Simple example code for remove_cvref.

 

Simple example code for remove_cvref. 

.

#include <iostream>

#include <type_traits>

// Simple implementation of remove_cvref_t (C++20 feature)

template<typename T>

struct remove_cvref {

using type = std::remove_cv_t<std::remove_reference_t<T>>;

};

template<typename T>

using remove_cvref_t = typename remove_cvref<T>::type;

// Helper to print type names

template<typename T>

void print_type_info(const char* original_type) {

std::cout << "Original: " << original_type << std::endl;

std::cout << "After remove_cvref_t: ";

// Check what type we have after removal

if (std::is_same_v<T, int>) {

std::cout << "int" << std::endl;

} else if (std::is_same_v<T, float>) {

std::cout << "float" << std::endl;

} else if (std::is_same_v<T, double>) {

std::cout << "double" << std::endl;

}

std::cout << "---" << std::endl;

}

// Example class

class MyClass_MareArts {

public:

int value;

};

int main() {

// Example 1: const int&

using Type1 = const int&;

using Clean1 = remove_cvref_t<Type1>;

print_type_info<Clean1>("const int&");

// Example 2: volatile float&&

using Type2 = volatile float&&;

using Clean2 = remove_cvref_t<Type2>;

print_type_info<Clean2>("volatile float&&");

// Example 3: const volatile double&

using Type3 = const volatile double&;

using Clean3 = remove_cvref_t<Type3>;

print_type_info<Clean3>("const volatile double&");

// Example 4: Plain int (no change)

using Type4 = int;

using Clean4 = remove_cvref_t<Type4>;

print_type_info<Clean4>("int");

// Practical example with templates

auto lambda = []<typename T>(T&& value) {

// T might be const MyClass&, MyClass&&, etc.

using CleanType = remove_cvref_t<T>;

// Now CleanType is always just MyClass

CleanType copy = value; // Can create a clean copy

copy.value = 42; // Can modify the copy

std::cout << "Modified copy value: " << copy.value << std::endl;

};

const MyClass_MareArts obj{10};

lambda(obj); // Pass const object

MyClass_MareArts obj2{20};

lambda(std::move(obj2)); // Pass rvalue

return 0;

}

..

GPU memory vs shared memory

ceiling technic

 Add the maximum possible remainder (TILE-1) before dividing!

  Simple Example with 10:

  Let's use TILE=10 for easier understanding:

  Without ceiling (wrong):

  11 / 10 = 1 (need 2!) ❌

  19 / 10 = 1 (need 2!) ❌

  With ceiling technique:

  (11 + 9) / 10 = 20 / 10 = 2 ✓

  (19 + 9) / 10 = 28 / 10 = 2 ✓

  (20 + 9) / 10 = 29 / 10 = 2 ✓ (still 2, correct!)

  (21 + 9) / 10 = 30 / 10 = 3 ✓

  Why Add (TILE-1)?

  Think of it like this:

  If remainder = 0 (perfectly divisible):

  20 / 10 = 2.0

  (20 + 9) / 10 = 29 / 10 = 2.9 → 2 (same!)

  If remainder > 0 (needs extra block):

  21 / 10 = 2.1 (remainder 1)

  (21 + 9) / 10 = 30 / 10 = 3.0 → 3 (pushed to next!)

  The Magic:

  Adding (TILE-1):

  - Remainder 0: Adds 0.9999... → stays same integer

  - Remainder ≥1: Adds enough to reach next integer

  Visual Pattern:

  Value | +9 | /10 | Result

  ------|----|----|-------

  10    | 19 | 1.9| 1 ✓

  11    | 20 | 2.0| 2 ✓ (jumps up!)

  19    | 28 | 2.8| 2 ✓

  20    | 29 | 2.9| 2 ✓

  21    | 30 | 3.0| 3 ✓ (jumps up!)

