ispc/builtins/target-avx.ll

;;  Copyright (c) 2010-2015, Intel Corporation
;;  All rights reserved.
;;
;;  Redistribution and use in source and binary forms, with or without
;;  modification, are permitted provided that the following conditions are
;;  met:
;;
;;    * Redistributions of source code must retain the above copyright
;;      notice, this list of conditions and the following disclaimer.
;;
;;    * Redistributions in binary form must reproduce the above copyright
;;      notice, this list of conditions and the following disclaimer in the
;;      documentation and/or other materials provided with the distribution.
;;
;;    * Neither the name of Intel Corporation nor the names of its
;;      contributors may be used to endorse or promote products derived from
;;      this software without specific prior written permission.
;;
;;
;;   THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
;;   IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
;;   TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
;;   PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
;;   OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
;;   EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
;;   PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
;;   PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
;;   LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
;;   NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
;;   SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.  

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Basic 8-wide definitions

define(`WIDTH',`8')
define(`MASK',`i32')
include(`util.m4')

stdlib_core()
packed_load_and_store()
scans()
int64minmax()

include(`target-avx-common.ll')

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; rcp

declare <8 x float> @llvm.x86.avx.rcp.ps.256(<8 x float>) nounwind readnone

define <8 x float> @__rcp_varying_float(<8 x float>) nounwind readonly alwaysinline {
  ; do one N-R iteration to improve precision
  ;  float iv = __rcp_v(v);
  ;  return iv * (2. - v * iv);
  %call = call <8 x float> @llvm.x86.avx.rcp.ps.256(<8 x float> %0)
  %v_iv = fmul <8 x float> %0, %call
  %two_minus = fsub <8 x float> <float 2., float 2., float 2., float 2.,
                                 float 2., float 2., float 2., float 2.>, %v_iv  
  %iv_mul = fmul <8 x float> %call, %two_minus
  ret <8 x float> %iv_mul
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; rsqrt

declare <8 x float> @llvm.x86.avx.rsqrt.ps.256(<8 x float>) nounwind readnone

define <8 x float> @__rsqrt_varying_float(<8 x float> %v) nounwind readonly alwaysinline {
  ;  float is = __rsqrt_v(v);
  %is = call <8 x float> @llvm.x86.avx.rsqrt.ps.256(<8 x float> %v)
  ; Newton-Raphson iteration to improve precision
  ;  return 0.5 * is * (3. - (v * is) * is);
  %v_is = fmul <8 x float> %v, %is
  %v_is_is = fmul <8 x float> %v_is, %is
  %three_sub = fsub <8 x float> <float 3., float 3., float 3., float 3.,
                                 float 3., float 3., float 3., float 3.>, %v_is_is
  %is_mul = fmul <8 x float> %is, %three_sub
  %half_scale = fmul <8 x float> <float 0.5, float 0.5, float 0.5, float 0.5,
                                  float 0.5, float 0.5, float 0.5, float 0.5>, %is_mul
  ret <8 x float> %half_scale
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; sqrt

declare <8 x float> @llvm.x86.avx.sqrt.ps.256(<8 x float>) nounwind readnone

define <8 x float> @__sqrt_varying_float(<8 x float>) nounwind readonly alwaysinline {
  %call = call <8 x float> @llvm.x86.avx.sqrt.ps.256(<8 x float> %0)
  ret <8 x float> %call
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; double precision sqrt

declare <4 x double> @llvm.x86.avx.sqrt.pd.256(<4 x double>) nounwind readnone

define <8 x double> @__sqrt_varying_double(<8 x double>) nounwind alwaysinline {
  unary4to8(ret, double, @llvm.x86.avx.sqrt.pd.256, %0)
  ret <8 x double> %ret
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; rounding floats

declare <8 x float> @llvm.x86.avx.round.ps.256(<8 x float>, i32) nounwind readnone

define <8 x float> @__round_varying_float(<8 x float>) nounwind readonly alwaysinline {
  ; roundps, round mode nearest 0b00 | don't signal precision exceptions 0b1000 = 8
  %call = call <8 x float> @llvm.x86.avx.round.ps.256(<8 x float> %0, i32 8)
  ret <8 x float> %call
}

