
#endif
2009-05-05 22:18:10 +04:00
else if (sbt != VT_LLONG)
vtop->c.ll = vtop->c.i;
if (dbt == (VT_LLONG|VT_UNSIGNED))
vtop->c.ull = vtop->c.ll;
else if (dbt == VT_BOOL)
vtop->c.i = (vtop->c.ll != 0);
else if (dbt != VT_LLONG) {
int s = 0;
if ((dbt & VT_BTYPE) == VT_BYTE)
s = 24;
else if ((dbt & VT_BTYPE) == VT_SHORT)
s = 16;
if(dbt & VT_UNSIGNED)
vtop->c.ui = ((unsigned int)vtop->c.ll << s) >> s;
else
vtop->c.i = ((int)vtop->c.ll << s) >> s;
}
}
} else if (p && dbt == VT_BOOL) {
vtop->r = VT_CONST;
vtop->c.i = 1;
} else if (!nocode_wanted) {
/* non constant case: generate code */
if (sf && df) {
/* convert from fp to fp */
gen_cvt_ftof(dbt);
} else if (df) {
/* convert int to fp */
gen_cvt_itof1(dbt);
} else if (sf) {
/* convert fp to int */
if (dbt == VT_BOOL) {
vpushi(0);
gen_op(TOK_NE);
} else {
/* we handle char/short/etc... with generic code */
if (dbt != (VT_INT | VT_UNSIGNED) &&
dbt != (VT_LLONG | VT_UNSIGNED) &&
dbt != VT_LLONG)
dbt = VT_INT;
gen_cvt_ftoi1(dbt);
if (dbt == VT_INT && (type->t & (VT_BTYPE | VT_UNSIGNED)) != dbt) {
/* additional cast for char/short... */
vtop->type.t = dbt;
gen_cast(type);
}
}
#ifndef TCC_TARGET_X86_64
} else if ((dbt & VT_BTYPE) == VT_LLONG) {
if ((sbt & VT_BTYPE) != VT_LLONG) {
/* scalar to long long */
/* machine independent conversion */
gv(RC_INT);
/* generate high word */
if (sbt == (VT_INT | VT_UNSIGNED)) {
vpushi(0);
gv(RC_INT);
} else {
if (sbt == VT_PTR) {
/* cast from pointer to int before we apply
shift operation, which pointers don't support*/
gen_cast(&int_type);
}
gv_dup();
vpushi(31);
gen_op(TOK_SAR);
}
/* patch second register */
vtop[-1].r2 = vtop->r;
vpop();
}
#else
} else if ((dbt & VT_BTYPE) == VT_LLONG ||
(dbt & VT_BTYPE) == VT_PTR) {
/* XXX: not sure if this is perfect... need more tests */
if ((sbt & VT_BTYPE) != VT_LLONG) {
int r = gv(RC_INT);
if (sbt != (VT_INT | VT_UNSIGNED) &&
sbt != VT_PTR && sbt != VT_FUNC) {
/* x86_64 specific: movslq */
o(0x6348);
o(0xc0 + (REG_VALUE(r) << 3) + REG_VALUE(r));
}
}
#endif
} else if (dbt == VT_BOOL) {
/* scalar to bool */
vpushi(0);
gen_op(TOK_NE);
} else if ((dbt & VT_BTYPE) == VT_BYTE ||
(dbt & VT_BTYPE) == VT_SHORT) {
if (sbt == VT_PTR) {
vtop->type.t = VT_INT;
warning("nonportable conversion from pointer to char/short");
}
force_charshort_cast(dbt);
} else if ((dbt & VT_BTYPE) == VT_INT) {
/* scalar to int */
if (sbt == VT_LLONG) {
/* from long long: just take low order word */
lexpand();
vpop();
}
/* if lvalue and single word type, nothing to do because
the lvalue already contains the real type size (see
VT_LVAL_xxx constants) */
}
}
} else if ((dbt & VT_BTYPE) == VT_PTR && !(vtop->r & VT_LVAL)) {
/* if we are casting between pointer types,
we must update the VT_LVAL_xxx size */
vtop->r = (vtop->r & ~VT_LVAL_TYPE)
| (lvalue_type(type->ref->type.t) & VT_LVAL_TYPE);
}
vtop->type = *type;
}
/* return type size. Put alignment at 'a' */
static int type_size(CType *type, int *a)
{
Sym *s;
int bt;
bt = type->t & VT_BTYPE;
if (bt == VT_STRUCT) {
/* struct/union */
s = type->ref;
*a = s->r;
return s->c;
} else if (bt == VT_PTR) {
if (type->t & VT_ARRAY) {
int ts;
s = type->ref;
ts = type_size(&s->type, a);
if (ts < 0 && s->c < 0)
ts = -ts;
return ts * s->c;
} else {
*a = PTR_SIZE;
return PTR_SIZE;
}
} else if (bt == VT_LDOUBLE) {
*a = LDOUBLE_ALIGN;
return LDOUBLE_SIZE;
} else if (bt == VT_DOUBLE || bt == VT_LLONG) {
#ifdef TCC_TARGET_I386
#ifdef TCC_TARGET_PE
*a = 8;
#else
*a = 4;
#endif
#elif defined(TCC_TARGET_ARM)
#ifdef TCC_ARM_EABI
*a = 8;
#else
*a = 4;
#endif
#else
*a = 8;
#endif
return 8;
} else if (bt == VT_INT || bt == VT_ENUM || bt == VT_FLOAT) {
*a = 4;
return 4;
} else if (bt == VT_SHORT) {
*a = 2;
return 2;
} else {
/* char, void, function, _Bool */
*a = 1;
return 1;
}
}
/* return the pointed type of t */
static inline CType *pointed_type(CType *type)
{
return &type->ref->type;
}
/* modify type so that its it is a pointer to type. */
static void mk_pointer(CType *type)
{
Sym *s;
s = sym_push(SYM_FIELD, type, 0, -1);
type->t = VT_PTR | (type->t & ~VT_TYPE);
type->ref = s;
}
/* compare function types. OLD functions match any new functions */
static int is_compatible_func(CType *type1, CType *type2)
{
Sym *s1, *s2;
s1 = type1->ref;
s2 = type2->ref;
if (!is_compatible_types(&s1->type, &s2->type))
return 0;
/* check func_call */
if (FUNC_CALL(s1->r) != FUNC_CALL(s2->r))
return 0;
/* XXX: not complete */
if (s1->c == FUNC_OLD || s2->c == FUNC_OLD)
return 1;
if (s1->c != s2->c)
return 0;
while (s1 != NULL) {
if (s2 == NULL)
return 0;
if (!is_compatible_parameter_types(&s1->type, &s2->type))
return 0;
s1 = s1->next;
s2 = s2->next;
}
if (s2)
return 0;
return 1;
}
/* return true if type1 and type2 are the same. If unqualified is
true, qualifiers on the types are ignored.
- enums are not checked as gcc __builtin_types_compatible_p ()
*/
static int compare_types(CType *type1, CType *type2, int unqualified)
{
int bt1, t1, t2;
t1 = type1->t & VT_TYPE;
t2 = type2->t & VT_TYPE;
if (unqualified) {
/* strip qualifiers before comparing */
t1 &= ~(VT_CONSTANT | VT_VOLATILE);
t2 &= ~(VT_CONSTANT | VT_VOLATILE);
}
/* XXX: bitfields ? */
if (t1 != t2)
return 0;
/* test more complicated cases */
bt1 = t1 & VT_BTYPE;
if (bt1 == VT_PTR) {
type1 = pointed_type(type1);
type2 = pointed_type(type2);
return is_compatible_types(type1, type2);
} else if (bt1 == VT_STRUCT) {
return (type1->ref == type2->ref);
} else if (bt1 == VT_FUNC) {
return is_compatible_func(type1, type2);
} else {
return 1;
}
}
/* return true if type1 and type2 are exactly the same (including
qualifiers).
*/
static int is_compatible_types(CType *type1, CType *type2)
{
return compare_types(type1,type2,0);
}
/* return true if type1 and type2 are the same (ignoring qualifiers).
*/
static int is_compatible_parameter_types(CType *type1, CType *type2)
{
return compare_types(type1,type2,1);
}
/* print a type. If 'varstr' is not NULL, then the variable is also
printed in the type */
/* XXX: union */
/* XXX: add array and function pointers */
void type_to_str(char *buf, int buf_size,
CType *type, const char *varstr)
{
int bt, v, t;
Sym *s, *sa;
char buf1[256];
const char *tstr;
t = type->t & VT_TYPE;
bt = t & VT_BTYPE;
buf[0] = '\0';
if (t & VT_CONSTANT)
pstrcat(buf, buf_size, "const ");
if (t & VT_VOLATILE)
pstrcat(buf, buf_size, "volatile ");
if (t & VT_UNSIGNED)
pstrcat(buf, buf_size, "unsigned ");
switch(bt) {
case VT_VOID:
tstr = "void";
goto add_tstr;
case VT_BOOL:
tstr = "_Bool";
goto add_tstr;
case VT_BYTE:
tstr = "char";
goto add_tstr;
case VT_SHORT:
tstr = "short";
goto add_tstr;
case VT_INT:
tstr = "int";
goto add_tstr;
case VT_LONG:
tstr = "long";
goto add_tstr;
case VT_LLONG:
tstr = "long long";
goto add_tstr;
case VT_FLOAT:
tstr = "float";
goto add_tstr;
case VT_DOUBLE:
tstr = "double";
goto add_tstr;
case VT_LDOUBLE:
tstr = "long double";
add_tstr:
pstrcat(buf, buf_size, tstr);
break;
case VT_ENUM:
case VT_STRUCT:
if (bt == VT_STRUCT)
tstr = "struct ";
else
tstr = "enum ";
pstrcat(buf, buf_size, tstr);
v = type->ref->v & ~SYM_STRUCT;
if (v >= SYM_FIRST_ANOM)
pstrcat(buf, buf_size, "<anonymous>");
else
pstrcat(buf, buf_size, get_tok_str(v, NULL));
break;
case VT_FUNC:
s = type->ref;
type_to_str(buf, buf_size, &s->type, varstr);
pstrcat(buf, buf_size, "(");
sa = s->next;
while (sa != NULL) {
type_to_str(buf1, sizeof(buf1), &sa->type, NULL);
pstrcat(buf, buf_size, buf1);
sa = sa->next;
if (sa)
pstrcat(buf, buf_size, ", ");
}
pstrcat(buf, buf_size, ")");
goto no_var;
case VT_PTR:
s = type->ref;
pstrcpy(buf1, sizeof(buf1), "*");
if (varstr)
pstrcat(buf1, sizeof(buf1), varstr);
type_to_str(buf, buf_size, &s->type, buf1);
goto no_var;
}
if (varstr) {
pstrcat(buf, buf_size, " ");
pstrcat(buf, buf_size, varstr);
}
no_var: ;
}
/* verify type compatibility to store vtop in 'dt' type, and generate
casts if needed. */
static void gen_assign_cast(CType *dt)
{
CType *st, *type1, *type2, tmp_type1, tmp_type2;
char buf1[256], buf2[256];
int dbt, sbt;
st = &vtop->type; /* source type */
dbt = dt->t & VT_BTYPE;
sbt = st->t & VT_BTYPE;
if (dt->t & VT_CONSTANT)
warning("assignment of read-only location");
switch(dbt) {
case VT_PTR:
/* special cases for pointers */
/* '0' can also be a pointer */
if (is_null_pointer(vtop))
goto type_ok;
/* accept implicit pointer to integer cast with warning */
if (is_integer_btype(sbt)) {
warning("assignment makes pointer from integer without a cast");
goto type_ok;
}
type1 = pointed_type(dt);
/* a function is implicitely a function pointer */
if (sbt == VT_FUNC) {
if ((type1->t & VT_BTYPE) != VT_VOID &&
!is_compatible_types(pointed_type(dt), st))
warning("assignment from incompatible pointer type");
goto type_ok;
2009-05-05 22:18:10 +04:00
}
if (sbt != VT_PTR)
goto error;
type2 = pointed_type(st);
if ((type1->t & VT_BTYPE) == VT_VOID ||
(type2->t & VT_BTYPE) == VT_VOID) {
/* void * can match anything */
} else {
/* exact type match, except for unsigned */
tmp_type1 = *type1;
tmp_type2 = *type2;
tmp_type1.t &= ~(VT_UNSIGNED | VT_CONSTANT | VT_VOLATILE);
tmp_type2.t &= ~(VT_UNSIGNED | VT_CONSTANT | VT_VOLATILE);
if (!is_compatible_types(&tmp_type1, &tmp_type2))
warning("assignment from incompatible pointer type");
}
/* check const and volatile */
if ((!(type1->t & VT_CONSTANT) && (type2->t & VT_CONSTANT)) ||
(!(type1->t & VT_VOLATILE) && (type2->t & VT_VOLATILE)))
warning("assignment discards qualifiers from pointer target type");
break;
case VT_BYTE:
case VT_SHORT:
case VT_INT:
case VT_LLONG:
if (sbt == VT_PTR || sbt == VT_FUNC) {
warning("assignment makes integer from pointer without a cast");
