model_util/util.c - sw/vec_iree - Git at Google

 /*
  * Copyright 2023 Google LLC
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 // An example based on iree/samples/simple_embedding.

 #include "model_util/util.h"

 #include <log.h>

 #include "device/device.h"
 #include "iree/modules/hal/inline/module.h"
 #include "iree/modules/hal/loader/module.h"

 typedef struct {
   uint32_t return_code;  // Populated in crt0.S
 #ifndef BUILD_KELVIN
   uint32_t epc;          // Populated in crt0.S
 #else
   uint32_t output_ptr;
 #endif
   uint32_t length;
 } OutputHeader;

 __attribute__((section(".model_output_header"))) OutputHeader output_header;

 extern const MlModel kModel;

 // Create context that will hold the module state across invocations.
 static iree_status_t create_context(iree_vm_instance_t *instance,
                                     iree_hal_device_t **device,
                                     iree_vm_context_t **context) {
   iree_allocator_t host_allocator = iree_allocator_system();
   iree_status_t result = iree_vm_instance_create(IREE_VM_TYPE_CAPACITY_DEFAULT,
                                                  host_allocator, &instance);

 #if defined(BUILD_INLINE_HAL)
   IREE_RETURN_IF_ERROR(iree_hal_module_register_inline_types(instance));
 #elif defined(BUILD_LOADER_HAL)
   IREE_RETURN_IF_ERROR(iree_hal_module_register_loader_types(instance));
 #else
   IREE_RETURN_IF_ERROR(iree_hal_module_register_all_types(instance));
 #endif

   iree_hal_executable_loader_t *loader = NULL;
   if (iree_status_is_ok(result)) {
     result = create_sample_device(host_allocator, device, &loader);
   }

   // Load bytecode or C module.
   iree_vm_module_t *module = NULL;
   if (iree_status_is_ok(result)) {
     result = create_module(instance, &module);
   }

 #if defined(BUILD_INLINE_HAL) || defined(BUILD_LOADER_HAL)
   // Create hal_inline_module
   iree_vm_module_t *hal_inline_module = NULL;
   if (iree_status_is_ok(result)) {
     result = iree_hal_inline_module_create(
         instance, IREE_HAL_INLINE_MODULE_FLAG_NONE,
         iree_hal_module_debug_sink_stdio(stderr),
         iree_hal_device_allocator(*device), host_allocator, &hal_inline_module);
   }
 #endif
 #if defined(BUILD_INLINE_HAL)
   iree_vm_module_t *modules[] = {hal_inline_module, module};
 #elif defined(BUILD_LOADER_HAL)
   // Create hal_loader_module
   iree_vm_module_t *hal_loader_module = NULL;
   if (iree_status_is_ok(result)) {
     result = iree_hal_loader_module_create(instance, IREE_HAL_MODULE_FLAG_NONE,
                                            /*loader_count=*/1, &loader,
                                            host_allocator, &hal_loader_module);
   }
   iree_vm_module_t *modules[] = {hal_inline_module, hal_loader_module, module};
 #else
   // Create hal_module
   iree_vm_module_t *hal_module = NULL;
   if (iree_status_is_ok(result)) {
     result = iree_hal_module_create(instance, /*device_count=*/1, device,
                                     IREE_HAL_MODULE_FLAG_NONE,
                                     iree_hal_module_debug_sink_stdio(stderr),
                                     host_allocator,
                                     &hal_module);
   }
   iree_vm_module_t *modules[] = {hal_module, module};
 #endif
   iree_hal_executable_loader_release(loader);

   // Allocate a context that will hold the module state across invocations.
   if (iree_status_is_ok(result)) {
     result = iree_vm_context_create_with_modules(
         instance, IREE_VM_CONTEXT_FLAG_NONE, IREE_ARRAYSIZE(modules),
         &modules[0], host_allocator, context);
   }
 #if defined(BUILD_INLINE_HAL) || defined(BUILD_LOADER_HAL)
   iree_vm_module_release(hal_inline_module);
 #else
   iree_vm_module_release(hal_module);
 #endif
 #if defined(BUILD_LOADER_HAL)
   iree_vm_module_release(hal_loader_module);
 #endif
   iree_vm_module_release(module);
   return result;
 }

 // Prepare the input buffers and buffer_views based on the data type. They must
 // be released by the caller.
 static iree_status_t prepare_input_hal_buffer_views(
     const MlModel *model, iree_hal_device_t *device, void **arg_buffers,
     iree_hal_buffer_view_t **arg_buffer_views) {
   iree_status_t result = iree_ok_status();

