https://github.com/JuliaLang/julia
Tip revision: 6763ed8c45d1184a210943f03cc88c706ecd9f2b authored by Chris Foster on 10 May 2019, 08:36:29 UTC
WIP: Add macro expansion to backtraces
WIP: Add macro expansion to backtraces
Tip revision: 6763ed8
util.jl
# This file is a part of Julia. License is MIT: https://julialang.org/license
# This type must be kept in sync with the C struct in src/gc.h
struct GC_Num
allocd ::Int64 # GC internal
deferred_alloc::Int64 # GC internal
freed ::Int64 # GC internal
malloc ::UInt64
realloc ::UInt64
poolalloc ::UInt64
bigalloc ::UInt64
freecall ::UInt64
total_time ::UInt64
total_allocd::UInt64 # GC internal
since_sweep ::UInt64 # GC internal
collect ::Csize_t # GC internal
pause ::Cint
full_sweep ::Cint
end
gc_num() = ccall(:jl_gc_num, GC_Num, ())
# This type is to represent differences in the counters, so fields may be negative
struct GC_Diff
allocd ::Int64 # Bytes allocated
malloc ::Int64 # Number of GC aware malloc()
realloc ::Int64 # Number of GC aware realloc()
poolalloc ::Int64 # Number of pool allocation
bigalloc ::Int64 # Number of big (non-pool) allocation
freecall ::Int64 # Number of GC aware free()
total_time ::Int64 # Time spent in garbage collection
pause ::Int64 # Number of GC pauses
full_sweep ::Int64 # Number of GC full collection
end
gc_total_bytes(gc_num::GC_Num) =
(gc_num.allocd + gc_num.deferred_alloc +
Int64(gc_num.collect) + Int64(gc_num.total_allocd))
function GC_Diff(new::GC_Num, old::GC_Num)
# logic from `src/gc.c:jl_gc_total_bytes`
old_allocd = gc_total_bytes(old)
new_allocd = gc_total_bytes(new)
return GC_Diff(new_allocd - old_allocd,
Int64(new.malloc - old.malloc),
Int64(new.realloc - old.realloc),
Int64(new.poolalloc - old.poolalloc),
Int64(new.bigalloc - old.bigalloc),
Int64(new.freecall - old.freecall),
Int64(new.total_time - old.total_time),
new.pause - old.pause,
new.full_sweep - old.full_sweep)
end
function gc_alloc_count(diff::GC_Diff)
diff.malloc + diff.realloc + diff.poolalloc + diff.bigalloc
end
# total time spend in garbage collection, in nanoseconds
gc_time_ns() = ccall(:jl_gc_total_hrtime, UInt64, ())
# total number of bytes allocated so far
gc_bytes() = ccall(:jl_gc_total_bytes, Int64, ())
# print elapsed time, return expression value
const _mem_units = ["byte", "KiB", "MiB", "GiB", "TiB", "PiB"]
const _cnt_units = ["", " k", " M", " G", " T", " P"]
function prettyprint_getunits(value, numunits, factor)
if value == 0 || value == 1
return (value, 1)
end
unit = ceil(Int, log(value) / log(factor))
unit = min(numunits, unit)
number = value/factor^(unit-1)
return number, unit
end
function padded_nonzero_print(value,str)
if value != 0
blanks = " "[1:18-length(str)]
println("$str:$blanks$value")
end
end
function format_bytes(bytes)
bytes, mb = prettyprint_getunits(bytes, length(_mem_units), Int64(1024))
if mb == 1
Printf.@sprintf("%d %s%s", bytes, _mem_units[mb], bytes==1 ? "" : "s")
else
Printf.@sprintf("%.3f %s", bytes, _mem_units[mb])
end
end
function time_print(elapsedtime, bytes=0, gctime=0, allocs=0)
Printf.@printf("%10.6f seconds", elapsedtime/1e9)
if bytes != 0 || allocs != 0
allocs, ma = prettyprint_getunits(allocs, length(_cnt_units), Int64(1000))
if ma == 1
Printf.@printf(" (%d%s allocation%s: ", allocs, _cnt_units[ma], allocs==1 ? "" : "s")
else
Printf.@printf(" (%.2f%s allocations: ", allocs, _cnt_units[ma])
end
print(format_bytes(bytes))
if gctime > 0
Printf.@printf(", %.2f%% gc time", 100*gctime/elapsedtime)
end
print(")")
elseif gctime > 0
Printf.@printf(", %.2f%% gc time", 100*gctime/elapsedtime)
end
end
function timev_print(elapsedtime, diff::GC_Diff)
allocs = gc_alloc_count(diff)
time_print(elapsedtime, diff.allocd, diff.total_time, allocs)
print("\nelapsed time (ns): $elapsedtime\n")
padded_nonzero_print(diff.total_time, "gc time (ns)")
padded_nonzero_print(diff.allocd, "bytes allocated")
padded_nonzero_print(diff.poolalloc, "pool allocs")
padded_nonzero_print(diff.bigalloc, "non-pool GC allocs")
padded_nonzero_print(diff.malloc, "malloc() calls")
padded_nonzero_print(diff.realloc, "realloc() calls")
padded_nonzero_print(diff.freecall, "free() calls")
padded_nonzero_print(diff.pause, "GC pauses")
padded_nonzero_print(diff.full_sweep, "full collections")
end
"""
@time
A macro to execute an expression, printing the time it took to execute, the number of
allocations, and the total number of bytes its execution caused to be allocated, before
returning the value of the expression.