}
/* XXX: more tests */
break;
case VT_STRUCT:
tmp_type1 = *dt;
tmp_type2 = *st;
tmp_type1.t &= ~(VT_CONSTANT | VT_VOLATILE);
tmp_type2.t &= ~(VT_CONSTANT | VT_VOLATILE);
if (!is_compatible_types(&tmp_type1, &tmp_type2)) {
error:
type_to_str(buf1, sizeof(buf1), st, NULL);
type_to_str(buf2, sizeof(buf2), dt, NULL);
error("cannot cast '%s' to '%s'", buf1, buf2);
}
break;
}
type_ok:
gen_cast(dt);
}
/* store vtop in lvalue pushed on stack */
void vstore(void)
{
int sbt, dbt, ft, r, t, size, align, bit_size, bit_pos, rc, delayed_cast;
ft = vtop[-1].type.t;
sbt = vtop->type.t & VT_BTYPE;
dbt = ft & VT_BTYPE;
if (((sbt == VT_INT || sbt == VT_SHORT) && dbt == VT_BYTE) ||
(sbt == VT_INT && dbt == VT_SHORT)) {
/* optimize char/short casts */
delayed_cast = VT_MUSTCAST;
vtop->type.t = ft & (VT_TYPE & ~(VT_BITFIELD | (-1 << VT_STRUCT_SHIFT)));
/* XXX: factorize */
if (ft & VT_CONSTANT)
warning("assignment of read-only location");
} else {
delayed_cast = 0;
if (!(ft & VT_BITFIELD))
gen_assign_cast(&vtop[-1].type);
}
if (sbt == VT_STRUCT) {
/* if structure, only generate pointer */
/* structure assignment : generate memcpy */
/* XXX: optimize if small size */
if (!nocode_wanted) {
size = type_size(&vtop->type, &align);
/* destination */
vswap();
vtop->type.t = VT_PTR;
gaddrof();
/* address of memcpy() */
2009-05-05 22:18:10 +04:00
#ifdef TCC_ARM_EABI
if(!(align & 7))
vpush_global_sym(&func_old_type, TOK_memcpy8);
else if(!(align & 3))
vpush_global_sym(&func_old_type, TOK_memcpy4);
else
#endif
vpush_global_sym(&func_old_type, TOK_memcpy);
vswap();
2009-05-05 22:18:10 +04:00
/* source */
vpushv(vtop - 2);
vtop->type.t = VT_PTR;
gaddrof();
/* type size */
vpushi(size);
gfunc_call(3);
} else {
vswap();
vpop();
}
/* leave source on stack */
} else if (ft & VT_BITFIELD) {
/* bitfield store handling */
bit_pos = (ft >> VT_STRUCT_SHIFT) & 0x3f;
bit_size = (ft >> (VT_STRUCT_SHIFT + 6)) & 0x3f;
/* remove bit field info to avoid loops */
vtop[-1].type.t = ft & ~(VT_BITFIELD | (-1 << VT_STRUCT_SHIFT));
/* duplicate source into other register */
gv_dup();
vswap();
vrott(3);
if((ft & VT_BTYPE) == VT_BOOL) {
gen_cast(&vtop[-1].type);
vtop[-1].type.t = (vtop[-1].type.t & ~VT_BTYPE) | (VT_BYTE | VT_UNSIGNED);
}
/* duplicate destination */
vdup();
vtop[-1] = vtop[-2];
/* mask and shift source */
if((ft & VT_BTYPE) != VT_BOOL) {
if((ft & VT_BTYPE) == VT_LLONG) {
vpushll((1ULL << bit_size) - 1ULL);
} else {
vpushi((1 << bit_size) - 1);
}
gen_op('&');
}
vpushi(bit_pos);
gen_op(TOK_SHL);
/* load destination, mask and or with source */
vswap();
if((ft & VT_BTYPE) == VT_LLONG) {
vpushll(~(((1ULL << bit_size) - 1ULL) << bit_pos));
} else {
vpushi(~(((1 << bit_size) - 1) << bit_pos));
}
gen_op('&');
gen_op('|');
/* store result */
vstore();
/* pop off shifted source from "duplicate source..." above */
vpop();
} else {
#ifdef CONFIG_TCC_BCHECK
/* bound check case */
if (vtop[-1].r & VT_MUSTBOUND) {
vswap();
gbound();
vswap();
}
#endif
if (!nocode_wanted) {
rc = RC_INT;
if (is_float(ft)) {
rc = RC_FLOAT;
#ifdef TCC_TARGET_X86_64
if ((ft & VT_BTYPE) == VT_LDOUBLE) {
rc = RC_ST0;
}
#endif
}
r = gv(rc); /* generate value */
/* if lvalue was saved on stack, must read it */
if ((vtop[-1].r & VT_VALMASK) == VT_LLOCAL) {
SValue sv;
t = get_reg(RC_INT);
#ifdef TCC_TARGET_X86_64
sv.type.t = VT_PTR;
#else
sv.type.t = VT_INT;
#endif
sv.r = VT_LOCAL | VT_LVAL;
sv.c.ul = vtop[-1].c.ul;
load(t, &sv);
vtop[-1].r = t | VT_LVAL;
}
store(r, vtop - 1);
#ifndef TCC_TARGET_X86_64
/* two word case handling : store second register at word + 4 */
if ((ft & VT_BTYPE) == VT_LLONG) {
vswap();
/* convert to int to increment easily */
vtop->type.t = VT_INT;
gaddrof();
vpushi(4);
gen_op('+');
vtop->r |= VT_LVAL;
vswap();
/* XXX: it works because r2 is spilled last ! */
store(vtop->r2, vtop - 1);
}
#endif
}
vswap();
vtop--; /* NOT vpop() because on x86 it would flush the fp stack */
vtop->r |= delayed_cast;
}
}
/* post defines POST/PRE add. c is the token ++ or -- */
void inc(int post, int c)
{
test_lvalue();
vdup(); /* save lvalue */
if (post) {
gv_dup(); /* duplicate value */
vrotb(3);
vrotb(3);
}
/* add constant */
vpushi(c - TOK_MID);
gen_op('+');
vstore(); /* store value */
if (post)
vpop(); /* if post op, return saved value */
}
/* Parse GNUC __attribute__ extension. Currently, the following
extensions are recognized:
- aligned(n) : set data/function alignment.
- packed : force data alignment to 1
- section(x) : generate data/code in this section.
- unused : currently ignored, but may be used someday.
- regparm(n) : pass function parameters in registers (i386 only)
*/
static void parse_attribute(AttributeDef *ad)
{
int t, n;
while (tok == TOK_ATTRIBUTE1 || tok == TOK_ATTRIBUTE2) {
next();
skip('(');
skip('(');
while (tok != ')') {
if (tok < TOK_IDENT)
expect("attribute name");
t = tok;
next();
switch(t) {
case TOK_SECTION1:
case TOK_SECTION2:
skip('(');
if (tok != TOK_STR)
expect("section name");
ad->section = find_section(tcc_state, (char *)tokc.cstr->data);
next();
skip(')');
break;
case TOK_ALIGNED1:
case TOK_ALIGNED2:
if (tok == '(') {
next();
n = expr_const();
if (n <= 0 || (n & (n - 1)) != 0)
error("alignment must be a positive power of two");
skip(')');
} else {
n = MAX_ALIGN;
}
ad->aligned = n;
break;
case TOK_PACKED1:
case TOK_PACKED2:
ad->packed = 1;
break;
case TOK_UNUSED1:
case TOK_UNUSED2:
/* currently, no need to handle it because tcc does not
track unused objects */
break;
case TOK_NORETURN1:
case TOK_NORETURN2:
/* currently, no need to handle it because tcc does not
track unused objects */
break;
case TOK_CDECL1:
case TOK_CDECL2:
case TOK_CDECL3:
ad->func_call = FUNC_CDECL;
2009-05-05 22:18:10 +04:00
break;
case TOK_STDCALL1:
case TOK_STDCALL2:
case TOK_STDCALL3:
ad->func_call = FUNC_STDCALL;
2009-05-05 22:18:10 +04:00
break;
#ifdef TCC_TARGET_I386
case TOK_REGPARM1:
case TOK_REGPARM2:
skip('(');
n = expr_const();
if (n > 3)
n = 3;
else if (n < 0)
n = 0;
if (n > 0)
ad->func_call = FUNC_FASTCALL1 + n - 1;
2009-05-05 22:18:10 +04:00
skip(')');
break;
case TOK_FASTCALL1:
case TOK_FASTCALL2:
case TOK_FASTCALL3:
ad->func_call = FUNC_FASTCALLW;
2009-05-05 22:18:10 +04:00
break;
#endif
case TOK_DLLEXPORT:
ad->func_export = 1;
2009-05-05 22:18:10 +04:00
break;
2009-11-13 19:14:05 +03:00
case TOK_DLLIMPORT:
ad->func_import = 1;
2009-11-13 19:14:05 +03:00
break;
2009-05-05 22:18:10 +04:00
default:
if (tcc_state->warn_unsupported)
warning("'%s' attribute ignored", get_tok_str(t, NULL));
/* skip parameters */
if (tok == '(') {
int parenthesis = 0;
do {
if (tok == '(')
parenthesis++;
else if (tok == ')')
parenthesis--;
next();
} while (parenthesis && tok != -1);
}
break;
}
if (tok != ',')
break;
next();
}
skip(')');
skip(')');
}
}
/* enum/struct/union declaration. u is either VT_ENUM or VT_STRUCT */
static void struct_decl(CType *type, int u)
{
int a, v, size, align, maxalign, c, offset;
int bit_size, bit_pos, bsize, bt, lbit_pos, prevbt;
Sym *s, *ss, *ass, **ps;
AttributeDef ad;
CType type1, btype;
a = tok; /* save decl type */
next();
if (tok != '{') {
v = tok;
next();
/* struct already defined ? return it */
if (v < TOK_IDENT)
expect("struct/union/enum name");
s = struct_find(v);
if (s) {
if (s->type.t != a)
error("invalid type");
goto do_decl;
}
} else {
v = anon_sym++;
}
type1.t = a;
/* we put an undefined size for struct/union */
s = sym_push(v | SYM_STRUCT, &type1, 0, -1);
s->r = 0; /* default alignment is zero as gcc */
/* put struct/union/enum name in type */
do_decl:
type->t = u;
type->ref = s;
if (tok == '{') {
next();
if (s->c != -1)
error("struct/union/enum already defined");
/* cannot be empty */
c = 0;
/* non empty enums are not allowed */
if (a == TOK_ENUM) {
for(;;) {
v = tok;
if (v < TOK_UIDENT)
expect("identifier");
next();
if (tok == '=') {
next();
c = expr_const();
}
/* enum symbols have static storage */
ss = sym_push(v, &int_type, VT_CONST, c);
ss->type.t |= VT_STATIC;
if (tok != ',')
break;
next();
c++;
/* NOTE: we accept a trailing comma */
if (tok == '}')
break;
}
skip('}');
} else {
maxalign = 1;
ps = &s->next;
prevbt = VT_INT;
bit_pos = 0;
offset = 0;
while (tok != '}') {
parse_btype(&btype, &ad);
while (1) {
bit_size = -1;
v = 0;
type1 = btype;
if (tok != ':') {
type_decl(&type1, &ad, &v, TYPE_DIRECT | TYPE_ABSTRACT);
if (v == 0 && (type1.t & VT_BTYPE) != VT_STRUCT)
expect("identifier");
if ((type1.t & VT_BTYPE) == VT_FUNC ||
(type1.t & (VT_TYPEDEF | VT_STATIC | VT_EXTERN | VT_INLINE)))
error("invalid type for '%s'",
get_tok_str(v, NULL));
}
if (tok == ':') {
next();
bit_size = expr_const();
/* XXX: handle v = 0 case for messages */
if (bit_size < 0)
error("negative width in bit-field '%s'",
get_tok_str(v, NULL));
if (v && bit_size == 0)
error("zero width for bit-field '%s'",
get_tok_str(v, NULL));
}
size = type_size(&type1, &align);
if (ad.aligned) {
if (align < ad.aligned)
align = ad.aligned;
} else if (ad.packed) {
align = 1;
} else if (*tcc_state->pack_stack_ptr) {
if (align > *tcc_state->pack_stack_ptr)
align = *tcc_state->pack_stack_ptr;
}
lbit_pos = 0;
if (bit_size >= 0) {
bt = type1.t & VT_BTYPE;
if (bt != VT_INT &&
bt != VT_BYTE &&
bt != VT_SHORT &&
bt != VT_BOOL &&
bt != VT_ENUM &&
bt != VT_LLONG)
error("bitfields must have scalar type");
bsize = size * 8;
if (bit_size > bsize) {
error("width of '%s' exceeds its type",
get_tok_str(v, NULL));
} else if (bit_size == bsize) {
/* no need for bit fields */
bit_pos = 0;
} else if (bit_size == 0) {
/* XXX: what to do if only padding in a
structure ? */
/* zero size: means to pad */
bit_pos = 0;
} else {
/* we do not have enough room ?
