/* * ARMv4 code generator for TCC * * Copyright (c) 2003 Daniel Glöckner * Copyright (c) 2012 Thomas Preud'homme * * Based on i386-gen.c by 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 */ #ifdef TARGET_DEFS_ONLY #if defined(TCC_ARM_EABI) && !defined(TCC_ARM_VFP) #error "Currently TinyCC only supports float computation with VFP instructions" #endif /* number of available registers */ #ifdef TCC_ARM_VFP #define NB_REGS 13 #else #define NB_REGS 9 #endif #ifndef TCC_CPU_VERSION # define TCC_CPU_VERSION 5 #endif /* a register can belong to several classes. The classes must be sorted from more general to more precise (see gv2() code which does assumptions on it). */ #define RC_INT 0x0001 /* generic integer register */ #define RC_FLOAT 0x0002 /* generic float register */ #define RC_R0 0x0004 #define RC_R1 0x0008 #define RC_R2 0x0010 #define RC_R3 0x0020 #define RC_R12 0x0040 #define RC_F0 0x0080 #define RC_F1 0x0100 #define RC_F2 0x0200 #define RC_F3 0x0400 #ifdef TCC_ARM_VFP #define RC_F4 0x0800 #define RC_F5 0x1000 #define RC_F6 0x2000 #define RC_F7 0x4000 #endif #define RC_IRET RC_R0 /* function return: integer register */ #define RC_LRET RC_R1 /* function return: second integer register */ #define RC_FRET RC_F0 /* function return: float register */ /* pretty names for the registers */ enum { TREG_R0 = 0, TREG_R1, TREG_R2, TREG_R3, TREG_R12, TREG_F0, TREG_F1, TREG_F2, TREG_F3, #ifdef TCC_ARM_VFP TREG_F4, TREG_F5, TREG_F6, TREG_F7, #endif TREG_SP = 13, TREG_LR, }; #ifdef TCC_ARM_VFP #define T2CPR(t) (((t) & VT_BTYPE) != VT_FLOAT ? 0x100 : 0) #endif /* return registers for function */ #define REG_IRET TREG_R0 /* single word int return register */ #define REG_LRET TREG_R1 /* second word return register (for long long) */ #define REG_FRET TREG_F0 /* float return register */ #ifdef TCC_ARM_EABI #define TOK___divdi3 TOK___aeabi_ldivmod #define TOK___moddi3 TOK___aeabi_ldivmod #define TOK___udivdi3 TOK___aeabi_uldivmod #define TOK___umoddi3 TOK___aeabi_uldivmod #endif /* defined if function parameters must be evaluated in reverse order */ #define INVERT_FUNC_PARAMS /* defined if structures are passed as pointers. Otherwise structures are directly pushed on stack. */ /* #define FUNC_STRUCT_PARAM_AS_PTR */ /* pointer size, in bytes */ #define PTR_SIZE 4 /* long double size and alignment, in bytes */ #ifdef TCC_ARM_VFP #define LDOUBLE_SIZE 8 #endif #ifndef LDOUBLE_SIZE #define LDOUBLE_SIZE 8 #endif #ifdef TCC_ARM_EABI #define LDOUBLE_ALIGN 8 #else #define LDOUBLE_ALIGN 4 #endif /* maximum alignment (for aligned attribute support) */ #define MAX_ALIGN 8 #define CHAR_IS_UNSIGNED /******************************************************/ #else /* ! TARGET_DEFS_ONLY */ /******************************************************/ #include "tcc.h" enum float_abi float_abi; ST_DATA const int reg_classes[NB_REGS] = { /* r0 */ RC_INT | RC_R0, /* r1 */ RC_INT | RC_R1, /* r2 */ RC_INT | RC_R2, /* r3 */ RC_INT | RC_R3, /* r12 */ RC_INT | RC_R12, /* f0 */ RC_FLOAT | RC_F0, /* f1 */ RC_FLOAT | RC_F1, /* f2 */ RC_FLOAT | RC_F2, /* f3 */ RC_FLOAT | RC_F3, #ifdef TCC_ARM_VFP /* d4/s8 */ RC_FLOAT | RC_F4, /* d5/s10 */ RC_FLOAT | RC_F5, /* d6/s12 */ RC_FLOAT | RC_F6, /* d7/s14 */ RC_FLOAT | RC_F7, #endif }; static int func_sub_sp_offset, last_itod_magic; static int leaffunc; #if defined(TCC_ARM_EABI) && defined(TCC_ARM_VFP) static CType float_type, double_type, func_float_type, func_double_type; ST_FUNC void arm_init(struct TCCState *s) { float_type.t = VT_FLOAT; double_type.t = VT_DOUBLE; func_float_type.t = VT_FUNC; func_float_type.ref = sym_push(SYM_FIELD, &float_type, FUNC_CDECL, FUNC_OLD); func_double_type.t = VT_FUNC; func_double_type.ref = sym_push(SYM_FIELD, &double_type, FUNC_CDECL, FUNC_OLD); float_abi = s->float_abi; #ifndef TCC_ARM_HARDFLOAT tcc_warning("soft float ABI currently not supported: default to softfp"); #endif } #else #define func_float_type func_old_type #define func_double_type func_old_type #define func_ldouble_type func_old_type ST_FUNC void arm_init(struct TCCState *s) { #if 0 #if !defined (TCC_ARM_VFP) tcc_warning("Support for FPA is deprecated and will be removed in next" " release"); #endif #if !defined (TCC_ARM_EABI) tcc_warning("Support for OABI is deprecated and will be removed in next" " release"); #endif #endif } #endif static int two2mask(int a,int b) { return (reg_classes[a]|reg_classes[b])&~(RC_INT|RC_FLOAT); } static int regmask(int r) { return reg_classes[r]&~(RC_INT|RC_FLOAT); } /******************************************************/ #if defined(TCC_ARM_EABI) && !defined(CONFIG_TCC_ELFINTERP) const char *default_elfinterp(struct TCCState *s) { if (s->float_abi == ARM_HARD_FLOAT) return "/lib/ld-linux-armhf.so.3"; else return "/lib/ld-linux.so.3"; } #endif void o(uint32_t i) { /* this is a good place to start adding big-endian support*/ int ind1; if (nocode_wanted) return; ind1 = ind + 4; if (!cur_text_section) tcc_error("compiler error! This happens f.ex. if the compiler\n" "can't evaluate constant expressions outside of a function."); if (ind1 > cur_text_section->data_allocated) section_realloc(cur_text_section, ind1); cur_text_section->data[ind++] = i&255; i>>=8; cur_text_section->data[ind++] = i&255; i>>=8; cur_text_section->data[ind++] = i&255; i>>=8; cur_text_section->data[ind++] = i; } static uint32_t stuff_const(uint32_t op, uint32_t c) { int try_neg=0; uint32_t nc = 0, negop = 0; switch(op&0x1F00000) { case 0x800000: //add case 0x400000: //sub try_neg=1; negop=op^0xC00000; nc=-c; break; case 0x1A00000: //mov case 0x1E00000: //mvn try_neg=1; negop=op^0x400000; nc=~c; break; case 0x200000: //xor if(c==~0) return (op&0xF010F000)|((op>>16)&0xF)|0x1E00000; break; case 0x0: //and if(c==~0) return (op&0xF010F000)|((op>>16)&0xF)|0x1A00000; case 0x1C00000: //bic try_neg=1; negop=op^0x1C00000; nc=~c; break; case 0x1800000: //orr if(c==~0) return (op&0xFFF0FFFF)|0x1E00000; break; } do { uint32_t m; int i; if(c<256) /* catch undefined <<32 */ return op|c; for(i=2;i<32;i+=2) { m=(0xff>>i)|(0xff<<(32-i)); if(!