   // Prepare the input buffer, and populate the initial value.
   // The input buffer must be released by the caller.
   iree_const_byte_span_t *byte_span[MAX_MODEL_INPUT_NUM] = {NULL};
   result = load_input_data(model, arg_buffers, byte_span);

   // Wrap buffers in shaped buffer views.
   // The buffers can be mapped on the CPU and that can also be used
   // on the device. Not all devices support this, but the ones we have now do.

   iree_hal_buffer_params_t buffer_params = {
       .type =
           IREE_HAL_MEMORY_TYPE_HOST_LOCAL | IREE_HAL_MEMORY_TYPE_DEVICE_VISIBLE,
       .access = IREE_HAL_MEMORY_ACCESS_ALL,
       .usage = IREE_HAL_BUFFER_USAGE_DEFAULT};
   for (int i = 0; i < model->num_input; ++i) {
     if (iree_status_is_ok(result)) {
       result = iree_hal_buffer_view_allocate_buffer_copy(
           device, iree_hal_device_allocator(device), model->num_input_dim[i],
           model->input_shape[i], model->hal_element_type,
           IREE_HAL_ENCODING_TYPE_DENSE_ROW_MAJOR, buffer_params, *byte_span[i],
           &(arg_buffer_views[i]));
     }
     if (byte_span[i] != NULL) {
       free(byte_span[i]);
     }
   }
   return result;
 }

 iree_status_t run(const MlModel *model) {
   iree_vm_instance_t *instance = NULL;
   iree_hal_device_t *device = NULL;
   iree_vm_context_t *context = NULL;
   // create context
   iree_status_t result = create_context(instance, &device, &context);

   // Lookup the entry point function.
   // Note that we use the synchronous variant which operates on pure type/shape
   // erased buffers.
   iree_vm_function_t main_function;
   if (iree_status_is_ok(result)) {
     result = (iree_vm_context_resolve_function(
         context, iree_make_cstring_view(model->entry_func), &main_function));
   }

   // Prepare the input buffers.
   void *arg_buffers[MAX_MODEL_INPUT_NUM] = {NULL};
   iree_hal_buffer_view_t *arg_buffer_views[MAX_MODEL_INPUT_NUM] = {NULL};
   if (iree_status_is_ok(result)) {
     result = prepare_input_hal_buffer_views(model, device, arg_buffers,
                                             arg_buffer_views);
   }

   // Setup call inputs with our buffers.
   iree_vm_list_t *inputs = NULL;
   if (iree_status_is_ok(result)) {
     result = iree_vm_list_create(iree_vm_make_undefined_type_def(),
                                  /*capacity=*/model->num_input,
                                  iree_allocator_system(), &inputs);
   }
   iree_vm_ref_t arg_buffer_view_ref;
   for (int i = 0; i < model->num_input; ++i) {
     arg_buffer_view_ref = iree_hal_buffer_view_move_ref(arg_buffer_views[i]);
     if (iree_status_is_ok(result)) {
       result = iree_vm_list_push_ref_move(inputs, &arg_buffer_view_ref);
     }
   }

   // Prepare outputs list to accept the results from the invocation.
   // The output vm list is allocated statically.
   iree_vm_list_t *outputs = NULL;
   if (iree_status_is_ok(result)) {
     result =
         iree_vm_list_create(iree_vm_make_undefined_type_def(),
                             /*capacity=*/1, iree_allocator_system(), &outputs);
   }

   // Invoke the function.
   if (iree_status_is_ok(result)) {
     result = iree_vm_invoke(context, main_function, IREE_VM_CONTEXT_FLAG_NONE,
                             /*policy=*/NULL, inputs, outputs,
                             iree_allocator_system());
   }

