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review.mlplatform.org / ml / ComputeLibrary / 73bb6b7ad80801e56633ad4ea12b0404b586a979 / . / src / core / experimental / dynamic_fusion / ClKernelBuildingImpl / Common.h
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/*
* Copyright (c) 2022 Arm Limited.
*
* SPDX-License-Identifier: MIT
*
* 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.
*/
#ifdef ENABLE_EXPERIMENTAL_DYNAMIC_FUSION
#ifndef ARM_COMPUTE_EXPERIMENTAL_DYNAMICFUSION_IMPL_COMMON_H
#define ARM_COMPUTE_EXPERIMENTAL_DYNAMICFUSION_IMPL_COMMON_H
#include "arm_compute/core/CL/CLCompileContext.h"
#include "arm_compute/core/CL/CLKernelLibrary.h"
#include "arm_compute/core/Error.h"
#include "arm_compute/core/GPUTarget.h"
#include "src/core/common/Macros.h"
#include "support/Requires.h"
#include "support/StringSupport.h"
#include "src/core/experimental/dynamic_fusion/ClKernelBuildingAPI.h"
#include <iostream>
#include <queue>
#include <stack>
#include <string>
#include <unordered_set>
namespace arm_compute
{
namespace experimental
{
namespace dynamic_fusion
{
/** We introduce the concept of *Shared Variables* in the context of kernel building.
* They are variables that can be accessed / shared among all the kernel components within a single kernel.
* For now we consider 2 groups of shared variables:
* Argument: The argument variables (parameters) of a kernel
* Automatic: The automatic variables declared inside a kernel
* All Shared Variables have the same kernel scope, and are thus visible to all kernel components
*/
enum class SharedVarIO
{
Input,
Output
};
enum class SharedVarGroup
{
Argument, // Parameters to a kernel function == dst or src tensors of the whole blueprint graph
Automatic // Automatic variables declared within the kernel body == intermediate tensors of the whole blueprint graph
};
/** Specifies a shared variable link for a component.
* It describes all the information that's available when a component is constructed / added:
* e.g. its linkage (via ArgumentID and io) and its group
* This is not shared variable on its own, but is used for instantiating a SharedVar when building the code
*/
struct SharedVarLink
{
ArgumentID arg_id{ g_arg_placeholder };
SharedVarIO io{ SharedVarIO::Input };
bool is_empty() const
{
return arg_id == g_arg_placeholder;
}
};
/** A table of all the variables used in the kernel / blueprint
* Because we limit the DependencyGraph in the blueprint to a Linear Sequence for now, we only allow ** a single global variable (the accumulator) **
*
* NOTE: the order they appear in the table is the order of their "declaration" in the component code, and is also their ID
* NOTE: the variables all have the scope of the full kernel function
*/
class SharedVarTable
{
public:
/** A fully realized SharedVarLink
*/
struct SharedVar
{
ArgumentID arg_id{ g_arg_placeholder };
SharedVarIO io{ SharedVarIO::Input };
SharedVarGroup group{ SharedVarGroup::Argument };
std::string uniq_name{}; // Unique name, also the final variable name used in the built code
ClKernelArgDescriptor desc{}; // Automatic variables can and should still be described using this struct
bool is_empty() const
{
return arg_id == g_arg_placeholder;
}
};
class Arguments
{
public:
Arguments() = default;
