Revert "Add gdb pretty printers for a wide variety of libc++ data structures."
This reverts commit d8c9f2f572fe06a34ccfc28ee9223b64d7d275d3.
git-svn-id: https://llvm.org/svn/llvm-project/libcxx/trunk@370553 91177308-0d34-0410-b5e6-96231b3b80d8
diff --git a/test/pretty_printers/gdb_pretty_printer_test.py b/test/pretty_printers/gdb_pretty_printer_test.py
deleted file mode 100644
index 5e42568..0000000
--- a/test/pretty_printers/gdb_pretty_printer_test.py
+++ /dev/null
@@ -1,112 +0,0 @@
-#===----------------------------------------------------------------------===##
-#
-# Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
-# See https://llvm.org/LICENSE.txt for license information.
-# SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
-#
-#===----------------------------------------------------------------------===##
-"""Commands used to automate testing gdb pretty printers.
-
-This script is part of a larger framework to test gdb pretty printers. It
-runs the program, detects test cases, checks them, and prints results.
-
-See gdb_pretty_printer_test.sh.cpp on how to write a test case.
-
-"""
-
-from __future__ import print_function
-import re
-import gdb
-
-test_failures = 0
-
-
-class CheckResult(gdb.Command):
-
- def __init__(self):
- super(CheckResult, self).__init__(
- "print_and_compare", gdb.COMMAND_DATA)
-
- def invoke(self, arg, from_tty):
- try:
- # Stack frame is:
- # 0. StopForDebugger
- # 1. ComparePrettyPrintToChars or ComparePrettyPrintToRegex
- # 2. TestCase
- compare_frame = gdb.newest_frame().older()
- testcase_frame = compare_frame.older()
- test_loc = testcase_frame.find_sal()
- # Use interactive commands in the correct context to get the pretty
- # printed version
-
- value_str = self._get_value_string(compare_frame, testcase_frame)
-
- # Ignore the convenience variable name and newline
- value = value_str[value_str.find("= ") + 2:-1]
- gdb.newest_frame().select()
-
- expectation_val = compare_frame.read_var("expectation")
- if "PrettyPrintToRegex" in compare_frame.name():
- check_literal = expectation_val.string()
- test_fails = not re.match(check_literal, value)
- else:
- check_literal_string = expectation_val.string(encoding="utf-8")
- check_literal = check_literal_string.encode("utf-8")
- test_fails = value != check_literal
-
- if test_fails:
- global test_failures
- print("FAIL: " + test_loc.symtab.filename +
- ":" + str(test_loc.line))
- print("GDB printed:")
- print(" " + value)
- print("Value should match:")
- print(" " + check_literal)
- test_failures += 1
- else:
- print("PASS: " + test_loc.symtab.filename +
- ":" + str(test_loc.line))
-
- except RuntimeError as e:
- # At this point, lots of different things could be wrong, so don't try to
- # recover or figure it out. Don't exit either, because then it's
- # impossible debug the framework itself.
- print("FAIL: Something is wrong in the test framework.")
- print(str(e))
- test_failures += 1
-
- def _get_value_string(self, compare_frame, testcase_frame):
- compare_frame.select()
- if "ComparePrettyPrint" in compare_frame.name():
- return gdb.execute("p value", to_string=True)
- value_str = str(compare_frame.read_var("value"))
- clean_expression_str = value_str.strip("'\"")
- testcase_frame.select()
- return gdb.execute("p " + clean_expression_str, to_string=True)
-
-
-def exit_handler(event=None):
- global test_failures
- if test_failures:
- print("FAILED %d cases" % test_failures)
- exit(test_failures)
-
-
-# Start code executed at load time
-
-# Disable terminal paging
-gdb.execute("set height 0")
-gdb.execute("set python print-stack full")
-test_failures = 0
-CheckResult()
-test_bp = gdb.Breakpoint("StopForDebugger")
-test_bp.enabled = True
-test_bp.silent = True
-test_bp.commands = "print_and_compare\ncontinue"
-# "run" won't return if the program exits; ensure the script regains control.
-gdb.events.exited.connect(exit_handler)
-gdb.execute("run")
-# If the program didn't exit, something went wrong, but we don't
-# know what. Fail on exit.
-test_failures += 1
-exit_handler(None)
diff --git a/test/pretty_printers/gdb_pretty_printer_test.sh.cpp b/test/pretty_printers/gdb_pretty_printer_test.sh.cpp
deleted file mode 100644
index 27c747b..0000000
--- a/test/pretty_printers/gdb_pretty_printer_test.sh.cpp
+++ /dev/null
@@ -1,631 +0,0 @@
-// -*- C++ -*-
-//===----------------------------------------------------------------------===//
-//
-// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
-// See https://llvm.org/LICENSE.txt for license information.
-// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
-//
-//===----------------------------------------------------------------------===//
-// UNSUPPORTED: system-windows
-
-// RUN: %cxx %flags %s -o %t.exe %compile_flags -g %link_flags
-// Ensure locale-independence for unicode tests.
-// RUN: LC_CTYPE="en_US.UTF-8" gdb -batch -nx -iex "set autoload off" -ex "source %libcxx_src_root/utils/gdb/libcxx/printers.py" -ex "python register_libcxx_printer_loader()" -ex "source %libcxx_src_root/test/pretty_printers/gdb_pretty_printer_test.py" %t.exe
-
-#include <bitset>
-#include <deque>
-#include <list>
-#include <map>
-#include <memory>
-#include <queue>
-#include <set>
-#include <sstream>
-#include <stack>
-#include <string>
-#include <tuple>
-#include <unordered_map>
-#include <unordered_set>
-
-// To write a pretty-printer test:
-//
-// 1. Declare a variable of the type you want to test
-//
-// 2. Set its value to something which will test the pretty printer in an
-// interesting way.
-//
-// 3. Call ComparePrettyPrintToChars with that variable, and a "const char*"
-// value to compare to the printer's output.
-//
-// Or
-//
-// Call ComparePrettyPrintToChars with that variable, and a "const char*"
-// *python* regular expression to match against the printer's output.
