nir_fneg(b, arc), arc);
}
-static nir_ssa_def *
-build_frexp16(nir_builder *b, nir_ssa_def *x, nir_ssa_def **exponent)
-{
- assert(x->bit_size == 16);
-
- nir_ssa_def *abs_x = nir_fabs(b, x);
- nir_ssa_def *zero = nir_imm_floatN_t(b, 0, 16);
-
- /* Half-precision floating-point values are stored as
- * 1 sign bit;
- * 5 exponent bits;
- * 10 mantissa bits.
- *
- * An exponent shift of 10 will shift the mantissa out, leaving only the
- * exponent and sign bit (which itself may be zero, if the absolute value
- * was taken before the bitcast and shift).
- */
- nir_ssa_def *exponent_shift = nir_imm_int(b, 10);
- nir_ssa_def *exponent_bias = nir_imm_intN_t(b, -14, 16);
-
- nir_ssa_def *sign_mantissa_mask = nir_imm_intN_t(b, 0x83ffu, 16);
-
- /* Exponent of floating-point values in the range [0.5, 1.0). */
- nir_ssa_def *exponent_value = nir_imm_intN_t(b, 0x3800u, 16);
-
- nir_ssa_def *is_not_zero = nir_fne(b, abs_x, zero);
-
- /* Significand return must be of the same type as the input, but the
- * exponent must be a 32-bit integer.
- */
- *exponent =
- nir_i2i32(b,
- nir_iadd(b, nir_ushr(b, abs_x, exponent_shift),
- nir_bcsel(b, is_not_zero, exponent_bias, zero)));
-
- return nir_ior(b, nir_iand(b, x, sign_mantissa_mask),
- nir_bcsel(b, is_not_zero, exponent_value, zero));
-}
-
-static nir_ssa_def *
-build_frexp32(nir_builder *b, nir_ssa_def *x, nir_ssa_def **exponent)
-{
- nir_ssa_def *abs_x = nir_fabs(b, x);
- nir_ssa_def *zero = nir_imm_float(b, 0.0f);
-
- /* Single-precision floating-point values are stored as
- * 1 sign bit;
- * 8 exponent bits;
- * 23 mantissa bits.
- *
- * An exponent shift of 23 will shift the mantissa out, leaving only the
- * exponent and sign bit (which itself may be zero, if the absolute value
- * was taken before the bitcast and shift.
- */
- nir_ssa_def *exponent_shift = nir_imm_int(b, 23);
- nir_ssa_def *exponent_bias = nir_imm_int(b, -126);
-
- nir_ssa_def *sign_mantissa_mask = nir_imm_int(b, 0x807fffffu);
-
- /* Exponent of floating-point values in the range [0.5, 1.0). */
- nir_ssa_def *exponent_value = nir_imm_int(b, 0x3f000000u);
-
- nir_ssa_def *is_not_zero = nir_fne(b, abs_x, zero);
-
- *exponent =
- nir_iadd(b, nir_ushr(b, abs_x, exponent_shift),
- nir_bcsel(b, is_not_zero, exponent_bias, zero));
-
- return nir_ior(b, nir_iand(b, x, sign_mantissa_mask),
- nir_bcsel(b, is_not_zero, exponent_value, zero));
-}
-
-static nir_ssa_def *
-build_frexp64(nir_builder *b, nir_ssa_def *x, nir_ssa_def **exponent)
-{
- nir_ssa_def *abs_x = nir_fabs(b, x);
- nir_ssa_def *zero = nir_imm_double(b, 0.0);
- nir_ssa_def *zero32 = nir_imm_float(b, 0.0f);
-
- /* Double-precision floating-point values are stored as
- * 1 sign bit;
- * 11 exponent bits;
- * 52 mantissa bits.
- *
- * We only need to deal with the exponent so first we extract the upper 32
- * bits using nir_unpack_64_2x32_split_y.
- */
- nir_ssa_def *upper_x = nir_unpack_64_2x32_split_y(b, x);
- nir_ssa_def *abs_upper_x = nir_unpack_64_2x32_split_y(b, abs_x);
-
- /* An exponent shift of 20 will shift the remaining mantissa bits out,
- * leaving only the exponent and sign bit (which itself may be zero, if the
- * absolute value was taken before the bitcast and shift.
- */
- nir_ssa_def *exponent_shift = nir_imm_int(b, 20);
- nir_ssa_def *exponent_bias = nir_imm_int(b, -1022);
-
- nir_ssa_def *sign_mantissa_mask = nir_imm_int(b, 0x800fffffu);
-
- /* Exponent of floating-point values in the range [0.5, 1.0). */
- nir_ssa_def *exponent_value = nir_imm_int(b, 0x3fe00000u);
-
- nir_ssa_def *is_not_zero = nir_fne(b, abs_x, zero);
-
- *exponent =
- nir_iadd(b, nir_ushr(b, abs_upper_x, exponent_shift),
- nir_bcsel(b, is_not_zero, exponent_bias, zero32));
-
- nir_ssa_def *new_upper =
- nir_ior(b, nir_iand(b, upper_x, sign_mantissa_mask),
- nir_bcsel(b, is_not_zero, exponent_value, zero32));
-
- nir_ssa_def *lower_x = nir_unpack_64_2x32_split_x(b, x);
-
- return nir_pack_64_2x32_split(b, lower_x, new_upper);
-}
-
static nir_op
vtn_nir_alu_op_for_spirv_glsl_opcode(struct vtn_builder *b,
enum GLSLstd450 opcode)
return;
case GLSLstd450Frexp: {
- nir_ssa_def *exponent;
- if (src[0]->bit_size == 64)
- val->ssa->def = build_frexp64(nb, src[0], &exponent);
- else if (src[0]->bit_size == 32)
- val->ssa->def = build_frexp32(nb, src[0], &exponent);
- else
- val->ssa->def = build_frexp16(nb, src[0], &exponent);
+ nir_ssa_def *exponent = nir_frexp_exp(nb, src[0]);
+ val->ssa->def = nir_frexp_sig(nb, src[0]);
nir_store_deref(nb, vtn_nir_deref(b, w[6]), exponent, 0xf);
return;
}
case GLSLstd450FrexpStruct: {
vtn_assert(glsl_type_is_struct_or_ifc(val->ssa->type));
- if (src[0]->bit_size == 64)
- val->ssa->elems[0]->def = build_frexp64(nb, src[0],
- &val->ssa->elems[1]->def);
- else if (src[0]->bit_size == 32)
- val->ssa->elems[0]->def = build_frexp32(nb, src[0],
- &val->ssa->elems[1]->def);
- else
- val->ssa->elems[0]->def = build_frexp16(nb, src[0],
- &val->ssa->elems[1]->def);
+ val->ssa->elems[0]->def = nir_frexp_sig(nb, src[0]);
+ val->ssa->elems[1]->def = nir_frexp_exp(nb, src[0]);
return;
}
case GLSLstd450InterpolateAtCentroid:
case GLSLstd450InterpolateAtSample:
case GLSLstd450InterpolateAtOffset:
- handle_glsl450_interpolation(b, ext_opcode, w, count);
+ handle_glsl450_interpolation(b, (enum GLSLstd450)ext_opcode, w, count);
break;
default:
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