Merge branch 'develop' of github.com:ROCmSoftwarePlatform/AMDMIGraphX into refactor_dynamic_compute

b76a9043 · charlie · 68c17b1b · 66bbff1e · b76a9043 · b76a9043
Commit b76a9043 authored Sep 26, 2022 by charlie
13 changed files
--- a/src/targets/gpu/kernels/include/migraphx/kernels/layernorm.hpp
+++ b/src/targets/gpu/kernels/include/migraphx/kernels/layernorm.hpp
@@ -43,7 +43,7 @@ template <index_int Axis,
          class Input2,
          class... Inputs>
 __device__ void generic_binary_layernorm(
-    F compute, BinOp op, Output output, Input1 input1, Input2 input2, Inputs... inputs)
+    F compute, BinOp op, float eps, Output output, Input1 input1, Input2 input2, Inputs... inputs)
 {
    using reduce_output = reduce::with_axis<Input1, Axis>;
    reduce::block::run<reduce_output>([&](auto, auto r) {
@@ -55,32 +55,34 @@ __device__ void generic_binary_layernorm(
                return make_array(x, x * x) * vec_type<value_type>{1.0 / relements};
            })(input1, input2);

-        auto mean_x   = means[0];
-        auto mean_x2  = means[1];
-        auto variance = mean_x2 - (mean_x * mean_x);
+        auto mean_x        = means[0];
+        auto mean_x2       = means[1];
+        auto variance      = mean_x2 - (mean_x * mean_x);
+        value_type eps_val = eps; // implicit conversion for eps

        r.inner([&](auto& y, auto x1, auto x2, auto... xs) {
            auto x = op(x1, x2);
            auto m = x - mean_x;
-            // m * rsqrt(mean(m ^ 2) + 1e-12)
-            y = compute(m * rsqrt(variance + value_type{1e-12}), xs...);
+
+            // m * rsqrt(mean(m ^ 2) + epsilon)
+            y = compute(m * rsqrt(variance + eps_val), xs...);
        })(output, input1, input2, inputs...);
    });
 }

 template <index_int Axis, class F, class Output, class Input, class... Inputs>
-__device__ void layernorm(F compute, Output output, Input input, Inputs... inputs)
+__device__ void layernorm(F compute, float eps, Output output, Input input, Inputs... inputs)
 {
    generic_binary_layernorm<Axis>(
-        compute, [](auto x, auto) { return x; }, output, input, input, inputs...);
+        compute, [](auto x, auto) { return x; }, eps, output, input, input, inputs...);
 }

 template <index_int Axis, class F, class Output, class Input1, class Input2, class... Inputs>
 __device__ void
-add_layernorm(F compute, Output output, Input1 input1, Input2 input2, Inputs... inputs)
+add_layernorm(F compute, float eps, Output output, Input1 input1, Input2 input2, Inputs... inputs)
 {
    generic_binary_layernorm<Axis>(
-        compute, [](auto x1, auto x2) { return x1 + x2; }, output, input1, input2, inputs...);
+        compute, [](auto x1, auto x2) { return x1 + x2; }, eps, output, input1, input2, inputs...);
 }

 } // namespace migraphx

--- a/src/targets/gpu/lowering.cpp
+++ b/src/targets/gpu/lowering.cpp
@@ -104,54 +104,10 @@ struct miopen_apply

        offload_copy = (mod->name() == "main") ? pass->offload_copy : false;