-// The set of special characters in a Python regular expression overlaps
-// with a lot of things the pretty printers print--brackets, for
-// example--so take care to escape appropriately.
-//
-// Alternatively, construct a string that gdb can parse as an expression,
-// so that printing the value of the expression will test the pretty printer
-// in an interesting way. Then, call CompareExpressionPrettyPrintToChars or
-// CompareExpressionPrettyPrintToRegex to compare the printer's output.
-
-// Avoids setting a breakpoint in every-single instantiation of
-// ComparePrettyPrintTo*. Also, make sure neither it, nor the
-// variables we need present in the Compare functions are optimized
-// away.
-void StopForDebugger(void *value, void *check) __attribute__((optnone)) { }
-
-// Prevents the compiler optimizing away the parameter in the caller function.
-template <typename Type>
-void MarkAsLive(Type &&t) __attribute__((optnone)) { }
-
-// In all of the Compare(Expression)PrettyPrintTo(Regex/Chars) functions below,
-// the python script sets a breakpoint just before the call to StopForDebugger,
-// compares the result to the expectation.
-//
-// The expectation is a literal string to be matched exactly in
-// *PrettyPrintToChars functions, and is a python regular expression in
-// *PrettyPrintToRegex functions.
-//
-// In ComparePrettyPrint* functions, the value is a variable of any type. In
-// CompareExpressionPrettyPrint functions, the value is a string expression that
-// gdb will parse and print the result.
-//
-// The python script will print either "PASS", or a detailed failure explanation
-// along with the line that has invoke the function. The testing will continue
-// in either case.
-
-template <typename TypeToPrint> void ComparePrettyPrintToChars(
- TypeToPrint value,
- const char *expectation) {
- StopForDebugger(&value, &expectation);
-}
-
-template <typename TypeToPrint> void ComparePrettyPrintToRegex(
- TypeToPrint value,
- const char *expectation) {
- StopForDebugger(&value, &expectation);
-}
-
-void CompareExpressionPrettyPrintToChars(
- std::string value,
- const char *expectation) {
- StopForDebugger(&value, &expectation);
-}
-
-void CompareExpressionPrettyPrintToRegex(
- std::string value,
- const char *expectation) {
- StopForDebugger(&value, &expectation);
-}
-
-namespace example {
- struct example_struct {
- int a = 0;
- int arr[1000];
- };
-}
-
-// If enabled, the self test will "fail"--because we want to be sure it properly
-// diagnoses tests that *should* fail. Evaluate the output by hand.
-void framework_self_test() {
-#ifdef FRAMEWORK_SELF_TEST
- // Use the most simple data structure we can.
- const char a = 'a';
-
- // Tests that should pass
- ComparePrettyPrintToChars(a, "97 'a'");
- ComparePrettyPrintToRegex(a, ".*");
-
- // Tests that should fail.
- ComparePrettyPrintToChars(a, "b");
- ComparePrettyPrintToRegex(a, "b");
-#endif
-}
-
-// A simple pass-through allocator to check that we handle CompressedPair
-// correctly.
-template <typename T> class UncompressibleAllocator : public std::allocator<T> {
- public:
- char X;
-};
-
-void string_test() {
- std::string short_string("kdjflskdjf");
- // The display_hint "string" adds quotes the printed result.
- ComparePrettyPrintToChars(short_string, "\"kdjflskdjf\"");
-
- std::basic_string<char, std::char_traits<char>, UncompressibleAllocator<char>>
- long_string("mehmet bizim dostumuz agzi kirik testimiz");
- ComparePrettyPrintToChars(long_string,
- "\"mehmet bizim dostumuz agzi kirik testimiz\"");
-}
-
-void u16string_test() {
- std::u16string test0 = u"Hello World";
- ComparePrettyPrintToChars(test0, "u\"Hello World\"");
- std::u16string test1 = u"\U00010196\u20AC\u00A3\u0024";
- ComparePrettyPrintToChars(test1, "u\"\U00010196\u20AC\u00A3\u0024\"");
- std::u16string test2 = u"\u0024\u0025\u0026\u0027";
- ComparePrettyPrintToChars(test2, "u\"\u0024\u0025\u0026\u0027\"");
- std::u16string test3 = u"mehmet bizim dostumuz agzi kirik testimiz";
- ComparePrettyPrintToChars(test3,
- ("u\"mehmet bizim dostumuz agzi kirik testimiz\""));
-}
-
-void u32string_test() {
- std::u32string test0 = U"Hello World";
- ComparePrettyPrintToChars(test0, "U\"Hello World\"");
- std::u32string test1 =
- U"\U0001d552\U0001d553\U0001d554\U0001d555\U0001d556\U0001d557";
- ComparePrettyPrintToChars(
- test1,
- ("U\"\U0001d552\U0001d553\U0001d554\U0001d555\U0001d556\U0001d557\""));
- std::u32string test2 = U"\U00004f60\U0000597d";
- ComparePrettyPrintToChars(test2, ("U\"\U00004f60\U0000597d\""));
- std::u32string test3 = U"mehmet bizim dostumuz agzi kirik testimiz";
- ComparePrettyPrintToChars(test3, ("U\"mehmet bizim dostumuz agzi kirik testimiz\""));
-}
-
-void tuple_test() {
- std::tuple<int, int, int> test0(2, 3, 4);
- ComparePrettyPrintToChars(
- test0,
- "std::tuple containing = {[1] = 2, [2] = 3, [3] = 4}");
-
- std::tuple<> test1;
- ComparePrettyPrintToChars(
- test1,
- "empty std::tuple");
-}
-
-void unique_ptr_test() {
- std::unique_ptr<std::string> matilda(new std::string("Matilda"));
- ComparePrettyPrintToRegex(
- std::move(matilda),
- R"(std::unique_ptr<std::string> containing = {__ptr_ = 0x[a-f0-9]+})");
- std::unique_ptr<int> forty_two(new int(42));
- ComparePrettyPrintToRegex(std::move(forty_two),
- R"(std::unique_ptr<int> containing = {__ptr_ = 0x[a-f0-9]+})");
-
- std::unique_ptr<int> this_is_null;
- ComparePrettyPrintToChars(std::move(this_is_null),
- R"(std::unique_ptr is nullptr)");
-}
-
-void bitset_test() {
- std::bitset<258> i_am_empty(0);
- ComparePrettyPrintToChars(i_am_empty, "std::bitset<258>");
-
- std::bitset<0> very_empty;
- ComparePrettyPrintToChars(very_empty, "std::bitset<0>");
-
- std::bitset<15> b_000001111111100(1020);
