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implement os.path.dirname for windows

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This commit is contained in:
Andrew Kelley 2017-10-06 00:27:15 -04:00
parent 968ff38cad
commit 08ee69dac3
4 changed files with 559 additions and 95 deletions
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5
README.md
View File

@ -43,15 +43,12 @@ clarity.
* Cross-compiling is a primary use case.
* In addition to creating executables, creating a C library is a primary use
case. You can export an auto-generated .h file.
* Standard library supports Operating System abstractions for:
* `x86_64` `linux`
* `x86_64` `macos`
* Support for all popular operating systems and architectures is planned.
* For OS development, Zig supports all architectures that LLVM does. All the
standard library that does not depend on an OS is available to you in
freestanding mode.
### Support Table
Freestanding means that you do not directly interact with the OS
or you are writing your own OS.

55
std/mem.zig
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@ -216,20 +216,28 @@ pub fn dupe(allocator: &Allocator, comptime T: type, m: []const T) -> %[]T {
/// Linear search for the index of a scalar value inside a slice.
pub fn indexOfScalar(comptime T: type, slice: []const T, value: T) -> ?usize {
for (slice) |item, i| {
if (item == value) {
return indexOfScalarPos(T, slice, 0, value);
}
pub fn indexOfScalarPos(comptime T: type, slice: []const T, start_index: usize, value: T) -> ?usize {
var i: usize = start_index;
while (i < slice.len) : (i += 1) {
if (slice[i] == value)
return i;
}
}
return null;
}
// TODO boyer-moore algorithm
pub fn indexOf(comptime T: type, haystack: []const T, needle: []const T) -> ?usize {
return indexOfPos(T, haystack, 0, needle);
}
// TODO boyer-moore algorithm
pub fn indexOfPos(comptime T: type, haystack: []const T, start_index: usize, needle: []const T) -> ?usize {
if (needle.len > haystack.len)
return null;
var i: usize = 0;
var i: usize = start_index;
const end = haystack.len - needle.len;
while (i <= end) : (i += 1) {
if (eql(T, haystack[i .. i + needle.len], needle))
@ -303,15 +311,15 @@ pub fn eql_slice_u8(a: []const u8, b: []const u8) -> bool {
return eql(u8, a, b);
}
/// Returns an iterator that iterates over the slices of ::s that are not
/// the byte ::c.
/// split(" abc def ghi ")
/// Returns an iterator that iterates over the slices of `buffer` that are not
/// any of the bytes in `split_bytes`.
/// split(" abc def ghi ", " ")
/// Will return slices for "abc", "def", "ghi", null, in that order.
pub fn split(s: []const u8, c: u8) -> SplitIterator {
pub fn split(buffer: []const u8, split_bytes: []const u8) -> SplitIterator {
SplitIterator {
.index = 0,
.s = s,
.c = c,
.buffer = buffer,
.split_bytes = split_bytes,
}
}
@ -328,31 +336,32 @@ pub fn startsWith(comptime T: type, haystack: []const T, needle: []const T) -> b
}
const SplitIterator = struct {
s: []const u8,
c: u8,
buffer: []const u8,
split_bytes: []const u8,
index: usize,
pub fn next(self: &SplitIterator) -> ?[]const u8 {
// move to beginning of token
while (self.index < self.s.len and self.s[self.index] == self.c) : (self.index += 1) {}
while (self.index < self.buffer.len and self.isSplitByte(self.buffer[self.index])) : (self.index += 1) {}
const start = self.index;
if (start == self.s.len) {
if (start == self.buffer.len) {
return null;
}
// move to end of token
while (self.index < self.s.len and self.s[self.index] != self.c) : (self.index += 1) {}
while (self.index < self.buffer.len and !self.isSplitByte(self.buffer[self.index])) : (self.index += 1) {}
const end = self.index;
return self.s[start..end];
return self.buffer[start..end];
}
/// Returns a slice of the remaining bytes. Does not affect iterator state.