  Formula Summary:

  // Ceiling division formula:

  ceil(A/B) = (A + B - 1) / B

  // For our GEMM tiles:

  num_blocks = (matrix_size + tile_size - 1) / tile_size

  It's simple: "Add almost one tile, then divide" - this guarantees rounding up!

CK Tile Tutorial Day 2 (AMD hip programming) - Simple GEMM.

 Concepts Added:

• 2D grid/block configuration
• Matrix multiplication basics
• Each thread computes one output element

Key Pattern:

// Each thread computes C[row][col]
for (int k = 0; k < K; k++) {
    sum += A[row][k] * B[k][col];
}

.

=== Thread Mapping Visualization ===

Each thread computes one C[i][j]:

  Block(0,0)        Block(1,0)

  ┌─────────┐      ┌─────────┐

  │T00 T01..│      │T00 T01..│

  │T10 T11..│      │T10 T11..│

  │... ... ..│      │... ... ..│

  └─────────┘      └─────────┘

       ↓                ↓

  C[0:16,0:16]    C[0:16,16:32]

Each thread's work:

  for k in 0..K:

    sum += A[row][k] * B[k][col]

  C[row][col] = sum

=== Step 2: Simple GEMM ===

Matrix multiply: (64x64) * (64x64) = (64x64)

Launching with grid(4,4), block(16,16)

Result: CORRECT

Time: 0.4232 ms

Performance: 1.23887 GFLOPS

=== Step 2: Simple GEMM ===

Matrix multiply: (128x128) * (128x128) = (128x128)

Launching with grid(8,8), block(16,16)

Result: CORRECT

Time: 0.03824 ms

Performance: 109.684 GFLOPS

Key Concepts Added:

1. 2D grid/block configuration

2. Each thread computes one output element

3. Row-major vs column-major layouts

4. Performance measurement (GFLOPS)

..

code

.

// Step 2: Simple GEMM (Matrix Multiplication)

// Building on Step 1, now each thread computes one output element

#include <hip/hip_runtime.h>

#include <iostream>

#include <vector>

// ============================================

// PART 1: Kernel Arguments

// ============================================

struct SimpleGemmKernelArgs {

const float* a_ptr; // M x K matrix

const float* b_ptr; // K x N matrix

float* c_ptr; // M x N matrix

int M;

int N;

int K;

SimpleGemmKernelArgs(const float* a, const float* b, float* c,

int m, int n, int k)

: a_ptr(a), b_ptr(b), c_ptr(c), M(m), N(n), K(k) {}

};

// ============================================

// PART 2: The Kernel (One thread per output)

// ============================================

struct SimpleGemmKernel {

static dim3 GridSize(const SimpleGemmKernelArgs& args) {

// 16x16 threads per block

int grid_m = (args.M + 15) / 16;

int grid_n = (args.N + 15) / 16;

return dim3(grid_n, grid_m, 1); // Note: x=N, y=M

}

static dim3 BlockSize() {

return dim3(16, 16, 1); // 16x16 = 256 threads

}

__device__ void operator()(const SimpleGemmKernelArgs& args) const {

// Each thread computes one element of C

int col = blockIdx.x * blockDim.x + threadIdx.x; // N dimension

int row = blockIdx.y * blockDim.y + threadIdx.y; // M dimension

// Bounds check

if (row >= args.M || col >= args.N) return;

// Compute dot product for C[row][col]

float sum = 0.0f;

for (int k = 0; k < args.K; k++) {

// A is row-major: A[row][k] = A[row * K + k]

// B is column-major: B[k][col] = B[k + col * K]

float a_val = args.a_ptr[row * args.K + k];

float b_val = args.b_ptr[k + col * args.K];

sum += a_val * b_val;

}

// Store result (C is row-major)

args.c_ptr[row * args.N + col] = sum;

}

};

// ============================================

// PART 3: Host Code

// ============================================

__global__ void simple_gemm_kernel(SimpleGemmKernelArgs args) {

SimpleGemmKernel kernel;

kernel(args);