- ComparePrettyPrintToChars(b_000001111111100,
- "std::bitset<15> = {[2] = 1, [3] = 1, [4] = 1, [5] = 1, [6] = 1, "
- "[7] = 1, [8] = 1, [9] = 1}");
-
- std::bitset<258> b_0_129_132(0);
- b_0_129_132[0] = true;
- b_0_129_132[129] = true;
- b_0_129_132[132] = true;
- ComparePrettyPrintToChars(b_0_129_132,
- "std::bitset<258> = {[0] = 1, [129] = 1, [132] = 1}");
-}
-
-void list_test() {
- std::list<int> i_am_empty{};
- ComparePrettyPrintToChars(i_am_empty, "std::list is empty");
-
- std::list<int> one_two_three {1, 2, 3};
- ComparePrettyPrintToChars(one_two_three,
- "std::list with 3 elements = {1, 2, 3}");
-
- std::list<std::string> colors {"red", "blue", "green"};
- ComparePrettyPrintToChars(colors,
- R"(std::list with 3 elements = {"red", "blue", "green"})");
-}
-
-void deque_test() {
- std::deque<int> i_am_empty{};
- ComparePrettyPrintToChars(i_am_empty, "std::deque is empty");
-
- std::deque<int> one_two_three {1, 2, 3};
- ComparePrettyPrintToChars(one_two_three,
- "std::deque with 3 elements = {1, 2, 3}");
-
- std::deque<example::example_struct> bfg;
- for (int i = 0; i < 10; ++i) {
- example::example_struct current;
- current.a = i;
- bfg.push_back(current);
- }
- for (int i = 0; i < 3; ++i) {
- bfg.pop_front();
- }
- for (int i = 0; i < 3; ++i) {
- bfg.pop_back();
- }
- ComparePrettyPrintToRegex(bfg,
- "std::deque with 4 elements = {"
- "{a = 3, arr = {[^}]+}}, "
- "{a = 4, arr = {[^}]+}}, "
- "{a = 5, arr = {[^}]+}}, "
- "{a = 6, arr = {[^}]+}}}");
-}
-
-void map_test() {
- std::map<int, int> i_am_empty{};
- ComparePrettyPrintToChars(i_am_empty, "std::map is empty");
-
- std::map<int, std::string> one_two_three;
- one_two_three.insert({1, "one"});
- one_two_three.insert({2, "two"});
- one_two_three.insert({3, "three"});
- ComparePrettyPrintToChars(one_two_three,
- "std::map with 3 elements = "
- R"({[1] = "one", [2] = "two", [3] = "three"})");
-
- std::map<int, example::example_struct> bfg;
- for (int i = 0; i < 4; ++i) {
- example::example_struct current;
- current.a = 17 * i;
- bfg.insert({i, current});
- }
- ComparePrettyPrintToRegex(bfg,
- R"(std::map with 4 elements = {)"
- R"(\[0\] = {a = 0, arr = {[^}]+}}, )"
- R"(\[1\] = {a = 17, arr = {[^}]+}}, )"
- R"(\[2\] = {a = 34, arr = {[^}]+}}, )"
- R"(\[3\] = {a = 51, arr = {[^}]+}}})");
-}
-
-void multimap_test() {
- std::multimap<int, int> i_am_empty{};
- ComparePrettyPrintToChars(i_am_empty, "std::multimap is empty");
-
- std::multimap<int, std::string> one_two_three;
- one_two_three.insert({1, "one"});
- one_two_three.insert({3, "three"});
- one_two_three.insert({1, "ein"});
- one_two_three.insert({2, "two"});
- one_two_three.insert({2, "zwei"});
- one_two_three.insert({1, "bir"});
-
- ComparePrettyPrintToChars(one_two_three,
- "std::multimap with 6 elements = "
- R"({[1] = "one", [1] = "ein", [1] = "bir", )"
- R"([2] = "two", [2] = "zwei", [3] = "three"})");
-}
-
-void queue_test() {
- std::queue<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty,
- "std::queue wrapping = {std::deque is empty}");
-
- std::queue<int> one_two_three(std::deque<int>{1, 2, 3});
- ComparePrettyPrintToChars(one_two_three,
- "std::queue wrapping = {"
- "std::deque with 3 elements = {1, 2, 3}}");
-}
-
-void priority_queue_test() {
- std::priority_queue<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty,
- "std::priority_queue wrapping = {std::vector of length 0, capacity 0}");
-
- std::priority_queue<int> one_two_three;
- one_two_three.push(11111);
- one_two_three.push(22222);
- one_two_three.push(33333);
-
- ComparePrettyPrintToRegex(one_two_three,
- R"(std::priority_queue wrapping = )"
- R"({std::vector of length 3, capacity 3 = {33333)");
-
- ComparePrettyPrintToRegex(one_two_three, ".*11111.*");
- ComparePrettyPrintToRegex(one_two_three, ".*22222.*");
-}
-
-void set_test() {
- std::set<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::set is empty");
-
- std::set<int> one_two_three {3, 1, 2};
- ComparePrettyPrintToChars(one_two_three,
- "std::set with 3 elements = {1, 2, 3}");
-
- std::set<std::pair<int, int>> prime_pairs {
- std::make_pair(3, 5), std::make_pair(5, 7), std::make_pair(3, 5)};
-
- ComparePrettyPrintToChars(prime_pairs,
- "std::set with 2 elements = {"
- "{first = 3, second = 5}, {first = 5, second = 7}}");
-}
-
-void stack_test() {
- std::stack<int> test0;
- ComparePrettyPrintToChars(test0,
- "std::stack wrapping = {std::deque is empty}");
- test0.push(5);
- test0.push(6);
- ComparePrettyPrintToChars(
- test0, "std::stack wrapping = {std::deque with 2 elements = {5, 6}}");
- std::stack<bool> test1;
- test1.push(true);
- test1.push(false);
- ComparePrettyPrintToChars(
- test1,
- "std::stack wrapping = {std::deque with 2 elements = {true, false}}");
-
- std::stack<std::string> test2;
- test2.push("Hello");
- test2.push("World");
- ComparePrettyPrintToChars(test2,
- "std::stack wrapping = {std::deque with 2 elements "
- "= {\"Hello\", \"World\"}}");
-}
-
-void multiset_test() {
- std::multiset<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::multiset is empty");
-
- std::multiset<std::string> one_two_three {"1:one", "2:two", "3:three", "1:one"};
- ComparePrettyPrintToChars(one_two_three,
- "std::multiset with 4 elements = {"
- R"("1:one", "1:one", "2:two", "3:three"})");
-}
-
-void vector_test() {
- std::vector<bool> test0 = {true, false};
- ComparePrettyPrintToChars(test0,
- "std::vector<bool> of "
- "length 2, capacity 64 = {1, 0}");
- for (int i = 0; i < 31; ++i) {
- test0.push_back(true);
- test0.push_back(false);
- }
- ComparePrettyPrintToRegex(
- test0,
- "std::vector<bool> of length 64, "
- "capacity 64 = {1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, "
- "0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, "