pub fn rest(self: &const SplitIterator) -> []const u8 {
// move to beginning of token
var index: usize = self.index;
while (index < self.s.len and self.s[index] == self.c) : (index += 1) {}
return self.s[index..];
fn isSplitByte(self: &SplitIterator, byte: u8) -> bool {
for (self.split_bytes) |split_byte| {
if (byte == split_byte) {
return true;
}
}
return false;
}
};

32
std/os/index.zig
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@ -474,18 +474,28 @@ pub const args = struct {
/// Caller must free the returned memory.
pub fn getCwd(allocator: &Allocator) -> %[]u8 {
var buf = %return allocator.alloc(u8, 1024);
%defer allocator.free(buf);
while (true) {
const err = posix.getErrno(posix.getcwd(buf.ptr, buf.len));
if (err == posix.ERANGE) {
buf = %return allocator.realloc(u8, buf, buf.len * 2);
continue;
} else if (err > 0) {
return error.Unexpected;
}
switch (builtin.os) {
Os.windows => {
@panic("implement getCwd for windows");
//if (windows.GetCurrentDirectoryA(buf_len(out_cwd), buf_ptr(out_cwd)) == 0) {
// zig_panic("GetCurrentDirectory failed");
//}
},
else => {
var buf = %return allocator.alloc(u8, 1024);
%defer allocator.free(buf);
while (true) {
const err = posix.getErrno(posix.getcwd(buf.ptr, buf.len));
if (err == posix.ERANGE) {
buf = %return allocator.realloc(u8, buf, buf.len * 2);
continue;
} else if (err > 0) {
return error.Unexpected;
}
return cstr.toSlice(buf.ptr);
return cstr.toSlice(buf.ptr);
}
},
}
}

562
std/os/path.zig
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@ -11,39 +11,223 @@ const posix = os.posix;
const c = @import("../c/index.zig");
const cstr = @import("../cstr.zig");
pub const sep = switch (builtin.os) {
Os.windows => '\\',
else => '/',
};
pub const delimiter = switch (builtin.os) {
Os.windows => ';',
else => ':',
};
pub const sep_windows = '\\';
pub const sep_posix = '/';
pub const sep = if (is_windows) sep_windows else sep_posix;
pub const delimiter_windows = ';';
pub const delimiter_posix = ':';
pub const delimiter = if (is_windows) delimiter_windows else delimiter_posix;
const is_windows = builtin.os == builtin.Os.windows;
/// Naively combines a series of paths with the native path seperator.
/// Allocates memory for the result, which must be freed by the caller.
pub fn join(allocator: &Allocator, paths: ...) -> %[]u8 {
mem.join(allocator, sep, paths)
if (is_windows) {
return joinWindows(allocator, paths);
} else {
return joinPosix(allocator, paths);
}
}
pub fn joinWindows(allocator: &Allocator, paths: ...) -> %[]u8 {
return mem.join(allocator, sep_windows, paths);
}
pub fn joinPosix(allocator: &Allocator, paths: ...) -> %[]u8 {
return mem.join(allocator, sep_posix, paths);
}
test "os.path.join" {
assert(mem.eql(u8, %%join(&debug.global_allocator, "/a/b", "c"), "/a/b/c"));
assert(mem.eql(u8, %%join(&debug.global_allocator, "/a/b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinWindows(&debug.global_allocator, "c:\\a\\b", "c"), "c:\\a\\b\\c"));
assert(mem.eql(u8, %%joinWindows(&debug.global_allocator, "c:\\a\\b\\", "c"), "c:\\a\\b\\c"));
assert(mem.eql(u8, %%join(&debug.global_allocator, "/", "a", "b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%join(&debug.global_allocator, "/a/", "b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinWindows(&debug.global_allocator, "c:\\", "a", "b\\", "c"), "c:\\a\\b\\c"));