-        add_generic_op("acos");
-        add_generic_op("acosh");
-        add_generic_op("add");
-        add_generic_op("asin");
-        add_generic_op("asinh");
-        add_generic_op("atan");
-        add_generic_op("atanh");
-        add_generic_op("ceil");
        add_generic_op("contiguous");
-        add_generic_op("cos");
-        add_generic_op("cosh");
-        add_generic_op("div");
-        add_generic_op("equal");
-        add_generic_op("erf");
-        add_generic_op("exp");
-        add_generic_op("floor");
-        add_generic_op("greater");
-        add_generic_op("less");
-        add_generic_op("log");
-        add_generic_op("logical_and");
-        add_generic_op("logical_or");
-        add_generic_op("logical_xor");
-        add_generic_op("max");
-        add_generic_op("min");
-        add_generic_op("mul");
-        add_generic_op("not");
-        add_generic_op("pow");
-        add_generic_op("prelu");
-        add_generic_op("recip");
-        add_generic_op("relu");
-        add_generic_op("round");
-        add_generic_op("rsqrt");
-        add_generic_op("sigmoid");
-        add_generic_op("sign");
-        add_generic_op("sin");
-        add_generic_op("sinh");
-        add_generic_op("sqdiff");
-        add_generic_op("sqrt");
-        add_generic_op("sub");
-        add_generic_op("tan");
-        add_generic_op("tanh");
-        add_generic_op("where");
-
-        add_extend_op("abs");
+
        add_extend_op("argmax");
        add_extend_op("argmin");
-        add_extend_op("clip");
-        add_extend_op("convert");
        add_extend_op("elu");
        add_extend_op("gather");
        add_extend_op("leaky_relu");

--- a/src/targets/gpu/prefuse_ops.cpp
+++ b/src/targets/gpu/prefuse_ops.cpp
@@ -35,6 +35,12 @@ namespace {
 template <class Derived, std::size_t N>
 struct layernorm_base
 {
+    float epsilon = 1e-12f;
+    template <class Self, class F>
+    static auto reflect(Self& self, F f)
+    {
+        return pack(f(self.epsilon, "epsilon"));
+    }
    shape compute_shape(std::vector<shape> inputs, std::vector<module_ref> mods) const
    {
        std::size_t nargs = 1;
@@ -62,6 +68,7 @@ struct layernorm_base

 struct layernorm : layernorm_base<layernorm, 0>
 {
+
    std::string name() const { return "gpu::prelayernorm"; }
 };
 MIGRAPHX_REGISTER_OP(layernorm);
@@ -80,8 +87,9 @@ struct find_layernorm
    {
        auto ins   = r.result;
        auto x_ins = r.instructions["x"];
+        auto eps   = r.instructions["eps"]->eval().at<float>();

-        m.replace_instruction(ins, layernorm{}, x_ins);
+        m.replace_instruction(ins, layernorm{eps}, x_ins);
    }
 };

@@ -96,8 +104,9 @@ struct find_add_layernorm
    {
        auto ins     = r.result;
        auto add_ins = r.instructions["add"];
+        auto eps     = r.instructions["eps"]->eval().at<float>();

-        m.replace_instruction(ins, add_layernorm{}, add_ins->inputs());
+        m.replace_instruction(ins, add_layernorm{eps}, add_ins->inputs());
    }
 };
 } // namespace

--- a/src/targets/gpu/quant_convolution.cpp
+++ b/src/targets/gpu/quant_convolution.cpp
@@ -22,7 +22,6 @@
 * THE SOFTWARE.
 */
 #include <migraphx/gpu/quant_convolution.hpp>
-#include <migraphx/gpu/device/convert.hpp>
 #include <migraphx/gpu/context.hpp>
 #include <migraphx/generate.hpp>


--- a/src/targets/gpu/softmax.cpp
+++ b/src/targets/gpu/softmax.cpp
-/*
- * The MIT License (MIT)
- *
- * Copyright (c) 2015-2022 Advanced Micro Devices, Inc. All rights reserved.
- *
- * 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 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 <migraphx/gpu/softmax.hpp>
-#include <migraphx/gpu/device/softmax.hpp>
-#include <migraphx/gpu/context.hpp>
-#include <migraphx/tune_axis.hpp>
-
-namespace migraphx {
-inline namespace MIGRAPHX_INLINE_NS {
-namespace gpu {
-
-shape hip_softmax::compute_shape(const std::vector<shape>& inputs) const
-{
-    check_shapes{inputs, *this}.has(2).standard();
-    return op.normalize_compute_shape({inputs.at(0)});
-}
-
-argument hip_softmax::compute(context& ctx, const shape&, const std::vector<argument>& args) const
-{
-    auto n_dim      = args.front().get_shape().lens().size();
-    auto tuned_axis = tune_axis(n_dim, op.axis, op.name());
-    device::softmax(ctx.get_stream().get(), args.back(), args.front(), tuned_axis);
-    return args.back();
-}
-
-} // namespace gpu
-} // namespace MIGRAPHX_INLINE_NS
-} // namespace migraphx
--- a/src/tf/tf_parser.cpp
+++ b/src/tf/tf_parser.cpp
@@ -347,7 +347,7 @@ void tf_parser::parse_node(const std::string& name)
                // input was from a node with multiple outputs
                if(contains(input_name, ':'))
                {
-                    input_name = input_name.substr(0, input.find(':'));
+                    input_name.resize(input.find(':'));
                }
                else
                {