define <8 x float> @__floor_varying_float(<8 x float>) nounwind readonly alwaysinline {
  ; roundps, round down 0b01 | don't signal precision exceptions 0b1001 = 9
  %call = call <8 x float> @llvm.x86.avx.round.ps.256(<8 x float> %0, i32 9)
  ret <8 x float> %call
}

define <8 x float> @__ceil_varying_float(<8 x float>) nounwind readonly alwaysinline {
  ; roundps, round up 0b10 | don't signal precision exceptions 0b1010 = 10
  %call = call <8 x float> @llvm.x86.avx.round.ps.256(<8 x float> %0, i32 10)
  ret <8 x float> %call
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; rounding doubles

declare <4 x double> @llvm.x86.avx.round.pd.256(<4 x double>, i32) nounwind readnone

define <8 x double> @__round_varying_double(<8 x double>) nounwind readonly alwaysinline {
  round4to8double(%0, 8)
}

define <8 x double> @__floor_varying_double(<8 x double>) nounwind readonly alwaysinline {
  ; roundpd, round down 0b01 | don't signal precision exceptions 0b1001 = 9
  round4to8double(%0, 9)
}

define <8 x double> @__ceil_varying_double(<8 x double>) nounwind readonly alwaysinline {
  ; roundpd, round up 0b10 | don't signal precision exceptions 0b1010 = 10
  round4to8double(%0, 10)
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; float min/max

declare <8 x float> @llvm.x86.avx.max.ps.256(<8 x float>, <8 x float>) nounwind readnone
declare <8 x float> @llvm.x86.avx.min.ps.256(<8 x float>, <8 x float>) nounwind readnone

define <8 x float> @__max_varying_float(<8 x float>,
                                        <8 x float>) nounwind readonly alwaysinline {
  %call = call <8 x float> @llvm.x86.avx.max.ps.256(<8 x float> %0, <8 x float> %1)
  ret <8 x float> %call
}

define <8 x float> @__min_varying_float(<8 x float>,
                                        <8 x float>) nounwind readonly alwaysinline {
  %call = call <8 x float> @llvm.x86.avx.min.ps.256(<8 x float> %0, <8 x float> %1)
  ret <8 x float> %call
}


;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; double precision min/max

declare <4 x double> @llvm.x86.avx.max.pd.256(<4 x double>, <4 x double>) nounwind readnone
declare <4 x double> @llvm.x86.avx.min.pd.256(<4 x double>, <4 x double>) nounwind readnone

define <8 x double> @__min_varying_double(<8 x double>, <8 x double>) nounwind readnone alwaysinline {
  binary4to8(ret, double, @llvm.x86.avx.min.pd.256, %0, %1)
  ret <8 x double> %ret
}

define <8 x double> @__max_varying_double(<8 x double>, <8 x double>) nounwind readnone alwaysinline {
  binary4to8(ret, double, @llvm.x86.avx.max.pd.256, %0, %1)
  ret <8 x double> %ret
}


;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; svml

include(`svml.m4')
;; single precision
svml_declare(float,f8,8)
svml_define(float,f8,8,f)

;; double precision
svml_declare(double,4,4)
svml_define_x(double,4,4,d,8)


;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; mask handling

declare i32 @llvm.x86.avx.movmsk.ps.256(<8 x float>) nounwind readnone

define i64 @__movmsk(<8 x i32>) nounwind readnone alwaysinline {
  %floatmask = bitcast <8 x i32> %0 to <8 x float>
  %v = call i32 @llvm.x86.avx.movmsk.ps.256(<8 x float> %floatmask) nounwind readnone
  %v64 = zext i32 %v to i64
  ret i64 %v64
}

define i1 @__any(<8 x i32>) nounwind readnone alwaysinline {
  %floatmask = bitcast <8 x i32> %0 to <8 x float>
  %v = call i32 @llvm.x86.avx.movmsk.ps.256(<8 x float> %floatmask) nounwind readnone
  %cmp = icmp ne i32 %v, 0
  ret i1 %cmp
}