did the type change?
is it a union? */
if ((bit_pos + bit_size) > bsize ||
bt != prevbt || a == TOK_UNION)
bit_pos = 0;
lbit_pos = bit_pos;
/* XXX: handle LSB first */
type1.t |= VT_BITFIELD |
(bit_pos << VT_STRUCT_SHIFT) |
(bit_size << (VT_STRUCT_SHIFT + 6));
bit_pos += bit_size;
}
prevbt = bt;
} else {
bit_pos = 0;
}
if (v != 0 || (type1.t & VT_BTYPE) == VT_STRUCT) {
/* add new memory data only if starting
bit field */
if (lbit_pos == 0) {
if (a == TOK_STRUCT) {
c = (c + align - 1) & -align;
offset = c;
if (size > 0)
c += size;
} else {
offset = 0;
if (size > c)
c = size;
}
if (align > maxalign)
maxalign = align;
}
#if 0
printf("add field %s offset=%d",
get_tok_str(v, NULL), offset);
if (type1.t & VT_BITFIELD) {
printf(" pos=%d size=%d",
(type1.t >> VT_STRUCT_SHIFT) & 0x3f,
(type1.t >> (VT_STRUCT_SHIFT + 6)) & 0x3f);
}
printf("\n");
#endif
}
if (v == 0 && (type1.t & VT_BTYPE) == VT_STRUCT) {
ass = type1.ref;
while ((ass = ass->next) != NULL) {
ss = sym_push(ass->v, &ass->type, 0, offset + ass->c);
*ps = ss;
ps = &ss->next;
}
} else if (v) {
ss = sym_push(v | SYM_FIELD, &type1, 0, offset);
*ps = ss;
ps = &ss->next;
}
if (tok == ';' || tok == TOK_EOF)
break;
skip(',');
}
skip(';');
}
skip('}');
/* store size and alignment */
s->c = (c + maxalign - 1) & -maxalign;
s->r = maxalign;
}
}
}
/* return 0 if no type declaration. otherwise, return the basic type
and skip it.
*/
static int parse_btype(CType *type, AttributeDef *ad)
{
int t, u, type_found, typespec_found, typedef_found;
Sym *s;
CType type1;
memset(ad, 0, sizeof(AttributeDef));
type_found = 0;
typespec_found = 0;
typedef_found = 0;
t = 0;
while(1) {
switch(tok) {
case TOK_EXTENSION:
/* currently, we really ignore extension */
next();
continue;
/* basic types */
case TOK_CHAR:
u = VT_BYTE;
basic_type:
next();
basic_type1:
if ((t & VT_BTYPE) != 0)
error("too many basic types");
t |= u;
typespec_found = 1;
break;
case TOK_VOID:
u = VT_VOID;
goto basic_type;
case TOK_SHORT:
u = VT_SHORT;
goto basic_type;
case TOK_INT:
next();
typespec_found = 1;
break;
case TOK_LONG:
next();
if ((t & VT_BTYPE) == VT_DOUBLE) {
2009-07-19 00:07:17 +04:00
#ifndef TCC_TARGET_PE
2009-05-05 22:18:10 +04:00
t = (t & ~VT_BTYPE) | VT_LDOUBLE;
2009-07-19 00:07:17 +04:00
#endif
2009-05-05 22:18:10 +04:00
} else if ((t & VT_BTYPE) == VT_LONG) {
t = (t & ~VT_BTYPE) | VT_LLONG;
} else {
u = VT_LONG;
goto basic_type1;
}
break;
case TOK_BOOL:
u = VT_BOOL;
goto basic_type;
case TOK_FLOAT:
u = VT_FLOAT;
goto basic_type;
case TOK_DOUBLE:
next();
if ((t & VT_BTYPE) == VT_LONG) {
2009-07-19 00:07:17 +04:00
#ifdef TCC_TARGET_PE
t = (t & ~VT_BTYPE) | VT_DOUBLE;
#else
2009-05-05 22:18:10 +04:00
t = (t & ~VT_BTYPE) | VT_LDOUBLE;
2009-07-19 00:07:17 +04:00
#endif
2009-05-05 22:18:10 +04:00
} else {
u = VT_DOUBLE;
goto basic_type1;
}
break;
case TOK_ENUM:
struct_decl(&type1, VT_ENUM);
basic_type2:
u = type1.t;
type->ref = type1.ref;
goto basic_type1;
case TOK_STRUCT:
case TOK_UNION:
struct_decl(&type1, VT_STRUCT);
goto basic_type2;
/* type modifiers */
case TOK_CONST1:
case TOK_CONST2:
case TOK_CONST3:
t |= VT_CONSTANT;
next();
break;
case TOK_VOLATILE1:
case TOK_VOLATILE2:
case TOK_VOLATILE3:
t |= VT_VOLATILE;
next();
break;
case TOK_SIGNED1:
case TOK_SIGNED2:
case TOK_SIGNED3:
typespec_found = 1;
t |= VT_SIGNED;
next();
break;
case TOK_REGISTER:
case TOK_AUTO:
case TOK_RESTRICT1:
case TOK_RESTRICT2:
case TOK_RESTRICT3:
next();
break;
case TOK_UNSIGNED:
t |= VT_UNSIGNED;
next();
typespec_found = 1;
break;
/* storage */
case TOK_EXTERN:
t |= VT_EXTERN;
next();
break;
case TOK_STATIC:
t |= VT_STATIC;
next();
break;
case TOK_TYPEDEF:
t |= VT_TYPEDEF;
next();
break;
case TOK_INLINE1:
case TOK_INLINE2:
case TOK_INLINE3:
t |= VT_INLINE;
next();
break;
/* GNUC attribute */
case TOK_ATTRIBUTE1:
case TOK_ATTRIBUTE2:
parse_attribute(ad);
break;
/* GNUC typeof */
case TOK_TYPEOF1:
case TOK_TYPEOF2:
case TOK_TYPEOF3:
next();
parse_expr_type(&type1);
goto basic_type2;
default:
if (typespec_found || typedef_found)
goto the_end;
s = sym_find(tok);
if (!s || !(s->type.t & VT_TYPEDEF))
goto the_end;
typedef_found = 1;
t |= (s->type.t & ~VT_TYPEDEF);
type->ref = s->type.ref;
if (s->r) {
/* get attributes from typedef */
if (0 == ad->aligned)
ad->aligned = FUNC_ALIGN(s->r);
if (0 == ad->func_call)
ad->func_call = FUNC_CALL(s->r);
ad->packed |= FUNC_PACKED(s->r);
}
2009-05-05 22:18:10 +04:00
next();
typespec_found = 1;
break;
}
type_found = 1;
}
the_end:
if ((t & (VT_SIGNED|VT_UNSIGNED)) == (VT_SIGNED|VT_UNSIGNED))
error("signed and unsigned modifier");
if (tcc_state->char_is_unsigned) {
if ((t & (VT_SIGNED|VT_UNSIGNED|VT_BTYPE)) == VT_BYTE)
t |= VT_UNSIGNED;
}
t &= ~VT_SIGNED;
/* long is never used as type */
if ((t & VT_BTYPE) == VT_LONG)
2009-07-19 00:05:27 +04:00
#if !defined TCC_TARGET_X86_64 || defined TCC_TARGET_PE
2009-05-05 22:18:10 +04:00
t = (t & ~VT_BTYPE) | VT_INT;
#else
t = (t & ~VT_BTYPE) | VT_LLONG;
#endif
type->t = t;
return type_found;
}
/* convert a function parameter type (array to pointer and function to
function pointer) */
static inline void convert_parameter_type(CType *pt)
{
/* remove const and volatile qualifiers (XXX: const could be used
to indicate a const function parameter */
pt->t &= ~(VT_CONSTANT | VT_VOLATILE);
/* array must be transformed to pointer according to ANSI C */
pt->t &= ~VT_ARRAY;
if ((pt->t & VT_BTYPE) == VT_FUNC) {
mk_pointer(pt);
}
}
static void post_type(CType *type, AttributeDef *ad)
{
int n, l, t1, arg_size, align;
Sym **plast, *s, *first;
AttributeDef ad1;
CType pt;
if (tok == '(') {
/* function declaration */
next();
l = 0;
first = NULL;
plast = &first;
arg_size = 0;
if (tok != ')') {
for(;;) {
/* read param name and compute offset */
if (l != FUNC_OLD) {
if (!parse_btype(&pt, &ad1)) {
if (l) {
error("invalid type");
} else {
l = FUNC_OLD;
goto old_proto;
}
}
l = FUNC_NEW;
if ((pt.t & VT_BTYPE) == VT_VOID && tok == ')')
break;
type_decl(&pt, &ad1, &n, TYPE_DIRECT | TYPE_ABSTRACT);
if ((pt.t & VT_BTYPE) == VT_VOID)
error("parameter declared as void");
arg_size += (type_size(&pt, &align) + 3) & ~3;
} else {
old_proto:
n = tok;
if (n < TOK_UIDENT)
expect("identifier");
pt.t = VT_INT;
next();
}
convert_parameter_type(&pt);
s = sym_push(n | SYM_FIELD, &pt, 0, 0);
*plast = s;
plast = &s->next;
if (tok == ')')
break;
skip(',');
if (l == FUNC_NEW && tok == TOK_DOTS) {
l = FUNC_ELLIPSIS;
next();
break;
}
}
}
/* if no parameters, then old type prototype */
if (l == 0)
l = FUNC_OLD;
skip(')');
t1 = type->t & VT_STORAGE;
/* NOTE: const is ignored in returned type as it has a special
meaning in gcc / C++ */
type->t &= ~(VT_STORAGE | VT_CONSTANT);
post_type(type, ad);
/* we push a anonymous symbol which will contain the function prototype */
ad->func_args = arg_size;
s = sym_push(SYM_FIELD, type, INT_ATTR(ad), l);
2009-05-05 22:18:10 +04:00
s->next = first;
type->t = t1 | VT_FUNC;
type->ref = s;
} else if (tok == '[') {
/* array definition */
next();
if (tok == TOK_RESTRICT1)
next();
n = -1;
if (tok != ']') {
n = expr_const();
if (n < 0)
error("invalid array size");
}
skip(']');
/* parse next post type */
t1 = type->t & VT_STORAGE;
type->t &= ~VT_STORAGE;
post_type(type, ad);
/* we push a anonymous symbol which will contain the array
element type */
s = sym_push(SYM_FIELD, type, 0, n);
type->t = t1 | VT_ARRAY | VT_PTR;
type->ref = s;
}
}
/* Parse a type declaration (except basic type), and return the type
in 'type'. 'td' is a bitmask indicating which kind of type decl is
expected. 'type' should contain the basic type. 'ad' is the
attribute definition of the basic type. It can be modified by
type_decl().
