src/compiler/spirv/vtn_glsl450.c - platform/external/mesa3d - Git at Google

 /*
  * Copyright © 2015 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.
  *
  * Authors:
  *    Jason Ekstrand (jason@jlekstrand.net)
  *
  */

 #include <math.h>

 #include "nir/nir_builtin_builder.h"

 #include "vtn_private.h"
 #include "GLSL.std.450.h"

 #define M_PIf   ((float) M_PI)
 #define M_PI_2f ((float) M_PI_2)
 #define M_PI_4f ((float) M_PI_4)

 static nir_ssa_def *
 build_mat2_det(nir_builder *b, nir_ssa_def *col[2])
 {
    unsigned swiz[2] = {1, 0 };
    nir_ssa_def *p = nir_fmul(b, col[0], nir_swizzle(b, col[1], swiz, 2));
    return nir_fsub(b, nir_channel(b, p, 0), nir_channel(b, p, 1));
 }

 static nir_ssa_def *
 build_mat3_det(nir_builder *b, nir_ssa_def *col[3])
 {
    unsigned yzx[3] = {1, 2, 0 };
    unsigned zxy[3] = {2, 0, 1 };

    nir_ssa_def *prod0 =
       nir_fmul(b, col[0],
                nir_fmul(b, nir_swizzle(b, col[1], yzx, 3),
                            nir_swizzle(b, col[2], zxy, 3)));
    nir_ssa_def *prod1 =
       nir_fmul(b, col[0],
                nir_fmul(b, nir_swizzle(b, col[1], zxy, 3),
                            nir_swizzle(b, col[2], yzx, 3)));

    nir_ssa_def *diff = nir_fsub(b, prod0, prod1);

    return nir_fadd(b, nir_channel(b, diff, 0),
                       nir_fadd(b, nir_channel(b, diff, 1),
                                   nir_channel(b, diff, 2)));
 }

 static nir_ssa_def *
 build_mat4_det(nir_builder *b, nir_ssa_def **col)
 {
    nir_ssa_def *subdet[4];
    for (unsigned i = 0; i < 4; i++) {
       unsigned swiz[3];
       for (unsigned j = 0; j < 3; j++)
          swiz[j] = j + (j >= i);

       nir_ssa_def *subcol[3];
       subcol[0] = nir_swizzle(b, col[1], swiz, 3);
       subcol[1] = nir_swizzle(b, col[2], swiz, 3);
       subcol[2] = nir_swizzle(b, col[3], swiz, 3);

       subdet[i] = build_mat3_det(b, subcol);
    }

    nir_ssa_def *prod = nir_fmul(b, col[0], nir_vec(b, subdet, 4));

    return nir_fadd(b, nir_fsub(b, nir_channel(b, prod, 0),
                                   nir_channel(b, prod, 1)),
                       nir_fsub(b, nir_channel(b, prod, 2),
                                   nir_channel(b, prod, 3)));
 }

 static nir_ssa_def *
 build_mat_det(struct vtn_builder *b, struct vtn_ssa_value *src)
 {
    unsigned size = glsl_get_vector_elements(src->type);

    nir_ssa_def *cols[4];
    for (unsigned i = 0; i < size; i++)
       cols[i] = src->elems[i]->def;

    switch(size) {
    case 2: return build_mat2_det(&b->nb, cols);
    case 3: return build_mat3_det(&b->nb, cols);
    case 4: return build_mat4_det(&b->nb, cols);
    default:
       vtn_fail("Invalid matrix size");
    }
 }

 /* Computes the determinate of the submatrix given by taking src and
  * removing the specified row and column.
  */
 static nir_ssa_def *
 build_mat_subdet(struct nir_builder *b, struct vtn_ssa_value *src,
                  unsigned size, unsigned row, unsigned col)
 {
    assert(row < size && col < size);
    if (size == 2) {
       return nir_channel(b, src->elems[1 - col]->def, 1 - row);
    } else {
       /* Swizzle to get all but the specified row */
       unsigned swiz[NIR_MAX_VEC_COMPONENTS] = {0};
       for (unsigned j = 0; j < 3; j++)
          swiz[j] = j + (j >= row);

       /* Grab all but the specified column */
       nir_ssa_def *subcol[3];
       for (unsigned j = 0; j < size; j++) {
          if (j != col) {
             subcol[j - (j > col)] = nir_swizzle(b, src->elems[j]->def,
                                                 swiz, size - 1);
          }
       }

       if (size == 3) {
          return build_mat2_det(b, subcol);
       } else {
          assert(size == 4);
          return build_mat3_det(b, subcol);
       }
    }
 }

 static struct vtn_ssa_value *
 matrix_inverse(struct vtn_builder *b, struct vtn_ssa_value *src)
 {
    nir_ssa_def *adj_col[4];
    unsigned size = glsl_get_vector_elements(src->type);

    /* Build up an adjugate matrix */
    for (unsigned c = 0; c < size; c++) {
       nir_ssa_def *elem[4];
       for (unsigned r = 0; r < size; r++) {
          elem[r] = build_mat_subdet(&b->nb, src, size, c, r);

          if ((r + c) % 2)
             elem[r] = nir_fneg(&b->nb, elem[r]);
       }

       adj_col[c] = nir_vec(&b->nb, elem, size);
    }

    nir_ssa_def *det_inv = nir_frcp(&b->nb, build_mat_det(b, src));

    struct vtn_ssa_value *val = vtn_create_ssa_value(b, src->type);
    for (unsigned i = 0; i < size; i++)
       val->elems[i]->def = nir_fmul(&b->nb, adj_col[i], det_inv);

    return val;
 }

 /**
  * Approximate asin(x) by the piecewise formula:
  * for |x| < 0.5, asin~(x) = x * (1 + x²(pS0 + x²(pS1 + x²*pS2)) / (1 + x²*qS1))
  * for |x| ≥ 0.5, asin~(x) = sign(x) * (π/2 - sqrt(1 - |x|) * (π/2 + |x|(π/4 - 1 + |x|(p0 + |x|p1))))
  *
  * The latter is correct to first order at x=0 and x=±1 regardless of the p
  * coefficients but can be made second-order correct at both ends by selecting
  * the fit coefficients appropriately.  Different p coefficients can be used
  * in the asin and acos implementation to minimize some relative error metric
  * in each case.
  */
 static nir_ssa_def *
 build_asin(nir_builder *b, nir_ssa_def *x, float p0, float p1, bool piecewise)
 {
    if (x->bit_size == 16) {
       /* The polynomial approximation isn't precise enough to meet half-float
        * precision requirements. Alternatively, we could implement this using
        * the formula:
        *
        * asin(x) = atan2(x, sqrt(1 - x*x))
        *
        * But that is very expensive, so instead we just do the polynomial
        * approximation in 32-bit math and then we convert the result back to
        * 16-bit.
        */
       return nir_f2f16(b, build_asin(b, nir_f2f32(b, x), p0, p1, piecewise));
    }
    nir_ssa_def *one = nir_imm_floatN_t(b, 1.0f, x->bit_size);
    nir_ssa_def *half = nir_imm_floatN_t(b, 0.5f, x->bit_size);
    nir_ssa_def *abs_x = nir_fabs(b, x);

