/* * Copyright © 2016 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. */ #include #include "vtn_private.h" /* * Normally, column vectors in SPIR-V correspond to a single NIR SSA * definition. But for matrix multiplies, we want to do one routine for * multiplying a matrix by a matrix and then pretend that vectors are matrices * with one column. So we "wrap" these things, and unwrap the result before we * send it off. */ static struct vtn_ssa_value * wrap_matrix(struct vtn_builder *b, struct vtn_ssa_value *val) { if (val == NULL) return NULL; if (glsl_type_is_matrix(val->type)) return val; struct vtn_ssa_value *dest = rzalloc(b, struct vtn_ssa_value); dest->type = val->type; dest->elems = ralloc_array(b, struct vtn_ssa_value *, 1); dest->elems[0] = val; return dest; } static struct vtn_ssa_value * unwrap_matrix(struct vtn_ssa_value *val) { if (glsl_type_is_matrix(val->type)) return val; return val->elems[0]; } static struct vtn_ssa_value * matrix_multiply(struct vtn_builder *b, struct vtn_ssa_value *_src0, struct vtn_ssa_value *_src1) { struct vtn_ssa_value *src0 = wrap_matrix(b, _src0); struct vtn_ssa_value *src1 = wrap_matrix(b, _src1); struct vtn_ssa_value *src0_transpose = wrap_matrix(b, _src0->transposed); struct vtn_ssa_value *src1_transpose = wrap_matrix(b, _src1->transposed); unsigned src0_rows = glsl_get_vector_elements(src0->type); unsigned src0_columns = glsl_get_matrix_columns(src0->type); unsigned src1_columns = glsl_get_matrix_columns(src1->type); const struct glsl_type *dest_type; if (src1_columns > 1) { dest_type = glsl_matrix_type(glsl_get_base_type(src0->type), src0_rows, src1_columns); } else { dest_type = glsl_vector_type(glsl_get_base_type(src0->type), src0_rows); } struct vtn_ssa_value *dest = vtn_create_ssa_value(b, dest_type); dest = wrap_matrix(b, dest); bool transpose_result = false; if (src0_transpose && src1_transpose) { /* transpose(A) * transpose(B) = transpose(B * A) */ src1 = src0_transpose; src0 = src1_transpose; src0_transpose = NULL; src1_transpose = NULL; transpose_result = true; } if (src0_transpose && !src1_transpose && glsl_get_base_type(src0->type) == GLSL_TYPE_FLOAT) { /* We already have the rows of src0 and the columns of src1 available, * so we can just take the dot product of each row with each column to * get the result. */ for (unsigned i = 0; i < src1_columns; i++) { nir_ssa_def *vec_src[4]; for (unsigned j = 0; j < src0_rows; j++) { vec_src[j] = nir_fdot(&b->nb, src0_transpose->elems[j]->def, src1->elems[i]->def); } dest->elems[i]->def = nir_vec(&b->nb, vec_src, src0_rows); } } else { /* We don't handle the case where src1 is transposed but not src0, since * the general case only uses individual components of src1 so the * optimizer should chew through the transpose we emitted for src1. */ for (unsigned i = 0; i < src1_columns; i++) { /* dest[i] = sum(src0[j] * src1[i][j] for all j) */ dest->elems[i]->def = nir_fmul(&b->nb, src0->elems[0]->def, nir_channel(&b->nb, src1->elems[i]->def, 0)); for (unsigned j = 1; j < src0_columns; j++) { dest->elems[i]->def = nir_fadd(&b->nb, dest->elems[i]->def, nir_fmul(&b->nb, src0->elems[j]->def, nir_channel(&b->nb, src1->elems[i]->def, j))); } } } dest = unwrap_matrix(dest); if (transpose_result) dest = vtn_ssa_transpose(b, dest); return dest; } static struct vtn_ssa_value * mat_times_scalar(struct vtn_builder *b, struct vtn_ssa_value *mat, nir_ssa_def *scalar) { struct vtn_ssa_value *dest = vtn_create_ssa_value(b, mat->type); for (unsigned i = 0; i < glsl_get_matrix_columns(mat->type); i++) { if (glsl_base_type_is_integer(glsl_get_base_type(mat->type))) dest->elems[i]->def = nir_imul(&b->nb, mat->elems[i]->def, scalar); else dest->elems[i]->def = nir_fmul(&b->nb, mat->elems[i]->def, scalar); } return dest; } static void vtn_handle_matrix_alu(struct vtn_builder *b, SpvOp opcode, struct vtn_value *dest, struct vtn_ssa_value *src0, struct vtn_ssa_value *src1) { switch (opcode) { case SpvOpFNegate: { dest->ssa = vtn_create_ssa_value(b, src0->type); unsigned cols = glsl_get_matrix_columns(src0->type); for (unsigned i = 0; i < cols; i++) dest->ssa->elems[i]->def = nir_fneg(&b->nb, src0->elems[i]->def); break; } case SpvOpFAdd: { dest->ssa = vtn_create_ssa_value(b, src0->type); unsigned cols = glsl_get_matrix_columns(src0->type); for (unsigned i = 0; i < cols; i++) dest->ssa->elems[i]->def = nir_fadd(&b->nb, src0->elems[i]->def, src1->elems[i]->def); break; } case SpvOpFSub: { dest->ssa = vtn_create_ssa_value(b, src0->type); unsigned cols = glsl_get_matrix_columns(src0->type); for (unsigned i = 0; i < cols; i++) dest->ssa->elems[i]->def = nir_fsub(&b->nb, src0->elems[i]->def, src1->elems[i]->def); break; } case SpvOpTranspose: dest->ssa = vtn_ssa_transpose(b, src0); break; case SpvOpMatrixTimesScalar: if (src0->transposed) { dest->ssa = vtn_ssa_transpose(b, mat_times_scalar(b, src0->transposed, src1->def)); } else { dest->ssa = mat_times_scalar(b, src0, src1->def); } break; case SpvOpVectorTimesMatrix: case SpvOpMatrixTimesVector: case SpvOpMatrixTimesMatrix: if (opcode == SpvOpVectorTimesMatrix) { dest->ssa = matrix_multiply(b, vtn_ssa_transpose(b, src1), src0); } else { dest->ssa = matrix_multiply(b, src0, src1); } break; default: vtn_fail("unknown matrix opcode"); } } static void vtn_handle_bitcast(struct vtn_builder *b, struct vtn_ssa_value *dest, struct nir_ssa_def *src) { if (glsl_get_vector_elements(dest->type) == src->num_components) { /* From the definition of OpBitcast in the SPIR-V 1.2 spec: * * "If Result Type has the same number of components as Operand, they * must also have the same component width, and results are computed per * component." */ dest->def = nir_imov(&b->nb, src); return; } /* From the definition of OpBitcast in the SPIR-V 1.2 spec: * * "If Result Type has a different number of components than Operand, the * total number of bits in Result Type must equal the total number of bits * in Operand. Let L be the type, either Result Type or Operand’s type, that * has the larger number of components. Let S be the other type, with the * smaller number of components. The number of components in L must be an * integer multiple of the number of components in S. The first component * (that is, the only or lowest-numbered component) of S maps to the first * components of L, and so on, up to the last component of S mapping to the * last components of L. Within this mapping, any single component of S * (mapping to multiple components of L) maps its lower-ordered bits to the * lower-numbered components of L." */ unsigned src_bit_size = src->bit_size; unsigned dest_bit_size = glsl_get_bit_size(dest->type); unsigned src_components = src->num_components; unsigned dest_components = glsl_get_vector_elements(dest->type); vtn_assert(src_bit_size * src_components == dest_bit_size * dest_components); nir_ssa_def *dest_chan[NIR_MAX_VEC_COMPONENTS]; if (src_bit_size > dest_bit_size) { vtn_assert(src_bit_size % dest_bit_size == 0); unsigned divisor = src_bit_size / dest_bit_size; for (unsigned comp = 0; comp < src_components; comp++) { nir_ssa_def *split; if (src_bit_size == 64) { assert(dest_bit_size == 32 || dest_bit_size == 16); split = dest_bit_size == 32 ? nir_unpack_64_2x32(&b->nb, nir_channel(&b->nb, src, comp)) : nir_unpack_64_4x16(&b->nb, nir_channel(&b->nb, src, comp)); } else { vtn_assert(src_bit_size == 32); vtn_assert(dest_bit_size == 16); split = nir_unpack_32_2x16(&b->nb, nir_channel(&b->nb, src, comp)); } for (unsigned i = 0; i < divisor; i++) dest_chan[divisor * comp + i] = nir_channel(&b->nb, split, i); } } else { vtn_assert(dest_bit_size % src_bit_size == 0); unsigned divisor = dest_bit_size / src_bit_size; for (unsigned comp = 0; comp < dest_components; comp++) { unsigned channels = ((1 << divisor) - 1) << (comp * divisor); nir_ssa_def *src_chan = nir_channels(&b->nb, src, channels); if (dest_bit_size == 64) { assert(src_bit_size == 32 || src_bit_size == 16); dest_chan[comp] = src_bit_size == 32 ? nir_pack_64_2x32(&b->nb, src_chan) : nir_pack_64_4x16(&b->nb, src_chan); } else { vtn_assert(dest_bit_size == 32); vtn_assert(src_bit_size == 16); dest_chan[comp] = nir_pack_32_2x16(&b->nb, src_chan); } } } dest->def = nir_vec(&b->nb, dest_chan, dest_components); } nir_op vtn_nir_alu_op_for_spirv_opcode(struct vtn_builder *b, SpvOp opcode, bool *swap, unsigned src_bit_size, unsigned dst_bit_size) { /* Indicates that the first two arguments should be swapped. This is * used for implementing greater-than and less-than-or-equal. */ *swap = false; switch (opcode) { case SpvOpSNegate: return nir_op_ineg; case SpvOpFNegate: return nir_op_fneg; case SpvOpNot: return nir_op_inot; case SpvOpIAdd: return nir_op_iadd; case SpvOpFAdd: return nir_op_fadd; case SpvOpISub: return nir_op_isub; case SpvOpFSub: return nir_op_fsub; case SpvOpIMul: return nir_op_imul; case SpvOpFMul: return nir_op_fmul; case SpvOpUDiv: return nir_op_udiv; case SpvOpSDiv: return nir_op_idiv; case SpvOpFDiv: return nir_op_fdiv; case SpvOpUMod: return nir_op_umod; case SpvOpSMod: return nir_op_imod; case SpvOpFMod: return nir_op_fmod; case SpvOpSRem: return nir_op_irem; case SpvOpFRem: return nir_op_frem; case SpvOpShiftRightLogical: return nir_op_ushr; case SpvOpShiftRightArithmetic: return nir_op_ishr; case SpvOpShiftLeftLogical: return nir_op_ishl; case SpvOpLogicalOr: return nir_op_ior; case SpvOpLogicalEqual: return nir_op_ieq; case SpvOpLogicalNotEqual: return nir_op_ine; case SpvOpLogicalAnd: return nir_op_iand; case SpvOpLogicalNot: return nir_op_inot; case SpvOpBitwiseOr: return nir_op_ior; case SpvOpBitwiseXor: return nir_op_ixor; case SpvOpBitwiseAnd: return nir_op_iand; case SpvOpSelect: return nir_op_bcsel; case SpvOpIEqual: return nir_op_ieq; case SpvOpBitFieldInsert: return nir_op_bitfield_insert; case SpvOpBitFieldSExtract: return nir_op_ibitfield_extract; case SpvOpBitFieldUExtract: return nir_op_ubitfield_extract; case SpvOpBitReverse: return nir_op_bitfield_reverse; case SpvOpBitCount: return nir_op_bit_count; /* The ordered / unordered operators need special implementation besides * the logical operator to use since they also need to check if operands are * ordered. */ case SpvOpFOrdEqual: return nir_op_feq; case SpvOpFUnordEqual: return nir_op_feq; case SpvOpINotEqual: return nir_op_ine; case SpvOpFOrdNotEqual: return nir_op_fne; case SpvOpFUnordNotEqual: return nir_op_fne; case SpvOpULessThan: return nir_op_ult; case SpvOpSLessThan: return nir_op_ilt; case SpvOpFOrdLessThan: return nir_op_flt; case SpvOpFUnordLessThan: return nir_op_flt; case SpvOpUGreaterThan: *swap = true; return nir_op_ult; case SpvOpSGreaterThan: *swap = true; return nir_op_ilt; case SpvOpFOrdGreaterThan: *swap = true; return nir_op_flt; case SpvOpFUnordGreaterThan: *swap = true; return nir_op_flt; case SpvOpULessThanEqual: *swap = true; return nir_op_uge; case SpvOpSLessThanEqual: *swap = true; return nir_op_ige; case SpvOpFOrdLessThanEqual: *swap = true; return nir_op_fge; case SpvOpFUnordLessThanEqual: *swap = true; return nir_op_fge; case SpvOpUGreaterThanEqual: return nir_op_uge; case SpvOpSGreaterThanEqual: return nir_op_ige; case SpvOpFOrdGreaterThanEqual: return nir_op_fge; case SpvOpFUnordGreaterThanEqual: return nir_op_fge; /* Conversions: */ case SpvOpQuantizeToF16: return nir_op_fquantize2f16; case SpvOpUConvert: case SpvOpConvertFToU: case SpvOpConvertFToS: case SpvOpConvertSToF: case SpvOpConvertUToF: case SpvOpSConvert: case SpvOpFConvert: { nir_alu_type src_type; nir_alu_type dst_type; switch (opcode) { case SpvOpConvertFToS: src_type = nir_type_float; dst_type = nir_type_int; break; case SpvOpConvertFToU: src_type = nir_type_float; dst_type = nir_type_uint; break; case SpvOpFConvert: src_type = dst_type = nir_type_float; break; case SpvOpConvertSToF: src_type = nir_type_int; dst_type = nir_type_float; break; case SpvOpSConvert: src_type = dst_type = nir_type_int; break; case SpvOpConvertUToF: src_type = nir_type_uint; dst_type = nir_type_float; break; case SpvOpUConvert: src_type = dst_type = nir_type_uint; break; default: unreachable("Invalid opcode"); } src_type |= src_bit_size; dst_type |= dst_bit_size; return nir_type_conversion_op(src_type, dst_type, nir_rounding_mode_undef); } /* Derivatives: */ case SpvOpDPdx: return nir_op_fddx; case SpvOpDPdy: return nir_op_fddy; case SpvOpDPdxFine: return nir_op_fddx_fine; case SpvOpDPdyFine: return nir_op_fddy_fine; case SpvOpDPdxCoarse: return nir_op_fddx_coarse; case SpvOpDPdyCoarse: return nir_op_fddy_coarse; default: vtn_fail("No NIR equivalent: %u", opcode); } } static void handle_no_contraction(struct vtn_builder *b, struct vtn_value *val, int member, const struct vtn_decoration *dec, void *_void) { vtn_assert(dec->scope == VTN_DEC_DECORATION); if (dec->decoration != SpvDecorationNoContraction) return; b->nb.exact = true; } static void handle_rounding_mode(struct vtn_builder *b, struct vtn_value *val, int member, const struct vtn_decoration *dec, void *_out_rounding_mode) { nir_rounding_mode *out_rounding_mode = _out_rounding_mode; assert(dec->scope == VTN_DEC_DECORATION); if (dec->decoration != SpvDecorationFPRoundingMode) return; switch (dec->literals[0]) { case SpvFPRoundingModeRTE: *out_rounding_mode = nir_rounding_mode_rtne; break; case SpvFPRoundingModeRTZ: *out_rounding_mode = nir_rounding_mode_rtz; break; default: unreachable("Not supported rounding mode"); break; } } void vtn_handle_alu(struct vtn_builder *b, SpvOp opcode, const uint32_t *w, unsigned count) { struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa); const struct glsl_type *type = vtn_value(b, w[1], vtn_value_type_type)->type->type; vtn_foreach_decoration(b, val, handle_no_contraction, NULL); /* Collect