/************************************************************************** * * Copyright (C) 2008 Tungsten Graphics, Inc. All Rights Reserved. * Copyright (C) 2009 VMware, Inc. 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 * BRIAN PAUL 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. * **************************************************************************/ /** * PPC code generation. * For reference, see http://www.power.org/resources/reading/PowerISA_V2.05.pdf * ABI info: http://www.cs.utsa.edu/~whaley/teach/cs6463FHPO/LEC/lec12_ho.pdf * * Other PPC refs: * http://www-01.ibm.com/chips/techlib/techlib.nsf/techdocs/852569B20050FF778525699600719DF2 * http://www.ibm.com/developerworks/eserver/library/es-archguide-v2.html * http://www.freescale.com/files/product/doc/MPCFPE32B.pdf * * \author Brian Paul */ #include #include "util/u_memory.h" #include "util/u_debug.h" #include "rtasm_execmem.h" #include "rtasm_ppc.h" void ppc_init_func(struct ppc_function *p) { uint i; memset(p, 0, sizeof(*p)); p->num_inst = 0; p->max_inst = 100; /* first guess at buffer size */ p->store = rtasm_exec_malloc(p->max_inst * PPC_INST_SIZE); p->reg_used = 0x0; p->fp_used = 0x0; p->vec_used = 0x0; p->print = FALSE; p->indent = 0; /* only allow using gp registers 3..12 for now */ for (i = 0; i < 3; i++) ppc_reserve_register(p, i); for (i = 12; i < PPC_NUM_REGS; i++) ppc_reserve_register(p, i); } void ppc_release_func(struct ppc_function *p) { assert(p->num_inst <= p->max_inst); if (p->store != NULL) { rtasm_exec_free(p->store); } p->store = NULL; } uint ppc_num_instructions(const struct ppc_function *p) { return p->num_inst; } void (*ppc_get_func(struct ppc_function *p))(void) { #if 0 DUMP_END(); if (DISASSEM && p->store) debug_printf("disassemble %p %p\n", p->store, p->csr); if (p->store == p->error_overflow) return (void (*)(void)) NULL; else #endif return (void (*)(void)) pointer_to_func(p->store); } void ppc_dump_func(const struct ppc_function *p) { uint i; for (i = 0; i < p->num_inst; i++) { debug_printf("%3u: 0x%08x\n", i, p->store[i]); } } void ppc_print_code(struct ppc_function *p, boolean enable) { p->print = enable; } void ppc_indent(struct ppc_function *p, int spaces) { p->indent += spaces; } static void indent(const struct ppc_function *p) { int i; for (i = 0; i < p->indent; i++) { putchar(' '); } } void ppc_comment(struct ppc_function *p, int rel_indent, const char *s) { if (p->print) { p->indent += rel_indent; indent(p); p->indent -= rel_indent; printf("# %s\n", s); } } /** * Mark a register as being unavailable. */ int ppc_reserve_register(struct ppc_function *p, int reg) { assert(reg < PPC_NUM_REGS); p->reg_used |= (1 << reg); return reg; } /** * Allocate a general purpose register. * \return register index or -1 if none left. */ int ppc_allocate_register(struct ppc_function *p) { unsigned i; for (i = 0; i < PPC_NUM_REGS; i++) { const uint32_t mask = 1 << i; if ((p->reg_used & mask) == 0) { p->reg_used |= mask; return i; } } printf("OUT OF PPC registers!\n"); return -1; } /** * Mark the given general purpose register as "unallocated". */ void ppc_release_register(struct ppc_function *p, int reg) { assert(reg < PPC_NUM_REGS); assert(p->reg_used & (1 << reg)); p->reg_used &= ~(1 << reg); } /** * Allocate a floating point register. * \return register index or -1 if none left. */ int ppc_allocate_fp_register(struct ppc_function *p) { unsigned i; for (i = 0; i < PPC_NUM_FP_REGS; i++) { const uint32_t mask = 1 << i; if ((p->fp_used & mask) == 0) { p->fp_used |= mask; return i; } } printf("OUT OF PPC FP registers!