define i1 @__all(<8 x i32>) nounwind readnone alwaysinline {
  %floatmask = bitcast <8 x i32> %0 to <8 x float>
  %v = call i32 @llvm.x86.avx.movmsk.ps.256(<8 x float> %floatmask) nounwind readnone
  %cmp = icmp eq i32 %v, 255
  ret i1 %cmp
}

define i1 @__none(<8 x i32>) nounwind readnone alwaysinline {
  %floatmask = bitcast <8 x i32> %0 to <8 x float>
  %v = call i32 @llvm.x86.avx.movmsk.ps.256(<8 x float> %floatmask) nounwind readnone
  %cmp = icmp eq i32 %v, 0
  ret i1 %cmp
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal ops / reductions

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal float ops

declare <8 x float> @llvm.x86.avx.hadd.ps.256(<8 x float>, <8 x float>) nounwind readnone

define float @__reduce_add_float(<8 x float>) nounwind readonly alwaysinline {
  %v1 = call <8 x float> @llvm.x86.avx.hadd.ps.256(<8 x float> %0, <8 x float> %0)
  %v2 = call <8 x float> @llvm.x86.avx.hadd.ps.256(<8 x float> %v1, <8 x float> %v1)
  %scalar1 = extractelement <8 x float> %v2, i32 0
  %scalar2 = extractelement <8 x float> %v2, i32 4
  %sum = fadd float %scalar1, %scalar2
  ret float %sum
}

define float @__reduce_min_float(<8 x float>) nounwind readnone alwaysinline {
  reduce8(float, @__min_varying_float, @__min_uniform_float)
}

define float @__reduce_max_float(<8 x float>) nounwind readnone alwaysinline {
  reduce8(float, @__max_varying_float, @__max_uniform_float)
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal double ops

declare <4 x double> @llvm.x86.avx.hadd.pd.256(<4 x double>, <4 x double>) nounwind readnone

define double @__reduce_add_double(<8 x double>) nounwind readonly alwaysinline {
  %v0 = shufflevector <8 x double> %0, <8 x double> undef,
                      <4 x i32> <i32 0, i32 1, i32 2, i32 3>
  %v1 = shufflevector <8 x double> %0, <8 x double> undef,
                      <4 x i32> <i32 4, i32 5, i32 6, i32 7>
  %sum0 = call <4 x double> @llvm.x86.avx.hadd.pd.256(<4 x double> %v0, <4 x double> %v1)
  %sum1 = call <4 x double> @llvm.x86.avx.hadd.pd.256(<4 x double> %sum0, <4 x double> %sum0)
  %final0 = extractelement <4 x double> %sum1, i32 0
  %final1 = extractelement <4 x double> %sum1, i32 2
  %sum = fadd double %final0, %final1

  ret double %sum
}

define double @__reduce_min_double(<8 x double>) nounwind readnone alwaysinline {
  reduce8(double, @__min_varying_double, @__min_uniform_double)
}

define double @__reduce_max_double(<8 x double>) nounwind readnone alwaysinline {
  reduce8(double, @__max_varying_double, @__max_uniform_double)
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal int8 ops

declare <2 x i64> @llvm.x86.sse2.psad.bw(<16 x i8>, <16 x i8>) nounwind readnone

define i16 @__reduce_add_int8(<8 x i8>) nounwind readnone alwaysinline {
  %wide8 = shufflevector <8 x i8> %0, <8 x i8> zeroinitializer,
      <16 x i32> <i32 0, i32 1, i32 2, i32 3, i32 4, i32 5, i32 6, i32 7,
                  i32 8, i32 8, i32 8, i32 8, i32 8, i32 8, i32 8, i32 8>
  %rv = call <2 x i64> @llvm.x86.sse2.psad.bw(<16 x i8> %wide8,
                                              <16 x i8> zeroinitializer)
  %r0 = extractelement <2 x i64> %rv, i32 0
  %r1 = extractelement <2 x i64> %rv, i32 1
  %r = add i64 %r0, %r1
  %r16 = trunc i64 %r to i16
  ret i16 %r16
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal int16 ops

define internal <8 x i16> @__add_varying_i16(<8 x i16>,
                                  <8 x i16>) nounwind readnone alwaysinline {
  %r = add <8 x i16> %0, %1
  ret <8 x i16> %r
}

define internal i16 @__add_uniform_i16(i16, i16) nounwind readnone alwaysinline {
  %r = add i16 %0, %1
  ret i16 %r
}

define i16 @__reduce_add_int16(<8 x i16>) nounwind readnone alwaysinline {
  reduce8(i16, @__add_varying_i16, @__add_uniform_i16)
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal int32 ops