assert(mem.eql(u8, %%joinWindows(&debug.global_allocator, "c:\\a\\", "b\\", "c"), "c:\\a\\b\\c"));
assert(mem.eql(u8, %%join(&debug.global_allocator, "/home/andy/dev/zig/build/lib/zig/std", "io.zig"),
assert(mem.eql(u8, %%joinWindows(&debug.global_allocator,
"c:\\home\\andy\\dev\\zig\\build\\lib\\zig\\std", "io.zig"),
"c:\\home\\andy\\dev\\zig\\build\\lib\\zig\\std\\io.zig"));
assert(mem.eql(u8, %%joinPosix(&debug.global_allocator, "/a/b", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinPosix(&debug.global_allocator, "/a/b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinPosix(&debug.global_allocator, "/", "a", "b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinPosix(&debug.global_allocator, "/a/", "b/", "c"), "/a/b/c"));
assert(mem.eql(u8, %%joinPosix(&debug.global_allocator, "/home/andy/dev/zig/build/lib/zig/std", "io.zig"),
"/home/andy/dev/zig/build/lib/zig/std/io.zig"));
}
pub fn isAbsolute(path: []const u8) -> bool {
switch (builtin.os) {
Os.windows => @compileError("Unsupported OS"),
else => return path[0] == sep,
if (is_windows) {
return isAbsoluteWindows(path);
} else {
return isAbsolutePosix(path);
}
}
pub fn isAbsoluteWindows(path: []const u8) -> bool {
if (path[0] == '/')
return true;
if (path[0] == '\\') {
return true;
}
if (path.len < 3) {
return false;
}
if (path[1] == ':') {
if (path[2] == '/')
return true;
if (path[2] == '\\')
return true;
}
return false;
}
pub fn isAbsolutePosix(path: []const u8) -> bool {
return path[0] == sep_posix;
}
test "os.path.isAbsoluteWindows" {
testIsAbsoluteWindows("/", true);
testIsAbsoluteWindows("//", true);
testIsAbsoluteWindows("//server", true);
testIsAbsoluteWindows("//server/file", true);
testIsAbsoluteWindows("\\\\server\\file", true);
testIsAbsoluteWindows("\\\\server", true);
testIsAbsoluteWindows("\\\\", true);
testIsAbsoluteWindows("c", false);
testIsAbsoluteWindows("c:", false);
testIsAbsoluteWindows("c:\\", true);
testIsAbsoluteWindows("c:/", true);
testIsAbsoluteWindows("c://", true);
testIsAbsoluteWindows("C:/Users/", true);
testIsAbsoluteWindows("C:\\Users\\", true);
testIsAbsoluteWindows("C:cwd/another", false);
testIsAbsoluteWindows("C:cwd\\another", false);
testIsAbsoluteWindows("directory/directory", false);
testIsAbsoluteWindows("directory\\directory", false);
}
test "os.path.isAbsolutePosix" {
testIsAbsolutePosix("/home/foo", true);
testIsAbsolutePosix("/home/foo/..", true);
testIsAbsolutePosix("bar/", false);
testIsAbsolutePosix("./baz", false);
}
fn testIsAbsoluteWindows(path: []const u8, expected_result: bool) {
assert(isAbsoluteWindows(path) == expected_result);
}
fn testIsAbsolutePosix(path: []const u8, expected_result: bool) {
assert(isAbsolutePosix(path) == expected_result);
}
pub fn drive(path: []const u8) -> ?[]const u8 {
if (path.len < 2)
return null;
if (path[1] != ':')
return null;
return path[0..2];
}
pub fn networkShare(path: []const u8) -> ?[]const u8 {
if (path.len < "//a/b".len)
return null;
{
const this_sep = '/';
const two_sep = []u8{this_sep, this_sep};
if (mem.startsWith(u8, path, two_sep)) {
if (path[2] == this_sep)
return null;
const index_host = mem.indexOfScalarPos(u8, path, 3, this_sep) ?? return null;
