tnlogy/micrograd.lua

## micrograd.lua
--# Main
-- NN

function setup()
    -- Neural Network of 3 layers with 3 inputs
    local x = {Value(1), Value(1), Value(1)}
    local layer1 = Layer(3, 4) -- layer of 4 neurons with 3 inputs
    local layer2 = Layer(4, 4) -- layer of 4 neurons with 4 inputs
    local layer3 = Layer(4, 1) -- layer of 1 neuron with 4 inputs

    -- try to learn the output values y_train for the given test examples x_train
    x_train = {
        {2.0, 3.0, -1.0},
        {3.0, -1.0, 0.5},
        {0.5, 1.0, 1.0},
        {1.0, 1.0, -1.0}
    }

    y_train = {1.0, -1.0, -1.0, 1.0}

    local alpha = 0.01;
    for epoch = 1,200 do
        local total_loss = 0
        for i, x_in in ipairs(x_train) do
            local input = {}
            for j, x in ipairs(x_in) do
                table.insert(input, Value(x))
            end
            local out = layer3:call(layer2:call(layer1:call(input)))
            local loss = (out[1] - Value(y_train[i])):pow(Value(2))
            loss:backward()
            total_loss = total_loss + loss.value

            -- learn new values for the weights of the network
            layer1:update_grad(alpha)
            layer2:update_grad(alpha)
            layer3:update_grad(alpha)
        end
        if epoch % 20 == 0 then
            print("epoch:", epoch, " total loss:", total_loss)
        end
    end

    for i, x_in in ipairs(x_train) do
        local input = {}
        for j, x in ipairs(x_in) do
            table.insert(input, Value(x))
        end

        print("NN output:", layer3:call(layer2:call(layer1:call(input)))[1].value, "Actual value:", y_train[i])
    end
end

function example_linear_regression()
    -- try to learn values for this function
    function f_target(x)
        return 4 * x - 5
    end

    local x = Value(2)
    local w = Value(3)
    local b = Value(4)

    local alpha = 0.01
    for i = 1,300 do
        local total_loss = 0
        for x_in = 0,10 do
            local f = w * Value(x_in) + b
            local y_hat = Value(f_target(x_in))
            local loss = (f - y_hat):pow(Value(2))
            loss:backward()
            w.value = w.value - alpha * w.grad -- learn new values for w and b
            b.value = b.value - alpha * b.grad
            total_loss = total_loss + loss.value
        end
        print("epoch:", i, " total loss:", total_loss)
    end
    print("Learned w:", w.value, " b:", b.value)
end

--# Value
Value = class()

VALUE = 0
ADD = 1
SUB = 2
MUL = 3
POW = 4
TANH = 5

function Value:init(value, op, left, right)
    self.value, self.op, self.left, self.right = value, op or VALUE, left, right
    self.grad = 0
    local mt = getmetatable(self)

    mt.__mul = function (self, other)
        return Value(self.value * other.value, MUL, self, other)
    end
    mt.__add = function (self, other)
        return Value(self.value + other.value, ADD, self, other)
    end
    mt.__sub = function (self, other)
        return Value(self.value - other.value, SUB, self, other)
    end
end

function Value:pow(other)
    return Value(self.value ^ other.value, POW, self, other)
end

function Value:tanh()
    local v = math.exp(self.value * 2)
    return Value((v - 1) / (v + 1), TANH, self)
end

function Value:backward()
    local visited = {}
    local topo = {}
    local function build_topo(v)
        if not visited[v] then
            visited[v] = true
            if v.left then build_topo(v.left) end
            if v.right then build_topo(v.right) end
            v.grad = 0 -- zero grad
            table.insert(topo, v)
        end
    end
    build_topo(self)

    self.grad = 1
    for i = #topo, 1, -1 do
        topo[i]:calculate_local_gradient()
    end
end

function Value:calculate_local_gradient()
    if self.op == ADD or self.op == SUB then
        self.left.grad = self.left.grad + self.grad
        self.right.grad = self.right.grad + self.grad
    elseif self.op == MUL then
        self.left.grad = self.left.grad + self.right.value * self.grad
        self.right.grad = self.right.grad + self.left.value * self.grad
    elseif self.op == POW then
        self.left.grad = self.left.grad + (self.right.value * self.left.value ^ (self.right.value - 1)) * self.grad
    elseif self.op == TANH then
        self.left.grad = self.left.grad + (1 - self.value ^ 2) * self.grad
    end
end

--# NeuralNetwork
Neuron = class()

function Neuron:init(number_of_inputs)
    self.w = {}
    for i = 1,number_of_inputs do
        table.insert(self.w, Value(math.random(-1.0, 1.0)))
    end
    self.b = Value(0)
end

function Neuron:call(x)
    local sum = self.b
    for i, w in ipairs(self.w) do
        sum = sum + (w * x[i])
    end
    return sum:tanh()
end

function Neuron:update_grad(alpha)
    for i, w in ipairs(self.w) do
        w.value = w.value - alpha * w.grad
    end
    self.b.value = self.b.value - alpha * self.b.grad
end

Layer = class()

function Layer:init(number_of_inputs, number_of_outputs)
    self.neurons = {}
    for o = 1,number_of_outputs do
        table.insert(self.neurons, Neuron(number_of_inputs))
    end
end

function Layer:call(x)
    local res = {}
    for i, n in ipairs(self.neurons) do
        table.insert(res, n:call(x))
    end
    return res
end

function Layer:update_grad(alpha)
    for i, n in ipairs(self.neurons) do
        n:update_grad(alpha)
    end
end
	--# Main
	-- NN

	function setup()
	-- Neural Network of 3 layers with 3 inputs
	local x = {Value(1), Value(1), Value(1)}
	local layer1 = Layer(3, 4) -- layer of 4 neurons with 3 inputs
	local layer2 = Layer(4, 4) -- layer of 4 neurons with 4 inputs
	local layer3 = Layer(4, 1) -- layer of 1 neuron with 4 inputs