--- a/test/gpu/adjust_allocation.cpp
+++ b/test/gpu/adjust_allocation.cpp
@@ -40,6 +40,10 @@
 #include <migraphx/make_op.hpp>
 #include <basic_ops.hpp>
 #include <test.hpp>
+#include "make_precompile_op.hpp"
+
+// Treat some operators as compilable to enable lowering
+MIGRAPHX_GPU_TEST_PRECOMPILE("add", "mul", "convert")

 void run_lowering(migraphx::program& p, bool offload_copy = false)
 {
@@ -118,7 +122,7 @@ TEST_CASE(no_copy_dead_param)
        auto xb = mm->add_instruction(migraphx::make_op("hip::allocate", {{"shape", to_value(s)}}));
        auto gx = mm->add_instruction(migraphx::make_op("hip::copy_to_gpu"), x, xb);
        auto ab = mm->add_instruction(migraphx::make_op("hip::allocate", {{"shape", to_value(s)}}));
-        auto sum = mm->add_instruction(migraphx::make_op("gpu::add"), gx, gx, ab);
+        auto sum = mm->add_instruction(make_precompile_op("add"), gx, gx, ab);
        auto r   = mm->add_instruction(migraphx::make_op("hip::copy_from_gpu"), sum);
        mm->add_return({r});


--- a/src/targets/gpu/device/gelu.cpp
+++ b/src/targets/gpu/device/gelu.cpp
@@ -21,63 +21,46 @@
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */
-#include <migraphx/gpu/device/gelu.hpp>
-#include <migraphx/gpu/device/nary.hpp>
-#include <migraphx/gpu/device/types.hpp>
-#include <cmath>
+#ifndef MIGRAPHX_GUARD_TEST_GPU_MAKE_PRECOMPILE_OP_HPP
+#define MIGRAPHX_GUARD_TEST_GPU_MAKE_PRECOMPILE_OP_HPP

-namespace migraphx {
-inline namespace MIGRAPHX_INLINE_NS {
-namespace gpu {
-namespace device {
+#include <migraphx/operation.hpp>
+#include <migraphx/gpu/compiler.hpp>
+#include <migraphx/make_op.hpp>

-// x * 0.5 * (1.0 + erf(x / sqrt(2.0)))
-template <class T>
-auto gelu_fn(T x) __device__
-{
-    return x * 0.5 * (1 + ::erf(x * M_SQRT1_2));
-}
+// NOLINTNEXTLINE
+#define MIGRAPHX_GPU_TEST_PRECOMPILE(...)                                \
+    struct test_compiler : migraphx::gpu::compiler<test_compiler>        \
+    {                                                                    \
+        std::vector<std::string> names() const { return {__VA_ARGS__}; } \
+                                                                         \
+        template <class... Ts>                                           \
+        migraphx::operation compile_op(Ts&&...) const                    \
+        {                                                                \
+            MIGRAPHX_THROW("Not compilable");                            \
+        }                                                                \
+                                                                         \
+        template <class... Ts>                                           \
+        migraphx::gpu::compiler_replace compile(Ts&&...) const           \
+        {                                                                \
+            MIGRAPHX_THROW("Not compilable");                            \
+        }                                                                \
+    };

-// 0.5 * x * (1 + tanh(sqrt(2 / pi) * (x + 0.044715 * pow(x, 3))))
-template <class T>
-auto gelu_fn_new(T x) __device__
+inline migraphx::operation make_precompile_op(migraphx::rank<0>, const migraphx::operation& op)
 {
-    return 0.5 * x * (1 + tanh(sqrt(M_2_PI) * (x + 0.044715 * x * x * x)));
+    return migraphx::make_op("gpu::precompile_op", {{"op", migraphx::to_value(op)}});
 }

