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	diff --git a/CMakeLists.txt b/CMakeLists.txt
	index 6c685d2..5cdddc8 100644
	--- a/CMakeLists.txt
	+++ b/CMakeLists.txt
	@@ -1,274 +1,274 @@
	cmake_minimum_required(VERSION 3.1 FATAL_ERROR)

	set(CMAKE_LEGACY_CYGWIN_WIN32 0)
	set(CMAKE_EXPORT_COMPILE_COMMANDS ON)

	project("HEJ" VERSION 2.0.4 LANGUAGES C CXX)

	# Set a default build type if none was specified
	set(default_build_type "RelWithDebInfo")

	if(NOT CMAKE_BUILD_TYPE AND NOT CMAKE_CONFIGURATION_TYPES)
	message(STATUS "Setting build type to '${default_build_type}' as none was specified.")
	set(CMAKE_BUILD_TYPE "${default_build_type}" CACHE
	STRING "Choose the type of build." FORCE)
	# Set the possible values of build type for cmake-gui
	set_property(CACHE CMAKE_BUILD_TYPE PROPERTY STRINGS
	"Debug" "Release" "MinSizeRel" "RelWithDebInfo")
	endif()

	## Flags for the compiler. No warning allowed.
	if (CMAKE_COMPILER_IS_GNUCC OR CMAKE_COMPILER_IS_GNUCXX)
	set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -Wall -Wextra")
	elseif (MSVC)
	set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} /W4 /WX /EHsc")
	endif()
	set(CMAKE_CXX_STANDARD_REQUIRED ON)
	set(CMAKE_CXX_STANDARD 14)

	## Create Version
	set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} "${CMAKE_SOURCE_DIR}/cmake/Modules/")


	# Get the latest abbreviated commit hash of the working branch
	execute_process(
	COMMAND git rev-parse HEAD
	WORKING_DIRECTORY ${CMAKE_CURRENT_SOURCE_DIR}
	OUTPUT_VARIABLE PROJECT_GIT_REVISION
	OUTPUT_STRIP_TRAILING_WHITESPACE
	)
	# Get the current working branch
	execute_process(
	COMMAND git rev-parse --abbrev-ref HEAD
	WORKING_DIRECTORY ${CMAKE_CURRENT_SOURCE_DIR}
	OUTPUT_VARIABLE PROJECT_GIT_BRANCH
	OUTPUT_STRIP_TRAILING_WHITESPACE
	)

	## target directories for install
	set(INSTALL_INCLUDE_DIR_BASE include)
	set(INSTALL_INCLUDE_DIR ${INSTALL_INCLUDE_DIR_BASE}/HEJ)
	set(INSTALL_BIN_DIR bin)
	set(INSTALL_LIB_DIR lib)
	set(INSTALL_CONFIG_DIR lib/cmake/HEJ)

	## Template files
	configure_file( ${CMAKE_CURRENT_SOURCE_DIR}/cmake/Templates/Version.hh.in
	${PROJECT_BINARY_DIR}/include/HEJ/Version.hh @ONLY )

	configure_file( ${CMAKE_CURRENT_SOURCE_DIR}/cmake/Templates/HEJ-config.cc.in
	${PROJECT_BINARY_DIR}/src/bin/HEJ-config.cc @ONLY )

	# Generate CMake config file
	include(CMakePackageConfigHelpers)
	configure_package_config_file(
	cmake/Templates/hej-config.cmake.in
	${CMAKE_CURRENT_BINARY_DIR}/${INSTALL_CONFIG_DIR}/hej-config.cmake
	INSTALL_DESTINATION ${INSTALL_CONFIG_DIR}
	PATH_VARS INSTALL_INCLUDE_DIR_BASE INSTALL_LIB_DIR
	)
	write_basic_package_version_file(
	${CMAKE_CURRENT_BINARY_DIR}/${INSTALL_CONFIG_DIR}/hej-config-version.cmake
	COMPATIBILITY SameMajorVersion
	)
	install(
	FILES ${CMAKE_CURRENT_BINARY_DIR}/${INSTALL_CONFIG_DIR}/hej-config.cmake
	${CMAKE_CURRENT_BINARY_DIR}/${INSTALL_CONFIG_DIR}/hej-config-version.cmake
	DESTINATION ${INSTALL_CONFIG_DIR})

	## Add directories and find dependences
	include_directories(${CMAKE_CURRENT_SOURCE_DIR}/include ${PROJECT_BINARY_DIR}/include)

	find_package(fastjet REQUIRED)
	include_directories(${fastjet_INCLUDE_DIRS})
	find_package(CLHEP 2.3 REQUIRED)
	include_directories(${CLHEP_INCLUDE_DIRS})
	find_package(LHAPDF REQUIRED)
	include_directories(${LHAPDF_INCLUDE_DIRS})
	## Amend unintuitive behaviour of FindBoost.cmake
	## Priority of BOOST_ROOT over BOOSTROOT matches FindBoost.cmake
	## at least for cmake 3.12
	if(DEFINED BOOST_ROOT)
	message("BOOST_ROOT set - only looking for Boost in ${BOOST_ROOT}")
	set(Boost_NO_BOOST_CMAKE ON)
	elseif(DEFINED BOOSTROOT)
	message("BOOSTROOT set - only looking for Boost in ${BOOSTROOT}")
	set(Boost_NO_BOOST_CMAKE ON)
	endif()
	find_package(Boost REQUIRED COMPONENTS iostreams)
	include_directories(${Boost_INCLUDE_DIRS})
	find_package(yaml-cpp) # requiring yaml does not work with fedora
	include_directories(${YAML_CPP_INCLUDE_DIR})
	if(${EXCLUDE_HepMC})
	message(STATUS "Skipping HepMC")
	# avoid "unused variable" warning if EXCLUDE_rivet is set by user
	set(EXCLUDE_rivet TRUE)
	else()
	find_package(HepMC 2)
	endif()
	if(${HepMC_FOUND})
	set(
	CMAKE_CXX_FLAGS
	"${CMAKE_CXX_FLAGS} -DHEJ_BUILD_WITH_HepMC_VERSION=${HepMC_VERSION_MAJOR}"
	)
	include_directories(${HepMC_INCLUDE_DIRS})
	if(${EXCLUDE_rivet})
	message(STATUS "Skipping rivet")
	else()
	find_package(rivet)
	endif()
	if(${rivet_FOUND})
	include_directories(${rivet_INCLUDE_DIRS})
	set(
	CMAKE_CXX_FLAGS
	"${CMAKE_CXX_FLAGS} -DHEJ_BUILD_WITH_RIVET"
	)
	endif()
	endif()
	if(${EXCLUDE_QCDloop})
	message(STATUS "Skipping QCDloop")
	else()
	find_package(QCDloop 2)
	endif()
	if(${QCDloop_FOUND})
	set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -DHEJ_BUILD_WITH_QCDLOOP")
	include_directories(SYSTEM ${QCDloop_INCLUDE_DIRS})
	endif()

	add_subdirectory(src)

	## define executable
	add_executable(HEJ src/bin/HEJ.cc)

	## link libraries
	target_link_libraries(HEJ hejlib)

	add_executable(HEJ-config src/bin/HEJ-config.cc)

	file(GLOB hej_headers ${CMAKE_CURRENT_SOURCE_DIR}/include/HEJ/.hh ${PROJECT_BINARY_DIR}/include/HEJ/.hh)
	file(GLOB lhef_headers ${CMAKE_CURRENT_SOURCE_DIR}/include/LHEF/*.h)
	install(FILES ${hej_headers} DESTINATION ${INSTALL_INCLUDE_DIR})
	install(FILES ${lhef_headers} DESTINATION include/LHEF/)
	install(TARGETS HEJ HEJ-config DESTINATION ${INSTALL_BIN_DIR})

	## tests
	enable_testing()
	set(tst_dir "${CMAKE_CURRENT_SOURCE_DIR}/t")
	add_executable(test_classify ${tst_dir}/test_classify.cc)
	add_executable(test_psp ${tst_dir}/test_psp.cc)
	add_executable(test_ME_generic ${tst_dir}/test_ME_generic.cc)
	add_executable(check_res ${tst_dir}/check_res.cc)
	add_executable(check_lhe ${tst_dir}/check_lhe.cc)
	add_library(scales SHARED ${tst_dir}/scales.cc)
	add_executable(test_scale_import ${tst_dir}/test_scale_import)
	add_executable(test_descriptions ${tst_dir}/test_descriptions)
	add_executable(test_scale_arithmetics ${tst_dir}/test_scale_arithmetics)
	-add_executable(test_colour_flow ${tst_dir}/test_colour_flow)
	+add_executable(test_colours ${tst_dir}/test_colours)
	target_link_libraries(test_classify hejlib)
	target_link_libraries(test_psp hejlib)
	target_link_libraries(test_ME_generic hejlib)
	target_link_libraries(check_res hejlib)
	target_link_libraries(check_lhe hejlib)
	target_link_libraries(test_scale_import hejlib)
	target_link_libraries(test_descriptions hejlib)
	target_link_libraries(test_scale_arithmetics hejlib)
	-target_link_libraries(test_colour_flow hejlib)
	+target_link_libraries(test_colours hejlib)

	## add tests
	add_test(
	NAME t_classify
	COMMAND test_classify ${tst_dir}/classify.lhe.gz
	)
	add_test(
	NAME t_psp
	COMMAND test_psp ${tst_dir}/psp_gen.lhe.gz
	)
	set(tst_ME_data_dir "${tst_dir}/ME_data")
	add_test(
	NAME t_ME_j
	COMMAND test_ME_generic ${tst_ME_data_dir}/config_mtinf.yml ${tst_ME_data_dir}/ME_jets.dat ${tst_ME_data_dir}/PSP_jets.lhe.gz
	)
	add_test(
	NAME t_ME_h
	COMMAND test_ME_generic ${tst_ME_data_dir}/config_mtinf.yml ${tst_ME_data_dir}/ME_h_mtinf.dat ${tst_ME_data_dir}/PSP_h.lhe.gz
	)
	if(${QCDloop_FOUND})
	add_test(
	NAME t_ME_h_mt
	COMMAND test_ME_generic ${tst_ME_data_dir}/config_mt.yml ${tst_ME_data_dir}/ME_h_mt.dat ${tst_ME_data_dir}/PSP_h.lhe.gz
	)
	add_test(
	NAME t_ME_h_mtmb
	COMMAND test_ME_generic ${tst_ME_data_dir}/config_mtmb.yml ${tst_ME_data_dir}/ME_h_mtmb.dat ${tst_ME_data_dir}/PSP_h.lhe.gz
	)
	endif()
	add_test(
	NAME t_2j
	COMMAND check_res ${tst_dir}/2j.lhe.gz 3.49391e+07 419684
	)
	add_test(
	NAME t_3j
	COMMAND check_res ${tst_dir}/3j.lhe.gz 2.37902e+06 25746.6
	)
	add_test(
	NAME t_4j
	COMMAND check_res ${tst_dir}/4j.lhe.gz 603713 72822.6
	)
	add_test(
	NAME t_h_3j
	COMMAND check_res ${tst_dir}/h_3j.lhe.gz 0.821622 0.0220334
	)
	add_test(
	NAME t_h_3j_uno
	COMMAND check_res ${tst_dir}/h_3j_uno.lhe.gz 0.0261968 0.000341549 uno
	)
	if(${HepMC_FOUND})
	file(READ "${tst_dir}/jet_config.yml" config)
	file(WRITE "${tst_dir}/jet_config_withHepMC.yml" "${config} - tst.hepmc")
	if(${rivet_FOUND})
	file(READ "${tst_dir}/jet_config_withHepMC.yml" config)
	file(WRITE "${tst_dir}/jet_config_withRivet.yml" "${config}\n\nanalysis:\n rivet: MC_XS\n output: tst")
	add_test(
	NAME t_main
	COMMAND HEJ ${tst_dir}/jet_config_withRivet.yml ${tst_dir}/2j.lhe.gz
	)
	else()
	add_test(
	NAME t_main
	COMMAND HEJ ${tst_dir}/jet_config_withHepMC.yml ${tst_dir}/2j.lhe.gz
	)
	endif()
	if(${HepMC_VERSION_MAJOR} GREATER 2)
	add_executable(check_hepmc ${tst_dir}/check_hepmc.cc)
	target_link_libraries(check_hepmc hejlib)
	add_test(
	NAME t_hepmc
	COMMAND check_hepmc tst.hepmc
	)
	endif()
	else()
	add_test(
	NAME t_main
	COMMAND HEJ ${tst_dir}/jet_config.yml ${tst_dir}/2j.lhe.gz
	)
	endif()
	add_test(
	NAME t_lhe
	COMMAND check_lhe tst.lhe
	)
	add_test(
	NAME t_scale_import
	COMMAND test_scale_import ${tst_dir}/jet_config_with_import.yml
	)
	add_test(
	NAME t_descriptions
	COMMAND test_descriptions
	)
	add_test(
	NAME t_scale_arithmetics
	COMMAND test_scale_arithmetics ${tst_dir}/jet_config.yml ${tst_dir}/2j.lhe.gz
	)
	add_test(
	NAME t_colour_flow
	- COMMAND test_colour_flow
	+ COMMAND test_colours
	)
	diff --git a/Changes.md b/Changes.md
	index 50718b9..b6282a6 100644
	--- a/Changes.md
	+++ b/Changes.md
	@@ -1,35 +1,35 @@
	# Version 2.0

	## 2.X.0

	* Made `MatrixElement::tree_kin` and `MatrixElement::tree_param` public
	* Allow multiplication and division of multiple scale functions e.g.
	`H_T/2*m_j1j2`
	* Follow HepMC convention for particle Status codes: incoming = 11,
	decaying = 2, outgoing = 1 (unchanged)
	* Added optional Colour charges to particles (`Particle.colour`)
	- Colours are read from and written to LHE files
	- Colour connection in the HEJ limit can be generated via
	- `Event::generate_colour_flow` (automatically done in the resummation)
	+ `Event::generate_colours` (automatically done in the resummation)

	## 2.0.4

	* Fixed wrong path of `HEJ_INCLUDE_DIR` in `hej-config.cmake`
	* Correctly include rivet headers
	* New `EXCLUDE_package` variable in `cmake` to not interface to specific
	packages
	* Consistent search and include for side packages in `cmake`

	## 2.0.3

	* Fixed parsing of (numerical factor) * (base scale) in configuration
	* Don't change scale names, but sanitise Rivet output file names instead

	## 2.0.2

	* Changed scale names to `"_over_"` and `"_times_"` for proper file names (was
	`"/"` and `"*"` before)

	## 2.0.1

	* Fixed name of fixed-order generator in error message.
	diff --git a/FixedOrderGen/src/EventGenerator.cc b/FixedOrderGen/src/EventGenerator.cc
	index cc35e45..c80e32a 100644
	--- a/FixedOrderGen/src/EventGenerator.cc
	+++ b/FixedOrderGen/src/EventGenerator.cc
	@@ -1,82 +1,82 @@
	#include "EventGenerator.hh"

	#include "Process.hh"
	#include "Beam.hh"
	#include "JetParameters.hh"
	#include "PhaseSpacePoint.hh"

	#include "HEJ/Event.hh"
	#include "HEJ/config.hh"

	namespace HEJFOG{
	EventGenerator::EventGenerator(
	Process process,
	Beam beam,
	HEJ::ScaleGenerator scale_gen,
	JetParameters jets,
	int pdf_id,
	double subl_change,
	unsigned int subl_channels,
	ParticlesPropMap particles_properties,
	HEJ::HiggsCouplingSettings Higgs_coupling,
	HEJ::RNG & ran
	):
	pdf_{pdf_id, beam.particles[0], beam.particles[1]},
	ME_{
	[this](double mu){ return pdf_.Halphas(mu); },
	HEJ::MatrixElementConfig{
	false,
	std::move(Higgs_coupling)
	}
	},
	scale_gen_{std::move(scale_gen)},
	process_{std::move(process)},
	jets_{std::move(jets)},
	beam_{std::move(beam)},
	subl_change_{subl_change},
	subl_channels_{subl_channels},
	particles_properties_{std::move(particles_properties)},
	ran_{ran}
	{
	}

	HEJ::Event EventGenerator::gen_event(){
	HEJFOG::PhaseSpacePoint psp{
	process_,
	jets_,
	pdf_, beam_.energy,
	subl_change_, subl_channels_,
	particles_properties_,
	ran_
	};
	status_ = psp.status();
	if(status_ != good) return {};

	HEJ::Event ev = scale_gen_(
	HEJ::Event{
	to_UnclusteredEvent(std::move(psp)),
	jets_.def, jets_.min_pt
	}
	);

	- ev.generate_colour_flow(ran_);
	+ ev.generate_colours(ran_);

	const double shat = HEJ::shat(ev);
	const double xa = (ev.incoming()[0].E()-ev.incoming()[0].pz())/(2.*beam_.energy);
	const double xb = (ev.incoming()[1].E()+ev.incoming()[1].pz())/(2.*beam_.energy);

	// evaluate matrix element on this point
	const auto ME_weights = ME_.tree(ev);
	ev.central().weight = ME_weights.central/(shatshat);
	ev.central().weight *= pdf_.pdfpt(0,xa,ev.central().muf, ev.incoming()[0].type);
	ev.central().weight *= pdf_.pdfpt(0,xb,ev.central().muf, ev.incoming()[1].type);
	for(size_t i = 0; i < ev.variations().size(); ++i){
	auto & var = ev.variations(i);
	var.weight = ME_weights.variations[i]/(shatshat);
	var.weight *= pdf_.pdfpt(0,xa,var.muf, ev.incoming()[0].type);
	var.weight *= pdf_.pdfpt(0,xb,var.muf, ev.incoming()[1].type);
	}
	return ev;
	}