(c&~m)) return op|(i<<7)|(c<>(32-i)); } op=negop; c=nc; } while(try_neg--); return 0; } //only add,sub void stuff_const_harder(uint32_t op, uint32_t v) { uint32_t x; x=stuff_const(op,v); if(x) o(x); else { uint32_t a[16], nv, no, o2, n2; int i,j,k; a[0]=0xff; o2=(op&0xfff0ffff)|((op&0xf000)<<4);; for(i=1;i<16;i++) a[i]=(a[i-1]>>2)|(a[i-1]<<30); for(i=0;i<12;i++) for(j=i<4?i+12:15;j>=i+4;j--) if((v&(a[i]|a[j]))==v) { o(stuff_const(op,v&a[i])); o(stuff_const(o2,v&a[j])); return; } no=op^0xC00000; n2=o2^0xC00000; nv=-v; for(i=0;i<12;i++) for(j=i<4?i+12:15;j>=i+4;j--) if((nv&(a[i]|a[j]))==nv) { o(stuff_const(no,nv&a[i])); o(stuff_const(n2,nv&a[j])); return; } for(i=0;i<8;i++) for(j=i+4;j<12;j++) for(k=i<4?i+12:15;k>=j+4;k--) if((v&(a[i]|a[j]|a[k]))==v) { o(stuff_const(op,v&a[i])); o(stuff_const(o2,v&a[j])); o(stuff_const(o2,v&a[k])); return; } no=op^0xC00000; nv=-v; for(i=0;i<8;i++) for(j=i+4;j<12;j++) for(k=i<4?i+12:15;k>=j+4;k--) if((nv&(a[i]|a[j]|a[k]))==nv) { o(stuff_const(no,nv&a[i])); o(stuff_const(n2,nv&a[j])); o(stuff_const(n2,nv&a[k])); return; } o(stuff_const(op,v&a[0])); o(stuff_const(o2,v&a[4])); o(stuff_const(o2,v&a[8])); o(stuff_const(o2,v&a[12])); } } uint32_t encbranch(int pos, int addr, int fail) { addr-=pos+8; addr/=4; if(addr>=0x1000000 || addr<-0x1000000) { if(fail) tcc_error("FIXME: function bigger than 32MB"); return 0; } return 0x0A000000|(addr&0xffffff); } int decbranch(int pos) { int x; x=*(uint32_t *)(cur_text_section->data + pos); x&=0x00ffffff; if(x&0x800000) x-=0x1000000; return x*4+pos+8; } /* output a symbol and patch all calls to it */ void gsym_addr(int t, int a) { uint32_t *x; int lt; while(t) { x=(uint32_t *)(cur_text_section->data + t); t=decbranch(lt=t); if(a==lt+4) *x=0xE1A00000; // nop else { *x &= 0xff000000; *x |= encbranch(lt,a,1); } } } void gsym(int t) { gsym_addr(t, ind); } #ifdef TCC_ARM_VFP static uint32_t vfpr(int r) { if(rTREG_F7) tcc_error("compiler error! register %i is no vfp register",r); return r - TREG_F0; } #else static uint32_t fpr(int r) { if(rTREG_F3) tcc_error("compiler error! register %i is no fpa register",r); return r - TREG_F0; } #endif static uint32_t intr(int r) { if(r == TREG_R12) return 12; if(r >= TREG_R0 && r <= TREG_R3) return r - TREG_R0; if (r >= TREG_SP && r <= TREG_LR) return r + (13 - TREG_SP); tcc_error("compiler error! register %i is no int register",r); } static void calcaddr(uint32_t *base, int *off, int *sgn, int maxoff, unsigned shift) { if(*off>maxoff || *off&((1<r; ft = sv->type.t; fc = sv->c.i; if(fc>=0) sign=0; else { sign=1; fc=-fc; } v = fr & VT_VALMASK; if (fr & VT_LVAL) { uint32_t base = 0xB; // fp if(v == VT_LLOCAL) { v1.type.t = VT_PTR; v1.r = VT_LOCAL | VT_LVAL; v1.c.i = sv->c.i; load(TREG_LR, &v1); base = 14; /* lr */ fc=sign=0; v=VT_LOCAL; } else if(v == VT_CONST) { v1.type.t = VT_PTR; v1.r = fr&~VT_LVAL; v1.c.i = sv->c.i; v1.sym=sv->sym; load(TREG_LR, &v1); base = 14; /* lr */ fc=sign=0; v=VT_LOCAL; } else if(v < VT_CONST) { base=intr(v); fc=sign=0; v=VT_LOCAL; } if(v == VT_LOCAL) { if(is_float(ft)) { calcaddr(&base,&fc,&sign,1020,2); #ifdef TCC_ARM_VFP op=0xED100A00; /* flds */ if(!sign) op|=0x800000; if ((ft & VT_BTYPE) != VT_FLOAT) op|=0x100; /* flds -> fldd */ o(op|(vfpr(r)<<12)|(fc>>2)|(base<<16)); #else op=0xED100100; if(!sign) op|=0x800000; #if LDOUBLE_SIZE == 8 if ((ft & VT_BTYPE) != VT_FLOAT) op|=0x8000; #else if ((ft & VT_BTYPE) == VT_DOUBLE) op|=0x8000; else if ((ft & VT_BTYPE) == VT_LDOUBLE) op|=0x400000; #endif o(op|(fpr(r)<<12)|(fc>>2)|(base<<16)); #endif } else if((ft & (VT_BTYPE|VT_UNSIGNED)) == VT_BYTE || (ft & VT_BTYPE) == VT_SHORT) { calcaddr(&base,&fc,&sign,255,0); op=0xE1500090; if ((ft & VT_BTYPE) == VT_SHORT) op|=0x20; if ((ft & VT_UNSIGNED) == 0) op|=0x40; if(!sign) op|=0x800000; o(op|(intr(r)<<12)|(base<<16)|((fc&0xf0)<<4)|(fc&0xf)); } else { calcaddr(&base,&fc,&sign,4095,0); op=0xE5100000; if(!sign) op|=0x800000; if ((ft & VT_BTYPE) == VT_BYTE || (ft & VT_BTYPE) == VT_BOOL) op|=0x400000; o(op|(intr(r)<<12)|fc|(base<<16)); } return; } } else { if (v == VT_CONST) { op=stuff_const(0xE3A00000|(intr(r)<<12),sv->c.i); if (fr & VT_SYM || !op) { o(0xE59F0000|(intr(r)<<12)); o(0xEA000000); if(fr & VT_SYM) greloc(cur_text_section, sv->sym, ind, R_ARM_ABS32); o(sv->c.i); } else o(op); return; } else if (v == VT_LOCAL) { op=stuff_const(0xE28B0000|(intr(r)<<12),sv->c.i); if (fr & VT_SYM || !op) { o(0xE59F0000|(intr(r)<<12)); o(0xEA000000); if(fr & VT_SYM) // needed ? greloc(cur_text_section, sv->sym, ind, R_ARM_ABS32); o(sv->c.i); o(0xE08B0000|(intr(r)<<12)|intr(r)); } else o(op); return; } else if(v == VT_CMP) { o(mapcc(sv->c.i)|0x3A00001|(intr(r)<<12)); o(mapcc(negcc(sv->c.i))|0x3A00000|(intr(r)<<12)); return; } else if (v == VT_JMP || v == VT_JMPI) { int t; t = v & 1; o(0xE3A00000|(intr(r)<<12)|t); o(0xEA000000); gsym(sv->c.i); o(0xE3A00000|(intr(r)<<12)|(t^1)); return; } else if (v < VT_CONST) { if(is_float(ft)) #ifdef TCC_ARM_VFP o(0xEEB00A40|(vfpr(r)<<12)|vfpr(v)|T2CPR(ft)); /* fcpyX */ #else o(0xEE008180|(fpr(r)<<12)|fpr(v)); #endif else o(0xE1A00000|(intr(r)<<12)|intr(v)); return; } } tcc_error("load