;; helper functions
define <8 x i32> @__add_varying_int32(<8 x i32>,
                                      <8 x i32>) nounwind readnone alwaysinline {
  %s = add <8 x i32> %0, %1
  ret <8 x i32> %s
}

define i32 @__add_uniform_int32(i32, i32) nounwind readnone alwaysinline {
  %s = add i32 %0, %1
  ret i32 %s
}

;; reduction functions
define i32 @__reduce_add_int32(<8 x i32>) nounwind readnone alwaysinline {
  reduce8(i32, @__add_varying_int32, @__add_uniform_int32)
}

define i32 @__reduce_min_int32(<8 x i32>) nounwind readnone alwaysinline {
  reduce8(i32, @__min_varying_int32, @__min_uniform_int32)
}

define i32 @__reduce_max_int32(<8 x i32>) nounwind readnone alwaysinline {
  reduce8(i32, @__max_varying_int32, @__max_uniform_int32)
}

define i32 @__reduce_min_uint32(<8 x i32>) nounwind readnone alwaysinline {
  reduce8(i32, @__min_varying_uint32, @__min_uniform_uint32)
}

define i32 @__reduce_max_uint32(<8 x i32>) nounwind readnone alwaysinline {
  reduce8(i32, @__max_varying_uint32, @__max_uniform_uint32)
}


;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; horizontal int64 ops

;; helper functions
define <8 x i64> @__add_varying_int64(<8 x i64>,
                                      <8 x i64>) nounwind readnone alwaysinline {
  %s = add <8 x i64> %0, %1
  ret <8 x i64> %s
}

define i64 @__add_uniform_int64(i64, i64) nounwind readnone alwaysinline {
  %s = add i64 %0, %1
  ret i64 %s
}

;; reduction functions
define i64 @__reduce_add_int64(<8 x i64>) nounwind readnone alwaysinline {
  reduce8(i64, @__add_varying_int64, @__add_uniform_int64)
}


define i64 @__reduce_min_int64(<8 x i64>) nounwind readnone alwaysinline {
  reduce8(i64, @__min_varying_int64, @__min_uniform_int64)
}


define i64 @__reduce_max_int64(<8 x i64>) nounwind readnone alwaysinline {
  reduce8(i64, @__max_varying_int64, @__max_uniform_int64)
}


define i64 @__reduce_min_uint64(<8 x i64>) nounwind readnone alwaysinline {
  reduce8(i64, @__min_varying_uint64, @__min_uniform_uint64)
}


define i64 @__reduce_max_uint64(<8 x i64>) nounwind readnone alwaysinline {
  reduce8(i64, @__max_varying_uint64, @__max_uniform_uint64)
}

reduce_equal(8)

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; unaligned loads/loads+broadcasts


; no masked load instruction for i8 and i16 types??
masked_load(i8,  1)
masked_load(i16, 2)

declare <8 x float> @llvm.x86.avx.maskload.ps.256(i8 *, <8 x MfORi32> %mask)
declare <4 x double> @llvm.x86.avx.maskload.pd.256(i8 *, <4 x MdORi64> %mask)
 
define <8 x i32> @__masked_load_i32(i8 *, <8 x i32> %mask) nounwind alwaysinline {
  %floatmask = bitcast <8 x i32> %mask to <8 x MfORi32>
  %floatval = call <8 x float> @llvm.x86.avx.maskload.ps.256(i8 * %0, <8 x MfORi32> %floatmask)
  %retval = bitcast <8 x float> %floatval to <8 x i32>
  ret <8 x i32> %retval
}


