fish-shell/src/parser.cpp

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// The fish parser. Contains functions for parsing and evaluating code.
#include <assert.h>
#include <stdbool.h>
#include <stdio.h>
#include <wchar.h>
#include <algorithm>
#include <memory>
#include "common.h"
#include "env.h"
#include "event.h"
#include "expand.h"
#include "fallback.h" // IWYU pragma: keep
#include "function.h"
#include "intern.h"
#include "parse_constants.h"
#include "parse_execution.h"
#include "parse_tree.h"
#include "parse_util.h"
#include "parser.h"
#include "proc.h"
#include "reader.h"
#include "sanity.h"
#include "wutil.h" // IWYU pragma: keep
class io_chain_t;
/// Error for evaluating in illegal scope.
#define INVALID_SCOPE_ERR_MSG _(L"Tried to evaluate commands using invalid block type '%ls'")
/// While block description.
#define WHILE_BLOCK N_(L"'while' block")
/// For block description.
#define FOR_BLOCK N_(L"'for' block")
/// Breakpoint block.
#define BREAKPOINT_BLOCK N_(L"Block created by breakpoint")
/// If block description.
#define IF_BLOCK N_(L"'if' conditional block")
/// Function definition block description.
#define FUNCTION_DEF_BLOCK N_(L"function definition block")
/// Function invocation block description.
#define FUNCTION_CALL_BLOCK N_(L"function invocation block")
/// Function invocation block description.
#define FUNCTION_CALL_NO_SHADOW_BLOCK N_(L"function invocation block with no variable shadowing")
/// Switch block description.
#define SWITCH_BLOCK N_(L"'switch' block")
/// Fake block description.
#define FAKE_BLOCK N_(L"unexecutable block")
/// Top block description.
#define TOP_BLOCK N_(L"global root block")
/// Command substitution block description.
#define SUBST_BLOCK N_(L"command substitution block")
/// Begin block description.
#define BEGIN_BLOCK N_(L"'begin' unconditional block")
/// Source block description.
#define SOURCE_BLOCK N_(L"Block created by the . builtin")
/// Source block description.
#define EVENT_BLOCK N_(L"event handler block")
/// Unknown block description.
#define UNKNOWN_BLOCK N_(L"unknown/invalid block")
/// Datastructure to describe a block type, like while blocks, command substitution blocks, etc.
struct block_lookup_entry {
// The block type id. The legal values are defined in parser.h.
block_type_t type;
// The name of the builtin that creates this type of block, if any.
const wchar_t *name;
// A description of this block type.
const wchar_t *desc;
};
/// List of all legal block types.
static const struct block_lookup_entry block_lookup[] = {
{WHILE, L"while", WHILE_BLOCK},
{FOR, L"for", FOR_BLOCK},
{IF, L"if", IF_BLOCK},
{FUNCTION_DEF, L"function", FUNCTION_DEF_BLOCK},
{FUNCTION_CALL, 0, FUNCTION_CALL_BLOCK},
{FUNCTION_CALL_NO_SHADOW, 0, FUNCTION_CALL_NO_SHADOW_BLOCK},
{SWITCH, L"switch", SWITCH_BLOCK},
{FAKE, 0, FAKE_BLOCK},
{TOP, 0, TOP_BLOCK},
{SUBST, 0, SUBST_BLOCK},
{BEGIN, L"begin", BEGIN_BLOCK},
{SOURCE, L".", SOURCE_BLOCK},
{EVENT, 0, EVENT_BLOCK},
{BREAKPOINT, L"breakpoint", BREAKPOINT_BLOCK},
{(block_type_t)0, 0, 0}};
// Given a file path, return something nicer. Currently we just "unexpand" tildes.
static wcstring user_presentable_path(const wcstring &path) {
return replace_home_directory_with_tilde(path);
}
parser_t::parser_t() : cancellation_requested(false), is_within_fish_initialization(false) {}
/// A pointer to the principal parser (which is a static local).