const next_start = index_host + 1;
if (next_start >= path.len)
return null;
const index_root = mem.indexOfScalarPos(u8, path, next_start, this_sep) ?? path.len;
return path[0..index_root];
}
}
{
const this_sep = '\\';
const two_sep = []u8{this_sep, this_sep};
if (mem.startsWith(u8, path, two_sep)) {
if (path[2] == this_sep)
return null;
const index_host = mem.indexOfScalarPos(u8, path, 3, this_sep) ?? return null;
const next_start = index_host + 1;
if (next_start >= path.len)
return null;
const index_root = mem.indexOfScalarPos(u8, path, next_start, this_sep) ?? path.len;
return path[0..index_root];
}
}
return null;
}
test "os.path.networkShare" {
assert(mem.eql(u8, ??networkShare("//a/b"), "//a/b"));
assert(mem.eql(u8, ??networkShare("\\\\a\\b"), "\\\\a\\b"));
assert(networkShare("\\\\a\\") == null);
}
pub fn preferredSepWindows(path: []const u8) -> u8 {
for (path) |byte| {
if (byte == '/' or byte == '\\') {
return byte;
}
}
return sep_windows;
}
pub fn preferredSep(path: []const u8) -> u8 {
if (is_windows) {
return preferredSepWindows(path);
} else {
return sep_posix;
}
}
pub fn root(path: []const u8) -> []const u8 {
if (is_windows) {
return rootWindows(path);
} else {
return rootPosix(path);
}
}
pub fn rootWindows(path: []const u8) -> []const u8 {
return drive(path) ?? (networkShare(path) ?? []u8{});
}
pub fn rootPosix(path: []const u8) -> ?[]const u8 {
if (path.len == 0 or path[0] != '/')
return []u8{};
return path[0..1];
}
pub fn drivesEqual(drive1: []const u8, drive2: []const u8) -> bool {
assert(drive1.len == 2);
assert(drive2.len == 2);
assert(drive1[1] == ':');
assert(drive2[1] == ':');
return asciiLower(drive1[0]) == asciiLower(drive2[0]);
}
fn asciiLower(byte: u8) -> u8 {
return switch (byte) {
'A' ... 'Z' => 'a' + (byte - 'A'),
else => byte,
};
}
/// This function is like a series of `cd` statements executed one after another.
/// The result does not have a trailing path separator.
pub fn resolve(allocator: &Allocator, args: ...) -> %[]u8 {
@ -56,17 +240,130 @@ pub fn resolve(allocator: &Allocator, args: ...) -> %[]u8 {
}
pub fn resolveSlice(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
if (builtin.os == builtin.Os.windows) {
@compileError("TODO implement os.path.resolve for windows");
if (is_windows) {
return resolveWindows(allocator, paths);
} else {
return resolvePosix(allocator, paths);
}
if (paths.len == 0)
}
pub fn resolveWindows(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
if (paths.len == 0) {
assert(is_windows); // resolveWindows called on non windows can't use getCwd
return os.getCwd(allocator);
}
// determine which drive we want to result with
var result_drive: ?[]const u8 = null;
var have_abs = false;
var first_index: usize = 0;
var max_size: usize = 0;
for (paths) |p, i| {
const is_abs = isAbsoluteWindows(p);
if (is_abs) {
have_abs = true;
first_index = i;
max_size = 0;
}
if (drive(p)) |d| {
result_drive = d;
} else if (is_abs) {
result_drive = null;
}
max_size += p.len + 1;
}
// if we will result with a drive, loop again to determine
// which is the first time the drive is absolutely specified, if any
// and count up the max bytes for paths related to this drive
if (result_drive) |res_dr| {
have_abs = false;
first_index = 0;
max_size = 0;