void add_var(const SharedVar &var)
{
ARM_COMPUTE_ERROR_ON(var.group != SharedVarGroup::Argument);
_vars.push_back(var);
}
std::vector<SharedVar> get_all_vars() const
{
return _vars;
}
std::vector<SharedVar> get_src_vars() const
{
std::vector<SharedVar> src_vars;
std::copy_if(_vars.begin(), _vars.end(), std::back_inserter(src_vars), [](const SharedVar & var)
{
return var.io == SharedVarIO::Input;
});
return src_vars;
}
SharedVar get_dst_var() const
{
std::vector<SharedVar> dst_vars;
std::copy_if(_vars.begin(), _vars.end(), std::back_inserter(dst_vars), [](const SharedVar & var)
{
return var.io == SharedVarIO::Output;
});
ARM_COMPUTE_ERROR_ON(dst_vars.size() != 1);
return dst_vars.at(0);
}
private:
std::vector<SharedVar> _vars{};
};
/** Create a SharedVar for a corresponding SharedVarLink (contains ArgumentID). If one has already been created for the SharedVarLink, simply return it instead of creating a new one
*
* @note: The order of insertion is important. There is one precondition:
* PRECOND: The components have been sorted topologically / is being traversed in topological order
* This ensures that all the consumer var links (Output, Automatic Links) can consume (return) the producer var links when they're referred
*/
void add(SharedVarLink var_link, SharedVarGroup group, ClKernelArgDescriptor runtime_desc, const std::string &name = "unnamed")
{
ARM_COMPUTE_ERROR_ON_MSG(var_link.is_empty(), "Non-empty SharedVarLink expected");
if(!get(var_link).is_empty())
{
return;
}
auto var_id = _num_var;
std::stringstream ss;
ss << name << "_" << var_id;
const auto uniq_name = ss.str();
SharedVar var{ var_link.arg_id, var_link.io, group, uniq_name, runtime_desc };
if(group == SharedVarGroup::Argument)
{
_arguments.emplace(var_id, var);
_arg_id_map.emplace(var_link.arg_id, var_id);
_num_var++;
}
else if(group == SharedVarGroup::Automatic)
{
if(_global_vars.empty())
{
if(var_link.io == SharedVarIO::Output)
{
_global_vars.emplace(var_id, var);
_arg_id_map.emplace(var_link.arg_id, var_id);
_num_var++;
}
else
{
ARM_COMPUTE_ERROR("Component likely not traversed in topological order");
}
}
else
{
// Associate additional SharedVarLinks with the single global shared variable
const auto global_var_id = _global_vars.begin()->first;
_arg_id_map[var_link.arg_id] = global_var_id;
}
}
else
{
ARM_COMPUTE_ERROR("Unrecognised SharedVarGroup");
}
}
/** Get the SharedVar associated with @p var_link
*
* @param var_link
* @return SharedVar
*/
SharedVar get(const SharedVarLink &var_link) const
{
const SharedVar empty_var{};
if(_arg_id_map.find(var_link.arg_id) != _arg_id_map.end())
{
const auto var_id = _arg_id_map.at(var_link.arg_id);
const auto arg_var = _arguments.find(var_id);
if(arg_var != _arguments.end())
{
return arg_var->second;
}
else
{
return _global_vars.at(var_id);
}
}
return empty_var;
}
/** @note The arguments are returned in the order they are added
*/
Arguments get_kernel_arguments() const
{
Arguments args{};
for(const auto &a : _arguments)
{
args.add_var(a.second);
}
return args;
}
private:
using VarID = int32_t;
private:
std::map<VarID, SharedVar> _global_vars{}; // Shared, global variable
std::map<VarID, SharedVar> _arguments{};
std::map<ArgumentID, VarID> _arg_id_map{}; // Track ArgumentIDs that have already been added