	}
	diff --git a/doc/developer_manual/developer_manual.tex b/doc/developer_manual/developer_manual.tex
	index e3dc12d..5989086 100644
	--- a/doc/developer_manual/developer_manual.tex
	+++ b/doc/developer_manual/developer_manual.tex
	@@ -1,1472 +1,1472 @@
	\documentclass[a4paper,11pt]{article}

	\usepackage{fourier}
	\usepackage[T1]{fontenc}
	\usepackage{microtype}
	\usepackage{geometry}
	\usepackage{enumitem}
	\setlist[description]{leftmargin=\parindent,labelindent=\parindent}
	\usepackage{amsmath}
	\usepackage{amssymb}
	\usepackage[utf8x]{inputenc}
	\usepackage{graphicx}
	\usepackage{xcolor}
	\usepackage{todonotes}
	\usepackage{listings}
	\usepackage{xspace}
	\usepackage{tikz}
	\usepackage{subcaption}
	\usetikzlibrary{arrows.meta}
	\usetikzlibrary{shapes}
	\usetikzlibrary{calc}
	\usepackage[colorlinks,linkcolor={blue!50!black}]{hyperref}
	\graphicspath{{build/figures/}{figures/}}
	\emergencystretch \hsize

	\newcommand{\HEJ}{{\tt HEJ}\xspace}
	\newcommand{\HIGHEJ}{\emph{High Energy Jets}\xspace}
	\newcommand{\cmake}{\href{https://cmake.org/}{cmake}\xspace}
	\newcommand{\html}{\href{https://www.w3.org/html/}{html}\xspace}
	\newcommand{\YAML}{\href{http://yaml.org/}{YAML}\xspace}
	\newcommand{\QCDloop}{\href{https://github.com/scarrazza/qcdloop}{QCDloop}\xspace}

	\newcommand{\as}{\alpha_s}
	\DeclareRobustCommand{\mathgraphics}[1]{\vcenter{\hbox{\includegraphics{#1}}}}
	\def\spa#1.#2{\left\langle#1\,#2\right\rangle}
	\def\spb#1.#2{\left[#1\,#2\right]} \def\spaa#1.#2.#3{\langle\mskip-1mu{#1} \|
	#2 \| {#3}\mskip-1mu\rangle} \def\spbb#1.#2.#3{[\mskip-1mu{#1} \| #2 \|
	{#3}\mskip-1mu]} \def\spab#1.#2.#3{\langle\mskip-1mu{#1} \| #2 \|
	{#3}\mskip-1mu\rangle} \def\spba#1.#2.#3{\langle\mskip-1mu{#1}^+ \| #2 \|
	{#3}^+\mskip-1mu\rangle} \def\spav#1.#2.#3{\\|\mskip-1mu{#1} \| #2 \|
	{#3}\mskip-1mu\\|^2} \def\jc#1.#2.#3{j^{#1}_{#2#3}}

	\definecolor{darkgreen}{rgb}{0,0.4,0}
	\lstset{ %
	backgroundcolor=\color{lightgray}, % choose the background color; you must add \usepackage{color} or \usepackage{xcolor}
	basicstyle=\footnotesize\usefont{T1}{DejaVuSansMono-TLF}{m}{n}, % the size of the fonts that are used for the code
	breakatwhitespace=false, % sets if automatic breaks should only happen at whitespace
	breaklines=false, % sets automatic line breaking
	captionpos=t, % sets the caption-position to bottom
	commentstyle=\color{red}, % comment style
	deletekeywords={...}, % if you want to delete keywords from the given language
	escapeinside={\%}{)}, % if you want to add LaTeX within your code
	extendedchars=true, % lets you use non-ASCII characters; for 8-bits encodings only, does not work with UTF-8
	frame=false, % adds a frame around the code
	keepspaces=true, % keeps spaces in text, useful for keeping indentation of code (possibly needs columns=flexible)
	keywordstyle=\color{blue}, % keyword style
	otherkeywords={}, % if you want to add more keywords to the set
	numbers=none, % where to put the line-numbers; possible values are (none, left, right)
	numbersep=5pt, % how far the line-numbers are from the code
	rulecolor=\color{black}, % if not set, the frame-color may be changed on line-breaks within not-black text (e.g. comments (green here))
	showspaces=false, % show spaces everywhere adding particular underscores; it overrides 'showstringspaces'
	showstringspaces=false, % underline spaces within strings only
	showtabs=false, % show tabs within strings adding particular underscores
	stepnumber=2, % the step between two line-numbers. If it's 1, each line will be numbered
	stringstyle=\color{gray}, % string literal style
	tabsize=2, % sets default tabsize to 2 spaces
	title=\lstname,
	emph={},
	emphstyle=\color{darkgreen}
	}

	\begin{document}

	\tikzstyle{mynode}=[rectangle split,rectangle split parts=2, draw,rectangle split part fill={lightgray, none}]


	\title{HEJ 2 developer manual}
	\author{}
	\maketitle
	\tableofcontents

	\newpage

	\section{Overview}
	\label{sec:overview}

	HEJ 2 is a C++ program and library implementing an algorithm to
	apply \HIGHEJ resummation~\cite{Andersen:2008ue,Andersen:2008gc} to
	pre-generated fixed-order events. This document is intended to give an
	overview over the concepts and structure of this implementation.

	\subsection{Project structure}
	\label{sec:project}

	HEJ 2 is developed under the \href{https://git-scm.com/}{git}
	version control system. The main repository is on the IPPP
	\href{https://gitlab.com/}{gitlab} server under
	\url{https://gitlab.dur.scotgrid.ac.uk/hej/hej}. To get a local
	copy, get an account on the gitlab server and use
	\begin{lstlisting}[language=sh,caption={}]
	git clone git@gitlab.dur.scotgrid.ac.uk:hej/hej.git
	\end{lstlisting}
	This should create a directory \texttt{hej} with the following
	contents:
	\begin{description}
	\item[doc:] Contains additional documentation, see section~\ref{sec:doc}.
	\item[include:] Contains the C++ header files.
	\item[src:] Contains the C++ source files.
	\item[t:] Contains the source code for the automated tests.
	\item[CMakeLists.txt:] Configuration file for the \cmake build
	system. See section~\ref{sec:cmake}.
	\item[cmake:] Auxiliary files for \cmake. This includes modules for
	finding installed software in \texttt{cmake/Modules} and templates for
	code generation during the build process in \texttt{cmake/Templates}.
	\item[config.yml:] Sample configuration file for running HEJ 2.
	\item[FixedOrderGen:] Contains the code for the fixed-order generator,
	see section~\ref{sec:HEJFOG}.
	\end{description}
	In the following all paths are given relative to the
	\texttt{hej} directory.

	\subsection{Documentation}
	\label{sec:doc}

	The \texttt{doc} directory contains user documentation in
	\texttt{doc/sphinx} and the configuration to generate source code
	documentation in \texttt{doc/doxygen}.

	The user documentation explains how to install and run HEJ 2. The
	format is
	\href{http://docutils.sourceforge.net/rst.html}{reStructuredText}, which
	is mostly human-readable. Other formats, like \html, can be generated with the
	\href{http://www.sphinx-doc.org/en/master/}{sphinx} generator with
	\begin{lstlisting}[language=sh,caption={}]
	make html
	\end{lstlisting}


	To document the source code we use
	\href{https://www.stack.nl/~dimitri/doxygen/}{doxygen}. To generate
	\html documentation, use the command
	\begin{lstlisting}[language=sh,caption={}]
	doxygen Doxyfile
	\end{lstlisting}
	in the \texttt{doc/doxygen} directory.

	\subsection{Build system}
	\label{sec:cmake}

	For the most part, HEJ 2 is a library providing classes and
	functions that can be used to add resummation to fixed-order events. In
	addition, there is a relatively small executable program leveraging this
	library to read in events from an input file and produce resummation
	events. Both the library and the program are built and installed with
	the help of \cmake.
	Debug information can be turned on by using
	\begin{lstlisting}[language=sh,caption={}]
	cmake base/directory -DCMAKE_BUILD_TYPE=Debug
	make install
	\end{lstlisting}
	This facilitates the use of debuggers like \href{https://www.gnu.org/software/gdb/}{gdb}.

	The main \cmake configuration file is \texttt{CMakeLists.txt}. It defines the
	compiler flags, software prerequisites, header and source files used to
	build HEJ 2, and the automated tests.
	\texttt{cmake/Modules} contains module files that help with the
	detection of the software prerequisites and \texttt{cmake/Templates}
	template files for the automatic generation of header and
	source files. For example, this allows to only keep the version
	information in one central location (\texttt{CMakeLists.txt}) and
	automatically generate a header file from the template \texttt{Version.hh.in} to propagate this to the C++ code.

	\subsection{General coding guidelines}
	\label{sec:notes}

	The goal is to make the HEJ 2 code well-structured and
	readable. Here are a number of guidelines to this end.

	\begin{description}
	\item[Observe the boy scout rule.] Always leave the code cleaner
	than how you found it. Ugly hacks can be useful for testing, but
	shouldn't make their way into the main branch.
	\item[Ask if something is unclear.] Often there is a good reason why
	code is written the way it is. Sometimes that reason is only obvious to
	the original author (use \lstinline!git blame! to find them), in which
	case they should be poked to add a comment. Sometimes there is no good
	reason, but nobody has had the time to come up with something better,
	yet. In some places the code might just be bad.
	\item[Don't break tests.] There are a number of tests in the \texttt{t}
	directory, which can be run with \lstinline!make test!. Ideally, all
	tests should run successfully in each git revision. If your latest
	commit broke a test and you haven't pushed to the central repository
	yet, you can fix it with \lstinline!git commit --amend!. If an earlier
	local commit broke a test, you can use \lstinline!git rebase -i! if
	you feel confident.
	\item[Test your new code.] When you add some new functionality, also add an
	automated test. This can be useful even if you don't know the
	``correct'' result because it prevents the code from changing its behaviour
	silently in the future. \href{http://www.valgrind.org/}{valgrind} is a
	very useful tool to detect potential memory leaks.
	\item[Stick to the coding style.] It is somewhat easier to read code
	that has a uniform coding and indentation style. We don't have a
	strict style, but it helps if your code looks similar to what is
	already there.
	\end{description}

	\section{Program flow}
	\label{sec:flow}

	A run of the HEJ 2 program has three stages: initialisation,
	event processing, and cleanup. The following sections outline these
	stages and their relations to the various classes and functions in the
	code. Unless denoted otherwise, all classes and functions are part of
	the \lstinline!HEJ! namespace. The code for the HEJ 2 program is
	in \texttt{src/bin/HEJ.cc}, all other code comprises the HEJ 2
	library. Classes and free functions are usually implemented in header
	and source files with a corresponding name, i.e. the code for
	\lstinline!MyClass! can usually be found in
	\texttt{include/HEJ/MyClass.hh} and \texttt{src/MyClass.cc}.

	\subsection{Initialisation}
	\label{sec:init}

	The first step is to load and parse the \YAML configuration file. The
	entry point for this is the \lstinline!load_config! function and the
	related code can be found in \texttt{include/HEJ/YAMLreader.hh},
	\texttt{include/HEJ/config.hh} and the corresponding \texttt{.cc} files
	in the \texttt{src} directory. The implementation is based on the
	\href{https://github.com/jbeder/yaml-cpp}{yaml-cpp} library.
	The \lstinline!load_config! function returns a \lstinline!Config! object
	containing all settings. To detect potential mistakes as early as
	possible, we throw an exception whenever one of the following errors
	occurs:
	\begin{itemize}
	\item There is an unknown option in the \YAML file.
	\item A setting is invalid, for example a string is given where a number
	would be expected.
	\item An option value is not set.
	\end{itemize}
	The third rule is sometimes relaxed for ``advanced'' settings with an
	obvious default, like for importing custom scales or analyses.

	The information stored in the \lstinline!Config! object is then used to
	initialise various objects required for the event processing stage
	described in section~\ref{sec:processing}. First, the
	\lstinline!get_analysis! function creates an object that inherits from
	the \lstinline!Analysis! interface.\footnote{In the context of C++ the
	proper technical expression is ``pure abstract class''.} Using an
	interface allows us to decide the concrete type of the analysis at run
	time instead of having to make a compile-time decision. Depending on the
	settings, \lstinline!get_analysis! creates either a user-defined
	analysis loaded from an external library (see the user documentation
	\url{https://hej.web.cern.ch/HEJ/doc/current/user/}) or the default \lstinline!EmptyAnalysis!, which does
	nothing.

	Together with a number of further objects, whose roles are described in
	section~\ref{sec:processing}, we also initialise the global random
	number generator. We again use an interface to defer deciding the
	concrete type until the program is actually run. Currently, we support the
	\href{https://mixmax.hepforge.org/}{MIXMAX}
	(\texttt{include/HEJ/Mixmax.hh}) and Ranlux64
	(\texttt{include/HEJ/Ranlux64.hh}) random number generators, both are provided
	by \href{http://proj-clhep.web.cern.ch/}{CLHEP}.

	We also set up a \lstinline!LHEF::Reader! object (see
	\href{http://home.thep.lu.se/~leif/LHEF/}{\texttt{include/LHEF/LHEF.h}}) for
	reading events from a file in the Les
	Houches event file format~\cite{Alwall:2006yp}. A small wrapper around
	the
	\href{https://www.boost.org/doc/libs/1_67_0/libs/iostreams/doc/index.html}{boost
	iostreams} library allows us to also read event files compressed with
	\href{https://www.gnu.org/software/gzip/}{gzip}. The wrapper code is in
	\texttt{include/HEJ/stream.hh} and the \texttt{src/stream.cc}.

	\subsection{Event processing}
	\label{sec:processing}

	In the second stage events are continously read from the event
	file. After jet clustering, a number of corresponding resummation events
	are generated for each input event and fed into the analysis and a
	number of output files. The roles of various classes and functions are
	illustrated in the following flow chart:
	\begin{center}
	\begin{tikzpicture}[node distance=2cm and 5mm]
	\node (reader) [mynode]
	{\lstinline!LHEF::Reader::readEvent!\nodepart{second}{read event}};
	\node
	(cluster) [mynode,below=of reader]
	{\lstinline!Event! constructor\nodepart{second}{cluster jets}};
	\node
	(resum) [mynode,below=of cluster]
	{\lstinline!EventReweighter::reweight!\nodepart{second}{perform resummation}};
	\node
	(cut) [mynode,below=of resum]
	{\lstinline!Analysis::pass_cuts!\nodepart{second}{apply cuts}};
	\node
	(fill) [mynode,below left=of cut]
	{\lstinline!Analysis::fill!\nodepart{second}{analyse event}};
	\node
	(write) [mynode,below right=of cut]
	{\lstinline!CombinedEventWriter::write!\nodepart{second}{write out event}};
	\node
	(control) [below=of cut] {};
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(reader.south) -- node[left] {\lstinline!LHEF::HEPEUP!} (cluster.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(cluster.south) -- node[left] {\lstinline!Event!} (resum.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(resum.south) -- (cut.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(resum.south)+(7mm, 0cm)$) -- ($(cut.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(resum.south)-(7mm, 0cm)$) -- node[left] {\lstinline!Event!} ($(cut.north)-(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cut.south)-(3mm,0mm)$) .. controls ($(control)-(3mm,0mm)$) ..node[left] {\lstinline!Event!} (fill.east);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cut.south)-(3mm,0mm)$) .. controls ($(control)-(3mm,0mm)$) .. (write.west);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cut.south)+(3mm,0mm)$) .. controls ($(control)+(3mm,0mm)$) .. (fill.east);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cut.south)+(3mm,0mm)$) .. controls ($(control)+(3mm,0mm)$) ..node[right] {\lstinline!Event!} (write.west);
	\end{tikzpicture}
	\end{center}
	The resummation is performed by the \lstinline!EventReweighter! class,
	which is described in more detail in section~\ref{sec:resum}. The
	\lstinline!CombinedEventWriter! writes events to zero or more output
	files. To this end, it contains a number of objects implementing the
	\lstinline!EventWriter! interface. These event writers typically write
	the events to a file in a given format. We currently have the
	\lstinline!LesHouchesWriter! for event files in the Les Houches Event
	File format and the \lstinline!HepMCWriter! for the
	\href{https://hepmc.web.cern.ch/hepmc/}{HepMC} format (Version 2 and 3).