var correct_drive = false;
for (paths) |p, i| {
if (drive(p)) |dr| {
correct_drive = drivesEqual(dr, res_dr);
}
if (!correct_drive) {
continue;
}
const is_abs = isAbsoluteWindows(p);
if (is_abs) {
first_index = i;
max_size = 0;
}
max_size += p.len + 1;
}
}
var result: []u8 = undefined;
var result_index: usize = 0;
if (have_abs) {
result = %return allocator.alloc(u8, max_size);
mem.copy(u8, result, paths[first_index]);
result_index += paths[first_index].len;
first_index += 1;
} else {
assert(is_windows); // resolveWindows called on non windows can't use getCwd
// TODO get cwd for result_drive if applicable
const cwd = %return os.getCwd(allocator);
defer allocator.free(cwd);
result = %return allocator.alloc(u8, max_size + cwd.len + 1);
mem.copy(u8, result, cwd);
result_index += cwd.len;
}
%defer allocator.free(result);
var correct_drive = false;
const rootSlice = rootWindows(result[0..result_index]);
const preferred_path_sep = preferredSepWindows(result[0..result_index]);
for (paths[first_index..]) |p, i| {
if (result_drive) |res_dr| {
if (drive(p)) |dr| {
correct_drive = drivesEqual(dr, res_dr);
}
if (!correct_drive) {
continue;
}
}
var it = mem.split(p, "/\\");
while (it.next()) |component| {
if (mem.eql(u8, component, ".")) {
continue;
} else if (mem.eql(u8, component, "..")) {
while (true) {
if (result_index == 0 or result_index == rootSlice.len)
break;
result_index -= 1;
if (result[result_index] == '\\' or result[result_index] == '/')
break;
}
} else {
result[result_index] = preferred_path_sep;
result_index += 1;
mem.copy(u8, result[result_index..], component);
result_index += component.len;
}
}
}
return result[0..result_index];
}
pub fn resolvePosix(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
if (paths.len == 0) {
assert(!is_windows); // resolvePosix called on windows can't use getCwd
return os.getCwd(allocator);
}
var first_index: usize = 0;
var have_abs = false;
var max_size: usize = 0;
for (paths) |p, i| {
if (isAbsolute(p)) {
if (isAbsolutePosix(p)) {
first_index = i;
have_abs = true;
max_size = 0;
@ -80,6 +377,7 @@ pub fn resolveSlice(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
if (have_abs) {
result = %return allocator.alloc(u8, max_size);
} else {
assert(!is_windows); // resolvePosix called on windows can't use getCwd
const cwd = %return os.getCwd(allocator);
defer allocator.free(cwd);
result = %return allocator.alloc(u8, max_size + cwd.len + 1);
@ -89,7 +387,7 @@ pub fn resolveSlice(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
%defer allocator.free(result);
for (paths[first_index..]) |p, i| {
var it = mem.split(p, '/');
var it = mem.split(p, "/");
while (it.next()) |component| {
if (mem.eql(u8, component, ".")) {
continue;
@ -119,22 +417,95 @@ pub fn resolveSlice(allocator: &Allocator, paths: []const []const u8) -> %[]u8 {
}
test "os.path.resolve" {
assert(mem.eql(u8, testResolve("/a/b", "c"), "/a/b/c"));
assert(mem.eql(u8, testResolve("/a/b", "c", "//d", "e///"), "/d/e"));
assert(mem.eql(u8, testResolve("/a/b/c", "..", "../"), "/a"));
assert(mem.eql(u8, testResolve("/", "..", ".."), "/"));
assert(mem.eql(u8, testResolve("/a/b/c/"), "/a/b/c"));
const cwd = %%os.getCwd(&debug.global_allocator);
if (is_windows) {
assert(mem.eql(u8, testResolveWindows([][]const u8{"."}), cwd));