}

void run_simple_gemm(int M, int N, int K) {

std::cout << "\n=== Step 2: Simple GEMM ===\n";

std::cout << "Matrix multiply: (" << M << "x" << K << ") * ("

<< K << "x" << N << ") = (" << M << "x" << N << ")\n";

// Allocate host memory

std::vector<float> h_a(M * K);

std::vector<float> h_b(K * N);

std::vector<float> h_c(M * N, 0.0f);

// Initialize with simple values

for (int i = 0; i < M * K; i++) h_a[i] = 1.0f;

for (int i = 0; i < K * N; i++) h_b[i] = 2.0f;

// Allocate device memory

float *d_a, *d_b, *d_c;

hipMalloc(&d_a, M * K * sizeof(float));

hipMalloc(&d_b, K * N * sizeof(float));

hipMalloc(&d_c, M * N * sizeof(float));

// Copy to device

hipMemcpy(d_a, h_a.data(), M * K * sizeof(float), hipMemcpyHostToDevice);

hipMemcpy(d_b, h_b.data(), K * N * sizeof(float), hipMemcpyHostToDevice);

// Create kernel arguments

SimpleGemmKernelArgs args(d_a, d_b, d_c, M, N, K);

// Get launch configuration

dim3 grid = SimpleGemmKernel::GridSize(args);

dim3 block = SimpleGemmKernel::BlockSize();

std::cout << "Launching with grid(" << grid.x << "," << grid.y

<< "), block(" << block.x << "," << block.y << ")\n";

// Launch kernel

hipEvent_t start, stop;

hipEventCreate(&start);

hipEventCreate(&stop);

hipEventRecord(start);

simple_gemm_kernel<<<grid, block>>>(args);

hipEventRecord(stop);

hipEventSynchronize(stop);

float milliseconds = 0;

hipEventElapsedTime(&milliseconds, start, stop);

// Copy result back

hipMemcpy(h_c.data(), d_c, M * N * sizeof(float), hipMemcpyDeviceToHost);

// Verify (each element should be K * 1.0 * 2.0 = 2K)

float expected = 2.0f * K;

bool correct = true;

for (int i = 0; i < std::min(10, M*N); i++) {

if (h_c[i] != expected) {

correct = false;

break;

}

}

std::cout << "Result: " << (correct ? "CORRECT" : "WRONG") << "\n";

std::cout << "Time: " << milliseconds << " ms\n";

// Calculate FLOPS

double flops = 2.0 * M * N * K; // 2 ops per multiply-add

double gflops = (flops / milliseconds) / 1e6;

std::cout << "Performance: " << gflops << " GFLOPS\n";

// Cleanup

hipFree(d_a);

hipFree(d_b);

hipFree(d_c);

hipEventDestroy(start);

hipEventDestroy(stop);

}

// ============================================

// VISUALIZATION: How threads map to output

// ============================================

void visualize_thread_mapping() {

std::cout << "\n=== Thread Mapping Visualization ===\n";

std::cout << "Each thread computes one C[i][j]:\n\n";

std::cout << " Block(0,0) Block(1,0)\n";

std::cout << " ┌─────────┐ ┌─────────┐\n";

std::cout << " │T00 T01..│ │T00 T01..│\n";

std::cout << " │T10 T11..│ │T10 T11..│\n";

std::cout << " │... ... ..│ │... ... ..│\n";

std::cout << " └─────────┘ └─────────┘\n";

std::cout << " ↓ ↓\n";

std::cout << " C[0:16,0:16] C[0:16,16:32]\n\n";

std::cout << "Each thread's work:\n";

std::cout << " for k in 0..K:\n";

std::cout << " sum += A[row][k] * B[k][col]\n";

std::cout << " C[row][col] = sum\n";

}

// ============================================

// PART 4: Main

// ============================================

int main() {

std::cout << "MareArts CK Tile Tutorial - Step 2: Simple GEMM\n";

std::cout << "======================================\n";

visualize_thread_mapping();