See also [`@timev`](@ref), [`@timed`](@ref), [`@elapsed`](@ref), and
[`@allocated`](@ref).
```julia-repl
julia> @time rand(10^6);
0.001525 seconds (7 allocations: 7.630 MiB)
julia> @time begin
sleep(0.3)
1+1
end
0.301395 seconds (8 allocations: 336 bytes)
2
```
"""
macro time(ex)
quote
local stats = gc_num()
local elapsedtime = time_ns()
local val = $(esc(ex))
elapsedtime = time_ns() - elapsedtime
local diff = GC_Diff(gc_num(), stats)
time_print(elapsedtime, diff.allocd, diff.total_time,
gc_alloc_count(diff))
println()
val
end
end
"""
@timev
This is a verbose version of the `@time` macro. It first prints the same information as
`@time`, then any non-zero memory allocation counters, and then returns the value of the
expression.
See also [`@time`](@ref), [`@timed`](@ref), [`@elapsed`](@ref), and
[`@allocated`](@ref).
```julia-repl
julia> @timev rand(10^6);
0.001006 seconds (7 allocations: 7.630 MiB)
elapsed time (ns): 1005567
bytes allocated: 8000256
pool allocs: 6
malloc() calls: 1
```
"""
macro timev(ex)
quote
local stats = gc_num()
local elapsedtime = time_ns()
local val = $(esc(ex))
elapsedtime = time_ns() - elapsedtime
timev_print(elapsedtime, GC_Diff(gc_num(), stats))
val
end
end
"""
@elapsed
A macro to evaluate an expression, discarding the resulting value, instead returning the
number of seconds it took to execute as a floating-point number.
See also [`@time`](@ref), [`@timev`](@ref), [`@timed`](@ref),
and [`@allocated`](@ref).
```julia-repl
julia> @elapsed sleep(0.3)
0.301391426
```
"""
macro elapsed(ex)
quote
local t0 = time_ns()
local val = $(esc(ex))
(time_ns()-t0)/1e9
end
end
# measure bytes allocated without *most* contamination from compilation
# Note: This reports a different value from the @time macros, because
# it wraps the call in a function, however, this means that things
# like: @allocated y = foo()
# will not work correctly, because it will set y in the context of
# the local function made by the macro, not the current function
"""
@allocated
A macro to evaluate an expression, discarding the resulting value, instead returning the
total number of bytes allocated during evaluation of the expression. Note: the expression is
evaluated inside a local function, instead of the current context, in order to eliminate the
effects of compilation, however, there still may be some allocations due to JIT compilation.
This also makes the results inconsistent with the `@time` macros, which do not try to adjust
for the effects of compilation.
See also [`@time`](@ref), [`@timev`](@ref), [`@timed`](@ref),
and [`@elapsed`](@ref).
```julia-repl
julia> @allocated rand(10^6)
8000080
```
"""
macro allocated(ex)
quote
let
local f
function f()
b0 = gc_bytes()
$(esc(ex))
gc_bytes() - b0
end
f()
end
end
end
"""
@timed
A macro to execute an expression, and return the value of the expression, elapsed time,
total bytes allocated, garbage collection time, and an object with various memory allocation
counters.
