The code in this vignette provides a basic introduction to parallel routing. Routing is something that is highly parallelisable because each route can be calculated independently of the others. The code should be fairly self-explanatory. No results are shown and the code is not run to reduce package build times.
library(stplanr)
library(sf)
library(dplyr)
library(tmap)
library(parallel)
library(cyclestreets)
# ?route
= flowlines_sf %>%
l ::filter()
dplyr= Sys.time()
t1 = line2route(l)
routes_route_cyclestreet Sys.time() - t1
ncol(routes_route_cyclestreet)
nrow(routes_route_cyclestreet)
names(routes_route_cyclestreet)
= dplyr::inner_join(routes_route_cyclestreet, sf::st_drop_geometry(l))
routes_route_cyclestreet_joined Sys.time() - t1
= overline(routes_route_cyclestreet_joined, "All")
rnet_go_dutch Sys.time() - t1
tm_shape(rnet_go_dutch) +
tm_lines(lwd = 5, col = "All", breaks = c(0, 10, 100, 500, 1000), palette = "viridis")
# ?route
= Sys.time()
t1 = route(l = l, route_fun = cyclestreets::journey)
routes_journey ncol(routes_journey)
nrow(routes_journey)
Sys.time() - t1
names(routes_journey)
= overline(routes_journey, "All")
rnet_go_dutch_journey Sys.time() - t1
= overline(routes_journey, "All")
rnet_go_dutch_agg Sys.time() - t1
tm_shape(rnet_go_dutch_agg) +
tm_lines(lwd = 5, col = "All", breaks = c(0, 10, 100, 500, 1000), palette = "viridis")
# ?route
= Sys.time()
t1
# load parallel stuff
<- makeCluster(detectCores())
cl clusterExport(cl, c("journey"))
Sys.time() - t1
= route(l = l, route_fun = cyclestreets::journey, cl = cl) # multi-core
routes_journey_par stopCluster(cl) # kill cluster
Sys.time() - t1
Sys.time() - t1
names(routes_journey_par)
= overline(routes_journey_par, "All")
rnet_go_dutch_journey Sys.time() - t1
= overline(routes_journey_par, "All")
rnet_go_dutch_agg Sys.time() - t1
tm_shape(rnet_go_dutch_agg) +
tm_lines(lwd = 5, col = "All", breaks = c(0, 10, 100, 500, 1000), palette = "viridis")
# ?route
= Sys.time()
t1
# load parallel stuff
library(parallel)
library(cyclestreets)
<- makeCluster(detectCores())
cl clusterExport(cl, c("journey"))
Sys.time() - t1
= route(l = l, route_fun = cyclestreets::journey, cl = cl, plan = "quietest") # multi-core
routes_journey_par stopCluster(cl) # kill cluster
Sys.time() - t1
Sys.time() - t1
names(routes_journey_par)
= overline(routes_journey_par, "All")
rnet_go_dutch_journey Sys.time() - t1
= overline(routes_journey_par, "All")
rnet_go_dutch_agg Sys.time() - t1
tm_shape(rnet_go_dutch_agg) +
tm_lines(lwd = 5, col = "All", breaks = c(0, 10, 100, 500, 1000), palette = "viridis")
= routes_journey %>% # already has data from data frame in there!
routes_journey_aggregated group_by(id) %>%
summarise(All = median(All)) %>%
::st_cast("LINESTRING")
sf
= routes_journey %>% # already has data from data frame in there!
rnet_journey_dplyr group_by(name, distances) %>%
summarise(All = sum(All))
Sys.time() - t1
tm_shape(rnet_journey_dplyr) +
tm_lines(lwd = 5, col = "All", breaks = c(0, 10, 100, 500, 1000), palette = "viridis") # quite different...
= routes_journey %>%
rnet_journey_go_dutch group_by(start_longitude, start_latitude, finish_longitude, finish_latitude) %>%
summarise(All = sum(All))