	\subsection{Resummation}
	\label{sec:resum}

	In the \lstinline!EventReweighter::reweight! member function, we first
	classify the input fixed-order event (FKL, unordered, non-HEJ, \dots)
	and decide according to the user settings whether to discard, keep, or
	resum the event. If we perform resummation for the given event, we
	generate a number of trial \lstinline!PhaseSpacePoint! objects. Phase
	space generation is discussed in more detail in
	section~\ref{sec:pspgen}. We then perform jet clustering according to
	the settings for the resummation jets on each
	\lstinline!PhaseSpacePoint!, update the factorisation and
	renormalisation scale in the resulting \lstinline!Event! and reweight it
	according to the ratio of pdf factors and \HEJ matrix elements between
	resummation and original fixed-order event:
	\begin{center}
	\begin{tikzpicture}[node distance=1.5cm and 5mm]
	\node (in) {};
	\node (treat) [diamond,draw,below=of in,minimum size=3.5cm,
	label={[anchor=west, inner sep=8pt]west:discard},
	label={[anchor=east, inner sep=14pt]east:keep},
	label={[anchor=south, inner sep=20pt]south:reweight}
	] {};
	\draw (treat.north west) -- (treat.south east);
	\draw (treat.north east) -- (treat.south west);
	\node
	(psp) [mynode,below=of treat]
	{\lstinline!PhaseSpacePoint! constructor};
	\node
	(cluster) [mynode,below=of psp]
	{\lstinline!Event! constructor\nodepart{second}{cluster jets}};
	\node
	(colour) [mynode,below=of cluster]
	- {\lstinline!Event::generate_colour_flow()!\nodepart{second}{generate particle colour}};
	+ {\lstinline!Event::generate_colours()!\nodepart{second}{generate particle colour}};
	\node
	(gen_scales) [mynode,below=of colour]
	{\lstinline!ScaleGenerator::operator()!\nodepart{second}{update scales}};
	\node
	(rescale) [mynode,below=of gen_scales]
	{\lstinline!PDF::pdfpt!,
	\lstinline!MatrixElement!\nodepart{second}{reweight}};
	\node (out) [below of=rescale] {};

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(in.south) -- node[left] {\lstinline!Event!} (treat.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(treat.south) -- node[left] {\lstinline!Event!} (psp.north);

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(psp.south) -- (cluster.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(psp.south)+(7mm, 0cm)$) -- ($(cluster.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(psp.south)-(7mm, 0cm)$) -- node[left]
	{\lstinline!PhaseSpacePoint!} ($(cluster.north)-(7mm, 0cm)$);

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(cluster.south) -- (colour.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cluster.south)+(7mm, 0cm)$) -- ($(colour.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(cluster.south)-(7mm, 0cm)$) -- node[left]
	{\lstinline!Event!} ($(colour.north)-(7mm, 0cm)$);

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(colour.south) -- (gen_scales.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(colour.south)+(7mm, 0cm)$) -- ($(gen_scales.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(colour.south)-(7mm, 0cm)$) -- node[left]
	{\lstinline!Event!} ($(gen_scales.north)-(7mm, 0cm)$);

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(gen_scales.south) -- (rescale.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(gen_scales.south)+(7mm, 0cm)$) -- ($(rescale.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(gen_scales.south)-(7mm, 0cm)$) -- node[left]
	{\lstinline!Event!} ($(rescale.north)-(7mm, 0cm)$);

	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(rescale.south) -- (out.north);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(rescale.south)+(7mm, 0cm)$) -- ($(out.north)+(7mm, 0cm)$);
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	($(rescale.south)-(7mm, 0cm)$) -- node[left]
	{\lstinline!Event!} ($(out.north)-(7mm, 0cm)$);

	\node (helper) at ($(treat.east) + (15mm,0cm)$) {};
	\draw[-{Latex[length=3mm, width=1.5mm]}]
	(treat.east) -- ($(treat.east) + (15mm,0cm)$)
	-- node[left] {\lstinline!Event!} (helper \|- gen_scales.east) -- (gen_scales.east)
	;
	\end{tikzpicture}
	\end{center}

	\subsection{Phase space point generation}
	\label{sec:pspgen}

	The resummed and matched \HEJ cross section for pure jet production of
	FKL configurations is given by (cf. eq. (3) of~\cite{Andersen:2018tnm})
	\begin{align}
	\label{eq:resumdijetFKLmatched2}
	% \begin{split}
	\sigma&_{2j}^\mathrm{resum, match}=\sum_{f_1, f_2}\ \sum_m
	\prod_{j=1}^m\left(
	\int_{p_{j\perp}^B=0}^{p_{j\perp}^B=\infty}
	\frac{\mathrm{d}^2\mathbf{p}_{j\perp}^B}{(2\pi)^3}\ \int
	\frac{\mathrm{d} y_j^B}{2} \right) \
	(2\pi)^4\ \delta^{(2)}\!\!\left(\sum_{k=1}^{m}
	\mathbf{p}_{k\perp}^B\right)\nonumber\\
	&\times\ x_a^B\ f_{a, f_1}(x_a^B, Q_a^B)\ x_b^B\ f_{b, f_2}(x_b^B, Q_b^B)\
	\frac{\overline{\left\|\mathcal{M}_\text{LO}^{f_1f_2\to f_1g\cdots
	gf_2}\big(\big\{p^B_j\big\}\big)\right\|}^2}{(\hat {s}^B)^2}\nonumber\\
	& \times (2\pi)^{-4+3m}\ 2^m \nonumber\\
	&\times\ \sum_{n=2}^\infty\
	\int_{p_{1\perp}=p_{\perp,\mathrm{min}} }^{p_{1\perp}=\infty}
	\frac{\mathrm{d}^2\mathbf{p}_{1\perp}}{(2\pi)^3}\
	\int_{p_{n\perp}=p_{\perp,\mathrm{min}}}^{p_{n\perp}=\infty}
	\frac{\mathrm{d}^2\mathbf{p}_{n\perp}}{(2\pi)^3}\
	\prod_{i=2}^{n-1}\int_{p_{i\perp}=\lambda}^{p_{i\perp}=\infty}
	\frac{\mathrm{d}^2\mathbf{p}_{i\perp}}{(2\pi)^3}\ (2\pi)^4\ \delta^{(2)}\!\!\left(\sum_{k=1}^n
	\mathbf{p}_{k\perp}\right )\\
	&\times \ \mathbf{T}_y \prod_{i=1}^n
	\left(\int \frac{\mathrm{d} y_i}{2}\right)\
	\mathcal{O}_{mj}^e\
	\left(\prod_{l=1}^{m-1}\delta^{(2)}(\mathbf{p}_{\mathcal{J}_{l}\perp}^B -
	\mathbf{j}_{l\perp})\right)\
	\left(\prod_{l=1}^m\delta(y^B_{\mathcal{J}_l}-y_{\mathcal{J}_l})\right)
	\ \mathcal{O}_{2j}(\{p_i\})\nonumber\\
	&\times \frac{(\hat{s}^B)^2}{\hat{s}^2}\ \frac{x_a f_{a,f_1}(x_a, Q_a)\ x_b f_{b,f_2}(x_b, Q_b)}{x_a^B\ f_{a,f_1}(x_a^B, Q_a^B)\ x_b^B\ f_{b,f_2}(x_b^B, Q_b^B)}\ \frac{\overline{\left\|\mathcal{M}_{\mathrm{HEJ}}^{f_1 f_2\to f_1 g\cdots
	gf_2}(\{ p_i\})\right\|}^2}{\overline{\left\|\mathcal{M}_\text{LO, HEJ}^{f_1f_2\to f_1g\cdots
	gf_2}\big(\big\{p^B_j\big\}\big)\right\|}^{2}} \,.\nonumber
	% \end{split}
	\end{align}
	The first two lines correspond to the generation of the fixed-order
	input events with incoming partons $f_1, f_2$ and outgoing momenta
	$p_j^B$, where $\mathbf{p}_{j\perp}^B$ and $y_j^B$ denote the respective
	transverse momentum and rapidity. Note that, at leading order, these
	coincide with the fixed-order jet momenta $p_{\mathcal{J}_j}^B$.
	$f_{a,f_1}(x_a, Q_a),f_{b,f_2}(x_b, Q_b)$ are the pdf factors for the incoming partons with
	momentum fractions $x_a$ and $x_b$. The square of the partonic
	centre-of-mass energy is denoted by $\hat{s}^B$ and
	$\mathcal{M}_\text{LO}^{f_1f_2\to f_1g\cdots gf_2}$ is the
	leading-order matrix element.

	The third line is a factor accounting for the different multiplicities
	between fixed-order and resummation events. Lines four and five are
	the integration over the resummation phase space described in this
	section. $p_i$ are the momenta of the outgoing partons in resummation
	phase space. $\mathbf{T}_y$ denotes rapidity
	ordering and $\mathcal{O}_{mj}^e$ projects out the exclusive $m$-jet
	component. The relation between resummation and fixed-order momenta is
	fixed by the $\delta$ functions. The first sets each transverse fixed-order jet
	momentum to some function $\mathbf{j_{l\perp}}$ of the resummation
	momenta. The exact form is described in section~\ref{sec:ptj_res}. The second
	$\delta$ forces the rapidities of resummation and fixed-order jets to be
	the same. Finally, the last line is the reweighting of pdf and matrix
	element factors already shown in section~\ref{sec:resum}.

	There are two kinds of cut-off in the integration over the resummation
	partons. $\lambda$ is a technical cut-off connected to the cancellation
	of infrared divergencies between real and virtual corrections. Its
	numerical value is set in
	\texttt{include/HEJ/Constants.h}. $p_{\perp,\mathrm{min}}$ regulates
	and \emph{uncancelled} divergence in the extremal parton momenta. Its
	size is set by the user configuration \url{https://hej.web.cern.ch/HEJ/doc/current/user/HEJ.html#settings}.

	It is straightforward to generalise eq.~(\ref{eq:resumdijetFKLmatched2})
	to unordered configurations and processes with additional colourless
	emissions, for example a Higgs or electroweak boson. In the latter case only
	the fixed-order integration and the matrix elements change.

	\subsubsection{Gluon Multiplicity}
	\label{sec:psp_ng}

	The first step in evaluating the resummation phase space in
	eq.~(\ref{eq:resumdijetFKLmatched2}) is to randomly pick terms in the
	sum over the number of emissions. This sampling of the gluon
	multiplicity is done in the \lstinline!PhaseSpacePoint::sample_ng!
	function in \texttt{src/PhaseSpacePoint.cc}.

	The typical number of extra emissions depends strongly on the rapidity
	span of the underlying fixed-order event. Let us, for example, consider
	a fixed-order FKL-type multi-jet configuration with rapidities
	$y_{j_f},\,y_{j_b}$ of the most forward and backward jets,
	respectively. By eq.~(\ref{eq:resumdijetFKLmatched2}), the jet
	multiplicity and the rapidity of each jet are conserved when adding
	resummation. This implies that additional hard radiation is restricted
	to rapidities $y$ within a region $y_{j_b} \lesssim y \lesssim
	y_{j_f}$. Within \HEJ, we require the most forward and most backward
	emissions to be hard \todo{specify how hard} in order to avoid divergences, so this constraint
	in fact applies to \emph{all} additional radiation.

	To simplify the remaining discussion, let us remove the FKL rapidity
	ordering
	\begin{equation}
	\label{eq:remove_y_order}
	\mathbf{T}_y \prod_{i=1}^n\int \frac{\mathrm{d}y_i}{2} =
	\frac{1}{n!}\prod_{i=1}^n\int
	\frac{\mathrm{d}y_i}{2}\,,
	\end{equation}
	where all rapidity integrals now cover a region which is approximately
	bounded by $y_{j_b}$ and $y_{j_f}$. Each of the $m$ jets has to contain at least
	one parton; selecting random emissions we can rewrite the phase space
	integrals as
	\begin{equation}
	\label{eq:select_jets}
	\frac{1}{n!}\prod_{i=1}^n\int [\mathrm{d}p_i] =
	\left(\prod_{i=1}^{m}\int [\mathrm{d}p_i]\ {\cal J}_i(p_i)\right)
	\frac{1}{n_g!}\prod_{i=m+1}^{m+n_g}\int [\mathrm{d}p_i]
	\end{equation}
	with jet selection functions
	\begin{equation}
	\label{eq:def_jet_selection}
	{\cal J}_i(p) =
	\begin{cases}
	1 &p\text{ clustered into jet }i\\
	0 & \text{otherwise}
	\end{cases}
	\end{equation}
	and $n_g \equiv n - m$. Here and in the following we use the short-hand
	notation $[\mathrm{d}p_i]$ to denote the phase-space measure for parton
	$i$. As is evident from eq.~\eqref{eq:select_jets}, adding an extra emission
	$n_g+1$ introduces a suppression factor $\tfrac{1}{n_g+1}$. However, the
	additional phase space integral also results in an enhancement proportional
	to $\Delta y_{j_f j_b} = y_{j_f} - y_{j_b}$. This is a result of the
	rapidity-independence of the MRK limit of the integrand, consisting of the
	matrix elements divided by the flux factor. Indeed, we observe that the
	typical number of gluon emissions is to a good approximation proportional to
	the rapidity separation and the phase space integral is dominated by events
	with $n_g \approx \Delta y_{j_f j_b}$.

	For the actual phase space sampling, we assume a Poisson distribution
	and extract the mean number of gluon emissions in different rapidity
	bins and fit the results to a linear function in $\Delta y_{j_f j_b}$,
	finding a coefficient of $0.975$ for the inclusive production of a Higgs
	boson with two jets. Here are the observed and fitted average gluon
	multiplicities as a function of $\Delta y_{j_f j_b}$:
	\begin{center}
	\includegraphics[width=.75\textwidth]{ng_mean}
	\end{center}
	As shown for two rapidity slices the assumption of a Poisson
	distribution is also a good approximation:
	\begin{center}
	\includegraphics[width=.49\textwidth]{{ng_1.5}.pdf}\hfill
	\includegraphics[width=.49\textwidth]{{ng_5.5}.pdf}
	\end{center}

	\subsubsection{Number of Gluons inside Jets}
	\label{sec:psp_ng_jet}

	For each of the $n_g$ gluon emissions we can split the phase-space
	integral into a (disconnected) region inside the jets and a remainder:
	\begin{equation}
	\label{eq:psp_split}
	\int [\mathrm{d}p_i] = \int [\mathrm{d}p_i]\,
	\theta\bigg(\sum_{j=1}^{m}{\cal J}_j(p_i)\bigg) + \int [\mathrm{d}p_i]\,
	\bigg[1-\theta\bigg(\sum_{j=1}^{m}{\cal J}_j(p_i)\bigg)\bigg]\,.
	\end{equation}
	The next step is to decide how many of the gluons will form part of a
	jet. This is done in the \lstinline!PhaseSpacePoint::sample_ng_jets!
	function.

	We choose an importance sampling which is flat in the plane
	spanned by the azimuthal angle $\phi$ and the rapidity $y$. This is
	observed in BFKL and valid in the limit of Multi-Regge-Kinematics
	(MRK). Furthermore, we assume anti-$k_t$ jets, which cover an area of
	$\pi R^2$.

	In principle, the total accessible area in the $y$-$\phi$ plane is given
	by $2\pi \Delta y_{fb}$, where $\Delta y_{fb}\geq \Delta y_{j_f j_b}$ is
	the a priori unknown rapidity separation between the most forward and
	backward partons. In most cases the extremal jets consist of single
	partons, so that $\Delta y_{fb} = \Delta y_{j_f j_b}$. For the less common
	case of two partons forming a jet we observe a maximum distance of $R$
	between the constituents and the jet centre. In rare cases jets have
	more than two constituents. Empirically, they are always within a
	distance of $\tfrac{5}{3}R$ to the centre of the jet, so
	$\Delta y_{fb} \leq \Delta y_{j_f j_b} + \tfrac{10}{3} R$. In practice, the
	extremal partons are required to carry a large fraction of the jet
	transverse momentum and will therefore be much closer to the jet axis.

	In summary, for sufficiently large rapidity separations we can use the
	approximation $\Delta y_{fb} \approx \Delta y_{j_f j_b}$. This scenario
	is depicted here:
	\begin{center}
	\includegraphics[width=0.5\linewidth]{ps_large_y}
	\end{center}
	If there is no overlap between jets, the probability $p_{\cal J, >}$ for
	an extra gluon to end up inside a jet is then given by
	\begin{equation}
	\label{eq:p_J_large}
	p_{\cal J, >} = \frac{(m - 1)\*R^2}{2\Delta y_{j_f j_b}}\,.
	\end{equation}
	For a very small rapidity separation, eq.~\eqref{eq:p_J_large}
	obviously overestimates the true probability. The maximum phase space
	covered by jets in the limit of a vanishing rapidity distance between
	all partons is $2mR \Delta y_{fb}$:
	\begin{center}
	\includegraphics[width=0.5\linewidth]{ps_small_y}
	\end{center}
	We therefore estimate the probability for a parton to end up inside a jet as
	\begin{equation}
	\label{eq:p_J}
	p_{\cal J} = \min\bigg(\frac{(m - 1)\*R^2}{2\Delta y_{j_f j_b}}, \frac{mR}{\pi}\bigg)\,.
	\end{equation}
	Here we compare this estimate with the actually observed
	fraction of additional emissions into jets as a function of the rapidity
	separation:
	\begin{center}
	\includegraphics[width=0.75\linewidth]{pJ}
	\end{center}

	\subsubsection{Gluons outside Jets}
	\label{sec:gluons_nonjet}

	Using our estimate for the probability of a gluon to be a jet
	constituent, we choose a number $n_{g,{\cal J}}$ of gluons inside
	jets, which also fixes the number $n_g - n_{g,{\cal J}}$ of gluons
	outside jets. As explained later on, we need to generate the momenta of
	the gluons outside jets first. This is done in
	\lstinline!PhaseSpacePoint::gen_non_jet!.

