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)

C++ tuple vs vector, Tutorial

 

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

// SIMPLE COMPARISON: TUPLE vs VECTOR

// When to use which one and why they're different

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

#include <tuple>

#include <vector>

#include <iostream>

#include <string>

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

// VECTOR: Dynamic Array of SAME TYPE

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

void vector_example() {

std::cout << "=== VECTOR EXAMPLE ===" << std::endl;

// Vector holds multiple values of THE SAME TYPE

std::vector<int> numbers = {10, 20, 30, 40, 50};

std::cout << "Vector contents: ";

for (size_t i = 0; i < numbers.size(); i++) {

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

}

std::cout << std::endl;

// Add more elements

numbers.push_back(60);

numbers.push_back(70);

std::cout << "After adding elements: ";

for (int num : numbers) {

std::cout << num << " ";

}

std::cout << std::endl;

std::cout << "Vector size: " << numbers.size() << std::endl;

std::cout << "Can grow/shrink at runtime: YES" << std::endl;

std::cout << "All elements same type: YES (int)" << std::endl;

}

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

// TUPLE: Fixed Collection of DIFFERENT TYPES

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

void tuple_example() {

std::cout << "\n=== TUPLE EXAMPLE ===" << std::endl;

// Tuple holds DIFFERENT TYPES in fixed positions

std::tuple<int, float, std::string, bool> data = {42, 3.14f, "hello", true};

std::cout << "Tuple contents:" << std::endl;

std::cout << "Position 0 (int): " << std::get<0>(data) << std::endl;

std::cout << "Position 1 (float): " << std::get<1>(data) << std::endl;

std::cout << "Position 2 (string): " << std::get<2>(data) << std::endl;

std::cout << "Position 3 (bool): " << std::get<3>(data) << std::endl;

// Cannot add elements - size is fixed at compile time

// data.push_back(something); // ERROR! No such method

std::cout << "Tuple size: " << std::tuple_size_v<decltype(data)> << std::endl;

std::cout << "Can grow/shrink at runtime: NO" << std::endl;

std::cout << "All elements same type: NO (int, float, string, bool)" << std::endl;

}

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

// SIDE-BY-SIDE COMPARISON

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

void comparison() {

std::cout << "\n=== SIDE-BY-SIDE COMPARISON (marearts.com)===" << std::endl;

// VECTOR: All same type, dynamic size

std::vector<double> grades = {85.5, 92.0, 78.5, 95.0};

// TUPLE: Different types, fixed size

std::tuple<std::string, int, double, char> student = {"Alice", 20, 89.5, 'A'};

std::cout << "VECTOR (grades):" << std::endl;

std::cout << " Type: vector<double>" << std::endl;

std::cout << " Values: ";

for (double grade : grades) {

std::cout << grade << " ";

}

std::cout << std::endl;

std::cout << " Access: grades[0], grades[1], grades[2]..." << std::endl;

std::cout << " Can add more: YES (grades.push_back(88.0))" << std::endl;

std::cout << "\nTUPLE (student info):" << std::endl;

std::cout << " Type: tuple<string, int, double, char>" << std::endl;

std::cout << " Values: " << std::get<0>(student) << ", "

<< std::get<1>(student) << ", "

<< std::get<2>(student) << ", "

<< std::get<3>(student) << std::endl;

std::cout << " Access: std::get<0>(student), std::get<1>(student)..." << std::endl;

std::cout << " Can add more: NO (fixed at compile time)" << std::endl;

}

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

// WHEN TO USE WHICH?

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

void when_to_use() {

std::cout << "\n=== WHEN TO USE WHICH? ===" << std::endl;

std::cout << "USE VECTOR WHEN:" << std::endl;

std::cout << " ✓ All elements are the same type" << std::endl;

std::cout << " ✓ You don't know size at compile time" << std::endl;

std::cout << " ✓ Size can change during runtime" << std::endl;

std::cout << " ✓ You want to loop through elements" << std::endl;

std::cout << " ✓ Examples: list of numbers, array of names, dynamic data" << std::endl;

std::cout << "\nUSE TUPLE WHEN:" << std::endl;

std::cout << " ✓ Elements have different types" << std::endl;

std::cout << " ✓ Size is fixed and known at compile time" << std::endl;

std::cout << " ✓ Each position has specific meaning" << std::endl;

std::cout << " ✓ You want type safety for each element" << std::endl;

std::cout << " ✓ Examples: coordinates (x,y), person data (name,age,score), config settings" << std::endl;

