// Inferno utils/5l/asm.c // http://code.google.com/p/inferno-os/source/browse/utils/5l/asm.c // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. All rights reserved. // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. // Writing object files. #include "l.h" #include "../ld/lib.h" #include "../ld/elf.h" #include "../ld/dwarf.h" static Prog *PP; char linuxdynld[] = "/lib/ld-linux.so.3"; // 2 for OABI, 3 for EABI char freebsddynld[] = "/usr/libexec/ld-elf.so.1"; char openbsddynld[] = "XXX"; char netbsddynld[] = "/libexec/ld.elf_so"; int32 entryvalue(void) { char *a; Sym *s; a = INITENTRY; if(*a >= '0' && *a <= '9') return atolwhex(a); s = lookup(a, 0); if(s->type == 0) return INITTEXT; if(s->type != STEXT) diag("entry not text: %s", s->name); return s->value; } static int needlib(char *name) { char *p; Sym *s; if(*name == '\0') return 0; /* reuse hash code in symbol table */ p = smprint(".dynlib.%s", name); s = lookup(p, 0); free(p); if(s->type == 0) { s->type = 100; // avoid SDATA, etc. return 1; } return 0; } int nelfsym = 1; static void addpltsym(Sym*); static void addgotsym(Sym*); static void addgotsyminternal(Sym*); // Preserve highest 8 bits of a, and do addition to lower 24-bit // of a and b; used to adjust ARM branch intruction's target static int32 braddoff(int32 a, int32 b) { return (((uint32)a) & 0xff000000U) | (0x00ffffffU & (uint32)(a + b)); } Sym * lookuprel(void) { return lookup(".rel", 0); } void adddynrela(Sym *rel, Sym *s, Reloc *r) { addaddrplus(rel, s, r->off); adduint32(rel, R_ARM_RELATIVE); } void adddynrel(Sym *s, Reloc *r) { Sym *targ, *rel; targ = r->sym; cursym = s; switch(r->type) { default: if(r->type >= 256) { diag("unexpected relocation type %d", r->type); return; } break; // Handle relocations found in ELF object files. case 256 + R_ARM_PLT32: r->type = D_CALL; if(targ->type == SDYNIMPORT) { addpltsym(targ); r->sym = lookup(".plt", 0); r->add = braddoff(r->add, targ->plt / 4); } return; case 256 + R_ARM_THM_PC22: // R_ARM_THM_CALL diag("R_ARM_THM_CALL, are you using -marm?"); errorexit(); return; case 256 + R_ARM_GOT32: // R_ARM_GOT_BREL if(targ->type != SDYNIMPORT) { addgotsyminternal(targ); } else { addgotsym(targ); } r->type = D_CONST; // write r->add during relocsym r->sym = S; r->add += targ->got; return; case 256 + R_ARM_GOT_PREL: // GOT(S) + A - P if(targ->type != SDYNIMPORT) { addgotsyminternal(targ); } else { addgotsym(targ); } r->type = D_PCREL; r->sym = lookup(".got", 0); r->add += targ->got + 4; return; case 256 + R_ARM_GOTOFF: // R_ARM_GOTOFF32 r->type = D_GOTOFF; return; case 256 + R_ARM_GOTPC: // R_ARM_BASE_PREL r->type = D_PCREL; r->sym = lookup(".got", 0); r->add += 4; return; case 256 + R_ARM_CALL: r->type = D_CALL; if(targ->type == SDYNIMPORT) { addpltsym(targ); r->sym = lookup(".plt", 0); r->add = braddoff(r->add, targ->plt / 4); } return; case 256 + R_ARM_REL32: // R_ARM_REL32 r->type = D_PCREL; r->add += 4; return; case 256 + R_ARM_ABS32: if(targ->type == SDYNIMPORT) diag("unexpected R_ARM_ABS32 relocation for dynamic symbol %s", targ->name); r->type = D_ADDR; return; case 256 + R_ARM_V4BX: // we can just ignore this, because we are targeting ARM V5+ anyway if(r->sym) { // R_ARM_V4BX is ABS relocation, so this symbol is a dummy symbol, ignore it r->sym->type = 0; } r->sym = S; return; case 256 + R_ARM_PC24: case 256 + R_ARM_JUMP24: r->type = D_CALL; if(targ->type == SDYNIMPORT) { addpltsym(targ); r->sym = lookup(".plt", 0); r->add = braddoff(r->add, targ->plt / 4); } return; } // Handle references to ELF symbols from our own object files. if(targ->type != SDYNIMPORT) return; switch(r->type) { case D_PCREL: addpltsym(targ); r->sym = lookup(".plt", 0); r->add = targ->plt; return; case D_ADDR: if(s->type != SDATA) break; if(iself) { adddynsym(targ); rel = lookup(".rel", 0); addaddrplus(rel, s, r->off); adduint32(rel, ELF32_R_INFO(targ->dynid, R_ARM_GLOB_DAT)); // we need a S + A dynmic reloc r->type = D_CONST; // write r->add during relocsym r->sym = S; return; } break; } cursym = s; diag("unsupported relocation for dynamic symbol %s (type=%d stype=%d)", targ->name, r->type, targ->type); } int elfreloc1(Reloc *r, vlong sectoff) { int32 elfsym; LPUT(sectoff); elfsym = r->xsym->elfsym; switch(r->type) { default: return -1; case D_ADDR: if(r->siz == 4) LPUT(R_ARM_ABS32 | elfsym<<8); else return -1; break; case D_PCREL: if(r->siz == 4) LPUT(R_ARM_REL32 | elfsym<<8); else return -1; break; } return 0; } void elfsetupplt(void) { Sym *plt, *got; plt = lookup(".plt", 0); got = lookup(".got.plt", 0); if(plt->size == 0) { // str lr, [sp, #-4]! adduint32(plt, 0xe52de004); // ldr lr, [pc, #4] adduint32(plt, 0xe59fe004); // add lr, pc, lr adduint32(plt, 0xe08fe00e); // ldr pc, [lr, #8]! adduint32(plt, 0xe5bef008); // .word &GLOBAL_OFFSET_TABLE[0] - . addpcrelplus(plt, got, 4); // the first .plt entry requires 3 .plt.got entries adduint32(got, 0); adduint32(got, 0); adduint32(got, 0); } } int machoreloc1(Reloc *r, vlong sectoff) { USED(r); USED(sectoff); return -1; } int archreloc(Reloc *r, Sym *s, vlong *val) { switch(r->type) { case D_CONST: *val = r->add; return 0; case D_GOTOFF: *val = symaddr(r->sym) + r->add - symaddr(lookup(".got", 0)); return 0; // The following three arch specific relocations are only for generation of // Linux/ARM ELF's PLT entry (3 assembler instruction) case D_PLT0: // add ip, pc, #0xXX00000 if (symaddr(lookup(".got.plt", 0)) < symaddr(lookup(".plt", 0))) diag(".got.plt should be placed after .plt section."); *val = 0xe28fc600U + (0xff & ((uint32)(symaddr(r->sym) - (symaddr(lookup(".plt", 0)) + r->off) + r->add) >> 20)); return 0; case D_PLT1: // add ip, ip, #0xYY000 *val = 0xe28cca00U + (0xff & ((uint32)(symaddr(r->sym) - (symaddr(lookup(".plt", 0)) + r->off) + r->add + 4) >> 12)); return 0; case D_PLT2: // ldr pc, [ip, #0xZZZ]! *val = 0xe5bcf000U + (0xfff & (uint32)(symaddr(r->sym) - (symaddr(lookup(".plt", 0)) + r->off) + r->add + 8)); return 0; case D_CALL: // bl XXXXXX or b YYYYYY *val = braddoff((0xff000000U & (uint32)r->add), (0xffffff & (uint32) ((symaddr(r->sym) + ((uint32)r->add) * 4 - (s->value + r->off)) / 4))); return 0; } return -1; } static Reloc * addpltreloc(Sym *plt, Sym *got, Sym *sym, int typ) { Reloc *r; r = addrel(plt); r->sym = got; r->off = plt->size; r->siz = 4; r->type = typ; r->add = sym->got - 8; plt->reachable = 1; plt->size += 4; symgrow(plt, plt->size); return r; } static void addpltsym(Sym *s) { Sym *plt, *got, *rel; if(s->plt >= 0) return; adddynsym(s); if(iself) { plt = lookup(".plt", 0); got = lookup(".got.plt", 0); rel = lookup(".rel.plt", 0); if(plt->size == 0) elfsetupplt(); // .got entry s->got = got->size; // In theory, all GOT should point to the first PLT entry, // Linux/ARM's dynamic linker will do that for us, but FreeBSD/ARM's // dynamic linker won't, so we'd better do it ourselves. addaddrplus(got, plt, 0); // .plt entry, this depends on the .got entry s->plt = plt->size; addpltreloc(plt, got, s, D_PLT0); // add lr, pc, #0xXX00000 addpltreloc(plt, got, s, D_PLT1); // add lr, lr, #0xYY000 addpltreloc(plt, got, s, D_PLT2); // ldr pc, [lr, #0xZZZ]! // rel addaddrplus(rel, got, s->got); adduint32(rel, ELF32_R_INFO(s->dynid, R_ARM_JUMP_SLOT)); } else { diag("addpltsym: unsupported binary format"); } } static void addgotsyminternal(Sym *s) { Sym *got; if(s->got >= 0) return; got = lookup(".got", 0); s->got = got->size; addaddrplus(got, s, 0); if(iself) { ; } else { diag("addgotsyminternal: unsupported binary format"); } } static void addgotsym(Sym *s) { Sym *got, *rel; if(s->got >= 0) return; adddynsym(s); got = lookup(".got", 0); s->got = got->size; adduint32(got, 0); if(iself) { rel = lookup(".rel", 0); addaddrplus(rel, got, s->got); adduint32(rel, ELF32_R_INFO(s->dynid, R_ARM_GLOB_DAT)); } else { diag("addgotsym: unsupported binary format"); } } void adddynsym(Sym *s) { Sym *d; int t; char *name; if(s->dynid >= 0) return; if(iself) { s->dynid = nelfsym++; d = lookup(".dynsym", 0); /* name */ name = s->extname; adduint32(d, addstring(lookup(".dynstr", 0), name)); /* value */ if(s->type == SDYNIMPORT) adduint32(d, 0); else addaddr(d, s); /* size */ adduint32(d, 0); /* type */ t = STB_GLOBAL << 4; if((s->cgoexport & CgoExportDynamic) && (s->type&SMASK) == STEXT) t |= STT_FUNC; else t |= STT_OBJECT; adduint8(d, t); adduint8(d, 0); /* shndx */ if(s->type == SDYNIMPORT) adduint16(d, SHN_UNDEF); else { switch(s->type) { default: case STEXT: t = 11; break; case SRODATA: t = 12; break; case SDATA: t = 13; break; case SBSS: t = 14; break; } adduint16(d, t); } } else { diag("adddynsym: unsupported binary format"); } } void adddynlib(char *lib) { Sym *s; if(!needlib(lib)) return; if(iself) { s = lookup(".dynstr", 0); if(s->size == 0) addstring(s, ""); elfwritedynent(lookup(".dynamic", 0), DT_NEEDED, addstring(s, lib)); } else { diag("adddynlib: unsupported binary format"); } } vlong datoff(vlong addr) { if(addr >= segdata.vaddr) return addr - segdata.vaddr + segdata.fileoff; if(addr >= segtext.vaddr) return addr - segtext.vaddr + segtext.fileoff; diag("datoff %#x", addr); return 0; } void asmb(void) { int32 t; uint32 symo; Section *sect; Sym *sym; int i; if(debug['v']) Bprint(&bso, "%5.2f asmb\n", cputime()); Bflush(&bso); if(iself) asmbelfsetup(); sect = segtext.sect; cseek(sect->vaddr - segtext.vaddr + segtext.fileoff); codeblk(sect->vaddr, sect->len); /* output read-only data in text segment (rodata, gosymtab, pclntab, ...) */ for(sect = sect->next; sect != nil; sect = sect->next) { cseek(sect->vaddr - segtext.vaddr + segtext.fileoff); datblk(sect->vaddr, sect->len); } if(debug['v']) Bprint(&bso, "%5.2f