/* * (C) Copyright IBM Corporation 2008 * 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 * on the rights to use, copy, modify, merge, publish, distribute, sub * license, 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 (including the next * paragraph) 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 NON-INFRINGEMENT. IN NO EVENT SHALL * AUTHORS, COPYRIGHT HOLDERS, AND/OR THEIR SUPPLIERS 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. */ /** * \file * Real-time assembly generation interface for Cell B.E. SPEs. * * \author Ian Romanick */ #include "pipe/p_compiler.h" #include "util/u_memory.h" #include "rtasm_ppc_spe.h" #ifdef GALLIUM_CELL /** * SPE instruction types * * There are 6 primary instruction encodings used on the Cell's SPEs. Each of * the following unions encodes one type. * * \bug * If, at some point, we start generating SPE code from a little-endian host * these unions will not work. */ /*@{*/ /** * Encode one output register with two input registers */ union spe_inst_RR { uint32_t bits; struct { unsigned op:11; unsigned rB:7; unsigned rA:7; unsigned rT:7; } inst; }; /** * Encode one output register with three input registers */ union spe_inst_RRR { uint32_t bits; struct { unsigned op:4; unsigned rT:7; unsigned rB:7; unsigned rA:7; unsigned rC:7; } inst; }; /** * Encode one output register with one input reg. and a 7-bit signed immed */ union spe_inst_RI7 { uint32_t bits; struct { unsigned op:11; unsigned i7:7; unsigned rA:7; unsigned rT:7; } inst; }; /** * Encode one output register with one input reg. and an 8-bit signed immed */ union spe_inst_RI8 { uint32_t bits; struct { unsigned op:10; unsigned i8:8; unsigned rA:7; unsigned rT:7; } inst; }; /** * Encode one output register with one input reg. and a 10-bit signed immed */ union spe_inst_RI10 { uint32_t bits; struct { unsigned op:8; unsigned i10:10; unsigned rA:7; unsigned rT:7; } inst; }; /** * Encode one output register with a 16-bit signed immediate */ union spe_inst_RI16 { uint32_t bits; struct { unsigned op:9; unsigned i16:16; unsigned rT:7; } inst; }; /** * Encode one output register with a 18-bit signed immediate */ union spe_inst_RI18 { uint32_t bits; struct { unsigned op:7; unsigned i18:18; unsigned rT:7; } inst; }; /*@}*/ static void emit_RR(struct spe_function *p, unsigned op, unsigned rT, unsigned rA, unsigned rB) { union spe_inst_RR inst; inst.inst.op = op; inst.inst.rB = rB; inst.inst.rA = rA; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } static void emit_RRR(struct spe_function *p, unsigned op, unsigned rT, unsigned rA, unsigned rB, unsigned rC) { union spe_inst_RRR inst; inst.inst.op = op; inst.inst.rT = rT; inst.inst.rB = rB; inst.inst.rA = rA; inst.inst.rC = rC; *p->csr = inst.bits; p->csr++; } static void emit_RI7(struct spe_function *p, unsigned op, unsigned rT, unsigned rA, int imm) { union spe_inst_RI7 inst; inst.inst.op = op; inst.inst.i7 = imm; inst.inst.rA = rA; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } static void emit_RI8(struct spe_function *p, unsigned op, unsigned rT, unsigned rA, int imm) { union spe_inst_RI8 inst; inst.inst.op = op; inst.inst.i8 = imm; inst.inst.rA = rA; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } static void emit_RI10(struct spe_function *p, unsigned op, unsigned rT, unsigned rA, int imm) { union spe_inst_RI10 inst; inst.inst.op = op; inst.inst.i10 = imm; inst.inst.rA = rA; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } static void emit_RI16(struct spe_function *p, unsigned op, unsigned rT, int imm) { union spe_inst_RI16 inst; inst.inst.op = op; inst.inst.i16 = imm; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } static void emit_RI18(struct spe_function *p, unsigned op, unsigned rT, int imm) { union