VarID _num_var{ 0 };
};
enum class ComponentType
{
Simple,
Complex,
Store
};
using ComponentID = DependencyGraph::Id;
using ComponentList = std::vector<ComponentID>;
class IClKernelComponent
{
public:
using Link = SharedVarLink;
using Tag = std::string;
struct TagVal
{
TagVal() = default;
TagVal(const SharedVarTable::SharedVar &var)
: value{ var.uniq_name }
{
}
template <typename T, ARM_COMPUTE_REQUIRES_TA(std::is_integral<T>::value)>
TagVal(T val)
: value{ support::cpp11::to_string(val) }
{
}
TagVal(const std::string &val)
: value{ val }
{
}
TagVal(const char *val)
: value{ std::string(val) }
{
}
TagVal(const DataType &data_type)
: value{ get_cl_type_from_data_type(data_type) }
{
}
std::string value{};
};
using TagLUT = std::unordered_map<Tag, TagVal>; // Used to instantiating a code template / replacing tags
public:
IClKernelComponent(ClKernelBlueprint *blueprint)
: _blueprint(blueprint)
{
}
ARM_COMPUTE_DISALLOW_COPY_ALLOW_MOVE(IClKernelComponent);
virtual ~IClKernelComponent() = default;
virtual ComponentType get_component_type() const = 0;
virtual std::vector<Link> get_links() const = 0;
virtual std::string name() const = 0;
// @note: some tags can be unused since they could be used only for the macros, or only for the component code
static std::string replace_tags(const std::string &code_template, const TagLUT &tags)
{
std::string replaced_code = "";
bool scanning_pattern = false;
std::string pattern_found = "";
for(size_t i = 0; i < code_template.size() - 1; ++i)
{
if(!scanning_pattern)
{
if(code_template[i] == '{' && code_template[i + 1] == '{')
{
i += 1;
scanning_pattern = true;
pattern_found = "";
}
else
{
replaced_code += code_template[i];
}
}
else
{
if(code_template[i] == '}' && code_template[i + 1] == '}')
{
i += 1;
scanning_pattern = false;
std::string err = "Pattern " + pattern_found + " not found in tags";
ARM_COMPUTE_ERROR_ON_MSG(tags.find(pattern_found) == tags.end(), err.c_str());
replaced_code += tags.find(pattern_found)->second.value;
}
else
{
pattern_found += code_template[i];
}
}
}
return replaced_code;
}
ComponentID id() const
{
return _id;
}
void set_id(ComponentID id)
{
_id = id;
}
virtual std::set<std::string> get_headers_list() const
{
return std::set<std::string> {};
}
virtual std::string get_additional_macros() const
{
return "";
}
virtual std::string get_component_code() const
{
return "";
}
virtual Window get_window() const
{
return Window{};
}
/** Get the tag look-up table used to instantiate the component code.
*
* @param vtable
* @return TagLUT
*/
virtual TagLUT get_tag_lut(const SharedVarTable &vtable) const = 0;
/** Allocate all shared variables used by the component in the @p vtable
*
* @param vtable
*/
virtual void allocate_shared_vars(SharedVarTable &vtable) const = 0;
virtual std::string get_dst_addr_calculation() const
{
return "";
}
/** Generate config id of the component
*
* @return std::string
*/
virtual std::string generate_config_id() const
{
return "";
}
virtual CLBuildOptions generate_build_options() const
{
return CLBuildOptions{};
}
protected:
ClKernelBlueprint *_blueprint;
private:
ComponentID _id{};
};
using ComponentUniquePtr = std::unique_ptr<IClKernelComponent>;
/** Intermediate representation of the final, complete kernel source.