- "0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0}");
- test0.push_back(true);
- ComparePrettyPrintToRegex(
- test0,
- "std::vector<bool> of length 65, "
- "capacity 128 = {1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, "
- "1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, "
- "1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1}");
-
- std::vector<int> test1;
- ComparePrettyPrintToChars(test1, "std::vector of length 0, capacity 0");
-
- std::vector<int> test2 = {5, 6, 7};
- ComparePrettyPrintToChars(test2,
- "std::vector of length "
- "3, capacity 3 = {5, 6, 7}");
-
- std::vector<int, UncompressibleAllocator<int>> test3({7, 8});
- ComparePrettyPrintToChars(std::move(test3),
- "std::vector of length "
- "2, capacity 2 = {7, 8}");
-}
-
-void set_iterator_test() {
- std::set<int> one_two_three {1111, 2222, 3333};
- auto it = one_two_three.find(2222);
- MarkAsLive(it);
- CompareExpressionPrettyPrintToRegex("it",
- R"(std::__tree_const_iterator = {\[0x[a-f0-9]+\] = 2222})");
-
- auto not_found = one_two_three.find(1234);
- MarkAsLive(not_found);
- // Because the end_node is not easily detected, just be sure it doesn't crash.
- CompareExpressionPrettyPrintToRegex("not_found",
- R"(std::__tree_const_iterator = {\[0x[a-f0-9]+\] = .*})");
-}
-
-void map_iterator_test() {
- std::map<int, std::string> one_two_three;
- one_two_three.insert({1, "one"});
- one_two_three.insert({2, "two"});
- one_two_three.insert({3, "three"});
- auto it = one_two_three.begin();
- MarkAsLive(it);
- CompareExpressionPrettyPrintToRegex("it",
- R"(std::__map_iterator = )"
- R"({\[0x[a-f0-9]+\] = {first = 1, second = "one"}})");
-
- auto not_found = one_two_three.find(7);
- MarkAsLive(not_found);
- CompareExpressionPrettyPrintToRegex("not_found",
- R"(std::__map_iterator = {\[0x[a-f0-9]+\] = end\(\)})");
-}
-
-void unordered_set_test() {
- std::unordered_set<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::unordered_set is empty");
-
- std::unordered_set<int> numbers {12345, 67890, 222333, 12345};
- numbers.erase(numbers.find(222333));
- ComparePrettyPrintToRegex(numbers, "std::unordered_set with 2 elements = ");
- ComparePrettyPrintToRegex(numbers, ".*12345.*");
- ComparePrettyPrintToRegex(numbers, ".*67890.*");
-
- std::unordered_set<std::string> colors {"red", "blue", "green"};
- ComparePrettyPrintToRegex(colors, "std::unordered_set with 3 elements = ");
- ComparePrettyPrintToRegex(colors, R"(.*"red".*)");
- ComparePrettyPrintToRegex(colors, R"(.*"blue".*)");
- ComparePrettyPrintToRegex(colors, R"(.*"green".*)");
-}
-
-void unordered_multiset_test() {
- std::unordered_multiset<int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::unordered_multiset is empty");
-
- std::unordered_multiset<int> numbers {12345, 67890, 222333, 12345};
- ComparePrettyPrintToRegex(numbers,
- "std::unordered_multiset with 4 elements = ");
- ComparePrettyPrintToRegex(numbers, ".*12345.*12345.*");
- ComparePrettyPrintToRegex(numbers, ".*67890.*");
- ComparePrettyPrintToRegex(numbers, ".*222333.*");
-
- std::unordered_multiset<std::string> colors {"red", "blue", "green", "red"};
- ComparePrettyPrintToRegex(colors,
- "std::unordered_multiset with 4 elements = ");
- ComparePrettyPrintToRegex(colors, R"(.*"red".*"red".*)");
- ComparePrettyPrintToRegex(colors, R"(.*"blue".*)");
- ComparePrettyPrintToRegex(colors, R"(.*"green".*)");
-}
-
-void unordered_map_test() {
- std::unordered_map<int, int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::unordered_map is empty");
-
- std::unordered_map<int, std::string> one_two_three;
- one_two_three.insert({1, "one"});
- one_two_three.insert({2, "two"});
- one_two_three.insert({3, "three"});
- ComparePrettyPrintToRegex(one_two_three,
- "std::unordered_map with 3 elements = ");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[1\] = "one".*)");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[2\] = "two".*)");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[3\] = "three".*)");
-}
-
-void unordered_multimap_test() {
- std::unordered_multimap<int, int> i_am_empty;
- ComparePrettyPrintToChars(i_am_empty, "std::unordered_multimap is empty");
-
- std::unordered_multimap<int, std::string> one_two_three;
- one_two_three.insert({1, "one"});
- one_two_three.insert({2, "two"});
- one_two_three.insert({3, "three"});
- one_two_three.insert({2, "two"});
- ComparePrettyPrintToRegex(one_two_three,
- "std::unordered_multimap with 4 elements = ");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[1\] = "one".*)");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[2\] = "two".*\[2\] = "two")");
- ComparePrettyPrintToRegex(one_two_three, R"(.*\[3\] = "three".*)");
-}
-
-void unordered_map_iterator_test() {
- std::unordered_map<int, int> ones_to_eights;
- ones_to_eights.insert({1, 8});
- ones_to_eights.insert({11, 88});
- ones_to_eights.insert({111, 888});
-
- auto ones_to_eights_begin = ones_to_eights.begin();
- MarkAsLive(ones_to_eights_begin);
- CompareExpressionPrettyPrintToRegex("ones_to_eights_begin",
- R"(std::__hash_map_iterator = {\[1+\] = 8+})");
-
- auto not_found = ones_to_eights.find(5);
- MarkAsLive(not_found);
- CompareExpressionPrettyPrintToRegex("not_found",
- R"(std::__hash_map_iterator = end\(\))");
-}
-
-void unordered_set_iterator_test() {
- std::unordered_set<int> ones;
- ones.insert(111);
- ones.insert(1111);
- ones.insert(11111);
-
- auto ones_begin = ones.begin();
- MarkAsLive(ones_begin);
- CompareExpressionPrettyPrintToRegex("ones_begin",
- R"(std::__hash_const_iterator = {1+})");
-
- auto not_found = ones.find(5);
- MarkAsLive(not_found);
- CompareExpressionPrettyPrintToRegex("not_found",
- R"(std::__hash_const_iterator = end\(\))");
-}
-
-// Check that libc++ pretty printers do not handle pointers.