datblk\n", cputime()); Bflush(&bso); cseek(segdata.fileoff); datblk(segdata.vaddr, segdata.filelen); /* output symbol table */ symsize = 0; lcsize = 0; symo = 0; if(!debug['s']) { // TODO: rationalize if(debug['v']) Bprint(&bso, "%5.2f sym\n", cputime()); Bflush(&bso); switch(HEADTYPE) { default: if(iself) goto ElfSym; case Hnoheader: case Hrisc: case Hixp1200: case Hipaq: debug['s'] = 1; break; case Hplan9x32: symo = HEADR+segtext.len+segdata.filelen; break; ElfSym: symo = rnd(HEADR+segtext.filelen, INITRND)+segdata.filelen; symo = rnd(symo, INITRND); break; } cseek(symo); switch(HEADTYPE) { default: if(iself) { if(debug['v']) Bprint(&bso, "%5.2f elfsym\n", cputime()); asmelfsym(); cflush(); cwrite(elfstrdat, elfstrsize); if(debug['v']) Bprint(&bso, "%5.2f dwarf\n", cputime()); dwarfemitdebugsections(); if(linkmode == LinkExternal) elfemitreloc(); } break; case Hplan9x32: asmplan9sym(); cflush(); sym = lookup("pclntab", 0); if(sym != nil) { lcsize = sym->np; for(i=0; i < lcsize; i++) cput(sym->p[i]); cflush(); } break; } } cursym = nil; if(debug['v']) Bprint(&bso, "%5.2f header\n", cputime()); Bflush(&bso); cseek(0L); switch(HEADTYPE) { default: case Hnoheader: /* no header */ break; case Hrisc: /* aif for risc os */ lputl(0xe1a00000); /* NOP - decompress code */ lputl(0xe1a00000); /* NOP - relocation code */ lputl(0xeb000000 + 12); /* BL - zero init code */ lputl(0xeb000000 + (entryvalue() - INITTEXT + HEADR - 12 - 8) / 4); /* BL - entry code */ lputl(0xef000011); /* SWI - exit code */ lputl(segtext.filelen+HEADR); /* text size */ lputl(segdata.filelen); /* data size */ lputl(0); /* sym size */ lputl(segdata.len - segdata.filelen); /* bss size */ lputl(0); /* sym type */ lputl(INITTEXT-HEADR); /* text addr */ lputl(0); /* workspace - ignored */ lputl(32); /* addr mode / data addr flag */ lputl(0); /* data addr */ for(t=0; t<2; t++) lputl(0); /* reserved */ for(t=0; t<15; t++) lputl(0xe1a00000); /* NOP - zero init code */ lputl(0xe1a0f00e); /* B (R14) - zero init return */ break; case Hplan9x32: /* plan 9 */ lput(0x647); /* magic */ lput(segtext.filelen); /* sizes */ lput(segdata.filelen); lput(segdata.len - segdata.filelen); lput(symsize); /* nsyms */ lput(entryvalue()); /* va of entry */ lput(0L); lput(lcsize); break; case Hixp1200: /* boot for IXP1200 */ break; case Hipaq: /* boot for ipaq */ lputl(0xe3300000); /* nop */ lputl(0xe3300000); /* nop */ lputl(0xe3300000); /* nop */ lputl(0xe3300000); /* nop */ break; case Hlinux: case Hfreebsd: case Hnetbsd: case Hopenbsd: asmbelf(symo); break; } cflush(); if(debug['c']){ print("textsize=%ulld\n", segtext.filelen); print("datsize=%ulld\n", segdata.filelen); print("bsssize=%ulld\n", segdata.len - segdata.filelen); print("symsize=%d\n", symsize); print("lcsize=%d\n", lcsize); print("total=%lld\n", segtext.filelen+segdata.len+symsize+lcsize); } } /* void cput(int32 c) { *cbp++ = c; if(--cbc <= 0) cflush(); } */ void wput(int32 l) { cbp[0] = l>>8; cbp[1] = l; cbp += 2; cbc -= 2; if(cbc <= 0) cflush(); } void hput(int32 l) { cbp[0] = l>>8; cbp[1] = l; cbp += 2; cbc -= 2; if(cbc <= 0) cflush(); } void lput(int32 l) { cbp[0] = l>>24; cbp[1] = l>>16; cbp[2] = l>>8; cbp[3] = l; cbp += 4; cbc -= 4; if(cbc <= 0) cflush(); } void nopstat(char *f, Count *c) { if(c->outof) Bprint(&bso, "%s delay %d/%d (%.2f)\n", f, c->outof - c->count, c->outof, (double)(c->outof - c->count)/c->outof); } void asmout(Prog *p, Optab *o, int32 *out) { int32 o1, o2, o3, o4, o5, o6, v; int r, rf, rt, rt2; Reloc *rel; PP = p; o1 = 0; o2 = 0; o3 = 0; o4 = 0; o5 = 0; o6 = 0; armsize += o->size; if(debug['P']) print("%ux: %P type %d\n", (uint32)(p->pc), p, o->type); switch(o->type) { default: diag("unknown asm %d", o->type); prasm(p); break; case 0: /* pseudo ops */ if(debug['G']) print("%ux: %s: arm %d\n", (uint32)(p->pc), p->from.sym->name, p->from.sym->fnptr); break; case 1: /* op R,[R],R */ o1 = oprrr(p->as, p->scond); rf = p->from.reg; rt = p->to.reg; r = p->reg; if(p->to.type == D_NONE) rt = 0; if(p->as == AMOVW || p->as == AMVN) r = 0; else if(r == NREG) r = rt; o1 |= rf | (r<<16) | (rt<<12); break; case 2: /* movbu $I,[R],R */ aclass(&p->from); o1 = oprrr(p->as, p->scond); o1 |= immrot(instoffset); rt = p->to.reg; r = p->reg; if(p->to.type == D_NONE) rt = 0; if(p->as == AMOVW || p->as == AMVN) r = 0; else if(r == NREG) r = rt; o1 |= (r<<16) | (rt<<12); break; case 3: /* add R<<[IR],[R],R */ mov: aclass(&p->from); o1 = oprrr(p->as, p->scond); o1 |= p->from.offset; rt = p->to.reg; r = p->reg; if(p->to.type == D_NONE) rt = 0; if(p->as == AMOVW || p->as == AMVN) r = 0; else if(r == NREG) r = rt; o1 |= (r<<16) | (rt<<12); break; case 4: /* add $I,[R],R */ aclass(&p->from); o1 = oprrr(AADD, p->scond); o1 |= immrot(instoffset); r = p->from.reg; if(r == NREG) r = o->param; o1 |= r << 16; o1 |= p->to.reg << 12; break; case 5: /* bra s */ v = -8; // TODO: Use addrel. if(p->cond != P) v = (p->cond->pc - pc) - 8; o1 = opbra(p->as, p->scond); o1 |= (v >> 2) & 0xffffff; break; case 6: /* b ,O(R) -> add $O,R,PC */ aclass(&p->to); o1 = oprrr(AADD, p->scond); o1 |= immrot(instoffset); o1 |= p->to.reg << 16; o1 |= REGPC << 12; break; case 7: /* bl ,O(R) -> mov PC,link; add $O,R,PC */ aclass(&p->to); o1 = oprrr(AADD, p->scond); o1 |= immrot(0); o1 |= REGPC << 16; o1 |= REGLINK << 12; o2 = oprrr(AADD, p->scond); o2 |= immrot(instoffset); o2 |= p->to.reg << 16; o2 |= REGPC << 12; break; case 8: /* sll $c,[R],R -> mov (R<<$c),R */ aclass(&p->from); o1 = oprrr(p->as, p->scond); r = p->reg; if(r == NREG) r = p->to.reg; o1 |= r; o1 |= (instoffset&31) << 7; o1 |= p->to.reg << 12; break; case 9: /* sll R,[R],R -> mov (R<as, p->scond); r = p->reg; if(r == NREG) r = p->to.reg; o1 |= r; o1 |= (p->from.reg << 8) | (1<<4); o1 |= p->to.reg << 12; break; case 10: /* swi [$con] */ o1 = oprrr(p->as, p->scond); if(p->to.type != D_NONE) { aclass(&p->to); o1 |= instoffset & 0xffffff; } break; case 11: /* word */ aclass(&p->to); o1 = instoffset; if(p->to.sym != S) { rel = addrel(cursym); rel->off = pc - cursym->value; rel->siz = 4; rel->sym = p->to.sym; rel->add = p->to.offset; if(flag_shared) { rel->type = D_PCREL; rel->add += pc - p->pcrel->pc - 8; } else rel->type = D_ADDR; o1 = 0; } break; case 12: /* movw $lcon, reg */ o1 = omvl(p, &p->from, p->to.reg); if(o->flag & LPCREL) { o2 = oprrr(AADD, p->scond) | p->to.reg | REGPC << 16 | p->to.reg << 12; } break; case 13: /* op $lcon, [R], R */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; o2 = oprrr(p->as, p->scond); o2 |= REGTMP; r = p->reg; if(p->as == AMOVW || p->as == AMVN) r = 0; else if(r == NREG) r = p->to.reg; o2 |= r << 16; if(p->to.type != D_NONE) o2 |= p->to.reg << 12; break; case 14: /* movb/movbu/movh/movhu R,R */ o1 = oprrr(ASLL, p->scond); if(p->as == AMOVBU || p->as == AMOVHU) o2 = oprrr(ASRL, p->scond); else o2 = oprrr(ASRA, p->scond); r = p->to.reg; o1 |= (p->from.reg)|(r<<12); o2 |= (r)|(r<<12); if(p->as == AMOVB || p->as == AMOVBU) { o1 |= (24<<7); o2 |= (24<<7); } else { o1 |= (16<<7); o2 |= (16<<7); } break; case 15: /* mul r,[r,]r */ o1 = oprrr(p->as, p->scond); rf = p->from.reg; rt = p->to.reg; r = p->reg; if(r == NREG) r = rt; if(rt == r) { r = rf; rf = rt; } if(0) if(rt == r || rf == REGPC || r == REGPC || rt == REGPC) { diag("bad registers in MUL"); prasm(p); } o1 |= (rf<<8) | r | (rt<<16); break; case 16: /* div r,[r,]r */ o1 = 0xf << 28; o2 = 0; break; case 17: o1 = oprrr(p->as, p->scond); rf = p->from.reg; rt = p->to.reg; rt2 = p->to.offset; r = p->reg; o1 |= (rf<<8) | r | (rt<<16) | (rt2<<12); break; case 20: /* mov/movb/movbu R,O(R) */ aclass(&p->to); r = p->to.reg; if(r == NREG) r = o->param; o1 = osr(p->as, p->from.reg, instoffset, r, p->scond); break; case 21: /* mov/movbu O(R),R -> lr */ aclass(&p->from); r = p->from.reg; if(r == NREG) r = o->param; o1 = olr(instoffset, r, p->to.reg, p->scond); if(p->as != AMOVW) o1 |= 1<<22; break; case 30: /* mov/movb/movbu R,L(R) */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; r = p->to.reg; if(r == NREG) r = o->param; o2 = osrr(p->from.reg, REGTMP,r, p->scond); if(p->as != AMOVW) o2 |= 1<<22; break; case 31: /* mov/movbu L(R),R -> lr[b] */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; r = p->from.reg; if(r == NREG) r = o->param; o2 = olrr(REGTMP,r, p->to.reg, p->scond); if(p->as == AMOVBU || p->as == AMOVB) o2 |= 1<<22; break; case 34: /* mov $lacon,R */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; o2 = oprrr(AADD, p->scond); o2 |= REGTMP; r = p->from.reg; if(r == NREG) r = o->param; o2 |= r << 16; if(p->to.type != D_NONE) o2 |= p->to.reg << 12; break; case 35: /* mov PSR,R */ o1 = (2<<23) | (0xf<<16) | (0<<0); o1 |= (p->scond & C_SCOND) << 28; o1 |= (p->from.reg & 1) << 22; o1 |= p->to.reg << 12; break; case 36: /* mov R,PSR */ o1 = (2<<23) | (0x29f<<12) | (0<<4); if(p->scond & C_FBIT) o1 ^= 0x010 << 12; o1 |= (p->scond & C_SCOND) << 28; o1 |= (p->to.reg & 1) << 22; o1 |= p->from.reg << 0; break; case 37: /* mov $con,PSR */ aclass(&p->from); o1 = (2<<23) | (0x29f<<12) | (0<<4); if(p->scond & C_FBIT) o1 ^= 0x010 << 12; o1 |= (p->scond & C_SCOND) << 28; o1 |= immrot(instoffset); o1 |= (p->to.reg & 1) << 22; o1 |= p->from.reg << 0; break; case 38: /* movm $con,oreg -> stm */ o1 = (0x4 << 25); o1 |= p->from.offset & 0xffff; o1 |= p->to.reg << 16; aclass(&p->to); goto movm; case 39: /* movm oreg,$con -> ldm */ o1 = (0x4 << 25) | (1 << 20); o1 |= p->to.offset & 0xffff; o1 |= p->from.reg << 16; aclass(&p->from); movm: if(instoffset != 0) diag("offset must be zero in MOVM"); o1 |= (p->scond & C_SCOND) << 28; if(p->scond & C_PBIT) o1 |= 1 << 24; if(p->scond & C_UBIT) o1 |= 1 << 23; if(p->scond & C_SBIT) o1 |= 1 << 22; if(p->scond & C_WBIT) o1 |= 1 << 21; break; case 40: /* swp oreg,reg,reg */ aclass(&p->from); if(instoffset != 0) diag("offset must be zero in SWP"); o1 = (0x2<<23) | (0x9<<4); if(p->as != ASWPW) o1 |= 1 << 22; o1 |= p->from.reg << 16; o1 |= p->reg << 0; o1 |= p->to.reg << 12; o1 |= (p->scond & C_SCOND) << 28; break; case 41: /* rfe -> movm.s.w.u 0(r13),[r15] */ o1 = 0xe8fd8000; break; case 50: /* floating point store */ v = regoff(&p->to); r = p->to.reg; if(r == NREG) r = o->param; o1 = ofsr(p->as, p->from.reg, v, r, p->scond, p); break; case 51: /* floating point load */ v = regoff(&p->from); r = p->from.reg; if(r == NREG) r = o->param; o1 = ofsr(p->as, p->to.reg, v, r, p->scond, p) | (1<<20); break; case 52: /* floating point store, int32 offset UGLY */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; r = p->to.reg; if(r == NREG) r = o->param; o2 = oprrr(AADD, p->scond) | (REGTMP << 12) | (REGTMP << 16) | r; o3 = ofsr(p->as, p->from.reg, 0, REGTMP, p->scond, p); break; case 53: /* floating point load, int32 offset UGLY */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; r = p->from.reg; if(r == NREG) r = o->param; o2 = oprrr(AADD, p->scond) | (REGTMP << 12) | (REGTMP << 16) | r; o3 = ofsr(p->as, p->to.reg, 0, REGTMP, p->scond, p) | (1<<20); break; case 54: /* floating point arith */ o1 = oprrr(p->as, p->scond); rf = p->from.reg; rt = p->to.reg; r = p->reg; if(r == NREG) { r = rt; if(p->as == AMOVF || p->as == AMOVD || p->as == ASQRTF || p->as == ASQRTD || p->as == AABSF || p->as == AABSD) r = 0; } o1 |= rf | (r<<16) | (rt<<12); break; case 56: /* move to FP[CS]R */ o1 = ((p->scond & C_SCOND) << 28) | (0xe << 24) | (1<<8) | (1<<4); o1 |= ((p->to.reg+1)<<21) | (p->from.reg << 12); break; case 57: /* move from FP[CS]R */ o1 = ((p->scond & C_SCOND) << 28) | (0xe << 24) | (1<<8) | (1<<4); o1 |= ((p->from.reg+1)<<21) | (p->to.reg<<12) | (1<<20); break; case 58: /* movbu R,R */ o1 = oprrr(AAND, p->scond); o1 |= immrot(0xff); rt = p->to.reg; r = p->from.reg; if(p->to.type == D_NONE) rt = 0; if(r == NREG) r = rt; o1 |= (r<<16) | (rt<<12); break; case 59: /* movw/bu R< ldr indexed */ if(p->from.reg == NREG) { if(p->as != AMOVW) diag("byte MOV from shifter operand"); goto mov; } if(p->from.offset&(1<<4)) diag("bad shift in LDR"); o1 = olrr(p->from.offset, p->from.reg, p->to.reg, p->scond); if(p->as == AMOVBU) o1 |= 1<<22; break; case 60: /* movb R(R),R -> ldrsb indexed */ if(p->from.reg == NREG) { diag("byte MOV from shifter operand"); goto mov; } if(p->from.offset&(~0xf)) diag("bad shift in LDRSB"); o1 = olhrr(p->from.offset, p->from.reg, p->to.reg, p->scond); o1 ^= (1<<5)|(1<<6); break; case 61: /* movw/b/bu R,R<<[IR](R) -> str indexed */ if(p->to.reg == NREG) diag("MOV to shifter operand"); o1 = osrr(p->from.reg, p->to.offset, p->to.reg, p->scond); if(p->as == AMOVB || p->as == AMOVBU) o1 |= 1<<22; break; case 62: /* case R -> movw R<<2(PC),PC */ if(o->flag & LPCREL) { o1 = oprrr(AADD, p->scond) | immrot(1) | p->from.reg << 16 | REGTMP << 12; o2 = olrr(REGTMP, REGPC, REGTMP, p->scond); o2 |= 2<<7; o3 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGPC << 12; } else { o1 = olrr(p->from.reg, REGPC, REGPC, p->scond); o1 |= 2<<7; } break; case 63: /* bcase */ if(p->cond != P) { o1 = p->cond->pc; if(flag_shared) o1 = o1 - p->pcrel->pc - 16; } break; /* reloc ops */ case 64: /* mov/movb/movbu R,addr */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; o2 = osr(p->as, p->from.reg, 0, REGTMP, p->scond); if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; case 65: /* mov/movbu addr,R */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; o2 = olr(0, REGTMP, p->to.reg, p->scond); if(p->as == AMOVBU || p->as == AMOVB) o2 |= 1<<22; if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; case 68: /* floating point store -> ADDR */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; o2 = ofsr(p->as, p->from.reg, 0, REGTMP, p->scond, p); if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; case 69: /* floating point load <- ADDR */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; o2 = ofsr(p->as, p->to.reg, 0, REGTMP, p->scond, p) | (1<<20); if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; /* ArmV4 ops: */ case 70: /* movh/movhu R,O(R) -> strh */ aclass(&p->to); r = p->to.reg; if(r == NREG) r = o->param; o1 = oshr(p->from.reg, instoffset, r, p->scond); break; case 71: /* movb/movh/movhu O(R),R -> ldrsb/ldrsh/ldrh */ aclass(&p->from); r = p->from.reg; if(r == NREG) r = o->param; o1 = olhr(instoffset, r, p->to.reg, p->scond); if(p->as == AMOVB) o1 ^= (1<<5)|(1<<6); else if(p->as == AMOVH) o1 ^= (1<<6); break; case 72: /* movh/movhu R,L(R) -> strh */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; r = p->to.reg; if(r == NREG) r = o->param; o2 = oshrr(p->from.reg, REGTMP,r, p->scond); break; case 73: /* movb/movh/movhu L(R),R -> ldrsb/ldrsh/ldrh */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; r = p->from.reg; if(r == NREG) r = o->param; o2 = olhrr(REGTMP, r, p->to.reg, p->scond); if(p->as == AMOVB) o2 ^= (1<<5)|(1<<6); else if(p->as == AMOVH) o2 ^= (1<<6); break; case 74: /* bx $I */ diag("ABX $I"); break; case 75: /* bx O(R) */ aclass(&p->to); if(instoffset != 0) diag("non-zero offset in ABX"); /* o1 = oprrr(AADD, p->scond) | immrot(0) | (REGPC<<16) | (REGLINK<<12); // mov PC, LR o2 = ((p->scond&C_SCOND)<<28) | (0x12fff<<8) | (1<<4) | p->to.reg; // BX R */ // p->to.reg may be REGLINK o1 = oprrr(AADD, p->scond); o1 |= immrot(instoffset); o1 |= p->to.reg << 16; o1 |= REGTMP << 12; o2 = oprrr(AADD, p->scond) | immrot(0) | (REGPC<<16) | (REGLINK<<12); // mov PC, LR o3 = ((p->scond&C_SCOND)<<28) | (0x12fff<<8) | (1<<4) | REGTMP; // BX Rtmp break; case 76: /* bx O(R) when returning from fn*/ diag("ABXRET"); break; case 77: /* ldrex oreg,reg */ aclass(&p->from); if(instoffset != 0) diag("offset must be zero in LDREX"); o1 = (0x19<<20) | (0xf9f); o1 |= p->from.reg << 16; o1 |= p->to.reg << 12; o1 |= (p->scond & C_SCOND) << 28; break; case 78: /* strex reg,oreg,reg */ aclass(&p->from); if(instoffset != 0) diag("offset must be zero in STREX"); o1 = (0x18<<20) | (0xf90); o1 |= p->from.reg << 16; o1 |= p->reg << 0; o1 |= p->to.reg << 12; o1 |= (p->scond & C_SCOND) << 28; break; case 80: /* fmov zfcon,freg */ if(p->as == AMOVD) { o1 = 0xeeb00b00; // VMOV imm 64 o2 = oprrr(ASUBD, p->scond); } else { o1 = 0x0eb00a00; // VMOV imm 32 o2 = oprrr(ASUBF, p->scond); } v = 0x70; // 1.0 r = p->to.reg; // movf $1.0, r o1 |= (p->scond & C_SCOND) << 28; o1 |= r << 12; o1 |= (v&0xf) << 0; o1 |= (v&0xf0) << 12; // subf r,r,r o2 |= r | (r<<16) | (r<<12); break; case 81: /* fmov sfcon,freg */ o1 = 0x0eb00a00; // VMOV imm 32 if(p->as == AMOVD) o1 = 0xeeb00b00; // VMOV imm 64 o1 |= (p->scond & C_SCOND) << 28; o1 |= p->to.reg << 12; v = chipfloat(&p->from.ieee); o1 |= (v&0xf) << 0; o1 |= (v&0xf0) << 12; break; case 82: /* fcmp freg,freg, */ o1 = oprrr(p->as, p->scond); o1 |= (p->reg<<12) | (p->from.reg<<0); o2 = 0x0ef1fa10; // VMRS R15 o2 |= (p->scond & C_SCOND) << 28; break; case 83: /* fcmp freg,, */ o1 = oprrr(p->as, p->scond); o1 |= (p->from.reg<<12) | (1<<16); o2 = 0x0ef1fa10; // VMRS R15 o2 |= (p->scond & C_SCOND) << 28; break; case 84: /* movfw freg,freg - truncate float-to-fix */ o1 = oprrr(p->as, p->scond); o1 |= (p->from.reg<<0); o1 |= (p->to.reg<<12); break; case 85: /* movwf freg,freg - fix-to-float */ o1 = oprrr(p->as, p->scond); o1 |= (p->from.reg<<0); o1 |= (p->to.reg<<12); break; case 86: /* movfw freg,reg - truncate float-to-fix */ // macro for movfw freg,FTMP; movw FTMP,reg o1 = oprrr(p->as, p->scond); o1 |= (p->from.reg<<0); o1 |= (FREGTMP<<12); o2 = oprrr(AMOVFW+AEND, p->scond); o2 |= (FREGTMP<<16); o2 |= (p->to.reg<<12); break; case 87: /* movwf reg,freg - fix-to-float */ // macro for movw reg,FTMP; movwf FTMP,freg o1 = oprrr(AMOVWF+AEND, p->scond); o1 |= (p->from.reg<<12); o1 |= (FREGTMP<<16); o2 = oprrr(p->as, p->scond); o2 |= (FREGTMP<<0); o2 |= (p->to.reg<<12); break; case 88: /* movw reg,freg */ o1 = oprrr(AMOVWF+AEND, p->scond); o1 |= (p->from.reg<<12); o1 |= (p->to.reg<<16); break; case 89: /* movw freg,reg */ o1 = oprrr(AMOVFW+AEND, p->scond); o1 |= (p->from.reg<<16); o1 |= (p->to.reg<<12); break; case 90: /* tst reg */ o1 = oprrr(ACMP+AEND, p->scond); o1 |= p->from.reg<<16; break; case 91: /* ldrexd oreg,reg */ aclass(&p->from); if(instoffset != 0) diag("offset must be zero in LDREX"); o1 = (0x1b<<20) | (0xf9f); o1 |= p->from.reg << 16; o1 |= p->to.reg << 12; o1 |= (p->scond & C_SCOND) << 28; break; case 92: /* strexd reg,oreg,reg */ aclass(&p->from); if(instoffset != 0) diag("offset must be zero in STREX"); o1 = (0x1a<<20) | (0xf90); o1 |= p->from.reg << 16; o1 |= p->reg << 0; o1 |= p->to.reg << 12; o1 |= (p->scond & C_SCOND) << 28; break; case 93: /* movb/movh/movhu addr,R -> ldrsb/ldrsh/ldrh */ o1 = omvl(p, &p->from, REGTMP); if(!o1) break; o2 = olhr(0, REGTMP, p->to.reg, p->scond); if(p->as == AMOVB) o2 ^= (1<<5)|(1<<6); else if(p->as == AMOVH) o2 ^= (1<<6); if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; case 94: /* movh/movhu R,addr -> strh */ o1 = omvl(p, &p->to, REGTMP); if(!o1) break; o2 = oshr(p->from.reg, 0, REGTMP, p->scond); if(o->flag & LPCREL) { o3 = o2; o2 = oprrr(AADD, p->scond) | REGTMP | REGPC << 16 | REGTMP << 12; } break; case 95: /* PLD off(reg) */ o1 = 0xf5d0f000; o1 |= p->from.reg << 16; if(p->from.offset < 0) { o1 &= ~(1 << 23); o1 |= (-p->from.offset) & 0xfff; } else o1 |= p->from.offset & 0xfff; break; case 96: /* UNDEF */ // This is supposed to be something that stops execution. // It's not supposed to be reached, ever, but if it is, we'd // like to be able to tell how we got there. Assemble as // BL $0 // TODO: Use addrel. v = (0 - pc) - 8; o1 = opbra(ABL, C_SCOND_NONE); o1 |= (v >> 2) & 0xffffff; break; case 97: /* CLZ Rm, Rd */ o1 = oprrr(p->as, p->scond); o1 |= p->to.reg << 12; o1 |= p->from.reg; break; case 98: /* MULW{T,B} Rs, Rm, Rd */ o1 = oprrr(p->as, p->scond); o1 |= p->to.reg << 16; o1 |= p->from.reg << 8; o1 |= p->reg; break; case 99: /* MULAW{T,B} Rs, Rm, Rn, Rd */ o1 = oprrr(p->as, p->scond); o1 |= p->to.reg << 12; o1 |= p->from.reg << 8; o1 |= p->reg; o1 |= p->to.offset << 16; break; } out[0] = o1; out[1] = o2; out[2] = o3; out[3] = o4; out[4] = o5; out[5] = o6; return; #ifdef NOTDEF v = p->pc; switch(o->size) { default: if(debug['a']) Bprint(&bso, " %.8ux:\t\t%P\n", v, p); break; case 4: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux\t%P\n", v, o1, p); lputl(o1); break; case 8: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux %.8ux%P\n", v, o1, o2, p); lputl(o1); lputl(o2); break; case 12: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux %.8ux %.8ux%P\n", v, o1, o2, o3, p); lputl(o1); lputl(o2); lputl(o3); break; case 16: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux %.8ux %.8ux %.8ux%P\n", v, o1, o2, o3, o4, p); lputl(o1); lputl(o2); lputl(o3); lputl(o4); break; case 20: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux %.8ux %.8ux %.8ux %.8ux%P\n", v, o1, o2, o3, o4, o5, p); lputl(o1); lputl(o2); lputl(o3); lputl(o4); lputl(o5); break; case 24: if(debug['a']) Bprint(&bso, " %.8ux: %.8ux %.8ux %.8ux %.8ux %.8ux %.8ux%P\n", v, o1, o2, o3, o4, o5, o6, p); lputl(o1); lputl(o2); lputl(o3); lputl(o4); lputl(o5); lputl(o6); break; } #endif } int32 oprrr(int a, int sc) { int32 o; o = (sc & C_SCOND) << 28; if(sc & C_SBIT) o |= 1 << 20; if(sc & (C_PBIT|C_WBIT)) diag(".P/.W on dp instruction"); switch(a) { case AMULU: case AMUL: return o | (0x0<<21) | (0x9<<4); case AMULA: return o | (0x1<<21) | (0x9<<4); case AMULLU: return o | (0x4<<21) | (0x9<<4); case AMULL: return o | (0x6<<21) | (0x9<<4); case AMULALU: return o | (0x5<<21) | (0x9<<4); case AMULAL: return o | (0x7<<21) | (0x9<<4); case AAND: return o | (0x0<<21); case AEOR: return o | (0x1<<21); case ASUB: return o | (0x2<<21); case ARSB: return o | (0x3<<21); case AADD: return o | (0x4<<21); case AADC: return o | (0x5<<21); case ASBC: return o | (0x6<<21); case ARSC: return o | (0x7<<21); case ATST: return o | (0x8<<21) | (1<<20); case ATEQ: return o | (0x9<<21) | (1<<20); case ACMP: return o | (0xa<<21) | (1<<20); case ACMN: return o | (0xb<<21) | (1<<20); case AORR: return o | (0xc<<21); case AMOVW: return o | (0xd<<21); case ABIC: return o | (0xe<<21); case AMVN: return o | (0xf<<21); case ASLL: return o | (0xd<<21) | (0<<5); case ASRL: return o | (0xd<<21) | (1<<5); case ASRA: return o | (0xd<<21) | (2<<5); case ASWI: return o | (0xf<<24); case AADDD: return o | (0xe<<24) | (0x3<<20) | (0xb<<8) | (0<<4); case AADDF: return o | (0xe<<24) | (0x3<<20) | (0xa<<8) | (0<<4); case ASUBD: return o | (0xe<<24) | (0x3<<20) | (0xb<<8) | (4<<4); case ASUBF: return o | (0xe<<24) | (0x3<<20) | (0xa<<8) | (4<<4); case AMULD: return o | (0xe<<24) | (0x2<<20) | (0xb<<8) | (0<<4); case AMULF: return o | (0xe<<24) | (0x2<<20) | (0xa<<8) | (0<<4); case ADIVD: return o | (0xe<<24) | (0x8<<20) | (0xb<<8) | (0<<4); case ADIVF: return o | (0xe<<24) | (0x8<<20) | (0xa<<8) | (0<<4); case ASQRTD: return o | (0xe<<24) | (0xb<<20) | (1<<16) | (0xb<<8) | (0xc<<4); case ASQRTF: return o | (0xe<<24) | (0xb<<20) | (1<<16) | (0xa<<8) | (0xc<<4); case AABSD: return o | (0xe<<24) | (0xb<<20) | (0<<16) | (0xb<<8) | (0xc<<4); case AABSF: return o | (0xe<<24) | (0xb<<20) | (0<<16) | (0xa<<8) | (0xc<<4); case ACMPD: return o | (0xe<<24) | (0xb<<20) | (4<<16) | (0xb<<8) | (0xc<<4); case ACMPF: return o | (0xe<<24) | (0xb<<20) | (4<<16) | (0xa<<8) | (0xc<<4); case AMOVF: return o | (0xe<<24) | (0xb<<20) | (0<<16) | (0xa<<8) | (4<<4); case AMOVD: return o | (0xe<<24) | (0xb<<20) | (0<<16) | (0xb<<8) | (4<<4); case AMOVDF: return o | (0xe<<24) | (0xb<<20) | (7<<16) | (0xa<<8) | (0xc<<4) | (1<<8); // dtof case AMOVFD: return o | (0xe<<24) | (0xb<<20) | (7<<16) | (0xa<<8) | (0xc<<4) | (0<<8); // dtof case AMOVWF: if((sc & C_UBIT) == 0) o |= 1<<7; /* signed */ return o | (0xe<<24) | (0xb<<20) | (8<<16) | (0xa<<8) | (4<<4) | (0<<18) | (0<<8); // toint, double case AMOVWD: if((sc & C_UBIT) == 0) o |= 1<<7; /* signed */ return o | (0xe<<24) | (0xb<<20) | (8<<16) | (0xa<<8) | (4<<4) | (0<<18) | (1<<8); // toint, double case AMOVFW: if((sc & C_UBIT) == 0) o |= 1<<16; /* signed */ return o | (0xe<<24) | (0xb<<20) | (8<<16) | (0xa<<8) | (4<<4) | (1<<18) | (0<<8) | (1<<7); // toint, double, trunc