    nir_ssa_def *p0_plus_xp1 = nir_fadd_imm(b, nir_fmul_imm(b, abs_x, p1), p0);

    nir_ssa_def *expr_tail =
       nir_fadd_imm(b, nir_fmul(b, abs_x,
                                   nir_fadd_imm(b, nir_fmul(b, abs_x,
                                                                p0_plus_xp1),
                                                   M_PI_4f - 1.0f)),
                       M_PI_2f);

    nir_ssa_def *result0 = nir_fmul(b, nir_fsign(b, x),
                       nir_fsub(b, nir_imm_floatN_t(b, M_PI_2f, x->bit_size),
                                   nir_fmul(b, nir_fsqrt(b, nir_fsub(b, one, abs_x)),
                                                            expr_tail)));
    if (piecewise) {
       /* approximation for |x| < 0.5 */
       const float pS0 =  1.6666586697e-01f;
       const float pS1 = -4.2743422091e-02f;
       const float pS2 = -8.6563630030e-03f;
       const float qS1 = -7.0662963390e-01f;

       nir_ssa_def *x2 = nir_fmul(b, x, x);
       nir_ssa_def *p = nir_fmul(b,
                                 x2,
                                 nir_fadd_imm(b,
                                              nir_fmul(b,
                                                       x2,
                                                       nir_fadd_imm(b, nir_fmul_imm(b, x2, pS2),
                                                                    pS1)),
                                              pS0));

       nir_ssa_def *q = nir_fadd(b, one, nir_fmul_imm(b, x2, qS1));
       nir_ssa_def *result1 = nir_fadd(b, x, nir_fmul(b, x, nir_fdiv(b, p, q)));
       return nir_bcsel(b, nir_flt(b, abs_x, half), result1, result0);
    } else {
       return result0;
    }
 }

 static nir_op
 vtn_nir_alu_op_for_spirv_glsl_opcode(struct vtn_builder *b,
                                      enum GLSLstd450 opcode,
                                      unsigned execution_mode,
                                      bool *exact)
 {
    *exact = false;
    switch (opcode) {
    case GLSLstd450Round:         return nir_op_fround_even;
    case GLSLstd450RoundEven:     return nir_op_fround_even;
    case GLSLstd450Trunc:         return nir_op_ftrunc;
    case GLSLstd450FAbs:          return nir_op_fabs;
    case GLSLstd450SAbs:          return nir_op_iabs;
    case GLSLstd450FSign:         return nir_op_fsign;
    case GLSLstd450SSign:         return nir_op_isign;
    case GLSLstd450Floor:         return nir_op_ffloor;
    case GLSLstd450Ceil:          return nir_op_fceil;
    case GLSLstd450Fract:         return nir_op_ffract;
    case GLSLstd450Sin:           return nir_op_fsin;
    case GLSLstd450Cos:           return nir_op_fcos;
    case GLSLstd450Pow:           return nir_op_fpow;
    case GLSLstd450Exp2:          return nir_op_fexp2;
    case GLSLstd450Log2:          return nir_op_flog2;
    case GLSLstd450Sqrt:          return nir_op_fsqrt;
    case GLSLstd450InverseSqrt:   return nir_op_frsq;
    case GLSLstd450NMin:          *exact = true; return nir_op_fmin;
    case GLSLstd450FMin:          return nir_op_fmin;
    case GLSLstd450UMin:          return nir_op_umin;
    case GLSLstd450SMin:          return nir_op_imin;
    case GLSLstd450NMax:          *exact = true; return nir_op_fmax;
    case GLSLstd450FMax:          return nir_op_fmax;
    case GLSLstd450UMax:          return nir_op_umax;
    case GLSLstd450SMax:          return nir_op_imax;
    case GLSLstd450FMix:          return nir_op_flrp;
    case GLSLstd450Fma:           return nir_op_ffma;
    case GLSLstd450Ldexp:         return nir_op_ldexp;
    case GLSLstd450FindILsb:      return nir_op_find_lsb;
    case GLSLstd450FindSMsb:      return nir_op_ifind_msb;
    case GLSLstd450FindUMsb:      return nir_op_ufind_msb;

    /* Packing/Unpacking functions */
    case GLSLstd450PackSnorm4x8:     return nir_op_pack_snorm_4x8;
    case GLSLstd450PackUnorm4x8:     return nir_op_pack_unorm_4x8;
    case GLSLstd450PackSnorm2x16:    return nir_op_pack_snorm_2x16;
    case GLSLstd450PackUnorm2x16:    return nir_op_pack_unorm_2x16;
    case GLSLstd450PackHalf2x16:     return nir_op_pack_half_2x16;
    case GLSLstd450PackDouble2x32:   return nir_op_pack_64_2x32;
    case GLSLstd450UnpackSnorm4x8:   return nir_op_unpack_snorm_4x8;
    case GLSLstd450UnpackUnorm4x8:   return nir_op_unpack_unorm_4x8;
    case GLSLstd450UnpackSnorm2x16:  return nir_op_unpack_snorm_2x16;
    case GLSLstd450UnpackUnorm2x16:  return nir_op_unpack_unorm_2x16;
    case GLSLstd450UnpackHalf2x16:
       if (execution_mode & FLOAT_CONTROLS_DENORM_FLUSH_TO_ZERO_FP16)
          return nir_op_unpack_half_2x16_flush_to_zero;
       else
          return nir_op_unpack_half_2x16;
    case GLSLstd450UnpackDouble2x32: return nir_op_unpack_64_2x32;

    default:
       vtn_fail("No NIR equivalent");
    }
 }

 #define NIR_IMM_FP(n, v) (nir_imm_floatN_t(n, v, src[0]->bit_size))

 static void
 handle_glsl450_alu(struct vtn_builder *b, enum GLSLstd450 entrypoint,
                    const uint32_t *w, unsigned count)
 {
    struct nir_builder *nb = &b->nb;
    const struct glsl_type *dest_type = vtn_get_type(b, w[1])->type;
    struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
    val->ssa = vtn_create_ssa_value(b, dest_type);