\n"); return -1; } /** * Mark the given floating point register as "unallocated". */ void ppc_release_fp_register(struct ppc_function *p, int reg) { assert(reg < PPC_NUM_FP_REGS); assert(p->fp_used & (1 << reg)); p->fp_used &= ~(1 << reg); } /** * Allocate a vector register. * \return register index or -1 if none left. */ int ppc_allocate_vec_register(struct ppc_function *p) { unsigned i; for (i = 0; i < PPC_NUM_VEC_REGS; i++) { const uint32_t mask = 1 << i; if ((p->vec_used & mask) == 0) { p->vec_used |= mask; return i; } } printf("OUT OF PPC VEC registers!\n"); return -1; } /** * Mark the given vector register as "unallocated". */ void ppc_release_vec_register(struct ppc_function *p, int reg) { assert(reg < PPC_NUM_VEC_REGS); assert(p->vec_used & (1 << reg)); p->vec_used &= ~(1 << reg); } /** * Append instruction to instruction buffer. Grow buffer if out of room. */ static void emit_instruction(struct ppc_function *p, uint32_t inst_bits) { if (!p->store) return; /* out of memory, drop the instruction */ if (p->num_inst == p->max_inst) { /* allocate larger buffer */ uint32_t *newbuf; p->max_inst *= 2; /* 2x larger */ newbuf = rtasm_exec_malloc(p->max_inst * PPC_INST_SIZE); if (newbuf) { memcpy(newbuf, p->store, p->num_inst * PPC_INST_SIZE); } rtasm_exec_free(p->store); p->store = newbuf; if (!p->store) { /* out of memory */ p->num_inst = 0; return; } } p->store[p->num_inst++] = inst_bits; } union vx_inst { uint32_t bits; struct { unsigned op:6; unsigned vD:5; unsigned vA:5; unsigned vB:5; unsigned op2:11; } inst; }; static INLINE void emit_vx(struct ppc_function *p, uint op2, uint vD, uint vA, uint vB, const char *format, boolean transpose) { union vx_inst inst; inst.inst.op = 4; inst.inst.vD = vD; inst.inst.vA = vA; inst.inst.vB = vB; inst.inst.op2 = op2; emit_instruction(p, inst.bits); if (p->print) { indent(p); if (transpose) printf(format, vD, vB, vA); else printf(format, vD, vA, vB); } } union vxr_inst { uint32_t bits; struct { unsigned op:6; unsigned vD:5; unsigned vA:5; unsigned vB:5; unsigned rC:1; unsigned op2:10; } inst; }; static INLINE void emit_vxr(struct ppc_function *p, uint op2, uint vD, uint vA, uint vB, const char *format) { union vxr_inst inst; inst.inst.op = 4; inst.inst.vD = vD; inst.inst.vA = vA; inst.inst.vB = vB; inst.inst.rC = 0; inst.inst.op2 = op2; emit_instruction(p, inst.bits); if (p->print) { indent(p); printf(format, vD, vA, vB); } } union va_inst { uint32_t bits; struct { unsigned op:6; unsigned vD:5; unsigned vA:5; unsigned vB:5; unsigned vC:5; unsigned op2:6; } inst; }; static INLINE void emit_va(struct ppc_function *p, uint op2, uint vD, uint vA, uint vB, uint vC, const char *format) { union va_inst inst; inst.inst.op = 4; inst.inst.vD = vD; inst.inst.vA = vA; inst.inst.vB = vB; inst.inst.vC = vC; inst.inst.op2 = op2; emit_instruction(p, inst.bits); if (p->print) { indent(p); printf(format, vD, vA, vB, vC); } } union i_inst { uint32_t bits; struct { unsigned op:6; unsigned li:24; unsigned aa:1; unsigned lk:1; } inst; }; static INLINE void emit_i(struct ppc_function *p, uint op, uint li, uint aa, uint lk) { union i_inst inst; inst.inst.op = op; inst.inst.li = li; inst.inst.aa = aa; inst.inst.lk = lk; emit_instruction(p, inst.bits); } union xl_inst { uint32_t bits; struct { unsigned op:6; unsigned bo:5; unsigned bi:5; unsigned unused:3; unsigned bh:2; unsigned op2:10; unsigned lk:1; } inst; }; static INLINE void emit_xl(struct ppc_function *p, uint op, uint bo, uint bi, uint bh, uint op2, uint lk) { union xl_inst inst; inst.inst.op = op; inst.inst.bo = bo; inst.inst.bi = bi; inst.inst.unused = 0x0; inst.inst.bh = bh; inst.inst.op2 = op2; inst.inst.lk = lk; emit_instruction(p, inst.bits); } static INLINE void dump_xl(const char *name, uint inst) { union xl_inst i; i.bits = inst; debug_printf("%s = 0x%08x\n", name, inst); debug_printf(" op: %d 0x%x\n", i.inst.op, i.inst.op); debug_printf(" bo: %d 0x%x\n", i.inst.bo, i.inst.bo); debug_printf(" bi: %d 0x%x\n", i.inst.bi, i.inst.bi); debug_printf(" unused: %d 0x%x\n", i.inst.unused, i.inst.unused); debug_printf(" bh: %d 0x%x\n", i.inst.bh, i.inst.bh); debug_printf(" op2: %d 0x%x\n", i.inst.op2, i.inst.op2); debug_printf(" lk: %d 0x%x\n", i.inst.lk, i.inst.lk); } union x_inst { uint32_t bits; struct { unsigned op:6; unsigned vrs:5; unsigned ra:5; unsigned rb:5; unsigned op2:10; unsigned unused:1; } inst; }; static INLINE void emit_x(struct ppc_function *p, uint op, uint vrs, uint ra, uint rb, uint op2, const char *format) { union x_inst inst; inst.inst.op = op; inst.inst.vrs = vrs; inst.inst.ra = ra; inst.inst.rb = rb; inst.inst.op2 = op2; inst.inst.unused = 0x0; emit_instruction(p, inst.bits); if (p->print) { indent(p); printf(format, vrs, ra, rb); } } union d_inst { uint32_t bits; struct { unsigned op:6; unsigned rt:5; unsigned ra:5; unsigned si:16; } inst; }; static INLINE void emit_d(struct ppc_function *p, uint op, uint rt, uint ra, int si, const char *format, boolean transpose) { union d_inst inst; assert(si >= -32768); assert(si <= 32767); inst.inst.op = op; inst.inst.rt = rt; inst.inst.ra = ra; inst.inst.si = (unsigned) (si & 0xffff); emit_instruction(p, inst.bits); if (p->print) { indent(p); if (transpose) printf(format, rt, si, ra); else printf(format, rt, ra, si); } } union a_inst { uint32_t bits; struct { unsigned op:6; unsigned frt:5; unsigned fra:5; unsigned frb:5; unsigned unused:5; unsigned op2:5; unsigned rc:1; } inst; }; static INLINE void emit_a(struct ppc_function *p, uint op, uint frt, uint fra, uint frb, uint op2, uint rc, const char *format) { union a_inst inst; inst.inst.op = op; inst.inst.frt = frt; inst.inst.fra = fra; inst.inst.frb = frb; inst.inst.unused = 0x0; inst.inst.op2 = op2; inst.inst.rc = rc; emit_instruction(p, inst.bits); if (p->print) { indent(p); printf(format, frt, fra, frb); } } union xo_inst { uint32_t bits; struct { unsigned op:6; unsigned rt:5; unsigned ra:5; unsigned rb:5; unsigned oe:1; unsigned op2:9; unsigned rc:1; } inst; }; static INLINE void emit_xo(struct ppc_function *p, uint op, uint rt, uint ra, uint rb, uint oe, uint op2, uint rc, const char *format) { union xo_inst inst; inst.inst.op = op; inst.inst.rt = rt; inst.inst.ra = ra; inst.inst.rb = rb; inst.inst.oe = oe; inst.inst.op2 = op2; inst.inst.rc = rc; emit_instruction(p, inst.bits); if (p->print) { indent(p); printf(format, rt, ra, rb); } } /** ** float vector arithmetic **/ /** vector float add */ void ppc_vaddfp(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 10, vD, vA, vB, "vaddfp\t%u, v%u, v%u\n", FALSE); } /** vector float substract */ void