/* * Copyright 2013 Vadim Girlin * * 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 * THE AUTHOR(S) 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. * * Authors: * Vadim Girlin */ #include #include "sb_shader.h" namespace r600_sb { value* get_select_value_for_em(shader& sh, value* em) { if (!em->def) return NULL; node *predset = em->def; if (!predset->is_pred_set()) return NULL; alu_node *s = sh.clone(static_cast(predset)); convert_predset_to_set(sh, s); predset->insert_after(s); value* &d0 = s->dst[0]; d0 = sh.create_temp_value(); d0->def = s; return d0; } void convert_to_mov(alu_node &n, value *src, bool neg, bool abs) { n.src.resize(1); n.src[0] = src; n.bc.src[0].abs = abs; n.bc.src[0].neg = neg; n.bc.set_op(ALU_OP1_MOV); } expr_handler::expr_handler(shader& sh) : sh(sh), vt(sh.vt) {} value * expr_handler::get_const(const literal &l) { value *v = sh.get_const_value(l); if (!v->gvn_source) vt.add_value(v); return v; } void expr_handler::assign_source(value *dst, value *src) { dst->gvn_source = src->gvn_source; } bool expr_handler::equal(value *l, value *r) { assert(l != r); if (l->is_lds_access() || r->is_lds_access()) return false; if (l->gvalue() == r->gvalue()) return true; if (l->def && r->def) return defs_equal(l, r); if (l->is_rel() && r->is_rel()) return ivars_equal(l, r); return false; } bool expr_handler::ivars_equal(value* l, value* r) { if (l->rel->gvalue() == r->rel->gvalue() && l->select == r->select) { vvec &lv = l->mdef.empty() ? l->muse : l->mdef; vvec &rv = r->mdef.empty() ? r->muse : r->mdef; // FIXME: replace this with more precise aliasing test return lv == rv; } return false; } bool expr_handler::defs_equal(value* l, value* r) { node *d1 = l->def; node *d2 = r->def; if (d1->type != d2->type || d1->subtype != d2->subtype) return false; if (d1->is_pred_set() || d2->is_pred_set()) return false; if (d1->type == NT_OP) { switch (d1->subtype) { case NST_ALU_INST: return ops_equal( static_cast(d1), static_cast(d2)); // case NST_FETCH_INST: return ops_equal(static_cast(d1), // static_cast(d2); // case NST_CF_INST: return ops_equal(static_cast(d1), // static_cast(d2); default: break; } } return false; } bool expr_handler::try_fold(value* v) { assert(!v->gvn_source); if (v->def) try_fold(v->def); if (v->gvn_source) return true; return false; } bool expr_handler::try_fold(node* n) { return n->fold_dispatch(this); } bool expr_handler::fold(node& n) { if (n.subtype == NST_PHI) { value *s = n.src[0]; // FIXME disabling phi folding for registers for now, otherwise we lose // control flow information in some cases // (GCM fails on tests/shaders/glsl-fs-if-nested-loop.shader_test) // probably control flow transformation is required to enable it if (s->is_sgpr()) return false; for(vvec::iterator I = n.src.begin() + 1, E = n.src.end(); I != E; ++I) { value *v = *I; if (!s->v_equal(v)) return false; } assign_source(n.dst[0], s); } else { assert(n.subtype == NST_PSI); assert(n.src.size() >= 6); value *s = n.src[2]; assert(s->gvn_source); for(vvec::iterator I = n.src.begin() + 3, E = n.src.end(); I != E; I += 3) { value *v = *(I+2); if (!s->v_equal(v)) return false; } assign_source(n.dst[0], s); } return true; } bool expr_handler::fold(container_node& n) { return false; } bool expr_handler::fold_setcc(alu_node &n) { value* v0 = n.src[0]->gvalue(); value* v1 = n.src[1]->gvalue(); assert(v0 && v1 && n.dst[0]); unsigned flags = n.bc.op_ptr->flags; unsigned cc = flags & AF_CC_MASK; unsigned cmp_type = flags & AF_CMP_TYPE_MASK; unsigned dst_type = flags & AF_DST_TYPE_MASK; bool cond_result; bool have_result = false; bool isc0 = v0->is_const(); bool isc1 = v1->is_const(); literal dv, cv0, cv1; if (isc0) { cv0 = v0->get_const_value(); apply_alu_src_mod(n.bc, 0, cv0); } if (isc1) { cv1 = v1->get_const_value(); apply_alu_src_mod(n.bc, 1, cv1); } if (isc0 && isc1) { cond_result = evaluate_condition(flags, cv0, cv1); have_result = true; } else if (isc1) { if (cmp_type == AF_FLOAT_CMP) { if (n.bc.src[0].abs && !n.bc.src[0].neg) { if (cv1.f < 0.0f && cc == AF_CC_NE) { cond_result = true; have_result = true; } } else if (n.bc.src[0].abs && n.bc.src[0].neg) { if (cv1.f > 0.0f && cc == AF_CC_E) { cond_result = false; have_result = true; } } } else if (cmp_type == AF_UINT_CMP && cv1.u == 0 && cc == AF_CC_GE) { cond_result = true; have_result = true; } } else if (isc0) { if (cmp_type == AF_FLOAT_CMP) { if (n.bc.src[1].abs && !n.bc.src[1].neg) { if (cv0.f < 0.0f && (cc == AF_CC_E)) { cond_result = false; have_result = true; } } else if (n.bc.src[1].abs && n.bc.src[1].neg) { if (cv0.f > 0.0f && cc == AF_CC_NE) { cond_result = true; have_result = true; } } } else if (cmp_type == AF_UINT_CMP && cv0.u == 0 && cc == AF_CC_GT) { cond_result = false; have_result = true; } } else if (v0 == v1) { bc_alu_src &s0 = n.bc.src[0], &s1 = n.bc.src[1]; if (s0.abs == s1.abs && s0.neg == s1.neg && cmp_type != AF_FLOAT_CMP) { // NOTE can't handle float comparisons here because of NaNs cond_result = (cc == AF_CC_E || cc == AF_CC_GE); have_result = true; } } if (have_result) { literal result; if (cond_result) result = dst_type != AF_FLOAT_DST ? literal(0xFFFFFFFFu) : literal(1.0f); else result = literal(0); convert_to_mov(n, sh.get_const_value(result)); return fold_alu_op1(n); } return false; } bool expr_handler::fold(alu_node& n) { switch (n.bc.op_ptr->src_count) { case 1: return fold_alu_op1(n); case 2: return fold_alu_op2(n); case 3: return fold_alu_op3(n); default: assert(0); } return false; } bool expr_handler::fold(fetch_node& n) { unsigned chan = 0; for (vvec::iterator I = n.dst.begin(), E = n.dst.end(); I != E; ++I) { value* &v = *I; if (v) { if (n.bc.dst_sel[chan] == SEL_0) assign_source(*I, get_const(0.0f)); else if (n.bc.dst_sel[chan] == SEL_1) assign_source(*I, get_const(1.0f)); } ++chan; } return false; } bool expr_handler::fold(cf_node& n) { return false; } void expr_handler::apply_alu_src_mod(const bc_alu &bc, unsigned src, literal &v) { const bc_alu_src &s = bc.src[src]; if (s.abs) v = fabsf(v.f); if (s.neg) v = -v.f; } void expr_handler::apply_alu_dst_mod(const bc_alu &bc, literal &v) { const float omod_coeff[] = {2.0f, 4.0, 0.5f}; if (bc.omod) v = v.f * omod_coeff[bc.omod - 1]; if (bc.clamp) v = float_clamp(v.f); } bool expr_handler::args_equal(const vvec &l, const vvec &r) { assert(l.size() == r.size()); int s = l.size(); for (int k = 0; k < s; ++k) { if (!l[k]->v_equal(r[k])) return false; } return true; } bool expr_handler::ops_equal(const alu_node *l, const alu_node* r) { const bc_alu &b0 = l->bc; const bc_alu &b1 = r->bc; if (b0.op != b1.op) return false; unsigned src_count = b0.op_ptr->src_count; if (b0.index_mode != b1.index_mode) return false; if (b0.clamp != b1.clamp || b0.omod != b1.omod) return false; for (unsigned s = 0; s < src_count; ++s) { const bc_alu_src &s0 = b0.src[s]; const bc_alu_src &s1 = b1.src[s]; if (s0.abs != s1.abs || s0.neg != s1.neg) return false; } return args_equal(l->src, r->src); } bool expr_handler::fold_alu_op1(alu_node& n) { assert(!n.src.empty()); if (n.src.empty()) return false; /* don't fold LDS instructions */ if (n.bc.op_ptr->flags & AF_LDS) return false; value* v0 = n.src[0]->gvalue(); if (v0->is_lds_oq() || v0->is_lds_access()) return false; assert(v0 && n.dst[0]); if (!v0->is_const()) { // handle (MOV -(MOV -x)) => (MOV x) if (n.bc.op == ALU_OP1_MOV && n.bc.src[0].neg && !n.bc.src[1].abs && v0->def && v0->def->is_alu_op(ALU_OP1_MOV)) { alu_node *sd = static_cast(v0->def); if (!sd->bc.clamp && !sd->bc.omod && !sd->bc.src[0].abs && sd->bc.src[0].neg) { n.src[0] = sd->src[0]; n.bc.src[0].neg = 0; v0 = n.src[0]->gvalue(); } } if ((n.bc.op == ALU_OP1_MOV || n.bc.op == ALU_OP1_MOVA_INT || n.bc.op == ALU_OP1_MOVA_GPR_INT) && n.bc.clamp == 0 && n.bc.omod == 0 && n.bc.src[0].abs == 0 && n.bc.src[0].neg == 0 && n.src.size() == 1 /* RIM/SIM can be appended as additional values */ && n.dst[0]->no_reladdr_conflict_with(v0)) { assign_source(n.dst[0], v0); return true; } return false; } literal dv, cv = v0->get_const_value(); apply_alu_src_mod(n.bc, 0, cv); switch (n.bc.op) { case ALU_OP1_CEIL: dv = ceilf(cv.f); break; case ALU_OP1_COS: dv = cos(cv.f * 2.0f * M_PI); break; case ALU_OP1_EXP_IEEE: dv = exp2f(cv.f); break; case ALU_OP1_FLOOR: dv = floorf(cv.f); break; case ALU_OP1_FLT_TO_INT: dv = (int)cv.f; break; // FIXME: round modes ???? case ALU_OP1_FLT_TO_INT_FLOOR: dv = (int32_t)floorf(cv.f); break; case ALU_OP1_FLT_TO_INT_RPI: dv = (int32_t)floorf(cv.f + 0.5f); break; case ALU_OP1_FLT_TO_INT_TRUNC: dv = (int32_t)truncf(cv.f); break; case ALU_OP1_FLT_TO_UINT: dv = (uint32_t)cv.f; break; case ALU_OP1_FRACT: dv = cv.f - floorf(cv.f); break; case ALU_OP1_INT_TO_FLT: dv = (float)cv.i; break; case ALU_OP1_LOG_CLAMPED: case ALU_OP1_LOG_IEEE: if (cv.f != 0.0f) dv = log2f(cv.f); else // don't fold to NAN, let the GPU handle it for now // (prevents degenerate LIT tests from failing) return false; break; case ALU_OP1_MOV: dv = cv; break; case ALU_OP1_MOVA_INT: dv = cv; break; // FIXME ??? // case ALU_OP1_MOVA_FLOOR: dv = (int32_t)floor(cv.f); break; // case ALU_OP1_MOVA_GPR_INT: case ALU_OP1_NOT_INT: dv = ~cv.i; break; case ALU_OP1_PRED_SET_INV: dv = cv.f == 0.0f ? 1.0f : (cv.f == 1.0f ? 0.0f : cv.f); break; case ALU_OP1_PRED_SET_RESTORE: dv = cv; break; case ALU_OP1_RECIPSQRT_CLAMPED: case ALU_OP1_RECIPSQRT_FF: case ALU_OP1_RECIPSQRT_IEEE: dv = 1.0f / sqrtf(cv.f); break; case ALU_OP1_RECIP_CLAMPED: case ALU_OP1_RECIP_FF: case ALU_OP1_RECIP_IEEE: dv = 1.0f / cv.f; break; // case ALU_OP1_RECIP_INT: case ALU_OP1_RECIP_UINT: { if (!cv.u) return false; dv.u = (1ull << 32) / cv.u; break; } // case ALU_OP1_RNDNE: dv = floor(cv.f + 0.5f); break; case ALU_OP1_SIN: dv = sin(cv.f * 2.0f * M_PI); break; case ALU_OP1_SQRT_IEEE: dv = sqrtf(cv.f); break; case ALU_OP1_TRUNC: dv = truncf(cv.f); break; default: return false; } apply_alu_dst_mod(n.bc, dv); assign_source(n.dst[0], get_const(dv)); return true; } bool expr_handler::fold_mul_add(alu_node *n) { bool ieee; value* v0 = n->src[0]->gvalue(); alu_node *d0 = (v0->def && v0->def->is_alu_inst()) ? static_cast(v0->def) : NULL; if (d0) { if (d0->is_alu_op(ALU_OP2_MUL_IEEE)) ieee = true; else if (d0->is_alu_op(ALU_OP2_MUL)) ieee = false; else return false; if (!d0->bc.src[0].abs && !d0->bc.src[1].abs && !n->bc.src[1].abs && !n->bc.src[0].abs && !d0->bc.omod && !d0->bc.clamp && !n->bc.omod && (!d0->src[0]->is_kcache() || !d0->src[1]->is_kcache() || !n->src[1]->is_kcache())) { bool mul_neg = n->bc.src[0].neg; n->src.resize(3); n->bc.set_op(ieee ? ALU_OP3_MULADD_IEEE : ALU_OP3_MULADD); n->src[2] = n->src[1]; n->bc.src[2] = n->bc.src[1]; n->src[0] = d0->src[0]; n->bc.src[0] = d0->bc.src[0]; n->src[1] = d0->src[1]; n->bc.src[1] = d0->bc.src[1]; n->bc.src[0].neg ^= mul_neg; fold_alu_op3(*n); return true; } } value* v1 = n->src[1]->gvalue(); alu_node *d1 = (v1->def && v1->def->is_alu_inst()) ? static_cast(v1->def) : NULL; if (d1) { if (d1->is_alu_op(ALU_OP2_MUL_IEEE)) ieee = true; else if (d1->is_alu_op(ALU_OP2_MUL)) ieee = false; else return false; if (!d1->bc.src[1].abs && !d1->bc.src[0].abs && !n->bc.src[0].abs && !n->bc.src[1].abs && !d1->bc.omod && !d1->bc.clamp && !n->bc.omod && (!d1->src[0]->is_kcache() || !d1->src[1]->is_kcache() || !n->src[0]->is_kcache())) { bool mul_neg = n->bc.src[1].neg; n->src.resize(3); n->bc.set_op(ieee ? ALU_OP3_MULADD_IEEE : ALU_OP3_MULADD); n->src[2] = n->src[0]; n->bc.src[2] = n->bc.src[0]; n->src[1] = d1->src[1]; n->bc.src[1] = d1->bc.src[1]; n->src[0] = d1->src[0]; n->bc.src[0] = d1->bc.src[0]; n->bc.src[1].neg ^= mul_neg; fold_alu_op3(*n); return true; } } return false; } bool expr_handler::eval_const_op(unsigned op, literal &r, literal cv0, literal cv1) { switch (op) { case ALU_OP2_ADD: r = cv0.f + cv1.f; break; case ALU_OP2_ADDC_UINT: r = (uint32_t)(((uint64_t)cv0.u + cv1.u)>>32); break; case ALU_OP2_ADD_INT: r = cv0.i + cv1.i; break; case ALU_OP2_AND_INT: r = cv0.i & cv1.i; break; case ALU_OP2_ASHR_INT: r = cv0.i >> (cv1.i & 0x1F); break; case ALU_OP2_BFM_INT: r = (((1 << (cv0.i & 0x1F)) - 1) << (cv1.i & 0x1F)); break; case ALU_OP2_LSHL_INT: r = cv0.i << cv1.i; break; case ALU_OP2_LSHR_INT: r = cv0.u >> cv1.u; break; case ALU_OP2_MAX: case ALU_OP2_MAX_DX10: r = cv0.f > cv1.f ? cv0.f : cv1.f; break; case ALU_OP2_MAX_INT: r = cv0.i > cv1.i ? cv0.i : cv1.i; break; case ALU_OP2_MAX_UINT: r = cv0.u > cv1.u ? cv0.u : cv1.u; break; case ALU_OP2_MIN: case ALU_OP2_MIN_DX10: r = cv0.f < cv1.f ? cv0.f : cv1.f; break; case ALU_OP2_MIN_INT: r = cv0.i < cv1.i ? cv0.i : cv1.i; break; case ALU_OP2_MIN_UINT: r = cv0.u < cv1.u ? cv0.u : cv1.u; break; case ALU_OP2_MUL: case ALU_OP2_MUL_IEEE: r = cv0.f * cv1.f; break; case ALU_OP2_MULHI_INT: r = (int32_t)(((int64_t)cv0.u * cv1.u)>>32); break; case ALU_OP2_MULHI_UINT: r = (uint32_t)(((uint64_t)cv0.u * cv1.u)>>32); break; case ALU_OP2_MULLO_INT: r = (int32_t)(((int64_t)cv0.u * cv1.u) & 0xFFFFFFFF); break; case ALU_OP2_MULLO_UINT: r = (uint32_t)(((uint64_t)cv0.u * cv1.u) & 0xFFFFFFFF); break; case ALU_OP2_OR_INT: r = cv0.i | cv1.i; break; case ALU_OP2_SUB_INT: r = cv0.i - cv1.i; break; case ALU_OP2_XOR_INT: r = cv0.i ^ cv1.i; break; default: return false; } return true; } // fold the chain of associative ops, e.g. (ADD 2, (ADD x, 3)) => (ADD x, 5) bool expr_handler::fold_assoc(alu_node *n) { alu_node *a = n; literal cr; int last_arg = -3; unsigned op = n->bc.op; bool allow_neg = false, cur_neg = false; bool distribute_neg = false; switch(op) { case ALU_OP2_ADD: distribute_neg = true; allow_neg = true; break; case ALU_OP2_MUL: case ALU_OP2_MUL_IEEE: allow_neg = true; break; case ALU_OP3_MULADD: allow_neg = true; op = ALU_OP2_MUL; break; case ALU_OP3_MULADD_IEEE: allow_neg = true; op = ALU_OP2_MUL_IEEE; break; default: if (n->bc.op_ptr->src_count != 2) return false; } // check if we can evaluate the op if (!eval_const_op(op, cr, literal(0), literal(0))) return false; while (true) { value *v0 = a->src[0]->gvalue(); value *v1 = a->src[1]->gvalue(); last_arg = -2; if (v1->is_const()) { literal arg = v1->get_const_value(); apply_alu_src_mod(a->bc, 1, arg); if (cur_neg && distribute_neg) arg.f = -arg.f; if (a == n) cr = arg; else eval_const_op(op, cr, cr, arg); if (v0->def) { alu_node *d0 = static_cast(v0->def); if ((d0->is_alu_op(op) || (op == ALU_OP2_MUL_IEEE && d0->is_alu_op(ALU_OP2_MUL))) && !d0->bc.omod && !d0->bc.clamp && !a->bc.src[0].abs && (!a->bc.src[0].neg || allow_neg)) { cur_neg ^= a->bc.src[0].neg; a = d0; continue; } } last_arg = 0; } if (v0->is_const()) { literal arg = v0->get_const_value(); apply_alu_src_mod(a->bc, 0, arg); if (cur_neg && distribute_neg) arg.f = -arg.f; if (last_arg == 0) { eval_const_op(op, cr, cr, arg); last_arg = -1; break; } if (a == n) cr = arg; else eval_const_op(op, cr, cr, arg); if (v1->def) { alu_node *d1 = static_cast(v1->def); if ((d1->is_alu_op(op) || (op == ALU_OP2_MUL_IEEE && d1->is_alu_op(ALU_OP2_MUL))) && !d1->bc.omod && !d1->bc.clamp && !a->bc.src[1].abs && (!a->bc.src[1].neg || allow_neg)) { cur_neg ^= a->bc.src[1].neg; a = d1; continue; } } last_arg = 1; } break; }; if (last_arg == -1) { // result is const apply_alu_dst_mod(n->bc, cr); if (n->bc.op == op) { convert_to_mov(*n, sh.get_const_value(cr)); fold_alu_op1(*n); return true; } else { // MULADD => ADD n->src[0] = n->src[2]; n->bc.src[0] = n->bc.src[2]; n->src[1] = sh.get_const_value(cr); n->bc.src[1].clear(); n->src.resize(2); n->bc.set_op(ALU_OP2_ADD); } } else if (last_arg >= 0) { n->src[0] = a->src[last_arg]; n->bc.src[0] = a->bc.src[last_arg]; n->bc.src[0].neg ^= cur_neg; n->src[1] = sh.get_const_value(cr); n->bc.src[1].clear(); } return false; } bool expr_handler::fold_alu_op2(alu_node& n) { if (n.src.size() < 2) return false; unsigned flags = n.bc.op_ptr->flags; if (flags & AF_SET) { return fold_setcc(n); } if (!sh.safe_math && (flags & AF_M_ASSOC)) { if (fold_assoc(&n)) return true; } value* v0 = n.src[0]->gvalue(); value* v1 = n.src[1]->gvalue(); assert(v0 && v1); // handle some operations with equal args, e.g. x + x => x * 2 if (v0 == v1) { if (n.bc.src[0].neg == n.bc.src[1].neg && n.bc.src[0].abs == n.bc.src[1].abs) { switch (n.bc.op) { case ALU_OP2_MIN: // (MIN x, x) => (MOV x) case ALU_OP2_MIN_DX10: case ALU_OP2_MAX: case ALU_OP2_MAX_DX10: convert_to_mov(n, v0, n.bc.src[0].neg, n.bc.src[0].abs); return fold_alu_op1(n); case ALU_OP2_ADD: // (ADD x, x) => (MUL x, 2) if (!sh.safe_math) { n.src[1] = sh.get_const_value(2.0f); n.bc.src[1].clear(); n.bc.set_op(ALU_OP2_MUL); return fold_alu_op2(n); } break; } } if (n.bc.src[0].neg != n.bc.src[1].neg && n.bc.src[0].abs == n.bc.src[1].abs) { switch (n.bc.op) { case ALU_OP2_ADD: // (ADD x, -x) => (MOV 0) if (!sh.safe_math) { convert_to_mov(n, sh.get_const_value(literal(0))); return fold_alu_op1(n); } break; } } } if (n.bc.op == ALU_OP2_ADD) { if (fold_mul_add(&n)) return true; } bool isc0 = v0->is_const(); bool isc1 = v1->is_const(); if (!isc0 && !isc1) return false; literal dv, cv0, cv1; if (isc0) { cv0 = v0->get_const_value(); apply_alu_src_mod(n.bc, 0, cv0); } if (isc1) { cv1 = v1->get_const_value(); apply_alu_src_mod(n.bc, 1, cv1); } if (isc0 && isc1) { if (!eval_const_op(n.bc.op, dv, cv0, cv1)) return false; } else { // one source is const if (isc0 && cv0 == literal(0)) { switch (n.bc.op) { case ALU_OP2_ADD: case ALU_OP2_ADD_INT: case ALU_OP2_MAX_UINT: case ALU_OP2_OR_INT: case ALU_OP2_XOR_INT: convert_to_mov(n, n.src[1], n.bc.src[1].neg, n.bc.src[1].abs); return fold_alu_op1(n); case ALU_OP2_AND_INT: case ALU_OP2_ASHR_INT: case ALU_OP2_LSHL_INT: case ALU_OP2_LSHR_INT: case ALU_OP2_MIN_UINT: case ALU_OP2_MUL: case ALU_OP2_MULHI_UINT: case ALU_OP2_MULLO_UINT: convert_to_mov(n, sh.get_const_value(literal(0))); return fold_alu_op1(n); } } else if (isc1 && cv1 == literal(0)) { switch (n.bc.op) { case ALU_OP2_ADD: case ALU_OP2_ADD_INT: case ALU_OP2_ASHR_INT: case ALU_OP2_LSHL_INT: case ALU_OP2_LSHR_INT: case ALU_OP2_MAX_UINT: case ALU_OP2_OR_INT: case ALU_OP2_SUB_INT: case ALU_OP2_XOR_INT: convert_to_mov(n, n.src[0], n.bc.src[0].neg, n.bc.src[0].abs); return fold_alu_op1(n); case ALU_OP2_AND_INT: case ALU_OP2_MIN_UINT: case ALU_OP2_MUL: case ALU_OP2_MULHI_UINT: case ALU_OP2_MULLO_UINT: convert_to_mov(n, sh.get_const_value(literal(0))); return fold_alu_op1(n); } } else if (isc0 && cv0 == literal(1.0f)) { switch (n.bc.op) { case ALU_OP2_MUL: case ALU_OP2_MUL_IEEE: convert_to_mov(n, n.src[1], n.bc.src[1].neg, n.bc.src[1].abs); return fold_alu_op1(n); } } else if (isc1 && cv1 == literal(1.0f)) { switch (n.bc.op) { case ALU_OP2_MUL: case ALU_OP2_MUL_IEEE: convert_to_mov(n, n.src[0], n.bc.src[0].neg, n.bc.src[0].abs); return fold_alu_op1(n); } } return false; } apply_alu_dst_mod(n.bc, dv); assign_source(n.dst[0], get_const(dv)); return true; } bool expr_handler::evaluate_condition(unsigned alu_cnd_flags, literal s1, literal s2) { unsigned cmp_type = alu_cnd_flags & AF_CMP_TYPE_MASK; unsigned cc = alu_cnd_flags & AF_CC_MASK; switch (cmp_type) { case AF_FLOAT_CMP: { switch (cc) { case AF_CC_E : return s1.f == s2.f; case AF_CC_GT: return s1.f > s2.f; case AF_CC_GE: return s1.f >= s2.f; case AF_CC_NE: return s1.f != s2.f; case AF_CC_LT: return s1.f < s2.f; case AF_CC_LE: return s1.f <= s2.f; default: assert(!"invalid condition code"); return false; } } case AF_INT_CMP: { switch (cc) { case AF_CC_E : return s1.i == s2.i; case AF_CC_GT: return s1.i > s2.i; case AF_CC_GE: return s1.i >= s2.i; case AF_CC_NE: return s1.i != s2.i; case AF_CC_LT: return s1.i < s2.i; case AF_CC_LE: return s1.i <= s2.i; default: assert(!"invalid condition code"); return false; } } case AF_UINT_CMP: { switch (cc) { case AF_CC_E : return s1.u == s2.u; case AF_CC_GT: return s1.u > s2.u; case AF_CC_GE: return s1.u >= s2.u; case AF_CC_NE: return s1.u != s2.u; case AF_CC_LT: return s1.u < s2.u; case AF_CC_LE: return s1.u <= s2.u; default: assert(!"invalid condition code"); return false; } } default: assert(!"invalid cmp_type"); return false; } } bool expr_handler::fold_alu_op3(alu_node& n) { if (n.src.size() < 3) return false; if (!sh.safe_math && (n.bc.op_ptr->flags & AF_M_ASSOC)) { if (fold_assoc(&n)) return true; if (n.src.size() < 3) return fold_alu_op2(n); } value* v0 = n.src[0]->gvalue(); value* v1 = n.src[1]->gvalue(); value* v2 = n.src[2]->gvalue(); /* LDS instructions look like op3 with no dst - don't fold. */ if (!n.dst[0]) return false; assert(v0 && v1 && v2 && n.dst[0]); bool isc0 = v0->is_const(); bool isc1 = v1->is_const(); bool isc2 = v2->is_const(); literal dv, cv0, cv1, cv2; if (isc0) { cv0 = v0->get_const_value(); apply_alu_src_mod(n.bc, 0, cv0); } if (isc1) { cv1 = v1->get_const_value(); apply_alu_src_mod(n.bc, 1, cv1); } if (isc2) { cv2 = v2->get_const_value(); apply_alu_src_mod(n.bc, 2, cv2); } unsigned flags = n.bc.op_ptr->flags; if (flags & AF_CMOV) { int src = 0; if (v1 == v2 && n.bc.src[1].neg == n.bc.src[2].neg) { // result doesn't depend on condition, convert to MOV src = 1; } else if (isc0) { // src0 is const, condition can be evaluated, convert to MOV bool cond = evaluate_condition(n.bc.op_ptr->flags & (AF_CC_MASK | AF_CMP_TYPE_MASK), cv0, literal(0)); src = cond ? 