See also [`@time`](@ref), [`@timev`](@ref), [`@elapsed`](@ref), and
[`@allocated`](@ref).
```julia-repl
julia> val, t, bytes, gctime, memallocs = @timed rand(10^6);
julia> t
0.006634834
julia> bytes
8000256
julia> gctime
0.0055765
julia> fieldnames(typeof(memallocs))
(:allocd, :malloc, :realloc, :poolalloc, :bigalloc, :freecall, :total_time, :pause, :full_sweep)
julia> memallocs.total_time
5576500
```
"""
macro timed(ex)
quote
local stats = gc_num()
local elapsedtime = time_ns()
local val = $(esc(ex))
elapsedtime = time_ns() - elapsedtime
local diff = GC_Diff(gc_num(), stats)
val, elapsedtime/1e9, diff.allocd, diff.total_time/1e9, diff
end
end
## printing with color ##
const text_colors = AnyDict(
:black => "\033[30m",
:red => "\033[31m",
:green => "\033[32m",
:yellow => "\033[33m",
:blue => "\033[34m",
:magenta => "\033[35m",
:cyan => "\033[36m",
:white => "\033[37m",
:light_black => "\033[90m", # gray
:light_red => "\033[91m",
:light_green => "\033[92m",
:light_yellow => "\033[93m",
:light_blue => "\033[94m",
:light_magenta => "\033[95m",
:light_cyan => "\033[96m",
:normal => "\033[0m",
:default => "\033[39m",
:bold => "\033[1m",
:underline => "\033[4m",
:blink => "\033[5m",
:reverse => "\033[7m",
:hidden => "\033[8m",
:nothing => "",
)
for i in 0:255
text_colors[i] = "\033[38;5;$(i)m"
end
const disable_text_style = AnyDict(
:bold => "\033[22m",
:underline => "\033[24m",
:blink => "\033[25m",
:reverse => "\033[27m",
:hidden => "\033[28m",
:normal => "",
:default => "",
:nothing => "",
)
# Create a docstring with an automatically generated list
# of colors.
available_text_colors = collect(Iterators.filter(x -> !isa(x, Integer), keys(text_colors)))
const possible_formatting_symbols = [:normal, :bold, :default]
available_text_colors = cat(
sort!(intersect(available_text_colors, possible_formatting_symbols), rev=true),
sort!(setdiff( available_text_colors, possible_formatting_symbols));
dims=1)
const available_text_colors_docstring =
string(join([string("`:", key,"`")
for key in available_text_colors], ",\n", ", or \n"))
"""Dictionary of color codes for the terminal.
Available colors are: $available_text_colors_docstring as well as the integers 0 to 255 inclusive.
The color `:default` will print text in the default color while the color `:normal`
will print text with all text properties (like boldness) reset.
Printing with the color `:nothing` will print the string without modifications.
"""
text_colors
function with_output_color(f::Function, color::Union{Int, Symbol}, io::IO, args...; bold::Bool = false)
buf = IOBuffer()
iscolor = get(io, :color, false)
try f(IOContext(buf, io), args...)
finally
str = String(take!(buf))
if !iscolor
print(io, str)
else
bold && color == :bold && (color = :nothing)
enable_ansi = get(text_colors, color, text_colors[:default]) *
(bold ? text_colors[:bold] : "")
disable_ansi = (bold ? disable_text_style[:bold] : "") *
get(disable_text_style, color, text_colors[:default])
first = true
for line in split(str, '\n')
first || print(buf, '\n')
first = false
isempty(line) && continue
print(buf, enable_ansi, line, disable_ansi)
end
print(io, String(take!(buf)))
end
end
end
"""
printstyled([io], xs...; bold::Bool=false, color::Union{Symbol,Int}=:normal)
Print `xs` in a color specified as a symbol or integer, optionally in bold.
`color` may take any of the values $(Base.available_text_colors_docstring)
or an integer between 0 and 255 inclusive. Note that not all terminals support 256 colors.
If the keyword `bold` is given as `true`, the result will be printed in bold.
"""
printstyled(io::IO, msg...; bold::Bool=false, color::Union{Int,Symbol}=:normal) =
with_output_color(print, color, io, msg...; bold=bold)
printstyled(msg...; bold::Bool=false, color::Union{Int,Symbol}=:normal) =
printstyled(stdout, msg...; bold=bold, color=color)
"""
Base.julia_cmd(juliapath=joinpath(Sys.BINDIR::String, julia_exename()))
Return a julia command similar to the one of the running process.