*/
static void type_decl(CType *type, AttributeDef *ad, int *v, int td)
{
Sym *s;
CType type1, *type2;
int qualifiers;
while (tok == '*') {
qualifiers = 0;
redo:
next();
switch(tok) {
case TOK_CONST1:
case TOK_CONST2:
case TOK_CONST3:
qualifiers |= VT_CONSTANT;
goto redo;
case TOK_VOLATILE1:
case TOK_VOLATILE2:
case TOK_VOLATILE3:
qualifiers |= VT_VOLATILE;
goto redo;
case TOK_RESTRICT1:
case TOK_RESTRICT2:
case TOK_RESTRICT3:
goto redo;
}
mk_pointer(type);
type->t |= qualifiers;
}
/* XXX: clarify attribute handling */
if (tok == TOK_ATTRIBUTE1 || tok == TOK_ATTRIBUTE2)
parse_attribute(ad);
/* recursive type */
/* XXX: incorrect if abstract type for functions (e.g. 'int ()') */
type1.t = 0; /* XXX: same as int */
if (tok == '(') {
next();
/* XXX: this is not correct to modify 'ad' at this point, but
the syntax is not clear */
if (tok == TOK_ATTRIBUTE1 || tok == TOK_ATTRIBUTE2)
parse_attribute(ad);
type_decl(&type1, ad, v, td);
skip(')');
} else {
/* type identifier */
if (tok >= TOK_IDENT && (td & TYPE_DIRECT)) {
*v = tok;
next();
} else {
if (!(td & TYPE_ABSTRACT))
expect("identifier");
*v = 0;
}
}
post_type(type, ad);
if (tok == TOK_ATTRIBUTE1 || tok == TOK_ATTRIBUTE2)
parse_attribute(ad);
if (!type1.t)
return;
/* append type at the end of type1 */
type2 = &type1;
for(;;) {
s = type2->ref;
type2 = &s->type;
if (!type2->t) {
*type2 = *type;
break;
}
}
*type = type1;
}
/* compute the lvalue VT_LVAL_xxx needed to match type t. */
static int lvalue_type(int t)
{
int bt, r;
r = VT_LVAL;
bt = t & VT_BTYPE;
if (bt == VT_BYTE || bt == VT_BOOL)
r |= VT_LVAL_BYTE;
else if (bt == VT_SHORT)
r |= VT_LVAL_SHORT;
else
return r;
if (t & VT_UNSIGNED)
r |= VT_LVAL_UNSIGNED;
return r;
}
/* indirection with full error checking and bound check */
static void indir(void)
{
if ((vtop->type.t & VT_BTYPE) != VT_PTR) {
if ((vtop->type.t & VT_BTYPE) == VT_FUNC)
return;
expect("pointer");
}
if ((vtop->r & VT_LVAL) && !nocode_wanted)
gv(RC_INT);
vtop->type = *pointed_type(&vtop->type);
/* Arrays and functions are never lvalues */
if (!(vtop->type.t & VT_ARRAY)
&& (vtop->type.t & VT_BTYPE) != VT_FUNC) {
vtop->r |= lvalue_type(vtop->type.t);
/* if bound checking, the referenced pointer must be checked */
if (tcc_state->do_bounds_check)
2009-05-05 22:18:10 +04:00
vtop->r |= VT_MUSTBOUND;
}
}
/* pass a parameter to a function and do type checking and casting */
static void gfunc_param_typed(Sym *func, Sym *arg)
{
int func_type;
CType type;
func_type = func->c;
if (func_type == FUNC_OLD ||
(func_type == FUNC_ELLIPSIS && arg == NULL)) {
/* default casting : only need to convert float to double */
if ((vtop->type.t & VT_BTYPE) == VT_FLOAT) {
type.t = VT_DOUBLE;
gen_cast(&type);
}
} else if (arg == NULL) {
error("too many arguments to function");
} else {
type = arg->type;
type.t &= ~VT_CONSTANT; /* need to do that to avoid false warning */
gen_assign_cast(&type);
}
}
/* parse an expression of the form '(type)' or '(expr)' and return its
type */
static void parse_expr_type(CType *type)
{
int n;
AttributeDef ad;
skip('(');
if (parse_btype(type, &ad)) {
type_decl(type, &ad, &n, TYPE_ABSTRACT);
} else {
expr_type(type);
}
skip(')');
}
static void parse_type(CType *type)
{
AttributeDef ad;
int n;
if (!parse_btype(type, &ad)) {
expect("type");
}
type_decl(type, &ad, &n, TYPE_ABSTRACT);
}
static void vpush_tokc(int t)
{
CType type;
type.t = t;
vsetc(&type, VT_CONST, &tokc);
}
static void unary(void)
{
int n, t, align, size, r;
CType type;
Sym *s;
AttributeDef ad;
/* XXX: GCC 2.95.3 does not generate a table although it should be
better here */
tok_next:
switch(tok) {
case TOK_EXTENSION:
next();
goto tok_next;
case TOK_CINT:
case TOK_CCHAR:
case TOK_LCHAR:
vpushi(tokc.i);
next();
break;
case TOK_CUINT:
vpush_tokc(VT_INT | VT_UNSIGNED);
next();
break;
case TOK_CLLONG:
vpush_tokc(VT_LLONG);
next();
break;
case TOK_CULLONG:
vpush_tokc(VT_LLONG | VT_UNSIGNED);
next();
break;
case TOK_CFLOAT:
vpush_tokc(VT_FLOAT);
next();
break;
case TOK_CDOUBLE:
vpush_tokc(VT_DOUBLE);
next();
break;
case TOK_CLDOUBLE:
vpush_tokc(VT_LDOUBLE);
next();
break;
case TOK___FUNCTION__:
if (!gnu_ext)
goto tok_identifier;
/* fall thru */
case TOK___FUNC__:
{
void *ptr;
int len;
/* special function name identifier */
len = strlen(funcname) + 1;
/* generate char[len] type */
type.t = VT_BYTE;
mk_pointer(&type);
type.t |= VT_ARRAY;
type.ref->c = len;
vpush_ref(&type, data_section, data_section->data_offset, len);
ptr = section_ptr_add(data_section, len);
memcpy(ptr, funcname, len);
next();
}
break;
case TOK_LSTR:
#ifdef TCC_TARGET_PE
t = VT_SHORT | VT_UNSIGNED;
#else
t = VT_INT;
#endif
goto str_init;
case TOK_STR:
/* string parsing */
t = VT_BYTE;
str_init:
if (tcc_state->warn_write_strings)
t |= VT_CONSTANT;
type.t = t;
mk_pointer(&type);
type.t |= VT_ARRAY;
memset(&ad, 0, sizeof(AttributeDef));
decl_initializer_alloc(&type, &ad, VT_CONST, 2, 0, 0);
break;
case '(':
next();
/* cast ? */
if (parse_btype(&type, &ad)) {
type_decl(&type, &ad, &n, TYPE_ABSTRACT);
skip(')');
/* check ISOC99 compound literal */
if (tok == '{') {
/* data is allocated locally by default */
if (global_expr)
r = VT_CONST;
else
r = VT_LOCAL;
/* all except arrays are lvalues */
if (!(type.t & VT_ARRAY))
r |= lvalue_type(type.t);
memset(&ad, 0, sizeof(AttributeDef));
decl_initializer_alloc(&type, &ad, r, 1, 0, 0);
} else {
unary();
gen_cast(&type);
}
} else if (tok == '{') {
/* save all registers */
save_regs(0);
/* statement expression : we do not accept break/continue
inside as GCC does */
block(NULL, NULL, NULL, NULL, 0, 1);
skip(')');
} else {
gexpr();
skip(')');
}
break;
case '*':
next();
unary();
indir();
break;
case '&':
next();
unary();
/* functions names must be treated as function pointers,
except for unary '&' and sizeof. Since we consider that
functions are not lvalues, we only have to handle it
there and in function calls. */
/* arrays can also be used although they are not lvalues */
if ((vtop->type.t & VT_BTYPE) != VT_FUNC &&
!(vtop->type.t & VT_ARRAY) && !(vtop->type.t & VT_LLOCAL))
test_lvalue();
mk_pointer(&vtop->type);
gaddrof();
break;
case '!':
next();
unary();
if ((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST) {
CType boolean;
boolean.t = VT_BOOL;
gen_cast(&boolean);
vtop->c.i = !vtop->c.i;
} else if ((vtop->r & VT_VALMASK) == VT_CMP)
vtop->c.i = vtop->c.i ^ 1;
else {
save_regs(1);
vseti(VT_JMP, gtst(1, 0));
}
break;
case '~':
next();
unary();
vpushi(-1);
gen_op('^');
break;
case '+':
next();
/* in order to force cast, we add zero */
unary();
if ((vtop->type.t & VT_BTYPE) == VT_PTR)
error("pointer not accepted for unary plus");
vpushi(0);
gen_op('+');
break;
case TOK_SIZEOF:
case TOK_ALIGNOF1:
case TOK_ALIGNOF2:
t = tok;
next();
if (tok == '(') {
parse_expr_type(&type);
} else {
unary_type(&type);
}
size = type_size(&type, &align);
if (t == TOK_SIZEOF) {
if (size < 0)
error("sizeof applied to an incomplete type");
vpushi(size);
} else {
vpushi(align);
}
vtop->type.t |= VT_UNSIGNED;
break;
case TOK_builtin_types_compatible_p:
{
CType type1, type2;
next();
skip('(');
parse_type(&type1);
skip(',');
parse_type(&type2);
skip(')');
type1.t &= ~(VT_CONSTANT | VT_VOLATILE);
type2.t &= ~(VT_CONSTANT | VT_VOLATILE);
vpushi(is_compatible_types(&type1, &type2));
}
break;
case TOK_builtin_constant_p:
{
int saved_nocode_wanted, res;
next();
skip('(');
saved_nocode_wanted = nocode_wanted;
nocode_wanted = 1;
gexpr();
res = (vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST;
vpop();
nocode_wanted = saved_nocode_wanted;
skip(')');
vpushi(res);
}
break;
case TOK_builtin_frame_address:
{
CType type;
next();
skip('(');
if (tok != TOK_CINT) {
error("__builtin_frame_address only takes integers");
}
if (tokc.i != 0) {
error("TCC only supports __builtin_frame_address(0)");
}
next();
skip(')');
type.t = VT_VOID;
mk_pointer(&type);
vset(&type, VT_LOCAL, 0);
}
break;
#ifdef TCC_TARGET_X86_64
case TOK_builtin_malloc:
tok = TOK_malloc;
goto tok_identifier;
case TOK_builtin_free:
tok = TOK_free;
goto tok_identifier;
#endif
case TOK_INC:
case TOK_DEC:
t = tok;
next();
unary();
inc(0, t);
break;
case '-':
next();
vpushi(0);
unary();
gen_op('-');
break;
case TOK_LAND:
if (!gnu_ext)
goto tok_identifier;
next();
/* allow to take the address of a label */
if (tok < TOK_UIDENT)
expect("label identifier");
s = label_find(tok);
if (!s) {
s = label_push(&global_label_stack, tok, LABEL_FORWARD);
} else {
if (s->r == LABEL_DECLARED)
s->r = LABEL_FORWARD;
}
if (!s->type.t) {
s->type.t = VT_VOID;
mk_pointer(&s->type);
s->type.t |= VT_STATIC;
}
vset(&s->type, VT_CONST | VT_SYM, 0);
vtop->sym = s;
next();
break;
default:
tok_identifier:
t = tok;
next();
if (t < TOK_UIDENT)
expect("identifier");
s = sym_find(t);
if (!s) {
if (tok != '(')
error("'%s' undeclared", get_tok_str(t, NULL));
/* for simple function calls, we tolerate undeclared
external reference to int() function */
if (tcc_state->warn_implicit_function_declaration)
warning("implicit declaration of function '%s'",
get_tok_str(t, NULL));
s = external_global_sym(t, &func_old_type, 0);
}
if ((s->type.t & (VT_STATIC | VT_INLINE | VT_BTYPE)) ==
(VT_STATIC | VT_INLINE | VT_FUNC)) {
/* if referencing an inline function, then we generate a
symbol to it if not already done. It will have the
effect to generate code for it at the end of the
compilation unit. Inline function as always
generated in the text section. */
if (!s->c)
put_extern_sym(s, text_section, 0, 0);
r = VT_SYM | VT_CONST;
} else {
r = s->r;
}
vset(&s->type, r, s->c);
/* if forward reference, we must point to s */
if (vtop->r & VT_SYM) {
vtop->sym = s;
vtop->c.ul = 0;
}
break;
}
/* post operations */
while (1) {
if (tok == TOK_INC || tok == TOK_DEC) {
inc(1, tok);
next();
} else if (tok == '.' || tok == TOK_ARROW) {
2009-06-16 00:26:44 +04:00
int qualifiers;
2009-05-05 22:18:10 +04:00
/* field */
if (tok == TOK_ARROW)
indir();
2009-06-16 00:26:44 +04:00
qualifiers = vtop->type.t & (VT_CONSTANT | VT_VOLATILE);
2009-05-05 22:18:10 +04:00
test_lvalue();
gaddrof();
next();
/* expect pointer on structure */
if ((vtop->type.t & VT_BTYPE) != VT_STRUCT)
expect("struct or union");
s = vtop->type.ref;
/* find field */
tok |= SYM_FIELD;
while ((s = s->next) != NULL) {
if (s->v == tok)
break;
}
if (!s)