}

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

// PRACTICAL EXAMPLES

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

void practical_examples() {

std::cout << "\n=== PRACTICAL EXAMPLES ===" << std::endl;

// VECTOR EXAMPLES (same type, dynamic)

std::cout << "VECTOR use cases:" << std::endl;

std::vector<int> test_scores; // Dynamic list of test scores

test_scores.push_back(85);

test_scores.push_back(92);

test_scores.push_back(78); // Can keep adding

std::vector<std::string> names = {"Alice", "Bob", "Charlie"}; // List of names

std::cout << " Test scores: ";

for (int score : test_scores) std::cout << score << " ";

std::cout << std::endl;

// TUPLE EXAMPLES (different types, fixed)

std::cout << "\nTUPLE use cases:" << std::endl;

std::tuple<int, int> coordinates = {10, 20}; // 2D point (x, y)

std::tuple<std::string, int, char> student = {"Bob", 19, 'B'}; // Name, age, grade

std::tuple<float, float, float> rgb_color = {0.8f, 0.2f, 0.5f}; // Red, green, blue

auto [x, y] = coordinates; // C++17 structured binding

std::cout << " Coordinates: (" << x << ", " << y << ")" << std::endl;

std::cout << " Student: " << std::get<0>(student) << ", age " << std::get<1>(student)

<< ", grade " << std::get<2>(student) << std::endl;

}

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

// MEMORY AND PERFORMANCE

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

void memory_and_performance() {

std::cout << "\n=== MEMORY & PERFORMANCE ===" << std::endl;

// Vector - dynamic allocation

std::vector<int> vec = {1, 2, 3, 4, 5};

// Tuple - compile-time known, usually stack allocated

std::tuple<int, int, int, int, int> tup = {1, 2, 3, 4, 5};

std::cout << "VECTOR:" << std::endl;

std::cout << " Memory: Heap allocated (dynamic)" << std::endl;

std::cout << " Access: Runtime indexing vec[i]" << std::endl;

std::cout << " Size overhead: Stores capacity + size info" << std::endl;

std::cout << " Performance: Slight overhead for bounds checking" << std::endl;

std::cout << "\nTUPLE:" << std::endl;

std::cout << " Memory: Usually stack allocated (compile-time size)" << std::endl;

std::cout << " Access: Compile-time indexing std::get<N>()" << std::endl;

std::cout << " Size overhead: None (just the data)" << std::endl;

std::cout << " Performance: Maximum efficiency (compile-time optimized)" << std::endl;

}

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

// CANNOT MIX - ERROR EXAMPLES

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

void error_examples() {

std::cout << "\n=== WHAT YOU CANNOT DO ===" << std::endl;

std::cout << "VECTOR limitations:" << std::endl;

std::cout << " ✗ Cannot mix types: vector<int, string> // COMPILER ERROR" << std::endl;

std::cout << " ✗ All elements must be same type" << std::endl;

std::cout << "\nTUPLE limitations:" << std::endl;

std::cout << " ✗ Cannot resize: tuple.push_back() // NO SUCH METHOD" << std::endl;

std::cout << " ✗ Cannot loop easily (no iterators)" << std::endl;

std::cout << " ✗ Must know position at compile time: tuple[i] // ERROR" << std::endl;

// Demonstrate what works

std::vector<int> good_vector = {1, 2, 3}; // ✓ Same type

// std::vector<int, string> bad_vector; // ✗ COMPILER ERROR

std::tuple<int, std::string> good_tuple = {42, "hello"}; // ✓ Different types

// good_tuple.push_back(123); // ✗ NO SUCH METHOD

std::cout << "\nWorking examples:" << std::endl;

std::cout << " Vector: " << good_vector[0] << ", " << good_vector[1] << std::endl;

std::cout << " Tuple: " << std::get<0>(good_tuple) << ", " << std::get<1>(good_tuple) << std::endl;