   // Validate output and gather buffers.
   iree_hal_buffer_mapping_t mapped_memories[MAX_MODEL_OUTPUTS] = {{}};
   for (int index_output = 0; index_output < model->num_output; index_output++) {
     iree_hal_buffer_view_t *ret_buffer_view = NULL;
     if (iree_status_is_ok(result)) {
       // Get the result buffers from the invocation.
       ret_buffer_view =
           iree_vm_list_get_buffer_view_assign(outputs, index_output);
       if (ret_buffer_view == NULL) {
         result = iree_make_status(IREE_STATUS_NOT_FOUND,
                                   "can't find return buffer view");
       }
     }
     if (iree_status_is_ok(result)) {
       result = iree_hal_buffer_map_range(
           iree_hal_buffer_view_buffer(ret_buffer_view),
           IREE_HAL_MAPPING_MODE_SCOPED, IREE_HAL_MEMORY_ACCESS_READ, 0,
           IREE_WHOLE_BUFFER, &mapped_memories[index_output]);
     }

     if (iree_status_is_ok(result)) {
       if (index_output > model->num_output ||
           mapped_memories[index_output].contents.data_length /
                   model->output_size_bytes !=
               model->output_length[index_output]) {
         result =
             iree_make_status(IREE_STATUS_UNKNOWN, "output length mismatches");
       }
     }
   }

   // Post-process memory into model output.
   if (iree_status_is_ok(result)) {
     uint32_t length = 0;
     uint32_t output_ptr = 0;
     result = process_output(model, mapped_memories, &length, &output_ptr);
     output_header.length = length;
 #ifdef BUILD_KELVIN
     output_header.output_ptr = output_ptr;
 #endif
   }

   for (int index_output = 0; index_output < model->num_output; index_output++) {
     if (mapped_memories[index_output].contents.data != NULL) {
       iree_hal_buffer_unmap_range(&mapped_memories[index_output]);
     }
   }
   iree_vm_list_release(inputs);
   iree_vm_list_release(outputs);
   for (int i = 0; i < model->num_input; ++i) {
     if (arg_buffers[i] != NULL) {
       free(arg_buffers[i]);
     }
   }
   iree_vm_context_release(context);
   IREE_IGNORE_ERROR(iree_hal_allocator_statistics_fprint(
       stdout, iree_hal_device_allocator(device)));
   iree_hal_device_release(device);
   iree_vm_instance_release(instance);
   return result;
 }

 int main() {
   const MlModel *model_ptr = &kModel;
   const iree_status_t result = run(model_ptr);
   int ret = (int)iree_status_code(result);
   if (!iree_status_is_ok(result)) {
     iree_status_fprint(stderr, result);
     iree_status_free(result);
   } else {
     LOG_INFO("%s finished successfully", model_ptr->model_name);
   }

   return ret;
 }
	/*
	* Copyright 2023 Google LLC
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	// An example based on iree/samples/simple_embedding.

	#include "model_util/util.h"

	#include <log.h>

	#include "device/device.h"
	#include "iree/modules/hal/inline/module.h"
	#include "iree/modules/hal/loader/module.h"

	typedef struct {
	uint32_t return_code; // Populated in crt0.S
	#ifndef BUILD_KELVIN
	uint32_t epc; // Populated in crt0.S
	#else
	uint32_t output_ptr;
	#endif
	uint32_t length;
	} OutputHeader;

	__attribute__((section(".model_output_header"))) OutputHeader output_header;

	extern const MlModel kModel;

	// Create context that will hold the module state across invocations.
	static iree_status_t create_context(iree_vm_instance_t *instance,
	iree_hal_device_t **device,
	iree_vm_context_t **context) {
	iree_allocator_t host_allocator = iree_allocator_system();
	iree_status_t result = iree_vm_instance_create(IREE_VM_TYPE_CAPACITY_DEFAULT,
	host_allocator, &instance);

	#if defined(BUILD_INLINE_HAL)
	IREE_RETURN_IF_ERROR(iree_hal_module_register_inline_types(instance));
	#elif defined(BUILD_LOADER_HAL)
	IREE_RETURN_IF_ERROR(iree_hal_module_register_loader_types(instance));
	#else
	IREE_RETURN_IF_ERROR(iree_hal_module_register_all_types(instance));
	#endif

	iree_hal_executable_loader_t *loader = NULL;
	if (iree_status_is_ok(result)) {
	result = create_sample_device(host_allocator, device, &loader);
	}

	// Load bytecode or C module.
	iree_vm_module_t *module = NULL;
	if (iree_status_is_ok(result)) {
	result = create_module(instance, &module);
	}