*/
struct ClKernelBlueprint::Implementation
{
public:
Implementation() = default;
~Implementation() = default;
public:
Status update_merge_point(ArgumentID t_id, ArgumentID merge_point)
{
return _graph.update_merge_point(t_id, merge_point);
}
ArgumentID add_kernel_tensor(ITensorInfo *tensor_info, ArgumentID merge_point = DependencyGraph::empty_id())
{
const auto id = _graph.add_tensor(merge_point);
if(_kernel_tensors.find(id) == _kernel_tensors.end())
{
_kernel_tensors.insert(std::make_pair(id, tensor_info));
}
return id;
}
void set_tile_info(const TileDescriptor &tile_info)
{
_tile_info = tile_info;
}
SharedVarGroup group(ArgumentID arg_id) const
{
if(arg_id == g_arg_placeholder)
{
// In case of placeholder, don't care what we return;
return SharedVarGroup::Argument;
}
return _shared_var_group_lut.at(arg_id);
}
void validate_arg_ids(std::initializer_list<ArgumentID> args) const
{
for(const auto arg_id : args)
{
ARM_COMPUTE_UNUSED(arg_id);
ARM_COMPUTE_ERROR_ON_MSG(_kernel_tensors.find(arg_id) == _kernel_tensors.end() && arg_id != g_arg_placeholder,
"Trying to use an argument that hasn't been added to the blueprint");
}
}
void add_component(ComponentUniquePtr component)
{
if(component->get_component_type() == ComponentType::Complex)
{
++_num_complex_components;
ARM_COMPUTE_ERROR_ON_MSG(_num_complex_components > 1, "Only one complex component per blueprint is supported.");
}
// Get an unique ID for the component that's being added
std::vector<ArgumentID> src_tensors;
std::vector<ArgumentID> dst_tensors;
for(const auto &link : component->get_links())
{
if(link.is_empty())
{
continue;
}
if(link.io == SharedVarIO::Input)
{
src_tensors.push_back(link.arg_id);
}
else
{
dst_tensors.push_back(link.arg_id);
}
}
const ComponentID component_id = _graph.add_operator(src_tensors, dst_tensors).second;
component->set_id(component_id);
// Add this component to the component graph. Don't connect it to anything yet
_component_graph.emplace(component_id, ComponentList{});
// For every { arg_id, arg_io } passed along with this component...
for(const auto &link : component->get_links())
{
const ArgumentID &arg_id = link.arg_id;
const SharedVarIO &arg_io = link.io;
// Add the arg_id to the map describing the input/output relationship between an argument and the components that use it, if it doesn't yet exist there
if(_outgoing_components.find(arg_id) == _outgoing_components.end())
{
_outgoing_components.emplace(arg_id, ComponentList{});
_incoming_components.emplace(arg_id, ComponentList{});
}
// If it's an input argument, connect any other component that has it as output with this component
// Additionally, set this component as one that treats this argument as "Input" (append to index 0)
// This is used so that we keep track of whether two components use the same argument, one as input and one as output
if(arg_io == SharedVarIO::Input)
{
for(const auto &prev_component : _incoming_components[arg_id])
{
_component_graph[prev_component].push_back(component_id);
}
_outgoing_components[arg_id].push_back(component_id);
}
// If it's an output argument, connect this component with any other component that has it as input
// Additionally, set this component as one that treats this argument as "Output" (append to index 1)
else
{
if(component->get_component_type() == ComponentType::Store)
{
ARM_COMPUTE_ERROR_ON_MSG(_dst_id >= 0, "Trying to add more than one dst argument to the graph");
_dst_id = arg_id;
}
for(const auto &subseq_component : _outgoing_components[arg_id])
{
_component_graph[component_id].push_back(subseq_component);
}
_incoming_components[arg_id].push_back(component_id);
}
}
ARM_COMPUTE_ERROR_ON_MSG(_graph.get_root_ops().size() != 1, "Trying to add more than one root to the graph");