error("field not found: %s", get_tok_str(tok & ~SYM_FIELD, NULL));
/* add field offset to pointer */
vtop->type = char_pointer_type; /* change type to 'char *' */
vpushi(s->c);
gen_op('+');
/* change type to field type, and set to lvalue */
vtop->type = s->type;
2009-06-16 00:26:44 +04:00
vtop->type.t |= qualifiers;
2009-05-05 22:18:10 +04:00
/* an array is never an lvalue */
if (!(vtop->type.t & VT_ARRAY)) {
vtop->r |= lvalue_type(vtop->type.t);
/* if bound checking, the referenced pointer must be checked */
if (tcc_state->do_bounds_check)
2009-05-05 22:18:10 +04:00
vtop->r |= VT_MUSTBOUND;
}
next();
} else if (tok == '[') {
next();
gexpr();
gen_op('+');
indir();
skip(']');
} else if (tok == '(') {
SValue ret;
Sym *sa;
int nb_args;
/* function call */
if ((vtop->type.t & VT_BTYPE) != VT_FUNC) {
/* pointer test (no array accepted) */
if ((vtop->type.t & (VT_BTYPE | VT_ARRAY)) == VT_PTR) {
vtop->type = *pointed_type(&vtop->type);
if ((vtop->type.t & VT_BTYPE) != VT_FUNC)
goto error_func;
} else {
error_func:
expect("function pointer");
}
} else {
vtop->r &= ~VT_LVAL; /* no lvalue */
}
/* get return type */
s = vtop->type.ref;
next();
sa = s->next; /* first parameter */
nb_args = 0;
ret.r2 = VT_CONST;
/* compute first implicit argument if a structure is returned */
if ((s->type.t & VT_BTYPE) == VT_STRUCT) {
/* get some space for the returned structure */
size = type_size(&s->type, &align);
loc = (loc - size) & -align;
ret.type = s->type;
ret.r = VT_LOCAL | VT_LVAL;
/* pass it as 'int' to avoid structure arg passing
problems */
vseti(VT_LOCAL, loc);
ret.c = vtop->c;
nb_args++;
} else {
ret.type = s->type;
/* return in register */
if (is_float(ret.type.t)) {
ret.r = reg_fret(ret.type.t);
} else {
if ((ret.type.t & VT_BTYPE) == VT_LLONG)
ret.r2 = REG_LRET;
ret.r = REG_IRET;
}
ret.c.i = 0;
}
if (tok != ')') {
for(;;) {
expr_eq();
gfunc_param_typed(s, sa);
nb_args++;
if (sa)
sa = sa->next;
if (tok == ')')
break;
skip(',');
}
}
if (sa)
error("too few arguments to function");
skip(')');
if (!nocode_wanted) {
gfunc_call(nb_args);
} else {
vtop -= (nb_args + 1);
}
/* return value */
vsetc(&ret.type, ret.r, &ret.c);
vtop->r2 = ret.r2;
} else {
break;
}
}
}
static void uneq(void)
{
int t;
unary();
if (tok == '=' ||
(tok >= TOK_A_MOD && tok <= TOK_A_DIV) ||
tok == TOK_A_XOR || tok == TOK_A_OR ||
tok == TOK_A_SHL || tok == TOK_A_SAR) {
test_lvalue();
t = tok;
next();
if (t == '=') {
expr_eq();
} else {
vdup();
expr_eq();
gen_op(t & 0x7f);
}
vstore();
}
}
static void expr_prod(void)
{
int t;
uneq();
while (tok == '*' || tok == '/' || tok == '%') {
t = tok;
next();
uneq();
gen_op(t);
}
}
static void expr_sum(void)
{
int t;
expr_prod();
while (tok == '+' || tok == '-') {
t = tok;
next();
expr_prod();
gen_op(t);
}
}
static void expr_shift(void)
{
int t;
expr_sum();
while (tok == TOK_SHL || tok == TOK_SAR) {
t = tok;
next();
expr_sum();
gen_op(t);
}
}
static void expr_cmp(void)
{
int t;
expr_shift();
while ((tok >= TOK_ULE && tok <= TOK_GT) ||
tok == TOK_ULT || tok == TOK_UGE) {
t = tok;
next();
expr_shift();
gen_op(t);
}
}
static void expr_cmpeq(void)
{
int t;
expr_cmp();
while (tok == TOK_EQ || tok == TOK_NE) {
t = tok;
next();
expr_cmp();
gen_op(t);
}
}
static void expr_and(void)
{
expr_cmpeq();
while (tok == '&') {
next();
expr_cmpeq();
gen_op('&');
}
}
static void expr_xor(void)
{
expr_and();
while (tok == '^') {
next();
expr_and();
gen_op('^');
}
}
static void expr_or(void)
{
expr_xor();
while (tok == '|') {
next();
expr_xor();
gen_op('|');
}
}
/* XXX: fix this mess */
static void expr_land_const(void)
{
expr_or();
while (tok == TOK_LAND) {
next();
expr_or();
gen_op(TOK_LAND);
}
}
/* XXX: fix this mess */
static void expr_lor_const(void)
{
expr_land_const();
while (tok == TOK_LOR) {
next();
expr_land_const();
gen_op(TOK_LOR);
}
}
/* only used if non constant */
static void expr_land(void)
{
int t;
expr_or();
if (tok == TOK_LAND) {
t = 0;
save_regs(1);
for(;;) {
t = gtst(1, t);
if (tok != TOK_LAND) {
vseti(VT_JMPI, t);
break;
}
next();
expr_or();
}
}
}
static void expr_lor(void)
{
int t;
expr_land();
if (tok == TOK_LOR) {
t = 0;
save_regs(1);
for(;;) {
t = gtst(0, t);
if (tok != TOK_LOR) {
vseti(VT_JMP, t);
break;
}
next();
expr_land();
}
}
}
/* XXX: better constant handling */
static void expr_eq(void)
{
int tt, u, r1, r2, rc, t1, t2, bt1, bt2;
SValue sv;
CType type, type1, type2;
if (const_wanted) {
expr_lor_const();
if (tok == '?') {
CType boolean;
int c;
boolean.t = VT_BOOL;
vdup();
gen_cast(&boolean);
c = vtop->c.i;
vpop();
next();
if (tok != ':' || !gnu_ext) {
vpop();
gexpr();
}
if (!c)
vpop();
skip(':');
expr_eq();
if (c)
vpop();
}
} else {
expr_lor();
if (tok == '?') {
next();
if (vtop != vstack) {
/* needed to avoid having different registers saved in
each branch */
if (is_float(vtop->type.t)) {
rc = RC_FLOAT;
#ifdef TCC_TARGET_X86_64
if ((vtop->type.t & VT_BTYPE) == VT_LDOUBLE) {
rc = RC_ST0;
}
#endif
}
else
rc = RC_INT;
gv(rc);
save_regs(1);
}
if (tok == ':' && gnu_ext) {
gv_dup();
tt = gtst(1, 0);
} else {
tt = gtst(1, 0);
gexpr();
}
type1 = vtop->type;
sv = *vtop; /* save value to handle it later */
vtop--; /* no vpop so that FP stack is not flushed */
skip(':');
u = gjmp(0);
gsym(tt);
expr_eq();
type2 = vtop->type;
t1 = type1.t;
bt1 = t1 & VT_BTYPE;
t2 = type2.t;
bt2 = t2 & VT_BTYPE;
/* cast operands to correct type according to ISOC rules */
if (is_float(bt1) || is_float(bt2)) {
if (bt1 == VT_LDOUBLE || bt2 == VT_LDOUBLE) {
type.t = VT_LDOUBLE;
} else if (bt1 == VT_DOUBLE || bt2 == VT_DOUBLE) {
type.t = VT_DOUBLE;
} else {
type.t = VT_FLOAT;
}
} else if (bt1 == VT_LLONG || bt2 == VT_LLONG) {
/* cast to biggest op */
type.t = VT_LLONG;
/* convert to unsigned if it does not fit in a long long */
if ((t1 & (VT_BTYPE | VT_UNSIGNED)) == (VT_LLONG | VT_UNSIGNED) ||
(t2 & (VT_BTYPE | VT_UNSIGNED)) == (VT_LLONG | VT_UNSIGNED))
type.t |= VT_UNSIGNED;
} else if (bt1 == VT_PTR || bt2 == VT_PTR) {
/* XXX: test pointer compatibility */
type = type1;
} else if (bt1 == VT_FUNC || bt2 == VT_FUNC) {
/* XXX: test function pointer compatibility */
type = type1;
} else if (bt1 == VT_STRUCT || bt2 == VT_STRUCT) {
/* XXX: test structure compatibility */
type = type1;
} else if (bt1 == VT_VOID || bt2 == VT_VOID) {
/* NOTE: as an extension, we accept void on only one side */
type.t = VT_VOID;
} else {
/* integer operations */
type.t = VT_INT;
/* convert to unsigned if it does not fit in an integer */
if ((t1 & (VT_BTYPE | VT_UNSIGNED)) == (VT_INT | VT_UNSIGNED) ||
(t2 & (VT_BTYPE | VT_UNSIGNED)) == (VT_INT | VT_UNSIGNED))
type.t |= VT_UNSIGNED;
}
/* now we convert second operand */
gen_cast(&type);
if (VT_STRUCT == (vtop->type.t & VT_BTYPE))
gaddrof();
rc = RC_INT;
if (is_float(type.t)) {
rc = RC_FLOAT;
#ifdef TCC_TARGET_X86_64
if ((type.t & VT_BTYPE) == VT_LDOUBLE) {
rc = RC_ST0;
}
#endif
} else if ((type.t & VT_BTYPE) == VT_LLONG) {
/* for long longs, we use fixed registers to avoid having
to handle a complicated move */
rc = RC_IRET;
}
r2 = gv(rc);
/* this is horrible, but we must also convert first
operand */
tt = gjmp(0);
gsym(u);
/* put again first value and cast it */
*vtop = sv;
gen_cast(&type);
if (VT_STRUCT == (vtop->type.t & VT_BTYPE))
gaddrof();
r1 = gv(rc);
move_reg(r2, r1);
vtop->r = r2;
gsym(tt);
}
}
}
static void gexpr(void)
{
while (1) {
expr_eq();
if (tok != ',')
break;
vpop();
next();
}
}
/* parse an expression and return its type without any side effect. */
static void expr_type(CType *type)
{
int saved_nocode_wanted;
saved_nocode_wanted = nocode_wanted;
nocode_wanted = 1;
gexpr();
*type = vtop->type;
vpop();
nocode_wanted = saved_nocode_wanted;
}
/* parse a unary expression and return its type without any side
effect. */
static void unary_type(CType *type)
{
int a;
a = nocode_wanted;
nocode_wanted = 1;
unary();
*type = vtop->type;
vpop();
nocode_wanted = a;
}
/* parse a constant expression and return value in vtop. */
static void expr_const1(void)
{
int a;
a = const_wanted;
const_wanted = 1;
expr_eq();
const_wanted = a;
}
/* parse an integer constant and return its value. */
static int expr_const(void)
{
int c;
expr_const1();
if ((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) != VT_CONST)
expect("constant expression");
c = vtop->c.i;
vpop();
return c;
}
/* return the label token if current token is a label, otherwise
return zero */
static int is_label(void)
{
int last_tok;
/* fast test first */
if (tok < TOK_UIDENT)
return 0;
/* no need to save tokc because tok is an identifier */
last_tok = tok;
next();
if (tok == ':') {
next();
return last_tok;
} else {
unget_tok(last_tok);
return 0;
}
}
static void block(int *bsym, int *csym, int *case_sym, int *def_sym,
int case_reg, int is_expr)
{
int a, b, c, d;
Sym *s;
/* generate line number info */
if (tcc_state->do_debug &&
2009-05-05 22:18:10 +04:00
(last_line_num != file->line_num || last_ind != ind)) {
put_stabn(N_SLINE, 0, file->line_num, ind - func_ind);
last_ind = ind;
last_line_num = file->line_num;
}
if (is_expr) {
/* default return value is (void) */
vpushi(0);
vtop->type.t = VT_VOID;
}
if (tok == TOK_IF) {
/* if test */
next();
skip('(');
gexpr();
skip(')');
a = gtst(1, 0);
block(bsym, csym, case_sym, def_sym, case_reg, 0);
c = tok;
if (c == TOK_ELSE) {
next();
d = gjmp(0);
gsym(a);
block(bsym, csym, case_sym, def_sym, case_reg, 0);
gsym(d); /* patch else jmp */
} else
gsym(a);
} else if (tok == TOK_WHILE) {
next();
d = ind;
skip('(');
gexpr();
skip(')');
a = gtst(1, 0);
b = 0;
block(&a, &b, case_sym, def_sym, case_reg, 0);
gjmp_addr(d);
gsym(a);
gsym_addr(b, d);
} else if (tok == '{') {
Sym *llabel;
next();
/* record local declaration stack position */
s = local_stack;
llabel = local_label_stack;
/* handle local labels declarations */
if (tok == TOK_LABEL) {
next();
for(;;) {
if (tok < TOK_UIDENT)
expect("label identifier");
label_push(&local_label_stack, tok, LABEL_DECLARED);
next();
if (tok == ',') {
next();
} else {
skip(';');
break;
}
}
}
while (tok != '}') {
decl(VT_LOCAL);
if (tok != '}') {
if (is_expr)
vpop();
block(bsym, csym, case_sym, def_sym, case_reg, is_expr);
}
}
/* pop locally defined labels */
label_pop(&local_label_stack, llabel);
/* pop locally defined symbols */
if(is_expr) {
/* XXX: this solution makes only valgrind happy...