static parser_t *s_principal_parser = NULL;
parser_t &parser_t::principal_parser(void) {
ASSERT_IS_NOT_FORKED_CHILD();
ASSERT_IS_MAIN_THREAD();
static parser_t parser;
if (!s_principal_parser) {
s_principal_parser = &parser;
}
return parser;
}
void parser_t::set_is_within_fish_initialization(bool flag) {
is_within_fish_initialization = flag;
}
void parser_t::skip_all_blocks(void) {
// Tell all blocks to skip.
if (s_principal_parser) {
s_principal_parser->cancellation_requested = true;
// write(2, "Cancelling blocks\n", strlen("Cancelling blocks\n"));
for (size_t i = 0; i < s_principal_parser->block_count(); i++) {
s_principal_parser->block_at_index(i)->skip = true;
}
}
}
void parser_t::push_block(block_t *new_current) {
const enum block_type_t type = new_current->type();
new_current->src_lineno = parser_t::get_lineno();
const wchar_t *filename = parser_t::current_filename();
if (filename != NULL) {
new_current->src_filename = intern(filename);
}
const block_t *old_current = this->current_block();
if (old_current && old_current->skip) {
new_current->skip = true;
}
// New blocks should be skipped if the outer block is skipped, except TOP ans SUBST block, which
// open up new environments. Fake blocks should always be skipped. Rather complicated... :-(
new_current->skip = old_current ? old_current->skip : 0;
// Type TOP and SUBST are never skipped.
if (type == TOP || type == SUBST) {
new_current->skip = 0;
}
// Fake blocks and function definition blocks are never executed.
if (type == FAKE || type == FUNCTION_DEF) {
new_current->skip = 1;
}
new_current->job = 0;
new_current->loop_status = LOOP_NORMAL;
this->block_stack.push_back(new_current);
// Types TOP and SUBST are not considered blocks for the purposes of `status -b`.
if (type != TOP && type != SUBST) {
is_block = 1;
}
if ((new_current->type() != FUNCTION_DEF) && (new_current->type() != FAKE) &&
(new_current->type() != TOP)) {
env_push(type == FUNCTION_CALL);
new_current->wants_pop_env = true;
}
}
void parser_t::pop_block() {
if (block_stack.empty()) {
debug(1, L"function %s called on empty block stack.", __func__);
bugreport();
return;
}
block_t *old = block_stack.back();
block_stack.pop_back();
if (old->wants_pop_env) env_pop();
delete old;
// Figure out if `status -b` should consider us to be in a block now.
int new_is_block = 0;
for (std::vector<block_t *>::const_iterator it = block_stack.begin(), end = block_stack.end();
it != end; ++it) {
const enum block_type_t type = (*it)->type();
if (type != TOP && type != SUBST) {
new_is_block = 1;
break;
}
}
is_block = new_is_block;
}
void parser_t::pop_block(const block_t *expected) {
assert(expected == this->current_block());
this->pop_block();
}
const wchar_t *parser_t::get_block_desc(int block) const {
for (size_t i = 0; block_lookup[i].desc; i++) {
if (block_lookup[i].type == block) {
return _(block_lookup[i].desc);
}
}
return _(UNKNOWN_BLOCK);
}
wcstring parser_t::block_stack_description() const {
wcstring result;
size_t idx = this->block_count();
size_t spaces = 0;
while (idx--) {
if (spaces > 0) {
result.push_back(L'\n');
}
for (size_t j = 0; j < spaces; j++) {
result.push_back(L' ');
}
result.append(this->block_at_index(idx)->description());
spaces++;
}
return result;
}
const block_t *parser_t::block_at_index(size_t idx) const {
// Zero corresponds to the last element in our vector.