}

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

// MAIN FUNCTION

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

int main() {

std::cout << "TUPLE vs VECTOR - Simple Comparison" << std::endl;

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

vector_example();

tuple_example();

comparison();

when_to_use();

practical_examples();

memory_and_performance();

error_examples();

std::cout << "\n=== QUICK SUMMARY ===" << std::endl;

std::cout << "VECTOR = Same type + Dynamic size + Runtime flexibility" << std::endl;

std::cout << "TUPLE = Different types + Fixed size + Compile-time safety" << std::endl;

std::cout << "\nThey solve different problems!" << std::endl;

return 0;

}

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

// KEY DIFFERENCES SUMMARY:

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

//

// VECTOR<T>:

// - All elements type T (same type)

// - Dynamic size (can grow/shrink)

// - Runtime access: vec[i]

// - Memory: heap allocated

// - Use for: lists, arrays, collections

//

// TUPLE<T1, T2, T3>:

// - Each element different type

// - Fixed size (compile-time)

// - Compile-time access: std::get<N>()

// - Memory: usually stack

// - Use for: structured data, coordinates, configs

//

// CHOOSE BASED ON:

// - Same vs different types?

// - Dynamic vs fixed size?

// - Runtime vs compile-time access?

C++ Tuple Tutorial,

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

// COMPLETE C++ TUPLE TUTORIAL

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

#include <tuple>

#include <iostream>

#include <string>

#include <typeinfo>

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

// PART 1: BASIC TUPLE CONCEPTS

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

void basic_tuple_usage() {

std::cout << "=== PART 1: Basic Tuple Usage ===" << std::endl;

// Creating tuples with values

std::tuple<int, float, std::string> data1 = {42, 3.14f, "hello"};

std::tuple<int, float, std::string> data2(100, 2.5f, "world");

auto data3 = std::make_tuple(200, 1.5f, "auto");

// Accessing elements

int first = std::get<0>(data1); // Gets 42

float second = std::get<1>(data1); // Gets 3.14f

std::string third = std::get<2>(data1); // Gets "hello"

std::cout << "data1: " << first << ", " << second << ", " << third << std::endl;

// Modifying elements

std::get<0>(data1) = 999;

std::cout << "Modified data1[0]: " << std::get<0>(data1) << std::endl;

// Tuple size

constexpr size_t size = std::tuple_size_v<decltype(data1)>;

std::cout << "Tuple size: " << size << std::endl;

}

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

// PART 2: TUPLES WITH DIFFERENT SIZES

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

void different_tuple_sizes() {

std::cout << "\n=== PART 2: Different Tuple Sizes ===" << std::endl;

std::tuple<int> single = {10}; // 1 element

std::tuple<int, int> pair = {20, 30}; // 2 elements

std::tuple<int, int, int> triple = {40, 50, 60}; // 3 elements

std::tuple<int, int, int, int, int> quintuple = {1, 2, 3, 4, 5}; // 5 elements

std::cout << "Single: " << std::get<0>(single) << std::endl;

std::cout << "Pair: " << std::get<0>(pair) << ", " << std::get<1>(pair) << std::endl;

std::cout << "Triple: " << std::get<0>(triple) << ", " << std::get<1>(triple) << ", " << std::get<2>(triple) << std::endl;

std::cout << "Quintuple[4]: " << std::get<4>(quintuple) << std::endl;

// Tuple sizes

std::cout << "Sizes: " << std::tuple_size_v<decltype(single)> << ", "

<< std::tuple_size_v<decltype(pair)> << ", "

<< std::tuple_size_v<decltype(triple)> << ", "

<< std::tuple_size_v<decltype(quintuple)> << std::endl;

}

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

// PART 3: MIXED TYPE TUPLES

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

void mixed_type_tuples() {

std::cout << "\n=== PART 3: Mixed Type Tuples ===" << std::endl;

// Different types in same tuple

std::tuple<int, float, double, char, bool, std::string> mixed = {

42, 3.14f, 2.718, 'A', true, "mixed"