unimplemented!"); } /* store register 'r' in lvalue 'v' */ void store(int r, SValue *sv) { SValue v1; int v, ft, fc, fr, sign; uint32_t op; fr = sv->r; ft = sv->type.t; fc = sv->c.i; if(fc>=0) sign=0; else { sign=1; fc=-fc; } v = fr & VT_VALMASK; if (fr & VT_LVAL || fr == VT_LOCAL) { uint32_t base = 0xb; /* fp */ if(v < VT_CONST) { base=intr(v); v=VT_LOCAL; fc=sign=0; } else if(v == VT_CONST) { v1.type.t = ft; v1.r = fr&~VT_LVAL; v1.c.i = sv->c.i; v1.sym=sv->sym; load(TREG_LR, &v1); base = 14; /* lr */ fc=sign=0; v=VT_LOCAL; } if(v == VT_LOCAL) { if(is_float(ft)) { calcaddr(&base,&fc,&sign,1020,2); #ifdef TCC_ARM_VFP op=0xED000A00; /* fsts */ if(!sign) op|=0x800000; if ((ft & VT_BTYPE) != VT_FLOAT) op|=0x100; /* fsts -> fstd */ o(op|(vfpr(r)<<12)|(fc>>2)|(base<<16)); #else op=0xED000100; if(!sign) op|=0x800000; #if LDOUBLE_SIZE == 8 if ((ft & VT_BTYPE) != VT_FLOAT) op|=0x8000; #else if ((ft & VT_BTYPE) == VT_DOUBLE) op|=0x8000; if ((ft & VT_BTYPE) == VT_LDOUBLE) op|=0x400000; #endif o(op|(fpr(r)<<12)|(fc>>2)|(base<<16)); #endif return; } else if((ft & VT_BTYPE) == VT_SHORT) { calcaddr(&base,&fc,&sign,255,0); op=0xE14000B0; if(!sign) op|=0x800000; o(op|(intr(r)<<12)|(base<<16)|((fc&0xf0)<<4)|(fc&0xf)); } else { calcaddr(&base,&fc,&sign,4095,0); op=0xE5000000; if(!sign) op|=0x800000; if ((ft & VT_BTYPE) == VT_BYTE || (ft & VT_BTYPE) == VT_BOOL) op|=0x400000; o(op|(intr(r)<<12)|fc|(base<<16)); } return; } } tcc_error("store unimplemented"); } static void gadd_sp(int val) { stuff_const_harder(0xE28DD000,val); } /* 'is_jmp' is '1' if it is a jump */ static void gcall_or_jmp(int is_jmp) { int r; uint32_t x; if ((vtop->r & (VT_VALMASK | VT_LVAL)) == VT_CONST) { /* constant case */ if(vtop->r & VT_SYM){ x=encbranch(ind,ind+vtop->c.i,0); if(x) { /* relocation case */ greloc(cur_text_section, vtop->sym, ind, R_ARM_PC24); o(x|(is_jmp?0xE0000000:0xE1000000)); } else { if(!is_jmp) o(0xE28FE004); // add lr,pc,#4 o(0xE51FF004); // ldr pc,[pc,#-4] greloc(cur_text_section, vtop->sym, ind, R_ARM_ABS32); o(vtop->c.i); } }else{ if(!is_jmp) o(0xE28FE004); // add lr,pc,#4 o(0xE51FF004); // ldr pc,[pc,#-4] o(vtop->c.i); } } else { /* otherwise, indirect call */ r = gv(RC_INT); if(!is_jmp) o(0xE1A0E00F); // mov lr,pc o(0xE1A0F000|intr(r)); // mov pc,r } } static int unalias_ldbl(int btype) { #if LDOUBLE_SIZE == 8 if (btype == VT_LDOUBLE) btype = VT_DOUBLE; #endif return btype; } /* Return whether a structure is an homogeneous float aggregate or not. The answer is true if all the elements of the structure are of the same primitive float type and there is less than 4 elements. type: the type corresponding to the structure to be tested */ static int is_hgen_float_aggr(CType *type) { if ((type->t & VT_BTYPE) == VT_STRUCT) { struct Sym *ref; int btype, nb_fields = 0; ref = type->ref->next; btype = unalias_ldbl(ref->type.t & VT_BTYPE); if (btype == VT_FLOAT || btype == VT_DOUBLE) { for(; ref && btype == unalias_ldbl(ref->type.t & VT_BTYPE); ref = ref->next, nb_fields++); return !ref && nb_fields <= 4; } } return 0; } struct avail_regs { signed char avail[3]; /* 3 holes max with only float and double alignments */ int first_hole; /* first available hole */ int last_hole; /* last available hole (none if equal to first_hole) */ int first_free_reg; /* next free register in the sequence, hole excluded */ }; #define AVAIL_REGS_INITIALIZER (struct avail_regs) { { 0, 0, 0}, 0, 0, 0 } /* Find suitable registers for a VFP Co-Processor Register Candidate (VFP CPRC param) according to the rules described in the procedure call standard for the ARM architecture (AAPCS). If found, the registers are assigned to this VFP CPRC parameter. Registers are allocated in sequence unless a hole exists and the parameter is a single float. avregs: opaque structure to keep track of available VFP co-processor regs align: alignment constraints for the param, as returned by type_size() size: size of the parameter, as returned by type_size() */ int assign_vfpreg(struct avail_regs *avregs, int align, int size) { int first_reg = 0; if (avregs->first_free_reg == -1) return -1; if (align >> 3) { /* double alignment */ first_reg = avregs->first_free_reg; /* alignment constraint not respected so use next reg and record hole */ if (first_reg & 1) avregs->avail[avregs->last_hole++] = first_reg++; } else { /* no special alignment (float or array of float) */ /* if single float and a hole is available, assign the param to it */ if (size == 4 && avregs->first_hole != avregs->last_hole) return avregs->avail[avregs->first_hole++]; else first_reg = avregs->first_free_reg; } if (first_reg + size / 4 <= 16) { avregs->first_free_reg = first_reg + size / 4; return first_reg; } avregs->first_free_reg = -1; return -1; } /* Returns whether all params need to be passed in core registers or not. This is the case for function part of the runtime ABI. */ int floats_in_core_regs(SValue *sval) { if (!sval->sym) return 0; switch (sval->sym->v) { case TOK___floatundisf: case TOK___floatundidf: case TOK___fixunssfdi: case TOK___fixunsdfdi: #ifndef TCC_ARM_VFP case TOK___fixunsxfdi: #endif case TOK___floatdisf: case TOK___floatdidf: case TOK___fixsfdi: case TOK___fixdfdi: return 1; default: return 0; } } /* Return the number of registers needed to return the struct, or 0 if returning via struct pointer. */ ST_FUNC int gfunc_sret(CType *vt, int variadic, CType *ret, int *ret_align, int *regsize) { #ifdef TCC_ARM_EABI int size, align; size = type_size(vt, &align); if (float_abi == ARM_HARD_FLOAT && !variadic && (is_float(vt->t) || is_hgen_float_aggr(vt))) { *ret_align = 8; *regsize = 8; ret->ref = NULL; ret->t = VT_DOUBLE; return (size + 7) >> 3; } else if (size <= 4) { *ret_align = 4; *regsize = 4; ret->ref = NULL; ret->t = VT_INT; return 1; } else return 0; #else return 0; #endif } /* Parameters are classified according to how they are copied to their final destination for the function call. Because the copying is performed class after class according to the order in the union below, it is important that some constraints about the order of the members of this union are respected: - CORE_STRUCT_CLASS must come after STACK_CLASS; - CORE_CLASS must come after STACK_CLASS, CORE_STRUCT_CLASS and VFP_STRUCT_CLASS; - VFP_STRUCT_CLASS must come after VFP_CLASS. See the comment for the main loop in copy_params() for the reason. */ enum reg_class { STACK_CLASS = 0, CORE_STRUCT_CLASS, VFP_CLASS, VFP_STRUCT_CLASS, CORE_CLASS, NB_CLASSES }; struct param_plan { int start; /* first reg or addr used depending on the class */ int end; /* last reg used or next free addr depending on the class */ SValue *sval; /* pointer to SValue on the value stack */ struct param_plan *prev; /* previous element in this class */ }; struct plan { struct param_plan *pplans; /* array of all the param plans */ struct param_plan *clsplans[NB_CLASSES]; /* per class lists of param plans */ }; #define add_param_plan(plan,pplan,class) \ do { \ pplan.prev = plan->clsplans[class]; \ plan->pplans[plan ## _nb] = pplan; \ plan->clsplans[class] = &plan->pplans[plan ## _nb++]; \ } while(0) /* Assign parameters to registers and stack with alignment according to the rules in the procedure call standard for the ARM architecture (AAPCS). The overall assignment is recorded in an array of per parameter structures called parameter plans. The parameter plans are also further organized in a number of linked lists, one per class of parameter (see the comment for the definition of union reg_class). nb_args: number of parameters of the function for which a call is generated float_abi: float ABI in use for this function call plan: the structure where the overall assignment is recorded todo: a bitmap that record which core registers hold a parameter Returns the amount of stack space needed for parameter passing Note: this function allocated an array in plan->pplans with tcc_malloc. It is the responsibility of the caller to free this array once used (ie not before copy_params). */ static int assign_regs(int nb_args, int float_abi, struct plan *plan, int *todo) { int i, size, align; int ncrn /* next core register number */, nsaa /* next stacked argument address*/; int plan_nb = 0; struct param_plan pplan; struct avail_regs avregs = AVAIL_REGS_INITIALIZER; ncrn = nsaa = 0; *todo = 0; plan->pplans = tcc_malloc(nb_args * sizeof(*plan->pplans)); memset(plan->clsplans, 0, sizeof(plan->clsplans)); for(i = nb_args; i-- ;) { int j, start_vfpreg = 0; CType type = vtop[-i].type; type.t &= ~VT_ARRAY; size = type_size(&type, &align); size = (size + 3) & ~3; align = (align + 3) & ~3; switch(vtop[-i].type.t & VT_BTYPE) { case VT_STRUCT: case VT_FLOAT: case VT_DOUBLE: case VT_LDOUBLE: if (float_abi == ARM_HARD_FLOAT) { int is_hfa = 0; /* Homogeneous float aggregate */ if (is_float(vtop[-i].type.t) || (is_hfa = is_hgen_float_aggr(&vtop[-i].type))) { int end_vfpreg; start_vfpreg = assign_vfpreg(&avregs, align, size); end_vfpreg = start_vfpreg + ((size - 1) >> 2); if (start_vfpreg >= 0) { pplan = (struct param_plan) {start_vfpreg, end_vfpreg, &vtop[-i]}; if (is_hfa) add_param_plan(plan, pplan, VFP_STRUCT_CLASS); else add_param_plan(plan, pplan, VFP_CLASS); continue; } else break; } } ncrn = (ncrn + (align-1)/4) & ~((align/4) - 1); if (ncrn + size/4 <= 4 || (ncrn < 4 && start_vfpreg != -1)) { /* The parameter is allocated both in core register and on stack. As * such, it can be of either class: it would either be the last of * CORE_STRUCT_CLASS or the first of STACK_CLASS. */ for (j = ncrn; j < 4 && j < ncrn + size / 4; j++) *todo|=(1< 4) nsaa = (ncrn - 4) * 4; } else { ncrn = 4; break; } continue; default: if (ncrn < 4) { int is_long = (vtop[-i].type.t & VT_BTYPE) == VT_LLONG; if (is_long) { ncrn = (ncrn + 1) & -2; if (ncrn == 4) break; } pplan = (struct param_plan) {ncrn, ncrn, &vtop[-i]}; ncrn++; if (is_long) pplan.end = ncrn++; add_param_plan(plan, pplan, CORE_CLASS); continue; } } nsaa = (nsaa + (align - 1)) & ~(align - 1); pplan = (struct param_plan) {nsaa, nsaa + size, &vtop[-i]}; add_param_plan(plan, pplan, STACK_CLASS); nsaa += size; /* size already rounded up before */ } return nsaa; } #undef add_param_plan /* Copy parameters to their final destination (core reg, VFP reg or stack) for function call. nb_args: number of parameters the function take plan: the overall assignment plan for parameters todo: a bitmap indicating what core reg will hold a parameter Returns the number of SValue added by this function on the value stack */ static int copy_params(int nb_args, struct plan *plan, int todo) { int size, align, r, i, nb_extra_sval = 0; struct param_plan *pplan; int pass = 0; /* Several constraints require parameters to be copied in a specific order: - structures are copied to the stack before being loaded in a reg; - floats loaded to an odd numbered VFP reg are first copied to the preceding even numbered VFP reg and then moved to the next VFP reg. It is thus important that: - structures assigned to core regs must be copied after parameters assigned to the stack but before structures assigned to VFP regs because a structure can lie partly