ppc_vsubfp(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 74, vD, vA, vB, "vsubfp\tv%u, v%u, v%u\n", FALSE); } /** vector float min */ void ppc_vminfp(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1098, vD, vA, vB, "vminfp\tv%u, v%u, v%u\n", FALSE); } /** vector float max */ void ppc_vmaxfp(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1034, vD, vA, vB, "vmaxfp\tv%u, v%u, v%u\n", FALSE); } /** vector float mult add: vD = vA * vB + vC */ void ppc_vmaddfp(struct ppc_function *p, uint vD, uint vA, uint vB, uint vC) { /* note arg order */ emit_va(p, 46, vD, vA, vC, vB, "vmaddfp\tv%u, v%u, v%u, v%u\n"); } /** vector float negative mult subtract: vD = vA - vB * vC */ void ppc_vnmsubfp(struct ppc_function *p, uint vD, uint vA, uint vB, uint vC) { /* note arg order */ emit_va(p, 47, vD, vB, vA, vC, "vnmsubfp\tv%u, v%u, v%u, v%u\n"); } /** vector float compare greater than */ void ppc_vcmpgtfpx(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vxr(p, 710, vD, vA, vB, "vcmpgtfpx\tv%u, v%u, v%u"); } /** vector float compare greater than or equal to */ void ppc_vcmpgefpx(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vxr(p, 454, vD, vA, vB, "vcmpgefpx\tv%u, v%u, v%u"); } /** vector float compare equal */ void ppc_vcmpeqfpx(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vxr(p, 198, vD, vA, vB, "vcmpeqfpx\tv%u, v%u, v%u"); } /** vector float 2^x */ void ppc_vexptefp(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 394, vD, 0, vB, "vexptefp\tv%u, 0%u, v%u\n", FALSE); } /** vector float log2(x) */ void ppc_vlogefp(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 458, vD, 0, vB, "vlogefp\tv%u, 0%u, v%u\n", FALSE); } /** vector float reciprocol */ void ppc_vrefp(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 266, vD, 0, vB, "vrefp\tv%u, 0%u, v%u\n", FALSE); } /** vector float reciprocol sqrt estimate */ void ppc_vrsqrtefp(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 330, vD, 0, vB, "vrsqrtefp\tv%u, 0%u, v%u\n", FALSE); } /** vector float round to negative infinity */ void ppc_vrfim(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 714, vD, 0, vB, "vrfim\tv%u, 0%u, v%u\n", FALSE); } /** vector float round to positive infinity */ void ppc_vrfip(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 650, vD, 0, vB, "vrfip\tv%u, 0%u, v%u\n", FALSE); } /** vector float round to nearest int */ void ppc_vrfin(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 522, vD, 0, vB, "vrfin\tv%u, 0%u, v%u\n", FALSE); } /** vector float round to int toward zero */ void ppc_vrfiz(struct ppc_function *p, uint vD, uint vB) { emit_vx(p, 586, vD, 0, vB, "vrfiz\tv%u, 0%u, v%u\n", FALSE); } /** vector store: store vR at mem[rA+rB] */ void ppc_stvx(struct ppc_function *p, uint vR, uint rA, uint rB) { emit_x(p, 31, vR, rA, rB, 231, "stvx\tv%u, r%u, r%u\n"); } /** vector load: vR = mem[rA+rB] */ void ppc_lvx(struct ppc_function *p, uint vR, uint rA, uint rB) { emit_x(p, 31, vR, rA, rB, 103, "lvx\tv%u, r%u, r%u\n"); } /** load vector element word: vR = mem_word[ra+rb] */ void ppc_lvewx(struct ppc_function *p, uint vR, uint rA, uint rB) { emit_x(p, 31, vR, rA, rB, 71, "lvewx\tv%u, r%u, r%u\n"); } /** ** vector bitwise operations **/ /** vector and */ void ppc_vand(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1028, vD, vA, vB, "vand\tv%u, v%u, v%u\n", FALSE); } /** vector and complement */ void