};

std::cout << "Mixed tuple contents:" << std::endl;

std::cout << "int: " << std::get<0>(mixed) << std::endl;

std::cout << "float: " << std::get<1>(mixed) << std::endl;

std::cout << "double: " << std::get<2>(mixed) << std::endl;

std::cout << "char: " << std::get<3>(mixed) << std::endl;

std::cout << "bool: " << std::get<4>(mixed) << std::endl;

std::cout << "string: " << std::get<5>(mixed) << std::endl;

}

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

// PART 4: TUPLE_ELEMENT_T - EXTRACTING TYPES (NOT VALUES)

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

void tuple_element_type_extraction() {

std::cout << "\n=== PART 4: Type Extraction with std::tuple_element_t ===" << std::endl;

// Define a tuple TYPE (no actual values stored)

using MyTupleType = std::tuple<int, float, double, std::string>;

// Extract individual types from the tuple

using FirstType = std::tuple_element_t<0, MyTupleType>; // int

using SecondType = std::tuple_element_t<1, MyTupleType>; // float

using ThirdType = std::tuple_element_t<2, MyTupleType>; // double

using FourthType = std::tuple_element_t<3, MyTupleType>; // std::string

// Use the extracted types to create variables

FirstType var1 = 100; // int var1 = 100;

SecondType var2 = 2.5f; // float var2 = 2.5f;

ThirdType var3 = 3.14159; // double var3 = 3.14159;

FourthType var4 = "extracted"; // std::string var4 = "extracted";

std::cout << "Variables created from extracted types:" << std::endl;

std::cout << "var1 (int): " << var1 << std::endl;

std::cout << "var2 (float): " << var2 << std::endl;

std::cout << "var3 (double): " << var3 << std::endl;

std::cout << "var4 (string): " << var4 << std::endl;

// Show type information

std::cout << "Type information:" << std::endl;

std::cout << "FirstType: " << typeid(FirstType).name() << std::endl;

std::cout << "SecondType: " << typeid(SecondType).name() << std::endl;

std::cout << "ThirdType: " << typeid(ThirdType).name() << std::endl;

std::cout << "FourthType: " << typeid(FourthType).name() << std::endl;

}

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

// PART 5: TUPLES IN TEMPLATES

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

template <typename TupleType>

class TupleProcessor {

public:

// Extract types from the tuple

using FirstType = std::tuple_element_t<0, TupleType>;

using SecondType = std::tuple_element_t<1, TupleType>;

static constexpr size_t tuple_size = std::tuple_size_v<TupleType>;

void process() {

std::cout << "Processing tuple with " << tuple_size << " elements" << std::endl;

// Create variables using extracted types

FirstType first_var{}; // Default initialize

SecondType second_var{};

std::cout << "FirstType size: " << sizeof(FirstType) << " bytes" << std::endl;

std::cout << "SecondType size: " << sizeof(SecondType) << " bytes" << std::endl;

}

};

void tuples_in_templates() {

std::cout << "\n=== PART 5: Tuples in Templates ===" << std::endl;

// Different tuple types

using IntFloatTuple = std::tuple<int, float>;

using DoubleCharTuple = std::tuple<double, char>;

using StringBoolTuple = std::tuple<std::string, bool>;

// Create template instances with different tuple types

TupleProcessor<IntFloatTuple> processor1;

TupleProcessor<DoubleCharTuple> processor2;

TupleProcessor<StringBoolTuple> processor3;

processor1.process();

processor2.process();

processor3.process();

}

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

// PART 6: ADVANCED TUPLE TECHNIQUES

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

// Template that can handle tuples of any size

template <typename TupleType>

class FlexibleTupleHandler {

public:

static constexpr size_t size = std::tuple_size_v<TupleType>;

// Always safe - every tuple has at least element 0

using FirstType = std::tuple_element_t<0, TupleType>;

// Conditional type extraction (C++17 feature)

using SecondType = std::conditional_t<

(size >= 2),

std::tuple_element_t<1, TupleType>,

void // If tuple has less than 2 elements, use void

>;

void analyze_tuple() {

std::cout << "Tuple analysis:" << std::endl;

std::cout << " Size: " << size << std::endl;

std::cout << " FirstType size: " << sizeof(FirstType) << " bytes" << std::endl;

if constexpr (size >= 2) {

std::cout << " SecondType size: " << sizeof(SecondType) << " bytes" << std::endl;

} else {

std::cout << " No second element" << std::endl;