    /* Collect the various SSA sources */
    unsigned num_inputs = count - 5;
    nir_ssa_def *src[3] = { NULL, };
    for (unsigned i = 0; i < num_inputs; i++) {
       /* These are handled specially below */
       if (vtn_untyped_value(b, w[i + 5])->value_type == vtn_value_type_pointer)
          continue;

       src[i] = vtn_ssa_value(b, w[i + 5])->def;
    }

    switch (entrypoint) {
    case GLSLstd450Radians:
       val->ssa->def = nir_radians(nb, src[0]);
       return;
    case GLSLstd450Degrees:
       val->ssa->def = nir_degrees(nb, src[0]);
       return;
    case GLSLstd450Tan:
       val->ssa->def = nir_ftan(nb, src[0]);
       return;

    case GLSLstd450Modf: {
       nir_ssa_def *sign = nir_fsign(nb, src[0]);
       nir_ssa_def *abs = nir_fabs(nb, src[0]);
       val->ssa->def = nir_fmul(nb, sign, nir_ffract(nb, abs));
       nir_store_deref(nb, vtn_nir_deref(b, w[6]),
                       nir_fmul(nb, sign, nir_ffloor(nb, abs)), 0xf);
       return;
    }

    case GLSLstd450ModfStruct: {
       nir_ssa_def *sign = nir_fsign(nb, src[0]);
       nir_ssa_def *abs = nir_fabs(nb, src[0]);
       vtn_assert(glsl_type_is_struct_or_ifc(val->ssa->type));
       val->ssa->elems[0]->def = nir_fmul(nb, sign, nir_ffract(nb, abs));
       val->ssa->elems[1]->def = nir_fmul(nb, sign, nir_ffloor(nb, abs));
       return;
    }

    case GLSLstd450Step:
       val->ssa->def = nir_sge(nb, src[1], src[0]);
       return;

    case GLSLstd450Length:
       val->ssa->def = nir_fast_length(nb, src[0]);
       return;
    case GLSLstd450Distance:
       val->ssa->def = nir_fast_distance(nb, src[0], src[1]);
       return;
    case GLSLstd450Normalize:
       val->ssa->def = nir_fast_normalize(nb, src[0]);
       return;

    case GLSLstd450Exp:
       val->ssa->def = nir_fexp(nb, src[0]);
       return;

    case GLSLstd450Log:
       val->ssa->def = nir_flog(nb, src[0]);
       return;

    case GLSLstd450FClamp:
       val->ssa->def = nir_fclamp(nb, src[0], src[1], src[2]);
       return;
    case GLSLstd450NClamp:
       nb->exact = true;
       val->ssa->def = nir_fclamp(nb, src[0], src[1], src[2]);
       nb->exact = false;
       return;
    case GLSLstd450UClamp:
       val->ssa->def = nir_uclamp(nb, src[0], src[1], src[2]);
       return;
    case GLSLstd450SClamp:
       val->ssa->def = nir_iclamp(nb, src[0], src[1], src[2]);
       return;

    case GLSLstd450Cross: {
       val->ssa->def = nir_cross3(nb, src[0], src[1]);
       return;
    }

    case GLSLstd450SmoothStep: {
       val->ssa->def = nir_smoothstep(nb, src[0], src[1], src[2]);
       return;
    }

    case GLSLstd450FaceForward:
       val->ssa->def =
          nir_bcsel(nb, nir_flt(nb, nir_fdot(nb, src[2], src[1]),
                                    NIR_IMM_FP(nb, 0.0)),
                        src[0], nir_fneg(nb, src[0]));
       return;

    case GLSLstd450Reflect:
       /* I - 2 * dot(N, I) * N */
       val->ssa->def =
          nir_fsub(nb, src[0], nir_fmul(nb, NIR_IMM_FP(nb, 2.0),
                               nir_fmul(nb, nir_fdot(nb, src[0], src[1]),
                                            src[1])));
       return;

    case GLSLstd450Refract: {
       nir_ssa_def *I = src[0];
       nir_ssa_def *N = src[1];
       nir_ssa_def *eta = src[2];
       nir_ssa_def *n_dot_i = nir_fdot(nb, N, I);
       nir_ssa_def *one = NIR_IMM_FP(nb, 1.0);
       nir_ssa_def *zero = NIR_IMM_FP(nb, 0.0);
       /* According to the SPIR-V and GLSL specs, eta is always a float
        * regardless of the type of the other operands. However in practice it
        * seems that if you try to pass it a float then glslang will just
        * promote it to a double and generate invalid SPIR-V. In order to
        * support a hypothetical fixed version of glslang we’ll promote eta to
        * double if the other operands are double also.
        */
       if (I->bit_size != eta->bit_size) {
          nir_op conversion_op =
             nir_type_conversion_op(nir_type_float | eta->bit_size,
                                    nir_type_float | I->bit_size,
                                    nir_rounding_mode_undef);
          eta = nir_build_alu(nb, conversion_op, eta, NULL, NULL, NULL);
       }
       /* k = 1.0 - eta * eta * (1.0 - dot(N, I) * dot(N, I)) */
       nir_ssa_def *k =
          nir_fsub(nb, one, nir_fmul(nb, eta, nir_fmul(nb, eta,
                       nir_fsub(nb, one, nir_fmul(nb, n_dot_i, n_dot_i)))));
       nir_ssa_def *result =
          nir_fsub(nb, nir_fmul(nb, eta, I),
                       nir_fmul(nb, nir_fadd(nb, nir_fmul(nb, eta, n_dot_i),
                                                 nir_fsqrt(nb, k)), N));
       /* XXX: bcsel, or if statement? */
       val->ssa->def = nir_bcsel(nb, nir_flt(nb, k, zero), zero, result);
       return;
    }

    case GLSLstd450Sinh:
       /* 0.5 * (e^x - e^(-x)) */
       val->ssa->def =
          nir_fmul_imm(nb, nir_fsub(nb, nir_fexp(nb, src[0]),
                                        nir_fexp(nb, nir_fneg(nb, src[0]))),
                           0.5f);
       return;

    case GLSLstd450Cosh:
       /* 0.5 * (e^x + e^(-x)) */
       val->ssa->def =
          nir_fmul_imm(nb, nir_fadd(nb, nir_fexp(nb, src[0]),
                                        nir_fexp(nb, nir_fneg(nb, src[0]))),
                           0.5f);
       return;