-void pointer_negative_test() {
- int abc = 123;
- int *int_ptr = &abc;
- // Check that the result is equivalent to "p/r int_ptr" command.
- ComparePrettyPrintToRegex(int_ptr, R"(\(int \*\) 0x[a-f0-9]+)");
-}
-
-void shared_ptr_test() {
- // Shared ptr tests while using test framework call another function
- // due to which there is one more count for the pointer. Hence, all the
- // following tests are testing with expected count plus 1.
- std::shared_ptr<const int> test0 = std::make_shared<const int>(5);
- ComparePrettyPrintToRegex(
- test0,
- R"(std::shared_ptr<int> count 2, weak 0 containing = {__ptr_ = 0x[a-f0-9]+})");
-
- std::shared_ptr<const int> test1(test0);
- ComparePrettyPrintToRegex(
- test1,
- R"(std::shared_ptr<int> count 3, weak 0 containing = {__ptr_ = 0x[a-f0-9]+})");
-
- {
- std::weak_ptr<const int> test2 = test1;
- ComparePrettyPrintToRegex(
- test0,
- R"(std::shared_ptr<int> count 3, weak 1 containing = {__ptr_ = 0x[a-f0-9]+})");
- }
-
- ComparePrettyPrintToRegex(
- test0,
- R"(std::shared_ptr<int> count 3, weak 0 containing = {__ptr_ = 0x[a-f0-9]+})");
-
- std::shared_ptr<const int> test3;
- ComparePrettyPrintToChars(test3, "std::shared_ptr is nullptr");
-}
-
-void streampos_test() {
- std::streampos test0 = 67;
- ComparePrettyPrintToChars(
- test0, "std::fpos with stream offset:67 with state: {count:0 value:0}");
- std::istringstream input("testing the input stream here");
- std::streampos test1 = input.tellg();
- ComparePrettyPrintToChars(
- test1, "std::fpos with stream offset:0 with state: {count:0 value:0}");
- std::unique_ptr<char[]> buffer(new char[5]);
- input.read(buffer.get(), 5);
- test1 = input.tellg();
- ComparePrettyPrintToChars(
- test1, "std::fpos with stream offset:5 with state: {count:0 value:0}");
-}
-
-int main(int argc, char* argv[]) {
- framework_self_test();
-
- string_test();
-
- u32string_test();
- tuple_test();
- unique_ptr_test();
- shared_ptr_test();
- bitset_test();
- list_test();
- deque_test();
- map_test();
- multimap_test();
- queue_test();
- priority_queue_test();
- stack_test();
- set_test();
- multiset_test();
- vector_test();
- set_iterator_test();
- map_iterator_test();
- unordered_set_test();
- unordered_multiset_test();
- unordered_map_test();
- unordered_multimap_test();
- unordered_map_iterator_test();
- unordered_set_iterator_test();
- pointer_negative_test();
- streampos_test();
- return 0;
-}
diff --git a/utils/gdb/libcxx/printers.py b/utils/gdb/libcxx/printers.py
deleted file mode 100644
index dc2f2e9..0000000
--- a/utils/gdb/libcxx/printers.py
+++ /dev/null
@@ -1,992 +0,0 @@
-#===----------------------------------------------------------------------===##
-#
-# Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
-# See https://llvm.org/LICENSE.txt for license information.
-# SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
-#
-#===----------------------------------------------------------------------===##
-"""GDB pretty-printers for libc++.
-
-These should work for objects compiled when _LIBCPP_ABI_UNSTABLE is defined
-and when it is undefined.
-"""
-
-from __future__ import print_function
-
-import re
-import gdb
-
-# One under-documented feature of the gdb pretty-printer API
-# is that clients can call any other member of the API
-# before they call to_string.
-# Therefore all self.FIELDs must be set in the pretty-printer's
-# __init__ function.
-
-_void_pointer_type = gdb.lookup_type("void").pointer()
-
-
-_long_int_type = gdb.lookup_type("unsigned long long")
-
-
-def addr_as_long(addr):
- return int(addr.cast(_long_int_type))
-
-
-# The size of a pointer in bytes.
-_pointer_size = _void_pointer_type.sizeof
-
-
-def _remove_cxx_namespace(typename):
- """Removed libc++ specific namespace from the type.
-
- Arguments:
- typename(string): A type, such as std::__u::something.