-void gelu(hipStream_t stream, const argument& result, const argument& arg)
+inline migraphx::operation make_precompile_op(migraphx::rank<1>, const std::string& name)
 {
-    nary(stream, result, arg)([](auto x) __device__ { return gelu_fn(to_hip_type(x)); });
+    return make_precompile_op(migraphx::rank<0>{}, migraphx::make_op(name));
 }

-void gelu_new(hipStream_t stream, const argument& result, const argument& arg)
-{
-    nary(stream, result, arg)([](auto x) __device__ { return gelu_fn_new(to_hip_type(x)); });
-}
-
-void add_gelu(hipStream_t stream,
-              const argument& result,
-              const argument& arg1,
-              const argument& arg2)
-{
-    nary(stream, result, arg1, arg2)([](auto x, auto y) __device__ {
-        auto sum = to_hip_type(x + y);
-        return gelu_fn(sum);
-    });
-}
-
-void add_gelu_new(hipStream_t stream,
-                  const argument& result,
-                  const argument& arg1,
-                  const argument& arg2)
+template <class T>
+auto make_precompile_op(const T& x)
 {
-    nary(stream, result, arg1, arg2)([](auto x, auto y) __device__ {
-        auto sum = to_hip_type(x + y);
-        return gelu_fn(sum);
-    });
+    return make_precompile_op(migraphx::rank<1>{}, x);
 }

-} // namespace device
-} // namespace gpu
-} // namespace MIGRAPHX_INLINE_NS
-} // namespace migraphx
+#endif // MIGRAPHX_GUARD_TEST_GPU_MAKE_PRECOMPILE_OP_HPP
--- a/test/gpu/pack_int8_args.cpp
+++ b/test/gpu/pack_int8_args.cpp
@@ -38,6 +38,10 @@
 #include <migraphx/pass_manager.hpp>
 #include <migraphx/make_op.hpp>
 #include <test.hpp>
+#include "make_precompile_op.hpp"
+
+// Treat some operators as compilable to enable lowering
+MIGRAPHX_GPU_TEST_PRECOMPILE("add", "mul", "convert")

 void run_passes(migraphx::module& m)
 {
@@ -116,9 +120,8 @@ TEST_CASE(quant_dot)
            m.add_instruction(migraphx::make_op("gpu::contiguous"), beta_broadcast, beta_alloc);
        auto mul_alloc = m.add_instruction(
            migraphx::make_op("hip::allocate", {{"shape", migraphx::to_value(m3_shape)}}));
-        auto m3_beta =
-            m.add_instruction(migraphx::make_op("gpu::mul"), l3, beta_contiguous, mul_alloc);
-        auto gemm_add = m.add_instruction(migraphx::make_op("gpu::add"), gemm, m3_beta, output);
+        auto m3_beta = m.add_instruction(make_precompile_op("mul"), l3, beta_contiguous, mul_alloc);
+        auto gemm_add = m.add_instruction(make_precompile_op("add"), gemm, m3_beta, output);
        m.add_return({gemm_add});

        return m;
@@ -187,21 +190,23 @@ TEST_CASE(quant_dot_trans)
        // back result to int8
        auto tl1_convert_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(alpha_contiguous->get_shape())}}));
-        auto tl1_convert       = m.add_instruction(
-            migraphx::make_op("gpu::convert", {{"target_type", alpha->get_shape().type()}}),
-            conta,
-            tl1_convert_alloc);
-        auto mul_alloc       = m.add_instruction(migraphx::make_op(
+        auto tl1_convert =
+            m.add_instruction(make_precompile_op(migraphx::make_op(
+                                  "convert", {{"target_type", alpha->get_shape().type()}})),
+                              conta,
+                              tl1_convert_alloc);
+        auto mul_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(tl1_convert->get_shape())}}));
-        auto tl1_alpha_int32 = m.add_instruction(
-            migraphx::make_op("gpu::mul"), alpha_contiguous, tl1_convert, mul_alloc);
+        auto tl1_alpha_int32 =
+            m.add_instruction(make_precompile_op("mul"), alpha_contiguous, tl1_convert, mul_alloc);
        // convert mul_res to int8
        auto tl1_alpha_int8_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(conta->get_shape())}}));
-        auto tl1_alpha_int8       = m.add_instruction(
-            migraphx::make_op("gpu::convert", {{"target_type", conta->get_shape().type()}}),
-            tl1_alpha_int32,
-            tl1_alpha_int8_alloc);
+        auto tl1_alpha_int8 =
+            m.add_instruction(make_precompile_op(migraphx::make_op(
+                                  "convert", {{"target_type", conta->get_shape().type()}})),
+                              tl1_alpha_int32,
+                              tl1_alpha_int8_alloc);