size_t count = block_stack.size();
return idx < count ? block_stack.at(count - idx - 1) : NULL;
}
block_t *parser_t::block_at_index(size_t idx) {
size_t count = block_stack.size();
return idx < count ? block_stack.at(count - idx - 1) : NULL;
}
const block_t *parser_t::current_block() const {
return block_stack.empty() ? NULL : block_stack.back();
}
block_t *parser_t::current_block() { return block_stack.empty() ? NULL : block_stack.back(); }
void parser_t::forbid_function(const wcstring &function) { forbidden_function.push_back(function); }
void parser_t::allow_function() { forbidden_function.pop_back(); }
/// Print profiling information to the specified stream.
static void print_profile(const std::vector<profile_item_t *> &items, FILE *out) {
for (size_t pos = 0; pos < items.size(); pos++) {
const profile_item_t *me, *prev;
size_t i;
int my_time;
me = items.at(pos);
if (!me->skipped) {
my_time = me->parse + me->exec;
for (i = pos + 1; i < items.size(); i++) {
prev = items.at(i);
if (prev->skipped) {
continue;
}
if (prev->level <= me->level) {
break;
}
if (prev->level > me->level + 1) {
continue;
}
my_time -= prev->parse;
my_time -= prev->exec;
}
if (me->cmd.size() > 0) {
if (fwprintf(out, L"%d\t%d\t", my_time, me->parse + me->exec) < 0) {
wperror(L"fwprintf");
return;
}
for (i = 0; i < me->level; i++) {
if (fwprintf(out, L"-") < 0) {
wperror(L"fwprintf");
return;
}
}
if (fwprintf(out, L"> %ls\n", me->cmd.c_str()) < 0) {
wperror(L"fwprintf");
return;
}
}
}
}
}
void parser_t::emit_profiling(const char *path) const {
// Save profiling information. OK to not use CLO_EXEC here because this is called while fish is
// dying (and hence will not fork).
FILE *f = fopen(path, "w");
if (!f) {
debug(1, _(L"Could not write profiling information to file '%s'"), path);
} else {
if (fwprintf(f, _(L"Time\tSum\tCommand\n"), profile_items.size()) < 0) {
wperror(L"fwprintf");
} else {
print_profile(profile_items, f);
}
if (fclose(f)) {
wperror(L"fclose");
}
}
}
void parser_t::expand_argument_list(const wcstring &arg_list_src, expand_flags_t eflags,
std::vector<completion_t> *output_arg_list) {
assert(output_arg_list != NULL);
// Parse the string as an argument list.
parse_node_tree_t tree;
if (!parse_tree_from_string(arg_list_src, parse_flag_none, &tree, NULL /* errors */,
symbol_freestanding_argument_list)) {
// Failed to parse. Here we expect to have reported any errors in test_args.
return;
}
// Get the root argument list.
assert(!tree.empty());
const parse_node_t *arg_list = &tree.at(0);
assert(arg_list->type == symbol_freestanding_argument_list);
// Extract arguments from it.
while (arg_list != NULL) {
const parse_node_t *arg_node =
tree.next_node_in_node_list(*arg_list, symbol_argument, &arg_list);
if (arg_node != NULL) {
const wcstring arg_src = arg_node->get_source(arg_list_src);
if (expand_string(arg_src, output_arg_list, eflags, NULL) == EXPAND_ERROR) {
break; // failed to expand a string
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}
}
}
}
wcstring parser_t::stack_trace() const {
wcstring trace;
this->stack_trace_internal(0, &trace);
return trace;
}
void parser_t::stack_trace_internal(size_t block_idx, wcstring *buff) const {
// Check if we should end the recursion.
if (block_idx >= this->block_count()) return;
const block_t *b = this->block_at_index(block_idx);
if (b->type() == EVENT) {
// This is an event handler.
const event_block_t *eb = static_cast<const event_block_t *>(b);
wcstring description = event_get_desc(eb->event);
append_format(*buff, _(L"in event handler: %ls\n"), description.c_str());
buff->append(L"\n");
// Stop recursing at event handler. No reason to believe that any other code is relevant.