Propagates any of the `--cpu-target`, `--sysimage`, `--compile`, `--sysimage-native-code`,
`--compiled-modules`, `--inline`, `--check-bounds`, `--optimize`, `-g`,
`--code-coverage`, and `--depwarn`
command line arguments that are not at their default values.
Among others, `--math-mode`, `--warn-overwrite`, and `--trace-compile` are notably not propagated currently.
!!! compat "Julia 1.1"
Only the `--cpu-target`, `--sysimage`, `--depwarn`, `--compile` and `--check-bounds` flags were propagated before Julia 1.1.
"""
function julia_cmd(julia=joinpath(Sys.BINDIR::String, julia_exename()))
opts = JLOptions()
cpu_target = unsafe_string(opts.cpu_target)
image_file = unsafe_string(opts.image_file)
addflags = String[]
let compile = if opts.compile_enabled == 0
"no"
elseif opts.compile_enabled == 2
"all"
elseif opts.compile_enabled == 3
"min"
else
"" # default = "yes"
end
isempty(compile) || push!(addflags, "--compile=$compile")
end
let depwarn = if opts.depwarn == 0
"no"
elseif opts.depwarn == 2
"error"
else
"" # default = "yes"
end
isempty(depwarn) || push!(addflags, "--depwarn=$depwarn")
end
let check_bounds = if opts.check_bounds == 1
"yes" # on
elseif opts.check_bounds == 2
"no" # off
else
"" # "default"
end
isempty(check_bounds) || push!(addflags, "--check-bounds=$check_bounds")
end
opts.can_inline == 0 && push!(addflags, "--inline=no")
opts.use_compiled_modules == 0 && push!(addflags, "--compiled-modules=no")
opts.opt_level == 2 || push!(addflags, "-O$(opts.opt_level)")
push!(addflags, "-g$(opts.debug_level)")
if opts.code_coverage != 0
# Forward the code-coverage flag only if applicable (if the filename is pid-dependent)
coverage_file = (opts.output_code_coverage != C_NULL) ? unsafe_string(opts.output_code_coverage) : ""
if isempty(coverage_file) || occursin("%p", coverage_file)
if opts.code_coverage == 1
push!(addflags, "--code-coverage=user")
elseif opts.code_coverage == 2
push!(addflags, "--code-coverage=all")
end
isempty(coverage_file) || push!(addflags, "--code-coverage=$coverage_file")
end
end
if opts.malloc_log != 0
if opts.malloc_log == 1
push!(addflags, "--track-allocation=user")
elseif opts.malloc_log == 2
push!(addflags, "--track-allocation=all")
end
end
return `$julia -C$cpu_target -J$image_file $addflags`
end
function julia_exename()
if ccall(:jl_is_debugbuild, Cint, ()) == 0
return @static Sys.iswindows() ? "julia.exe" : "julia"
else
return @static Sys.iswindows() ? "julia-debug.exe" : "julia-debug"
end
end
"""
securezero!(o)
`securezero!` fills the memory associated with an object `o` with zeros.
Unlike `fill!(o,0)` and similar code, which might be optimized away by
the compiler for objects about to be discarded, the `securezero!` function
will always be called.
"""
function securezero! end
@noinline securezero!(a::AbstractArray{<:Number}) = fill!(a, 0)
@noinline unsafe_securezero!(p::Ptr{T}, len::Integer=1) where {T} =
ccall(:memset, Ptr{T}, (Ptr{T}, Cint, Csize_t), p, 0, len*sizeof(T))
unsafe_securezero!(p::Ptr{Cvoid}, len::Integer=1) = Ptr{Cvoid}(unsafe_securezero!(Ptr{UInt8}(p), len))
"""
Base.getpass(message::AbstractString) -> Base.SecretBuffer
Display a message and wait for the user to input a secret, returning an `IO`
object containing the secret.
Note that on Windows, the secret might be displayed as it is typed; see
`Base.winprompt` for securely retrieving username/password pairs from a
graphical interface.