        auto packb = contb;
        if(int8_x4)
@@ -306,9 +311,8 @@ TEST_CASE(quant_dot_pad)
            m.add_instruction(migraphx::make_op("gpu::contiguous"), beta_broadcast, beta_alloc);
        auto mul_alloc = m.add_instruction(
            migraphx::make_op("hip::allocate", {{"shape", migraphx::to_value(s3)}}));
-        auto m3_beta =
-            m.add_instruction(migraphx::make_op("gpu::mul"), l3, beta_contiguous, mul_alloc);
-        auto gemm_add = m.add_instruction(migraphx::make_op("gpu::add"), gemm, m3_beta, output);
+        auto m3_beta = m.add_instruction(make_precompile_op("mul"), l3, beta_contiguous, mul_alloc);
+        auto gemm_add = m.add_instruction(make_precompile_op("add"), gemm, m3_beta, output);
        m.add_return({gemm_add});
        return m;
    };
@@ -396,14 +400,15 @@ TEST_CASE(quant_dot_trans_pad)
        // back result to int8
        auto tl1_convert_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(alpha_contiguous->get_shape())}}));
-        auto tl1_convert       = m.add_instruction(
-            migraphx::make_op("gpu::convert", {{"target_type", alpha->get_shape().type()}}),
-            conta,
-            tl1_convert_alloc);
-        auto mul_alloc       = m.add_instruction(migraphx::make_op(
+        auto tl1_convert =
+            m.add_instruction(make_precompile_op(migraphx::make_op(
+                                  "convert", {{"target_type", alpha->get_shape().type()}})),
+                              conta,
+                              tl1_convert_alloc);
+        auto mul_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(tl1_convert->get_shape())}}));
-        auto tl1_alpha_int32 = m.add_instruction(
-            migraphx::make_op("gpu::mul"), alpha_contiguous, tl1_convert, mul_alloc);
+        auto tl1_alpha_int32 =
+            m.add_instruction(make_precompile_op("mul"), alpha_contiguous, tl1_convert, mul_alloc);
        // convert mul_res to int8
        auto tl1_alpha_int8_alloc = m.add_instruction(migraphx::make_op(
            "hip::allocate", {{"shape", migraphx::to_value(conta->get_shape())}}));
@@ -415,10 +420,11 @@ TEST_CASE(quant_dot_trans_pad)
                migraphx::make_op("hip::allocate", {{"shape", migraphx::to_value(ps1)}}));
        }

-        auto tl1_alpha_int8 = m.add_instruction(
-            migraphx::make_op("gpu::convert", {{"target_type", conta->get_shape().type()}}),
-            tl1_alpha_int32,
-            tl1_alpha_int8_alloc);
+        auto tl1_alpha_int8 =
+            m.add_instruction(make_precompile_op(migraphx::make_op(
+                                  "convert", {{"target_type", conta->get_shape().type()}})),
+                              tl1_alpha_int32,
+                              tl1_alpha_int8_alloc);

        auto pa = tl1_alpha_int8;
        if(int8_x4)

--- a/test/memory_coloring_test.cpp
+++ b/test/memory_coloring_test.cpp
@@ -724,7 +724,7 @@ TEST_CASE(test39)

    auto sub_modules = p.get_modules();
    std::reverse(sub_modules.begin(), sub_modules.end());
-    for(auto& smod : sub_modules)
+    for(const auto& smod : sub_modules)
    {
        run_pass(*smod);
    }