    case GLSLstd450Tanh: {
       /* tanh(x) := (e^x - e^(-x)) / (e^x + e^(-x))
        *
        * We clamp x to [-10, +10] to avoid precision problems.  When x > 10,
        * e^x dominates the sum, e^(-x) is lost and tanh(x) is 1.0 for 32 bit
        * floating point.
        *
        * For 16-bit precision this we clamp x to [-4.2, +4.2].
        */
       const uint32_t bit_size = src[0]->bit_size;
       const double clamped_x = bit_size > 16 ? 10.0 : 4.2;
       nir_ssa_def *x = nir_fclamp(nb, src[0],
                                   nir_imm_floatN_t(nb, -clamped_x, bit_size),
                                   nir_imm_floatN_t(nb, clamped_x, bit_size));
       val->ssa->def =
          nir_fdiv(nb, nir_fsub(nb, nir_fexp(nb, x),
                                nir_fexp(nb, nir_fneg(nb, x))),
                   nir_fadd(nb, nir_fexp(nb, x),
                            nir_fexp(nb, nir_fneg(nb, x))));
       return;
    }

    case GLSLstd450Asinh:
       val->ssa->def = nir_fmul(nb, nir_fsign(nb, src[0]),
          nir_flog(nb, nir_fadd(nb, nir_fabs(nb, src[0]),
                       nir_fsqrt(nb, nir_fadd_imm(nb, nir_fmul(nb, src[0], src[0]),
                                                     1.0f)))));
       return;
    case GLSLstd450Acosh:
       val->ssa->def = nir_flog(nb, nir_fadd(nb, src[0],
          nir_fsqrt(nb, nir_fadd_imm(nb, nir_fmul(nb, src[0], src[0]),
                                         -1.0f))));
       return;
    case GLSLstd450Atanh: {
       nir_ssa_def *one = nir_imm_floatN_t(nb, 1.0, src[0]->bit_size);
       val->ssa->def =
          nir_fmul_imm(nb, nir_flog(nb, nir_fdiv(nb, nir_fadd(nb, src[0], one),
                                        nir_fsub(nb, one, src[0]))),
                           0.5f);
       return;
    }

    case GLSLstd450Asin:
       val->ssa->def = build_asin(nb, src[0], 0.086566724, -0.03102955, true);
       return;

    case GLSLstd450Acos:
       val->ssa->def =
          nir_fsub(nb, nir_imm_floatN_t(nb, M_PI_2f, src[0]->bit_size),
                       build_asin(nb, src[0], 0.08132463, -0.02363318, false));
       return;

    case GLSLstd450Atan:
       val->ssa->def = nir_atan(nb, src[0]);
       return;

    case GLSLstd450Atan2:
       val->ssa->def = nir_atan2(nb, src[0], src[1]);
       return;

    case GLSLstd450Frexp: {
       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));
       val->ssa->elems[0]->def = nir_frexp_sig(nb, src[0]);
       val->ssa->elems[1]->def = nir_frexp_exp(nb, src[0]);
       return;
    }

    default: {
       unsigned execution_mode =
          b->shader->info.float_controls_execution_mode;
       bool exact;
       nir_op op = vtn_nir_alu_op_for_spirv_glsl_opcode(b, entrypoint, execution_mode, &exact);
       b->nb.exact = exact;
       val->ssa->def = nir_build_alu(&b->nb, op, src[0], src[1], src[2], NULL);
       b->nb.exact = false;
       return;
    }
    }
 }

 static void
 handle_glsl450_interpolation(struct vtn_builder *b, enum GLSLstd450 opcode,
                              const uint32_t *w, unsigned count)
 {
    const struct glsl_type *dest_type = vtn_get_type(b, w[1])->type;
    struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
    val->ssa = vtn_create_ssa_value(b, dest_type);

    nir_intrinsic_op op;
    switch (opcode) {
    case GLSLstd450InterpolateAtCentroid:
       op = nir_intrinsic_interp_deref_at_centroid;
       break;
    case GLSLstd450InterpolateAtSample:
       op = nir_intrinsic_interp_deref_at_sample;
       break;
    case GLSLstd450InterpolateAtOffset:
       op = nir_intrinsic_interp_deref_at_offset;
       break;
    default:
       vtn_fail("Invalid opcode");
    }

    nir_intrinsic_instr *intrin = nir_intrinsic_instr_create(b->nb.shader, op);

    struct vtn_pointer *ptr =
       vtn_value(b, w[5], vtn_value_type_pointer)->pointer;
    nir_deref_instr *deref = vtn_pointer_to_deref(b, ptr);

    /* If the value we are interpolating has an index into a vector then
     * interpolate the vector and index the result of that instead. This is
     * necessary because the index will get generated as a series of nir_bcsel
     * instructions so it would no longer be an input variable.
     */
    const bool vec_array_deref = deref->deref_type == nir_deref_type_array &&
       glsl_type_is_vector(nir_deref_instr_parent(deref)->type);

    nir_deref_instr *vec_deref = NULL;
    if (vec_array_deref) {
       vec_deref = deref;
       deref = nir_deref_instr_parent(deref);
    }
    intrin->src[0] = nir_src_for_ssa(&deref->dest.ssa);

    switch (opcode) {
    case GLSLstd450InterpolateAtCentroid:
       break;
    case GLSLstd450InterpolateAtSample:
    case GLSLstd450InterpolateAtOffset:
       intrin->src[1] = nir_src_for_ssa(vtn_ssa_value(b, w[6])->def);
       break;
    default:
       vtn_fail("Invalid opcode");
    }

    intrin->num_components = glsl_get_vector_elements(deref->type);
    nir_ssa_dest_init(&intrin->instr, &intrin->dest,
                      glsl_get_vector_elements(deref->type),
                      glsl_get_bit_size(deref->type), NULL);

    nir_builder_instr_insert(&b->nb, &intrin->instr);

    if (vec_array_deref) {
       assert(vec_deref);
       val->ssa->def = nir_vector_extract(&b->nb, &intrin->dest.ssa,
                                          vec_deref->arr.index.ssa);
    } else {
       val->ssa->def = &intrin->dest.ssa;
    }
 }

 bool
 vtn_handle_glsl450_instruction(struct vtn_builder *b, SpvOp ext_opcode,
                                const uint32_t *w, unsigned count)
 {
    switch ((enum GLSLstd450)ext_opcode) {
    case GLSLstd450Determinant: {
       struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
       val->ssa = rzalloc(b, struct vtn_ssa_value);
       val->ssa->type = vtn_get_type(b, w[1])->type;
       val->ssa->def = build_mat_det(b, vtn_ssa_value(b, w[5]));
       break;
    }

    case GLSLstd450MatrixInverse: {
       struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
       val->ssa = matrix_inverse(b, vtn_ssa_value(b, w[5]));
       break;
    }

    case GLSLstd450InterpolateAtCentroid:
    case GLSLstd450InterpolateAtSample:
    case GLSLstd450InterpolateAtOffset:
       handle_glsl450_interpolation(b, (enum GLSLstd450)ext_opcode, w, count);
       break;

    default:
       handle_glsl450_alu(b, (enum GLSLstd450)ext_opcode, w, count);
    }

    return true;
 }
	/*
	* Copyright © 2015 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.
	*
	* Authors:
	* Jason Ekstrand (jason@jlekstrand.net)
	*
	*/

