ladybird/Userland/Shell/ImmediateFunctions.cpp
Andreas Kling dc65f54c06 AK: Rename Vector::append(Vector) => Vector::extend(Vector)
Let's make it a bit more clear when we're appending the elements from
one vector to the end of another vector.
2021-06-12 13:24:45 +02:00

411 lines
16 KiB
C++

/*
* Copyright (c) 2021, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "Formatter.h"
#include "Shell.h"
#include <LibRegex/Regex.h>
namespace Shell {
RefPtr<AST::Node> Shell::immediate_length_impl(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments, bool across)
{
auto name = across ? "length_across" : "length";
if (arguments.size() < 1 || arguments.size() > 2) {
raise_error(ShellError::EvaluatedSyntaxError, String::formatted("Expected one or two arguments to `{}'", name), invoking_node.position());
return nullptr;
}
enum {
Infer,
String,
List,
} mode { Infer };
bool is_inferred = false;
const AST::Node* expr_node;
if (arguments.size() == 2) {
// length string <expr>
// length list <expr>
auto& mode_arg = arguments.first();
if (!mode_arg.is_bareword()) {
raise_error(ShellError::EvaluatedSyntaxError, String::formatted("Expected a bareword (either 'string' or 'list') in the two-argument form of the `{}' immediate", name), mode_arg.position());
return nullptr;
}
const auto& mode_name = static_cast<const AST::BarewordLiteral&>(mode_arg).text();
if (mode_name == "list") {
mode = List;
} else if (mode_name == "string") {
mode = String;
} else if (mode_name == "infer") {
mode = Infer;
} else {
raise_error(ShellError::EvaluatedSyntaxError, String::formatted("Expected either 'string' or 'list' (and not {}) in the two-argument form of the `{}' immediate", mode_name, name), mode_arg.position());
return nullptr;
}
expr_node = &arguments[1];
} else {
expr_node = &arguments[0];
}
if (mode == Infer) {
is_inferred = true;
if (expr_node->is_list())
mode = List;
else if (expr_node->is_simple_variable()) // "Look inside" variables
mode = const_cast<AST::Node*>(expr_node)->run(this)->resolve_without_cast(this)->is_list_without_resolution() ? List : String;
else if (is<AST::ImmediateExpression>(expr_node))
mode = List;
else
mode = String;
}
auto value_with_number = [&](auto number) -> NonnullRefPtr<AST::Node> {
return AST::create<AST::BarewordLiteral>(invoking_node.position(), String::number(number));
};
auto do_across = [&](StringView mode_name, auto& values) {
if (is_inferred)
mode_name = "infer";
// Translate to a list of applications of `length <mode_name>`
Vector<NonnullRefPtr<AST::Node>> resulting_nodes;
resulting_nodes.ensure_capacity(values.size());
for (auto& entry : values) {
// ImmediateExpression(length <mode_name> <entry>)
resulting_nodes.unchecked_append(AST::create<AST::ImmediateExpression>(
expr_node->position(),
AST::NameWithPosition { "length", invoking_node.function_position() },
NonnullRefPtrVector<AST::Node> { Vector<NonnullRefPtr<AST::Node>> {
static_cast<NonnullRefPtr<AST::Node>>(AST::create<AST::BarewordLiteral>(expr_node->position(), mode_name)),
AST::create<AST::SyntheticNode>(expr_node->position(), NonnullRefPtr<AST::Value>(entry)),
} },
expr_node->position()));
}
return AST::create<AST::ListConcatenate>(invoking_node.position(), move(resulting_nodes));
};
switch (mode) {
default:
case Infer:
VERIFY_NOT_REACHED();
case List: {
auto value = (const_cast<AST::Node*>(expr_node))->run(this);
if (!value)
return value_with_number(0);
value = value->resolve_without_cast(this);
if (auto list = dynamic_cast<AST::ListValue*>(value.ptr())) {
if (across)
return do_across("list", list->values());
return value_with_number(list->values().size());
}
auto list = value->resolve_as_list(this);
if (!across)
return value_with_number(list.size());
dbgln("List has {} entries", list.size());
auto values = AST::create<AST::ListValue>(move(list));
return do_across("list", values->values());
}
case String: {
// 'across' will only accept lists, and '!across' will only accept non-lists here.