	The azimuthal angle $\phi$ is generated flat within $0\leq \phi \leq 2
	\pi$. The allowed rapidity interval is set by the most forward and
	backward partons, which are necessarily inside jets. Since these parton
	rapidities are not known at this point, we also have to postpone the
	rapidity generation for the gluons outside jets. For the scalar
	transverse momentum $p_\perp = \|\mathbf{p}_\perp\|$ of a gluon outside
	jets we use the parametrisation
	\begin{equation}
	\label{eq:p_nonjet}
	p_\perp = \lambda + \tilde{p}_\perp\\tan(\tau\r)\,, \qquad
	\tau = \arctan\bigg(\frac{p_{\perp{\cal J}_\text{min}} - \lambda}{\tilde{p}_\perp}\bigg)\,.
	\end{equation}
	For $r \in [0,1)$, $p_\perp$ is always less than the minimum momentum
	$p_{\perp{\cal J}_\text{min}}$ required for a jet. $\tilde{p}_\perp$ is
	a free parameter, a good empirical value is $\tilde{p}_\perp = [1.3 +
	0.2\*(n_g - n_{g,\cal J})]\,$GeV

	\subsubsection{Resummation jet momenta}
	\label{sec:ptj_res}

	On the one hand, each jet momentum is given by the sum of its
	constituent momenta. On the other hand, the resummation jet momenta are
	fixed by the constraints in line five of the master
	equation~\eqref{eq:resumdijetFKLmatched2}. We therefore have to
	calculate the resummation jet momenta from these constraints before
	generating the momenta of the gluons inside jets. This is done in
	\lstinline!PhaseSpacePoint::reshuffle! and in the free
	\lstinline!resummation_jet_momenta! function (declared in \texttt{resummation\_jet.hh}).

	The resummation jet momenta are determined by the $\delta$ functions in
	line five of eq.~(\ref{eq:resumdijetFKLmatched2}). The rapidities are
	fixed to the rapidities of the jets in the input fixed-order events, so
	that the FKL ordering is guaranteed to be preserved.

	In traditional \HEJ reshuffling the transverse momentum are given through
	\begin{equation}
	\label{eq:ptreassign_old}
	\mathbf{p}^B_{\mathcal{J}_{l\perp}} = \mathbf{j}_{l\perp} \equiv \mathbf{p}_{\mathcal{J}_{l}\perp}
	+ \mathbf{q}_\perp \,\frac{\|\mathbf{p}_{\mathcal{J}_{l}\perp}\|}{P_\perp},
	\end{equation}
	where $\mathbf{q}_\perp = \sum_{j=1}^n \mathbf{p}_{i\perp}
	\bigg[1-\theta\bigg(\sum_{j=1}^{m}{\cal J}_j(p_i)\bigg)\bigg] $ is the
	total transverse momentum of all partons \emph{outside} jets and
	$P_\perp = \sum_{j=1}^m \|\mathbf{p}_{\mathcal{J}_{j}\perp}\|$. Since the
	total transverse momentum of an event vanishes, we can also use
	$\mathbf{q}_\perp = - \sum_{j=1}^m
	\mathbf{p}_{\mathcal{J}_{j}\perp}$. Eq.~(\ref{eq:ptreassign}) is a
	non-linear system of equations in the resummation jet momenta
	$\mathbf{p}_{\mathcal{J}_{l}\perp}$. Hence we would have to solve
	\begin{equation}
	\label{eq:ptreassign_eq}
	\mathbf{p}_{\mathcal{J}_{l}\perp}=\mathbf{j}^B_{l\perp} \equiv\mathbf{j}_{l\perp}^{-1}
	\left(\mathbf{p}^B_{\mathcal{J}_{l\perp}}\right)
	\end{equation}
	numerically.

	Since solving such a system is computationally expensive, we instead
	change the reshuffling around to be linear in the resummation jet
	momenta. Hence~\eqref{eq:ptreassign_eq} gets replaces by
	\begin{equation}
	\label{eq:ptreassign}
	\mathbf{p}_{\mathcal{J}_{l\perp}} = \mathbf{j}^B_{l\perp} \equiv \mathbf{p}^B_{\mathcal{J}_{l}\perp}
	- \mathbf{q}_\perp \,\frac{\|\mathbf{p}^B_{\mathcal{J}_{l}\perp}\|}{P^B_\perp},
	\end{equation}
	which is linear in the resummation momentum. Consequently the equivalent
	of~\eqref{eq:ptreassign_old} is non-linear in the Born momentum. However
	the exact form of~\eqref{eq:ptreassign_old} is not relevant for the resummation.
	Both methods have been tested for two and three jets with the \textsc{rivet}
	standard analysis \texttt{MC\_JETS}. They didn't show any differences even
	after $10^9$ events.

	The reshuffling relation~\eqref{eq:ptreassign} allows the transverse
	momenta $p^B_{\mathcal{J}_{l\perp}}$ of the fixed-order jets to be
	somewhat below the minimum transverse momentum of resummation jets. It
	is crucial that this difference does not become too large, as the
	fixed-order cross section diverges for vanishing transverse momenta. In
	the production of a Higgs boson with resummation jets above $30\,$GeV we observe
	that the contribution from fixed-order events with jets softer than
	about $20\,$GeV can be safely neglected. This is shown in the following
	plot of the differential cross section over the transverse momentum of
	the softest fixed-order jet:
	\begin{center}
	\includegraphics[width=.75\textwidth]{ptBMin}
	\end{center}

	Finally, we have to account for the fact that the reshuffling
	relation~\eqref{eq:ptreassign} is non-linear in the Born momenta. To
	arrive at the master formula~\eqref{eq:resumdijetFKLmatched2} for the
	cross section, we have introduced unity in the form of an integral over
	the Born momenta with $\delta$ functions in the integrand, that is
	\begin{equation}
	\label{eq:delta_intro}
	1 = \int_{p_{j\perp}^B=0}^{p_{j\perp}^B=\infty}
	\mathrm{d}^2\mathbf{p}_{j\perp}^B\delta^{(2)}(\mathbf{p}_{\mathcal{J}_{j\perp}}^B -
	\mathbf{j}_{j\perp})\,.
	\end{equation}
	If the arguments of the $\delta$ functions are not linear in the Born
	momenta, we have to compensate with additional Jacobians as
	factors. Explicitly, for the reshuffling relation~\eqref{eq:ptreassign}
	we have
	\begin{equation}
	\label{eq:delta_rewrite}
	\prod_{l=1}^m \delta^{(2)}(\mathbf{p}_{\mathcal{J}_{l\perp}}^B -
	\mathbf{j}_{l\perp}) = \Delta \prod_{l=1}^m \delta^{(2)}(\mathbf{p}_{\mathcal{J}_{l\perp}} -
	\mathbf{j}_{l\perp}^B)\,,
	\end{equation}
	where $\mathbf{j}_{l\perp}^B$ is given by~\eqref{eq:ptreassign_eq} and only
	depends on the Born momenta. We have extended the product to run to $m$
	instead of $m-1$ by eliminating the last $\delta$ function
	$\delta^{(2)}\!\!\left(\sum_{k=1}^n \mathbf{p}_{k\perp}\right )$.
	The Jacobian $\Delta$ is the determinant of a $2m \times 2m$ matrix with $l, l' = 1,\dots,m$
	and $X, X' = x,y$.
	\begin{equation}
	\label{eq:jacobian}
	\Delta = \left\|\frac{\partial\,\mathbf{j}^B_{l'\perp}}{\partial\, \mathbf{p}^B_{{\cal J}_l \perp}} \right\|
	= \left\| \delta_{l l'} \delta_{X X'} - \frac{q_X\, p^B_{{\cal
	J}_{l'}X'}}{\left\|\mathbf{p}^B_{{\cal J}_{l'} \perp}\right\| P^B_\perp}\left(\delta_{l l'}
	- \frac{\left\|\mathbf{p}^B_{{\cal J}_l \perp}\right\|}{P^B_\perp}\right)\right\|\,.
	\end{equation}
	The determinant is calculated in \lstinline!resummation_jet_weight!,
	again coming from the \texttt{resummation\_jet.hh} header.
	Having to introduce this Jacobian is not a disadvantage specific to the new
	reshuffling. If we instead use the old reshuffling
	relation~\eqref{eq:ptreassign_old} we \emph{also} have to introduce a
	similar Jacobian since we actually want to integrate over the
	resummation phase space and need to transform the argument of the
	$\delta$ function to be linear in the resummation momenta for this.

	\subsubsection{Gluons inside Jets}
	\label{sec:gluons_jet}

	After the steps outlined in section~\ref{sec:psp_ng_jet}, we have a
	total number of $m + n_{g,{\cal J}}$ constituents. In
	\lstinline!PhaseSpacePoint::distribute_jet_partons! we distribute them
	randomly among the jets such that each jet has at least one
	constituent. We then generate their momenta in
	\lstinline!PhaseSpacePoint::split! using the \lstinline!Splitter! class.

	The phase space integral for a jet ${\cal J}$ is given by
	\begin{equation}
	\label{eq:ps_jetparton} \prod_{i\text{ in }{\cal J}} \bigg(\int
	\mathrm{d}\mathbf{p}_{i\perp}\ \int \mathrm{d} y_i
	\bigg)\delta^{(2)}\Big(\sum_{i\text{ in }{\cal J}} \mathbf{p}_{i\perp} -
	\mathbf{j}_{\perp}^B\Big)\delta(y_{\mathcal{J}}-y^B_{\mathcal{J}})\,.
	\end{equation}
	For jets with a single constituent, the parton momentum is obiously equal to the
	jet momentum. In the case of two constituents, we observe that the
	partons are always inside the jet cone with radius $R$ and often very
	close to the jet centre. The following plots show the typical relative
	distance $\Delta R/R$ for this scenario:
	\begin{center}
	\includegraphics[width=0.45\linewidth]{dR_2}
	\includegraphics[width=0.45\linewidth]{dR_2_small}
	\end{center}
	According to this preference for small values of $\Delta R$, we
	parametrise the $\Delta R$ integrals as
	\begin{equation}
	\label{eq:dR_sampling}
	\frac{\Delta R}{R} =
	\begin{cases}
	0.25\,x_R & x_R < 0.4 \\
	1.5\,x_R - 0.5 & x_R \geq 0.4
	\end{cases}\,.
	\end{equation}
	Next, we generate $\Theta_1 \equiv \Theta$ and use the constraint $\Theta_2 = \Theta
	\pm \pi$. The transverse momentum of the first parton is then given by
	\begin{equation}
	\label{eq:delta_constraints}
	p_{1\perp} =
	\frac{p_{\mathcal{J} y} - \tan(\phi_2) p_{\mathcal{J} x}}{\sin(\phi_1)
	- \tan(\phi_2)\cos(\phi_1)}\,.
	\end{equation}
	We get $p_{2\perp}$ by exchanging $1 \leftrightarrow 2$ in the
	indices. To obtain the Jacobian of the transformation, we start from the
	single jet phase space eq.~(\ref{eq:ps_jetparton}) with the rapidity
	delta function already rewritten to be linear in the rapidity of the
	last parton, i.e.
	\begin{equation}
	\label{eq:jet_2p}
	\prod_{i=1,2} \bigg(\int
	\mathrm{d}\mathbf{p}_{i\perp}\ \int \mathrm{d} y_i
	\bigg)\delta^{(2)}\Big(\mathbf{p}_{1\perp} + \mathbf{p}_{2\perp} -
	\mathbf{j}_{\perp}^B\Big)\delta(y_2- \dots)\,.
	\end{equation}
	The integral over the second parton momentum is now trivial; we can just replace
	the integral over $y_2$ with the equivalent constraint
	\begin{equation}
	\label{eq:R2}
	\int \mathrm{d}R_2 \ \delta\bigg(R_2 - \bigg[\phi_{\cal J} - \arctan
	\bigg(\frac{p_{{\cal J}y} - p_{1y}}{p_{{\cal J}x} -
	p_{1x}}\bigg)\bigg]/\cos \Theta\bigg) \,.
	\end{equation}
	In order to fix the integral over $p_{1\perp}$ instead, we rewrite this
	$\delta$ function. This introduces the Jacobian
	\begin{equation}
	\label{eq:jac_pt1}
	\bigg\|\frac{\partial p_{1\perp}}{\partial R_2} \bigg\| =
	\frac{\cos(\Theta)\mathbf{p}_{2\perp}^2}{p_{{\cal J}\perp}\sin(\phi_{\cal J}-\phi_1)}\,.
	\end{equation}
	The final form of the integral over the two parton momenta is then
	\begin{equation}
	\label{eq:ps_jet_2p}
	\int \mathrm{d}R_1\ R_1 \int \mathrm{d}R_2 \int \mathrm{d}x_\Theta\ 2\pi \int
	\mathrm{d}p_{1\perp}\ p_{1\perp} \int \mathrm{d}p_{2\perp}
	\ \bigg\|\frac{\partial p_{1\perp}}{\partial R_2} \bigg\|\delta(p_{1\perp}
	-\dots) \delta(p_{2\perp} - \dots)\,.
	\end{equation}

	As is evident from section~\ref{sec:psp_ng_jet}, jets with three or more
	constituents are rare and an efficient phase-space sampling is less
	important. For such jets, we exploit the observation that partons with a
	distance larger than $R_{\text{max}} = \tfrac{5}{3} R$ to
	the jet centre are never clustered into the jet. Assuming $N$
	constituents, we generate all components
	for the first $N-1$ partons and fix the remaining parton with the
	$\delta$-functional. In order to end up inside the jet, we use the
	parametrisation
	\begin{align}
	\label{eq:ps_jet_param}
	\phi_i ={}& \phi_{\cal J} + \Delta \phi_i\,, & \Delta \phi_i ={}& \Delta
	R_i
	\cos(\Theta_i)\,, \\
	y_i ={}& y_{\cal J} + \Delta y_i\,, & \Delta y_i ={}& \Delta
	R_i
	\sin(\Theta_i)\,,
	\end{align}
	and generate $\Theta_i$ and $\Delta R_i$ randomly with $\Delta R_i \leq
	R_{\text{max}}$ and the empiric value $R_{\text{max}} = 5\*R/3$. We can
	then write the phase space integral for a single parton as $(p_\perp = \|\mathbf{p}_\perp\|)$
	\begin{equation}
	\label{eq:ps_jetparton_x}
	\int \mathrm{d}\mathbf{p}_{\perp}\ \int
	\mathrm{d} y \approx \int_{\Box} \mathrm{d}x_{\perp}
	\mathrm{d}x_{ R}
	\mathrm{d}x_{\theta}\
	2\\pi\,\R_{\text{max}}^2\,\x_{R}\,\p_{\perp}\,\*(p_{\perp,\text{max}}
	- p_{\perp,\text{min}})
	\end{equation}
	with
	\begin{align}
	\label{eq:ps_jetparton_parameters}
	\Delta \phi ={}& R_{\text{max}}\x_{R}\\cos(2\\pi\x_\theta)\,,&
	\Delta y ={}& R_{\text{max}}\x_{R}\\sin(2\\pi\x_\theta)\,, \\
	p_{\perp} ={}& (p_{\perp,\text{max}} - p_{\perp,\text{min}})\*x_\perp +
	p_{\perp,\text{min}}\,.
	\end{align}
	$p_{\perp,\text{max}}$ is determined from the requirement that the total
	contribution from the first $n-1$ partons --- i.e. the projection onto the
	jet $p_{\perp}$ axis --- must never exceed the jet $p_\perp$. This gives
	\todo{This bound is too high}
	\begin{equation}
	\label{eq:pt_max}
	p_{i\perp,\text{max}} = \frac{p_{{\cal J}\perp} - \sum_{j<i} p_{j\perp}
	\cos \Delta
	\phi_j}{\cos \Delta
	\phi_i}\,.
	\end{equation}
	The $x$ and $y$ components of the last parton follow immediately from
	the first $\delta$ function. The last rapidity is fixed by the condition that
	the jet rapidity is kept fixed by the reshuffling, i.e.
	\begin{equation}
	\label{eq:yJ_delta}
	y^B_{\cal J} = y_{\cal J} = \frac 1 2 \ln \frac{\sum_{i=1}^n E_i+ p_{iz}}{\sum_{i=1}^n E_i - p_{iz}}\,.
	\end{equation}
	With $E_n \pm p_{nz} = p_{n\perp}\exp(\pm y_n)$ this can be rewritten to
	\begin{equation}
	\label{eq:yn_quad_eq}
	\exp(2y_{\cal J}) = \frac{\sum_{i=1}^{n-1} E_i+ p_{iz}+p_{n\perp} \exp(y_n)}{\sum_{i=1}^{n-1} E_i - p_{iz}+p_{n\perp} \exp(-y_n)}\,,
	\end{equation}
	which is a quadratic equation in $\exp(y_n)$. The physical solution is
	\begin{align}
	\label{eq:yn}
	y_n ={}& \log\Big(-b + \sqrt{b^2 + \exp(2y_{\cal J})}\,\Big)\,,\\
	b ={}& \bigg(\sum_{i=1}^{n-1} E_i + p_{iz} - \exp(2y_{\cal J})
	\sum_{i=1}^{n-1} E_i - p_{iz}\bigg)/(2 p_{n\perp})\,.
	\end{align}
	\todo{what's wrong with the following?} To eliminate the remaining rapidity
	integral, we transform the $\delta$ function to be linear in the
	rapidity $y$ of the last parton. The corresponding Jacobian is
	\begin{equation}
	\label{eq:jacobian_y}
	\bigg\|\frac{\partial y_{\cal J}}{\partial y_n}\bigg\|^{-1} = 2 \bigg( \frac{E_n +
	p_{nz}}{E_{\cal J} + p_{{\cal J}z}} + \frac{E_n - p_{nz}}{E_{\cal J} -
	p_{{\cal J}z}}\bigg)^{-1}\,.
	\end{equation}
	Finally, we check that all designated constituents are actually
	clustered into the considered jet.