}

}

};

void advanced_tuple_techniques() {

std::cout << "\n=== PART 6: Advanced Tuple Techniques ===" << std::endl;

// Test with different sized tuples

FlexibleTupleHandler<std::tuple<int>> handler1; // 1 element

FlexibleTupleHandler<std::tuple<int, float>> handler2; // 2 elements

FlexibleTupleHandler<std::tuple<int, float, double>> handler3; // 3 elements

handler1.analyze_tuple();

handler2.analyze_tuple();

handler3.analyze_tuple();

}

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

// PART 7: PRACTICAL EXAMPLE - TYPE-BASED CONFIGURATION

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

// Define some configuration "types" (like layouts in GPU programming)

struct FastConfig { static constexpr const char* name = "Fast"; };

struct SmallConfig { static constexpr const char* name = "Small"; };

struct PreciseConfig { static constexpr const char* name = "Precise"; };

template <typename ConfigTuple>

class ConfigurableProcessor {

public:

using DataType = std::tuple_element_t<0, ConfigTuple>; // First: data type

using SpeedConfig = std::tuple_element_t<1, ConfigTuple>; // Second: speed config

using MemoryConfig = std::tuple_element_t<2, ConfigTuple>; // Third: memory config

void run() {

std::cout << "Running processor with:" << std::endl;

std::cout << " DataType size: " << sizeof(DataType) << " bytes" << std::endl;

std::cout << " Speed: " << SpeedConfig::name << std::endl;

std::cout << " Memory: " << MemoryConfig::name << std::endl;

}

};

void practical_example() {

std::cout << "\n=== PART 7: Practical Example ===" << std::endl;

// Different configurations using tuples

using Config1 = std::tuple<float, FastConfig, SmallConfig>;

using Config2 = std::tuple<double, PreciseConfig, FastConfig>;

using Config3 = std::tuple<int, SmallConfig, PreciseConfig>;

ConfigurableProcessor<Config1> processor1;

ConfigurableProcessor<Config2> processor2;

ConfigurableProcessor<Config3> processor3;

std::cout << "Configuration 1:" << std::endl;

processor1.run();

std::cout << "Configuration 2:" << std::endl;

processor2.run();

std::cout << "Configuration 3:" << std::endl;

processor3.run();

}

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

// PART 8: TUPLE UNPACKING AND STRUCTURED BINDINGS (C++17)

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

void tuple_unpacking() {

std::cout << "\n=== PART 8: Tuple Unpacking ===" << std::endl;

std::tuple<int, float, std::string> data = {42, 3.14f, "hello"};

// C++17 structured binding - unpack tuple into separate variables

auto [number, decimal, text] = data;

std::cout << "Unpacked values:" << std::endl;

std::cout << "number: " << number << std::endl;

std::cout << "decimal: " << decimal << std::endl;

std::cout << "text: " << text << std::endl;

// Modify unpacked variables (they're copies)

number = 999;

std::cout << "Modified number: " << number << std::endl;

std::cout << "Original tuple[0]: " << std::get<0>(data) << std::endl;

}

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

// MAIN FUNCTION - RUN ALL EXAMPLES

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

int main() {

std::cout << "C++ TUPLE COMPREHENSIVE TUTORIAL (MareArts)" << std::endl;

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

basic_tuple_usage();

different_tuple_sizes();

mixed_type_tuples();

tuple_element_type_extraction();

tuples_in_templates();

advanced_tuple_techniques();

practical_example();

tuple_unpacking();

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

std::cout << "1. Tuples can hold any number of elements (1, 2, 3, 5, 10...)" << std::endl;

std::cout << "2. Tuples can store VALUES or define TYPES" << std::endl;

std::cout << "3. std::get<N>(tuple) accesses values" << std::endl;

std::cout << "4. std::tuple_element_t<N, TupleType> extracts types" << std::endl;

std::cout << "5. Templates + tuples = powerful type-based programming" << std::endl;

std::cout << "6. Perfect for configuration systems and generic programming" << std::endl;

return 0;

}

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

// KEY TAKEAWAYS:

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

//

// 1. TUPLE BASICS:

// - std::tuple<T1, T2, T3> can hold any types

// - Access with std::get<0>(tuple), std::get<1>(tuple), etc.