the various SSA sources */ const unsigned num_inputs = count - 3; struct vtn_ssa_value *vtn_src[4] = { NULL, }; for (unsigned i = 0; i < num_inputs; i++) vtn_src[i] = vtn_ssa_value(b, w[i + 3]); if (glsl_type_is_matrix(vtn_src[0]->type) || (num_inputs >= 2 && glsl_type_is_matrix(vtn_src[1]->type))) { vtn_handle_matrix_alu(b, opcode, val, vtn_src[0], vtn_src[1]); b->nb.exact = false; return; } val->ssa = vtn_create_ssa_value(b, type); nir_ssa_def *src[4] = { NULL, }; for (unsigned i = 0; i < num_inputs; i++) { vtn_assert(glsl_type_is_vector_or_scalar(vtn_src[i]->type)); src[i] = vtn_src[i]->def; } switch (opcode) { case SpvOpAny: if (src[0]->num_components == 1) { val->ssa->def = nir_imov(&b->nb, src[0]); } else { nir_op op; switch (src[0]->num_components) { case 2: op = nir_op_bany_inequal2; break; case 3: op = nir_op_bany_inequal3; break; case 4: op = nir_op_bany_inequal4; break; default: vtn_fail("invalid number of components"); } val->ssa->def = nir_build_alu(&b->nb, op, src[0], nir_imm_int(&b->nb, NIR_FALSE), NULL, NULL); } break; case SpvOpAll: if (src[0]->num_components == 1) { val->ssa->def = nir_imov(&b->nb, src[0]); } else { nir_op op; switch (src[0]->num_components) { case 2: op = nir_op_ball_iequal2; break; case 3: op = nir_op_ball_iequal3; break; case 4: op = nir_op_ball_iequal4; break; default: vtn_fail("invalid number of components"); } val->ssa->def = nir_build_alu(&b->nb, op, src[0], nir_imm_int(&b->nb, NIR_TRUE), NULL, NULL); } break; case SpvOpOuterProduct: { for (unsigned i = 0; i < src[1]->num_components; i++) { val->ssa->elems[i]->def = nir_fmul(&b->nb, src[0], nir_channel(&b->nb, src[1], i)); } break; } case SpvOpDot: val->ssa->def = nir_fdot(&b->nb, src[0], src[1]); break; case SpvOpIAddCarry: vtn_assert(glsl_type_is_struct(val->ssa->type)); val->ssa->elems[0]->def = nir_iadd(&b->nb, src[0], src[1]); val->ssa->elems[1]->def = nir_uadd_carry(&b->nb, src[0], src[1]); break; case SpvOpISubBorrow: vtn_assert(glsl_type_is_struct(val->ssa->type)); val->ssa->elems[0]->def = nir_isub(&b->nb, src[0], src[1]); val->ssa->elems[1]->def = nir_usub_borrow(&b->nb, src[0], src[1]); break; case SpvOpUMulExtended: vtn_assert(glsl_type_is_struct(val->ssa->type)); val->ssa->elems[0]->def = nir_imul(&b->nb, src[0], src[1]); val->ssa->elems[1]->def = nir_umul_high(&b->nb, src[0], src[1]); break; case SpvOpSMulExtended: vtn_assert(glsl_type_is_struct(val->ssa->type)); val->ssa->elems[0]->def = nir_imul(&b->nb, src[0], src[1]); val->ssa->elems[1]->def = nir_imul_high(&b->nb, src[0], src[1]); break; case SpvOpFwidth: val->ssa->def = nir_fadd(&b->nb, nir_fabs(&b->nb, nir_fddx(&b->nb, src[0])), nir_fabs(&b->nb, nir_fddy(&b->nb, src[0]))); break; case SpvOpFwidthFine: val->ssa->def = nir_fadd(&b->nb, nir_fabs(&b->nb, nir_fddx_fine(&b->nb, src[0])), nir_fabs(&b->nb, nir_fddy_fine(&b->nb, src[0]))); break; case SpvOpFwidthCoarse: val->ssa->def = nir_fadd(&b->nb, nir_fabs(&b->nb, nir_fddx_coarse(&b->nb, src[0])), nir_fabs(&b->nb, nir_fddy_coarse(&b->nb, src[0]))); break; case SpvOpVectorTimesScalar: /* The builder will take care of splatting for us. */ val->ssa->def = nir_fmul(&b->nb, src[0], src[1]); break; case SpvOpIsNan: val->ssa->def = nir_fne(&b->nb, src[0], src[0]); break; case SpvOpIsInf: { nir_ssa_def *inf = nir_imm_floatN_t(&b->nb, INFINITY, src[0]->bit_size); val->ssa->def = nir_ieq(&b->nb, nir_fabs(&b->nb, src[0]), inf); break; } case SpvOpFUnordEqual: case SpvOpFUnordNotEqual: case SpvOpFUnordLessThan: case SpvOpFUnordGreaterThan: case SpvOpFUnordLessThanEqual: case SpvOpFUnordGreaterThanEqual: { bool swap; unsigned src_bit_size = glsl_get_bit_size(vtn_src[0]->type); unsigned dst_bit_size = glsl_get_bit_size(type); nir_op op = vtn_nir_alu_op_for_spirv_opcode(b, opcode, &swap, src_bit_size, dst_bit_size); if (swap) { nir_ssa_def *tmp = src[0]; src[0] = src[1]; src[1] = tmp; } val->ssa->def = nir_ior(&b->nb, nir_build_alu(&b->nb, op, src[0], src[1], NULL, NULL), nir_ior(&b->nb, nir_fne(&b->nb, src[0], src[0]), nir_fne(&b->nb, src[1], src[1]))); break; } case SpvOpFOrdNotEqual: { /* For all the SpvOpFOrd* comparisons apart from NotEqual, the value * from the ALU will probably already be false if the operands are not * ordered so we don’t need to handle it specially. */ bool swap; unsigned src_bit_size = glsl_get_bit_size(vtn_src[0]->type); unsigned dst_bit_size = glsl_get_bit_size(type); nir_op op = vtn_nir_alu_op_for_spirv_opcode(b, opcode, &swap, src_bit_size, dst_bit_size); assert(!swap); val->ssa->def = nir_iand(&b->nb, nir_build_alu(&b->nb, op, src[0], src[1], NULL, NULL), nir_iand(&b->nb, nir_feq(&b->nb, src[0], src[0]), nir_feq(&b->nb, src[1], src[1]))); break; } case SpvOpBitcast: vtn_handle_bitcast(b, val->ssa, src[0]); break; case SpvOpFConvert: { nir_alu_type src_alu_type = nir_get_nir_type_for_glsl_type(vtn_src[0]->type); nir_alu_type dst_alu_type = nir_get_nir_type_for_glsl_type(type); nir_rounding_mode rounding_mode = nir_rounding_mode_undef; vtn_foreach_decoration(b, val, handle_rounding_mode, &rounding_mode); nir_op op = nir_type_conversion_op(src_alu_type, dst_alu_type, rounding_mode); val->ssa->def = nir_build_alu(&b->nb, op, src[0], src[1], NULL, NULL); break; } case SpvOpBitFieldInsert: case SpvOpBitFieldSExtract: case SpvOpBitFieldUExtract: case SpvOpShiftLeftLogical: case SpvOpShiftRightArithmetic: case SpvOpShiftRightLogical: { bool swap; unsigned src0_bit_size = glsl_get_bit_size(vtn_src[0]->type); unsigned dst_bit_size = glsl_get_bit_size(type); nir_op op = vtn_nir_alu_op_for_spirv_opcode(b, opcode, &swap, src0_bit_size, dst_bit_size); assert (op == nir_op_ushr || op == nir_op_ishr || op == nir_op_ishl || op == nir_op_bitfield_insert || op == nir_op_ubitfield_extract || op == nir_op_ibitfield_extract); for (unsigned i = 0; i < nir_op_infos[op].num_inputs; i++) { unsigned src_bit_size = nir_alu_type_get_type_size(nir_op_infos[op].input_types[i]); if (src_bit_size == 0) continue; if (src_bit_size != src[i]->bit_size) { assert(src_bit_size == 32); /* Convert the Shift, Offset and Count operands to 32 bits, which is the bitsize * supported by the NIR instructions. See discussion here: * * https://lists.freedesktop.org/archives/mesa-dev/2018-April/193026.html */ src[i] = nir_u2u32(&b->nb, src[i]); } } val->ssa->def = nir_build_alu(&b->nb, op, src[0], src[1], src[2], src[3]); break; } default: { bool swap; unsigned src_bit_size = glsl_get_bit_size(vtn_src[0]->type); unsigned dst_bit_size = glsl_get_bit_size(type); nir_op op = vtn_nir_alu_op_for_spirv_opcode(b, opcode, &swap, src_bit_size, dst_bit_size); if (swap) { nir_ssa_def *tmp = src[0]; src[0] = src[1]; src[1] = tmp; } val->ssa->def = nir_build_alu(&b->nb, op, src[0], src[1], src[2], src[3]); break; } /* default */ } b->nb.exact = false; }