/* * Copyright © 2012 Intel Corporation * * 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 (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 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. */ /** @file brw_vec4_vp.cpp * * A translator from Mesa IR to the i965 driver's Vec4 IR, used to implement * ARB_vertex_program and fixed-function vertex processing. */ #include "brw_context.h" #include "brw_vec4.h" #include "brw_vs.h" extern "C" { #include "program/prog_parameter.h" #include "program/prog_print.h" } using namespace brw; void vec4_visitor::emit_vp_sop(enum brw_conditional_mod conditional_mod, dst_reg dst, src_reg src0, src_reg src1, src_reg one) { vec4_instruction *inst; inst = emit(BRW_OPCODE_CMP, dst_null_d(), src0, src1); inst->conditional_mod = conditional_mod; inst = emit(BRW_OPCODE_SEL, dst, one, src_reg(0.0f)); inst->predicate = BRW_PREDICATE_NORMAL; } void vec4_vs_visitor::emit_program_code() { this->need_all_constants_in_pull_buffer = false; setup_vp_regs(); /* Keep a reg with 1.0 around, for reuse by emit_vs_sop so that it can just * be: * * sel.f0 dst 1.0 0.0 * * instead of * * mov dst 0.0 * mov.f0 dst 1.0 */ src_reg one = src_reg(this, glsl_type::float_type); emit(MOV(dst_reg(one), src_reg(1.0f))); for (unsigned int insn = 0; insn < prog->NumInstructions; insn++) { const struct prog_instruction *vpi = &prog->Instructions[insn]; base_ir = vpi; dst_reg dst; src_reg src[3]; /* We always emit into a temporary destination register to avoid * aliasing issues. */ dst = dst_reg(this, glsl_type::vec4_type); for (int i = 0; i < 3; i++) src[i] = get_vp_src_reg(vpi->SrcReg[i]); switch (vpi->Opcode) { case OPCODE_ABS: src[0].abs = true; src[0].negate = false; emit(MOV(dst, src[0])); break; case OPCODE_ADD: emit(ADD(dst, src[0], src[1])); break; case OPCODE_ARL: if (brw->gen >= 6) { dst.writemask = WRITEMASK_X; dst_reg dst_f = dst; dst_f.type = BRW_REGISTER_TYPE_F; emit(RNDD(dst_f, src[0])); emit(MOV(dst, src_reg(dst_f))); } else { emit(RNDD(dst, src[0])); } break; case OPCODE_DP3: emit(DP3(dst, src[0], src[1])); break; case OPCODE_DP4: emit(DP4(dst, src[0], src[1])); break; case OPCODE_DPH: emit(DPH(dst, src[0], src[1])); break; case OPCODE_DST: { dst_reg t = dst; if (vpi->DstReg.WriteMask & WRITEMASK_X) { t.writemask = WRITEMASK_X; emit(MOV(t, src_reg(1.0f))); } if (vpi->DstReg.WriteMask & WRITEMASK_Y) { t.writemask = WRITEMASK_Y; emit(MUL(t, src[0], src[1])); } if (vpi->DstReg.WriteMask & WRITEMASK_Z) { t.writemask = WRITEMASK_Z; emit(MOV(t, src[0])); } if (vpi->DstReg.WriteMask & WRITEMASK_W) { t.writemask = WRITEMASK_W; emit(MOV(t, src[1])); } break; } case OPCODE_EXP: { dst_reg result = dst; if (vpi->DstReg.WriteMask & WRITEMASK_X) { /* tmp_d = floor(src[0].x) */ src_reg tmp_d = src_reg(this, glsl_type::ivec4_type); assert(tmp_d.type == BRW_REGISTER_TYPE_D); emit(RNDD(dst_reg(tmp_d), swizzle(src[0], BRW_SWIZZLE_XXXX))); /* result[0] = 2.0 ^ tmp */ /* Adjust exponent for floating point: exp += 127 */ dst_reg tmp_d_x(GRF, tmp_d.reg, glsl_type::int_type, WRITEMASK_X); emit(ADD(tmp_d_x, tmp_d, src_reg(127))); /* Install