//
// It might make sense in the future to continue printing the stack trace of the code that
// invoked the event, if this is a programmatic event, but we can't currently detect that.
return;
}
if (b->type() == FUNCTION_CALL || b->type() == FUNCTION_CALL_NO_SHADOW || b->type() == SOURCE ||
b->type() == SUBST) {
// These types of blocks should be printed.
int i;
switch (b->type()) {
case SOURCE: {
const source_block_t *sb = static_cast<const source_block_t *>(b);
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const wchar_t *source_dest = sb->source_file;
append_format(*buff, _(L"from sourcing file %ls\n"),
user_presentable_path(source_dest).c_str());
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break;
}
case FUNCTION_CALL:
case FUNCTION_CALL_NO_SHADOW: {
const function_block_t *fb = static_cast<const function_block_t *>(b);
append_format(*buff, _(L"in function '%ls'\n"), fb->name.c_str());
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break;
}
case SUBST: {
append_format(*buff, _(L"in command substitution\n"));
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break;
}
default: {
break; // can't get here
}
}
const wchar_t *file = b->src_filename;
if (file) {
append_format(*buff, _(L"\tcalled on line %d of file %ls\n"), b->src_lineno,
user_presentable_path(file).c_str());
} else if (is_within_fish_initialization) {
append_format(*buff, _(L"\tcalled during startup\n"));
} else {
append_format(*buff, _(L"\tcalled on standard input\n"));
}
if (b->type() == FUNCTION_CALL) {
const function_block_t *fb = static_cast<const function_block_t *>(b);
const process_t *const process = fb->process;
if (process->argv(1)) {
wcstring tmp;
for (i = 1; process->argv(i); i++) {
if (i > 1) tmp.push_back(L' ');
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tmp.append(process->argv(i));
}
append_format(*buff, _(L"\twith parameter list '%ls'\n"), tmp.c_str());
}
}
append_format(*buff, L"\n");
}
// Recursively print the next block.
parser_t::stack_trace_internal(block_idx + 1, buff);
}
/// Returns the name of the currently evaluated function if we are currently evaluating a function,
/// null otherwise. This is tested by moving down the block-scope-stack, checking every block if it
/// is of type FUNCTION_CALL.
const wchar_t *parser_t::is_function() const {
// PCA: Have to make this a string somehow.
ASSERT_IS_MAIN_THREAD();
const wchar_t *result = NULL;
for (size_t block_idx = 0; block_idx < this->block_count(); block_idx++) {
const block_t *b = this->block_at_index(block_idx);
if (b->type() == FUNCTION_CALL || b->type() == FUNCTION_CALL_NO_SHADOW) {
const function_block_t *fb = static_cast<const function_block_t *>(b);
result = fb->name.c_str();
break;
} else if (b->type() == SOURCE) {
// If a function sources a file, obviously that function's offset doesn't contribute.
break;
}
}
return result;
}
int parser_t::get_lineno() const {
int lineno = -1;
if (!execution_contexts.empty()) {
lineno = execution_contexts.back()->get_current_line_number();
// If we are executing a function, we have to add in its offset.
const wchar_t *function_name = is_function();
if (function_name != NULL) {
lineno += function_get_definition_offset(function_name);
}
}
return lineno;
}
const wchar_t *parser_t::current_filename() const {
ASSERT_IS_MAIN_THREAD();
for (size_t i = 0; i < this->block_count(); i++) {
const block_t *b = this->block_at_index(i);
if (b->type() == FUNCTION_CALL || b->type() == FUNCTION_CALL_NO_SHADOW) {
const function_block_t *fb = static_cast<const function_block_t *>(b);
return function_get_definition_file(fb->name);
} else if (b->type() == SOURCE) {
const source_block_t *sb = static_cast<const source_block_t *>(b);
return sb->source_file;
}
}
// We query a global array for the current file name, but only do that if we are the principal
// parser.