	#include <math.h>

	#include "nir/nir_builtin_builder.h"

	#include "vtn_private.h"
	#include "GLSL.std.450.h"

	#define M_PIf ((float) M_PI)
	#define M_PI_2f ((float) M_PI_2)
	#define M_PI_4f ((float) M_PI_4)

	static nir_ssa_def *
	build_mat2_det(nir_builder b, nir_ssa_def col[2])
	{
	unsigned swiz[2] = {1, 0 };
	nir_ssa_def *p = nir_fmul(b, col[0], nir_swizzle(b, col[1], swiz, 2));
	return nir_fsub(b, nir_channel(b, p, 0), nir_channel(b, p, 1));
	}

	static nir_ssa_def *
	build_mat3_det(nir_builder b, nir_ssa_def col[3])
	{
	unsigned yzx[3] = {1, 2, 0 };
	unsigned zxy[3] = {2, 0, 1 };

	nir_ssa_def *prod0 =
	nir_fmul(b, col[0],
	nir_fmul(b, nir_swizzle(b, col[1], yzx, 3),
	nir_swizzle(b, col[2], zxy, 3)));
	nir_ssa_def *prod1 =
	nir_fmul(b, col[0],
	nir_fmul(b, nir_swizzle(b, col[1], zxy, 3),
	nir_swizzle(b, col[2], yzx, 3)));

	nir_ssa_def *diff = nir_fsub(b, prod0, prod1);

	return nir_fadd(b, nir_channel(b, diff, 0),
	nir_fadd(b, nir_channel(b, diff, 1),
	nir_channel(b, diff, 2)));
	}

	static nir_ssa_def *
	build_mat4_det(nir_builder b, nir_ssa_def *col)
	{
	nir_ssa_def *subdet[4];
	for (unsigned i = 0; i < 4; i++) {
	unsigned swiz[3];
	for (unsigned j = 0; j < 3; j++)
	swiz[j] = j + (j >= i);

	nir_ssa_def *subcol[3];
	subcol[0] = nir_swizzle(b, col[1], swiz, 3);
	subcol[1] = nir_swizzle(b, col[2], swiz, 3);
	subcol[2] = nir_swizzle(b, col[3], swiz, 3);

	subdet[i] = build_mat3_det(b, subcol);
	}

	nir_ssa_def *prod = nir_fmul(b, col[0], nir_vec(b, subdet, 4));

	return nir_fadd(b, nir_fsub(b, nir_channel(b, prod, 0),
	nir_channel(b, prod, 1)),
	nir_fsub(b, nir_channel(b, prod, 2),
	nir_channel(b, prod, 3)));
	}

	static nir_ssa_def *
	build_mat_det(struct vtn_builder b, struct vtn_ssa_value src)
	{
	unsigned size = glsl_get_vector_elements(src->type);

	nir_ssa_def *cols[4];
	for (unsigned i = 0; i < size; i++)
	cols[i] = src->elems[i]->def;

	switch(size) {
	case 2: return build_mat2_det(&b->nb, cols);
	case 3: return build_mat3_det(&b->nb, cols);
	case 4: return build_mat4_det(&b->nb, cols);
	default:
	vtn_fail("Invalid matrix size");
	}
	}

	/* Computes the determinate of the submatrix given by taking src and
	* removing the specified row and column.
	*/
	static nir_ssa_def *
	build_mat_subdet(struct nir_builder b, struct vtn_ssa_value src,
	unsigned size, unsigned row, unsigned col)
	{
	assert(row < size && col < size);
	if (size == 2) {
	return nir_channel(b, src->elems[1 - col]->def, 1 - row);
	} else {
	/* Swizzle to get all but the specified row */
	unsigned swiz[NIR_MAX_VEC_COMPONENTS] = {0};
	for (unsigned j = 0; j < 3; j++)
	swiz[j] = j + (j >= row);

	/* Grab all but the specified column */
	nir_ssa_def *subcol[3];
	for (unsigned j = 0; j < size; j++) {
	if (j != col) {
	subcol[j - (j > col)] = nir_swizzle(b, src->elems[j]->def,
	swiz, size - 1);
	}
	}

	if (size == 3) {
	return build_mat2_det(b, subcol);
	} else {
	assert(size == 4);
	return build_mat3_det(b, subcol);
	}
	}
	}

	static struct vtn_ssa_value *
	matrix_inverse(struct vtn_builder b, struct vtn_ssa_value src)
	{
	nir_ssa_def *adj_col[4];
	unsigned size = glsl_get_vector_elements(src->type);

	/* Build up an adjugate matrix */
	for (unsigned c = 0; c < size; c++) {
	nir_ssa_def *elem[4];
	for (unsigned r = 0; r < size; r++) {
	elem[r] = build_mat_subdet(&b->nb, src, size, c, r);

	if ((r + c) % 2)
	elem[r] = nir_fneg(&b->nb, elem[r]);
	}

	adj_col[c] = nir_vec(&b->nb, elem, size);
	}

	nir_ssa_def *det_inv = nir_frcp(&b->nb, build_mat_det(b, src));

	struct vtn_ssa_value *val = vtn_create_ssa_value(b, src->type);
	for (unsigned i = 0; i < size; i++)
	val->elems[i]->def = nir_fmul(&b->nb, adj_col[i], det_inv);

	return val;
	}

	/**
	* Approximate asin(x) by the piecewise formula:
	* for \|x\| < 0.5, asin~(x) = x * (1 + x²(pS0 + x²(pS1 + x²pS2)) / (1 + x²qS1))
	* for \|x\| ≥ 0.5, asin~(x) = sign(x) * (π/2 - sqrt(1 - \|x\|) * (π/2 + \|x\|(π/4 - 1 + \|x\|(p0 + \|x\|p1))))
	*
	* The latter is correct to first order at x=0 and x=±1 regardless of the p
	* coefficients but can be made second-order correct at both ends by selecting
	* the fit coefficients appropriately. Different p coefficients can be used
	* in the asin and acos implementation to minimize some relative error metric
	* in each case.
	*/
	static nir_ssa_def *
	build_asin(nir_builder b, nir_ssa_def x, float p0, float p1, bool piecewise)
	{
	if (x->bit_size == 16) {
	/* The polynomial approximation isn't precise enough to meet half-float
	* precision requirements. Alternatively, we could implement this using
	* the formula:
	*
	* asin(x) = atan2(x, sqrt(1 - x*x))
	*
	* But that is very expensive, so instead we just do the polynomial
	* approximation in 32-bit math and then we convert the result back to
	* 16-bit.
	*/
	return nir_f2f16(b, build_asin(b, nir_f2f32(b, x), p0, p1, piecewise));
	}
	nir_ssa_def *one = nir_imm_floatN_t(b, 1.0f, x->bit_size);
	nir_ssa_def *half = nir_imm_floatN_t(b, 0.5f, x->bit_size);
	nir_ssa_def *abs_x = nir_fabs(b, x);