// Finally, add this component to the dictionary of components
_components.insert(std::make_pair(component_id, std::move(component)));
}
std::string build_kernel_name() const
{
std::string name = "";
traverse([&](std::stack<ComponentID> stack)
{
name += _components.find(stack.top())->second->name() + (stack.size() > 2 ? "___" : "");
});
return name;
}
std::string build_code()
{
ARM_COMPUTE_ERROR_ON_MSG(_graph_root == -1, "No root found in the component graph");
// These data structures will hold the data from all the components in the blueprint
std::set<std::string> headers_list{};
std::set<std::string> additional_macros{};
std::vector<std::string> component_codes{}; // vector because order matters
// Step 1: Allocate all kernel argument shared variables before generating the component code
auto stack = topological_sort();
while(!stack.empty())
{
auto curr_component_id = stack.top();
auto &curr_component = _components.find(curr_component_id)->second;
curr_component->allocate_shared_vars(_vtable);
stack.pop();
}
// Step 2: Generate component codes
stack = topological_sort();
while(!stack.empty())
{
auto curr_component_id = stack.top();
auto &curr_component = _components.find(curr_component_id)->second;
auto curr_headers_list = curr_component->get_headers_list();
auto curr_additional_macros = curr_component->get_additional_macros();
auto curr_component_code = curr_component->get_component_code();
const auto var_lut = curr_component->get_tag_lut(_vtable); // Ideally can be merged with get_component_code once we have finer-grained code generation technique
component_codes.push_back(IClKernelComponent::replace_tags(curr_component_code, var_lut));
headers_list.insert(curr_headers_list.begin(), curr_headers_list.end());
if(!curr_additional_macros.empty()) // Some components might not have any
{
additional_macros.insert(IClKernelComponent::replace_tags(curr_additional_macros, var_lut));
}
stack.pop();
}
// Step 3: Assemble the data gathered by traversing the graph into the string "code"
std::string code = "";
for(auto &header : headers_list)
{
#if defined(EMBEDDED_KERNELS)
code += CLKernelLibrary::get().get_program(header).first;
#else // defined(EMBEDDED_KERNELS)
code += "#include \"" + header + "\"\n";
#endif // defined(EMBEDDED_KERNELS)
}
for(auto &macros : additional_macros)
{
code += macros;
}
code += generate_kernel_signature(_vtable.get_kernel_arguments());
code += "\n{\n\n";
code += " //------------------ START KERNEL_BUILDER_COORDINATE ---------------------\n\n";
code += generate_global_section();
code += " //------------------ END KERNEL_BUILDER_COORDINATE ---------------------\n";
for(auto &component_code : component_codes)
{
code += component_code;
}
code += "}\n";
return code;
}
/** Generate config id of the entire kernel
*
* Format: kernel_name--comp0_config_id--comp1_config_id--...
*
* @return std::string
*/
std::string build_config_id() const
{
std::string config_id = build_kernel_name();
traverse([&](std::stack<ComponentID> stack)
{
config_id += "--" + _components.find(stack.top())->second->generate_config_id() + "--";
});
return config_id;
}
CLBuildOptions build_options() const
{
CLBuildOptions build_opts{};
traverse([&](std::stack<ComponentID> stack)
{
build_opts.add_options(_components.find(stack.top())->second->generate_build_options().options());
});
return build_opts;
}
TileDescriptor get_tile_info() const
{
return _tile_info;
}
// Get the global execution window, i.e. that of the root component
Window get_execution_window() const
{
ARM_COMPUTE_ERROR_ON_MSG(_graph_root == -1, "No root found in the component graph");
ARM_COMPUTE_ERROR_ON_MSG(_dst_id == -1, "Destination Tensor Id should be ready before calling get_execution_window()");
return _components.find(_graph_root)->second->get_window();
}