if (this == &principal_parser()) {
return reader_current_filename();
}
return NULL;
}
wcstring parser_t::current_line() {
if (execution_contexts.empty()) {
return wcstring();
}
const parse_execution_context_t *context = execution_contexts.back();
assert(context != NULL);
int source_offset = context->get_current_source_offset();
if (source_offset < 0) {
return wcstring();
}
const int lineno = this->get_lineno();
const wchar_t *file = this->current_filename();
wcstring prefix;
// If we are not going to print a stack trace, at least print the line number and filename.
if (!get_is_interactive() || is_function()) {
if (file) {
append_format(prefix, _(L"%ls (line %d): "), user_presentable_path(file).c_str(),
lineno);
} else if (is_within_fish_initialization) {
append_format(prefix, L"%ls: ", _(L"Startup"), lineno);
} else {
append_format(prefix, L"%ls: ", _(L"Standard input"), lineno);
}
}
bool is_interactive = get_is_interactive();
bool skip_caret = is_interactive && !is_function();
// Use an error with empty text.
assert(source_offset >= 0);
parse_error_t empty_error = {};
empty_error.source_start = source_offset;
wcstring line_info =
empty_error.describe_with_prefix(context->get_source(), prefix, is_interactive, skip_caret);
if (!line_info.empty()) {
line_info.push_back(L'\n');
}
line_info.append(this->stack_trace());
return line_info;
}
void parser_t::job_add(job_t *job) {
assert(job != NULL);
assert(job->first_process != NULL);
this->my_job_list.push_front(job);
}
bool parser_t::job_remove(job_t *j) {
job_list_t::iterator iter = std::find(my_job_list.begin(), my_job_list.end(), j);
if (iter != my_job_list.end()) {
my_job_list.erase(iter);
return true;
} else {
debug(1, _(L"Job inconsistency"));
sanity_lose();
return false;
}
}
void parser_t::job_promote(job_t *job) {
job_list_t::iterator loc = std::find(my_job_list.begin(), my_job_list.end(), job);
assert(loc != my_job_list.end());
// Move the job to the beginning.
my_job_list.splice(my_job_list.begin(), my_job_list, loc);
}
job_t *parser_t::job_get(job_id_t id) {
job_iterator_t jobs(my_job_list);
job_t *job;
while ((job = jobs.next())) {
if (id <= 0 || job->job_id == id) return job;
}
return NULL;
}
job_t *parser_t::job_get_from_pid(int pid) {
job_iterator_t jobs;
job_t *job;
while ((job = jobs.next())) {
if (job->pgid == pid) return job;
}
return 0;
}
profile_item_t *parser_t::create_profile_item() {
profile_item_t *result = NULL;
if (g_profiling_active) {
result = new profile_item_t();
profile_items.push_back(result);
}
return result;
}
int parser_t::eval(const wcstring &cmd, const io_chain_t &io, enum block_type_t block_type) {
// Parse the source into a tree, if we can.
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parse_node_tree_t tree;
parse_error_list_t error_list;
if (!parse_tree_from_string(cmd, parse_flag_none, &tree, &error_list)) {
// Get a backtrace. This includes the message.
wcstring backtrace_and_desc;
this->get_backtrace(cmd, error_list, &backtrace_and_desc);
// Print it.
fprintf(stderr, "%ls", backtrace_and_desc.c_str());
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return 1;
}
return this->eval_acquiring_tree(cmd, io, block_type, moved_ref<parse_node_tree_t>(tree));
}
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int parser_t::eval_acquiring_tree(const wcstring &cmd, const io_chain_t &io,
enum block_type_t block_type, moved_ref<parse_node_tree_t> tree) {
CHECK_BLOCK(1);
assert(block_type == TOP || block_type == SUBST);
if (tree.val.empty()) {
return 0;
}
// Determine the initial eval level. If this is the first context, it's -1; otherwise it's the
// eval level of the top context. This is sort of wonky because we're stitching together a
// global notion of eval level from these separate objects. A better approach would be some
// profile object that all contexts share, and that tracks the eval levels on its own.