	\subsubsection{Final steps}
	\label{sec:final}

	Knowing the rapidity span covered by the extremal partons, we can now
	generate the rapdities for the partons outside jets. We perform jet
	clustering on all partons and check in
	\lstinline!PhaseSpacePoint::jets_ok! that all the following criteria are
	fulfilled:
	\begin{itemize}
	\item The number of resummation jets must match the number of
	fixed-order jets.
	\item No partons designated to be outside jets may end up inside jets.
	\item All other outgoing partons \emph{must} end up inside jets.
	\item The extremal (in rapidity) partons must be inside the extremal
	jets. If there is, for example, an unordered forward emission, the
	most forward parton must end up inside the most forward jet and the
	next parton must end up inside second jet.
	\item The rapidities of fixed-order and resummation jets must match.
	\end{itemize}
	After this, we adjust the phase-space normalisation according to the
	third line of eq.~(\ref{eq:resumdijetFKLmatched2}), determine the
	flavours of the outgoing partons, and adopt any additional colourless
	bosons from the fixed-order input event. Finally, we use momentum
	conservation to reconstruct the momenta of the incoming partons.

	\subsection{Colour connection}
	\label{sec:Colour}

	\begin{figure}
	\input{src/ColourConnect.tex}
	\caption{Left: Non-crossing colour flow dominating in the MRK limit. The
	crossing of the colour line connecting to particle 2 can be resolved by
	writing particle 2 on the left. Right: A colour flow with a (manifest)
	colour-crossing. The crossing can only be resolved if one breaks the
	rapidities order, e.g. switching particles 2 and 3. From~\cite{Andersen:2017sht}.}
	\label{fig:Colour_crossing}
	\end{figure}

	After the phase space for the resummation event is generated, we can construct
	the colour for each particle. To generate the colour flow one has to call
	-\lstinline!Event::generate_colour_flow! on any \HEJ configuration. For non-\HEJ
	+\lstinline!Event::generate_colours! on any \HEJ configuration. For non-\HEJ
	event we do not change the colour, and assume it is provided by the user (e.g.
	through the LHE file input). The colour connection is done in the large $N_c$
	(infinite number of colour) limit with leading colour in
	MRK~\cite{Andersen:2008ue, Andersen:2017sht}. The idea is to allow only
	$t$-channel colour exchange, without any crossing colour lines. For example the
	colour crossing in the colour connection on the left of
	figure~\ref{fig:Colour_crossing} can be resolved by switching \textit{particle
	2} to the left.

	We can write down the colour connections by following the colour flow from
	\textit{gluon a} to \textit{gluon b} and back to \textit{gluon a}, e.g.
	figure~\ref{fig:Colour_gleft} corresponds to $a123ba$. In such an expression any
	valid, non-crossing colour flow will connect all external legs while respecting
	the rapidity ordering. Thus configurations like the left of
	figure~\ref{fig:Colour_crossing} are allowed ($a134b2a$), but the right of the
	same figures breaks the rapidity ordering between 2 and 3 ($a1324ba$). Note that
	connections between $b$ and $a$ are in inverse order, e.g. $ab321a$ corresponds to~\ref{fig:Colour_gright} ($a123ba$) just with colour and anti-colour swapped.

	\begin{figure}
	\centering
	\subcaptionbox{$a123ba$\label{fig:Colour_gright}}{
	\includegraphics[height=0.25\textwidth]{figures/colour_gright.jpg}}
	\subcaptionbox{$a13b2a$\label{fig:Colour_gleft}}{
	\includegraphics[height=0.25\textwidth]{figures/colour_gleft.jpg}}
	\subcaptionbox{$a\_123ba$\label{fig:Colour_qx}}{
	\includegraphics[height=0.25\textwidth]{figures/colour_qx.jpg}}
	\subcaptionbox{$a\_23b1a$\label{fig:Colour_uno}}{
	\includegraphics[height=0.25\textwidth]{figures/colour_uno.jpg}}
	\subcaptionbox{$a14b3\_2a$\label{fig:Colour_qqx}}{
	\includegraphics[height=0.25\textwidth]{figures/colour_centralqqx.jpg}}
	\caption{Different colour non-crossing colour connections. Both incoming
	particles are drawn at the top or bottom and the outgoing left or right. The Feynman diagram is shown in black and the colour flow in blue.}
	%TODO Maybe make these plots nicer (in Latex/asy)
	\end{figure}

	If we replace two gluons with a quark, (anti-)quark pair we break one of the
	colour connections. Still the basic
	concept from before holds, we just have to treat the connection between two
	(anti-)quarks like an unmovable (anti-)colour. We denote such a connection by a underscore
	(e.g. $1\_a$). For example the equivalent of~\ref{fig:Colour_gright} ($a123ba$)
	with an incoming antiquark is~\ref{fig:Colour_qx} ($a\_123ba$). As said this
	also holds for other subleading configurations like unordered
	emission~\ref{fig:Colour_uno} or central quark-antiquark
	pairs~\ref{fig:Colour_qqx} \footnote{Obviously this can not be guaranteed for
	non-\HEJ configurations, e.g. $qQ\to Qq$ requires a $u$-channel exchange.}.

	Some rapidity ordering can have multiple possible colour connections,
	e.g.~\ref{fig:Colour_gright} and~\ref{fig:Colour_gleft}. This is always the case
	if a gluon radiates off a gluon line. In that case we randomly connect the gluon
	to either the colour or anti-colour. Thus in the generation we keep track
	whether we are on a quark or gluon line, and act accordingly.



	\subsection{The matrix element }
	\label{sec:ME}

	The derivation of the \HEJ matrix element is explained in some detail
	in~\cite{Andersen:2017kfc}, where also results for leading and
	subleading matrix elements for pure multijet production and production
	of a Higgs boson with at least two associated jets are listed. Matrix
	elements for $W$ and $Z/\gamma^*$ production together with jets are
	given in~\cite{Andersen:2012gk,Andersen:2016vkp}, but not yet included.

	The matrix elements are implemented in the \lstinline!MatrixElement!
	class. To discuss the structure, let us consider the squared matrix
	element for FKL multijet production with $n$ final-state partons:
	\begin{align}
	\label{eq:ME}
	\begin{split}
	\overline{\left\|\mathcal{M}_\text{HEJ}^{f_1 f_2 \to f_1
	g\cdots g f_2}\right\|}^2 = \ &\frac {(4\pi\alpha_s)^n} {4\ (N_c^2-1)}
	\cdot\ \textcolor{blue}{\frac {K_{f_1}(p_1^-, p_a^-)} {t_1}\ \cdot\ \frac{K_{f_2}(p_n^+, p_b^+)}{t_{n-1}}\ \cdot\ \left\\|S_{f_1 f_2\to f_1 f_2}\right\\|^2}\\
	& \cdot \prod_{i=1}^{n-2} \textcolor{gray}{\left( \frac{-C_A}{t_it_{i+1}}\
	V^\mu(q_i,q_{i+1})V_\mu(q_i,q_{i+1}) \right)}\\
	& \cdot \prod_{j=1}^{n-1} \textcolor{red}{\exp\left[\omega^0(q_{j\perp})(y_{j+1}-y_j)\right]}.
	\end{split}
	\end{align}
	The structure and momentum assignment of the unsquared matrix element is
	as illustrated here:
	\begin{center}
	\includegraphics{HEJ_amplitude}
	\end{center}
	The square
	of the complete matrix element as given in eq.~(\ref{eq:ME}) is
	calculated by \lstinline!MatrixElement::operator()!. The \textcolor{red}{last line} of
	eq.~\eqref{eq:ME} constitutes the all-order virtual correction,
	implemented in
	\lstinline!MatrixElement::virtual_corrections!.
	$\omega^0$ is the
	\textit{regularised Regge trajectory}
	\begin{equation}
	\label{eq:omega_0}
	\omega^0(q_\perp) = - C_A \frac{\alpha_s}{\pi} \log \left(\frac{q_\perp^2}{\lambda^2}\right)\,,
	\end{equation}
	where $\lambda$ is the slicing parameter limiting the softness of real
	gluon emissions, cf. eq.~(\ref{eq:resumdijetFKLmatched2}).

	The remaining parts, which correspond to the square of the leading-order
	HEJ matrix element $\overline{\left\|\mathcal{M}_\text{LO,
	HEJ}^{f_1f_2\to f_1g\cdots
	gf_2}\big(\big\{p^B_j\big\}\big)\right\|}^{2}$, are computed in
	\lstinline!MatrixElement::tree!. We can further factor off the
	scale-dependent ``parametric'' part
	\lstinline!MatrixElement::tree_param! containing all factors of the
	strong coupling $4\pi\alpha_s$. Using this function saves some CPU time
	when adjusting the renormalisation scale, see
	section~\ref{sec:resum}. The remaining ``kinematic'' factors are
	calculated in \lstinline!MatrixElement::kin!.

	\subsubsection{Matrix elements for Higgs plus dijet}
	\label{sec:ME_h_jets}

	In the production of a Higgs boson together with jets the parametric
	parts and the virtual corrections only require minor changes in the
	respective functions. However, in the ``kinematic'' parts we have to
	distinguish between several cases, which is done in
	\lstinline!MatrixElement::tree_kin_Higgs!. The Higgs boson can be
	\emph{central}, i.e. inside the rapidity range spanned by the extremal
	partons (\lstinline!MatrixElement::tree_kin_Higgs_central!) or
	\emph{peripheral} and outside this range
	(\lstinline!MatrixElement::tree_kin_Higgs_first! or
	\lstinline!MatrixElement::tree_kin_Higgs_last!). In case there is also
	an unordered gluon emission the matrix element is already suppressed by one
	logarithm $\log(s/t)$. Therefore at NLL the Higgs boson can only be emitted
	centrally\footnote{In principle emitting a Higgs boson \textit{on the other
	side} of the unordered gluon is possible by contracting an unordered and
	external Higgs current. Obviously this would not cover all possible
	configurations, e.g. $qQ\to HgqQ$ requires contraction of the standard $Q\to Q$
	current with an (unknown) $q\to Hgq$ one.}.

	If a Higgs boson with momentum $p_H$ is emitted centrally, after parton
	$j$ in rapidity, the matrix element reads
	\begin{equation}
	\label{eq:ME_h_jets_central}
	\begin{split}
	\overline{\left\|\mathcal{M}_\text{HEJ}^{f_1 f_2 \to f_1 g\cdot H
	\cdot g f_2}\right\|}^2 = \ &\frac {\alpha_s^2 (4\pi\alpha_s)^n} {4\ (N_c^2-1)}
	\cdot\ \textcolor{blue}{\frac {K_{f_1}(p_1^-, p_a^-)} {t_1}\
	\cdot\ \frac{1}{t_j t_{j+1}} \cdot\ \frac{K_{f_2}(p_n^+, p_b^+)}{t_{n}}\ \cdot\ \left\\|S_{f_1
	f_2\to f_1 H f_2}\right\\|^2}\\
	& \cdot \prod_{\substack{i=1\\i \neq j}}^{n-1} \textcolor{gray}{\left( \frac{-C_A}{t_it_{i+1}}\
	V^\mu(q_i,q_{i+1})V_\mu(q_i,q_{i+1}) \right)}\\
	& \cdot \textcolor{red}{\prod_{i=1}^{n-1}
	\exp\left[\omega^0(q_{i\perp})\Delta y_i\right]}
	\end{split}
	\end{equation}
	with the momentum definitions
	\begin{center}
	\includegraphics{HEJ_central_Higgs_amplitude}
	\end{center}
	$q_i$ is the $i$th $t$-channel momentum and $\Delta y_i$ the rapidity
	gap between outgoing \emph{particles} (not partons) $i$ and $i+1$ in
	rapidity ordering.

	For \emph{peripheral} emission in the backward direction
	(\lstinline!MatrixElement::tree_kin_Higgs_first!) we first check whether
	the most backward parton is a gluon or an (anti-)quark. In the latter
	case the leading contribution to the matrix element arises through
	emission off the $t$-channel gluons and we can use the same formula
	eq.~(\ref{eq:ME_h_jets_central}) as for central emission. If the most
	backward parton is a gluon, the square of the matrix element can be
	written as
	\begin{equation}
	\label{eq:ME_h_jets_peripheral}
	\begin{split}
	\overline{\left\|\mathcal{M}_\text{HEJ}^{g f_2 \to H g\cdot g f_2}\right\|}^2 = \ &\frac {\alpha_s^2 (4\pi\alpha_s)^n} {\textcolor{blue}{4\ (N_c^2-1)}}
	\textcolor{blue}{\cdot\ K_{H}\
	\frac{K_{f_2}(p_n^+, p_b^+)}{t_{n-1}}\ \cdot\ \left\\|S_{g
	f_2\to H g f_2}\right\\|^2}\\
	& \cdot \prod_{\substack{i=1}}^{n-2} \textcolor{gray}{\left( \frac{-C_A}{t_it_{i+1}}\
	V^\mu(q_i,q_{i+1})V_\mu(q_i,q_{i+1}) \right)}\\
	& \cdot \textcolor{red}{\prod_{i=1}^{n-1}
	\exp\left[\omega^0(q_{i\perp}) (y_{i+1} - y_i)\right]}
	\end{split}
	\end{equation}
	with the momenta as follows:
	\begin{center}
	\includegraphics{HEJ_peripheral_Higgs_amplitude}
	\end{center}
	The \textcolor{blue}{blue part} is implemented in
	\lstinline!MatrixElement::MH2_forwardH!. All other building blocks are
	already available.\todo{Impact factors} The actual current contraction
	is calculated in \lstinline!MH2gq_outsideH! inside
	\lstinline!currents.cc!, which corresponds to $\tfrac{16 \pi^2}{t_1} \left\\|S_{g
	f_2\to H g f_2}\right\\|^2$.\todo{Fix this insane normalisation}

	The forward emission of a Higgs boson is completely analogous. We can
	use the same function \lstinline!MatrixElement::MH2_forwardH!, swapping
	$p_1 \leftrightarrow p_n,\,p_a \leftrightarrow p_b$.

	\subsubsection{FKL ladder and Lipatov vertices}
	\label{sec:FKL_ladder}

	The ``FKL ladder'' is the product
	\begin{equation}
	\label{eq:FKL_ladder}
	\prod_{i=1}^{n-2} \left( \frac{-C_A}{t_it_{i+1}}\
	V^\mu(q_i,q_{i+1})V_\mu(q_i,q_{i+1}) \right)
	\end{equation}
	appearing in the square of the matrix element for $n$ parton production,
	cf. eq.~(\ref{eq:ME}), and implemented in
	\lstinline!MatrixElement::FKL_ladder_weight!. The Lipatov vertex contraction
	$V^\mu(q_i,q_{i+1})V_\mu(q_i,q_{i+1})$ is implemented \lstinline!C2Lipatovots!.
	It is given by \todo{equation} \todo{mention difference between the two versions
	of \lstinline!C2Lipatovots!, maybe even get rid of one}.

	\subsubsection{Currents}
	\label{sec:currents}

	The current factors $\frac{K_{f_1}K_{f_2}}{t_1 t_{n-1}}\left\\|S_{f_1
	f_2\to f_1 f_2}\right\\|^2$ and their extensions for unordered and Higgs
	boson emissions are implemented in the \lstinline!jM2!$\dots$ functions
	of \texttt{src/currents.cc}. \todo{Only $\\|S\\|^2$ should be in currents}
	\footnote{The current implementation for
	Higgs production in \texttt{src/currents.cc} includes the $1/4$ factor
	inside $S$, opposing to~\eqref{eq:ME}. Thus the overall normalisation is
	unaffected.} The ``colour acceleration multiplier'' (CAM) $K_{f}$
	for a parton $f\in\{g,q,\bar{q}\}$ is defined as
	\begin{align}
	\label{eq:K_g}
	K_g(p_1^-, p_a^-) ={}& \frac{1}{2}\left(\frac{p_1^-}{p_a^-} + \frac{p_a^-}{p_1^-}\right)\left(C_A -
	\frac{1}{C_A}\right)+\frac{1}{C_A}\\
	\label{eq:K_q}
	K_q(p_1^-, p_a^-) ={}&K_{\bar{q}}(p_1^-, p_a^-) = C_F\,.
	\end{align}
	The Higgs current CAM used in eq.~(\ref{eq:ME_h_jets_peripheral}) is
	\begin{equation}
	\label{eq:K_H}
	K_H = C_A\,.
	\end{equation}
	The current contractions are given by\todo{check all this
	carefully!}
	\begin{align}
	\label{eq:S}
	\left\\|S_{f_1 f_2\to f_1 f_2}\right\\|^2 ={}& \sum_{\substack{\lambda_a =
	+,-\\\lambda_b = +,-}} \left\|j^{\lambda_a}_\mu(p_1, p_a)\
	j^{\lambda_b\,\mu}(p_n, p_b)\right\|^2 = 2\sum_{\lambda =
	+,-} \left\|j^{-}_\mu(p_1, p_a)\ j^{\lambda\,\mu}(p_n, p_b)\right\|^2\,,\\
	\left\\|S_{f_1 f_2\to f_1 H f_2}\right\\|^2 ={}& \sum_{\substack{\lambda_a =
	+,-\\\lambda_b = +,-}} \left\|j^{\lambda_a}_\mu(p_1, p_a)V_H^{\mu\nu}(q_j, q_{j+1})\
	j^{\lambda_b}_\nu(p_n, p_b)\right\|^2\,,\\
	\left\\|S_{g f_2 \to H g f_2}\right\\|^2 ={}& \sum_{
	\substack{
	\lambda_{a} = +,-\\
	\lambda_{1} =+,-\\
	\lambda_{b} = +,-
	}}
	\left\|j^{\lambda_a\lambda_1}_{H\,\mu}(p_1, p_a, p_H)\ j^{\lambda_b\,\mu}(p_n, p_b)\right\|^2\,.
	\end{align}
	The ``basic'' currents $j$ are independent of the parton flavour and read
	\begin{equation}
	\label{eq:j}
	j^\pm_\mu(p, q) = u^{\pm,\dagger}(p)\ \sigma^\pm_\mu\ u^{\pm}(q)\,,
	\end{equation}
	where $\sigma_\mu^\pm = (1, \pm \sigma_i)$ and $\sigma_i$ are the Pauli
	matrices
	\begin{equation}
	\label{eq:Pauli_matrices}
	\sigma_1 =
	\begin{pmatrix}
	0 & 1\\ 1 & 0
	\end{pmatrix}
	\,,
	\qquad \sigma_2 =
	\begin{pmatrix}
	0 & -i\\ i & 0
	\end{pmatrix}
	\,,
	\qquad \sigma_3 =
	\begin{pmatrix}
	1 & 0\\ 0 & -1
	\end{pmatrix}
	\,.
	\end{equation}
	The two-component chiral spinors are given by
	\begin{align}
	\label{eq:u_plus}
	u^+(p)={}& \left(\sqrt{p^+}, \sqrt{p^-} \hat{p}_\perp \right) \,,\\
	\label{eq:u_minus}
	u^-(p)={}& \left(\sqrt{p^-} \hat{p}^*_\perp, -\sqrt{p^+}\right)\,,
	\end{align}
	with $p^\pm = E\pm p_z,\, \hat{p}_\perp = \tfrac{p_\perp}{\|p_\perp\|},\,
	p_\perp = p_x + i p_y$. The spinors for vanishing transverse momentum
	are obtained by replacing $\hat{p_\perp} \to -1$.