ArgumentID get_dst_id() const
{
return _dst_id;
}
ClKernelArgList get_arguments() const
{
ClKernelArgList arg_list{};
for(const auto &arg_var : _vtable.get_kernel_arguments().get_all_vars())
{
arg_list[arg_var.desc.arg_id] = arg_var.desc;
}
return arg_list;
}
/** Get the arguments as shared vars from the vtable
*
* @return SharedVarTable::Arguments
*/
SharedVarTable::Arguments get_argument_shared_vars() const
{
return _vtable.get_kernel_arguments();
}
const ITensorInfo *get_kernel_argument_info(const ArgumentID id) const
{
auto it = _kernel_tensors.find(id);
if(it != _kernel_tensors.end())
{
return it->second;
}
return nullptr;
}
ITensorInfo *get_kernel_argument_info(const ArgumentID id)
{
auto it = _kernel_tensors.find(id);
if(it != _kernel_tensors.end())
{
return it->second;
}
return nullptr;
}
/** Finalize graph construction. Graph is expected to not mutate after being finalized
*/
void finalize()
{
cache_root_component();
assign_shared_var_group();
}
DependencyGraph get_graph() const
{
return _graph;
}
private:
void cache_root_component()
{
const auto roots = _graph.get_root_ops();
ARM_COMPUTE_ERROR_ON_MSG(roots.size() != 1, "Trying to add more than one root to the graph");
_graph_root = roots.at(0);
}
/** Assign the group for each shared var. Can only be performed at the end of the graph construction, before building
*/
void assign_shared_var_group()
{
for(const auto &tensor : _kernel_tensors)
{
const auto tensor_id = tensor.first;
if(_graph.is_src_tensor(tensor_id) || _graph.is_dst_tensor(tensor_id))
{
_shared_var_group_lut[tensor_id] = SharedVarGroup::Argument;
}
else
{
_shared_var_group_lut[tensor_id] = SharedVarGroup::Automatic;
}
}
}
void topological_sort_utility(ComponentID component_id, std::unordered_set<ComponentID> &visited, std::stack<ComponentID> &stack) const
{
visited.insert(component_id);
for(auto connected_component : _component_graph.find(component_id)->second)
{
if(visited.find(connected_component) == visited.end())
{
topological_sort_utility(connected_component, visited, stack);
}
}
stack.push(component_id);
}
std::stack<ComponentID> topological_sort() const
{
std::stack<ComponentID> stack{};
std::unordered_set<ComponentID> visited{};
topological_sort_utility(_graph_root, visited, stack);
return stack;
}
void traverse(const std::function<void(std::stack<ComponentID>)> &func) const
{
std::stack<ComponentID> stack = topological_sort();
while(!stack.empty())
{
func(stack);
stack.pop();
}
}
std::string generate_argument_declaration(const SharedVarTable::SharedVar &var) const
{
ARM_COMPUTE_ERROR_ON_MSG(var.group != SharedVarGroup::Argument, "An argument declaration can only be generated from a kernel argument");
std::string code;
switch(var.desc.tensor_arg_type)
{
case ClKernelTensorArgType::Vector:
{
code += "\n VECTOR_DECLARATION(" + var.uniq_name + ")";
break;
}
case ClKernelTensorArgType::Image:
{
code += "\n IMAGE_DECLARATION(" + var.uniq_name + ")";
break;
}
case ClKernelTensorArgType::Image_3D:
{
code += "\n IMAGE_DECLARATION(" + var.uniq_name + "),";
code += "\n uint " + var.uniq_name + "_stride_z";
break;
}
case ClKernelTensorArgType::Image_3D_Export_To_ClImage2D:
{
code += "\n __read_only image2d_t " + var.uniq_name + "_img,";
code += "\n uint " + var.uniq_name + "_stride_z";
break;
}
case ClKernelTensorArgType::Tensor_4D_t_Buffer:
{
code += "\n TENSOR4D_T(" + var.uniq_name + ", BUFFER)";
break;
}
case ClKernelTensorArgType::Tensor_4D_t_Image:
{
code += "\n TENSOR4D_T(" + var.uniq_name + ", IMAGE)";
break;
}
default:
{
ARM_COMPUTE_ERROR("Unsupported declaration generation for ClKernelTensorArgType");
}
}
return code;
}
std::string generate_kernel_signature(const SharedVarTable::Arguments &argument_list) const
{
std::string code = "\n__kernel void " + build_kernel_name() + "(";