	nir_ssa_def *p0_plus_xp1 = nir_fadd_imm(b, nir_fmul_imm(b, abs_x, p1), p0);

	nir_ssa_def *expr_tail =
	nir_fadd_imm(b, nir_fmul(b, abs_x,
	nir_fadd_imm(b, nir_fmul(b, abs_x,
	p0_plus_xp1),
	M_PI_4f - 1.0f)),
	M_PI_2f);

	nir_ssa_def *result0 = nir_fmul(b, nir_fsign(b, x),
	nir_fsub(b, nir_imm_floatN_t(b, M_PI_2f, x->bit_size),
	nir_fmul(b, nir_fsqrt(b, nir_fsub(b, one, abs_x)),
	expr_tail)));
	if (piecewise) {
	/* approximation for \|x\| < 0.5 */
	const float pS0 = 1.6666586697e-01f;
	const float pS1 = -4.2743422091e-02f;
	const float pS2 = -8.6563630030e-03f;
	const float qS1 = -7.0662963390e-01f;

	nir_ssa_def *x2 = nir_fmul(b, x, x);
	nir_ssa_def *p = nir_fmul(b,
	x2,
	nir_fadd_imm(b,
	nir_fmul(b,
	x2,
	nir_fadd_imm(b, nir_fmul_imm(b, x2, pS2),
	pS1)),
	pS0));

	nir_ssa_def *q = nir_fadd(b, one, nir_fmul_imm(b, x2, qS1));
	nir_ssa_def *result1 = nir_fadd(b, x, nir_fmul(b, x, nir_fdiv(b, p, q)));
	return nir_bcsel(b, nir_flt(b, abs_x, half), result1, result0);
	} else {
	return result0;
	}
	}

	static nir_op
	vtn_nir_alu_op_for_spirv_glsl_opcode(struct vtn_builder *b,
	enum GLSLstd450 opcode,
	unsigned execution_mode,
	bool *exact)
	{
	*exact = false;
	switch (opcode) {
	case GLSLstd450Round: return nir_op_fround_even;
	case GLSLstd450RoundEven: return nir_op_fround_even;
	case GLSLstd450Trunc: return nir_op_ftrunc;
	case GLSLstd450FAbs: return nir_op_fabs;
	case GLSLstd450SAbs: return nir_op_iabs;
	case GLSLstd450FSign: return nir_op_fsign;
	case GLSLstd450SSign: return nir_op_isign;
	case GLSLstd450Floor: return nir_op_ffloor;
	case GLSLstd450Ceil: return nir_op_fceil;
	case GLSLstd450Fract: return nir_op_ffract;
	case GLSLstd450Sin: return nir_op_fsin;
	case GLSLstd450Cos: return nir_op_fcos;
	case GLSLstd450Pow: return nir_op_fpow;
	case GLSLstd450Exp2: return nir_op_fexp2;
	case GLSLstd450Log2: return nir_op_flog2;
	case GLSLstd450Sqrt: return nir_op_fsqrt;
	case GLSLstd450InverseSqrt: return nir_op_frsq;
	case GLSLstd450NMin: *exact = true; return nir_op_fmin;
	case GLSLstd450FMin: return nir_op_fmin;
	case GLSLstd450UMin: return nir_op_umin;
	case GLSLstd450SMin: return nir_op_imin;
	case GLSLstd450NMax: *exact = true; return nir_op_fmax;
	case GLSLstd450FMax: return nir_op_fmax;
	case GLSLstd450UMax: return nir_op_umax;
	case GLSLstd450SMax: return nir_op_imax;
	case GLSLstd450FMix: return nir_op_flrp;
	case GLSLstd450Fma: return nir_op_ffma;
	case GLSLstd450Ldexp: return nir_op_ldexp;
	case GLSLstd450FindILsb: return nir_op_find_lsb;
	case GLSLstd450FindSMsb: return nir_op_ifind_msb;
	case GLSLstd450FindUMsb: return nir_op_ufind_msb;

	/* Packing/Unpacking functions */
	case GLSLstd450PackSnorm4x8: return nir_op_pack_snorm_4x8;
	case GLSLstd450PackUnorm4x8: return nir_op_pack_unorm_4x8;
	case GLSLstd450PackSnorm2x16: return nir_op_pack_snorm_2x16;
	case GLSLstd450PackUnorm2x16: return nir_op_pack_unorm_2x16;
	case GLSLstd450PackHalf2x16: return nir_op_pack_half_2x16;
	case GLSLstd450PackDouble2x32: return nir_op_pack_64_2x32;
	case GLSLstd450UnpackSnorm4x8: return nir_op_unpack_snorm_4x8;
	case GLSLstd450UnpackUnorm4x8: return nir_op_unpack_unorm_4x8;
	case GLSLstd450UnpackSnorm2x16: return nir_op_unpack_snorm_2x16;
	case GLSLstd450UnpackUnorm2x16: return nir_op_unpack_unorm_2x16;
	case GLSLstd450UnpackHalf2x16:
	if (execution_mode & FLOAT_CONTROLS_DENORM_FLUSH_TO_ZERO_FP16)
	return nir_op_unpack_half_2x16_flush_to_zero;
	else
	return nir_op_unpack_half_2x16;
	case GLSLstd450UnpackDouble2x32: return nir_op_unpack_64_2x32;

	default:
	vtn_fail("No NIR equivalent");
	}
	}

	#define NIR_IMM_FP(n, v) (nir_imm_floatN_t(n, v, src[0]->bit_size))

	static void
	handle_glsl450_alu(struct vtn_builder *b, enum GLSLstd450 entrypoint,
	const uint32_t *w, unsigned count)
	{
	struct nir_builder *nb = &b->nb;
	const struct glsl_type *dest_type = vtn_get_type(b, w[1])->type;
	struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
	val->ssa = vtn_create_ssa_value(b, dest_type);