-
- Returns:
- A string without the libc++ specific part, such as std::something.
- """
-
- return re.sub("std::__.*?::", "std::", typename)
-
-
-def _remove_generics(typename):
- """Remove generics part of the type. Assumes typename is not empty.
-
- Arguments:
- typename(string): A type such as std::my_collection<element>.
-
- Returns:
- The prefix up to the generic part, such as std::my_collection.
- """
-
- match = re.match("^([^<]+)", typename)
- return match.group(1)
-
-
-# Some common substitutions on the types to reduce visual clutter (A user who
-# wants to see the actual details can always use print/r).
-_common_substitutions = [
- ("std::basic_string<char, std::char_traits<char>, std::allocator<char> >",
- "std::string"),
-]
-
-
-def _prettify_typename(gdb_type):
- """Returns a pretty name for the type, or None if no name can be found.
-
- Arguments:
- gdb_type(gdb.Type): A type object.
-
- Returns:
- A string, without type_defs, libc++ namespaces, and common substitutions
- applied.
- """
-
- type_without_typedefs = gdb_type.strip_typedefs()
- typename = type_without_typedefs.name or type_without_typedefs.tag or \
- str(type_without_typedefs)
- result = _remove_cxx_namespace(typename)
- for find_str, subst_str in _common_substitutions:
- result = re.sub(find_str, subst_str, result)
- return result
-
-
-def _typename_for_nth_generic_argument(gdb_type, n):
- """Returns a pretty string for the nth argument of the given type.
-
- Arguments:
- gdb_type(gdb.Type): A type object, such as the one for std::map<int, int>
- n: The (zero indexed) index of the argument to return.
-
- Returns:
- A string for the nth argument, such a "std::string"
- """
- element_type = gdb_type.template_argument(n)
- return _prettify_typename(element_type)
-
-
-def _typename_with_n_generic_arguments(gdb_type, n):
- """Return a string for the type with the first n (1, ...) generic args."""
-
- base_type = _remove_generics(_prettify_typename(gdb_type))
- arg_list = [base_type]
- template = "%s<"
- for i in range(n):
- arg_list.append(_typename_for_nth_generic_argument(gdb_type, i))
- template += "%s, "
- result = (template[:-2] + ">") % tuple(arg_list)
- return result
-
-
-def _typename_with_first_generic_argument(gdb_type):
- return _typename_with_n_generic_arguments(gdb_type, 1)
-
-
-class StdTuplePrinter(object):
- """Print a std::tuple."""
-
- class _Children(object):
- """Class to iterate over the tuple's children."""
-
- def __init__(self, val):
- self.val = val
- self.child_iter = iter(self.val["__base_"].type.fields())
- self.count = 0
-
- def __iter__(self):
- return self
-
- def next(self):
- # child_iter raises StopIteration when appropriate.
- field_name = self.child_iter.next()
- child = self.val["__base_"][field_name]["__value_"]
- self.count += 1
- return ("[%d]" % self.count, child)
-
- def __init__(self, val):
- self.val = val
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if not self.val.type.fields():
- return "empty %s" % typename
- return "%s containing" % typename
-
- def children(self):
- if not self.val.type.fields():
- return iter(())
- return self._Children(self.val)
-
-
-def _get_base_subobject(child_class_value, index=0):
- """Returns the object's value in the form of the parent class at index.
-
- This function effectively casts the child_class_value to the base_class's
- type, but the type-to-cast to is stored in the field at index, and once
- we know the field, we can just return the data.
-
- Args:
- child_class_value: the value to cast
- index: the parent class index
-
- Raises:
- Exception: field at index was not a base-class field.
- """
-
- field = child_class_value.type.fields()[index]
- if not field.is_base_class:
- raise Exception("Not a base-class field.")
- return child_class_value[field]
-
-
-def _value_of_pair_first(value):
- """Convenience for _get_base_subobject, for the common case."""
- return _get_base_subobject(value, 0)["__value_"]
-
-
-class StdStringPrinter(object):
- """Print a std::string."""
-
- def _get_short_size(self, short_field, short_size):
- """Short size depends on both endianness and a compile-time define."""
-
- # If the padding field is present after all this indirection, then string
- # was compiled with _LIBCPP_ABI_ALTERNATE_STRING_LAYOUT defined.
- field = short_field.type.fields()[1].type.fields()[0]
- libcpp_abi_alternate_string_layout = field.name and "__padding" in field.name
-
- # Strictly, this only tells us the current mode, not how libcxx was
- # compiled.
- libcpp_big_endian = "big endian" in gdb.execute("show endian",
- to_string=True)
-
- # This logical structure closely follows the original code (which is clearer
- # in C++). Keep them parallel to make them easier to compare.
- if libcpp_abi_alternate_string_layout:
- if libcpp_big_endian:
- return short_size >> 1
- else:
- return short_size
- elif libcpp_big_endian:
- return short_size
- else:
- return short_size >> 1
-
- def __init__(self, val):
- self.val = val
-
- def to_string(self):
- """Build a python string from the data whether stored inline or separately."""
-
- value_field = _value_of_pair_first(self.val["__r_"])
- short_field = value_field["__s"]
- short_size = short_field["__size_"]
- if short_size == 0:
- return ""
- short_mask = self.val["__short_mask"]
- # Counter intuitive to compare the size and short_mask to see if the string
- # is long, but that's the way the implementation does it. Note that
- # __is_long() doesn't use get_short_size in C++.
- is_long = short_size & short_mask
- if is_long:
- long_field = value_field["__l"]
- data = long_field["__data_"]
- size = long_field["__size_"]
- else:
- data = short_field["__data_"]
- size = self._get_short_size(short_field, short_size)
- if hasattr(data, "lazy_string"):
- return data.lazy_string(length=size)
- return data.string(length=size)
-
- def display_hint(self):
- return "string"
-
-
-class StdUniquePtrPrinter(object):
- """Print a std::unique_ptr."""