--- a/test/ref_ops_test.cpp
+++ b/test/ref_ops_test.cpp
@@ -3663,7 +3663,7 @@ TEST_CASE(multinomial_test)
    result.visit([&](auto output) { result_vec.assign(output.begin(), output.end()); });

    std::vector<int> res_dist(5, 0);
-    for(auto& r : result_vec)
+    for(const auto& r : result_vec)
        res_dist[r]++;
    auto dist_sum     = std::accumulate(dist.begin(), dist.end(), 0);
    auto res_dist_sum = std::accumulate(res_dist.begin(), res_dist.end(), 0);

--- a/test/simplify_algebra_test.cpp
+++ b/test/simplify_algebra_test.cpp
@@ -236,6 +236,105 @@ TEST_CASE(simplify_mul_conv1)
    EXPECT(new_conv->outputs().front()->name() != "mul");
 }

+TEST_CASE(simplify_mul_conv2)
+{
+    migraphx::module m;
+    auto x = m.add_parameter("x", {migraphx::shape::int32_type, {1, 128, 28, 28}});
+    auto w =
+        m.add_literal(migraphx::generate_literal({migraphx::shape::int32_type, {256, 128, 3, 3}}));
+    auto conv = m.add_instruction(
+        migraphx::make_op("convolution",
+                          {{"padding", {1, 1}}, {"stride", {2, 2}}, {"dilation", {1, 1}}}),
+        x,
+        w);
+    auto a      = m.add_literal(migraphx::generate_literal({migraphx::shape::int32_type, {256}}));
+    auto unsq_a = m.add_instruction(migraphx::make_op("unsqueeze", {{"axes", {1, 2}}}), a);
+    auto b      = m.add_instruction(
+        migraphx::make_op("multibroadcast", {{"out_lens", {1, 256, 14, 14}}}), unsq_a);
+    auto mul = m.add_instruction(migraphx::make_op("mul"), conv, b);
+    m.add_instruction(pass_op{}, mul);
+    EXPECT(conv->outputs().front()->name() == "mul");
+    run_pass(m);
+    auto new_conv =
+        std::find_if(m.begin(), m.end(), [](auto&& ins) { return ins.name() == "convolution"; });
+    EXPECT(new_conv->outputs().front()->name() != "mul");
+}
+
+// len = 1 case
+TEST_CASE(simplify_mul_conv3)
+{
+    migraphx::module m;
+    auto x = m.add_parameter("x", {migraphx::shape::int32_type, {1, 128, 28, 28}});
+    auto w =
+        m.add_literal(migraphx::generate_literal({migraphx::shape::int32_type, {256, 128, 3, 3}}));
+    auto conv = m.add_instruction(
+        migraphx::make_op("convolution",
+                          {{"padding", {1, 1}}, {"stride", {2, 2}}, {"dilation", {1, 1}}}),
+        x,
+        w);
+    auto a = m.add_literal(
+        migraphx::generate_literal({migraphx::shape::int32_type, {256, 1, 1}, {1, 18, 1}}));
+    auto b =
+        m.add_instruction(migraphx::make_op("multibroadcast", {{"out_lens", {1, 256, 14, 14}}}), a);
+    auto mul = m.add_instruction(migraphx::make_op("mul"), conv, b);
+    m.add_instruction(pass_op{}, mul);
+    EXPECT(conv->outputs().front()->name() == "mul");
+    run_pass(m);
+    auto new_conv =
+        std::find_if(m.begin(), m.end(), [](auto&& ins) { return ins.name() == "convolution"; });
+    EXPECT(new_conv->outputs().front()->name() != "mul");
+}
+
+// Previously broadcasted literal case, should skip
+TEST_CASE(simplify_mul_conv_skip1)
+{
+    migraphx::module m;
+    auto x = m.add_parameter("x", {migraphx::shape::int32_type, {1, 128, 28, 28}});
+    auto w =
+        m.add_literal(migraphx::generate_literal({migraphx::shape::int32_type, {256, 128, 3, 3}}));
+    auto conv = m.add_instruction(
+        migraphx::make_op("convolution",
+                          {{"padding", {1, 1}}, {"stride", {2, 2}}, {"dilation", {1, 1}}}),
+        x,
+        w);
+    auto a = m.add_literal(
+        migraphx::generate_literal({migraphx::shape::int32_type, {256, 14, 14}, {1, 0, 0}}));
+    auto b = m.add_instruction(
+        migraphx::make_op("broadcast", {{"axis", 1}, {"out_lens", {1, 256, 14, 14}}}), a);
+    auto mul = m.add_instruction(migraphx::make_op("mul"), conv, b);
+    m.add_instruction(pass_op{}, mul);
+    EXPECT(conv->outputs().front()->name() == "mul");
+    run_pass(m);
+    auto new_conv =
+        std::find_if(m.begin(), m.end(), [](auto&& ins) { return ins.name() == "convolution"; });
+    EXPECT(new_conv->outputs().front()->name() == "mul");
+}
+
+// Another previously broadcasted literal case, should skip
+TEST_CASE(simplify_mul_conv_skip2)
+{
+    migraphx::module m;
+    auto x = m.add_parameter("x", {migraphx::shape::int32_type, {1, 128, 28, 28}});
+    auto w =
+        m.add_literal(migraphx::generate_literal({migraphx::shape::int32_type, {256, 128, 3, 3}}));
+    auto conv = m.add_instruction(
+        migraphx::make_op("convolution",
+                          {{"padding", {1, 1}}, {"stride", {2, 2}}, {"dilation", {1, 1}}}),
+        x,
+        w);
+    auto a = m.add_literal(
+        migraphx::generate_literal({migraphx::shape::int32_type, {256, 14, 14}, {1, 0, 0}}));
+    auto b =
+        m.add_instruction(migraphx::make_op("multibroadcast", {{"out_lens", {1, 256, 14, 14}}}), a);
+    auto mul = m.add_instruction(migraphx::make_op("mul"), conv, b);
+    m.add_instruction(pass_op{}, mul);
+    EXPECT(conv->outputs().front()->name() == "mul");
+    run_pass(m);
+    auto new_conv =
+        std::find_if(m.begin(), m.end(), [](auto&& ins) { return ins.name() == "convolution"; });
+    EXPECT(new_conv->outputs().front()->name() == "mul");
+}
+
 TEST_CASE(simplify_mul_slice_conv1)
 {
    migraphx::module m1;