// - Size with std::tuple_size_v<TupleType>

//

// 2. TYPE EXTRACTION:

// - std::tuple_element_t<N, TupleType> gets the Nth type

// - Used at compile-time, not runtime

// - Perfect for template programming

//

// 3. TEMPLATE USAGE:

// - Tuples as template parameters enable type-based configuration

// - One template + multiple tuple types = multiple specialized classes

// - Compiler generates different code for each tuple type

//

// 4. FLEXIBILITY:

// - Any tuple size works

// - Mix any types in same tuple

// - Conditional type extraction for varying sizes

//

// 5. PRACTICAL APPLICATIONS:

// - Configuration systems (data type + algorithm choice)

// - Generic programming (same code, different types)

// - Type-safe parameter passing

// - Template specialization without code duplication

Claude Code install shell script

 install Claude Code using this shell script

.

#!/bin/bash

# install-claude.sh

# Installs Node.js 18+, npm, and Claude Code CLI, handling common conflicts.

set -e

echo "=== [1/5] Removing conflicting Node.js and libnode-dev packages ==="

apt-get remove -y nodejs nodejs-doc libnode-dev || true

echo "=== [2/5] Cleaning up package manager ==="

apt-get autoremove -y

apt-get clean

echo "=== [3/5] Installing Node.js 18.x and npm ==="

curl -fsSL https://deb.nodesource.com/setup_18.x | bash -

apt-get install -y nodejs

# Ensure npm is installed (should be bundled with Node.js 18.x)

if ! command -v npm &>/dev/null; then

echo "npm not found, installing..."

apt-get install -y npm

fi

echo "=== [4/5] Verifying Node.js and npm installation ==="

node --version

npm --version

echo "=== [5/5] Installing Claude Code CLI ==="

npm install -g @anthropic-ai/claude-code

echo "=== Claude Code CLI installed successfully! ==="

echo "Run 'claude' to get started."

..

Thank you!

Open Source License Commercial Use Guide

Understanding Commercial Rights in Open Source Licenses

📋 Legend

✅ Free: Commercial use is completely free without restrictions

⚠️ Conditional: Commercial use allowed with specific requirements

❌ Not Free: Commercial use prohibited or requires separate licensing

❓ Varies: Check specific license terms

💻 Traditional Software Licenses

Permissive Licenses (Business-Friendly)

License	Commercial Use	Key Requirements	Notes
Apache-2.0	✅ Free	Attribution, state changes, include license	Very permissive, patent grant included
MIT	✅ Free	Include copyright notice and license	One of the most permissive licenses
BSD-2-clause	✅ Free	Include copyright notice	Very permissive
BSD-3-clause	✅ Free	Include copyright notice, no endorsement	Slightly more restrictive than 2-clause
BSD-3-clause-clear	✅ Free	Same as BSD-3 but clarifies no patent rights	Patent rights explicitly not granted
ISC	✅ Free	Include copyright notice	Similar to MIT, very permissive
Unlicense	✅ Free	None - public domain dedication	No restrictions whatsoever
CC0-1.0	✅ Free	None - public domain dedication	Creative Commons "No Rights Reserved"
WTFPL	✅ Free	None	"Do What The F*** You Want" - no restrictions
Zlib	✅ Free	Don't misrepresent origin	Very permissive
PostgreSQL	✅ Free	Include copyright notice	Similar to MIT
BSL-1.0	✅ Free	Include license text if source distributed	Boost Software License - very permissive
PDDL	✅ Free	None - public domain	Public Domain Dedication License
NCSA	✅ Free	Include copyright and license	Similar to BSD/MIT

Copyleft Licenses (Conditional)