int exec_eval_level =
(execution_contexts.empty() ? -1 : execution_contexts.back()->current_eval_level());
// Append to the execution context stack.
parse_execution_context_t *ctx =
new parse_execution_context_t(tree, cmd, this, exec_eval_level);
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execution_contexts.push_back(ctx);
// Execute the first node.
this->eval_block_node(0, io, block_type);
// Clean up the execution context stack.
assert(!execution_contexts.empty() && execution_contexts.back() == ctx);
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execution_contexts.pop_back();
delete ctx;
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return 0;
}
int parser_t::eval_block_node(node_offset_t node_idx, const io_chain_t &io,
enum block_type_t block_type) {
// Paranoia. It's a little frightening that we're given only a node_idx and we interpret this in
// the topmost execution context's tree. What happens if two trees were to be interleaved?
// Fortunately that cannot happen (yet); in the future we probably want some sort of reference
// counted trees.
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parse_execution_context_t *ctx = execution_contexts.back();
assert(ctx != NULL);
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CHECK_BLOCK(1);
// Handle cancellation requests. If our block stack is currently empty, then we already did
// successfully cancel (or there was nothing to cancel); clear the flag. If our block stack is
// not empty, we are still in the process of cancelling; refuse to evaluate anything.
if (this->cancellation_requested) {
if (!block_stack.empty()) {
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return 1;
}
this->cancellation_requested = false;
}
// Only certain blocks are allowed.
if ((block_type != TOP) && (block_type != SUBST)) {
debug(1, INVALID_SCOPE_ERR_MSG, parser_t::get_block_desc(block_type));
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bugreport();
return 1;
}
job_reap(0); // not sure why we reap jobs here
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/* Start it up */
const block_t *const start_current_block = current_block();
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block_t *scope_block = new scope_block_t(block_type);
this->push_block(scope_block);
int result = ctx->eval_node_at_offset(node_idx, scope_block, io);
// Clean up the block stack.
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this->pop_block();
while (start_current_block != current_block()) {
if (current_block() == NULL) {
debug(0, _(L"End of block mismatch. Program terminating."));
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bugreport();
FATAL_EXIT();
break;
}
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this->pop_block();
}
job_reap(0); // reap again
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return result;
}
bool parser_t::detect_errors_in_argument_list(const wcstring &arg_list_src, wcstring *out,
const wchar_t *prefix) {
bool errored = false;
parse_error_list_t errors;
// Use empty string for the prefix if it's NULL.
if (prefix == NULL) {
prefix = L"";
}
// Parse the string as an argument list.
parse_node_tree_t tree;
if (!parse_tree_from_string(arg_list_src, parse_flag_none, &tree, &errors,
symbol_freestanding_argument_list)) {
// Failed to parse.
errored = true;
}
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if (!errored) {
// Get the root argument list.
assert(!tree.empty());
const parse_node_t *arg_list = &tree.at(0);
assert(arg_list->type == symbol_freestanding_argument_list);
// Extract arguments from it.
while (arg_list != NULL && !errored) {
const parse_node_t *arg_node =
tree.next_node_in_node_list(*arg_list, symbol_argument, &arg_list);
if (arg_node != NULL) {
const wcstring arg_src = arg_node->get_source(arg_list_src);
if (parse_util_detect_errors_in_argument(*arg_node, arg_src, &errors)) {
errored = true;
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}
}
}
}
if (!errors.empty() && out != NULL) {
out->assign(errors.at(0).describe_with_prefix(
arg_list_src, prefix, false /* not interactive */, false /* don't skip caret */));
}
return errored;
}
void parser_t::get_backtrace(const wcstring &src, const parse_error_list_t &errors,
wcstring *output) const {
assert(output != NULL);
if (!errors.empty()) {
const parse_error_t &err = errors.at(0);
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const bool is_interactive = get_is_interactive();
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// Determine if we want to try to print a caret to point at the source error. The
// err.source_start <= src.size() check is due to the nasty way that slices work, which is
// by rewriting the source.