"""
function getpass end
if Sys.iswindows()
function getpass(input::TTY, output::IO, prompt::AbstractString)
input === stdin || throw(ArgumentError("getpass only works for stdin"))
print(output, prompt, ": ")
flush(output)
s = SecretBuffer()
plen = 0
while true
c = UInt8(ccall(:_getch, Cint, ()))
if c == 0xff || c == UInt8('\n') || c == UInt8('\r')
break # EOF or return
elseif c == 0x00 || c == 0xe0
ccall(:_getch, Cint, ()) # ignore function/arrow keys
elseif c == UInt8('\b') && plen > 0
plen -= 1 # delete last character on backspace
elseif !iscntrl(Char(c)) && plen < 128
write(s, c)
end
end
return seekstart(s)
end
else
function getpass(input::TTY, output::IO, prompt::AbstractString)
(input === stdin && output === stdout) || throw(ArgumentError("getpass only works for stdin"))
msg = string(prompt, ": ")
unsafe_SecretBuffer!(ccall(:getpass, Cstring, (Cstring,), msg))
end
end
# allow new getpass methods to be defined if stdin has been
# redirected to some custom stream, e.g. in IJulia.
getpass(prompt::AbstractString) = getpass(stdin, stdout, prompt)
"""
prompt(message; default="") -> Union{String, Nothing}
Displays the `message` then waits for user input. Input is terminated when a newline (\\n)
is encountered or EOF (^D) character is entered on a blank line. If a `default` is provided
then the user can enter just a newline character to select the `default`.
See also `Base.getpass` and `Base.winprompt` for secure entry of passwords.
"""
function prompt(input::IO, output::IO, message::AbstractString; default::AbstractString="")
msg = !isempty(default) ? "$message [$default]: " : "$message: "
print(output, msg)
uinput = readline(input, keep=true)
isempty(uinput) && return nothing # Encountered an EOF
uinput = chomp(uinput)
isempty(uinput) ? default : uinput
end
# allow new prompt methods to be defined if stdin has been
# redirected to some custom stream, e.g. in IJulia.
prompt(message::AbstractString; default::AbstractString="") = prompt(stdin, stdout, message, default=default)
# Windows authentication prompt
if Sys.iswindows()
struct CREDUI_INFO
cbSize::UInt32
parent::Ptr{Cvoid}
pszMessageText::Ptr{UInt16}
pszCaptionText::Ptr{UInt16}
banner::Ptr{Cvoid}
end
const CREDUIWIN_GENERIC = 0x0001
const CREDUIWIN_IN_CRED_ONLY = 0x0020
const CREDUIWIN_ENUMERATE_CURRENT_USER = 0x0200
const CRED_PACK_GENERIC_CREDENTIALS = 0x0004
const ERROR_SUCCESS = 0x0000
const ERROR_CANCELLED = 0x04c7
function winprompt(message, caption, default_username; prompt_username = true)
# Step 1: Create an encrypted username/password bundle that will be used to set
# the default username (in theory could also provide a default password)
credbuf = Vector{UInt8}(undef, 1024)
credbufsize = Ref{UInt32}(sizeof(credbuf))
succeeded = ccall((:CredPackAuthenticationBufferW, "credui.dll"), stdcall, Bool,
(UInt32, Cwstring, Cwstring, Ptr{UInt8}, Ptr{UInt32}),
CRED_PACK_GENERIC_CREDENTIALS, default_username, "", credbuf, credbufsize)
@assert succeeded
# Step 2: Create the actual dialog
# 2.1: Set up the window
messageArr = Base.cwstring(message)
captionArr = Base.cwstring(caption)
pfSave = Ref{Bool}(false)
cred = Ref{CREDUI_INFO}(CREDUI_INFO(sizeof(CREDUI_INFO), C_NULL, pointer(messageArr), pointer(captionArr), C_NULL))
dwflags = CREDUIWIN_GENERIC | CREDUIWIN_ENUMERATE_CURRENT_USER
if !prompt_username
# Disable setting anything other than default_username
dwflags |= CREDUIWIN_IN_CRED_ONLY
end
authPackage = Ref{Culong}(0)
outbuf_data = Ref{Ptr{Cvoid}}(C_NULL)
outbuf_size = Ref{Culong}(0)
# 2.2: Do the actual request
code = ccall((:CredUIPromptForWindowsCredentialsW, "credui.dll"), stdcall, UInt32, (Ptr{CREDUI_INFO}, UInt32, Ptr{Culong},
Ptr{Cvoid}, Culong, Ptr{Ptr{Cvoid}}, Ptr{Culong}, Ptr{Bool}, UInt32), cred, 0, authPackage, credbuf, credbufsize[],
outbuf_data, outbuf_size, pfSave, dwflags)