-
- def __init__(self, val):
- self.val = val
- self.addr = _value_of_pair_first(self.val["__ptr_"])
- self.pointee_type = self.val.type.template_argument(0)
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if not self.addr:
- return "%s is nullptr" % typename
- return ("%s<%s> containing" %
- (typename,
- _remove_generics(_prettify_typename(self.pointee_type))))
-
- def __iter__(self):
- if self.addr:
- yield "__ptr_", self.addr.cast(self.pointee_type.pointer())
-
- def children(self):
- return self
-
-
-class StdSharedPointerPrinter(object):
- """Print a std::shared_ptr."""
-
- def __init__(self, val):
- self.val = val
- self.addr = self.val["__ptr_"]
-
- def to_string(self):
- """Returns self as a string."""
- typename = _remove_generics(_prettify_typename(self.val.type))
- pointee_type = _remove_generics(
- _prettify_typename(self.val.type.template_argument(0)))
- if not self.addr:
- return "%s is nullptr" % typename
- refcount = self.val["__cntrl_"]
- if refcount != 0:
- usecount = refcount["__shared_owners_"] + 1
- weakcount = refcount["__shared_weak_owners_"]
- if usecount == 0:
- state = "expired, weak %d" % weakcount
- else:
- state = "count %d, weak %d" % (usecount, weakcount)
- return "%s<%s> %s containing" % (typename, pointee_type, state)
-
- def __iter__(self):
- if self.addr:
- yield "__ptr_", self.addr
-
- def children(self):
- return self
-
-
-class StdVectorPrinter(object):
- """Print a std::vector."""
-
- class _VectorBoolIterator(object):
- """Class to iterate over the bool vector's children."""
-
- def __init__(self, begin, size, bits_per_word):
- self.item = begin
- self.size = size
- self.bits_per_word = bits_per_word
- self.count = 0
- self.offset = 0
-
- def __iter__(self):
- return self
-
- def next(self):
- """Retrieve the next element."""
-
- self.count += 1
- if self.count > self.size:
- raise StopIteration
- entry = self.item.dereference()
- if entry & (1 << self.offset):
- outbit = 1
- else:
- outbit = 0
- self.offset += 1
- if self.offset >= self.bits_per_word:
- self.item += 1
- self.offset = 0
- return ("[%d]" % self.count, outbit)
-
- class _VectorIterator(object):
- """Class to iterate over the non-bool vector's children."""
-
- def __init__(self, begin, end):
- self.item = begin
- self.end = end
- self.count = 0
-
- def __iter__(self):
- return self
-
- def next(self):
- self.count += 1
- if self.item == self.end:
- raise StopIteration
- entry = self.item.dereference()
- self.item += 1
- return ("[%d]" % self.count, entry)
-
- def __init__(self, val):
- """Set val, length, capacity, and iterator for bool and normal vectors."""
- self.val = val
- self.typename = _remove_generics(_prettify_typename(val.type))
- begin = self.val["__begin_"]
- if self.val.type.template_argument(0).code == gdb.TYPE_CODE_BOOL:
- self.typename += "<bool>"
- self.length = self.val["__size_"]
- bits_per_word = self.val["__bits_per_word"]
- self.capacity = _value_of_pair_first(
- self.val["__cap_alloc_"]) * bits_per_word
- self.iterator = self._VectorBoolIterator(
- begin, self.length, bits_per_word)
- else:
- end = self.val["__end_"]
- self.length = end - begin
- self.capacity = _get_base_subobject(
- self.val["__end_cap_"])["__value_"] - begin
- self.iterator = self._VectorIterator(begin, end)
-
- def to_string(self):
- return ("%s of length %d, capacity %d" %
- (self.typename, self.length, self.capacity))
-
- def children(self):
- return self.iterator
-
- def display_hint(self):
- return "array"
-
-
-class StdBitsetPrinter(object):
- """Print a std::bitset."""
-
- def __init__(self, val):
- self.val = val
- self.n_words = int(self.val["__n_words"])
- self.bits_per_word = int(self.val["__bits_per_word"])
- if self.n_words == 1:
- self.values = [int(self.val["__first_"])]
- else:
- self.values = [int(self.val["__first_"][index])
- for index in range(self.n_words)]
-
- def to_string(self):
- typename = _prettify_typename(self.val.type)
- return "%s" % typename
-
- def _byte_it(self, value):
- index = -1
- while value:
- index += 1
- will_yield = value % 2
- value /= 2
- if will_yield:
- yield index
-
- def _list_it(self):
- for word_index in range(self.n_words):
- current = self.values[word_index]
- if current:
- for n in self._byte_it(current):
- yield ("[%d]" % (word_index * self.bits_per_word + n), 1)
-
- def __iter__(self):
- return self._list_it()
-
- def children(self):
- return self
-
-
-class StdDequePrinter(object):
- """Print a std::deque."""
-
- def __init__(self, val):
- self.val = val
- self.size = int(_value_of_pair_first(val["__size_"]))
- self.start_ptr = self.val["__map_"]["__begin_"]
- self.first_block_start_index = int(self.val["__start_"])
- self.node_type = self.start_ptr.type
- self.block_size = self._calculate_block_size(
- val.type.template_argument(0))
-
- def _calculate_block_size(self, element_type):
- """Calculates the number of elements in a full block."""
- size = element_type.sizeof
- # Copied from struct __deque_block_size implementation of libcxx.
- return 4096 / size if size < 256 else 16
-
- def _bucket_it(self, start_addr, start_index, end_index):
- for i in range(start_index, end_index):
- yield i, (start_addr.dereference() + i).dereference()
-
- def _list_it(self):
- """Primary iteration worker."""
- num_emitted = 0
- current_addr = self.start_ptr
- start_index = self.first_block_start_index
- while num_emitted < self.size:
- end_index = min(start_index + self.size -
- num_emitted, self.block_size)
- for _, elem in self._bucket_it(current_addr, start_index, end_index):
- yield "", elem
- num_emitted += end_index - start_index
- current_addr = gdb.Value(addr_as_long(current_addr) + _pointer_size) \
- .cast(self.node_type)
- start_index = 0
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if self.size:
- return "%s with %d elements" % (typename, self.size)
- return "%s is empty" % typename
-
- def __iter__(self):
- return self._list_it()
-
- def children(self):
- return self
-
- def display_hint(self):
- return "array"
-
-
-class StdListPrinter(object):
- """Print a std::list."""