	#if defined(BUILD_INLINE_HAL) \|\| defined(BUILD_LOADER_HAL)
	// Create hal_inline_module
	iree_vm_module_t *hal_inline_module = NULL;
	if (iree_status_is_ok(result)) {
	result = iree_hal_inline_module_create(
	instance, IREE_HAL_INLINE_MODULE_FLAG_NONE,
	iree_hal_module_debug_sink_stdio(stderr),
	iree_hal_device_allocator(*device), host_allocator, &hal_inline_module);
	}
	#endif
	#if defined(BUILD_INLINE_HAL)
	iree_vm_module_t *modules[] = {hal_inline_module, module};
	#elif defined(BUILD_LOADER_HAL)
	// Create hal_loader_module
	iree_vm_module_t *hal_loader_module = NULL;
	if (iree_status_is_ok(result)) {
	result = iree_hal_loader_module_create(instance, IREE_HAL_MODULE_FLAG_NONE,
	/loader_count=/1, &loader,
	host_allocator, &hal_loader_module);
	}
	iree_vm_module_t *modules[] = {hal_inline_module, hal_loader_module, module};
	#else
	// Create hal_module
	iree_vm_module_t *hal_module = NULL;
	if (iree_status_is_ok(result)) {
	result = iree_hal_module_create(instance, /device_count=/1, device,
	IREE_HAL_MODULE_FLAG_NONE,
	iree_hal_module_debug_sink_stdio(stderr),
	host_allocator,
	&hal_module);
	}
	iree_vm_module_t *modules[] = {hal_module, module};
	#endif
	iree_hal_executable_loader_release(loader);

	// Allocate a context that will hold the module state across invocations.
	if (iree_status_is_ok(result)) {
	result = iree_vm_context_create_with_modules(
	instance, IREE_VM_CONTEXT_FLAG_NONE, IREE_ARRAYSIZE(modules),
	&modules[0], host_allocator, context);
	}
	#if defined(BUILD_INLINE_HAL) \|\| defined(BUILD_LOADER_HAL)
	iree_vm_module_release(hal_inline_module);
	#else
	iree_vm_module_release(hal_module);
	#endif
	#if defined(BUILD_LOADER_HAL)
	iree_vm_module_release(hal_loader_module);
	#endif
	iree_vm_module_release(module);
	return result;
	}

	// Prepare the input buffers and buffer_views based on the data type. They must
	// be released by the caller.
	static iree_status_t prepare_input_hal_buffer_views(
	const MlModel model, iree_hal_device_t device, void **arg_buffers,
	iree_hal_buffer_view_t **arg_buffer_views) {
	iree_status_t result = iree_ok_status();

	// Prepare the input buffer, and populate the initial value.
	// The input buffer must be released by the caller.
	iree_const_byte_span_t *byte_span[MAX_MODEL_INPUT_NUM] = {NULL};
	result = load_input_data(model, arg_buffers, byte_span);

	// Wrap buffers in shaped buffer views.
	// The buffers can be mapped on the CPU and that can also be used
	// on the device. Not all devices support this, but the ones we have now do.

	iree_hal_buffer_params_t buffer_params = {
	.type =
	IREE_HAL_MEMORY_TYPE_HOST_LOCAL \| IREE_HAL_MEMORY_TYPE_DEVICE_VISIBLE,
	.access = IREE_HAL_MEMORY_ACCESS_ALL,
	.usage = IREE_HAL_BUFFER_USAGE_DEFAULT};
	for (int i = 0; i < model->num_input; ++i) {
	if (iree_status_is_ok(result)) {
	result = iree_hal_buffer_view_allocate_buffer_copy(
	device, iree_hal_device_allocator(device), model->num_input_dim[i],
	model->input_shape[i], model->hal_element_type,
	IREE_HAL_ENCODING_TYPE_DENSE_ROW_MAJOR, buffer_params, *byte_span[i],
	&(arg_buffer_views[i]));
	}
	if (byte_span[i] != NULL) {
	free(byte_span[i]);
	}
	}
	return result;
	}

	iree_status_t run(const MlModel *model) {
	iree_vm_instance_t *instance = NULL;
	iree_hal_device_t *device = NULL;
	iree_vm_context_t *context = NULL;
	// create context
	iree_status_t result = create_context(instance, &device, &context);

	// Lookup the entry point function.
	// Note that we use the synchronous variant which operates on pure type/shape
	// erased buffers.
	iree_vm_function_t main_function;
	if (iree_status_is_ok(result)) {
	result = (iree_vm_context_resolve_function(
	context, iree_make_cstring_view(model->entry_func), &main_function));
	}