// Run with different sizes

run_simple_gemm(64, 64, 64);

run_simple_gemm(128, 128, 128);

std::cout << "\nKey Concepts Added:\n";

std::cout << "1. 2D grid/block configuration\n";

std::cout << "2. Each thread computes one output element\n";

std::cout << "3. Row-major vs column-major layouts\n";

std::cout << "4. Performance measurement (GFLOPS)\n";

std::cout << "\nProblem: Each thread reads K elements from A and B\n";

std::cout << " → Poor memory reuse!\n";

std::cout << "Next: Add tiling and shared memory for efficiency\n";

return 0;

}

..

🙇🏻‍♂️

MareArts

CK Tile Tutorial Day 1 (AMD hip programming) - Vector add.

.

Concepts:

• Basic kernel structure: Args → Kernel → operator()
• Grid/Block configuration
• One thread per element processing

Key Code:

struct VectorAddKernel {
    __device__ void operator()(args) {
        int idx = blockIdx.x * blockDim.x + threadIdx.x;
        c[idx] = a[idx] + b[idx];
    }
};

..

code

..

// Step 1: Simplest CK Tile Kernel - Vector Addition

// This demonstrates the absolute basics of CK Tile

#include <hip/hip_runtime.h>

#include <iostream>

#include <vector>

// ============================================

// PART 1: Kernel Arguments (Host → Device)

// ============================================

struct VectorAddKernelArgs {

const float* a_ptr;

const float* b_ptr;

float* c_ptr;

int n;

// Constructor from host arguments

VectorAddKernelArgs(const float* a, const float* b, float* c, int size)

: a_ptr(a), b_ptr(b), c_ptr(c), n(size) {}

};

// ============================================

// PART 2: The Kernel

// ============================================

struct VectorAddKernel {

// Static method to get grid size (how many blocks)

static dim3 GridSize(const VectorAddKernelArgs& args) {

// 256 threads per block, divide work

int blocks = (args.n + 255) / 256;

return dim3(blocks, 1, 1);

}

// Static method to get block size (threads per block)

static dim3 BlockSize() {

return dim3(256, 1, 1);

}

// The actual kernel function - called by each thread

__device__ void operator()(const VectorAddKernelArgs& args) const {

// Calculate global thread index

int idx = blockIdx.x * blockDim.x + threadIdx.x;

// Check bounds

if (idx < args.n) {

// Each thread does one element

args.c_ptr[idx] = args.a_ptr[idx] + args.b_ptr[idx];

}

}

};

// ============================================

// PART 3: Host Launch Function

// ============================================

__global__ void vector_add_kernel(VectorAddKernelArgs args) {

VectorAddKernel kernel;

kernel(args);

}

void run_vector_add(int n) {

std::cout << "\n=== Step 1: Vector Addition ===\n";

std::cout << "Adding two vectors of size " << n << "\n";

// Allocate host memory

std::vector<float> h_a(n, 1.0f);

std::vector<float> h_b(n, 2.0f);

std::vector<float> h_c(n, 0.0f);

// Allocate device memory

float *d_a, *d_b, *d_c;

hipMalloc(&d_a, n * sizeof(float));

hipMalloc(&d_b, n * sizeof(float));

hipMalloc(&d_c, n * sizeof(float));

// Copy to device

hipMemcpy(d_a, h_a.data(), n * sizeof(float), hipMemcpyHostToDevice);

hipMemcpy(d_b, h_b.data(), n * sizeof(float), hipMemcpyHostToDevice);

// Create kernel arguments

VectorAddKernelArgs args(d_a, d_b, d_c, n);

// Get launch configuration

dim3 grid = VectorAddKernel::GridSize(args);

dim3 block = VectorAddKernel::BlockSize();

std::cout << "Launching with grid(" << grid.x << "), block(" << block.x << ")\n";

// Launch kernel

vector_add_kernel<<<grid, block>>>(args);