spe_inst_RI18 inst; inst.inst.op = op; inst.inst.i18 = imm; inst.inst.rT = rT; *p->csr = inst.bits; p->csr++; } #define EMIT_(_name, _op) \ void _name (struct spe_function *p, unsigned rT) \ { \ emit_RR(p, _op, rT, 0, 0); \ } #define EMIT_R(_name, _op) \ void _name (struct spe_function *p, unsigned rT, unsigned rA) \ { \ emit_RR(p, _op, rT, rA, 0); \ } #define EMIT_RR(_name, _op) \ void _name (struct spe_function *p, unsigned rT, unsigned rA, unsigned rB) \ { \ emit_RR(p, _op, rT, rA, rB); \ } #define EMIT_RRR(_name, _op) \ void _name (struct spe_function *p, unsigned rT, unsigned rA, unsigned rB, unsigned rC) \ { \ emit_RRR(p, _op, rT, rA, rB, rC); \ } #define EMIT_RI7(_name, _op) \ void _name (struct spe_function *p, unsigned rT, unsigned rA, int imm) \ { \ emit_RI7(p, _op, rT, rA, imm); \ } #define EMIT_RI8(_name, _op, bias) \ void _name (struct spe_function *p, unsigned rT, unsigned rA, int imm) \ { \ emit_RI8(p, _op, rT, rA, bias - imm); \ } #define EMIT_RI10(_name, _op) \ void _name (struct spe_function *p, unsigned rT, unsigned rA, int imm) \ { \ emit_RI10(p, _op, rT, rA, imm); \ } #define EMIT_RI16(_name, _op) \ void _name (struct spe_function *p, unsigned rT, int imm) \ { \ emit_RI16(p, _op, rT, imm); \ } #define EMIT_RI18(_name, _op) \ void _name (struct spe_function *p, unsigned rT, int imm) \ { \ emit_RI18(p, _op, rT, imm); \ } #define EMIT_I16(_name, _op) \ void _name (struct spe_function *p, int imm) \ { \ emit_RI16(p, _op, 0, imm); \ } #include "rtasm_ppc_spe.h" /* */ void spe_init_func(struct spe_function *p, unsigned code_size) { p->store = align_malloc(code_size, 16); p->csr = p->store; /* Conservatively treat R0 - R2 and R80 - R127 as non-volatile. */ p->regs[0] = ~7; p->regs[1] = (1U << (80 - 64)) - 1; } void spe_release_func(struct spe_function *p) { if (p->store != NULL) { align_free(p->store); } p->store = NULL; p->csr = NULL; } int spe_allocate_available_register(struct spe_function *p) { unsigned i; for (i = 0; i < 128; i++) { const uint64_t mask = (1ULL << (i % 64)); const unsigned idx = i / 64; if ((p->regs[idx] & mask) != 0) { p->regs[idx] &= ~mask; return i; } } return -1; } int spe_allocate_register(struct spe_function *p, int reg) { const unsigned idx = reg / 64; const unsigned bit = reg % 64; assert((p->regs[idx] & (1ULL << bit)) != 0); p->regs[idx] &= ~(1ULL << bit); return reg; } void spe_release_register(struct spe_function *p, int reg) { const unsigned idx = reg / 64; const unsigned bit = reg % 64; assert((p->regs[idx] & (1ULL << bit)) == 0); p->regs[idx] |= (1ULL << bit); } void spe_bi(struct spe_function *p, unsigned rA, int d, int e) { emit_RI7(p, 0x1a8, 0, rA, (d << 5) | (e << 4)); } void spe_iret(struct spe_function *p, unsigned rA, int d, int e) { emit_RI7(p, 0x1aa, 0, rA, (d << 5) | (e << 4)); } void spe_bisled(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x1ab, rT, rA, (d << 5) | (e << 4)); } void spe_bisl(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x1a9, rT, rA, (d << 5) | (e << 4)); } void spe_biz(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x128, rT, rA, (d << 5) | (e << 4)); } void spe_binz(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x129, rT, rA, (d << 5) | (e << 4)); } void spe_bihz(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x12a, rT, rA, (d << 5) | (e << 4)); } void spe_bihnz(struct spe_function *p, unsigned rT, unsigned rA, int d, int e) { emit_RI7(p, 0x12b, rT, rA, (d << 5) | (e << 4)); } /* Hint-for-branch instructions */ #if 0 hbr; hbra; hbrr; #endif /* Control instructions */ #if 0 stop; EMIT_RR (spe_stopd, 0x140); EMIT_ (spe_lnop, 0x001); EMIT_ (spe_nop, 0x201); sync; EMIT_ (spe_dsync, 0x003); EMIT_R (spe_mfspr, 0x00c); EMIT_R (spe_mtspr, 0x10c); #endif #endif /* GALLIUM_CELL */