	// Prepare the input buffers.
	void *arg_buffers[MAX_MODEL_INPUT_NUM] = {NULL};
	iree_hal_buffer_view_t *arg_buffer_views[MAX_MODEL_INPUT_NUM] = {NULL};
	if (iree_status_is_ok(result)) {
	result = prepare_input_hal_buffer_views(model, device, arg_buffers,
	arg_buffer_views);
	}

	// Setup call inputs with our buffers.
	iree_vm_list_t *inputs = NULL;
	if (iree_status_is_ok(result)) {
	result = iree_vm_list_create(iree_vm_make_undefined_type_def(),
	/capacity=/model->num_input,
	iree_allocator_system(), &inputs);
	}
	iree_vm_ref_t arg_buffer_view_ref;
	for (int i = 0; i < model->num_input; ++i) {
	arg_buffer_view_ref = iree_hal_buffer_view_move_ref(arg_buffer_views[i]);
	if (iree_status_is_ok(result)) {
	result = iree_vm_list_push_ref_move(inputs, &arg_buffer_view_ref);
	}
	}

	// Prepare outputs list to accept the results from the invocation.
	// The output vm list is allocated statically.
	iree_vm_list_t *outputs = NULL;
	if (iree_status_is_ok(result)) {
	result =
	iree_vm_list_create(iree_vm_make_undefined_type_def(),
	/capacity=/1, iree_allocator_system(), &outputs);
	}

	// Invoke the function.
	if (iree_status_is_ok(result)) {
	result = iree_vm_invoke(context, main_function, IREE_VM_CONTEXT_FLAG_NONE,
	/policy=/NULL, inputs, outputs,
	iree_allocator_system());
	}

	// Validate output and gather buffers.
	iree_hal_buffer_mapping_t mapped_memories[MAX_MODEL_OUTPUTS] = {{}};
	for (int index_output = 0; index_output < model->num_output; index_output++) {
	iree_hal_buffer_view_t *ret_buffer_view = NULL;
	if (iree_status_is_ok(result)) {
	// Get the result buffers from the invocation.
	ret_buffer_view =
	iree_vm_list_get_buffer_view_assign(outputs, index_output);
	if (ret_buffer_view == NULL) {
	result = iree_make_status(IREE_STATUS_NOT_FOUND,
	"can't find return buffer view");
	}
	}
	if (iree_status_is_ok(result)) {
	result = iree_hal_buffer_map_range(
	iree_hal_buffer_view_buffer(ret_buffer_view),
	IREE_HAL_MAPPING_MODE_SCOPED, IREE_HAL_MEMORY_ACCESS_READ, 0,
	IREE_WHOLE_BUFFER, &mapped_memories[index_output]);
	}

	if (iree_status_is_ok(result)) {
	if (index_output > model->num_output \|\|
	mapped_memories[index_output].contents.data_length /
	model->output_size_bytes !=
	model->output_length[index_output]) {
	result =
	iree_make_status(IREE_STATUS_UNKNOWN, "output length mismatches");
	}
	}
	}

	// Post-process memory into model output.
	if (iree_status_is_ok(result)) {
	uint32_t length = 0;
	uint32_t output_ptr = 0;
	result = process_output(model, mapped_memories, &length, &output_ptr);
	output_header.length = length;
	#ifdef BUILD_KELVIN
	output_header.output_ptr = output_ptr;
	#endif
	}

	for (int index_output = 0; index_output < model->num_output; index_output++) {
	if (mapped_memories[index_output].contents.data != NULL) {
	iree_hal_buffer_unmap_range(&mapped_memories[index_output]);
	}
	}
	iree_vm_list_release(inputs);
	iree_vm_list_release(outputs);
	for (int i = 0; i < model->num_input; ++i) {
	if (arg_buffers[i] != NULL) {
	free(arg_buffers[i]);
	}
	}
	iree_vm_context_release(context);
	IREE_IGNORE_ERROR(iree_hal_allocator_statistics_fprint(
	stdout, iree_hal_device_allocator(device)));
	iree_hal_device_release(device);
	iree_vm_instance_release(instance);
	return result;
	}

	int main() {
	const MlModel *model_ptr = &kModel;
	const iree_status_t result = run(model_ptr);
	int ret = (int)iree_status_code(result);
	if (!iree_status_is_ok(result)) {
	iree_status_fprint(stderr, result);
	iree_status_free(result);
	} else {
	LOG_INFO("%s finished successfully", model_ptr->model_name);
	}

	return ret;
	}