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A optimized CUDA C++ code generation engine for rigid body dynamics algorithms and their analytical gradients.

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GRiDCodeGenerator

A optimized CUDA C++ code generation engine for rigid body dynamics algorithms and their analytical gradients.

This package is written in Python and outputs CUDA C++ code. Helper functions have been written to speed up the algorithm implementation process and are detailed below. If your favorite rigid body dynamics algorithm is not yet implemented please either submit a PR to this repo with the code generation implementation or simply submit a PR to our rbdReference package with the Python implementation and we'll then try to get a GPU implementation designed as soon as possible.

Usage:

This package relies on an already parsed robot object from our URDFParser package.

GRiDCodeGenerator = GRiDCodeGenerator(robot, DEBUG_MODE = False)
GRiDCodeGenerator.gen_all_code()

A file named grid.cuh will be written to the current working directory and can then be included into your project. See the wrapper GRiD package for more instructions on how to use and test this code.

Instalation Instructions:

The only external dependencies needed to run this package are numpy,sympy which can be automatically installed by running:

pip3 install -r requirements.txt

This package also depends on our URDFParser package.

Running the CUDA C++ code output by the GRiDCodegenerator also requires CUDA to be installed on your system. Please see the README.md in the GRID wrapper package for instalation notes for CUDA.

C++ API

To enable GRiD to be used by both expert and novice GPU programmers we provide the following API interface for each rigid body dynamics algorithm:

  • ALGORITHM_inner: a device function that computes the core computation. These functions assume that inputs are already loaded into GPU shared memory, require a pointer to additional scratch shared memory, and store the result back in shared memory.
  • ALGORITHM_device: a device function that handles the shared memory allocation for the \_inner function. These functions assume that inputs are already loaded into, and return results to, GPU shared memory.
  • ALGORITHM_kernel: a kernel that handles the shared memory allocation for the \_inner function. These functions assume that inputs are loaded into, and return results to, the global GPU memory.
  • ALGORITHM: a host function that wraps the _kernel and handles the transfer of inputs to the GPU and the results back to the CPU.

Code Generation API

For each algorithm (written as a _algorithm.py file in the algorithms folder) the following functions are generally written:

  • gen_algorithm_temp_mem_size: returns a Python number noting the shared memory array size needed for all temporary variables
  • gen_algorithm_function_call: generates a function call for that algorithm and is intended to be used inside other algorithms
  • gen_algorithm_inner: generates a device function which computes the core computation. These functions assume that inputs are already loaded into GPU shared memory, require a pointer to additional scratch shared memory, and store the result back in shared memory.
  • gen_algorithm_device: generates a device function which handles the shared memory allocation for the _inner function. These functions still assume that inputs are already loaded into, and return results to, GPU shared memory.
  • gen_algorithm_kernel: generates a a kernel that handles the shared memory allocation for the _inner function. These functions assume that input are loaded into, and return results to, the global GPU memory.
  • gen_algorithm_host: generates a host function that wraps the _kernel and handles the transfer of inputs to the GPU and the results back to the CPU.
  • gen_algorithm: runs all of the above mention function generators

Codegeneration helper functions are as follows:

Note: most functions assume inputs are strings and are located in the helpers folder in the _code_generation_helpers.py file (and a few are also found in the _topology_helpers.py and _spatial_algebra_helpers.py files)

  • Add a string or list of strings of code with gen_add_code_line(new_code_line, add_indent_after = False) and gen_add_code_lines(new_code_lines, add_indent_after = False)
  • Reduce the global indentation level and insert a close brace with gen_add_end_control_flow() and gen_add_end_function()
  • Add a Doxygen formatted function description with gen_add_func_doc(description string, notes = [], params = [], return_val = None)
  • Ensure that a block of code is only run by one thread per block gen_add_serial_ops(use_thread_group = False) and make sure to end this control flow later
  • Run a block of code with N parallel threads or blocks gen_add_parallel_loop(var_name, max_val, use_thread_group = False, block_level = False) and make sure to end this control flow later
  • Add a thread synchronization point gen_add_sync(self, use_thread_group = False)
  • Test if a variable is or is not in a list gen_var_in_list(var_name, option_list) and gen_var_not_in_list(var_name, option_list)
  • Generate an if, elif, else statement that can be either non-branching (if only one output variable or the flag is set) or branching selectors for multiple variables at the same time. Variable types, names, and resulting values are defined in the select_tuples = [(type, name, values)] and are selected when the loop_counter varaible satisfies the condition set by the comparator according to each count in an if, elif, else paradigm. This is done with gen_add_multi_threaded_select(loop_counter, comparator, counts, select_tuples, USE_NON_BRANCH_ALWAYS = False)
  • Load values from global to shared memory (assuming varaibles are called s_name and d_name) with gen_kernel_load_inputs(name, stride, amount, use_thread_group = False, name2 = None, stride2 = 1, amount2 = 1, name3 = None, stride3 = 1, amount3 = 1)
  • Save values from shared to global memory (assuming varaibles are called s_name and d_name or overridden by load_from_name) with gen_kernel_save_result(store_to_name, stride, amount, use_thread_group = False, load_from_name = None)
  • Generate the optimized C++ code string to compute the matrix cross product operation on a set of links/joints gen_mx_func_call_for_cpp(inds = None, PEQ_FLAG = False, SCALE_FLAG = False, updated_var_names = None)
  • Get variables that hold C++ code strings that represent the optimized topology pointers for a given set of joint/link indicies for a given robot mode (e.g., either indexing into shared memory to get parent indicies or optimized to simply return the current index minus one for a serial chain roboto) with parent_ind, S_ind, dva_col_offset_for_jid, df_col_offset_for_jid, dva_col_offset_for_parent, df_col_offset_for_parent, dva_col_offset_for_jid_p1, df_col_that_is_jid = gen_topology_helpers_pointers_for_cpp(inds = None, updated_var_names = None, NO_GRAD_FLAG = False) and similar Python numerical values can be returned through dva_cols_per_partial, dva_cols_per_jid, running_sum_dva_cols_per_jid, df_cols_per_partial, df_cols_per_jid, running_sum_df_cols_per_jid, df_col_that_is_jid = gen_topology_sparsity_helpers_python()

Additonal Features:

This package also includes test functions which allow for code optimizations and refactorizations to be tested against reference implementations. This code is located in the _test.py file.

  • (c, v, a, f) = GRiDCodeGenerator.test_rnea(q, qd, qdd = None, GRAVITY = -9.81)
  • Minv = GRiDCodeGenerator.test_minv(q, densify_Minv = False)
  • dc_du = GRiDCodeGenerator.test_rnea_grad(q, qd, qdd = None, GRAVITY = -9.81) where dc_du = np.hstack((dc_dq,dc_dqd))
  • df_du = GRiDCodeGenerator.test_fd_grad(q, qd, u, GRAVITY = -9.81) where df_du = np.hstack((df_dq,df_dqd))

We also include functions that break these algorithms down into there different passes to enable easier testing.

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