triggered by gcc.c-torture/execute/20000917-1.c */
Sym *p;
switch(vtop->type.t & VT_BTYPE) {
case VT_PTR:
case VT_STRUCT:
case VT_ENUM:
case VT_FUNC:
for(p=vtop->type.ref;p;p=p->prev)
if(p->prev==s)
error("unsupported expression type");
}
}
sym_pop(&local_stack, s);
next();
} else if (tok == TOK_RETURN) {
next();
if (tok != ';') {
gexpr();
gen_assign_cast(&func_vt);
if ((func_vt.t & VT_BTYPE) == VT_STRUCT) {
CType type;
/* if returning structure, must copy it to implicit
first pointer arg location */
#ifdef TCC_ARM_EABI
int align, size;
size = type_size(&func_vt,&align);
if(size <= 4)
{
if((vtop->r != (VT_LOCAL | VT_LVAL) || (vtop->c.i & 3))
&& (align & 3))
{
int addr;
loc = (loc - size) & -4;
addr = loc;
type = func_vt;
vset(&type, VT_LOCAL | VT_LVAL, addr);
vswap();
vstore();
vset(&int_type, VT_LOCAL | VT_LVAL, addr);
}
vtop->type = int_type;
gv(RC_IRET);
} else {
#endif
type = func_vt;
mk_pointer(&type);
vset(&type, VT_LOCAL | VT_LVAL, func_vc);
indir();
vswap();
/* copy structure value to pointer */
vstore();
#ifdef TCC_ARM_EABI
}
#endif
} else if (is_float(func_vt.t)) {
gv(rc_fret(func_vt.t));
} else {
gv(RC_IRET);
}
vtop--; /* NOT vpop() because on x86 it would flush the fp stack */
}
skip(';');
rsym = gjmp(rsym); /* jmp */
} else if (tok == TOK_BREAK) {
/* compute jump */
if (!bsym)
error("cannot break");
*bsym = gjmp(*bsym);
next();
skip(';');
} else if (tok == TOK_CONTINUE) {
/* compute jump */
if (!csym)
error("cannot continue");
*csym = gjmp(*csym);
next();
skip(';');
} else if (tok == TOK_FOR) {
int e;
next();
skip('(');
if (tok != ';') {
gexpr();
vpop();
}
skip(';');
d = ind;
c = ind;
a = 0;
b = 0;
if (tok != ';') {
gexpr();
a = gtst(1, 0);
}
skip(';');
if (tok != ')') {
e = gjmp(0);
c = ind;
gexpr();
vpop();
gjmp_addr(d);
gsym(e);
}
skip(')');
block(&a, &b, case_sym, def_sym, case_reg, 0);
gjmp_addr(c);
gsym(a);
gsym_addr(b, c);
} else
if (tok == TOK_DO) {
next();
a = 0;
b = 0;
d = ind;
block(&a, &b, case_sym, def_sym, case_reg, 0);
skip(TOK_WHILE);
skip('(');
gsym(b);
gexpr();
c = gtst(0, 0);
gsym_addr(c, d);
skip(')');
gsym(a);
skip(';');
} else
if (tok == TOK_SWITCH) {
next();
skip('(');
gexpr();
/* XXX: other types than integer */
case_reg = gv(RC_INT);
vpop();
skip(')');
a = 0;
b = gjmp(0); /* jump to first case */
c = 0;
block(&a, csym, &b, &c, case_reg, 0);
/* if no default, jmp after switch */
if (c == 0)
c = ind;
/* default label */
gsym_addr(b, c);
/* break label */
gsym(a);
} else
if (tok == TOK_CASE) {
int v1, v2;
if (!case_sym)
expect("switch");
next();
v1 = expr_const();
v2 = v1;
if (gnu_ext && tok == TOK_DOTS) {
next();
v2 = expr_const();
if (v2 < v1)
warning("empty case range");
}
/* since a case is like a label, we must skip it with a jmp */
b = gjmp(0);
gsym(*case_sym);
vseti(case_reg, 0);
vpushi(v1);
if (v1 == v2) {
gen_op(TOK_EQ);
*case_sym = gtst(1, 0);
} else {
gen_op(TOK_GE);
*case_sym = gtst(1, 0);
vseti(case_reg, 0);
vpushi(v2);
gen_op(TOK_LE);
*case_sym = gtst(1, *case_sym);
}
gsym(b);
skip(':');
is_expr = 0;
goto block_after_label;
} else
if (tok == TOK_DEFAULT) {
next();
skip(':');
if (!def_sym)
expect("switch");
if (*def_sym)
error("too many 'default'");
*def_sym = ind;
is_expr = 0;
goto block_after_label;
} else
if (tok == TOK_GOTO) {
next();
if (tok == '*' && gnu_ext) {
/* computed goto */
next();
gexpr();
if ((vtop->type.t & VT_BTYPE) != VT_PTR)
expect("pointer");
ggoto();
} else if (tok >= TOK_UIDENT) {
s = label_find(tok);
/* put forward definition if needed */
if (!s) {
s = label_push(&global_label_stack, tok, LABEL_FORWARD);
} else {
if (s->r == LABEL_DECLARED)
s->r = LABEL_FORWARD;
}
/* label already defined */
if (s->r & LABEL_FORWARD)
s->jnext = gjmp(s->jnext);
2009-05-05 22:18:10 +04:00
else
gjmp_addr(s->jnext);
2009-05-05 22:18:10 +04:00
next();
} else {
expect("label identifier");
}
skip(';');
} else if (tok == TOK_ASM1 || tok == TOK_ASM2 || tok == TOK_ASM3) {
asm_instr();
} else {
b = is_label();
if (b) {
/* label case */
s = label_find(b);
if (s) {
if (s->r == LABEL_DEFINED)
error("duplicate label '%s'", get_tok_str(s->v, NULL));
gsym(s->jnext);
2009-05-05 22:18:10 +04:00
s->r = LABEL_DEFINED;
} else {
s = label_push(&global_label_stack, b, LABEL_DEFINED);
}
s->jnext = ind;
2009-05-05 22:18:10 +04:00
/* we accept this, but it is a mistake */
block_after_label:
if (tok == '}') {
warning("deprecated use of label at end of compound statement");
} else {
if (is_expr)
vpop();
block(bsym, csym, case_sym, def_sym, case_reg, is_expr);
}
} else {
/* expression case */
if (tok != ';') {
if (is_expr) {
vpop();
gexpr();
} else {
gexpr();
vpop();
}
}
skip(';');
}
}
}
/* t is the array or struct type. c is the array or struct
address. cur_index/cur_field is the pointer to the current
value. 'size_only' is true if only size info is needed (only used
in arrays) */
static void decl_designator(CType *type, Section *sec, unsigned long c,
int *cur_index, Sym **cur_field,
int size_only)
{
Sym *s, *f;
int notfirst, index, index_last, align, l, nb_elems, elem_size;
CType type1;
notfirst = 0;
elem_size = 0;
nb_elems = 1;
if (gnu_ext && (l = is_label()) != 0)
goto struct_field;
while (tok == '[' || tok == '.') {
if (tok == '[') {
if (!(type->t & VT_ARRAY))
expect("array type");
s = type->ref;
next();
index = expr_const();
if (index < 0 || (s->c >= 0 && index >= s->c))
expect("invalid index");
if (tok == TOK_DOTS && gnu_ext) {
next();
index_last = expr_const();
if (index_last < 0 ||
(s->c >= 0 && index_last >= s->c) ||
index_last < index)
expect("invalid index");
} else {
index_last = index;
}
skip(']');
if (!notfirst)
*cur_index = index_last;
type = pointed_type(type);
elem_size = type_size(type, &align);
c += index * elem_size;
/* NOTE: we only support ranges for last designator */
nb_elems = index_last - index + 1;
if (nb_elems != 1) {
notfirst = 1;
break;
}
} else {
next();
l = tok;
next();
struct_field:
if ((type->t & VT_BTYPE) != VT_STRUCT)
expect("struct/union type");
s = type->ref;
l |= SYM_FIELD;
f = s->next;
while (f) {
if (f->v == l)
break;
f = f->next;
}
if (!f)
expect("field");
if (!notfirst)
*cur_field = f;
/* XXX: fix this mess by using explicit storage field */
type1 = f->type;
type1.t |= (type->t & ~VT_TYPE);
type = &type1;
c += f->c;
}
notfirst = 1;
}
if (notfirst) {
if (tok == '=') {
next();
} else {
if (!gnu_ext)
expect("=");
}
} else {
if (type->t & VT_ARRAY) {
index = *cur_index;
type = pointed_type(type);
c += index * type_size(type, &align);
} else {
f = *cur_field;
if (!f)
error("too many field init");
/* XXX: fix this mess by using explicit storage field */
type1 = f->type;
type1.t |= (type->t & ~VT_TYPE);
type = &type1;
c += f->c;
}
}
decl_initializer(type, sec, c, 0, size_only);
/* XXX: make it more general */
if (!size_only && nb_elems > 1) {
unsigned long c_end;
uint8_t *src, *dst;
int i;
if (!sec)
error("range init not supported yet for dynamic storage");
c_end = c + nb_elems * elem_size;
if (c_end > sec->data_allocated)
section_realloc(sec, c_end);
src = sec->data + c;
dst = src;
for(i = 1; i < nb_elems; i++) {
dst += elem_size;
memcpy(dst, src, elem_size);
}
}
}
#define EXPR_VAL 0
#define EXPR_CONST 1
#define EXPR_ANY 2
/* store a value or an expression directly in global data or in local array */
static void init_putv(CType *type, Section *sec, unsigned long c,
int v, int expr_type)
{
int saved_global_expr, bt, bit_pos, bit_size;
void *ptr;
unsigned long long bit_mask;
CType dtype;
switch(expr_type) {
case EXPR_VAL:
vpushi(v);
break;
case EXPR_CONST:
/* compound literals must be allocated globally in this case */
saved_global_expr = global_expr;
global_expr = 1;
expr_const1();
global_expr = saved_global_expr;
/* NOTE: symbols are accepted */
if ((vtop->r & (VT_VALMASK | VT_LVAL)) != VT_CONST)
error("initializer element is not constant");
break;
case EXPR_ANY:
expr_eq();
break;
}
dtype = *type;
dtype.t &= ~VT_CONSTANT; /* need to do that to avoid false warning */
if (sec) {
/* XXX: not portable */
/* XXX: generate error if incorrect relocation */
gen_assign_cast(&dtype);
bt = type->t & VT_BTYPE;
/* we'll write at most 12 bytes */
if (c + 12 > sec->data_allocated) {
section_realloc(sec, c + 12);
}
ptr = sec->data + c;
/* XXX: make code faster ? */
if (!(type->t & VT_BITFIELD)) {
bit_pos = 0;
bit_size = 32;
bit_mask = -1LL;
} else {
bit_pos = (vtop->type.t >> VT_STRUCT_SHIFT) & 0x3f;
bit_size = (vtop->type.t >> (VT_STRUCT_SHIFT + 6)) & 0x3f;
bit_mask = (1LL << bit_size) - 1;
}
if ((vtop->r & VT_SYM) &&
(bt == VT_BYTE ||
bt == VT_SHORT ||
bt == VT_DOUBLE ||
bt == VT_LDOUBLE ||
bt == VT_LLONG ||
(bt == VT_INT && bit_size != 32)))
error("initializer element is not computable at load time");
switch(bt) {
case VT_BOOL:
vtop->c.i = (vtop->c.i != 0);
case VT_BYTE:
*(char *)ptr |= (vtop->c.i & bit_mask) << bit_pos;
break;
case VT_SHORT:
*(short *)ptr |= (vtop->c.i & bit_mask) << bit_pos;
break;
case VT_DOUBLE:
*(double *)ptr = vtop->c.d;
break;
case VT_LDOUBLE:
*(long double *)ptr = vtop->c.ld;
break;
case VT_LLONG:
*(long long *)ptr |= (vtop->c.ll & bit_mask) << bit_pos;
break;
default:
if (vtop->r & VT_SYM) {
greloc(sec, vtop->sym, c, R_DATA_PTR);
2009-05-05 22:18:10 +04:00
}
*(int *)ptr |= (vtop->c.i & bit_mask) << bit_pos;
break;
}
vtop--;
} else {
vset(&dtype, VT_LOCAL|VT_LVAL, c);
vswap();
vstore();
vpop();
}
}
/* put zeros for variable based init */
static void init_putz(CType *t, Section *sec, unsigned long c, int size)
{
if (sec) {
/* nothing to do because globals are already set to zero */
} else {
vpush_global_sym(&func_old_type, TOK_memset);
vseti(VT_LOCAL, c);
vpushi(0);
vpushi(size);
gfunc_call(3);
}
}
/* 't' contains the type and storage info. 'c' is the offset of the
object in section 'sec'. If 'sec' is NULL, it means stack based