if (expr_node->is_list()) {
if (!across) {
raise_no_list_allowed:;
Formatter formatter { *expr_node };
if (is_inferred) {
raise_error(ShellError::EvaluatedSyntaxError,
String::formatted("Could not infer expression type, please explicitly use `{0} string' or `{0} list'", name),
invoking_node.position());
return nullptr;
}
auto source = formatter.format();
raise_error(ShellError::EvaluatedSyntaxError,
source.is_empty()
? "Invalid application of `length' to a list"
: String::formatted("Invalid application of `length' to a list\nperhaps you meant `{1}length \"{0}\"{2}' or `{1}length_across {0}{2}'?", source, "\x1b[32m", "\x1b[0m"),
expr_node->position());
return nullptr;
}
}
auto value = (const_cast<AST::Node*>(expr_node))->run(this);
if (!value)
return value_with_number(0);
value = value->resolve_without_cast(*this);
if (auto list = dynamic_cast<AST::ListValue*>(value.ptr())) {
if (!across)
goto raise_no_list_allowed;
return do_across("string", list->values());
}
if (across && !value->is_list()) {
Formatter formatter { *expr_node };
auto source = formatter.format();
raise_error(ShellError::EvaluatedSyntaxError,
String::formatted("Invalid application of `length_across' to a non-list\nperhaps you meant `{1}length {0}{2}'?", source, "\x1b[32m", "\x1b[0m"),
expr_node->position());
return nullptr;
}
// Evaluate the nodes and substitute with the lengths.
auto list = value->resolve_as_list(this);
if (!expr_node->is_list()) {
if (list.size() == 1) {
if (across)
goto raise_no_list_allowed;
// This is the normal case, the expression is a normal non-list expression.
return value_with_number(list.first().length());
}
// This can be hit by asking for the length of a command list (e.g. `(>/dev/null)`)
// raise an error about misuse of command lists for now.
// FIXME: What's the length of `(>/dev/null)` supposed to be?
raise_error(ShellError::EvaluatedSyntaxError, "Length of meta value (or command list) requested, this is currently not supported.", expr_node->position());
return nullptr;
}
auto values = AST::create<AST::ListValue>(move(list));
return do_across("string", values->values());
}
}
}
RefPtr<AST::Node> Shell::immediate_length(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
return immediate_length_impl(invoking_node, arguments, false);
}
RefPtr<AST::Node> Shell::immediate_length_across(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
return immediate_length_impl(invoking_node, arguments, true);
}
RefPtr<AST::Node> Shell::immediate_regex_replace(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
if (arguments.size() != 3) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected exactly 3 arguments to regex_replace", invoking_node.position());
return nullptr;
}
auto pattern = const_cast<AST::Node&>(arguments[0]).run(this);
auto replacement = const_cast<AST::Node&>(arguments[1]).run(this);
auto value = const_cast<AST::Node&>(arguments[2]).run(this)->resolve_without_cast(this);
if (!pattern->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the regex_replace pattern to be a string", arguments[0].position());
return nullptr;
}
if (!replacement->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the regex_replace replacement string to be a string", arguments[1].position());
return nullptr;
}
if (!value->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the regex_replace target value to be a string", arguments[2].position());
return nullptr;
}
Regex<PosixExtendedParser> re { pattern->resolve_as_list(this).first() };
auto result = re.replace(value->resolve_as_list(this)[0], replacement->resolve_as_list(this)[0], PosixFlags::Global | PosixFlags::Multiline | PosixFlags::Unicode);
return AST::create<AST::StringLiteral>(invoking_node.position(), move(result));
}
RefPtr<AST::Node> Shell::immediate_remove_suffix(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
if (arguments.size() != 2) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected exactly 2 arguments to remove_suffix", invoking_node.position());
return nullptr;
}
auto suffix = const_cast<AST::Node&>(arguments[0]).run(this);
auto value = const_cast<AST::Node&>(arguments[1]).run(this)->resolve_without_cast(this);
if (!suffix->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the remove_suffix suffix string to be a string", arguments[0].position());
return nullptr;
}
auto suffix_str = suffix->resolve_as_list(this)[0];
auto values = value->resolve_as_list(this);
Vector<NonnullRefPtr<AST::Node>> nodes;
for (auto& value_str : values) {
StringView removed { value_str };
if (value_str.ends_with(suffix_str))
removed = removed.substring_view(0, value_str.length() - suffix_str.length());
nodes.append(AST::create<AST::StringLiteral>(invoking_node.position(), removed));
}
return AST::create<AST::ListConcatenate>(invoking_node.position(), move(nodes));
}
RefPtr<AST::Node> Shell::immediate_remove_prefix(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