1 : 2; } if (src) { // if src is selected, convert to MOV convert_to_mov(n, n.src[src], n.bc.src[src].neg); return fold_alu_op1(n); } } // handle (MULADD a, x, MUL (x, b)) => (MUL x, ADD (a, b)) if (!sh.safe_math && (n.bc.op == ALU_OP3_MULADD || n.bc.op == ALU_OP3_MULADD_IEEE)) { unsigned op = n.bc.op == ALU_OP3_MULADD_IEEE ? ALU_OP2_MUL_IEEE : ALU_OP2_MUL; if (!isc2 && v2->def && v2->def->is_alu_op(op)) { alu_node *md = static_cast(v2->def); value *mv0 = md->src[0]->gvalue(); value *mv1 = md->src[1]->gvalue(); int es0 = -1, es1 = -1; if (v0 == mv0) { es0 = 0; es1 = 0; } else if (v0 == mv1) { es0 = 0; es1 = 1; } else if (v1 == mv0) { es0 = 1; es1 = 0; } else if (v1 == mv1) { es0 = 1; es1 = 1; } value *va0 = es0 == 0 ? v1 : v0; value *va1 = es1 == 0 ? mv1 : mv0; /* Don't fold if no equal multipliers were found. * Also don#t fold if the operands of the to be created ADD are both * relatively accessed with different AR values because that would * create impossible code. */ if (es0 != -1 && (!va0->is_rel() || !va1->is_rel() || (va0->rel == va1->rel))) { alu_node *add = sh.create_alu(); add->bc.set_op(ALU_OP2_ADD); add->dst.resize(1); add->src.resize(2); value *t = sh.create_temp_value(); t->def = add; add->dst[0] = t; add->src[0] = va0; add->src[1] = va1; add->bc.src[0] = n.bc.src[!es0]; add->bc.src[1] = md->bc.src[!es1]; add->bc.src[1].neg ^= n.bc.src[2].neg ^ (n.bc.src[es0].neg != md->bc.src[es1].neg); n.insert_before(add); vt.add_value(t); t = t->gvalue(); if (es0 == 1) { n.src[0] = n.src[1]; n.bc.src[0] = n.bc.src[1]; } n.src[1] = t; n.bc.src[1].clear(); n.src.resize(2); n.bc.set_op(op); return fold_alu_op2(n); } } } if (!isc0 && !isc1 && !isc2) return false; if (isc0 && isc1 && isc2) { switch (n.bc.op) { case ALU_OP3_MULADD_IEEE: case ALU_OP3_MULADD: dv = cv0.f * cv1.f + cv2.f; break; // TODO default: return false; } } else { if (isc0 && isc1) { switch (n.bc.op) { case ALU_OP3_MULADD: case ALU_OP3_MULADD_IEEE: dv = cv0.f * cv1.f; n.bc.set_op(ALU_OP2_ADD); n.src[0] = sh.get_const_value(dv); n.bc.src[0].clear(); n.src[1] = n.src[2]; n.bc.src[1] = n.bc.src[2]; n.src.resize(2); return fold_alu_op2(n); } } if (n.bc.op == ALU_OP3_MULADD) { if ((isc0 && cv0 == literal(0)) || (isc1 && cv1 == literal(0))) { convert_to_mov(n, n.src[2], n.bc.src[2].neg, n.bc.src[2].abs); return fold_alu_op1(n); } } if (n.bc.op == ALU_OP3_MULADD || n.bc.op == ALU_OP3_MULADD_IEEE) { unsigned op = n.bc.op == ALU_OP3_MULADD_IEEE ? ALU_OP2_MUL_IEEE : ALU_OP2_MUL; if (isc1 && v0 == v2) { cv1.f += (n.bc.src[2].neg != n.bc.src[0].neg ? -1.0f : 1.0f); n.src[1] = sh.get_const_value(cv1); n.bc.src[1].neg = 0; n.bc.src[1].abs = 0; n.bc.set_op(op); n.src.resize(2); return fold_alu_op2(n); } else if (isc0 && v1 == v2) { cv0.f += (n.bc.src[2].neg != n.bc.src[1].neg ? -1.0f : 1.0f); n.src[0] = sh.get_const_value(cv0); n.bc.src[0].neg = 0; n.bc.src[0].abs = 0; n.bc.set_op(op); n.src.resize(2); return fold_alu_op2(n); } } return false; } apply_alu_dst_mod(n.bc, dv); assign_source(n.dst[0], get_const(dv)); return true; } unsigned invert_setcc_condition(unsigned cc, bool &swap_args) { unsigned ncc = 0; switch (cc) { case AF_CC_E: ncc = AF_CC_NE; break; case AF_CC_NE: ncc = AF_CC_E; break; case AF_CC_GE: ncc = AF_CC_GT; swap_args = true; break; case AF_CC_GT: ncc = AF_CC_GE; swap_args = true; break; default: assert(!"unexpected condition code"); break; } return ncc; } unsigned get_setcc_op(unsigned cc, unsigned cmp_type, bool