--- a/test/verify/test_layernorm.cpp
+++ b/test/verify/test_layernorm.cpp
@@ -29,14 +29,16 @@

 #include <migraphx/op/reduce_mean.hpp>

-migraphx::instruction_ref
-add_layernorm(migraphx::module& m, migraphx::instruction_ref x, std::vector<size_t> dims)
+migraphx::instruction_ref add_layernorm(migraphx::module& m,
+                                        migraphx::instruction_ref x,
+                                        std::vector<size_t> dims,
+                                        float eps = 1e-12f)
 {
    auto scale =
        m.add_parameter("scale", migraphx::shape{migraphx::shape::float_type, {dims.back()}});
    auto bias =
        m.add_parameter("bias", migraphx::shape{migraphx::shape::float_type, {dims.back()}});
-    auto epsilon  = m.add_literal(1e-12f);
+    auto epsilon  = m.add_literal(eps);
    auto exponent = m.add_literal(2.0f);

    auto mean = m.add_instruction(migraphx::op::reduce_mean({2}), x);
@@ -88,6 +90,19 @@ struct test_layernorm2 : verify_program<test_layernorm2>
    }
 };

+struct test_layernorm_eps : verify_program<test_layernorm_eps>
+{
+    migraphx::program create_program() const
+    {
+        migraphx::program p;
+        auto* mm                 = p.get_main_module();
+        std::vector<size_t> dims = {1, 2, 5};
+        auto x = mm->add_parameter("x", migraphx::shape{migraphx::shape::float_type, dims});
+        add_layernorm(*mm, x, dims, 1e-5f);
+        return p;
+    }
+};
+
 struct test_layernorm_triadd : verify_program<test_layernorm_triadd>
 {
    migraphx::program create_program() const