# NOT RUN {
1:10 %>%
map(rnorm, n = 10) %>%
map_dbl(mean)
# Or use an anonymous function
1:10 %>%
map(function(x) rnorm(10, x))
# Or a formula
1:10 %>%
map(~ rnorm(10, .x))
# Extract by name or position
# .default specifies value for elements that are missing or NULL
l1 <- list(list(a = 1L), list(a = NULL, b = 2L), list(b = 3L))
l1 %>% map("a", .default = "???")
l1 %>% map_int("b", .default = NA)
l1 %>% map_int(2, .default = NA)
# Supply multiple values to index deeply into a list
l2 <- list(
list(num = 1:3, letters[1:3]),
list(num = 101:103, letters[4:6]),
list()
)
l2 %>% map(c(2, 2))
# Use a list to build an extractor that mixes numeric indices and names,
# and .default to provide a default value if the element does not exist
l2 %>% map(list("num", 3))
l2 %>% map_int(list("num", 3), .default = NA)
# A more realistic example: split a data frame into pieces, fit a
# model to each piece, summarise and extract R^2
mtcars %>%
split(.$cyl) %>%
map(~ lm(mpg ~ wt, data = .x)) %>%
map(summary) %>%
map_dbl("r.squared")
# Use map_lgl(), map_dbl(), etc to reduce to a vector.
# * list
mtcars %>% map(sum)
# * vector
mtcars %>% map_dbl(sum)
# If each element of the output is a data frame, use
# map_df to row-bind them together:
mtcars %>%
split(.$cyl) %>%
map(~ lm(mpg ~ wt, data = .x)) %>%
map_df(~ as.data.frame(t(as.matrix(coef(.)))))
# (if you also want to preserve the variable names see
# the broom package)
# }
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