exponent and sign. Excess drops off the edge: */ dst_reg res_d_x(GRF, result.reg, glsl_type::int_type, WRITEMASK_X); emit(BRW_OPCODE_SHL, res_d_x, tmp_d, src_reg(23)); } if (vpi->DstReg.WriteMask & WRITEMASK_Y) { result.writemask = WRITEMASK_Y; emit(FRC(result, src[0])); } if (vpi->DstReg.WriteMask & WRITEMASK_Z) { result.writemask = WRITEMASK_Z; emit_math(SHADER_OPCODE_EXP2, result, src[0]); } if (vpi->DstReg.WriteMask & WRITEMASK_W) { result.writemask = WRITEMASK_W; emit(MOV(result, src_reg(1.0f))); } break; } case OPCODE_EX2: emit_math(SHADER_OPCODE_EXP2, dst, src[0]); break; case OPCODE_FLR: emit(RNDD(dst, src[0])); break; case OPCODE_FRC: emit(FRC(dst, src[0])); break; case OPCODE_LG2: emit_math(SHADER_OPCODE_LOG2, dst, src[0]); break; case OPCODE_LIT: { dst_reg result = dst; /* From the ARB_vertex_program spec: * * tmp = VectorLoad(op0); * if (tmp.x < 0) tmp.x = 0; * if (tmp.y < 0) tmp.y = 0; * if (tmp.w < -(128.0-epsilon)) tmp.w = -(128.0-epsilon); * else if (tmp.w > 128-epsilon) tmp.w = 128-epsilon; * result.x = 1.0; * result.y = tmp.x; * result.z = (tmp.x > 0) ? RoughApproxPower(tmp.y, tmp.w) : 0.0; * result.w = 1.0; * * Note that we don't do the clamping to +/- 128. We didn't in * brw_vs_emit.c either. */ if (vpi->DstReg.WriteMask & WRITEMASK_XW) { result.writemask = WRITEMASK_XW; emit(MOV(result, src_reg(1.0f))); } if (vpi->DstReg.WriteMask & WRITEMASK_YZ) { result.writemask = WRITEMASK_YZ; emit(MOV(result, src_reg(0.0f))); src_reg tmp_x = swizzle(src[0], BRW_SWIZZLE_XXXX); emit(CMP(dst_null_d(), tmp_x, src_reg(0.0f), BRW_CONDITIONAL_G)); emit(IF(BRW_PREDICATE_NORMAL)); if (vpi->DstReg.WriteMask & WRITEMASK_Y) { result.writemask = WRITEMASK_Y; emit(MOV(result, tmp_x)); } if (vpi->DstReg.WriteMask & WRITEMASK_Z) { /* if (tmp.y < 0) tmp.y = 0; */ src_reg tmp_y = swizzle(src[0], BRW_SWIZZLE_YYYY); result.writemask = WRITEMASK_Z; emit_minmax(BRW_CONDITIONAL_G, result, tmp_y, src_reg(0.0f)); src_reg clamped_y(result); clamped_y.swizzle = BRW_SWIZZLE_ZZZZ; src_reg tmp_w = swizzle(src[0], BRW_SWIZZLE_WWWW); emit_math(SHADER_OPCODE_POW, result, clamped_y, tmp_w); } emit(BRW_OPCODE_ENDIF); } break; } case OPCODE_LOG: { dst_reg result = dst; result.type = BRW_REGISTER_TYPE_UD; src_reg result_src = src_reg(result); src_reg arg0_ud = swizzle(src[0], BRW_SWIZZLE_XXXX); arg0_ud.type = BRW_REGISTER_TYPE_UD; /* Perform mant = frexpf(fabsf(x), &exp), adjust exp and mnt * according to spec: * * These almost look likey they could be joined up, but not really * practical: * * result[0].f = (x.i & ((1<<31)-1) >> 23) - 127 * result[1].i = (x.i & ((1<<23)-1) + (127<<23) */ if (vpi->DstReg.WriteMask & WRITEMASK_XZ) { result.writemask = WRITEMASK_X; emit(AND(result, arg0_ud, src_reg((1u << 31) - 1))); emit(BRW_OPCODE_SHR, result, result_src, src_reg(23u)); src_reg result_d(result_src); result_d.type = BRW_REGISTER_TYPE_D; /* does it matter? */ result.type = BRW_REGISTER_TYPE_F; emit(ADD(result, result_d, src_reg(-127))); } if (vpi->DstReg.WriteMask & WRITEMASK_YZ) { result.writemask = WRITEMASK_Y; result.type = BRW_REGISTER_TYPE_UD; emit(AND(result, arg0_ud, src_reg((1u << 23) - 1))); emit(OR(result, result_src, src_reg(127u << 23))); } if (vpi->DstReg.WriteMask & WRITEMASK_Z) { /* result[2] = result[0] + LOG2(result[1]); */ /* Why bother? The above is just a hint how to do this with a * taylor series. Maybe we *should* use a taylor series as by * the time all the above has been done it's almost certainly * quicker than calling the mathbox, even with low precision. * * Options are: * - result[0] + mathbox.LOG2(result[1]) * - mathbox.LOG2(arg0.x) * - result[0] + inline_taylor_approx(result[1]) */ result.type = BRW_REGISTER_TYPE_F; result.writemask = WRITEMASK_Z; src_reg result_x(result), result_y(result), result_z(result); result_x.swizzle = BRW_SWIZZLE_XXXX; result_y.swizzle = BRW_SWIZZLE_YYYY; result_z.swizzle = BRW_SWIZZLE_ZZZZ; emit_math(SHADER_OPCODE_LOG2, result, result_y); emit(ADD(result, result_z, result_x)); } if (vpi->DstReg.WriteMask & WRITEMASK_W) { result.type = BRW_REGISTER_TYPE_F; result.writemask = WRITEMASK_W; emit(MOV(result, src_reg(1.0f))); } break; } case OPCODE_MAD: { src_reg temp = src_reg(this, glsl_type::vec4_type); emit(MUL(dst_reg(temp), src[0], src[1])); emit(ADD(dst, temp, src[2])); break; } case OPCODE_MAX: emit_minmax(BRW_CONDITIONAL_G, dst, src[0], src[1]); break; case OPCODE_MIN: emit_minmax(BRW_CONDITIONAL_L, dst, src[0], src[1]); break; case OPCODE_MOV: emit(MOV(dst, src[0])); break; case OPCODE_MUL: emit(MUL(dst, src[0], src[1])); break; case OPCODE_POW: emit_math(SHADER_OPCODE_POW, dst, src[0], src[1]); break; case OPCODE_RCP: emit_math(SHADER_OPCODE_RCP, dst, src[0]); break; case OPCODE_RSQ: emit_math(SHADER_OPCODE_RSQ, dst, src[0]); break; case OPCODE_SGE: emit_vp_sop(BRW_CONDITIONAL_GE, dst, src[0], src[1], one); break; case OPCODE_SLT: emit_vp_sop(BRW_CONDITIONAL_L, dst, src[0], src[1], one); break; case OPCODE_SUB: { src_reg neg_src1 = src[1]; neg_src1.negate = !src[1].negate; emit(ADD(dst, src[0], neg_src1)); break; } case OPCODE_SWZ: /* Note that SWZ's extended swizzles are handled in the general * get_src_reg() code. */ emit(MOV(dst, src[0])); break; case OPCODE_XPD: { src_reg t1 = src_reg(this, glsl_type::vec4_type); src_reg t2 = src_reg(this, glsl_type::vec4_type); emit(MUL(dst_reg(t1), swizzle(src[0], BRW_SWIZZLE_YZXW), swizzle(src[1], BRW_SWIZZLE_ZXYW))); emit(MUL(dst_reg(t2), swizzle(src[0], BRW_SWIZZLE_ZXYW), swizzle(src[1], BRW_SWIZZLE_YZXW))); t2.negate = true; emit(ADD(dst, t1, t2)); break; } case OPCODE_END: break; default: _mesa_problem(ctx, "Unsupported opcode %s in vertex program\n", _mesa_opcode_string(vpi->Opcode)); } /* Copy the temporary back into the actual destination register. */ if (vpi->Opcode != OPCODE_END) { emit(MOV(get_vp_dst_reg(vpi->DstReg), src_reg(dst))); } } /* If we used relative addressing, we need to upload all constants as * pull constants. Do that now. */ if (this->need_all_constants_in_pull_buffer) { const struct gl_program_parameter_list *params = vs_compile->vp->program.Base.Parameters; unsigned i; for (i = 0; i < params->NumParameters * 4; i++) { stage_prog_data->pull_param[i] = ¶ms->ParameterValues[i / 4][i % 4].f; } stage_prog_data->nr_pull_params = i; } } void vec4_vs_visitor::setup_vp_regs() { /* PROGRAM_TEMPORARY */ int num_temp = prog->NumTemporaries; vp_temp_regs = rzalloc_array(mem_ctx, src_reg, num_temp); for (int i = 0; i < num_temp; i++) vp_temp_regs[i] = src_reg(this, glsl_type::vec4_type); /* PROGRAM_STATE_VAR etc. */ struct gl_program_parameter_list *plist = vs_compile->vp->program.Base.Parameters; for (unsigned p = 0; p < plist->NumParameters; p++) { unsigned components = plist->Parameters[p].Size; /* Parameters should be either vec4 uniforms or single component * constants; matrices and other larger types should have been broken * down earlier. */ assert(components <= 4); this->uniform_size[this->uniforms] = 1; /* 1 vec4 */ this->uniform_vector_size[this->uniforms] = components; for (unsigned i = 0; i < 4; i++) { stage_prog_data->param[this->uniforms * 4 + i] = i >= components ? 0 : &plist->ParameterValues[p][i].f; } this->uniforms++; /* counted in vec4 units */ } /* PROGRAM_OUTPUT */ for (int slot = 0; slot < prog_data->vue_map.num_slots; slot++) { int varying = prog_data->vue_map.slot_to_varying[slot]; if (varying == VARYING_SLOT_PSIZ) output_reg[varying] = dst_reg(this, glsl_type::float_type); else output_reg[varying] = dst_reg(this, glsl_type::vec4_type); assert(output_reg[varying].type == BRW_REGISTER_TYPE_F); } /* PROGRAM_ADDRESS */ this->vp_addr_reg = src_reg(this, glsl_type::int_type); assert(this->vp_addr_reg.type == BRW_REGISTER_TYPE_D); } dst_reg vec4_vs_visitor::get_vp_dst_reg(const prog_dst_register &dst) { dst_reg result; assert(!dst.RelAddr); switch (dst.File) { case PROGRAM_TEMPORARY: result = dst_reg(vp_temp_regs[dst.Index]); break; case PROGRAM_OUTPUT: result = output_reg[dst.Index]; break; case PROGRAM_ADDRESS: { assert(dst.Index == 0); result = dst_reg(this->vp_addr_reg); break; } case PROGRAM_UNDEFINED: return dst_null_f(); default: unreachable("vec4_vp: bad destination register file"); } result.writemask = dst.WriteMask; return result; } src_reg vec4_vs_visitor::get_vp_src_reg(const prog_src_register &src) { struct gl_program_parameter_list *plist = vs_compile->vp->program.Base.Parameters; src_reg result; assert(!src.Abs); switch (src.File) { case PROGRAM_UNDEFINED: return src_reg(brw_null_reg()); case PROGRAM_TEMPORARY: result = vp_temp_regs[src.Index]; break; case PROGRAM_INPUT: result = src_reg(ATTR, src.Index, glsl_type::vec4_type); result.type = BRW_REGISTER_TYPE_F; break; case PROGRAM_ADDRESS: { assert(src.Index == 0); result = this->vp_addr_reg; break; } case PROGRAM_STATE_VAR: case PROGRAM_CONSTANT: /* From the ARB_vertex_program specification: * "Relative addressing can only be used for accessing program * parameter arrays." */ if (src.RelAddr) { /* Since we have no idea what the base of the array is, we need to * upload ALL constants as push constants. */ this->need_all_constants_in_pull_buffer = true; /* Add the small constant index to the address register */ src_reg reladdr = src_reg(this, glsl_type::int_type); dst_reg dst_reladdr = dst_reg(reladdr); dst_reladdr.writemask = WRITEMASK_X; emit(ADD(dst_reladdr, this->vp_addr_reg, src_reg(src.Index))); if (brw->gen < 6) emit(MUL(dst_reladdr, reladdr, src_reg(16))); #if 0 assert(src.Index < this->uniforms); result = src_reg(dst_reg(UNIFORM, 0)); result.type = BRW_REGISTER_TYPE_F; result.reladdr = new(mem_ctx) src_reg(); memcpy(result.reladdr, &reladdr, sizeof(src_reg)); #endif result = src_reg(this, glsl_type::vec4_type); src_reg surf_index = src_reg(unsigned(prog_data->base.binding_table.pull_constants_start)); vec4_instruction *load; if (brw->gen >= 7) { load = new(mem_ctx) vec4_instruction(this, VS_OPCODE_PULL_CONSTANT_LOAD_GEN7, dst_reg(result), surf_index, reladdr); } else { load = new(mem_ctx) vec4_instruction(this, VS_OPCODE_PULL_CONSTANT_LOAD, dst_reg(result), surf_index, reladdr); load->base_mrf = 14; load->mlen = 1; } emit(load); break; } /* We actually want to look at the type in the Parameters list for this, * because this lets us upload constant builtin uniforms as actual * constants. */ switch (plist->Parameters[src.Index].Type) { case PROGRAM_CONSTANT: result = src_reg(this, glsl_type::vec4_type); for (int i = 0; i < 4; i++) { dst_reg t = dst_reg(result); t.writemask = 1 << i; emit(MOV(t, src_reg(plist->ParameterValues[src.Index][i].f))); } break; case PROGRAM_STATE_VAR: assert(src.Index < this->uniforms); result = src_reg(dst_reg(UNIFORM, src.Index)); result.type = BRW_REGISTER_TYPE_F; break; default: _mesa_problem(ctx, "bad uniform src register file: %s\n", _mesa_register_file_name((gl_register_file)src.File)); return src_reg(this, glsl_type::vec4_type); } break; default: _mesa_problem(ctx, "bad src register file: %s\n", _mesa_register_file_name((gl_register_file)src.File)); return src_reg(this, glsl_type::vec4_type); } if (src.Swizzle != SWIZZLE_NOOP || src.Negate) { unsigned short zeros_mask = 0; unsigned short ones_mask = 0; unsigned short src_mask = 0; unsigned short src_swiz[4]; for (int i = 0; i < 4; i++) { src_swiz[i] = 0; /* initialize for safety */ /* The ZERO, ONE, and Negate options are only used for OPCODE_SWZ, * but it's simplest to handle it here. */ int s = GET_SWZ(src.Swizzle, i); switch (s) { case SWIZZLE_X: case SWIZZLE_Y: case SWIZZLE_Z: case SWIZZLE_W: src_mask |= 1 << i; src_swiz[i] = s; break; case SWIZZLE_ZERO: zeros_mask |= 1 << i; break; case SWIZZLE_ONE: ones_mask |= 1 << i; break; } } result.swizzle = BRW_SWIZZLE4(src_swiz[0], src_swiz[1], src_swiz[2], src_swiz[3]); /* The hardware doesn't natively handle the SWZ instruction's zero/one * swizzles or per-component negation, so we need to use a temporary. */ if (zeros_mask || ones_mask || src.Negate) { src_reg temp_src(this, glsl_type::vec4_type); dst_reg temp(temp_src); if (src_mask) { temp.writemask = src_mask; emit(MOV(temp, result)); } if (zeros_mask) { temp.writemask = zeros_mask; emit(MOV(temp, src_reg(0.0f))); } if (ones_mask) { temp.writemask = ones_mask; emit(MOV(temp, src_reg(1.0f))); } if (src.Negate) { temp.writemask = src.Negate; src_reg neg(temp_src); neg.negate = true; emit(MOV(temp, neg)); } result = temp_src; } } return result; }