	/* Collect the various SSA sources */
	unsigned num_inputs = count - 5;
	nir_ssa_def *src[3] = { NULL, };
	for (unsigned i = 0; i < num_inputs; i++) {
	/* These are handled specially below */
	if (vtn_untyped_value(b, w[i + 5])->value_type == vtn_value_type_pointer)
	continue;

	src[i] = vtn_ssa_value(b, w[i + 5])->def;
	}

	switch (entrypoint) {
	case GLSLstd450Radians:
	val->ssa->def = nir_radians(nb, src[0]);
	return;
	case GLSLstd450Degrees:
	val->ssa->def = nir_degrees(nb, src[0]);
	return;
	case GLSLstd450Tan:
	val->ssa->def = nir_ftan(nb, src[0]);
	return;

	case GLSLstd450Modf: {
	nir_ssa_def *sign = nir_fsign(nb, src[0]);
	nir_ssa_def *abs = nir_fabs(nb, src[0]);
	val->ssa->def = nir_fmul(nb, sign, nir_ffract(nb, abs));
	nir_store_deref(nb, vtn_nir_deref(b, w[6]),
	nir_fmul(nb, sign, nir_ffloor(nb, abs)), 0xf);
	return;
	}

	case GLSLstd450ModfStruct: {
	nir_ssa_def *sign = nir_fsign(nb, src[0]);
	nir_ssa_def *abs = nir_fabs(nb, src[0]);
	vtn_assert(glsl_type_is_struct_or_ifc(val->ssa->type));
	val->ssa->elems[0]->def = nir_fmul(nb, sign, nir_ffract(nb, abs));
	val->ssa->elems[1]->def = nir_fmul(nb, sign, nir_ffloor(nb, abs));
	return;
	}

	case GLSLstd450Step:
	val->ssa->def = nir_sge(nb, src[1], src[0]);
	return;

	case GLSLstd450Length:
	val->ssa->def = nir_fast_length(nb, src[0]);
	return;
	case GLSLstd450Distance:
	val->ssa->def = nir_fast_distance(nb, src[0], src[1]);
	return;
	case GLSLstd450Normalize:
	val->ssa->def = nir_fast_normalize(nb, src[0]);
	return;

	case GLSLstd450Exp:
	val->ssa->def = nir_fexp(nb, src[0]);
	return;

	case GLSLstd450Log:
	val->ssa->def = nir_flog(nb, src[0]);
	return;

	case GLSLstd450FClamp:
	val->ssa->def = nir_fclamp(nb, src[0], src[1], src[2]);
	return;
	case GLSLstd450NClamp:
	nb->exact = true;
	val->ssa->def = nir_fclamp(nb, src[0], src[1], src[2]);
	nb->exact = false;
	return;
	case GLSLstd450UClamp:
	val->ssa->def = nir_uclamp(nb, src[0], src[1], src[2]);
	return;
	case GLSLstd450SClamp:
	val->ssa->def = nir_iclamp(nb, src[0], src[1], src[2]);
	return;

	case GLSLstd450Cross: {
	val->ssa->def = nir_cross3(nb, src[0], src[1]);
	return;
	}

	case GLSLstd450SmoothStep: {
	val->ssa->def = nir_smoothstep(nb, src[0], src[1], src[2]);
	return;
	}

	case GLSLstd450FaceForward:
	val->ssa->def =
	nir_bcsel(nb, nir_flt(nb, nir_fdot(nb, src[2], src[1]),
	NIR_IMM_FP(nb, 0.0)),
	src[0], nir_fneg(nb, src[0]));
	return;

	case GLSLstd450Reflect:
	/* I - 2 * dot(N, I) * N */
	val->ssa->def =
	nir_fsub(nb, src[0], nir_fmul(nb, NIR_IMM_FP(nb, 2.0),
	nir_fmul(nb, nir_fdot(nb, src[0], src[1]),
	src[1])));
	return;

	case GLSLstd450Refract: {
	nir_ssa_def *I = src[0];
	nir_ssa_def *N = src[1];
	nir_ssa_def *eta = src[2];
	nir_ssa_def *n_dot_i = nir_fdot(nb, N, I);
	nir_ssa_def *one = NIR_IMM_FP(nb, 1.0);
	nir_ssa_def *zero = NIR_IMM_FP(nb, 0.0);
	/* According to the SPIR-V and GLSL specs, eta is always a float
	* regardless of the type of the other operands. However in practice it
	* seems that if you try to pass it a float then glslang will just
	* promote it to a double and generate invalid SPIR-V. In order to
	* support a hypothetical fixed version of glslang we’ll promote eta to
	* double if the other operands are double also.
	*/
	if (I->bit_size != eta->bit_size) {
	nir_op conversion_op =
	nir_type_conversion_op(nir_type_float \| eta->bit_size,
	nir_type_float \| I->bit_size,
	nir_rounding_mode_undef);
	eta = nir_build_alu(nb, conversion_op, eta, NULL, NULL, NULL);
	}
	/* k = 1.0 - eta * eta * (1.0 - dot(N, I) * dot(N, I)) */
	nir_ssa_def *k =
	nir_fsub(nb, one, nir_fmul(nb, eta, nir_fmul(nb, eta,
	nir_fsub(nb, one, nir_fmul(nb, n_dot_i, n_dot_i)))));
	nir_ssa_def *result =
	nir_fsub(nb, nir_fmul(nb, eta, I),
	nir_fmul(nb, nir_fadd(nb, nir_fmul(nb, eta, n_dot_i),
	nir_fsqrt(nb, k)), N));
	/* XXX: bcsel, or if statement? */
	val->ssa->def = nir_bcsel(nb, nir_flt(nb, k, zero), zero, result);
	return;
	}

	case GLSLstd450Sinh:
	/* 0.5 * (e^x - e^(-x)) */
	val->ssa->def =
	nir_fmul_imm(nb, nir_fsub(nb, nir_fexp(nb, src[0]),
	nir_fexp(nb, nir_fneg(nb, src[0]))),
	0.5f);
	return;

	case GLSLstd450Cosh:
	/* 0.5 * (e^x + e^(-x)) */
	val->ssa->def =
	nir_fmul_imm(nb, nir_fadd(nb, nir_fexp(nb, src[0]),
	nir_fexp(nb, nir_fneg(nb, src[0]))),
	0.5f);
	return;

	case GLSLstd450Tanh: {
	/* tanh(x) := (e^x - e^(-x)) / (e^x + e^(-x))
	*
	* We clamp x to [-10, +10] to avoid precision problems. When x > 10,
	* e^x dominates the sum, e^(-x) is lost and tanh(x) is 1.0 for 32 bit
	* floating point.
	*
	* For 16-bit precision this we clamp x to [-4.2, +4.2].
	*/
	const uint32_t bit_size = src[0]->bit_size;
	const double clamped_x = bit_size > 16 ? 10.0 : 4.2;
	nir_ssa_def *x = nir_fclamp(nb, src[0],
	nir_imm_floatN_t(nb, -clamped_x, bit_size),
	nir_imm_floatN_t(nb, clamped_x, bit_size));
	val->ssa->def =
	nir_fdiv(nb, nir_fsub(nb, nir_fexp(nb, x),
	nir_fexp(nb, nir_fneg(nb, x))),
	nir_fadd(nb, nir_fexp(nb, x),
	nir_fexp(nb, nir_fneg(nb, x))));
	return;
	}