int_dst) { if (int_dst && cmp_type == AF_FLOAT_CMP) { switch (cc) { case AF_CC_E: return ALU_OP2_SETE_DX10; case AF_CC_NE: return ALU_OP2_SETNE_DX10; case AF_CC_GT: return ALU_OP2_SETGT_DX10; case AF_CC_GE: return ALU_OP2_SETGE_DX10; } } else { switch(cmp_type) { case AF_FLOAT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_SETE; case AF_CC_NE: return ALU_OP2_SETNE; case AF_CC_GT: return ALU_OP2_SETGT; case AF_CC_GE: return ALU_OP2_SETGE; } break; } case AF_INT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_SETE_INT; case AF_CC_NE: return ALU_OP2_SETNE_INT; case AF_CC_GT: return ALU_OP2_SETGT_INT; case AF_CC_GE: return ALU_OP2_SETGE_INT; } break; } case AF_UINT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_SETE_INT; case AF_CC_NE: return ALU_OP2_SETNE_INT; case AF_CC_GT: return ALU_OP2_SETGT_UINT; case AF_CC_GE: return ALU_OP2_SETGE_UINT; } break; } } } assert(!"unexpected cc&cmp_type combination"); return ~0u; } unsigned get_predsetcc_op(unsigned cc, unsigned cmp_type) { switch(cmp_type) { case AF_FLOAT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_PRED_SETE; case AF_CC_NE: return ALU_OP2_PRED_SETNE; case AF_CC_GT: return ALU_OP2_PRED_SETGT; case AF_CC_GE: return ALU_OP2_PRED_SETGE; } break; } case AF_INT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_PRED_SETE_INT; case AF_CC_NE: return ALU_OP2_PRED_SETNE_INT; case AF_CC_GT: return ALU_OP2_PRED_SETGT_INT; case AF_CC_GE: return ALU_OP2_PRED_SETGE_INT; } break; } case AF_UINT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_PRED_SETE_INT; case AF_CC_NE: return ALU_OP2_PRED_SETNE_INT; case AF_CC_GT: return ALU_OP2_PRED_SETGT_UINT; case AF_CC_GE: return ALU_OP2_PRED_SETGE_UINT; } break; } } assert(!"unexpected cc&cmp_type combination"); return ~0u; } unsigned get_killcc_op(unsigned cc, unsigned cmp_type) { switch(cmp_type) { case AF_FLOAT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_KILLE; case AF_CC_NE: return ALU_OP2_KILLNE; case AF_CC_GT: return ALU_OP2_KILLGT; case AF_CC_GE: return ALU_OP2_KILLGE; } break; } case AF_INT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_KILLE_INT; case AF_CC_NE: return ALU_OP2_KILLNE_INT; case AF_CC_GT: return ALU_OP2_KILLGT_INT; case AF_CC_GE: return ALU_OP2_KILLGE_INT; } break; } case AF_UINT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP2_KILLE_INT; case AF_CC_NE: return ALU_OP2_KILLNE_INT; case AF_CC_GT: return ALU_OP2_KILLGT_UINT; case AF_CC_GE: return ALU_OP2_KILLGE_UINT; } break; } } assert(!"unexpected cc&cmp_type combination"); return ~0u; } unsigned get_cndcc_op(unsigned cc, unsigned cmp_type) { switch(cmp_type) { case AF_FLOAT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP3_CNDE; case AF_CC_GT: return ALU_OP3_CNDGT; case AF_CC_GE: return ALU_OP3_CNDGE; } break; } case AF_INT_CMP: { switch (cc) { case AF_CC_E: return ALU_OP3_CNDE_INT; case AF_CC_GT: return ALU_OP3_CNDGT_INT; case AF_CC_GE: return ALU_OP3_CNDGE_INT; } break; } } assert(!"unexpected cc&cmp_type combination"); return ~0u; } void convert_predset_to_set(shader& sh, alu_node* a) { unsigned flags = a->bc.op_ptr->flags; unsigned cc = flags & AF_CC_MASK; unsigned cmp_type = flags & AF_CMP_TYPE_MASK; bool swap_args = false; cc = invert_setcc_condition(cc, swap_args); unsigned newop = get_setcc_op(cc, cmp_type, true); a->dst.resize(1); a->bc.set_op(newop); if (swap_args) { std::swap(a->src[0], a->src[1]); std::swap(a->bc.src[0], a->bc.src[1]); } a->bc.update_exec_mask = 0; a->bc.update_pred = 0; } } // namespace r600_sb