allocation. 'first' is true if array '{' must be read (multi
dimension implicit array init handling). 'size_only' is true if
size only evaluation is wanted (only for arrays). */
static void decl_initializer(CType *type, Section *sec, unsigned long c,
int first, int size_only)
{
int index, array_length, n, no_oblock, nb, parlevel, i;
int size1, align1, expr_type;
Sym *s, *f;
CType *t1;
if (type->t & VT_ARRAY) {
s = type->ref;
n = s->c;
array_length = 0;
t1 = pointed_type(type);
size1 = type_size(t1, &align1);
no_oblock = 1;
if ((first && tok != TOK_LSTR && tok != TOK_STR) ||
tok == '{') {
skip('{');
no_oblock = 0;
}
/* only parse strings here if correct type (otherwise: handle
them as ((w)char *) expressions */
if ((tok == TOK_LSTR &&
#ifdef TCC_TARGET_PE
(t1->t & VT_BTYPE) == VT_SHORT && (t1->t & VT_UNSIGNED)
#else
(t1->t & VT_BTYPE) == VT_INT
#endif
) || (tok == TOK_STR && (t1->t & VT_BTYPE) == VT_BYTE)) {
while (tok == TOK_STR || tok == TOK_LSTR) {
int cstr_len, ch;
CString *cstr;
cstr = tokc.cstr;
/* compute maximum number of chars wanted */
if (tok == TOK_STR)
cstr_len = cstr->size;
else
cstr_len = cstr->size / sizeof(nwchar_t);
cstr_len--;
nb = cstr_len;
if (n >= 0 && nb > (n - array_length))
nb = n - array_length;
if (!size_only) {
if (cstr_len > nb)
warning("initializer-string for array is too long");
/* in order to go faster for common case (char
string in global variable, we handle it
specifically */
if (sec && tok == TOK_STR && size1 == 1) {
memcpy(sec->data + c + array_length, cstr->data, nb);
} else {
for(i=0;i<nb;i++) {
if (tok == TOK_STR)
ch = ((unsigned char *)cstr->data)[i];
else
ch = ((nwchar_t *)cstr->data)[i];
init_putv(t1, sec, c + (array_length + i) * size1,
ch, EXPR_VAL);
}
}
}
array_length += nb;
next();
}
/* only add trailing zero if enough storage (no
warning in this case since it is standard) */
if (n < 0 || array_length < n) {
if (!size_only) {
init_putv(t1, sec, c + (array_length * size1), 0, EXPR_VAL);
}
array_length++;
}
} else {
index = 0;
while (tok != '}') {
decl_designator(type, sec, c, &index, NULL, size_only);
if (n >= 0 && index >= n)
error("index too large");
/* must put zero in holes (note that doing it that way
ensures that it even works with designators) */
if (!size_only && array_length < index) {
init_putz(t1, sec, c + array_length * size1,
(index - array_length) * size1);
}
index++;
if (index > array_length)
array_length = index;
/* special test for multi dimensional arrays (may not
be strictly correct if designators are used at the
same time) */
if (index >= n && no_oblock)
break;
if (tok == '}')
break;
skip(',');
}
}
if (!no_oblock)
skip('}');
/* put zeros at the end */
if (!size_only && n >= 0 && array_length < n) {
init_putz(t1, sec, c + array_length * size1,
(n - array_length) * size1);
}
/* patch type size if needed */
if (n < 0)
s->c = array_length;
} else if ((type->t & VT_BTYPE) == VT_STRUCT &&
(sec || !first || tok == '{')) {
int par_count;
/* NOTE: the previous test is a specific case for automatic
struct/union init */
/* XXX: union needs only one init */
/* XXX: this test is incorrect for local initializers
beginning with ( without {. It would be much more difficult
to do it correctly (ideally, the expression parser should
be used in all cases) */
par_count = 0;
if (tok == '(') {
AttributeDef ad1;
CType type1;
next();
while (tok == '(') {
par_count++;
next();
}
if (!parse_btype(&type1, &ad1))
expect("cast");
type_decl(&type1, &ad1, &n, TYPE_ABSTRACT);
#if 0
if (!is_assignable_types(type, &type1))
error("invalid type for cast");
#endif
skip(')');
}
no_oblock = 1;
if (first || tok == '{') {
skip('{');
no_oblock = 0;
}
s = type->ref;
f = s->next;
array_length = 0;
index = 0;
n = s->c;
while (tok != '}') {
decl_designator(type, sec, c, NULL, &f, size_only);
index = f->c;
if (!size_only && array_length < index) {
init_putz(type, sec, c + array_length,
index - array_length);
}
index = index + type_size(&f->type, &align1);
if (index > array_length)
array_length = index;
/* gr: skip fields from same union - ugly. */
while (f->next) {
///printf("index: %2d %08x -- %2d %08x\n", f->c, f->type.t, f->next->c, f->next->type.t);
/* test for same offset */
if (f->next->c != f->c)
break;
/* if yes, test for bitfield shift */
if ((f->type.t & VT_BITFIELD) && (f->next->type.t & VT_BITFIELD)) {
int bit_pos_1 = (f->type.t >> VT_STRUCT_SHIFT) & 0x3f;
int bit_pos_2 = (f->next->type.t >> VT_STRUCT_SHIFT) & 0x3f;
//printf("bitfield %d %d\n", bit_pos_1, bit_pos_2);
if (bit_pos_1 != bit_pos_2)
break;
}
f = f->next;
}
2009-05-05 22:18:10 +04:00
f = f->next;
if (no_oblock && f == NULL)
break;
if (tok == '}')
break;
skip(',');
}
/* put zeros at the end */
if (!size_only && array_length < n) {
init_putz(type, sec, c + array_length,
n - array_length);
}
if (!no_oblock)
skip('}');
while (par_count) {
skip(')');
par_count--;
}
} else if (tok == '{') {
next();
decl_initializer(type, sec, c, first, size_only);
skip('}');
} else if (size_only) {
/* just skip expression */
parlevel = 0;
while ((parlevel > 0 || (tok != '}' && tok != ',')) &&
tok != -1) {
if (tok == '(')
parlevel++;
else if (tok == ')')
parlevel--;
next();
}
} else {
/* currently, we always use constant expression for globals
(may change for scripting case) */
expr_type = EXPR_CONST;
if (!sec)
expr_type = EXPR_ANY;
init_putv(type, sec, c, 0, expr_type);
}
}
/* parse an initializer for type 't' if 'has_init' is non zero, and
allocate space in local or global data space ('r' is either
VT_LOCAL or VT_CONST). If 'v' is non zero, then an associated
variable 'v' of scope 'scope' is declared before initializers are
parsed. If 'v' is zero, then a reference to the new object is put
in the value stack. If 'has_init' is 2, a special parsing is done
to handle string constants. */
static void decl_initializer_alloc(CType *type, AttributeDef *ad, int r,
int has_init, int v, int scope)
{
int size, align, addr, data_offset;
int level;
ParseState saved_parse_state = {0};
TokenString init_str;
Section *sec;
size = type_size(type, &align);
/* If unknown size, we must evaluate it before
evaluating initializers because
initializers can generate global data too
(e.g. string pointers or ISOC99 compound
literals). It also simplifies local
initializers handling */
tok_str_new(&init_str);
if (size < 0) {
if (!has_init)
error("unknown type size");
/* get all init string */
if (has_init == 2) {
/* only get strings */
while (tok == TOK_STR || tok == TOK_LSTR) {
tok_str_add_tok(&init_str);
next();
}
} else {
level = 0;
while (level > 0 || (tok != ',' && tok != ';')) {
if (tok < 0)
error("unexpected end of file in initializer");
tok_str_add_tok(&init_str);
if (tok == '{')
level++;
else if (tok == '}') {
level--;
if (level <= 0) {
next();
break;
}
}
next();
}
}
tok_str_add(&init_str, -1);
tok_str_add(&init_str, 0);
/* compute size */
save_parse_state(&saved_parse_state);
macro_ptr = init_str.str;
next();
decl_initializer(type, NULL, 0, 1, 1);
/* prepare second initializer parsing */
macro_ptr = init_str.str;
next();
/* if still unknown size, error */
size = type_size(type, &align);
if (size < 0)
error("unknown type size");
}
/* take into account specified alignment if bigger */
if (ad->aligned) {
if (ad->aligned > align)
align = ad->aligned;
} else if (ad->packed) {
align = 1;
}
if ((r & VT_VALMASK) == VT_LOCAL) {
sec = NULL;
if (tcc_state->do_bounds_check && (type->t & VT_ARRAY))
2009-05-05 22:18:10 +04:00
loc--;
loc = (loc - size) & -align;
addr = loc;
/* handles bounds */
/* XXX: currently, since we do only one pass, we cannot track
'&' operators, so we add only arrays */
if (tcc_state->do_bounds_check && (type->t & VT_ARRAY)) {
2009-05-05 22:18:10 +04:00
unsigned long *bounds_ptr;
/* add padding between regions */
loc--;
/* then add local bound info */
bounds_ptr = section_ptr_add(lbounds_section, 2 * sizeof(unsigned long));
bounds_ptr[0] = addr;
bounds_ptr[1] = size;
}
if (v) {
/* local variable */
sym_push(v, type, r, addr);
} else {
/* push local reference */
vset(type, r, addr);
}
} else {
Sym *sym;
sym = NULL;
if (v && scope == VT_CONST) {
/* see if the symbol was already defined */
sym = sym_find(v);
if (sym) {
if (!is_compatible_types(&sym->type, type))
error("incompatible types for redefinition of '%s'",
get_tok_str(v, NULL));
if (sym->type.t & VT_EXTERN) {
/* if the variable is extern, it was not allocated */
sym->type.t &= ~VT_EXTERN;
/* set array size if it was ommited in extern
declaration */
if ((sym->type.t & VT_ARRAY) &&
sym->type.ref->c < 0 &&
type->ref->c >= 0)
sym->type.ref->c = type->ref->c;
} else {
/* we accept several definitions of the same
global variable. this is tricky, because we
must play with the SHN_COMMON type of the symbol */
/* XXX: should check if the variable was already
initialized. It is incorrect to initialized it
twice */
/* no init data, we won't add more to the symbol */
if (!has_init)
goto no_alloc;
}
}
}
/* allocate symbol in corresponding section */
sec = ad->section;
if (!sec) {
if (has_init)
sec = data_section;
else if (tcc_state->nocommon)
sec = bss_section;
}
if (sec) {
data_offset = sec->data_offset;
data_offset = (data_offset + align - 1) & -align;
addr = data_offset;
/* very important to increment global pointer at this time
because initializers themselves can create new initializers */
data_offset += size;
/* add padding if bound check */
if (tcc_state->do_bounds_check)
2009-05-05 22:18:10 +04:00
data_offset++;
sec->data_offset = data_offset;
/* allocate section space to put the data */
if (sec->sh_type != SHT_NOBITS &&
data_offset > sec->data_allocated)
section_realloc(sec, data_offset);
/* align section if needed */
if (align > sec->sh_addralign)
sec->sh_addralign = align;
} else {
addr = 0; /* avoid warning */