License	Commercial Use	Key Requirements	Notes
GPL-2.0/3.0	⚠️ Conditional	Must open source entire work	Strong copyleft - viral license
AGPL-3.0	⚠️ Conditional	Like GPL + network use = distribution	Strictest copyleft
LGPL-2.1/3.0	⚠️ Conditional	Share LGPL library mods, allow relinking	Lesser GPL - library-friendly
MPL-2.0	⚠️ Conditional	Share modifications of MPL code only	File-level copyleft
EPL-1.0/2.0	⚠️ Conditional	Share modifications, patent grant	Eclipse Public License
AFL-3.0	⚠️ Conditional	Attribution, share source if distributed	Academic Free License
OSL-3.0	⚠️ Conditional	Share source if distributed, attribution	Open Software License
ECL-2.0	⚠️ Conditional	Attribution, state changes	Educational Community License
MS-PL	⚠️ Conditional	Include license, share source if distributed	Microsoft Public License
EUPL-1.1/1.2	⚠️ Conditional	Share modifications	European Union Public License
Artistic-2.0	⚠️ Conditional	Attribution, share modifications	Perl's license
OFL-1.1	⚠️ Conditional	Keep font name, share modifications	Open Font License
GFDL	⚠️ Conditional	Include license, preserve sections	GNU Free Documentation License
LPPL-1.3c	⚠️ Conditional	Rename if modified	LaTeX Project Public License

🎨 Creative Commons Licenses

License	Commercial Use	Key Requirements	Notes
CC-BY-2.0/2.5/3.0/4.0	⚠️ Conditional	Attribution required	Creative Commons with attribution
CC-BY-SA-3.0/4.0	⚠️ Conditional	Attribution + share-alike	Must use same license for derivatives
CC-BY-ND-4.0	⚠️ Conditional	Attribution, no derivatives	Can't modify the work
CC-BY-NC-2.0/3.0/4.0	❌ Not Free	Non-commercial only	Commercial use prohibited
CC-BY-NC-SA-2.0/3.0/4.0	❌ Not Free	Non-commercial + share-alike	Commercial use prohibited
CC-BY-NC-ND-3.0/4.0	❌ Not Free	Non-commercial + no derivatives	Most restrictive CC license

🤖 AI Model Licenses

License	Commercial Use	Key Requirements	Notes
Llama2	⚠️ Conditional	Free up to 700M users, attribution	Meta's Llama 2 license
Llama3/3.1/3.2/3.3	⚠️ Conditional	Free up to 700M users, attribution	Updated Meta license
Llama4	⚠️ Conditional	Assumed similar to Llama3	Not yet released
Gemma	⚠️ Conditional	Prohibited uses list, attribution	Google's Gemma license
OpenRAIL	⚠️ Conditional	Use restrictions, attribution	Responsible AI License
OpenRAIL++	⚠️ Conditional	More restrictions than OpenRAIL	Enhanced responsible use
CreativeML-OpenRAIL-M	⚠️ Conditional	Use restrictions, attribution	For ML models
BigScience-OpenRAIL-M	⚠️ Conditional	Use restrictions, share license	BLOOM model license
BigScience-BLOOM-RAIL-1.0	⚠️ Conditional	Specific BLOOM restrictions	Original BLOOM license
BigCode-OpenRAIL-M	⚠️ Conditional	Code generation restrictions	For code models
DeepFloyd-IF-License	❌ Not Free	Research only by default	Commercial license needed
Apple-AMLA	⚠️ Conditional	Apple's specific terms	Apple Machine Learning
Apple-ASCL	⚠️ Conditional	Apple sample code terms	Limited to Apple platforms
Intel-Research	❌ Not Free	Research purposes only	Intel's research license

📊 Data Licenses

License	Commercial Use	Key Requirements	Notes
CDLA-Permissive-1.0/2.0	✅ Free	Attribution for data	Community Data License
CDLA-Sharing-1.0	⚠️ Conditional	Share data improvements	Copyleft for data
ODC-By	⚠️ Conditional	Attribution for databases	Open Data Commons
ODbL	⚠️ Conditional	Share-alike for databases	Open Database License
C-UDA	⚠️ Conditional	Computational use only	Computational Use of Data
Etalab-2.0	✅ Free	Attribution	French government open license

🔍 Generic/Other Licenses

License	Commercial Use	Key Requirements	Notes
Other	❓ Varies	Check specific license	Not a standard license
CC	❓ Varies	Depends on CC variant	Generic Creative Commons
BSD	✅ Free	Usually permissive	Generic BSD reference
GPL	⚠️ Conditional	Strong copyleft	Generic GPL reference
LGPL	⚠️ Conditional	Weak copyleft	Generic LGPL reference
LGPL-LR	⚠️ Conditional	LGPL with special exceptions	Language resources variant