	Explicitly, the currents read
	\begin{align}
	\label{eq:j-_explicit}
	j^-_\mu(p, q) ={}&
	\begin{pmatrix}
	\sqrt{p^+\,q^+} + \sqrt{p^-\,q^-} \hat{p}_{\perp} \hat{q}_{\perp}^*\\
	\sqrt{p^-\,q^+}\, \hat{p}_{\perp} + \sqrt{p^+\,q^-}\,\hat{q}_{\perp}^*\\
	-i \sqrt{p^-\,q^+}\, \hat{p}_{\perp} + i \sqrt{p^+\,q^-}\, \hat{q}_{\perp}^*\\
	\sqrt{p^+\,q^+} - \sqrt{p^-\,q^-}\, \hat{p}_{\perp}\, \hat{q}_{\perp}^*
	\end{pmatrix}\\
	j^+_\mu(p, q) ={}&\big(j^-_\mu(p, q)\big)^*
	\end{align}
	If $q= p_{\text{in}}$ is the momentum of an incoming parton, we have
	$\hat{p}_{\text{in} \perp} = -1$ and either $p_{\text{in}}^+ = 0$ or
	$p_{\text{in}}^- = 0$. The current simplifies further:\todo{Helicities flipped w.r.t code}
	\begin{align}
	\label{eq:j_explicit}
	j^-_\mu(p_{\text{out}}, p_{\text{in}}) ={}&
	\begin{pmatrix}
	\sqrt{p_{\text{in}}^+\,p_{\text{out}}^+}\\
	\sqrt{p_{\text{in}}^+\,p_{\text{out}}^-} \ \hat{p}_{\text{out}\,\perp}\\
	-i\,j^-_1\\
	j^-_0
	\end{pmatrix}
	& p_{\text{in}\,z} > 0\,,\\
	j^-_\mu(p_{\text{out}}, p_{\text{in}}) ={}&
	\begin{pmatrix}
	-\sqrt{p_{\text{in}}^-\,p_{\text{out}}^{-\phantom{+}}} \ \hat{p}_{\text{out}\,\perp}\\
	- \sqrt{p_{\text{in}}^-\,p_{\text{out}}^+}\\
	i\,j^-_1\\
	-j^-_0
	\end{pmatrix} & p_{\text{in}\,z} < 0\,.
	\end{align}

	\section{The fixed-order generator}
	\label{sec:HEJFOG}

	Even at leading order, standard fixed-order generators can only generate
	events with a limited number of final-state particles within reasonable
	CPU time. The purpose of the fixed-order generator is to supplement this
	with high-multiplicity input events according to the first two lines of
	eq.~\eqref{eq:resumdijetFKLmatched2} with the \HEJ approximation
	$\mathcal{M}_\text{LO, HEJ}^{f_1f_2\to f_1g\cdots gf_2}$ instead of the
	full fixed-order matrix element $\mathcal{M}_\text{LO}^{f_1f_2\to
	f_1g\cdots gf_2}$. Its usage is described in the user
	documentation \url{https://hej.web.cern.ch/HEJ/doc/current/user/HEJFOG.html}.

	\subsection{File structure}
	\label{sec:HEJFOG_structure}

	The code for the fixed-order generator is in the \texttt{FixedOrderGen}
	directory, which contains the following:
	\begin{description}
	\item[include:] Contains the C++ header files.
	\item[src:] Contains the C++ source files.
	\item[t:] Contains the source code for the automated tests.
	\item[CMakeLists.txt:] Configuration file for the \cmake build system.
	\item[configFO.yml:] Sample configuration file for the fixed-order generator.
	\end{description}
	The code is generally in the \lstinline!HEJFOG! namespace. Functions and
	classes \lstinline!MyClass! are usually declared in
	\texttt{include/MyClass.hh} and implemented in \texttt{src/MyClass.cc}.

	\subsection{Program flow}
	\label{sec:prog_flow}

	A single run of the fixed-order generator consists of three or four
	stages.

	First, we perform initialisation similar to HEJ 2, see
	section~\ref{sec:init}. Since there is a lot of overlap we frequently
	reuse classes and functions from HEJ 2, i.e. from the
	\lstinline!HEJ! namespace. The code for parsing the configuration file
	is in \texttt{include/config.hh} and implemented in
	\texttt{src/config.cc}.

	If partial unweighting is requested in the user settings \url{https://hej.web.cern.ch/HEJ/doc/current/user/HEJFOG.html#settings},
	the initialisation is followed by a calibration phase. We use a
	\lstinline!EventGenerator! to produce a number of trial
	events. We use these to calibrate the \lstinline!Unweighter! in
	its constructor and produce a first batch of partially unweighted
	events. This also allows us to estimate our unweighting efficiency.

	In the next step, we continue to generate events and potentially
	unweight them. Once the user-defined target number of events is reached,
	we adjust their weights according to the number of required trials. As
	in HEJ 2 (see section~\ref{sec:processing}), we pass the final
	events to a \lstinline!HEJ::Analysis! and a
	\lstinline!HEJ::CombinedEventWriter!.

	\subsection{Event generation}
	\label{sec:evgen}

	Event generation is performed by the
	\lstinline!EventGenerator::gen_event! member function. We begin by generating a
	\lstinline!PhaseSpacePoint!. This is not to be confused with
	the resummation phase space points represented by
	\lstinline!HEJ::PhaseSpacePoint!! After jet clustering, we compute the
	leading-order matrix element (see section~\ref{sec:ME}) and pdf factors.

	The phase space point generation is performed in the
	\lstinline!PhaseSpacePoint! constructor. We first construct the
	user-defined number of $n_p$ partons (by default gluons) in
	\lstinline!PhaseSpacePoint::gen_LO_partons!. We use flat sampling in
	rapidity and azimuthal angle. For the scalar transverse momenta, we
	distinguish between two cases. By default, they are generated based on a
	random variable $x_{p_\perp}$ according to
	\begin{equation}
	\label{eq:pt_sampling}
	p_\perp = p_{\perp,\text{min}} +
	\begin{cases}
	p_{\perp,\text{par}}
	\tan\left(
	x_{p_\perp}
	\arctan\left(
	\frac{p_{\perp,\text{max}} - p_{\perp,\text{min}}}{p_{\perp,\text{par}}}
	\right)
	\right)
	& y < y_\text{cut}
	\\
	- \tilde{p}_{\perp,\text{par}}\log\left(1 - x_{p_\perp}\left[1 -
	\exp\left(\frac{p_{\perp,\text{min}} -
	p_{\perp,\text{max}}}{\tilde{p}_{\perp,\text{par}}}\right)\right]\right)
	& y \geq y_\text{cut}
	\end{cases}\,,
	\end{equation}
	where $p_{\perp,\text{min}}$ is the minimum jet transverse momentum,
	$p_{\perp,\text{max}}$ is the maximum transverse parton momentum,
	tentatively set to the beam energy, and $y_\text{cut}$, $p_{\perp,\text{par}}$
	and $\tilde{p}_{\perp,\text{par}}$ are generation parameters set to
	heuristically determined values of
	\begin{align}
	y_\text{cut}&=3,\\
	p_{\perp,\text{par}}&=p_{\perp,\min}+\frac{n_p}{5}, \\
	\tilde{p}_{\perp,\text{par}}&=\frac{p_{\perp,\text{par}}}{1 +
	5(y-y_\text{cut})}.
	\end{align}
	The problem with this generation is that the transverse momenta peak at
	the minimum transverse momentum required for fixed-order jets. However,
	if we use the generated events as input for \HEJ resummation, events
	with such soft transverse momenta hardly contribute, see
	section~\ref{sec:ptj_res}. To generate efficient input for resummation,
	there is the user option \texttt{peak pt}, which specifies the
	dominant transverse momentum for resummation jets. If this option is
	set, most jets will be generated as above, but with
	$p_{\perp,\text{min}}$ set to the peak transverse momentum $p_{\perp,
	\text{peak}}$. In addition, there is a small chance of around $2\%$ to
	generate softer jets. The heuristic ansatz for the transverse momentum
	distribution in the ``soft'' region is
	\begin{equation}
	\label{FO_pt_soft}
	\frac{\partial \sigma}{\partial p_\perp} \propto e^{n_p\frac{p_\perp- p_{\perp,
	\text{peak}}}{\bar{p}_\perp}}\,,
	\end{equation}
	where $n_p$ is the number of partons and $\bar{p}_\perp \approx
	4\,$GeV. To achieve this distribution, we use
	\begin{equation}
	\label{eq:FO_pt_soft_sampling}
	p_\perp = p_{\perp, \text{peak}} + \bar{p}_\perp \frac{\log x_{p_\perp}}{n_p}
	\end{equation}
	and discard the phase space point if the parton is too soft, i.e. below the threshold for
	fixed-order jets.

	After ensuring that all partons form separate jets, we generate any
	potential colourless emissions. We then determine the incoming momenta
	and flavours in \lstinline!PhaseSpacePoint::reconstruct_incoming! and
	adjust the outgoing flavours to ensure an FKL configuration. Finally, we
	may reassign outgoing flavours to generate suppressed (for example
	unordered) configurations.

	\subsection{Unweighting}
	\label{sec:unweight}

	Straightforward event generation tends to produce many events with small
	weights. Those events have a negligible contribution to the final
	observables, but can take up considerable storage space and CPU time in
	later processing stages. This problem can be addressed by unweighting.

	For naive unweighting, one would determine the maximum weight
	$w_\text{max}$ of all events, discard each event with weight $w$ with a
	probability $p=w/w_\text{max}$, and set the weights of all remaining
	events to $w_\text{max}$. The downside to this procedure is that it also
	eliminates a sizeable fraction of events with moderate weight, so that
	the statistical convergence deteriorates.

	To ameliorate this problem, we perform unweighting only for events with
	sufficiently small weights. This is done by the
	\lstinline!Unweighter! class. In the constructor we estimate the
	mean and width of the weight-weight distribution from a sample of
	events. We use these estimates to determine the maximum weight below
	which unweighting is performed. The actual unweighting is the done in
	the \lstinline!Unweighter::unweight! function.

	\input{currents}

	\bibliographystyle{JHEP}
	\bibliography{biblio}


	\end{document}
	diff --git a/include/HEJ/Event.hh b/include/HEJ/Event.hh
	index 80a5694..32230d1 100644
	--- a/include/HEJ/Event.hh
	+++ b/include/HEJ/Event.hh
	@@ -1,211 +1,211 @@
	/** \file
	* \brief Declares the Event class and helpers
	*
	* \authors Jeppe Andersen, Tuomas Hapola, Marian Heil, Andreas Maier, Jennifer Smillie
	* \date 2019
	* \copyright GPLv2 or later
	*/

	#pragma once

	#include <array>
	#include <memory>
	#include <string>
	#include <unordered_map>
	#include <vector>

	#include "HEJ/event_types.hh"
	#include "HEJ/Particle.hh"
	#include "HEJ/RNG.hh"

	#include "fastjet/ClusterSequence.hh"

	namespace LHEF{
	class HEPEUP;
	class HEPRUP;
	}

	namespace fastjet{
	class JetDefinition;
	}

	namespace HEJ{

	struct ParameterDescription;

	//! Event parameters
	struct EventParameters{
	double mur; /*< Value of the Renormalisation Scale /
	double muf; /*< Value of the Factorisation Scale /
	double weight; /*< Event Weight /
	//! Optional description
	std::shared_ptr<ParameterDescription> description = nullptr;
	};

	//! Description of event parameters
	struct ParameterDescription {
	//! Name of central scale choice (e.g. "H_T/2")
	std::string scale_name;
	//! Actual renormalisation scale divided by central scale
	double mur_factor;
	//! Actual factorisation scale divided by central scale
	double muf_factor;

	ParameterDescription() = default;
	ParameterDescription(
	std::string scale_name, double mur_factor, double muf_factor
	):
	scale_name{scale_name}, mur_factor{mur_factor}, muf_factor{muf_factor}
	{};
	};

	//! An event before jet clustering & classification
	struct UnclusteredEvent{
	//! Default Constructor
	UnclusteredEvent() = default;
	//! Constructor from LesHouches event information
	UnclusteredEvent(LHEF::HEPEUP const & hepeup);

	std::array<Particle, 2> incoming; /*< Incoming Particles /
	std::vector<Particle> outgoing; /*< Outgoing Particles /
	//! Particle decays in the format {outgoing index, decay products}
	std::unordered_map<size_t, std::vector<Particle>> decays;
	//! Central parameter (e.g. scale) choice
	EventParameters central;
	std::vector<EventParameters> variations; /*< For parameter variation /
	};

	/** An event with clustered jets
	*
	* This is the main HEJ 2 event class.
	* It contains kinematic information including jet clustering,
	* parameter (e.g. scale) settings and the event weight.
	*/
	class Event{
	public:
	//! Default Event Constructor
	Event() = default;
	//! Event Constructor adding jet clustering to an unclustered event
	Event(
	UnclusteredEvent ev,
	fastjet::JetDefinition const & jet_def, double min_jet_pt
	);

	//! The jets formed by the outgoing partons
	std::vector<fastjet::PseudoJet> jets() const;

	//! The corresponding event before jet clustering
	UnclusteredEvent const & unclustered() const {
	return ev_;
	}

	//! Central parameter choice
	EventParameters const & central() const{
	return ev_.central;
	}

	//! Central parameter choice
	EventParameters & central(){
	return ev_.central;
	}

	//! Incoming particles
	std::array<Particle, 2> const & incoming() const{
	return ev_.incoming;
	}

	//! Outgoing particles
	std::vector<Particle> const & outgoing() const{
	return ev_.outgoing;
	}

	//! Particle decays
	/**
	* The key in the returned map corresponds to the index in the
	* vector returned by outgoing()
	*/
	std::unordered_map<size_t, std::vector<Particle>> const & decays() const{
	return ev_.decays;
	}

	//! Parameter (scale) variations
	std::vector<EventParameters> const & variations() const{
	return ev_.variations;
	}

	//! Parameter (scale) variations
	std::vector<EventParameters> & variations(){
	return ev_.variations;
	}

	//! Parameter (scale) variation
	/**
	* @param i Index of the requested variation
	*/
	EventParameters const & variations(size_t i) const{
	return ev_.variations[i];
	}

	//! Parameter (scale) variation
	/**
	* @param i Index of the requested variation
	*/
	EventParameters & variations(size_t i){
	return ev_.variations[i];
	}

	//! Indices of the jets the outgoing partons belong to
	/**
	* @param jets Jets to be tested
	* @returns A vector containing, for each outgoing parton,
	* the index in the vector of jets the considered parton
	* belongs to. If the parton is not inside any of the
	* passed jets, the corresponding index is set to -1.
	*/
	std::vector<int> particle_jet_indices(
	std::vector<fastjet::PseudoJet> const & jets
	) const{
	return cs_.particle_jet_indices(jets);
	}

	//! Jet definition used for clustering
	fastjet::JetDefinition const & jet_def() const{
	return cs_.jet_def();
	}

	//! Minimum jet transverse momentum
	double min_jet_pt() const{
	return min_jet_pt_;
	}

	//! Event type
	event_type::EventType type() const{
	return type_;
	}

	- //! Assign colours to each particle
	+ //! Give colours to each particle
	/**
	- * @returns true if new colour generated, i.e. same as is_HEJ()
	+ * @returns true if new colours are generated, i.e. same as is_HEJ()
	* @details Colour ordering is done according to leading colour in the MRK
	* limit, see \cite Andersen:2011zd. This only affects \ref
	* is_HEJ() "HEJ" configurations, all other \ref event_type
	* "EventTypes" will be ignored.
	- * @note This overwrites all previous set colours.
	+ * @note This overwrites all previously set colours.
	*/
	- bool generate_colour_flow(HEJ::RNG &);
	+ bool generate_colours(HEJ::RNG &);

	private:
	void sort(); /< Sort Particles in rapidity /
	UnclusteredEvent ev_;
	fastjet::ClusterSequence cs_;
	double min_jet_pt_;
	event_type::EventType type_;
	};