define <8 x i64> @__masked_load_i64(i8 *, <8 x i32> %mask) nounwind alwaysinline {
  ; double up masks, bitcast to doubles
  %mask0 = shufflevector <8 x i32> %mask, <8 x i32> undef,
     <8 x i32> <i32 0, i32 0, i32 1, i32 1, i32 2, i32 2, i32 3, i32 3>
  %mask1 = shufflevector <8 x i32> %mask, <8 x i32> undef,
     <8 x i32> <i32 4, i32 4, i32 5, i32 5, i32 6, i32 6, i32 7, i32 7>
  %mask0d = bitcast <8 x i32> %mask0 to <4 x MdORi64>
  %mask1d = bitcast <8 x i32> %mask1 to <4 x MdORi64>

  %val0d = call <4 x double> @llvm.x86.avx.maskload.pd.256(i8 * %0, <4 x MdORi64> %mask0d)
  %ptr1 = getelementptr PTR_OP_ARGS(`i8') %0, i32 32
  %val1d = call <4 x double> @llvm.x86.avx.maskload.pd.256(i8 * %ptr1, <4 x MdORi64> %mask1d)

  %vald = shufflevector <4 x double> %val0d, <4 x double> %val1d,
      <8 x i32> <i32 0, i32 1, i32 2, i32 3, i32 4, i32 5, i32 6, i32 7>
  %val = bitcast <8 x double> %vald to <8 x i64>
  ret <8 x i64> %val
}

masked_load_float_double()

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; masked store

gen_masked_store(i8)
gen_masked_store(i16)

; note that mask is the 2nd parameter, not the 3rd one!!
declare void @llvm.x86.avx.maskstore.ps.256(i8 *, <8 x MfORi32>, <8 x float>)
declare void @llvm.x86.avx.maskstore.pd.256(i8 *, <4 x MdORi64>, <4 x double>)

define void @__masked_store_i32(<8 x i32>* nocapture, <8 x i32>, 
                                <8 x i32>) nounwind alwaysinline {
  %ptr = bitcast <8 x i32> * %0 to i8 *
  %val = bitcast <8 x i32> %1 to <8 x float>
  %mask = bitcast <8 x i32> %2 to <8 x MfORi32>
  call void @llvm.x86.avx.maskstore.ps.256(i8 * %ptr, <8 x MfORi32> %mask, <8 x float> %val)
  ret void
}

define void @__masked_store_i64(<8 x i64>* nocapture, <8 x i64>,
                                <8 x i32> %mask) nounwind alwaysinline {
  %ptr = bitcast <8 x i64> * %0 to i8 *
  %val = bitcast <8 x i64> %1 to <8 x double>

  %mask0 = shufflevector <8 x i32> %mask, <8 x i32> undef,
     <8 x i32> <i32 0, i32 0, i32 1, i32 1, i32 2, i32 2, i32 3, i32 3>
  %mask1 = shufflevector <8 x i32> %mask, <8 x i32> undef,
     <8 x i32> <i32 4, i32 4, i32 5, i32 5, i32 6, i32 6, i32 7, i32 7>

  %mask0d = bitcast <8 x i32> %mask0 to <4 x MdORi64>
  %mask1d = bitcast <8 x i32> %mask1 to <4 x MdORi64>

  %val0 = shufflevector <8 x double> %val, <8 x double> undef,
     <4 x i32> <i32 0, i32 1, i32 2, i32 3>
  %val1 = shufflevector <8 x double> %val, <8 x double> undef,
     <4 x i32> <i32 4, i32 5, i32 6, i32 7>

  call void @llvm.x86.avx.maskstore.pd.256(i8 * %ptr, <4 x MdORi64> %mask0d, <4 x double> %val0)
  %ptr1 = getelementptr PTR_OP_ARGS(`i8') %ptr, i32 32
  call void @llvm.x86.avx.maskstore.pd.256(i8 * %ptr1, <4 x MdORi64> %mask1d, <4 x double> %val1)
  ret void
}

masked_store_float_double()