in core registers and partly on the stack; - parameters assigned to the stack and all structures be copied before parameters assigned to a core reg since copying a parameter to the stack require using a core reg; - parameters assigned to VFP regs be copied before structures assigned to VFP regs as the copy might use an even numbered VFP reg that already holds part of a structure. */ again: for(i = 0; i < NB_CLASSES; i++) { for(pplan = plan->clsplans[i]; pplan; pplan = pplan->prev) { if (pass && (i != CORE_CLASS || pplan->sval->r < VT_CONST)) continue; vpushv(pplan->sval); pplan->sval->r = pplan->sval->r2 = VT_CONST; /* disable entry */ switch(i) { case STACK_CLASS: case CORE_STRUCT_CLASS: case VFP_STRUCT_CLASS: if ((pplan->sval->type.t & VT_BTYPE) == VT_STRUCT) { int padding = 0; size = type_size(&pplan->sval->type, &align); /* align to stack align size */ size = (size + 3) & ~3; if (i == STACK_CLASS && pplan->prev) padding = pplan->start - pplan->prev->end; size += padding; /* Add padding if any */ /* allocate the necessary size on stack */ gadd_sp(-size); /* generate structure store */ r = get_reg(RC_INT); o(0xE28D0000|(intr(r)<<12)|padding); /* add r, sp, padding */ vset(&vtop->type, r | VT_LVAL, 0); vswap(); vstore(); /* memcpy to current sp + potential padding */ /* Homogeneous float aggregate are loaded to VFP registers immediately since there is no way of loading data in multiple non consecutive VFP registers as what is done for other structures (see the use of todo). */ if (i == VFP_STRUCT_CLASS) { int first = pplan->start, nb = pplan->end - first + 1; /* vpop.32 {pplan->start, ..., pplan->end} */ o(0xECBD0A00|(first&1)<<22|(first>>1)<<12|nb); /* No need to write the register used to a SValue since VFP regs cannot be used for gcall_or_jmp */ } } else { if (is_float(pplan->sval->type.t)) { #ifdef TCC_ARM_VFP r = vfpr(gv(RC_FLOAT)) << 12; if ((pplan->sval->type.t & VT_BTYPE) == VT_FLOAT) size = 4; else { size = 8; r |= 0x101; /* vpush.32 -> vpush.64 */ } o(0xED2D0A01 + r); /* vpush */ #else r = fpr(gv(RC_FLOAT)) << 12; if ((pplan->sval->type.t & VT_BTYPE) == VT_FLOAT) size = 4; else if ((pplan->sval->type.t & VT_BTYPE) == VT_DOUBLE) size = 8; else size = LDOUBLE_SIZE; if (size == 12) r |= 0x400000; else if(size == 8) r|=0x8000; o(0xED2D0100|r|(size>>2)); /* some kind of vpush for FPA */ #endif } else { /* simple type (currently always same size) */ /* XXX: implicit cast ? */ size=4; if ((pplan->sval->type.t & VT_BTYPE) == VT_LLONG) { lexpand(); size = 8; r = gv(RC_INT); o(0xE52D0004|(intr(r)<<12)); /* push r */ vtop--; } r = gv(RC_INT); o(0xE52D0004|(intr(r)<<12)); /* push r */ } if (i == STACK_CLASS && pplan->prev) gadd_sp(pplan->prev->end - pplan->start); /* Add padding if any */ } break; case VFP_CLASS: gv(regmask(TREG_F0 + (pplan->start >> 1))); if (pplan->start & 1) { /* Must be in upper part of double register */ o(0xEEF00A40|((pplan->start>>1)<<12)|(pplan->start>>1)); /* vmov.f32 s(n+1), sn */ vtop->r = VT_CONST; /* avoid being saved on stack by gv for next float */ } break; case CORE_CLASS: if ((pplan->sval->type.t & VT_BTYPE) == VT_LLONG) { lexpand(); gv(regmask(pplan->end)); pplan->sval->r2 = vtop->r; vtop--; } gv(regmask(pplan->start)); /* Mark register as used so that gcall_or_jmp use another one (regs >=4 are free as never used to pass parameters) */ pplan->sval->r = vtop->r; break; } vtop--; } } /* second pass to restore registers that were saved on stack by accident. Maybe redundant after the "lvalue_save" patch in tccgen.c:gv() */ if (++pass < 2) goto again; /* Manually free remaining registers since next parameters are loaded * manually, without the help of gv(int). */ save_regs(nb_args); if(todo) { o(0xE8BD0000|todo); /* pop {todo} */ for(pplan = plan->clsplans[CORE_STRUCT_CLASS]; pplan; pplan = pplan->prev) { int r; pplan->sval->r = pplan->start; /* An SValue can only pin 2 registers at best (r and r2) but a structure can occupy more than 2 registers. Thus, we need to push on the value stack some fake parameter to have on SValue for each registers used by a structure (r2 is not used). */ for (r = pplan->start + 1; r <= pplan->end; r++) { if (todo & (1 << r)) { nb_extra_sval++; vpushi(0); vtop->r = r; } } } } return nb_extra_sval; } /* Generate function call. The function address is pushed first, then all the parameters in call order. This functions pops all the parameters and the function address. */ void gfunc_call(int nb_args) { int r, args_size; int def_float_abi = float_abi; int todo; struct plan plan; #ifdef TCC_ARM_EABI int variadic; if (float_abi == ARM_HARD_FLOAT) { variadic = (vtop[-nb_args].type.ref->f.func_type == FUNC_ELLIPSIS); if (variadic || floats_in_core_regs(&vtop[-nb_args])) float_abi = ARM_SOFTFP_FLOAT; } #endif /* 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. */ r = vtop->r & VT_VALMASK; if (r == VT_CMP || (r & ~1) == VT_JMP) gv(RC_INT); args_size = assign_regs(nb_args, float_abi, &plan, &todo); #ifdef TCC_ARM_EABI if (args_size & 7) { /* Stack must be 8 byte aligned at fct call for EABI */ args_size = (args_size + 7) & ~7; o(0xE24DD004); /* sub sp, sp, #4 */ } #endif nb_args += copy_params(nb_args, &plan, todo); tcc_free(plan.pplans); /* Move fct SValue on top as required by gcall_or_jmp */ vrotb(nb_args + 1); gcall_or_jmp(0); if (args_size) gadd_sp(args_size); /* pop all parameters passed on the stack */ #if defined(TCC_ARM_EABI) && defined(TCC_ARM_VFP) if(float_abi == ARM_SOFTFP_FLOAT && is_float(vtop->type.ref->type.t)) { if((vtop->type.ref->type.t & VT_BTYPE) == VT_FLOAT) { o(0xEE000A10); /*vmov