	-- try to learn the output values y_train for the given test examples x_train
	x_train = {
	{2.0, 3.0, -1.0},
	{3.0, -1.0, 0.5},
	{0.5, 1.0, 1.0},
	{1.0, 1.0, -1.0}
	}

	y_train = {1.0, -1.0, -1.0, 1.0}

	local alpha = 0.01;
	for epoch = 1,200 do
	local total_loss = 0
	for i, x_in in ipairs(x_train) do
	local input = {}
	for j, x in ipairs(x_in) do
	table.insert(input, Value(x))
	end
	local out = layer3:call(layer2:call(layer1:call(input)))
	local loss = (out[1] - Value(y_train[i])):pow(Value(2))
	loss:backward()
	total_loss = total_loss + loss.value

	-- learn new values for the weights of the network
	layer1:update_grad(alpha)
	layer2:update_grad(alpha)
	layer3:update_grad(alpha)
	end
	if epoch % 20 == 0 then
	print("epoch:", epoch, " total loss:", total_loss)
	end
	end

	for i, x_in in ipairs(x_train) do
	local input = {}
	for j, x in ipairs(x_in) do
	table.insert(input, Value(x))
	end

	print("NN output:", layer3:call(layer2:call(layer1:call(input)))[1].value, "Actual value:", y_train[i])
	end
	end

	function example_linear_regression()
	-- try to learn values for this function
	function f_target(x)
	return 4 * x - 5
	end

	local x = Value(2)
	local w = Value(3)
	local b = Value(4)

	local alpha = 0.01
	for i = 1,300 do
	local total_loss = 0
	for x_in = 0,10 do
	local f = w * Value(x_in) + b
	local y_hat = Value(f_target(x_in))
	local loss = (f - y_hat):pow(Value(2))
	loss:backward()
	w.value = w.value - alpha * w.grad -- learn new values for w and b
	b.value = b.value - alpha * b.grad
	total_loss = total_loss + loss.value
	end
	print("epoch:", i, " total loss:", total_loss)
	end
	print("Learned w:", w.value, " b:", b.value)
	end

	--# Value
	Value = class()

	VALUE = 0
	ADD = 1
	SUB = 2
	MUL = 3
	POW = 4
	TANH = 5

	function Value:init(value, op, left, right)
	self.value, self.op, self.left, self.right = value, op or VALUE, left, right
	self.grad = 0
	local mt = getmetatable(self)

	mt.__mul = function (self, other)
	return Value(self.value * other.value, MUL, self, other)
	end
	mt.__add = function (self, other)
	return Value(self.value + other.value, ADD, self, other)
	end
	mt.__sub = function (self, other)
	return Value(self.value - other.value, SUB, self, other)
	end
	end

	function Value:pow(other)
	return Value(self.value ^ other.value, POW, self, other)
	end

	function Value:tanh()
	local v = math.exp(self.value * 2)
	return Value((v - 1) / (v + 1), TANH, self)
	end

	function Value:backward()
	local visited = {}
	local topo = {}
	local function build_topo(v)
	if not visited[v] then
	visited[v] = true
	if v.left then build_topo(v.left) end
	if v.right then build_topo(v.right) end
	v.grad = 0 -- zero grad
	table.insert(topo, v)
	end
	end
	build_topo(self)

	self.grad = 1
	for i = #topo, 1, -1 do
	topo[i]:calculate_local_gradient()
	end
	end

	function Value:calculate_local_gradient()
	if self.op == ADD or self.op == SUB then
	self.left.grad = self.left.grad + self.grad
	self.right.grad = self.right.grad + self.grad
	elseif self.op == MUL then
	self.left.grad = self.left.grad + self.right.value * self.grad
	self.right.grad = self.right.grad + self.left.value * self.grad
	elseif self.op == POW then
	self.left.grad = self.left.grad + (self.right.value * self.left.value ^ (self.right.value - 1)) * self.grad
	elseif self.op == TANH then
	self.left.grad = self.left.grad + (1 - self.value ^ 2) * self.grad
	end
	end

	--# NeuralNetwork
	Neuron = class()

	function Neuron:init(number_of_inputs)
	self.w = {}
	for i = 1,number_of_inputs do
	table.insert(self.w, Value(math.random(-1.0, 1.0)))
	end
	self.b = Value(0)
	end

	function Neuron:call(x)
	local sum = self.b
	for i, w in ipairs(self.w) do
	sum = sum + (w * x[i])
	end
	return sum:tanh()
	end

	function Neuron:update_grad(alpha)
	for i, w in ipairs(self.w) do
	w.value = w.value - alpha * w.grad
	end
	self.b.value = self.b.value - alpha * self.b.grad
	end

	Layer = class()

	function Layer:init(number_of_inputs, number_of_outputs)
	self.neurons = {}
	for o = 1,number_of_outputs do
	table.insert(self.neurons, Neuron(number_of_inputs))
	end
	end

	function Layer:call(x)
	local res = {}
	for i, n in ipairs(self.neurons) do
	table.insert(res, n:call(x))
	end
	return res
	end

	function Layer:update_grad(alpha)
	for i, n in ipairs(self.neurons) do
	n:update_grad(alpha)
	end
	end