ppc_vandc(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1092, vD, vA, vB, "vandc\tv%u, v%u, v%u\n", FALSE); } /** vector or */ void ppc_vor(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1156, vD, vA, vB, "vor\tv%u, v%u, v%u\n", FALSE); } /** vector nor */ void ppc_vnor(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1284, vD, vA, vB, "vnor\tv%u, v%u, v%u\n", FALSE); } /** vector xor */ void ppc_vxor(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 1220, vD, vA, vB, "vxor\tv%u, v%u, v%u\n", FALSE); } /** Pseudo-instruction: vector move */ void ppc_vmove(struct ppc_function *p, uint vD, uint vA) { boolean print = p->print; p->print = FALSE; ppc_vor(p, vD, vA, vA); if (print) { indent(p); printf("vor\tv%u, v%u, v%u \t# v%u = v%u\n", vD, vA, vA, vD, vA); } p->print = print; } /** Set vector register to {0,0,0,0} */ void ppc_vzero(struct ppc_function *p, uint vr) { boolean print = p->print; p->print = FALSE; ppc_vxor(p, vr, vr, vr); if (print) { indent(p); printf("vxor\tv%u, v%u, v%u \t# v%u = {0,0,0,0}\n", vr, vr, vr, vr); } p->print = print; } /** ** Vector shuffle / select / splat / etc **/ /** vector permute */ void ppc_vperm(struct ppc_function *p, uint vD, uint vA, uint vB, uint vC) { emit_va(p, 43, vD, vA, vB, vC, "vperm\tr%u, r%u, r%u, r%u"); } /** vector select */ void ppc_vsel(struct ppc_function *p, uint vD, uint vA, uint vB, uint vC) { emit_va(p, 42, vD, vA, vB, vC, "vsel\tr%u, r%u, r%u, r%u"); } /** vector splat byte */ void ppc_vspltb(struct ppc_function *p, uint vD, uint vB, uint imm) { emit_vx(p, 42, vD, imm, vB, "vspltb\tv%u, v%u, %u\n", TRUE); } /** vector splat half word */ void ppc_vsplthw(struct ppc_function *p, uint vD, uint vB, uint imm) { emit_vx(p, 588, vD, imm, vB, "vsplthw\tv%u, v%u, %u\n", TRUE); } /** vector splat word */ void ppc_vspltw(struct ppc_function *p, uint vD, uint vB, uint imm) { emit_vx(p, 652, vD, imm, vB, "vspltw\tv%u, v%u, %u\n", TRUE); } /** vector splat signed immediate word */ void ppc_vspltisw(struct ppc_function *p, uint vD, int imm) { assert(imm >= -16); assert(imm < 15); emit_vx(p, 908, vD, imm, 0, "vspltisw\tv%u, %d, %u\n", FALSE); } /** vector shift left word: vD[word] = vA[word] << (vB[word] & 0x1f) */ void ppc_vslw(struct ppc_function *p, uint vD, uint vA, uint vB) { emit_vx(p, 388, vD, vA, vB, "vslw\tv%u, v%u, v%u\n", FALSE); } /** ** integer arithmetic **/ /** rt = ra + imm */ void ppc_addi(struct ppc_function *p, uint rt, uint ra, int imm) { emit_d(p, 14, rt, ra, imm, "addi\tr%u, r%u, %d\n", FALSE); } /** rt = ra + (imm << 16) */ void ppc_addis(struct ppc_function *p, uint rt, uint ra, int imm) { emit_d(p, 15, rt, ra, imm, "addis\tr%u, r%u, %d\n", FALSE); } /** rt = ra + rb */ void ppc_add(struct ppc_function *p, uint rt, uint ra, uint rb) { emit_xo(p, 31, rt, ra, rb, 0, 266, 0, "add\tr%u, r%u, r%u\n"); } /** rt = ra AND ra */ void ppc_and(struct ppc_function *p, uint rt, uint ra, uint rb) { emit_x(p, 31, ra, rt, rb, 28, "and\tr%u, r%u, r%u\n"); /* note argument order */ } /** rt = ra AND imm */ void ppc_andi(struct ppc_function *p, uint rt, uint ra, int imm) { /* note argument order */ emit_d(p, 28, ra, rt, imm, "andi\tr%u, r%u, %d\n", FALSE); } /** rt = ra OR ra */ void ppc_or(struct ppc_function *p, uint rt, uint ra, uint rb) { emit_x(p, 31, ra, rt, rb, 444, "or\tr%u, r%u, r%u\n"); /* note argument order */ } /** rt = ra OR imm */ void ppc_ori(struct ppc_function *p, uint rt, uint ra, int imm) { /* note argument order */ emit_d(p, 24, ra, rt, imm, "ori\tr%u, r%u, %d\n", FALSE); } /** rt = ra XOR ra */ void ppc_xor(struct ppc_function *p, uint rt, uint ra, uint rb) { emit_x(p, 31, ra, rt, rb, 316, "xor\tr%u, r%u, r%u\n"); /* note argument order */ } /** rt = ra XOR imm */ void ppc_xori(struct ppc_function *p, uint rt, uint ra, int imm) { /* note argument order */ emit_d(p, 26, ra, rt, imm, "xori\tr%u, r%u, %d\n", FALSE); } /** pseudo instruction: move: rt = ra */ void ppc_mr(struct ppc_function *p, uint rt, uint ra) { ppc_or(p, rt, ra, ra); } /** pseudo instruction: load immediate: rt = imm */ void ppc_li(struct ppc_function *p, uint rt, int imm) { boolean print = p->print; p->print = FALSE; ppc_addi(p, rt, 0, imm); if (print) { indent(p); printf("addi\tr%u, r0, %d \t# r%u = %d\n", rt, imm, rt, imm); } p->print = print; } /** rt = imm << 16 */ void ppc_lis(struct ppc_function *p, uint rt, int imm) { ppc_addis(p, rt, 0, imm); } /** rt = imm */ void ppc_load_int(struct ppc_function *p, uint rt, int imm) { ppc_lis(p, rt, (imm >> 16)); /* rt = imm >> 16 */ ppc_ori(p, rt, rt, (imm & 0xffff)); /* rt = rt | (imm & 0xffff) */ } /** ** integer load/store **/ /** store rs at memory[(ra)+d], * then update ra = (ra)+d */ void ppc_stwu(struct ppc_function *p, uint rs, uint ra, int d) { emit_d(p, 37, rs, ra, d, "stwu\tr%u, %d(r%u)\n", TRUE); } /** store rs at memory[(ra)+d] */ void ppc_stw(struct ppc_function *p, uint rs, uint ra, int d) { emit_d(p, 36, rs, ra, d, "stw\tr%u, %d(r%u)\n", TRUE); } /** Load rt = mem[(ra)+d]; then zero set high 32 bits to zero. */ void ppc_lwz(struct ppc_function *p, uint rt, uint ra, int d) { emit_d(p, 32, rt, ra, d, "lwz\tr%u, %d(r%u)\n", TRUE); } /** ** Float (non-vector) arithmetic **/ /** add: frt = fra + frb */ void ppc_fadd(struct ppc_function *p, uint frt, uint fra, uint frb) { emit_a(p, 63, frt, fra, frb, 21, 0, "fadd\tf%u, f%u, f%u\n"); } /** sub: frt = fra - frb */ void ppc_fsub(struct ppc_function *p, uint frt, uint fra, uint frb) { emit_a(p, 63, frt, fra, frb, 20, 0, "fsub\tf%u, f%u, f%u\n"); } /** convert to int: rt = (int) ra */ void ppc_fctiwz(struct ppc_function *p, uint rt, uint fra) { emit_x(p, 63, rt, 0, fra, 15, "fctiwz\tr%u, r%u, r%u\n"); } /** store frs at mem[(ra)+offset] */ void ppc_stfs(struct ppc_function *p, uint frs, uint ra, int offset) { emit_d(p, 52, frs, ra, offset, "stfs\tr%u, %d(r%u)\n", TRUE); } /** store frs at mem[(ra)+(rb)] */ void ppc_stfiwx(struct ppc_function *p, uint frs, uint ra, uint rb) { emit_x(p, 31, frs, ra, rb, 983, "stfiwx\tr%u, r%u, r%u\n"); } /** load frt = mem[(ra)+offset] */ void ppc_lfs(struct ppc_function *p, uint frt, uint ra, int offset) { emit_d(p, 48, frt, ra, offset, "stfs\tr%u, %d(r%u)\n", TRUE); } /** ** branch instructions **/ /** BLR: Branch to link register (p. 35) */ void ppc_blr(struct ppc_function *p) { emit_i(p, 18, 0, 0, 1); if (p->print) { indent(p); printf("blr\n"); } } /** Branch Conditional to Link Register (p. 36) */ void ppc_bclr(struct ppc_function *p, uint condOp, uint branchHint, uint condReg) { emit_xl(p, 19, condOp, condReg, branchHint, 16, 0); if (p->print) { indent(p); printf("bclr\t%u %u %u\n", condOp, branchHint, condReg); } } /** Pseudo instruction: return from subroutine */ void ppc_return(struct ppc_function *p) { ppc_bclr(p, BRANCH_COND_ALWAYS, BRANCH_HINT_SUB_RETURN, 0); }