// Copy result back

hipMemcpy(h_c.data(), d_c, n * sizeof(float), hipMemcpyDeviceToHost);

// Verify

bool correct = true;

for (int i = 0; i < std::min(10, n); i++) {

if (h_c[i] != 3.0f) {

correct = false;

break;

}

}

std::cout << "Result: " << (correct ? "CORRECT" : "WRONG") << "\n";

std::cout << "First 5 elements: ";

for (int i = 0; i < std::min(5, n); i++) {

std::cout << h_c[i] << " ";

}

std::cout << "\n";

// Cleanup

hipFree(d_a);

hipFree(d_b);

hipFree(d_c);

}

// ============================================

// PART 4: Main

// ============================================

int main() {

std::cout << "MareArts CK Tile Tutorial - Step 1: Vector Addition\n";

std::cout << "==========================================\n";

// Run with different sizes

run_vector_add(1024);

run_vector_add(10000);

std::cout << "\nKey Concepts Demonstrated:\n";

std::cout << "1. Kernel structure: Args → Kernel → operator()\n";

std::cout << "2. Grid/Block configuration\n";

std::cout << "3. Each thread processes one element\n";

std::cout << "4. Bounds checking for safety\n";

return 0;

}

...

Result

CK Tile Tutorial - Step 1: Vector Addition

==========================================

=== Step 1: Vector Addition ===

Adding two vectors of size 1024

Launching with grid(4), block(256)

Result: CORRECT

First 5 elements: 3 3 3 3 3 

=== Step 1: Vector Addition ===

Adding two vectors of size 10000

Launching with grid(40), block(256)

Result: CORRECT

First 5 elements: 3 3 3 3 3 

Key Concepts Demonstrated:

1. Kernel structure: Args → Kernel → operator()

2. Grid/Block configuration

3. Each thread processes one element

4. Bounds checking for safety

ONNX Runtime with ROCm (AMD GPU) Setup Guide

Installation

Prerequisites

• ROCm installed (6.0+ recommended)
• Python 3.8-3.10

Install ONNX Runtime with ROCm Support

# 1. Remove existing ONNX Runtime (if any)
pip uninstall -y onnxruntime onnxruntime-gpu

# 2. Install from AMD ROCm repository
# For ROCm 6.4
pip install onnxruntime-rocm -f https://repo.radeon.com/rocm/manylinux/rocm-rel-6.4/

# For ROCm 6.2
pip install onnxruntime-rocm -f https://repo.radeon.com/rocm/manylinux/rocm-rel-6.2/

# For ROCm 6.0
pip install onnxruntime-rocm -f https://repo.radeon.com/rocm/manylinux/rocm-rel-6.0/

Verify Installation

import onnxruntime as ort

# Check available providers
print("Available providers:", ort.get_available_providers())

# Should show: ['MIGraphXExecutionProvider', 'ROCMExecutionProvider', 'CPUExecutionProvider']

Simple Usage Example

import onnxruntime as ort
import numpy as np

# Load ONNX model with ROCm
providers = ['ROCMExecutionProvider', 'CPUExecutionProvider']
session = ort.InferenceSession("model.onnx", providers=providers)

# Check which provider is being used
print(f"Using: {session.get_providers()[0]}")

# Prepare input (example: batch_size=1, 3 channels, 640x640 image)
input_data = np.random.randn(1, 3, 640, 640).astype(np.float32)

# Run inference
input_name = session.get_inputs()[0].name
output = session.run(None, {input_name: input_data})

print(f"Output shape: {output[0].shape}")

Advanced: Using MIGraphX (AMD Optimized)

# MIGraphX is AMD's optimized graph execution provider
# It can be faster than ROCMExecutionProvider for some models

providers = [
    'MIGraphXExecutionProvider',  # Fastest on AMD
    'ROCMExecutionProvider',       # Standard ROCm
    'CPUExecutionProvider'         # Fallback
]

session = ort.InferenceSession("model.onnx", providers=providers)