if (arguments.size() != 2) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected exactly 2 arguments to remove_prefix", invoking_node.position());
return nullptr;
}
auto prefix = const_cast<AST::Node&>(arguments[0]).run(this);
auto value = const_cast<AST::Node&>(arguments[1]).run(this)->resolve_without_cast(this);
if (!prefix->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the remove_prefix prefix string to be a string", arguments[0].position());
return nullptr;
}
auto prefix_str = prefix->resolve_as_list(this)[0];
auto values = value->resolve_as_list(this);
Vector<NonnullRefPtr<AST::Node>> nodes;
for (auto& value_str : values) {
StringView removed { value_str };
if (value_str.starts_with(prefix_str))
removed = removed.substring_view(prefix_str.length());
nodes.append(AST::create<AST::StringLiteral>(invoking_node.position(), removed));
}
return AST::create<AST::ListConcatenate>(invoking_node.position(), move(nodes));
}
RefPtr<AST::Node> Shell::immediate_split(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
if (arguments.size() != 2) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected exactly 2 arguments to split", invoking_node.position());
return nullptr;
}
auto delimiter = const_cast<AST::Node&>(arguments[0]).run(this);
auto value = const_cast<AST::Node&>(arguments[1]).run(this)->resolve_without_cast(this);
if (!delimiter->is_string()) {
raise_error(ShellError::EvaluatedSyntaxError, "Expected the split delimiter string to be a string", arguments[0].position());
return nullptr;
}
auto delimiter_str = delimiter->resolve_as_list(this)[0];
auto transform = [&](const auto& values) {
// Translate to a list of applications of `split <delimiter>`
Vector<NonnullRefPtr<AST::Node>> resulting_nodes;
resulting_nodes.ensure_capacity(values.size());
for (auto& entry : values) {
// ImmediateExpression(split <delimiter> <entry>)
resulting_nodes.unchecked_append(AST::create<AST::ImmediateExpression>(
arguments[1].position(),
invoking_node.function(),
NonnullRefPtrVector<AST::Node> { Vector<NonnullRefPtr<AST::Node>> {
arguments[0],
AST::create<AST::SyntheticNode>(arguments[1].position(), NonnullRefPtr<AST::Value>(entry)),
} },
arguments[1].position()));
}
return AST::create<AST::ListConcatenate>(invoking_node.position(), move(resulting_nodes));
};
if (auto list = dynamic_cast<AST::ListValue*>(value.ptr())) {
return transform(list->values());
}
// Otherwise, just resolve to a list and transform that.
auto list = value->resolve_as_list(this);
if (!value->is_list()) {
if (list.is_empty())
return AST::create<AST::ListConcatenate>(invoking_node.position(), NonnullRefPtrVector<AST::Node> {});
auto& value = list.first();
Vector<String> split_strings;
if (delimiter_str.is_empty()) {
StringBuilder builder;
for (auto code_point : Utf8View { value }) {
builder.append_code_point(code_point);
split_strings.append(builder.build());
builder.clear();
}
} else {
auto split = StringView { value }.split_view(delimiter_str, options.inline_exec_keep_empty_segments);
split_strings.ensure_capacity(split.size());
for (auto& entry : split)
split_strings.append(entry);
}
return AST::create<AST::SyntheticNode>(invoking_node.position(), AST::create<AST::ListValue>(move(split_strings)));
}
return transform(AST::create<AST::ListValue>(list)->values());
}
RefPtr<AST::Node> Shell::immediate_concat_lists(AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
NonnullRefPtrVector<AST::Node> result;
for (auto& argument : arguments) {
if (auto* list = dynamic_cast<const AST::ListConcatenate*>(&argument)) {
result.extend(list->list());
} else {
auto list_of_values = const_cast<AST::Node&>(argument).run(this)->resolve_without_cast(this);
if (auto* list = dynamic_cast<AST::ListValue*>(list_of_values.ptr())) {
for (auto& entry : static_cast<Vector<NonnullRefPtr<AST::Value>>&>(list->values()))
result.append(AST::create<AST::SyntheticNode>(argument.position(), entry));
} else {
auto values = list_of_values->resolve_as_list(this);
for (auto& entry : values)
result.append(AST::create<AST::StringLiteral>(argument.position(), entry));
}
}
}
return AST::create<AST::ListConcatenate>(invoking_node.position(), move(result));
}
RefPtr<AST::Node> Shell::run_immediate_function(StringView str, AST::ImmediateExpression& invoking_node, const NonnullRefPtrVector<AST::Node>& arguments)
{
#define __ENUMERATE_SHELL_IMMEDIATE_FUNCTION(name) \
if (str == #name) \
return immediate_##name(invoking_node, arguments);
ENUMERATE_SHELL_IMMEDIATE_FUNCTIONS()
#undef __ENUMERATE_SHELL_IMMEDIATE_FUNCTION
raise_error(ShellError::EvaluatedSyntaxError, String::formatted("Unknown immediate function {}", str), invoking_node.position());
return nullptr;
}
bool Shell::has_immediate_function(const StringView& str)
{
#define __ENUMERATE_SHELL_IMMEDIATE_FUNCTION(name) \
if (str == #name) \
return true;
ENUMERATE_SHELL_IMMEDIATE_FUNCTIONS()
#undef __ENUMERATE_SHELL_IMMEDIATE_FUNCTION
return false;
}
}