# 2.3: If that failed for any reason other than the user canceling, error out.
# If the user canceled, just return nothing
code == ERROR_CANCELLED && return nothing
windowserror(:winprompt, code != ERROR_SUCCESS)
# Step 3: Convert encrypted credentials back to plain text
passbuf = Vector{UInt16}(undef, 1024)
passlen = Ref{UInt32}(length(passbuf))
usernamebuf = Vector{UInt16}(undef, 1024)
usernamelen = Ref{UInt32}(length(usernamebuf))
# Need valid buffers for domain, even though we don't care
dummybuf = Vector{UInt16}(undef, 1024)
succeeded = ccall((:CredUnPackAuthenticationBufferW, "credui.dll"), Bool,
(UInt32, Ptr{Cvoid}, UInt32, Ptr{UInt16}, Ptr{UInt32}, Ptr{UInt16}, Ptr{UInt32}, Ptr{UInt16}, Ptr{UInt32}),
0, outbuf_data[], outbuf_size[], usernamebuf, usernamelen, dummybuf, Ref{UInt32}(1024), passbuf, passlen)
windowserror(:winprompt, !succeeded)
# Step 4: Free the encrypted buffer
# ccall(:SecureZeroMemory, Ptr{Cvoid}, (Ptr{Cvoid}, Csize_t), outbuf_data[], outbuf_size[]) - not an actual function
unsafe_securezero!(outbuf_data[], outbuf_size[])
ccall((:CoTaskMemFree, "ole32.dll"), Cvoid, (Ptr{Cvoid},), outbuf_data[])
# Done.
passbuf_ = passbuf[1:passlen[]-1]
result = (String(transcode(UInt8, usernamebuf[1:usernamelen[]-1])),
SecretBuffer!(transcode(UInt8, passbuf_)))
securezero!(passbuf_)
securezero!(passbuf)
return result
end
end
unsafe_crc32c(a, n, crc) = ccall(:jl_crc32c, UInt32, (UInt32, Ptr{UInt8}, Csize_t), crc, a, n)
_crc32c(a::Union{Array{UInt8},FastContiguousSubArray{UInt8,N,<:Array{UInt8}} where N}, crc::UInt32=0x00000000) =
unsafe_crc32c(a, length(a) % Csize_t, crc)
_crc32c(s::String, crc::UInt32=0x00000000) = unsafe_crc32c(s, sizeof(s) % Csize_t, crc)
function _crc32c(io::IO, nb::Integer, crc::UInt32=0x00000000)
nb < 0 && throw(ArgumentError("number of bytes to checksum must be ≥ 0, got $nb"))
# use block size 24576=8192*3, since that is the threshold for
# 3-way parallel SIMD code in the underlying jl_crc32c C function.
buf = Vector{UInt8}(undef, min(nb, 24576))
while !eof(io) && nb > 24576
n = readbytes!(io, buf)
crc = unsafe_crc32c(buf, n, crc)
nb -= n
end
return unsafe_crc32c(buf, readbytes!(io, buf, min(nb, length(buf))), crc)
end
_crc32c(io::IO, crc::UInt32=0x00000000) = _crc32c(io, typemax(Int64), crc)
_crc32c(io::IOStream, crc::UInt32=0x00000000) = _crc32c(io, filesize(io)-position(io), crc)
_crc32c(uuid::UUID, crc::UInt32=0x00000000) =
ccall(:jl_crc32c, UInt32, (UInt32, Ref{UInt128}, Csize_t), crc, uuid.value, 16)
"""
@kwdef typedef
This is a helper macro that automatically defines a keyword-based constructor for the type
declared in the expression `typedef`, which must be a `struct` or `mutable struct`
expression. The default argument is supplied by declaring fields of the form `field::T =
default` or `field = default`. If no default is provided then the keyword argument becomes
a required keyword argument in the resulting type constructor.
Inner constructors can still be defined, but at least one should accept arguments in the
same form as the default inner constructor (i.e. one positional argument per field) in
order to function correctly with the keyword outer constructor.
!!! compat "Julia 1.1"
`Base.@kwdef` for parametric structs, and structs with supertypes
requires at least Julia 1.1.