	//! Square of the partonic centre-of-mass energy \f$\hat{s}\f$
	double shat(Event const & ev);

	//! Convert an event to a LHEF::HEPEUP
	LHEF::HEPEUP to_HEPEUP(Event const & event, LHEF::HEPRUP *);

	}
	diff --git a/src/Event.cc b/src/Event.cc
	index 1f233c9..54e52f3 100644
	--- a/src/Event.cc
	+++ b/src/Event.cc
	@@ -1,474 +1,474 @@
	/**
	* \authors Jeppe Andersen, Tuomas Hapola, Marian Heil, Andreas Maier, Jennifer Smillie
	* \date 2019
	* \copyright GPLv2 or later
	*/
	#include "HEJ/Event.hh"

	#include <algorithm>
	#include <assert.h>
	#include <numeric>
	#include <utility>

	#include "LHEF/LHEF.h"

	#include "fastjet/JetDefinition.hh"

	#include "HEJ/Constants.hh"
	#include "HEJ/exceptions.hh"
	#include "HEJ/PDG_codes.hh"

	namespace HEJ{

	namespace{
	constexpr int status_in = -1;
	constexpr int status_decayed = 2;
	constexpr int status_out = 1;

	/// @name helper functions to determine event type
	//@{

	/**
	* \brief check if final state valid for HEJ
	*
	* check if there is at most one photon, W, H, Z in the final state
	* and all the rest are quarks or gluons
	*/
	bool final_state_ok(std::vector<Particle> const & outgoing){
	bool has_AWZH_boson = false;
	for(auto const & out: outgoing){
	if(is_AWZH_boson(out.type)){
	if(has_AWZH_boson) return false;
	has_AWZH_boson = true;
	}
	else if(! is_parton(out.type)) return false;
	}
	return true;
	}

	template<class Iterator>
	Iterator remove_AWZH(Iterator begin, Iterator end){
	return std::remove_if(
	begin, end, [](Particle const & p){return is_AWZH_boson(p);}
	);
	}

	template<class Iterator>
	bool valid_outgoing(Iterator begin, Iterator end){
	return std::distance(begin, end) >= 2
	&& std::is_sorted(begin, end, rapidity_less{})
	&& std::count_if(
	begin, end, [](Particle const & s){return is_AWZH_boson(s);}
	) < 2;
	}

	/// @note that this changes the outgoing range!
	template<class ConstIterator, class Iterator>
	bool is_FKL(
	ConstIterator begin_incoming, ConstIterator end_incoming,
	Iterator begin_outgoing, Iterator end_outgoing
	){
	assert(std::distance(begin_incoming, end_incoming) == 2);
	assert(std::distance(begin_outgoing, end_outgoing) >= 2);

	// One photon, W, H, Z in the final state is allowed.
	// Remove it for remaining tests,
	end_outgoing = remove_AWZH(begin_outgoing, end_outgoing);

	// Test if this is a standard FKL configuration.
	return
	(begin_incoming->type == begin_outgoing->type)
	&& ((end_incoming-1)->type == (end_outgoing-1)->type)
	&& std::all_of(
	begin_outgoing + 1, end_outgoing - 1,
	[](Particle const & p){ return p.type == pid::gluon; }
	);
	}

	bool is_FKL(
	std::array<Particle, 2> const & incoming,
	std::vector<Particle> outgoing
	){
	assert(std::is_sorted(begin(incoming), end(incoming), pz_less{}));
	assert(valid_outgoing(begin(outgoing), end(outgoing)));

	return is_FKL(
	begin(incoming), end(incoming),
	begin(outgoing), end(outgoing)
	);
	}

	bool has_2_jets(Event const & event){
	return event.jets().size() >= 2;
	}

	/**
	* \brief Checks whether event is unordered backwards
	* @param ev Event
	* @returns Is Event Unordered Backwards
	*
	* - Checks there is more than 3 constuents in the final state
	* - Checks there is more than 3 jets
	* - Checks the most backwards parton is a gluon
	* - Checks the most forwards jet is not a gluon
	* - Checks the rest of the event is FKL
	* - Checks the second most backwards is not a different boson
	* - Checks the unordered gluon actually forms a jet
	*/
	bool is_unordered_backward(Event const & ev){
	auto const & in = ev.incoming();
	auto const & out = ev.outgoing();
	assert(std::is_sorted(begin(in), end(in), pz_less{}));
	assert(valid_outgoing(begin(out), end(out)));

	if(out.size() < 3) return false;
	if(ev.jets().size() < 3) return false;
	if(in.front().type == pid::gluon) return false;
	if(out.front().type != pid::gluon) return false;
	// When skipping the unordered emission
	// the remainder should be a regular FKL event,
	// except that the (new) first outgoing particle must not be a A,W,Z,H.
	const auto FKL_begin = next(begin(out));
	if(is_AWZH_boson(*FKL_begin)) return false;
	if(!is_FKL(in, {FKL_begin, end(out)})) return false;
	// check that the unordered gluon forms an extra jet
	const auto jets = sorted_by_rapidity(ev.jets());
	const auto indices = ev.particle_jet_indices({jets.front()});
	return indices[0] >= 0 && indices[1] == -1;
	}

	/**
	* \brief Checks for a forward unordered gluon emission
	* @param ev Event
	* @returns Is the event a forward unordered emission
	*
	* \see is_unordered_backward
	*/
	bool is_unordered_forward(Event const & ev){
	auto const & in = ev.incoming();
	auto const & out = ev.outgoing();
	assert(std::is_sorted(begin(in), end(in), pz_less{}));
	assert(valid_outgoing(begin(out), end(out)));

	if(out.size() < 3) return false;
	if(ev.jets().size() < 3) return false;
	if(in.back().type == pid::gluon) return false;
	if(out.back().type != pid::gluon) return false;
	// When skipping the unordered emission
	// the remainder should be a regular FKL event,
	// except that the (new) last outgoing particle must not be a A,W,Z,H.
	const auto FKL_end = prev(end(out));
	if(is_AWZH_boson(*prev(FKL_end))) return false;
	if(!is_FKL(in, {begin(out), FKL_end})) return false;
	// check that the unordered gluon forms an extra jet
	const auto jets = sorted_by_rapidity(ev.jets());
	const auto indices = ev.particle_jet_indices({jets.back()});
	return indices.back() >= 0 && indices[indices.size()-2] == -1;
	}

	using event_type::EventType;

	EventType classify(Event const & ev){
	if(! final_state_ok(ev.outgoing())) return EventType::bad_final_state;
	if(! has_2_jets(ev)) return EventType::no_2_jets;
	if(is_FKL(ev.incoming(), ev.outgoing())) return EventType::FKL;
	if(is_unordered_backward(ev)){
	return EventType::unordered_backward;
	}
	if(is_unordered_forward(ev)){
	return EventType::unordered_forward;
	}
	return EventType::nonHEJ;
	}
	//@}

	Particle extract_particle(LHEF::HEPEUP const & hepeup, int i){
	const ParticleID id = static_cast<ParticleID>(hepeup.IDUP[i]);
	const fastjet::PseudoJet momentum{
	hepeup.PUP[i][0], hepeup.PUP[i][1],
	hepeup.PUP[i][2], hepeup.PUP[i][3]
	};
	if(is_parton(id))
	return Particle{ id, std::move(momentum), hepeup.ICOLUP[i] };
	return Particle{ id, std::move(momentum), {} };
	}

	bool is_decay_product(std::pair<int, int> const & mothers){
	if(mothers.first == 0) return false;
	return mothers.second == 0 \|\| mothers.first == mothers.second;
	}

	} // namespace anonymous

	UnclusteredEvent::UnclusteredEvent(LHEF::HEPEUP const & hepeup):
	central(EventParameters{
	hepeup.scales.mur, hepeup.scales.muf, hepeup.weight()
	})
	{
	size_t in_idx = 0;
	for (int i = 0; i < hepeup.NUP; ++i) {
	// skip decay products
	// we will add them later on, but we have to ensure that
	// the decayed particle is added before
	if(is_decay_product(hepeup.MOTHUP[i])) continue;

	auto particle = extract_particle(hepeup, i);
	// needed to identify mother particles for decay products
	particle.p.set_user_index(i+1);

	if(hepeup.ISTUP[i] == status_in){
	if(in_idx > incoming.size()) {
	throw std::invalid_argument{
	"Event has too many incoming particles"
	};
	}
	incoming[in_idx++] = std::move(particle);
	}
	else outgoing.emplace_back(std::move(particle));
	}

	// add decay products
	for (int i = 0; i < hepeup.NUP; ++i) {
	if(!is_decay_product(hepeup.MOTHUP[i])) continue;
	const int mother_id = hepeup.MOTHUP[i].first;
	const auto mother = std::find_if(
	begin(outgoing), end(outgoing),
	[mother_id](Particle const & particle){
	return particle.p.user_index() == mother_id;
	}
	);
	if(mother == end(outgoing)){
	throw std::invalid_argument{"invalid decay product parent"};
	}
	const int mother_idx = std::distance(begin(outgoing), mother);
	assert(mother_idx >= 0);
	decays[mother_idx].emplace_back(extract_particle(hepeup, i));
	}
	}

	namespace {
	void connect_incoming(Particle & in, int & colour, int & anti_colour){
	in.colour = std::make_pair(anti_colour, colour);
	// gluon
	if(in.type == pid::gluon)
	return;
	if(in.type > 0){
	// quark
	assert(is_quark(in));
	in.colour->second = 0;
	colour*=-1;
	return;
	}
	// anti-quark
	assert(is_antiquark(in));
	in.colour->first = 0;
	anti_colour*=-1;
	return;
	}
	}

	- bool Event::generate_colour_flow(RNG & ran){
	+ bool Event::generate_colours(RNG & ran){
	// generate only for HEJ events
	if(!event_type::is_HEJ(type()))
	return false;
	assert(std::is_sorted(
	begin(outgoing()), end(outgoing()), rapidity_less{}));
	assert(incoming()[0].pz() < incoming()[1].pz());

	// positive (anti-)colour -> can connect
	// negative (anti-)colour -> not available/used up by (anti-)quark
	int colour = COLOUR_OFFSET;
	int anti_colour = colour+1;
	// initialise first
	connect_incoming(ev_.incoming[0], colour, anti_colour);

	for(auto & part: ev_.outgoing){
	assert(colour>0 \|\| anti_colour>0);
	if(part.type == ParticleID::gluon){
	// gluon
	if(colour>0 && anti_colour>0){
	// on g line => connect to colour OR anti-colour (random)
	if(ran.flat() < 0.5){
	part.colour = std::make_pair(colour+2,colour);
	colour+=2;
	} else {
	part.colour = std::make_pair(anti_colour, anti_colour+2);
	anti_colour+=2;
	}
	} else if(colour > 0){
	// on q line => connect to available colour
	part.colour = std::make_pair(colour+2, colour);
	colour+=2;
	} else {
	assert(colour<0 && anti_colour>0);
	// on qx line => connect to available anti-colour
	part.colour = std::make_pair(anti_colour, anti_colour+2);
	anti_colour+=2;
	}
	} else if(is_quark(part)) {
	// quark
	assert(anti_colour>0);
	if(colour>0){
	// on g line => connect and remove anti-colour
	part.colour = std::make_pair(anti_colour, 0);
	anti_colour+=2;
	anti_colour*=-1;
	} else {
	// on qx line => new colour
	colour*=-1;
	part.colour = std::make_pair(colour, 0);
	}
	} else if(is_antiquark(part)) {
	// anti-quark
	assert(colour>0);
	if(anti_colour>0){
	// on g line => connect and remove colour
	part.colour = std::make_pair(0, colour);
	colour+=2;
	colour*=-1;
	} else {
	// on q line => new anti-colour
	anti_colour*=-1;
	part.colour = std::make_pair(0, anti_colour);
	}
	}
	// else not a parton
	}
	// Connect last
	connect_incoming(ev_.incoming[1], anti_colour, colour);
	return true;
	}

	void Event::sort(){
	// sort incoming
	std::sort(
	begin(ev_.incoming), end(ev_.incoming),
	[](Particle o1, Particle o2){return o1.p.pz()<o2.p.pz();}
	);

	//sort outgoing
	if(std::is_sorted(begin(ev_.outgoing), end(ev_.outgoing), rapidity_less{}))
	return;
	auto old_outgoing = std::move(ev_.outgoing);
	std::vector<size_t> idx(old_outgoing.size());
	std::iota(idx.begin(), idx.end(), 0);
	std::sort(idx.begin(), idx.end(), [&old_outgoing](size_t i, size_t j){
	return old_outgoing[i].rapidity() < old_outgoing[j].rapidity();
	});
	ev_.outgoing.clear();
	for(size_t i: idx) {
	ev_.outgoing.emplace_back(std::move(old_outgoing[i]));
	}

	// find decays again
	if(!ev_.decays.empty()){
	auto old_decays = std::move(ev_.decays);
	ev_.decays.clear();
	for(size_t i=0; i<idx.size(); ++i) {
	auto decay = old_decays.find(idx[i]);
	if(decay != old_decays.end())
	ev_.decays.emplace(i, std::move(decay->second));
	}
	assert(old_decays.size() == ev_.decays.size());
	}

	}

	Event::Event(
	UnclusteredEvent ev,
	fastjet::JetDefinition const & jet_def, double min_jet_pt
	):
	ev_{std::move(ev)},
	cs_{to_PseudoJet(filter_partons(ev_.outgoing)), jet_def},
	min_jet_pt_{min_jet_pt}
	{
	// sort particles
	sort();

	// classify event
	type_ = classify(*this);

	assert(std::is_sorted(begin(outgoing()), end(outgoing()), rapidity_less{}));
	}

	std::vector<fastjet::PseudoJet> Event::jets() const{
	return cs_.inclusive_jets(min_jet_pt_);
	}

	double shat(Event const & ev){
	return (ev.incoming()[0].p + ev.incoming()[1].p).m2();
	}

	LHEF::HEPEUP to_HEPEUP(Event const & event, LHEF::HEPRUP * heprup){
	LHEF::HEPEUP result;
	result.heprup = heprup;
	result.weights = {{event.central().weight, nullptr}};
	for(auto const & var: event.variations()){
	result.weights.emplace_back(var.weight, nullptr);
	}
	size_t num_particles = event.incoming().size() + event.outgoing().size();
	for(auto const & decay: event.decays()) num_particles += decay.second.size();
	result.NUP = num_particles;
	// the following entries are pretty much meaningless
	result.IDPRUP = event.type()+1; // event ID
	result.AQEDUP = 1./128.; // alpha_EW
	//result.AQCDUP = 0.118 // alpha_QCD
	// end meaningless part
	result.XWGTUP = event.central().weight;
	result.SCALUP = event.central().muf;
	result.scales.muf = event.central().muf;
	result.scales.mur = event.central().mur;
	result.scales.SCALUP = event.central().muf;
	result.pdfinfo.p1 = event.incoming().front().type;
	result.pdfinfo.p2 = event.incoming().back().type;
	result.pdfinfo.scale = event.central().muf;

	result.IDUP.reserve(num_particles); // PID
	result.ISTUP.reserve(num_particles); // status (in, out, decay)
	result.PUP.reserve(num_particles); // momentum
	result.MOTHUP.reserve(num_particles); // index mother particle
	result.ICOLUP.reserve(num_particles); // colour
	// incoming
	for(Particle const & in: event.incoming()){
	result.IDUP.emplace_back(in.type);
	result.ISTUP.emplace_back(status_in);
	result.PUP.push_back({in.p[0], in.p[1], in.p[2], in.p[3], in.p.m()});
	result.MOTHUP.emplace_back(0, 0);
	assert(in.colour);
	result.ICOLUP.emplace_back(*in.colour);
	}
	// outgoing
	for(size_t i = 0; i < event.outgoing().size(); ++i){
	Particle const & out = event.outgoing()[i];
	result.IDUP.emplace_back(out.type);
	const int status = event.decays().count(i)?status_decayed:status_out;
	result.ISTUP.emplace_back(status);
	result.PUP.push_back({out.p[0], out.p[1], out.p[2], out.p[3], out.p.m()});
	result.MOTHUP.emplace_back(1, 2);
	if(out.colour)
	result.ICOLUP.emplace_back(*out.colour);
	else{
	assert(is_AWZH_boson(out));
	result.ICOLUP.emplace_back(std::make_pair(0,0));
	}
	}
	// decays
	for(auto const & decay: event.decays()){
	for(auto const out: decay.second){
	result.IDUP.emplace_back(out.type);
	result.ISTUP.emplace_back(status_out);
	result.PUP.push_back({out.p[0], out.p[1], out.p[2], out.p[3], out.p.m()});
	const size_t mother_idx = 1 + event.incoming().size() + decay.first;
	result.MOTHUP.emplace_back(mother_idx, mother_idx);
	result.ICOLUP.emplace_back(0,0);
	}
	}

	assert(result.ICOLUP.size() == num_particles);
	static constexpr double unknown_spin = 9.; //per Les Houches accord
	result.VTIMUP = std::vector<double>(num_particles, unknown_spin);
	result.SPINUP = result.VTIMUP;
	return result;
	}

	}
	diff --git a/src/EventReweighter.cc b/src/EventReweighter.cc
	index a8e6b00..89ebea6 100644
	--- a/src/EventReweighter.cc
	+++ b/src/EventReweighter.cc
	@@ -1,276 +1,276 @@
	/**
	* \authors Jeppe Andersen, Tuomas Hapola, Marian Heil, Andreas Maier, Jennifer Smillie
	* \date 2019
	* \copyright GPLv2 or later
	*/
	#include "HEJ/EventReweighter.hh"