} else {
assert(mem.eql(u8, testResolvePosix([][]const u8{"a/b/c/", "../../.."}), cwd));
assert(mem.eql(u8, testResolvePosix([][]const u8{"."}), cwd));
}
}
fn testResolve(args: ...) -> []u8 {
return %%resolve(&debug.global_allocator, args);
test "os.path.resolveWindows" {
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/blah\\blah", "d:/games", "c:../a"}), "c:\\blah\\a"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/blah\\blah", "d:/games", "C:../a"}), "c:\\blah\\a"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/ignore", "d:\\a/b\\c/d", "\\e.exe"}), "d:\\e.exe"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/ignore", "c:/some/file"}), "c:\\some\\file"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"d:/ignore", "d:some/dir//"}), "d:\\ignore\\some\\dir"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"//server/share", "..", "relative\\"}), "\\\\server\\share\\relative"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/", "//"}), "c:\\"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/", "//dir"}), "c:\\dir"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/", "//server/share"}), "\\\\server\\share\\"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/", "//server//share"}), "\\\\server\\share\\"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"c:/", "///some//dir"}), "c:\\some\\dir"));
assert(mem.eql(u8, testResolveWindows([][]const u8{"C:\\foo\\tmp.3\\", "..\\tmp.3\\cycles\\root.js"}),
"C:\\foo\\tmp.3\\cycles\\root.js"));
}
test "os.path.resolvePosix" {
assert(mem.eql(u8, testResolvePosix([][]const u8{"/a/b", "c"}), "/a/b/c"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/a/b", "c", "//d", "e///"}), "/d/e"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/a/b/c", "..", "../"}), "/a"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/", "..", ".."}), "/"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/a/b/c/"}), "/a/b/c"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/var/lib", "../", "file/"}), "/var/file"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/var/lib", "/../", "file/"}), "/file"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/some/dir", ".", "/absolute/"}), "/absolute"));
assert(mem.eql(u8, testResolvePosix([][]const u8{"/foo/tmp.3/", "../tmp.3/cycles/root.js"}), "/foo/tmp.3/cycles/root.js"));
}
fn testResolveWindows(paths: []const []const u8) -> []u8 {
return %%resolveWindows(&debug.global_allocator, paths);
}
fn testResolvePosix(paths: []const []const u8) -> []u8 {
return %%resolvePosix(&debug.global_allocator, paths);
}
pub fn dirname(path: []const u8) -> []const u8 {
if (builtin.os == builtin.Os.windows) {
@compileError("TODO implement os.path.dirname for windows");
if (is_windows) {
return dirnameWindows(path);
} else {
return dirnamePosix(path);
}
}
pub fn dirnameWindows(path: []const u8) -> []const u8 {
if (path.len == 0)
return path[0..0];
const rootSlice = rootWindows(path);
if (path.len == rootSlice.len)
return path;
const have_root_slash = path.len > rootSlice.len and (path[rootSlice.len] == '/' or path[rootSlice.len] == '\\');
var end_index: usize = path.len - 1;
while ((path[end_index] == '/' or path[end_index] == '\\') and end_index > rootSlice.len) {
if (end_index == 0)
