# Exercise different output data options

variable        len equal 4.0
variable        lenz equal 10.0

dimension       2
units		metal
boundary	f f p

lattice         hex 1.0 origin 0.25 0.25 0.0

atom_style	atomic

region          box block 0 ${len}  0 ${len} 0.0 ${lenz}
region          atoms block 0 ${len}  0 ${len} 0.0 0.0
create_box      1 box
create_atoms    1 region atoms

mass 		1 1.0

pair_style      lj/cut 2.5
pair_coeff      1 1 0.0 1.0 

neighbor	1.0 nsq

#
# TEST 1: 
#

# This compute voronoi generates all three 
# types of quantity: per-atom, local, and global

compute 	v1 all voronoi/atom neighbors yes edge_histo 6

# write voronoi per-atom quantities to a file

dump    	dperatom all custom 1 dump.voro id type x y z c_v1[1] c_v1[2]

# writing voronoi local quantities to a file

dump            dlocal all local  1 dump.neighbors index c_v1[1] c_v1[2] c_v1[3]

# sum up a voronoi per-atom quantity

compute 	volvor all reduce sum c_v1[1]

variable 	volsys equal lz*lx*ly
variable 	err equal c_volvor-v_volsys

# output voronoi global quantities

thermo_style 	custom c_volvor v_volsys vol v_err c_v1[3] c_v1[4] c_v1[5] c_v1[6] c_v1[7]
thermo 		1

run  		0

uncompute       v1
uncompute       volvor
undump          dperatom
undump          dlocal

#
# TEST 2: 
#

# This compute voronoi generates  
# local and global quantities, but
# not per-atom quantities

compute 	v2 all voronoi/atom neighbors yes edge_histo 6 peratom no

# write voronoi local quantities to a file

dump            d2 all local  1 dump.neighbors2 index c_v2[1] c_v2[2] c_v2[3]

# sum up a voronoi local quantity

compute 	sumarea all reduce sum c_v2[3]

# output voronoi global quantities

thermo_style 	custom c_sumarea c_v2[3] c_v2[4] c_v2[5] c_v2[6] c_v2[7]
thermo 		1

run  		0