	case GLSLstd450Asinh:
	val->ssa->def = nir_fmul(nb, nir_fsign(nb, src[0]),
	nir_flog(nb, nir_fadd(nb, nir_fabs(nb, src[0]),
	nir_fsqrt(nb, nir_fadd_imm(nb, nir_fmul(nb, src[0], src[0]),
	1.0f)))));
	return;
	case GLSLstd450Acosh:
	val->ssa->def = nir_flog(nb, nir_fadd(nb, src[0],
	nir_fsqrt(nb, nir_fadd_imm(nb, nir_fmul(nb, src[0], src[0]),
	-1.0f))));
	return;
	case GLSLstd450Atanh: {
	nir_ssa_def *one = nir_imm_floatN_t(nb, 1.0, src[0]->bit_size);
	val->ssa->def =
	nir_fmul_imm(nb, nir_flog(nb, nir_fdiv(nb, nir_fadd(nb, src[0], one),
	nir_fsub(nb, one, src[0]))),
	0.5f);
	return;
	}

	case GLSLstd450Asin:
	val->ssa->def = build_asin(nb, src[0], 0.086566724, -0.03102955, true);
	return;

	case GLSLstd450Acos:
	val->ssa->def =
	nir_fsub(nb, nir_imm_floatN_t(nb, M_PI_2f, src[0]->bit_size),
	build_asin(nb, src[0], 0.08132463, -0.02363318, false));
	return;

	case GLSLstd450Atan:
	val->ssa->def = nir_atan(nb, src[0]);
	return;

	case GLSLstd450Atan2:
	val->ssa->def = nir_atan2(nb, src[0], src[1]);
	return;

	case GLSLstd450Frexp: {
	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));
	val->ssa->elems[0]->def = nir_frexp_sig(nb, src[0]);
	val->ssa->elems[1]->def = nir_frexp_exp(nb, src[0]);
	return;
	}

	default: {
	unsigned execution_mode =
	b->shader->info.float_controls_execution_mode;
	bool exact;
	nir_op op = vtn_nir_alu_op_for_spirv_glsl_opcode(b, entrypoint, execution_mode, &exact);
	b->nb.exact = exact;
	val->ssa->def = nir_build_alu(&b->nb, op, src[0], src[1], src[2], NULL);
	b->nb.exact = false;
	return;
	}
	}
	}

	static void
	handle_glsl450_interpolation(struct vtn_builder *b, enum GLSLstd450 opcode,
	const uint32_t *w, unsigned count)
	{
	const struct glsl_type *dest_type = vtn_get_type(b, w[1])->type;
	struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
	val->ssa = vtn_create_ssa_value(b, dest_type);

	nir_intrinsic_op op;
	switch (opcode) {
	case GLSLstd450InterpolateAtCentroid:
	op = nir_intrinsic_interp_deref_at_centroid;
	break;
	case GLSLstd450InterpolateAtSample:
	op = nir_intrinsic_interp_deref_at_sample;
	break;
	case GLSLstd450InterpolateAtOffset:
	op = nir_intrinsic_interp_deref_at_offset;
	break;
	default:
	vtn_fail("Invalid opcode");
	}

	nir_intrinsic_instr *intrin = nir_intrinsic_instr_create(b->nb.shader, op);

	struct vtn_pointer *ptr =
	vtn_value(b, w[5], vtn_value_type_pointer)->pointer;
	nir_deref_instr *deref = vtn_pointer_to_deref(b, ptr);

	/* If the value we are interpolating has an index into a vector then
	* interpolate the vector and index the result of that instead. This is
	* necessary because the index will get generated as a series of nir_bcsel
	* instructions so it would no longer be an input variable.
	*/
	const bool vec_array_deref = deref->deref_type == nir_deref_type_array &&
	glsl_type_is_vector(nir_deref_instr_parent(deref)->type);

	nir_deref_instr *vec_deref = NULL;
	if (vec_array_deref) {
	vec_deref = deref;
	deref = nir_deref_instr_parent(deref);
	}
	intrin->src[0] = nir_src_for_ssa(&deref->dest.ssa);

	switch (opcode) {
	case GLSLstd450InterpolateAtCentroid:
	break;
	case GLSLstd450InterpolateAtSample:
	case GLSLstd450InterpolateAtOffset:
	intrin->src[1] = nir_src_for_ssa(vtn_ssa_value(b, w[6])->def);
	break;
	default:
	vtn_fail("Invalid opcode");
	}

	intrin->num_components = glsl_get_vector_elements(deref->type);
	nir_ssa_dest_init(&intrin->instr, &intrin->dest,
	glsl_get_vector_elements(deref->type),
	glsl_get_bit_size(deref->type), NULL);

	nir_builder_instr_insert(&b->nb, &intrin->instr);

	if (vec_array_deref) {
	assert(vec_deref);
	val->ssa->def = nir_vector_extract(&b->nb, &intrin->dest.ssa,
	vec_deref->arr.index.ssa);
	} else {
	val->ssa->def = &intrin->dest.ssa;
	}
	}

	bool
	vtn_handle_glsl450_instruction(struct vtn_builder *b, SpvOp ext_opcode,
	const uint32_t *w, unsigned count)
	{
	switch ((enum GLSLstd450)ext_opcode) {
	case GLSLstd450Determinant: {
	struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
	val->ssa = rzalloc(b, struct vtn_ssa_value);
	val->ssa->type = vtn_get_type(b, w[1])->type;
	val->ssa->def = build_mat_det(b, vtn_ssa_value(b, w[5]));
	break;
	}

	case GLSLstd450MatrixInverse: {
	struct vtn_value *val = vtn_push_value(b, w[2], vtn_value_type_ssa);
	val->ssa = matrix_inverse(b, vtn_ssa_value(b, w[5]));
	break;
	}

	case GLSLstd450InterpolateAtCentroid:
	case GLSLstd450InterpolateAtSample:
	case GLSLstd450InterpolateAtOffset:
	handle_glsl450_interpolation(b, (enum GLSLstd450)ext_opcode, w, count);
	break;

	default:
	handle_glsl450_alu(b, (enum GLSLstd450)ext_opcode, w, count);
	}

	return true;
	}