size_t which_line = 0;
bool skip_caret = true;
if (err.source_start != SOURCE_LOCATION_UNKNOWN && err.source_start <= src.size()) {
// Determine which line we're on.
which_line = 1 + std::count(src.begin(), src.begin() + err.source_start, L'\n');
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// Don't include the caret if we're interactive, this is the first line of text, and our
// source is at its beginning, because then it's obvious.
skip_caret = (is_interactive && which_line == 1 && err.source_start == 0);
}
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wcstring prefix;
const wchar_t *filename = this->current_filename();
if (filename) {
if (which_line > 0) {
prefix = format_string(_(L"%ls (line %lu): "),
user_presentable_path(filename).c_str(), which_line);
} else {
prefix = format_string(_(L"%ls: "), user_presentable_path(filename).c_str());
}
} else {
prefix = L"fish: ";
}
const wcstring description =
err.describe_with_prefix(src, prefix, is_interactive, skip_caret);
if (!description.empty()) {
output->append(description);
output->push_back(L'\n');
}
output->append(this->stack_trace());
}
}
block_t::block_t(block_type_t t)
: block_type(t),
skip(),
tok_pos(),
node_offset(NODE_OFFSET_INVALID),
loop_status(LOOP_NORMAL),
job(),
src_filename(),
src_lineno(),
wants_pop_env(false),
event_blocks() {}
block_t::~block_t() {}
wcstring block_t::description() const {
wcstring result;
switch (this->type()) {
case WHILE: {
result.append(L"while");
break;
}
case FOR: {
result.append(L"for");
break;
}
case IF: {
result.append(L"if");
break;
}
case FUNCTION_DEF: {
result.append(L"function_def");
break;
}
case FUNCTION_CALL: {
result.append(L"function_call");
break;
}
case FUNCTION_CALL_NO_SHADOW: {
result.append(L"function_call_no_shadow");
break;
}
case SWITCH: {
result.append(L"switch");
break;
}
case FAKE: {
result.append(L"fake");
break;
}
case SUBST: {
result.append(L"substitution");
break;
}
case TOP: {
result.append(L"top");
break;
}
case BEGIN: {
result.append(L"begin");
break;
}
case SOURCE: {
result.append(L"source");
break;
}
case EVENT: {
result.append(L"event");
break;
}
case BREAKPOINT: {
result.append(L"breakpoint");
break;
}
default: {
append_format(result, L"unknown type %ld", (long)this->type());
break;
}
}
if (this->src_lineno >= 0) {
append_format(result, L" (line %d)", this->src_lineno);
}
if (this->src_filename != NULL) {
append_format(result, L" (file %ls)", this->src_filename);
}
return result;
}
// Various block constructors.
if_block_t::if_block_t() : block_t(IF) {}
event_block_t::event_block_t(const event_t &evt) : block_t(EVENT), event(evt) {}
function_block_t::function_block_t(const process_t *p, const wcstring &n, bool shadows)
: block_t(shadows ? FUNCTION_CALL : FUNCTION_CALL_NO_SHADOW), process(p), name(n) {}
source_block_t::source_block_t(const wchar_t *src) : block_t(SOURCE), source_file(src) {}
for_block_t::for_block_t() : block_t(FOR) {}
while_block_t::while_block_t() : block_t(WHILE) {}
switch_block_t::switch_block_t() : block_t(SWITCH) {}
fake_block_t::fake_block_t() : block_t(FAKE) {}
scope_block_t::scope_block_t(block_type_t type) : block_t(type) {
assert(type == BEGIN || type == TOP || type == SUBST);
}
breakpoint_block_t::breakpoint_block_t() : block_t(BREAKPOINT) {}