Complete Example: Image Detection

import onnxruntime as ort
import numpy as np
import cv2

def load_model(model_path, use_gpu=True):
    """Load ONNX model with ROCm support"""
    if use_gpu:
        providers = ['MIGraphXExecutionProvider', 'ROCMExecutionProvider', 'CPUExecutionProvider']
    else:
        providers = ['CPUExecutionProvider']
    
    session = ort.InferenceSession(model_path, providers=providers)
    print(f"Model loaded with: {session.get_providers()[0]}")
    return session

def preprocess_image(image_path, size=640):
    """Preprocess image for inference"""
    image = cv2.imread(image_path)
    resized = cv2.resize(image, (size, size))
    rgb = cv2.cvtColor(resized, cv2.COLOR_BGR2RGB)
    normalized = rgb.astype(np.float32) / 255.0
    transposed = normalized.transpose(2, 0, 1)  # HWC to CHW
    batched = np.expand_dims(transposed, axis=0)  # Add batch dimension
    return batched, image

def run_inference(session, input_data):
    """Run model inference"""
    input_name = session.get_inputs()[0].name
    outputs = session.run(None, {input_name: input_data})
    return outputs

# Usage
model = load_model("rtdetr_fp32.onnx", use_gpu=True)
input_data, original_image = preprocess_image("test.jpg")
outputs = run_inference(model, input_data)

print(f"Detection output shape: {outputs[0].shape}")

Troubleshooting

1. ROCMExecutionProvider not available

# Check ROCm installation
import subprocess
result = subprocess.run(['rocm-smi'], capture_output=True, text=True)
print(result.stdout)

2. Fallback to CPU

If ONNX Runtime falls back to CPU despite having ROCm:

• Check ROCm version compatibility
• Verify GPU is visible: rocm-smi
• Set environment variable: export HIP_VISIBLE_DEVICES=0

3. Performance Tips

• Use MIGraphXExecutionProvider for best performance on AMD GPUs
• FP16 models can be faster but may have slight accuracy loss
• Batch processing improves throughput

Environment Variables

# Select specific GPU
export HIP_VISIBLE_DEVICES=0

# Enable verbose logging
export ORT_ROCM_VERBOSE_LEVEL=1

# Set memory limit (in MB)
export ORT_ROCM_MEM_LIMIT=4096

Performance Comparison

Provider	Relative Speed	Use Case
MIGraphXExecutionProvider	Fastest	Production, optimized models
ROCMExecutionProvider	Fast	General purpose
CPUExecutionProvider	Slowest	Fallback, debugging

Notes

• ONNX Runtime ROCm version should match your ROCm installation
• Not all ONNX operators are supported on ROCm - unsupported ops fall back to CPU
• For best performance, export models with static shapes

Understanding C++ Templates, (class, member function and this)

 

template<int INT>

void AAA() {

std::cout << "INT = " << INT << std::endl;

}

How to Call It:

Normal Context (Outside Class):

AAA<2>(); // ✅ Just call directly

AAA<5>(); // ✅ Works fine

AAA<10>(); // ✅ No problem

Inside Template Class Context:

template<typename T>

class MyClass {

template<int INT>

void AAA() {

std::cout << "INT = " << INT << std::endl;

}

void some_function() {

// WRONG:

template AAA<2>(); // ❌ ERROR! Invalid syntax

// CORRECT:

this->template AAA<2>(); // ✅ Works!

AAA<2>(); // ✅ Usually works too

}

};

Key Point:

- template AAA<2>(); is INVALID C++ syntax

- this->template AAA<2>(); is VALID C++ syntax

The Rule:

- template keyword only goes after -> or . in template contexts

- You cannot start a statement with just template

Correct Examples:

this->template AAA<2>(); // ✅ In class context

obj.template AAA<2>(); // ✅ With object

ptr->template AAA<2>(); // ✅ With pointer

AAA<2>(); // ✅ Direct call (no template keyword needed)