return path[0..0];
end_index -= 1;
}
while (path[end_index] != '/' and path[end_index] != '\\' and end_index > rootSlice.len) {
if (end_index == 0)
return path[0..0];
end_index -= 1;
}
if (have_root_slash and end_index == rootSlice.len) {
end_index += 1;
}
return path[0..end_index];
}
pub fn dirnamePosix(path: []const u8) -> []const u8 {
if (path.len == 0)
return path[0..0];
var end_index: usize = path.len - 1;
while (path[end_index] == '/') {
if (end_index == 0)
@ -154,19 +525,60 @@ pub fn dirname(path: []const u8) -> []const u8 {
return path[0..end_index];
}
test "os.path.dirname" {
testDirname("/a/b/c", "/a/b");
testDirname("/a/b/c///", "/a/b");
testDirname("/a", "/");
testDirname("/", "/");
testDirname("////", "/");
testDirname("", "");
testDirname("a", "");
testDirname("a/", "");
testDirname("a//", "");
test "os.path.dirnamePosix" {
testDirnamePosix("/a/b/c", "/a/b");
testDirnamePosix("/a/b/c///", "/a/b");
testDirnamePosix("/a", "/");
testDirnamePosix("/", "/");
testDirnamePosix("////", "/");
testDirnamePosix("", "");
testDirnamePosix("a", "");
testDirnamePosix("a/", "");
testDirnamePosix("a//", "");
}
fn testDirname(input: []const u8, expected_output: []const u8) {
assert(mem.eql(u8, dirname(input), expected_output));
test "os.path.dirnameWindows" {
testDirnameWindows("c:\\", "c:\\");
testDirnameWindows("c:\\foo", "c:\\");
testDirnameWindows("c:\\foo\\", "c:\\");
testDirnameWindows("c:\\foo\\bar", "c:\\foo");
testDirnameWindows("c:\\foo\\bar\\", "c:\\foo");
testDirnameWindows("c:\\foo\\bar\\baz", "c:\\foo\\bar");
testDirnameWindows("\\", "\\");
testDirnameWindows("\\foo", "\\");
testDirnameWindows("\\foo\\", "\\");
testDirnameWindows("\\foo\\bar", "\\foo");
testDirnameWindows("\\foo\\bar\\", "\\foo");
testDirnameWindows("\\foo\\bar\\baz", "\\foo\\bar");
testDirnameWindows("c:", "c:");
testDirnameWindows("c:foo", "c:");
testDirnameWindows("c:foo\\", "c:");
testDirnameWindows("c:foo\\bar", "c:foo");
testDirnameWindows("c:foo\\bar\\", "c:foo");
testDirnameWindows("c:foo\\bar\\baz", "c:foo\\bar");
testDirnameWindows("file:stream", "");
testDirnameWindows("dir\\file:stream", "dir");
testDirnameWindows("\\\\unc\\share", "\\\\unc\\share");
testDirnameWindows("\\\\unc\\share\\foo", "\\\\unc\\share\\");
testDirnameWindows("\\\\unc\\share\\foo\\", "\\\\unc\\share\\");
testDirnameWindows("\\\\unc\\share\\foo\\bar", "\\\\unc\\share\\foo");
testDirnameWindows("\\\\unc\\share\\foo\\bar\\", "\\\\unc\\share\\foo");
testDirnameWindows("\\\\unc\\share\\foo\\bar\\baz", "\\\\unc\\share\\foo\\bar");
testDirnameWindows("/a/b/", "/a");
testDirnameWindows("/a/b", "/a");
testDirnameWindows("/a", "/");
testDirnameWindows("", "");
testDirnameWindows("/", "/");
testDirnameWindows("////", "/");
testDirnameWindows("foo", "");
}
fn testDirnamePosix(input: []const u8, expected_output: []const u8) {
assert(mem.eql(u8, dirnamePosix(input), expected_output));
}
fn testDirnameWindows(input: []const u8, expected_output: []const u8) {
assert(mem.eql(u8, dirnameWindows(input), expected_output));
}
pub fn basename(path: []const u8) -> []const u8 {
@ -215,9 +627,18 @@ fn testBasename(input: []const u8, expected_output: []const u8) {
/// resolve to the same path (after calling ::resolve on each), a zero-length
/// string is returned.