⚠️ Important Notes

1. Always read the full license text - This guide provides general guidance but specific versions may have additional terms
2. "Conditional" means you CAN use commercially BUT must follow requirements - These aren't necessarily restrictive
3. Attribution is usually simple - Just credit the original authors/source
4. Copyleft/Share-alike - You must license derivatives under the same terms
5. Patent grants - Some licenses (Apache, EPL) explicitly grant patent rights
6. Compatibility - Not all licenses can be combined in one project
7. AI/ML licenses often have use-case restrictions - Even if commercial use is allowed, certain uses may be prohibited

🏆 Quick Reference Guide

Most Business-Friendly Licenses

• MIT - Minimal requirements, maximum freedom
• Apache-2.0 - Patent protection included
• BSD variants - Simple and permissive
• ISC - MIT-style simplicity
• Unlicense - Public domain dedication
• CC0-1.0 - No rights reserved

Decision Tree for Choosing a License

• Want maximum freedom? → MIT or Apache-2.0
• Building a library? → LGPL or MPL-2.0
• Want improvements shared back? → GPL
• Running a SaaS? → AGPL (if you want to enforce sharing)
• Publishing content? → CC-BY (attribution only)
• Using AI models? → Check user count limits carefully

Most Restrictive for Commercial Use

• AGPL-3.0 - Requires source disclosure even for SaaS
• CC-BY-NC-ND - No commercial use, no modifications
• Research-only licenses - Intel-Research, DeepFloyd-IF
• Any "NC" (non-commercial) license

💡 Pro Tips

1. For startups: Stick to MIT or Apache-2.0 for maximum flexibility
2. For open source projects: Consider your goals - permissive for adoption, copyleft for contributions
3. For using AI models: Always check the user/revenue thresholds
4. For content creators: CC-BY allows commercial use with attribution
5. For enterprises: Create an approved license list to streamline decisions

---

Last updated: June 2025

Disclaimer: This guide is for informational purposes only and does not constitute legal advice. Always consult with a legal professional for specific licensing questions.

C++ Template Parameter Packs with sequence

C++ Template Parameter Packs with sequence

Simple Explanation

sequence<x,x,x> is a template that holds a compile-time list of integer values. It's like a

tuple but for numbers only, and the values are fixed at compile time. It's commonly used in

template metaprogramming to pass multiple integer parameters to other templates.

Simple Usage Example

.

#include <iostream>

// A simple sequence template that holds compile-time integers

template<int... Values>

struct sequence {

static constexpr int size = sizeof...(Values);

// Function to print all values

static void print() {

((std::cout << Values << " "), ...); // C++17 fold expression

std::cout << std::endl;

}

};

// Template that uses sequence to create arrays

template<typename T, int... Dims>

class MultiArray {

private:

static constexpr int total_size = (Dims * ...); // multiply all dimensions

T data[total_size];

public:

MultiArray() {

std::cout << "Created array with dimensions: ";

((std::cout << Dims << "x"), ...);

std::cout << " = " << total_size << " elements" << std::endl;

}

static constexpr int get_total_size() { return total_size; }

};

int main() {

// Create sequences with different values

sequence<1, 8> block_warps; // 1 block, 8 warps

sequence<16, 16, 8> tensor_dims; // 16x16x8 tensor

sequence<2, 4, 8, 16> powers_of_2; // sequence of powers

std::cout << "Block warps: ";

block_warps.print(); // Output: 1 8

std::cout << "Tensor dims: ";

tensor_dims.print(); // Output: 16 16 8

std::cout << "Powers of 2: ";

powers_of_2.print(); // Output: 2 4 8 16

// Use sequence values as template parameters

MultiArray<float, 10, 20> matrix2d; // 10x20 = 200 elements

MultiArray<int, 4, 4, 4> tensor3d; // 4x4x4 = 64 elements

return 0;

}

..

Output:

  Block warps: 1 8

  Tensor dims: 16 16 8

  Powers of 2: 2 4 8 16

  Created array with dimensions: 10x20x = 200 elements

  Created array with dimensions: 4x4x4x = 64 elements

Thank you. 🙏