case AMOVDW: if((sc & C_UBIT) == 0) o |= 1<<16; /* signed */ return o | (0xe<<24) | (0xb<<20) | (8<<16) | (0xa<<8) | (4<<4) | (1<<18) | (1<<8) | (1<<7); // toint, double, trunc case AMOVWF+AEND: // copy WtoF return o | (0xe<<24) | (0x0<<20) | (0xb<<8) | (1<<4); case AMOVFW+AEND: // copy FtoW return o | (0xe<<24) | (0x1<<20) | (0xb<<8) | (1<<4); case ACMP+AEND: // cmp imm return o | (0x3<<24) | (0x5<<20); case ACLZ: // CLZ doesn't support .S return (o & (0xf<<28)) | (0x16f<<16) | (0xf1<<4); case AMULWT: return (o & (0xf<<28)) | (0x12 << 20) | (0xe<<4); case AMULWB: return (o & (0xf<<28)) | (0x12 << 20) | (0xa<<4); case AMULAWT: return (o & (0xf<<28)) | (0x12 << 20) | (0xc<<4); case AMULAWB: return (o & (0xf<<28)) | (0x12 << 20) | (0x8<<4); } diag("bad rrr %d", a); prasm(curp); return 0; } int32 opbra(int a, int sc) { if(sc & (C_SBIT|C_PBIT|C_WBIT)) diag(".S/.P/.W on bra instruction"); sc &= C_SCOND; if(a == ABL) return (sc<<28)|(0x5<<25)|(0x1<<24); if(sc != 0xe) diag(".COND on bcond instruction"); switch(a) { case ABEQ: return (0x0<<28)|(0x5<<25); case ABNE: return (0x1<<28)|(0x5<<25); case ABCS: return (0x2<<28)|(0x5<<25); case ABHS: return (0x2<<28)|(0x5<<25); case ABCC: return (0x3<<28)|(0x5<<25); case ABLO: return (0x3<<28)|(0x5<<25); case ABMI: return (0x4<<28)|(0x5<<25); case ABPL: return (0x5<<28)|(0x5<<25); case ABVS: return (0x6<<28)|(0x5<<25); case ABVC: return (0x7<<28)|(0x5<<25); case ABHI: return (0x8<<28)|(0x5<<25); case ABLS: return (0x9<<28)|(0x5<<25); case ABGE: return (0xa<<28)|(0x5<<25); case ABLT: return (0xb<<28)|(0x5<<25); case ABGT: return (0xc<<28)|(0x5<<25); case ABLE: return (0xd<<28)|(0x5<<25); case AB: return (0xe<<28)|(0x5<<25); } diag("bad bra %A", a); prasm(curp); return 0; } int32 olr(int32 v, int b, int r, int sc) { int32 o; if(sc & C_SBIT) diag(".S on LDR/STR instruction"); o = (sc & C_SCOND) << 28; if(!(sc & C_PBIT)) o |= 1 << 24; if(!(sc & C_UBIT)) o |= 1 << 23; if(sc & C_WBIT) o |= 1 << 21; o |= (1<<26) | (1<<20); if(v < 0) { if(sc & C_UBIT) diag(".U on neg offset"); v = -v; o ^= 1 << 23; } if(v >= (1<<12) || v < 0) diag("literal span too large: %d (R%d)\n%P", v, b, PP); o |= v; o |= b << 16; o |= r << 12; return o; } int32 olhr(int32 v, int b, int r, int sc) { int32 o; if(sc & C_SBIT) diag(".S on LDRH/STRH instruction"); o = (sc & C_SCOND) << 28; if(!(sc & C_PBIT)) o |= 1 << 24; if(sc & C_WBIT) o |= 1 << 21; o |= (1<<23) | (1<<20)|(0xb<<4); if(v < 0) { v = -v; o ^= 1 << 23; } if(v >= (1<<8) || v < 0) diag("literal span too large: %d (R%d)\n%P", v, b, PP); o |= (v&0xf)|((v>>4)<<8)|(1<<22); o |= b << 16; o |= r << 12; return o; } int32 osr(int a, int r, int32 v, int b, int sc) { int32 o; o = olr(v, b, r, sc) ^ (1<<20); if(a != AMOVW) o |= 1<<22; return o; } int32 oshr(int r, int32 v, int b, int sc) { int32 o; o = olhr(v, b, r, sc) ^ (1<<20); return o; } int32 osrr(int r, int i, int b, int sc) { return olr(i, b, r, sc) ^ ((1<<25) | (1<<20)); } int32 oshrr(int r, int i, int b, int sc) { return olhr(i, b, r, sc) ^ ((1<<22) | (1<<20)); } int32 olrr(int i, int b, int r, int sc) { return olr(i, b, r, sc) ^ (1<<25); } int32 olhrr(int i, int b, int r, int sc) { return olhr(i, b, r, sc) ^ (1<<22); } int32 ofsr(int a, int r, int32 v, int b, int sc, Prog *p) { int32 o; if(sc & C_SBIT) diag(".S on FLDR/FSTR instruction"); o = (sc & C_SCOND) << 28; if(!(sc & C_PBIT)) o |= 1 << 24; if(sc & C_WBIT) o |= 1 << 21; o |= (6<<25) | (1<<24) | (1<<23) | (10<<8); if(v < 0) { v = -v; o ^= 1 << 23; } if(v & 3) diag("odd offset for floating point op: %d\n%P", v, p); else if(v >= (1<<10) || v < 0) diag("literal span too large: %d\n%P", v, p); o |= (v>>2) & 0xFF; o |= b << 16; o |= r << 12; switch(a) { default: diag("bad fst %A", a); case AMOVD: o |= 1 << 8; case AMOVF: break; } return o; } int32 omvl(Prog *p, Adr *a, int dr) { int32 v, o1; if(!p->cond) { aclass(a); v = immrot(~instoffset); if(v == 0) { diag("missing literal"); prasm(p); return 0; } o1 = oprrr(AMVN, p->scond&C_SCOND); o1 |= v; o1 |= dr << 12; } else { v = p->cond->pc - p->pc - 8; o1 = olr(v, REGPC, dr, p->scond&C_SCOND); } return o1; } int chipzero(Ieee *e) { // We use GOARM=7 to gate the use of VFPv3 vmov (imm) instructions. if(goarm < 7 || e->l != 0 || e->h != 0) return -1; return 0; } int chipfloat(Ieee *e) { int n; ulong h; // We use GOARM=7 to gate the use of VFPv3 vmov (imm) instructions. if(goarm < 7) goto no; if(e->l != 0 || (e->h&0xffff) != 0) goto no; h = e->h & 0x7fc00000; if(h != 0x40000000 && h != 0x3fc00000) goto no; n = 0; // sign bit (a) if(e->h & 0x80000000) n |= 1<<7; // exp sign bit (b) if(h == 0x3fc00000) n |= 1<<6; // rest of exp and mantissa (cd-efgh) n |= (e->h >> 16) & 0x3f; //print("match %.8lux %.8lux %d\n", e->l, e->h, n); return n; no: return -1; }