s0, r0 */ } else { o(0xEE000B10); /* vmov.32 d0[0], r0 */ o(0xEE201B10); /* vmov.32 d0[1], r1 */ } } #endif vtop -= nb_args + 1; /* Pop all params and fct address from value stack */ leaffunc = 0; /* we are calling a function, so we aren't in a leaf function */ float_abi = def_float_abi; } /* generate function prolog of type 't' */ void gfunc_prolog(CType *func_type) { Sym *sym,*sym2; int n, nf, size, align, rs, struct_ret = 0; int addr, pn, sn; /* pn=core, sn=stack */ CType ret_type; #ifdef TCC_ARM_EABI struct avail_regs avregs = AVAIL_REGS_INITIALIZER; #endif sym = func_type->ref; func_vt = sym->type; func_var = (func_type->ref->f.func_type == FUNC_ELLIPSIS); n = nf = 0; if ((func_vt.t & VT_BTYPE) == VT_STRUCT && !gfunc_sret(&func_vt, func_var, &ret_type, &align, &rs)) { n++; struct_ret = 1; func_vc = 12; /* Offset from fp of the place to store the result */ } for(sym2 = sym->next; sym2 && (n < 4 || nf < 16); sym2 = sym2->next) { size = type_size(&sym2->type, &align); #ifdef TCC_ARM_EABI if (float_abi == ARM_HARD_FLOAT && !func_var && (is_float(sym2->type.t) || is_hgen_float_aggr(&sym2->type))) { int tmpnf = assign_vfpreg(&avregs, align, size); tmpnf += (size + 3) / 4; nf = (tmpnf > nf) ? tmpnf : nf; } else #endif if (n < 4) n += (size + 3) / 4; } o(0xE1A0C00D); /* mov ip,sp */ if (func_var) n=4; if (n) { if(n>4) n=4; #ifdef TCC_ARM_EABI n=(n+1)&-2; #endif o(0xE92D0000|((1<16) nf=16; nf=(nf+1)&-2; /* nf => HARDFLOAT => EABI */ o(0xED2D0A00|nf); /* save s0-s15 on stack if needed */ } o(0xE92D5800); /* save fp, ip, lr */ o(0xE1A0B00D); /* mov fp, sp */ func_sub_sp_offset = ind; o(0xE1A00000); /* nop, leave space for stack adjustment in epilog */ #ifdef TCC_ARM_EABI if (float_abi == ARM_HARD_FLOAT) { func_vc += nf * 4; avregs = AVAIL_REGS_INITIALIZER; } #endif pn = struct_ret, sn = 0; while ((sym = sym->next)) { CType *type; type = &sym->type; size = type_size(type, &align); size = (size + 3) >> 2; align = (align + 3) & ~3; #ifdef TCC_ARM_EABI if (float_abi == ARM_HARD_FLOAT && !func_var && (is_float(sym->type.t) || is_hgen_float_aggr(&sym->type))) { int fpn = assign_vfpreg(&avregs, align, size << 2); if (fpn >= 0) addr = fpn * 4; else goto from_stack; } else #endif if (pn < 4) { #ifdef TCC_ARM_EABI pn = (pn + (align-1)/4) & -(align/4); #endif addr = (nf + pn) * 4; pn += size; if (!sn && pn > 4) sn = (pn - 4); } else { #ifdef TCC_ARM_EABI from_stack: sn = (sn + (align-1)/4) & -(align/4); #endif addr = (n + nf + sn) * 4; sn += size; } sym_push(sym->v & ~SYM_FIELD, type, VT_LOCAL | lvalue_type(type->t), addr + 12); } last_itod_magic=0; leaffunc = 1; loc = 0; } /* generate function epilog */ void gfunc_epilog(void) { uint32_t x; int diff; /* Copy float return value to core register if base standard is used and float computation is made with VFP */ #if defined(TCC_ARM_EABI) && defined(TCC_ARM_VFP) if ((float_abi == ARM_SOFTFP_FLOAT || func_var) && is_float(func_vt.t)) { if((func_vt.t & VT_BTYPE) == VT_FLOAT) o(0xEE100A10); /* fmrs r0, s0 */ else { o(0xEE100B10); /* fmrdl r0, d0 */ o(0xEE301B10); /* fmrdh r1, d0 */ } } #endif o(0xE89BA800); /* restore fp, sp, pc */ diff = (-loc + 3) & -4; #ifdef TCC_ARM_EABI if(!leaffunc) diff = ((diff + 11) & -8) - 4; #endif if(diff > 0) { x=stuff_const(0xE24BD000, diff); /* sub sp,fp,# */ if(x) *(uint32_t *)(cur_text_section->data + func_sub_sp_offset) = x; else { int addr; addr=ind; o(0xE59FC004); /* ldr ip,[pc+4] */ o(0xE04BD00C); /* sub sp,fp,ip */ o(0xE1A0F00E); /* mov pc,lr */ o(diff); *(uint32_t *)(cur_text_section->data + func_sub_sp_offset) = 0xE1000000|encbranch(func_sub_sp_offset,addr,1); } } } ST_FUNC void gen_fill_nops(int bytes) { if ((bytes & 3)) tcc_error("alignment of code section not multiple of 4"); while (bytes > 0) { o(0xE1A00000); bytes -= 4; } } /* generate a jump to a label */ int gjmp(int t) { int r; if (nocode_wanted) return t; r=ind; o(0xE0000000|encbranch(r,t,1)); return r; } /* generate a jump to a fixed address */ void gjmp_addr(int a) { gjmp(a); } /* generate a test. set 'inv' to invert test. Stack entry is popped */ int gtst(int inv, int t) { int v, r; uint32_t op; v = vtop->r & VT_VALMASK; r=ind; if (nocode_wanted) { ; } else if (v == VT_CMP) { op=mapcc(inv?negcc(vtop->c.i):vtop->c.i); op|=encbranch(r,t,1); o(op); t=r; } else if (v == VT_JMP || v == VT_JMPI) { if ((v & 1) == inv) { if(!vtop->c.i) vtop->c.i=t; else { uint32_t *x; int p,lp; if(t) { p = vtop->c.i; do { p = decbranch(lp=p); } while(p); x = (uint32_t *)(cur_text_section->data + lp); *x &= 0xff000000; *x |= encbranch(lp,t,1); } t = vtop->c.i; } } else { t = gjmp(t); gsym(vtop->c.i); } } vtop--; return t; } /* generate an integer binary operation */ void gen_opi(int op) { int c, func = 0; uint32_t opc = 0, r, fr; unsigned short retreg = REG_IRET; c=0; switch(op) { case '+': opc = 0x8; c=1; break; case TOK_ADDC1: /* add with carry generation */ opc = 0x9; c=1; break; case '-': opc = 0x4; c=1; break; case TOK_SUBC1: /* sub with carry generation */ opc = 0x5; c=1; break; case TOK_ADDC2: /* add with carry use */ opc = 0xA; c=1; break; case TOK_SUBC2: /* sub with carry use */ opc = 0xC; c=1; break; case '&': opc = 0x0; c=1; break; case '^': opc = 0x2; c=1; break; case '|': opc = 0x18; c=1; break; case '*': gv2(RC_INT, RC_INT); r = vtop[-1].r; fr = vtop[0].r; vtop--; o(0xE0000090|(intr(r)<<16)|(intr(r)<<8)|intr(fr)); return; case TOK_SHL: opc = 0; c=2; break; case TOK_SHR: opc = 1; c=2; break; case TOK_SAR: opc = 2; c=2; break; case '/': case TOK_PDIV: func=TOK___divsi3; c=3; break; case TOK_UDIV: func=TOK___udivsi3; c=3; break; case '%': #ifdef TCC_ARM_EABI func=TOK___aeabi_idivmod; retreg=REG_LRET; #else func=TOK___modsi3; #endif c=3; break; case TOK_UMOD: #ifdef TCC_ARM_EABI func=TOK___aeabi_uidivmod; retreg=REG_LRET; #else func=TOK___umodsi3; #endif c=3; break; case TOK_UMULL: gv2(RC_INT, RC_INT); r=intr(vtop[-1].r2=get_reg(RC_INT)); c=vtop[-1].r; vtop[-1].r=get_reg_ex(RC_INT,regmask(c)); vtop--; o(0xE0800090|(r<<16)|(intr(vtop->r)<<12)|(intr(c)<<8)|intr(vtop[1].r)); return; default: opc = 0x15; c=1; break; } switch(c) { case 1: if((vtop[-1].r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST) { if(opc == 4 || opc == 5 || opc == 0xc) { vswap(); opc|=2; // sub -> rsb } } if ((vtop->r & VT_VALMASK) == VT_CMP || (vtop->r & (VT_VALMASK & ~1)) == VT_JMP) gv(RC_INT); vswap(); c=intr(gv(RC_INT)); vswap(); opc=0xE0000000|(opc<<20)|(c<<16); if((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST) { uint32_t x; x=stuff_const(opc|0x2000000,vtop->c.i); if(x) { r=intr(vtop[-1].r=get_reg_ex(RC_INT,regmask(vtop[-1].r))); o(x|(r<<12)); goto done; } } fr=intr(gv(RC_INT)); r=intr(vtop[-1].r=get_reg_ex(RC_INT,two2mask(vtop->r,vtop[-1].r))); o(opc|(r<<12)|fr); done: vtop--; if (op >= TOK_ULT && op <= TOK_GT) { vtop->r = VT_CMP; vtop->c.i = op; } break; case 2: opc=0xE1A00000|(opc<<5); if ((vtop->r & VT_VALMASK) == VT_CMP || (vtop->r & (VT_VALMASK & ~1)) == VT_JMP) gv(RC_INT); vswap(); r=intr(gv(RC_INT)); vswap(); opc|=r; if ((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) == VT_CONST) { fr=intr(vtop[-1].r=get_reg_ex(RC_INT,regmask(vtop[-1].r))); c = vtop->c.i & 0x1f; o(opc|(c<<7)|(fr<<12)); } else { fr=intr(gv(RC_INT)); c=intr(vtop[-1].r=get_reg_ex(RC_INT,two2mask(vtop->r,vtop[-1].r))); o(opc|(c<<12)|(fr<<8)|0x10); } vtop--; break; case 3: vpush_global_sym(&func_old_type, func); vrott(3); gfunc_call(2); vpushi(0); vtop->r = retreg; break; default: tcc_error("gen_opi %i unimplemented!",op); } } #ifdef TCC_ARM_VFP static int is_zero(int i) { if((vtop[i].r & (VT_VALMASK | VT_LVAL | VT_SYM)) != VT_CONST) return 0; if (vtop[i].type.t == VT_FLOAT) return (vtop[i].c.f == 0.f); else if (vtop[i].type.t == VT_DOUBLE) return (vtop[i].c.d == 0.0); return (vtop[i].c.ld == 0.l); } /* generate a floating point operation 'v = t1 op t2' instruction. The * two operands are guaranteed to have the same floating point type */ void gen_opf(int op) { uint32_t x; int fneg=0,r; x=0xEE000A00|T2CPR(vtop->type.t); switch(op) { case '+': if(is_zero(-1)) vswap(); if(is_zero(0)) { vtop--; return; } x|=0x300000; break; case '-': x|=0x300040; if(is_zero(0)) { vtop--; return; } if(is_zero(-1)) { x|=0x810000; /* fsubX -> fnegX */ vswap(); vtop--; fneg=1; } break; case '*': x|=0x200000; break; case '/': x|=0x800000; break; default: if(op < TOK_ULT || op > TOK_GT) { tcc_error("unknown fp op %x!",op); return; } if(is_zero(-1)) { vswap(); switch(op) { case TOK_LT: op=TOK_GT; break; case TOK_GE: op=TOK_ULE; break; case TOK_LE: op=TOK_GE; break; case TOK_GT: op=TOK_ULT; break; } } x|=0xB40040; /* fcmpX */ if(op!=TOK_EQ && op!=TOK_NE) x|=0x80; /* fcmpX -> fcmpeX */ if(is_zero(0)) { vtop--; o(x|0x10000|(vfpr(gv(RC_FLOAT))<<12)); /* fcmp(e)X -> fcmp(e)zX */ } else { x|=vfpr(gv(RC_FLOAT)); vswap(); o(x|(vfpr(gv(RC_FLOAT))<<12)); vtop--; } o(0xEEF1FA10); /* fmstat */ switch(op) { case TOK_LE: op=TOK_ULE; break; case TOK_LT: op=TOK_ULT; break; case TOK_UGE: op=TOK_GE; break; case TOK_UGT: op=TOK_GT; break; } vtop->r = VT_CMP; vtop->c.i = op; return; } r=gv(RC_FLOAT); x|=vfpr(r); r=regmask(r); if(!fneg) { int r2; vswap(); r2=gv(RC_FLOAT); x|=vfpr(r2)<<16; r|=regmask(r2); } vtop->r=get_reg_ex(RC_FLOAT,r); if(!fneg) vtop--; o(x|(vfpr(vtop->r)<<12)); } #else static uint32_t is_fconst() { long double f; uint32_t r; if((vtop->r & (VT_VALMASK | VT_LVAL | VT_SYM)) != VT_CONST) return 0; if (vtop->type.t == VT_FLOAT) f = vtop->c.f; else if (vtop->type.t == VT_DOUBLE) f = vtop->c.d; else f = vtop->c.ld; if(!ieee_finite(f)) return 0; r=0x8; if(f<0.0) { r=0x18; f=-f; } if(f==0.0) return r; if(f==1.0) return r|1; if(f==2.0) return r|2; if(f==3.0) return r|3; if(f==4.0) return r|4; if(f==5.0) return r|5; if(f==0.5) return r|6; if(f==10.0) return r|7; return 0; } /* generate a floating point operation 'v = t1 op t2' instruction. The two operands are guaranteed to have the same floating point type */ void gen_opf(int op) { uint32_t x, r, r2, c1, c2; //fputs("gen_opf\n",stderr); vswap(); c1 = is_fconst(); vswap(); c2 = is_fconst(); x=0xEE000100; #if LDOUBLE_SIZE == 8 if ((vtop->type.t & VT_BTYPE) != VT_FLOAT) x|=0x80; #else if ((vtop->type.t & VT_BTYPE) == VT_DOUBLE) x|=0x80; else if ((vtop->type.t & VT_BTYPE) == VT_LDOUBLE) x|=0x80000; #endif switch(op) { case '+': if(!c2) { vswap(); c2=c1; } vswap(); r=fpr(gv(RC_FLOAT)); vswap(); if(c2) { if(c2>0xf) x|=0x200000; // suf r2=c2&0xf; } else { r2=fpr(gv(RC_FLOAT)); } break; case '-': if(c2) { if(c2<=0xf) x|=0x200000; // suf r2=c2&0xf; vswap(); r=fpr(gv(RC_FLOAT)); vswap(); } else if(c1 && c1<=0xf) { x|=0x300000; // rsf r2=c1; r=fpr(gv(RC_FLOAT)); vswap(); } else { x|=0x200000; // suf vswap(); r=fpr(gv(RC_FLOAT)); vswap(); r2=fpr(gv(RC_FLOAT)); } break; case '*': if(!c2 || c2>0xf) { vswap(); c2=c1; } vswap(); r=fpr(gv(RC_FLOAT)); vswap(); if(c2 && c2<=0xf) r2=c2; else r2=fpr(gv(RC_FLOAT)); x|=0x100000; // muf break; case '/': if(c2 && c2<=0xf) { x|=0x400000; // dvf r2=c2; vswap(); r=fpr(gv(RC_FLOAT)); vswap(); } else if(c1 && c1<=0xf) { x|=0x500000; // rdf r2=c1; r=fpr(gv(RC_FLOAT)); vswap(); } else { x|=0x400000; // dvf vswap(); r=fpr(gv(RC_FLOAT)); vswap(); r2=fpr(gv(RC_FLOAT)); } break; default: if(op >= TOK_ULT && op <= TOK_GT) { x|=0xd0f110; // cmfe /* bug (intention?) in Linux FPU emulator doesn't set carry if equal */ switch(op) { case TOK_ULT: case TOK_UGE: case TOK_ULE: case TOK_UGT: tcc_error("unsigned comparison on floats?"); break; case TOK_LT: op=TOK_Nset; break; case TOK_LE: op=TOK_ULE; /* correct in unordered case only if AC bit in FPSR set */ break; case TOK_EQ: case TOK_NE: x&=~0x400000; // cmfe -> cmf break; } if(c1 && !c2) { c2=c1; vswap(); switch(op) { case TOK_Nset: op=TOK_GT; break; case TOK_GE: op=TOK_ULE; break; case TOK_ULE: op=TOK_GE; break; case TOK_GT: op=TOK_Nset; break; } } vswap(); r=fpr(gv(RC_FLOAT)); vswap(); if(c2) { if(c2>0xf) x|=0x200000; r2=c2&0xf; } else { r2=fpr(gv(RC_FLOAT)); } vtop[-1].r = VT_CMP; vtop[-1].c.i = op; } else { tcc_error("unknown fp op %x!",op); return; } } if(vtop[-1].r == VT_CMP) c1=15; else { c1=vtop->r; if(r2&0x8) c1=vtop[-1].r; vtop[-1].r=get_reg_ex(RC_FLOAT,two2mask(vtop[-1].r,c1)); c1=fpr(vtop[-1].r); } vtop--; o(x|(r<<16)|(c1<<12)|r2); } #endif /* convert integers to fp 't' type. Must handle 'int', 'unsigned int' and 'long long' cases. */ ST_FUNC void gen_cvt_itof1(int t) { uint32_t r, r2; int bt; bt=vtop->type.t & VT_BTYPE; if(bt == VT_INT || bt == VT_SHORT || bt == VT_BYTE) { #ifndef TCC_ARM_VFP uint32_t dsize = 0; #endif r=intr(gv(RC_INT)); #ifdef TCC_ARM_VFP r2=vfpr(vtop->r=get_reg(RC_FLOAT)); o(0xEE000A10|(r<<12)|(r2<<16)); /* fmsr */ r2|=r2<<12; if(!(vtop->type.t & VT_UNSIGNED)) r2|=0x80; /* fuitoX -> fsituX */ o(0xEEB80A40|r2|T2CPR(t)); /* fYitoX*/ #else r2=fpr(vtop->r=get_reg(RC_FLOAT)); if((t & VT_BTYPE) != VT_FLOAT) dsize=0x80; /* flts -> fltd */ o(0xEE000110|dsize|(r2<<16)|(r<<12)); /* flts */ if((vtop->type.t & (VT_UNSIGNED|VT_BTYPE)) == (VT_UNSIGNED|VT_INT)) { uint32_t off = 0; o(0xE3500000|(r<<12)); /* cmp */ r=fpr(get_reg(RC_FLOAT)); if(last_itod_magic) { off=ind+8-last_itod_magic; off/=4; if(off>255) off=0; } o(0xBD1F0100|(r<<12)|off); /* ldflts */ if(!off) { o(0xEA000000); /* b */ last_itod_magic=ind; o(0x4F800000); /* 4294967296.0f */ } o(0xBE000100|dsize|(r2<<16)|(r2<<12)|r); /* adflt */ } #endif return; } else if(bt == VT_LLONG) { int func; CType *func_type = 0; if((t & VT_BTYPE) == VT_FLOAT) { func_type = &func_float_type; if(vtop->type.t & VT_UNSIGNED) func=TOK___floatundisf; else func=TOK___floatdisf; #if LDOUBLE_SIZE != 8 } else if((t & VT_BTYPE) == VT_LDOUBLE) { func_type = &func_ldouble_type; if(vtop->type.t & VT_UNSIGNED) func=TOK___floatundixf; else func=TOK___floatdixf; } else if((t & VT_BTYPE) == VT_DOUBLE) { #else } else if((t & VT_BTYPE) == VT_DOUBLE || (t & VT_BTYPE) == VT_LDOUBLE) { #endif func_type = &func_double_type; if(vtop->type.t & VT_UNSIGNED) func=TOK___floatundidf; else func=TOK___floatdidf; } if(func_type) { vpush_global_sym(func_type, func); vswap(); gfunc_call(1); vpushi(0); vtop->r=TREG_F0; return; } } tcc_error("unimplemented gen_cvt_itof %x!",vtop->type.t); } /* convert fp to int 't' type */ void gen_cvt_ftoi(int t) { uint32_t r, r2; int u, func = 0; u=t&VT_UNSIGNED; t&=VT_BTYPE; r2=vtop->type.t & VT_BTYPE; if(t==VT_INT) { #ifdef TCC_ARM_VFP r=vfpr(gv(RC_FLOAT)); u=u?0:0x10000; o(0xEEBC0AC0|(r<<12)|r|T2CPR(r2)|u); /* ftoXizY */ r2=intr(vtop->r=get_reg(RC_INT)); o(0xEE100A10|(r<<16)|(r2<<12)); return; #else if(u) { if(r2 == VT_FLOAT) func=TOK___fixunssfsi; #if LDOUBLE_SIZE != 8 else if(r2 == VT_LDOUBLE) func=TOK___fixunsxfsi; else if(r2 == VT_DOUBLE) #else else if(r2 == VT_LDOUBLE || r2 == VT_DOUBLE) #endif func=TOK___fixunsdfsi; } else { r=fpr(gv(RC_FLOAT)); r2=intr(vtop->r=get_reg(RC_INT)); o(0xEE100170|(r2<<12)|r); return; } #endif } else if(t == VT_LLONG) { // unsigned handled in gen_cvt_ftoi1 if(r2 == VT_FLOAT) func=TOK___fixsfdi; #if LDOUBLE_SIZE != 8 else if(r2 == VT_LDOUBLE) func=TOK___fixxfdi; else if(r2 == VT_DOUBLE) #else else if(r2 == VT_LDOUBLE || r2 == VT_DOUBLE) #endif func=TOK___fixdfdi; } if(func) { vpush_global_sym(&func_old_type, func); vswap(); gfunc_call(1); vpushi(0); if(t == VT_LLONG) vtop->r2 = REG_LRET; vtop->r = REG_IRET; return; } tcc_error("unimplemented gen_cvt_ftoi!"); } /* convert from one floating point type to another */ void gen_cvt_ftof(int t) { #ifdef TCC_ARM_VFP if(((vtop->type.t & VT_BTYPE) == VT_FLOAT) != ((t & VT_BTYPE) == VT_FLOAT)) { uint32_t r = vfpr(gv(RC_FLOAT)); o(0xEEB70AC0|(r<<12)|r|T2CPR(vtop->type.t)); } #else /* all we have to do on i386 and FPA ARM is to put the float in a register */ gv(RC_FLOAT); #endif } /* computed goto support */ void ggoto(void) { gcall_or_jmp(1); vtop--; } /* Save the stack pointer onto the stack and return the location of its address */ ST_FUNC void gen_vla_sp_save(int addr) { SValue v; v.type.t = VT_PTR; v.r = VT_LOCAL | VT_LVAL; v.c.i = addr; store(TREG_SP, &v); } /* Restore the SP from a location on the stack */ ST_FUNC void gen_vla_sp_restore(int addr) { SValue v; v.type.t = VT_PTR; v.r = VT_LOCAL | VT_LVAL; v.c.i = addr; load(TREG_SP, &v); } /* Subtract from the stack pointer, and push the resulting value onto the stack */ ST_FUNC void gen_vla_alloc(CType *type, int align) { int r = intr(gv(RC_INT)); o(0xE04D0000|(r<<12)|r); /* sub r, sp, r */ #ifdef TCC_ARM_EABI if (align < 8) align = 8; #else if (align < 4) align = 4; #endif if (align & (align - 1)) tcc_error("alignment is not a power of 2: %i", align); o(stuff_const(0xE3C0D000|(r<<16), align - 1)); /* bic sp, r, #align-1 */ vpop(); } /* end of ARM code generator */ /*************************************************************/ #endif /*************************************************************/