}
if (v) {
if (scope != VT_CONST || !sym) {
sym = sym_push(v, type, r | VT_SYM, 0);
}
/* update symbol definition */
if (sec) {
put_extern_sym(sym, sec, addr, size);
} else {
ElfW(Sym) *esym;
/* put a common area */
put_extern_sym(sym, NULL, align, size);
/* XXX: find a nicer way */
esym = &((ElfW(Sym) *)symtab_section->data)[sym->c];
esym->st_shndx = SHN_COMMON;
}
} else {
CValue cval;
/* push global reference */
sym = get_sym_ref(type, sec, addr, size);
cval.ul = 0;
vsetc(type, VT_CONST | VT_SYM, &cval);
vtop->sym = sym;
}
/* handles bounds now because the symbol must be defined
before for the relocation */
if (tcc_state->do_bounds_check) {
2009-05-05 22:18:10 +04:00
unsigned long *bounds_ptr;
greloc(bounds_section, sym, bounds_section->data_offset, R_DATA_PTR);
2009-05-05 22:18:10 +04:00
/* then add global bound info */
bounds_ptr = section_ptr_add(bounds_section, 2 * sizeof(long));
bounds_ptr[0] = 0; /* relocated */
bounds_ptr[1] = size;
}
}
if (has_init) {
decl_initializer(type, sec, addr, 1, 0);
/* restore parse state if needed */
if (init_str.str) {
tok_str_free(init_str.str);
restore_parse_state(&saved_parse_state);
}
}
no_alloc: ;
}
void put_func_debug(Sym *sym)
{
char buf[512];
/* stabs info */
/* XXX: we put here a dummy type */
snprintf(buf, sizeof(buf), "%s:%c1",
funcname, sym->type.t & VT_STATIC ? 'f' : 'F');
put_stabs_r(buf, N_FUN, 0, file->line_num, 0,
cur_text_section, sym->c);
/* //gr gdb wants a line at the function */
put_stabn(N_SLINE, 0, file->line_num, 0);
last_ind = 0;
last_line_num = 0;
}
/* parse an old style function declaration list */
/* XXX: check multiple parameter */
static void func_decl_list(Sym *func_sym)
{
AttributeDef ad;
int v;
Sym *s;
CType btype, type;
/* parse each declaration */
while (tok != '{' && tok != ';' && tok != ',' && tok != TOK_EOF) {
if (!parse_btype(&btype, &ad))
expect("declaration list");
if (((btype.t & VT_BTYPE) == VT_ENUM ||
(btype.t & VT_BTYPE) == VT_STRUCT) &&
tok == ';') {
/* we accept no variable after */
} else {
for(;;) {
type = btype;
type_decl(&type, &ad, &v, TYPE_DIRECT);
/* find parameter in function parameter list */
s = func_sym->next;
while (s != NULL) {
if ((s->v & ~SYM_FIELD) == v)
goto found;
s = s->next;
}
error("declaration for parameter '%s' but no such parameter",
get_tok_str(v, NULL));
found:
/* check that no storage specifier except 'register' was given */
if (type.t & VT_STORAGE)
error("storage class specified for '%s'", get_tok_str(v, NULL));
convert_parameter_type(&type);
/* we can add the type (NOTE: it could be local to the function) */
s->type = type;
/* accept other parameters */
if (tok == ',')
next();
else
break;
}
}
skip(';');
}
}
/* parse a function defined by symbol 'sym' and generate its code in
'cur_text_section' */
static void gen_function(Sym *sym)
{
int saved_nocode_wanted = nocode_wanted;
nocode_wanted = 0;
ind = cur_text_section->data_offset;
/* NOTE: we patch the symbol size later */
put_extern_sym(sym, cur_text_section, ind, 0);
funcname = get_tok_str(sym->v, NULL);
func_ind = ind;
/* put debug symbol */
if (tcc_state->do_debug)
2009-05-05 22:18:10 +04:00
put_func_debug(sym);
/* push a dummy symbol to enable local sym storage */
sym_push2(&local_stack, SYM_FIELD, 0, 0);
gfunc_prolog(&sym->type);
rsym = 0;
block(NULL, NULL, NULL, NULL, 0, 0);
gsym(rsym);
gfunc_epilog();
cur_text_section->data_offset = ind;
label_pop(&global_label_stack, NULL);
sym_pop(&local_stack, NULL); /* reset local stack */
/* end of function */
/* patch symbol size */
((ElfW(Sym) *)symtab_section->data)[sym->c].st_size =
ind - func_ind;
if (tcc_state->do_debug) {
2009-05-05 22:18:10 +04:00
put_stabn(N_FUN, 0, 0, ind - func_ind);
}
/* It's better to crash than to generate wrong code */
cur_text_section = NULL;
funcname = ""; /* for safety */
func_vt.t = VT_VOID; /* for safety */
ind = 0; /* for safety */
nocode_wanted = saved_nocode_wanted;
}
static void gen_inline_functions(void)
{
Sym *sym;
int *str, inline_generated, i;
struct InlineFunc *fn;
2009-05-05 22:18:10 +04:00
/* iterate while inline function are referenced */
for(;;) {
inline_generated = 0;
for (i = 0; i < tcc_state->nb_inline_fns; ++i) {
fn = tcc_state->inline_fns[i];
sym = fn->sym;
if (sym && sym->c) {
2009-05-05 22:18:10 +04:00
/* the function was used: generate its code and
convert it to a normal function */
str = fn->token_str;
fn->sym = NULL;
if (file)
strcpy(file->filename, fn->filename);
2009-05-05 22:18:10 +04:00
sym->r = VT_SYM | VT_CONST;
sym->type.t &= ~VT_INLINE;
macro_ptr = str;
next();
cur_text_section = text_section;
gen_function(sym);
macro_ptr = NULL; /* fail safe */
inline_generated = 1;
}
}
if (!inline_generated)
break;
}
for (i = 0; i < tcc_state->nb_inline_fns; ++i) {
fn = tcc_state->inline_fns[i];
str = fn->token_str;
tok_str_free(str);
}
dynarray_reset(&tcc_state->inline_fns, &tcc_state->nb_inline_fns);
2009-05-05 22:18:10 +04:00
}
/* 'l' is VT_LOCAL or VT_CONST to define default storage type */
static void decl(int l)
{
int v, has_init, r;
CType type, btype;
Sym *sym;
AttributeDef ad;
while (1) {
if (!parse_btype(&btype, &ad)) {
/* skip redundant ';' */
/* XXX: find more elegant solution */
if (tok == ';') {
next();
continue;
}
if (l == VT_CONST &&
(tok == TOK_ASM1 || tok == TOK_ASM2 || tok == TOK_ASM3)) {
/* global asm block */
asm_global_instr();
continue;
}
/* special test for old K&R protos without explicit int
type. Only accepted when defining global data */
if (l == VT_LOCAL || tok < TOK_DEFINE)
break;
btype.t = VT_INT;
}
if (((btype.t & VT_BTYPE) == VT_ENUM ||
(btype.t & VT_BTYPE) == VT_STRUCT) &&
tok == ';') {
/* we accept no variable after */
next();
continue;
}
while (1) { /* iterate thru each declaration */
type = btype;
type_decl(&type, &ad, &v, TYPE_DIRECT);
#if 0
{
char buf[500];
type_to_str(buf, sizeof(buf), t, get_tok_str(v, NULL));
printf("type = '%s'\n", buf);
}
#endif
if ((type.t & VT_BTYPE) == VT_FUNC) {
/* if old style function prototype, we accept a
declaration list */
sym = type.ref;
if (sym->c == FUNC_OLD)
func_decl_list(sym);
}
if (tok == '{') {
if (l == VT_LOCAL)
error("cannot use local functions");
if ((type.t & VT_BTYPE) != VT_FUNC)
expect("function definition");
/* reject abstract declarators in function definition */
sym = type.ref;
while ((sym = sym->next) != NULL)
if (!(sym->v & ~SYM_FIELD))
expect("identifier");
/* XXX: cannot do better now: convert extern line to static inline */
if ((type.t & (VT_EXTERN | VT_INLINE)) == (VT_EXTERN | VT_INLINE))
type.t = (type.t & ~VT_EXTERN) | VT_STATIC;
sym = sym_find(v);
if (sym) {
if ((sym->type.t & VT_BTYPE) != VT_FUNC)
goto func_error1;
2009-05-05 22:18:10 +04:00
r = sym->type.ref->r;
/* use func_call from prototype if not defined */
2009-05-05 22:18:10 +04:00
if (FUNC_CALL(r) != FUNC_CDECL
&& FUNC_CALL(type.ref->r) == FUNC_CDECL)
FUNC_CALL(type.ref->r) = FUNC_CALL(r);
/* use export from prototype */
2009-05-05 22:18:10 +04:00
if (FUNC_EXPORT(r))
FUNC_EXPORT(type.ref->r) = 1;
/* use static from prototype */
if (sym->type.t & VT_STATIC)
type.t = (type.t & ~VT_EXTERN) | VT_STATIC;
2009-05-05 22:18:10 +04:00
if (!is_compatible_types(&sym->type, &type)) {
func_error1:
error("incompatible types for redefinition of '%s'",
get_tok_str(v, NULL));
}
/* if symbol is already defined, then put complete type */
sym->type = type;
} else {
/* put function symbol */
sym = global_identifier_push(v, type.t, 0);
sym->type.ref = type.ref;
}
/* static inline functions are just recorded as a kind
of macro. Their code will be emitted at the end of
the compilation unit only if they are used */
if ((type.t & (VT_INLINE | VT_STATIC)) ==
(VT_INLINE | VT_STATIC)) {
TokenString func_str;
int block_level;
struct InlineFunc *fn;
const char *filename;
2009-05-05 22:18:10 +04:00
tok_str_new(&func_str);
block_level = 0;
for(;;) {
int t;
if (tok == TOK_EOF)
error("unexpected end of file");
tok_str_add_tok(&func_str);
t = tok;
next();
if (t == '{') {
block_level++;
} else if (t == '}') {
block_level--;
if (block_level == 0)
break;
}
}
tok_str_add(&func_str, -1);
tok_str_add(&func_str, 0);
filename = file ? file->filename : "";
fn = tcc_malloc(sizeof *fn + strlen(filename));
strcpy(fn->filename, filename);
fn->sym = sym;
fn->token_str = func_str.str;
dynarray_add((void ***)&tcc_state->inline_fns, &tcc_state->nb_inline_fns, fn);
2009-05-05 22:18:10 +04:00
} else {
/* compute text section */
cur_text_section = ad.section;
if (!cur_text_section)
cur_text_section = text_section;
sym->r = VT_SYM | VT_CONST;
gen_function(sym);
}
break;
} else {
if (btype.t & VT_TYPEDEF) {
/* save typedefed type */
/* XXX: test storage specifiers ? */
sym = sym_push(v, &type, INT_ATTR(&ad), 0);
2009-05-05 22:18:10 +04:00
sym->type.t |= VT_TYPEDEF;
} else if ((type.t & VT_BTYPE) == VT_FUNC) {
/* external function definition */
/* specific case for func_call attribute */
type.ref->r = INT_ATTR(&ad);
2009-05-05 22:18:10 +04:00
external_sym(v, &type, 0);
} else {
/* not lvalue if array */
r = 0;
if (!(type.t & VT_ARRAY))
r |= lvalue_type(type.t);
has_init = (tok == '=');
if ((btype.t & VT_EXTERN) ||
((type.t & VT_ARRAY) && (type.t & VT_STATIC) &&
!has_init && l == VT_CONST && type.ref->c < 0)) {
/* external variable */
/* NOTE: as GCC, uninitialized global static
arrays of null size are considered as
extern */
2009-11-13 19:14:05 +03:00
#ifdef TCC_TARGET_PE
if (ad.func_import)
2009-11-13 19:14:05 +03:00
type.t |= VT_IMPORT;
#endif
2009-05-05 22:18:10 +04:00
external_sym(v, &type, r);
} else {
type.t |= (btype.t & VT_STATIC); /* Retain "static". */
if (type.t & VT_STATIC)
r |= VT_CONST;
else
r |= l;
if (has_init)
next();
decl_initializer_alloc(&type, &ad, r,
has_init, v, l);
}
}
if (tok != ',') {
skip(';');
break;
}
next();
}
}
}
}