How can I generate irregular layout consisting of rectangular blocks in R, as opposed to a regular grid?

I am trying to generate something that resembles a city layout, with rectangular blocks representing buildings and spaces representing streets. I have, with the help of a colleague developed a regular grid of buildings and streets. the challenge is to make the arrangement look more random, or having another arrangement e.g. centric or something else. I tried doing this by using if-else constructs to rotate some of the blocks at different angles but all the blocks rotate at the same angle, forming a rotated regular arrangement again. here is the code i have used so far.

``````library(raster)
library(sp)
L=100
W=100
dx=1
x0=0.
y0=0.
z0=0.
LB=14
WB=12
sx=1    #street width in x-direction
sy=1    #street width in y- direction
Y=4
Hb=2   # building height
NB=ceiling(L/(LB+Y+sy))   # number of buildings
Nrow=ceiling(L/dx)
Ncol=ceiling(W/dx)

ymx = y0 + Nrow*dx

M <- matrix(z0, nrow=Nrow, ncol=Ncol, byrow=T)

Nbx= NB    #number of buildings in x-direction
Nby= NB    #number of buildings in y-direction

#rows and cols of buildings
Brow=ceiling(LB/dx)
Bcol=ceiling(WB/dx)

# assign values based on position
#M <- matrix(z0, nrow=Nrow, ncol=Ncol)

#------------TEST------------------------------------------------
# this function returns 1 if the point to be tested is in the polygon and 0 otherwise
# #### if a point is inside a polygon, then the vertices of a ray through the point
# intersects with the vertices of the polygon an even number of times ########
# x, y are the arrays containing cordinates of points to be tested
# polx and poly are arrays containing cordinates of the polygon

PIP = function(x, y, polx, poly, TOL_PIP){
n=0
for(i in 1:length(x)){
p1x = x[i]
p1y = y[i]
if(i < length(x)){
p2x = x[i+1]
p2y = y[i+1]
}else{
p2x = x
p2y = y
}
if((poly > min(p1y,p2y)) &&
(poly <= max(p1y, p2y)) &&
(polx <= max(p1x, p2x))){
if(p1y != p2y){
x_inters = p1x + (poly-p1y)*(p2x-p1x)/(p2y-p1y);
if(p1x==p2x || abs(polx-x_inters) <= TOL_PIP || polx < x_inters){
n=n+1
}
}
}
}
if(n %% 2 == 0){
return(0)
}
return(1)
}

#----------------------Test the function-------------------------------
#reference insertion point

#M <- matrix(z0, nrow=Nrow, ncol=Ncol)

p1x = 0
p1y = 0
p2x = 0
p2y = LB-sy
p3x = WB
p3y = LB-sy
p4x = WB
p4y = 0

# rotate the point
ro = 15
ro = ro*(pi/180)

r1x = p1x*cos(ro) + p1y*sin(ro)
r1y = p1y*cos(ro) - p1x*sin(ro)
r2x = p2x*cos(ro) + p2y*sin(ro)
r2y = p2y*cos(ro) - p2x*sin(ro)
r3x = p3x*cos(ro) + p3y*sin(ro)
r3y = p3y*cos(ro) - p3x*sin(ro)
r4x = p4x*cos(ro) + p4y*sin(ro)
r4y = p4y*cos(ro) - p4x*sin(ro)

x = c(p1x, p2x, p3x, p4x)
y = c(p1y, p2y, p3y, p4y)
#plot(x, y, t='l')

rx = c(r1x, r2x, r3x, r4x)
ry = c(r1y, r2y, r3y, r4y)
#lines(rx, ry, col='blue')

for(nx in 1:Nbx){
for(ny in 1:Nby){

# translation takes place at sx*
bx = x0 + nx*sx + (WB*cos(ro) + LB*sin(ro))*(nx-1)
by = ymx - (sy*(ny-1)  + (LB*cos(ro))*ny) - WB*sin(ro)*(ny-1)

vx = bx-p1x
vy = by-p1y

trx = rx+vx
try = ry+vy

imin = min(trx)/dx
imax = max(trx)/dx
jmin = min(ymx-try)/dx
jmax = max(ymx-try)/dx

for(i in imin:imax){
if(i>=1 && i<=Ncol){
Ax = x0 + dx*(i-0.5)
for(j in jmin:jmax){
if(j>=1 && j<= Nrow){
Ay = ymx-dx*(j-0.5)
M[j, i] = M[j, i] + Hb

}
}
}
}
}
}

R1=raster(M, xmn = x0, xmx=(x0+Ncol)*dx, ymn = y0, ymx = ymx)
plot(R1)
``````