for(const auto &arg : argument_list.get_all_vars())
{
code += generate_argument_declaration(arg) + ",";
}
code[code.length() - 1] = ')';
return code;
}
std::string generate_global_section() const
{
auto dst_info = get_kernel_argument_info(_dst_id);
auto dst_w = dst_info->dimension(0);
const auto tile_w = std::max(1, get_execution_window().x().step());
const auto tile_h = std::max(1, get_execution_window().y().step());
auto leftover_w = dst_w % tile_w;
std::string code = "";
code += std::string(" int cout = GET_SPATIAL_IDX(0, ") + std::to_string(tile_w) + ", " + std::to_string(leftover_w) + ");\n";
code += std::string(" int mout = GET_SPATIAL_IDX(1, ") + std::to_string(tile_h) + ", " + "0);\n";
code += std::string(" int bout = GET_SPATIAL_IDX(2, 1, 0);\n\n");
switch(_tile_info.clipping)
{
case ClippingStrategy::TOP_LEFT:
code += " const bool g_cond_x = (cout == 0);\n";
code += " const bool g_cond_y = (mout == 0);\n";
break;
case ClippingStrategy::TOP_RIGHT:
code += " const bool g_cond_x = ((cout + 1) * " + std::to_string(tile_w) + " >= " + std::to_string(_tile_info.boundaries.x()) + ");\n";
code += " const bool g_cond_y = (mout == 0);\n";
break;
case ClippingStrategy::BOTTOM_LEFT:
code += " const bool g_cond_x = (cout == 0);\n";
code += " const bool g_cond_y = ((mout + 1) * " + std::to_string(tile_h) + " >= " + std::to_string(_tile_info.boundaries.y()) + ");\n";
break;
case ClippingStrategy::BOTTOM_RIGHT:
code += " const bool g_cond_x = ((cout + 1) * " + std::to_string(tile_w) + " >= " + std::to_string(_tile_info.boundaries.x()) + ");\n";
code += " const bool g_cond_y = ((mout + 1) * " + std::to_string(tile_h) + " >= " + std::to_string(_tile_info.boundaries.y()) + ");\n";
break;
default:
ARM_COMPUTE_ERROR("Unsupported clipping strategy");
}
return code;
}
TileDescriptor _tile_info{};
int32_t _num_complex_components{};
ArgumentID _dst_id{ -1 }; // Initially set to -1, which means the graph has no dst yet, since node IDs are positive numbers
DependencyGraph _graph{};
// Tensors, components and IDs with corresponding ptrs (except intermediate)
std::unordered_map<ComponentID, ComponentUniquePtr> _components{};
std::unordered_map<ArgumentID, ITensorInfo *> _kernel_tensors{};
// Argument group lookup. Can be replaced by extending the ArgumentID type to include group info
std::unordered_map<ArgumentID, SharedVarGroup> _shared_var_group_lut{};
// Tracks all variables (e.g.: kernel arguments, kernel "global variables")
SharedVarTable _vtable{};
// Component directed graph (represented by an adjecency list of Component IDs)
// This is used to understand the ordering and bindings between components when generating the kernel
// It's initially set to -1 which means the graph has no root yet, since node IDs are positive numbers
ComponentID _graph_root{ -1 };
std::unordered_map<ComponentID, ComponentList> _component_graph{};
// Additional data structures used to define the relationships between components and arguments
// For each argument, it contains the list of components that consider it as an incoming or an outgoing argument
// E.g. tensor0 -> component0 -> tensor1
// _outgoing_components[tensor0] == {component0} (component0 is the outgoing component of tensor0. Component0 treats tensor0 as an input tensor)
// _incoming_components[tensor1] == {component0} (component0 is the incoming component of tensor1. Component1 treats tensor1 as an output tensor)
std::unordered_map<ArgumentID, ComponentList> _outgoing_components{};
std::unordered_map<ArgumentID, ComponentList> _incoming_components{};
};
} // namespace dynamic_fusion
} // namespace experimental
} // namespace arm_compute
#endif //ARM_COMPUTE_EXPERIMENTAL_DYNAMICFUSION_IMPL_COMMON_H
#endif /* ENABLE_EXPERIMENTAL_DYNAMIC_FUSION */