pub fn relative(allocator: &Allocator, from: []const u8, to: []const u8) -> %[]u8 {
if (builtin.os == builtin.Os.windows) {
@compileError("TODO implement os.path.relative for windows");
if (is_windows) {
return windowsRelative(allocator, from, to);
} else {
return posixRelative(allocator, from, to);
}
}
fn windowsRelative(allocator: &Allocator, from: []const u8, to: []const u8) -> %[]u8 {
@compileError("TODO implement this");
}
fn posixRelative(allocator: &Allocator, from: []const u8, to: []const u8) -> %[]u8 {
const resolved_from = %return resolve(allocator, from);
defer allocator.free(resolved_from);
@ -263,18 +684,45 @@ pub fn relative(allocator: &Allocator, from: []const u8, to: []const u8) -> %[]u
}
test "os.path.relative" {
testRelative("/var/lib", "/var", "..");
testRelative("/var/lib", "/bin", "../../bin");
testRelative("/var/lib", "/var/lib", "");
testRelative("/var/lib", "/var/apache", "../apache");
testRelative("/var/", "/var/lib", "lib");
testRelative("/", "/var/lib", "var/lib");
testRelative("/foo/test", "/foo/test/bar/package.json", "bar/package.json");
testRelative("/Users/a/web/b/test/mails", "/Users/a/web/b", "../..");
testRelative("/foo/bar/baz-quux", "/foo/bar/baz", "../baz");
testRelative("/foo/bar/baz", "/foo/bar/baz-quux", "../baz-quux");
testRelative("/baz-quux", "/baz", "../baz");
testRelative("/baz", "/baz-quux", "../baz-quux");
if (is_windows) {
testRelative("c:/blah\\blah", "d:/games", "d:\\games");
testRelative("c:/aaaa/bbbb", "c:/aaaa", "..");
testRelative("c:/aaaa/bbbb", "c:/cccc", "..\\..\\cccc");
testRelative("c:/aaaa/bbbb", "c:/aaaa/bbbb", "");
testRelative("c:/aaaa/bbbb", "c:/aaaa/cccc", "..\\cccc");
testRelative("c:/aaaa/", "c:/aaaa/cccc", "cccc");
testRelative("c:/", "c:\\aaaa\\bbbb", "aaaa\\bbbb");
testRelative("c:/aaaa/bbbb", "d:\\", "d:\\");
testRelative("c:/AaAa/bbbb", "c:/aaaa/bbbb", "");
testRelative("c:/aaaaa/", "c:/aaaa/cccc", "..\\aaaa\\cccc");
testRelative("C:\\foo\\bar\\baz\\quux", "C:\\", "..\\..\\..\\..");
testRelative("C:\\foo\\test", "C:\\foo\\test\\bar\\package.json", "bar\\package.json");
testRelative("C:\\foo\\bar\\baz-quux", "C:\\foo\\bar\\baz", "..\\baz");
testRelative("C:\\foo\\bar\\baz", "C:\\foo\\bar\\baz-quux", "..\\baz-quux");
testRelative("\\\\foo\\bar", "\\\\foo\\bar\\baz", "baz");
testRelative("\\\\foo\\bar\\baz", "\\\\foo\\bar", "..");
testRelative("\\\\foo\\bar\\baz-quux", "\\\\foo\\bar\\baz", "..\\baz");
testRelative("\\\\foo\\bar\\baz", "\\\\foo\\bar\\baz-quux", "..\\baz-quux");
testRelative("C:\\baz-quux", "C:\\baz", "..\\baz");
testRelative("C:\\baz", "C:\\baz-quux", "..\\baz-quux");
testRelative("\\\\foo\\baz-quux", "\\\\foo\\baz", "..\\baz");
testRelative("\\\\foo\\baz", "\\\\foo\\baz-quux", "..\\baz-quux");
testRelative("C:\\baz", "\\\\foo\\bar\\baz", "\\\\foo\\bar\\baz");
testRelative("\\\\foo\\bar\\baz", "C:\\baz", "C:\\baz")
} else {
testRelative("/var/lib", "/var", "..");
testRelative("/var/lib", "/bin", "../../bin");
testRelative("/var/lib", "/var/lib", "");
testRelative("/var/lib", "/var/apache", "../apache");
testRelative("/var/", "/var/lib", "lib");
testRelative("/", "/var/lib", "var/lib");
testRelative("/foo/test", "/foo/test/bar/package.json", "bar/package.json");
testRelative("/Users/a/web/b/test/mails", "/Users/a/web/b", "../..");
testRelative("/foo/bar/baz-quux", "/foo/bar/baz", "../baz");
testRelative("/foo/bar/baz", "/foo/bar/baz-quux", "../baz-quux");
testRelative("/baz-quux", "/baz", "../baz");
testRelative("/baz", "/baz-quux", "../baz-quux");
}
}
fn testRelative(from: []const u8, to: []const u8, expected_output: []const u8) {
const result = %%relative(&debug.global_allocator, from, to);