# Examples
```jldoctest
julia> Base.@kwdef struct Foo
a::Int = 1 # specified default
b::String # required keyword
end
Foo
julia> Foo(b="hi")
Foo(1, "hi")
julia> Foo()
ERROR: UndefKeywordError: keyword argument b not assigned
Stacktrace:
[...]
```
"""
macro kwdef(expr)
expr = macroexpand(__module__, expr) # to expand @static
expr isa Expr && expr.head == :struct || error("Invalid usage of @kwdef")
T = expr.args[2]
if T isa Expr && T.head == :<:
T = T.args[1]
end
params_ex = Expr(:parameters)
call_args = Any[]
_kwdef!(expr.args[3], params_ex.args, call_args)
# Only define a constructor if the type has fields, otherwise we'll get a stack
# overflow on construction
if !isempty(params_ex.args)
if T isa Symbol
kwdefs = :(($(esc(T)))($params_ex) = ($(esc(T)))($(call_args...)))
elseif T isa Expr && T.head == :curly
# if T == S{A<:AA,B<:BB}, define two methods
# S(...) = ...
# S{A,B}(...) where {A<:AA,B<:BB} = ...
S = T.args[1]
P = T.args[2:end]
Q = [U isa Expr && U.head == :<: ? U.args[1] : U for U in P]
SQ = :($S{$(Q...)})
kwdefs = quote
($(esc(S)))($params_ex) =($(esc(S)))($(call_args...))
($(esc(SQ)))($params_ex) where {$(esc.(P)...)} =
($(esc(SQ)))($(call_args...))
end
else
error("Invalid usage of @kwdef")
end
else
kwdefs = nothing
end
quote
Base.@__doc__($(esc(expr)))
$kwdefs
end
end
# @kwdef helper function
# mutates arguments inplace
function _kwdef!(blk, params_args, call_args)
for i in eachindex(blk.args)
ei = blk.args[i]
if ei isa Symbol
# var
push!(params_args, ei)
push!(call_args, ei)
elseif ei isa Expr
if ei.head == :(=)
lhs = ei.args[1]
if lhs isa Symbol
# var = defexpr
var = lhs
elseif lhs isa Expr && lhs.head == :(::) && lhs.args[1] isa Symbol
# var::T = defexpr
var = lhs.args[1]
else
# something else, e.g. inline inner constructor
# F(...) = ...
continue
end
defexpr = ei.args[2] # defexpr
push!(params_args, Expr(:kw, var, esc(defexpr)))
push!(call_args, var)
blk.args[i] = lhs
elseif ei.head == :(::) && ei.args[1] isa Symbol
# var::Typ
var = ei.args[1]
push!(params_args, var)
push!(call_args, var)
elseif ei.head == :block
# can arise with use of @static inside type decl
_kwdef!(ei, params_args, call_args)
end
end
end
blk
end
# testing
"""
Base.runtests(tests=["all"]; ncores=ceil(Int, Sys.CPU_THREADS / 2),
exit_on_error=false, [seed])
Run the Julia unit tests listed in `tests`, which can be either a string or an array of
strings, using `ncores` processors. If `exit_on_error` is `false`, when one test
fails, all remaining tests in other files will still be run; they are otherwise discarded,
when `exit_on_error == true`.
If a seed is provided via the keyword argument, it is used to seed the
global RNG in the context where the tests are run; otherwise the seed is chosen randomly.
"""
function runtests(tests = ["all"]; ncores = ceil(Int, Sys.CPU_THREADS / 2),
exit_on_error=false,
seed::Union{BitInteger,Nothing}=nothing)
if isa(tests,AbstractString)
tests = split(tests)
end
exit_on_error && push!(tests, "--exit-on-error")
seed !== nothing && push!(tests, "--seed=0x$(string(seed % UInt128, base=16))") # cast to UInt128 to avoid a minus sign
ENV2 = copy(ENV)
ENV2["JULIA_CPU_THREADS"] = "$ncores"
try
run(setenv(`$(julia_cmd()) $(joinpath(Sys.BINDIR::String,
Base.DATAROOTDIR, "julia", "test", "runtests.jl")) $tests`, ENV2))
catch
buf = PipeBuffer()
Base.require(Base, :InteractiveUtils).versioninfo(buf)
error("A test has failed. Please submit a bug report (https://github.com/JuliaLang/julia/issues)\n" *
"including error messages above and the output of versioninfo():\n$(read(buf, String))")
end
end