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; masked store blend

masked_store_blend_8_16_by_8()

declare <8 x float> @llvm.x86.avx.blendv.ps.256(<8 x float>, <8 x float>,
                                                <8 x float>) nounwind readnone

define void @__masked_store_blend_i32(<8 x i32>* nocapture, <8 x i32>, 
                                      <8 x i32>) nounwind alwaysinline {
  %mask_as_float = bitcast <8 x i32> %2 to <8 x float>
  %oldValue = load PTR_OP_ARGS(`<8 x i32>')  %0, align 4
  %oldAsFloat = bitcast <8 x i32> %oldValue to <8 x float>
  %newAsFloat = bitcast <8 x i32> %1 to <8 x float>
  %blend = call <8 x float> @llvm.x86.avx.blendv.ps.256(<8 x float> %oldAsFloat,
                                                        <8 x float> %newAsFloat,
                                                        <8 x float> %mask_as_float)
  %blendAsInt = bitcast <8 x float> %blend to <8 x i32>
  store <8 x i32> %blendAsInt, <8 x i32>* %0, align 4
  ret void
}


define void @__masked_store_blend_i64(<8 x i64>* nocapture %ptr, <8 x i64> %new, 
                                      <8 x i32> %i32mask) nounwind alwaysinline {
  %oldValue = load PTR_OP_ARGS(`<8 x i64>')  %ptr, align 8
  %mask = bitcast <8 x i32> %i32mask to <8 x float>

  ; Do 4x64-bit blends by doing two <8 x i32> blends, where the <8 x i32> values
  ; are actually bitcast <4 x i64> values
  ;
  ; set up the first four 64-bit values
  %old01  = shufflevector <8 x i64> %oldValue, <8 x i64> undef,
                          <4 x i32> <i32 0, i32 1, i32 2, i32 3>
  %old01f = bitcast <4 x i64> %old01 to <8 x float>
  %new01  = shufflevector <8 x i64> %new, <8 x i64> undef,
                          <4 x i32> <i32 0, i32 1, i32 2, i32 3>
  %new01f = bitcast <4 x i64> %new01 to <8 x float>
  ; compute mask--note that the indices are all doubled-up
  %mask01 = shufflevector <8 x float> %mask, <8 x float> undef,
                          <8 x i32> <i32 0, i32 0, i32 1, i32 1,
                                     i32 2, i32 2, i32 3, i32 3>
  ; and blend them
  %result01f = call <8 x float> @llvm.x86.avx.blendv.ps.256(<8 x float> %old01f,
                                                            <8 x float> %new01f,
                                                            <8 x float> %mask01)
  %result01 = bitcast <8 x float> %result01f to <4 x i64>

  ; and again
  %old23  = shufflevector <8 x i64> %oldValue, <8 x i64> undef,
                          <4 x i32> <i32 4, i32 5, i32 6, i32 7>
  %old23f = bitcast <4 x i64> %old23 to <8 x float>
  %new23  = shufflevector <8 x i64> %new, <8 x i64> undef,
                          <4 x i32> <i32 4, i32 5, i32 6, i32 7>
  %new23f = bitcast <4 x i64> %new23 to <8 x float>
  ; compute mask--note that the values are doubled-up...
  %mask23 = shufflevector <8 x float> %mask, <8 x float> undef,
                          <8 x i32> <i32 4, i32 4, i32 5, i32 5,
                                     i32 6, i32 6, i32 7, i32 7>
  ; and blend them
  %result23f = call <8 x float> @llvm.x86.avx.blendv.ps.256(<8 x float> %old23f,
                                                            <8 x float> %new23f,
                                                            <8 x float> %mask23)
  %result23 = bitcast <8 x float> %result23f to <4 x i64>

  ; reconstruct the final <8 x i64> vector
  %final = shufflevector <4 x i64> %result01, <4 x i64> %result23,
                         <8 x i32> <i32 0, i32 1, i32 2, i32 3,
                                    i32 4, i32 5, i32 6, i32 7>
  store <8 x i64> %final, <8 x i64> * %ptr, align 8
  ret void
}

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; scatter

gen_scatter(i8)
gen_scatter(i16)
gen_scatter(i32)
gen_scatter(float)
gen_scatter(i64)
gen_scatter(double)

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; reciprocals in double precision, if supported

rsqrtd_decl()
rcpd_decl()

transcendetals_decl()
trigonometry_decl()