	#include <algorithm>
	#include <assert.h>
	#include <limits>
	#include <math.h>
	#include <stddef.h>
	#include <string>
	#include <unordered_map>

	#include "fastjet/ClusterSequence.hh"

	#include "LHEF/LHEF.h"

	#include "HEJ/Event.hh"
	#include "HEJ/exceptions.hh"
	#include "HEJ/Particle.hh"
	#include "HEJ/PDG_codes.hh"
	#include "HEJ/PhaseSpacePoint.hh"
	#include "HEJ/Weights.hh"

	namespace HEJ{
	using EventType = event_type::EventType;

	namespace {

	static_assert(
	std::numeric_limits<double>::has_quiet_NaN,
	"no quiet NaN for double"
	);
	constexpr double NaN = std::numeric_limits<double>::quiet_NaN();

	UnclusteredEvent to_UnclusteredEvent(PhaseSpacePoint const & psp){
	UnclusteredEvent result;
	result.incoming = psp.incoming();
	std::sort(
	begin(result.incoming), end(result.incoming),
	[](Particle o1, Particle o2){return o1.p.pz()<o2.p.pz();}
	);
	assert(result.incoming.size() == 2);
	result.outgoing = psp.outgoing();
	assert(
	std::is_sorted(
	begin(result.outgoing), end(result.outgoing),
	rapidity_less{}
	)
	);
	assert(result.outgoing.size() >= 2);
	result.decays = psp.decays();
	result.central.mur = NaN;
	result.central.muf = NaN;
	result.central.weight = psp.weight();
	return result;
	}

	} // namespace anonymous

	EventReweighter::EventReweighter(
	LHEF::HEPRUP const & heprup,
	ScaleGenerator scale_gen,
	EventReweighterConfig conf,
	HEJ::RNG & ran
	):
	EventReweighter{
	HEJ::Beam{
	heprup.EBMUP.first,
	{{
	static_cast<HEJ::ParticleID>(heprup.IDBMUP.first),
	static_cast<HEJ::ParticleID>(heprup.IDBMUP.second)
	}}
	},
	heprup.PDFSUP.first,
	std::move(scale_gen),
	std::move(conf),
	ran
	}
	{
	if(heprup.EBMUP.second != E_beam_){
	throw std::invalid_argument(
	"asymmetric beam: " + std::to_string(E_beam_)
	+ " ---> <--- " + std::to_string(heprup.EBMUP.second)
	);
	};
	if(heprup.PDFSUP.second != pdf_.id()){
	throw std::invalid_argument(
	"conflicting PDF ids: " + std::to_string(pdf_.id())
	+ " vs. " + std::to_string(heprup.PDFSUP.second)
	);
	}
	}

	EventReweighter::EventReweighter(
	Beam beam,
	int pdf_id,
	ScaleGenerator scale_gen,
	EventReweighterConfig conf,
	HEJ::RNG & ran
	):
	param_{std::move(conf)},
	E_beam_{beam.E},
	pdf_{pdf_id, beam.type.front(), beam.type.back()},
	MEt2_{
	[this](double mu){ return pdf_.Halphas(mu); },
	param_.ME_config
	},
	scale_gen_(std::move(scale_gen)),
	ran_{ran}
	{}

	PDF const & EventReweighter::pdf() const{
	return pdf_;
	}

	std::vector<Event> EventReweighter::reweight(
	Event const & input_ev, int num_events
	){
	auto res_events = gen_res_events(input_ev, num_events);
	if(res_events.empty()) return {};
	for(auto & event: res_events) event = scale_gen_(event);
	return rescale(input_ev, std::move(res_events));
	}

	std::vector<Event> EventReweighter::gen_res_events(
	Event const & ev,
	int phase_space_points
	){
	assert(ev.variations().empty());

	switch(param_.treat.at(ev.type())){
	case EventTreatment::discard: return {};
	case EventTreatment::keep:
	if(! jets_pass_resummation_cuts(ev)) return {};
	else return {ev};
	default:;
	}
	const double Born_shat = shat(ev);

	std::vector<Event> resummation_events;
	for(int psp_number = 0; psp_number < phase_space_points; ++psp_number){
	PhaseSpacePoint psp{ev, param_.psp_config, ran_};
	if(psp.weight() == 0.) continue;
	if(psp.incoming()[0].E() > E_beam_ \|\| psp.incoming()[1].E() > E_beam_) continue;

	resummation_events.emplace_back(
	to_UnclusteredEvent(std::move(psp)),
	param_.jet_param.def, param_.jet_param.min_pt
	);
	auto & new_event = resummation_events.back();
	- new_event.generate_colour_flow(ran_);
	+ new_event.generate_colours(ran_);
	assert(new_event.variations().empty());
	new_event.central().mur = ev.central().mur;
	new_event.central().muf = ev.central().muf;
	const double resum_shat = shat(new_event);
	new_event.central().weight = ev.central().weightBorn_shat*Born_shat/
	(phase_space_pointsresum_shatresum_shat);
	}
	return resummation_events;
	}

	std::vector<Event> EventReweighter::rescale(
	Event const & Born_ev,
	std::vector<Event> events
	) const{
	const double Born_pdf = pdf_factors(Born_ev).central;
	const double Born_ME = tree_matrix_element(Born_ev);

	for(auto & cur_event: events){
	const auto pdf = pdf_factors(cur_event);
	assert(pdf.variations.size() == cur_event.variations().size());
	const auto ME = matrix_elements(cur_event);
	assert(ME.variations.size() == cur_event.variations().size());
	cur_event.central().weight = pdf.centralME.central/(Born_pdf*Born_ME);
	for(size_t i = 0; i < cur_event.variations().size(); ++i){
	cur_event.variations(i).weight *=
	pdf.variations[i]ME.variations[i]/(Born_pdfBorn_ME);
	}
	}
	return events;
	};

	bool EventReweighter::jets_pass_resummation_cuts(
	Event const & ev
	) const{
	const auto out_as_PseudoJet = to_PseudoJet(filter_partons(ev.outgoing()));
	fastjet::ClusterSequence cs{out_as_PseudoJet, param_.jet_param.def};
	return cs.inclusive_jets(param_.jet_param.min_pt).size() == ev.jets().size();
	}

	Weights
	EventReweighter::pdf_factors(Event const & ev) const{
	auto const & a = ev.incoming().front();
	auto const & b = ev.incoming().back();
	const double xa = a.p.e()/E_beam_;
	const double xb = b.p.e()/E_beam_;

	Weights result;
	std::unordered_map<double, double> known_pdf;
	result.central =
	pdf_.pdfpt(0,xa,ev.central().muf,a.type)*
	pdf_.pdfpt(1,xb,ev.central().muf,b.type);
	known_pdf.emplace(ev.central().muf, result.central);

	result.variations.reserve(ev.variations().size());
	for(auto const & ev_param: ev.variations()){
	const double muf = ev_param.muf;
	auto cur_pdf = known_pdf.find(muf);
	if(cur_pdf == known_pdf.end()){
	cur_pdf = known_pdf.emplace(
	muf,
	pdf_.pdfpt(0,xa,muf,a.type)*pdf_.pdfpt(1,xb,muf,b.type)
	).first;
	}
	result.variations.emplace_back(cur_pdf->second);
	}
	assert(result.variations.size() == ev.variations().size());
	return result;
	}

	Weights
	EventReweighter::matrix_elements(Event const & ev) const{
	assert(param_.treat.count(ev.type()) > 0);
	if(param_.treat.find(ev.type())->second == EventTreatment::keep){
	return fixed_order_scale_ME(ev);
	}

	return MEt2_(ev);
	}

	double EventReweighter::tree_matrix_element(Event const & ev) const{
	assert(ev.variations().empty());
	assert(param_.treat.count(ev.type()) > 0);
	if(param_.treat.find(ev.type())->second == EventTreatment::keep){
	return fixed_order_scale_ME(ev).central;
	}
	return MEt2_.tree(ev).central;
	}

	Weights
	EventReweighter::fixed_order_scale_ME(Event const & ev) const{
	int alpha_s_power = 0;
	for(auto const & part: ev.outgoing()){
	if(is_parton(part))
	++alpha_s_power;
	else {
	switch(part.type){
	case pid::Higgs: {
	alpha_s_power += 2;
	break;
	}
	// TODO
	case pid::Wp:
	case pid::Wm:
	case pid::photon:
	case pid::Z:
	default:
	throw not_implemented("Emission of boson of unsupported type");
	}
	}
	}

	Weights result;
	result.central = pow(pdf_.Halphas(ev.central().mur), alpha_s_power);
	for(auto const & var: ev.variations()){
	result.variations.emplace_back(
	pow(pdf_.Halphas(var.mur), alpha_s_power)
	);
	}
	return result;
	}

	} // namespace HEJ
	diff --git a/t/test_colour_flow.cc b/t/test_colours.cc
	similarity index 99%
	rename from t/test_colour_flow.cc
	rename to t/test_colours.cc
	index 78e9f6d..8c49ebe 100644
	--- a/t/test_colour_flow.cc
	+++ b/t/test_colours.cc
	@@ -1,213 +1,213 @@
	#include <stdexcept>
	#include <utility>

	#include "HEJ/Event.hh"
	#include "HEJ/RNG.hh"

	#define ASSERT(x) if(!(x)) { \
	throw std::logic_error("Assertion '" #x "' failed."); \
	}

	/// biased RNG to connect always to colour
	class dum_rnd: public HEJ::DefaultRNG {
	public:
	dum_rnd() = default;
	double flat() override {
	return 0.;
	};
	};

	void dump_event(HEJ::Event const & ev){
	for(auto const & in: ev.incoming()){
	std::cerr << "in type=" << in.type
	<< ", colour={" << (*in.colour).first
	<< ", " << (*in.colour).second << "}\n";
	}
	for(auto const & out: ev.outgoing()){
	std::cerr << "out type=" << out.type << ", colour={";
	if(out.colour)
	std::cerr << (out.colour).first << ", " << (out.colour).second;
	else
	std::cerr << "non, non";
	std::cerr << "}\n";
	}
	}

	/// true if colour is allowed for particle
	bool correct_colour(HEJ::Particle const & part){
	if(HEJ::is_AWZH_boson(part) && !part.colour) return true;
	if(!part.colour) return false;
	int const colour = part.colour->first;
	int const anti_colour = part.colour->second;
	if(part.type == HEJ::ParticleID::gluon)
	return colour != anti_colour && colour > 0 && anti_colour > 0;
	if(HEJ::is_quark(part))
	return anti_colour == 0 && colour > 0;
	return colour == 0 && anti_colour > 0;
	}

	bool correct_colour(HEJ::Event const & ev){
	for(auto const & part: ev.incoming()){
	if(!correct_colour(part))
	return false;
	}
	for(auto const & part: ev.outgoing()){
	if(!correct_colour(part))
	return false;
	}
	return true;
	}

	bool match_expected(
	HEJ::Event const & ev,
	std::vector<HEJ::Colour> const & expected
	){
	ASSERT(ev.outgoing().size()+2==expected.size());
	for(size_t i=0; i<ev.incoming().size(); ++i){
	ASSERT(ev.incoming()[i].colour);
	if( *ev.incoming()[i].colour != expected[i])
	return false;
	}
	for(size_t i=2; i<ev.outgoing().size()+2; ++i){
	if( ev.outgoing()[i-2].colour ){
	if( *ev.outgoing()[i-2].colour != expected[i] )
	return false;
	} else if( expected[i].first != 0 \|\| expected[i].second != 0)
	return false;
	}
	return true;
	}

	void check_event(
	HEJ::UnclusteredEvent unc_ev, std::vector<HEJ::Colour> const & expected_colours
	){
	HEJ::Event ev(
	unc_ev,
	fastjet::JetDefinition(fastjet::JetAlgorithm::antikt_algorithm, 0.4), 30.);
	ASSERT(HEJ::event_type::is_HEJ(ev.type()));
	dum_rnd rng;
	- ev.generate_colour_flow(rng);
	+ ev.generate_colours(rng);
	if(!correct_colour(ev)){
	std::cerr << "Found illegal colours for event\n";
	dump_event(ev);
	throw std::invalid_argument("Illegal colour set");
	}
	if(!match_expected(ev, expected_colours)){
	std::cerr << "Colours didn't match expectation. Found\n";
	dump_event(ev);
	std::cerr << "but expected\n";
	for(auto const & col: expected_colours){
	std::cerr << "colour={" << col.first << ", " << col.second << "}\n";
	}
	throw std::logic_error("Colours did not match expectation");
	}
	}

	int main() {
	HEJ::UnclusteredEvent ev;
	std::vector<HEJ::Colour> expected_colours(7);

	/// pure gluon
	ev.incoming[0] = { HEJ::ParticleID::gluon, { 0, 0,-427, 427}, {}};
	ev.incoming[1] = { HEJ::ParticleID::gluon, { 0, 0, 851, 851}, {}};
	ev.outgoing.push_back({ HEJ::ParticleID::gluon, { 196, 124, -82, 246}, {}});
	ev.outgoing.push_back({ HEJ::ParticleID::gluon, {-167,-184, 16, 249}, {}});
	ev.outgoing.push_back({ HEJ::ParticleID::higgs, { 197, 180, 168, 339}, {}});
	ev.outgoing.push_back({ HEJ::ParticleID::gluon, {-190, -57, 126, 235}, {}});
	ev.outgoing.push_back({ HEJ::ParticleID::gluon, { -36, -63, 196, 209}, {}});

	expected_colours[0] = {502, 501};
	expected_colours[1] = {509, 502};
	expected_colours[2] = {503, 501};
	expected_colours[3] = {505, 503};
	expected_colours[4] = { 0, 0};
	expected_colours[5] = {507, 505};
	expected_colours[6] = {509, 507};
	check_event(ev, expected_colours);

	/// last g to Qx (=> gQx -> g ... Qx)
	ev.incoming[1].type = HEJ::ParticleID::d_bar;
	ev.outgoing[4].type = HEJ::ParticleID::d_bar;
	// => only end changes
	expected_colours[1].first = 0;
	expected_colours[6].first = 0;
	check_event(ev, expected_colours);

	{
	// don't overwrite
	auto new_expected = expected_colours;
	auto new_ev = ev;
	/// uno forward (=> gQx -> g ... Qx g)
	std::swap(new_ev.outgoing[3].type, new_ev.outgoing[4].type);
	// => uno quarks eats colour and gluon connects to anti-colour
	new_expected[5] = {0, expected_colours[3].first};
	new_expected[6] = {expected_colours[0].first, expected_colours[0].first+2};
	new_expected[1].second += 2; // one more anti-colour in line
	check_event(new_ev, new_expected);
	}

	/// swap Qx <-> Q (=> gQx -> g ... Qx)
	ev.incoming[1].type = HEJ::ParticleID::d;
	ev.outgoing[4].type = HEJ::ParticleID::d;
	// => swap: colour<->anti && inital<->final
	std::swap(expected_colours[1], expected_colours[6]);
	std::swap(expected_colours[1].first, expected_colours[1].second);
	std::swap(expected_colours[6].first, expected_colours[6].second);
	check_event(ev, expected_colours);

	/// first g to q (=> qxQ -> qx ... Q)
	ev.incoming[0].type = HEJ::ParticleID::u_bar;
	ev.outgoing[0].type = HEJ::ParticleID::u_bar;
	expected_colours[0] = { 0, 501};
	// => shift anti-colour index one up
	expected_colours[1].first -= 2;
	expected_colours[5] = expected_colours[3];
	expected_colours[3] = expected_colours[2];
	expected_colours[2] = { 0, 502};
	check_event(ev, expected_colours);

	{
	// don't overwrite
	auto new_expected = expected_colours;
	auto new_ev = ev;
	/// uno backward (=> qxQ -> g qx ... Q)
	std::swap(new_ev.outgoing[0].type, new_ev.outgoing[1].type);
	// => uno gluon connects to quark colour
	new_expected[3] = expected_colours[2];
	new_expected[2] = {expected_colours[0].second+2, expected_colours[0].second};
	check_event(new_ev, new_expected);

	/// swap qx <-> q (=> qQ -> g q ... Q)
	new_ev.incoming[0].type = HEJ::ParticleID::u;
	new_ev.outgoing[1].type = HEJ::ParticleID::u;
	// => swap: colour<->anti && inital<->final
	std::swap(new_expected[0], new_expected[3]);
	std::swap(new_expected[0].first, new_expected[0].second);
	std::swap(new_expected[3].first, new_expected[3].second);
	// => & connect first gluon with remaining anti-colour
	new_expected[2] = {new_expected[0].first, new_expected[0].first+2};
	// shift colour line one down
	new_expected[1].first-=2;
	new_expected[5].first-=2;
	new_expected[5].second-=2;
	// shift anti-colour line one up
	new_expected[6].first+=2;
	check_event(new_ev, new_expected);
	}

	{
	// don't overwrite
	auto new_expected = expected_colours;
	auto new_ev = ev;
	/// uno forward (=> qxQ -> qx ... Q g)
	std::swap(new_ev.outgoing[3].type, new_ev.outgoing[4].type);
	// => uno gluon connects to remaining colour
	new_expected[5] = expected_colours[6];
	new_expected[6] = {expected_colours[3].first+2, expected_colours[3].first};
	check_event(new_ev, new_expected);
	}

	/// @TODO add qqx test when implemented (it should work)

	return EXIT_SUCCESS;
	}

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