Jarrett Revels jrevels

## TypedDataFrames.jl
params{T}(::Type{T}) = T.parameters

# Parameterize column types and fields
# by utilizing tuples
type DataFrame{C<:Tuple, F<:Tuple}
    columns::C
    fields::Type{F}
    function DataFrame(columns::C, fields::Type{F})
        nrows = length(first(columns))
        equallengths = true

## hessian_bug_check_issue_29.jl
using ForwardDiff

function check_failure_ratio(test_hessf::Function, input::Array, original::Array, max_iter=10e6)
    bad_versions = 0

    for iter = 1:max_iter
        if maximum(abs(test_hessf(input) - original)) > 1
            bad_versions += 1;
        end
    end

## GeneralComplex.jl
# This file is a naive implementation of numbers of the form x + y*i where i^2 = p

#######################
# GeneralComplex type #
#######################

immutable GeneralComplex{p,T} <: Number
    x::T
    y::T
end

## parallel-reload-bug.jl
@everywhere module A
    immutable Foo{T}
        x::T
    end

    cross(a::Foo, b::Foo) = Foo(a.x * b.x)

    function reload_cross(a, b)
        include(joinpath(pwd(), "parallel-reload-bug.jl"))
        return A.cross(a, b)

## mpi_pagerank_kernel0.jl
# execute by running `➜ mpiexec -n $NUM_PROCS julia mpi_pagerank_kernel0.jl`

import MPI

MPI.Init()

######################
# KronGraph500NoPerm #
######################

## generated_partials.jl
function tupexpr(f, N)
    ex = Expr(:tuple, [f(i) for i=1:N]...)
    return quote
        @inbounds return $(ex)
    end
end

@inline iszero_tuple(::Tuple{}) = true
@inline zero_tuple(::Type{Tuple{}}) = tuple()
@inline one_tuple(::Type{Tuple{}}) = tuple()

## kl_diff.jl
using ForwardDiff
using BenchmarkTools

function gen_beta_kl_obj(alpha2, beta2)
    lgamma_alpha2 = lgamma(alpha2)
    lgamma_beta2 = lgamma(beta2)
    return x -> begin
        alpha1, beta1 = x
        alpha_diff = alpha1 - alpha2
        beta_diff = beta1 - beta2

## autoencode.jl
using BenchmarkTools
using ReverseDiff: @forward, GradientTape, gradient!, compile

# Similar to XDiff's @diff_rule, except it gets the derivative automatically via forward mode.
# In future versions, `@forward` will no longer be necessary.
@forward logistic(x::Real) = 1 / (1 + exp(-x))

# This is how I would write this for ReverseDiff usage if parser fusion didn't mess things up.
# In the future, this form will be performant (all the pieces already exist, they just have
# to be hooked up).

## cassette_perf.jl
using Cassette

function rosenbrock(x)
    a = one(eltype(x))
    b = 100.0
    result = zero(a)
    for i in 1:length(x)-1
        result += (a - x[i])^2 + b*(x[i+1] - x[i]^2)^2
    end
    return result

## recursive_ad.jl
# This script requires an up-to-date ForwardDiff, ReverseDiff, and Julia v0.6 installation.

using ForwardDiff, ReverseDiff

D_f(f) = x::Number -> ForwardDiff.derivative(f, x)

# ReverseDiff's API only supports array inputs, so we just wrap our scalar input in a
# 1-element array and extract our scalar derivative from the returned gradient array
D_r(f) = x::Number -> ReverseDiff.gradient(y -> f(y[1]), [x])[1]
	params{T}(::Type{T}) = T.parameters

	# Parameterize column types and fields
	# by utilizing tuples
	type DataFrame{C<:Tuple, F<:Tuple}
	columns::C
	fields::Type{F}
	function DataFrame(columns::C, fields::Type{F})
	nrows = length(first(columns))
	equallengths = true
	using ForwardDiff

	function check_failure_ratio(test_hessf::Function, input::Array, original::Array, max_iter=10e6)
	bad_versions = 0

	for iter = 1:max_iter
	if maximum(abs(test_hessf(input) - original)) > 1
	bad_versions += 1;
	end
	end
	# This file is a naive implementation of numbers of the form x + y*i where i^2 = p

	#######################
	# GeneralComplex type #
	#######################

	immutable GeneralComplex{p,T} <: Number
	x::T
	y::T
	end
	@everywhere module A
	immutable Foo{T}
	x::T
	end

	cross(a::Foo, b::Foo) = Foo(a.x * b.x)

	function reload_cross(a, b)
	include(joinpath(pwd(), "parallel-reload-bug.jl"))
	return A.cross(a, b)
	# execute by running `➜ mpiexec -n $NUM_PROCS julia mpi_pagerank_kernel0.jl`

	import MPI

	MPI.Init()

	######################
	# KronGraph500NoPerm #
	######################
	function tupexpr(f, N)
	ex = Expr(:tuple, [f(i) for i=1:N]...)
	return quote
	@inbounds return $(ex)
	end
	end

	@inline iszero_tuple(::Tuple{}) = true
	@inline zero_tuple(::Type{Tuple{}}) = tuple()
	@inline one_tuple(::Type{Tuple{}}) = tuple()
	using ForwardDiff
	using BenchmarkTools

	function gen_beta_kl_obj(alpha2, beta2)
	lgamma_alpha2 = lgamma(alpha2)
	lgamma_beta2 = lgamma(beta2)
	return x -> begin
	alpha1, beta1 = x
	alpha_diff = alpha1 - alpha2
	beta_diff = beta1 - beta2
	using BenchmarkTools
	using ReverseDiff: @forward, GradientTape, gradient!, compile

	# Similar to XDiff's @diff_rule, except it gets the derivative automatically via forward mode.
	# In future versions, `@forward` will no longer be necessary.
	@forward logistic(x::Real) = 1 / (1 + exp(-x))

	# This is how I would write this for ReverseDiff usage if parser fusion didn't mess things up.
	# In the future, this form will be performant (all the pieces already exist, they just have
	# to be hooked up).
	using Cassette

	function rosenbrock(x)
	a = one(eltype(x))
	b = 100.0
	result = zero(a)
	for i in 1:length(x)-1
	result += (a - x[i])^2 + b*(x[i+1] - x[i]^2)^2
	end
	return result
	# This script requires an up-to-date ForwardDiff, ReverseDiff, and Julia v0.6 installation.

	using ForwardDiff, ReverseDiff

	D_f(f) = x::Number -> ForwardDiff.derivative(f, x)

	# ReverseDiff's API only supports array inputs, so we just wrap our scalar input in a
	# 1-element array and extract our scalar derivative from the returned gradient array
	D_r(f) = x::Number -> ReverseDiff.gradient(y -> f(y[1]), [x])[1]