-
- def __init__(self, val):
- self.val = val
- size_alloc_field = self.val["__size_alloc_"]
- self.size = int(_value_of_pair_first(size_alloc_field))
- dummy_node = self.val["__end_"]
- self.nodetype = gdb.lookup_type(
- re.sub("__list_node_base", "__list_node",
- str(dummy_node.type.strip_typedefs()))).pointer()
- self.first_node = dummy_node["__next_"]
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if self.size:
- return "%s with %d elements" % (typename, self.size)
- return "%s is empty" % typename
-
- def _list_iter(self):
- current_node = self.first_node
- for _ in range(self.size):
- yield "", current_node.cast(self.nodetype).dereference()["__value_"]
- current_node = current_node.dereference()["__next_"]
-
- def __iter__(self):
- return self._list_iter()
-
- def children(self):
- return self if self.nodetype else iter(())
-
- def display_hint(self):
- return "array"
-
-
-class StdQueueOrStackPrinter(object):
- """Print a std::queue or std::stack."""
-
- def __init__(self, val):
- self.val = val
- self.underlying = val["c"]
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- return "%s wrapping" % typename
-
- def children(self):
- return iter([("", self.underlying)])
-
- def display_hint(self):
- return "array"
-
-
-class StdPriorityQueuePrinter(object):
- """Print a std::priority_queue."""
-
- def __init__(self, val):
- self.val = val
- self.underlying = val["c"]
-
- def to_string(self):
- # TODO(tamur): It would be nice to print the top element. The technical
- # difficulty is that, the implementation refers to the underlying
- # container, which is a generic class. libstdcxx pretty printers do not
- # print the top element.
- typename = _remove_generics(_prettify_typename(self.val.type))
- return "%s wrapping" % typename
-
- def children(self):
- return iter([("", self.underlying)])
-
- def display_hint(self):
- return "array"
-
-
-class RBTreeUtils(object):
- """Utility class for std::(multi)map, and std::(multi)set and iterators."""
-
- def __init__(self, cast_type, root):
- self.cast_type = cast_type
- self.root = root
-
- def left_child(self, node):
- result = node.cast(self.cast_type).dereference()["__left_"]
- return result
-
- def right_child(self, node):
- result = node.cast(self.cast_type).dereference()["__right_"]
- return result
-
- def parent(self, node):
- """Return the parent of node, if it exists."""
- # If this is the root, then from the algorithm's point of view, it has no
- # parent.
- if node == self.root:
- return None
-
- # We don't have enough information to tell if this is the end_node (which
- # doesn't have a __parent_ field), or the root (which doesn't have a parent
- # from the algorithm's point of view), so cast_type may not be correct for
- # this particular node. Use heuristics.
-
- # The end_node's left child is the root. Note that when printing interators
- # in isolation, the root is unknown.
- if self.left_child(node) == self.root:
- return None
-
- parent = node.cast(self.cast_type).dereference()["__parent_"]
- # If the value at the offset of __parent_ doesn't look like a valid pointer,
- # then assume that node is the end_node (and therefore has no parent).
- # End_node type has a pointer embedded, so should have pointer alignment.
- if addr_as_long(parent) % _void_pointer_type.alignof:
- return None
- # This is ugly, but the only other option is to dereference an invalid
- # pointer. 0x8000 is fairly arbitrary, but has had good results in
- # practice. If there was a way to tell if a pointer is invalid without
- # actually dereferencing it and spewing error messages, that would be ideal.
- if parent < 0x8000:
- return None
- return parent
-
- def is_left_child(self, node):
- parent = self.parent(node)
- return parent is not None and self.left_child(parent) == node
-
- def is_right_child(self, node):
- parent = self.parent(node)
- return parent is not None and self.right_child(parent) == node
-
-
-class AbstractRBTreePrinter(object):
- """Abstract super class for std::(multi)map, and std::(multi)set."""
-
- def __init__(self, val):
- self.val = val
- tree = self.val["__tree_"]
- self.size = int(_value_of_pair_first(tree["__pair3_"]))
- dummy_root = tree["__pair1_"]
- root = _value_of_pair_first(dummy_root)["__left_"]
- cast_type = self._init_cast_type(val.type)
- self.util = RBTreeUtils(cast_type, root)
-
- def _get_key_value(self, node):
- """Subclasses should override to return a list of values to yield."""
- raise NotImplementedError
-
- def _traverse(self):
- """Traverses the binary search tree in order."""
- current = self.util.root
- skip_left_child = False
- while True:
- if not skip_left_child and self.util.left_child(current):
- current = self.util.left_child(current)
- continue
- skip_left_child = False
- for key_value in self._get_key_value(current):
- yield "", key_value
- right_child = self.util.right_child(current)
- if right_child:
- current = right_child
- continue
- while self.util.is_right_child(current):
- current = self.util.parent(current)
- if self.util.is_left_child(current):
- current = self.util.parent(current)
- skip_left_child = True
- continue
- break
-
- def __iter__(self):
- return self._traverse()
-
- def children(self):
- return self if self.util.cast_type and self.size > 0 else iter(())
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if self.size:
- return "%s with %d elements" % (typename, self.size)
- return "%s is empty" % typename
-
-
-class StdMapPrinter(AbstractRBTreePrinter):
- """Print a std::map or std::multimap."""
-
- def _init_cast_type(self, val_type):
- map_it_type = gdb.lookup_type(
- str(val_type) + "::iterator").strip_typedefs()
- tree_it_type = map_it_type.template_argument(0)
- node_ptr_type = tree_it_type.template_argument(1)
- return node_ptr_type
-
- def display_hint(self):
- return "map"
-
- def _get_key_value(self, node):
- key_value = node.cast(self.util.cast_type).dereference()[
- "__value_"]["__cc"]
- return [key_value["first"], key_value["second"]]
-
-
-class StdSetPrinter(AbstractRBTreePrinter):
- """Print a std::set."""
-
- def _init_cast_type(self, val_type):
- set_it_type = gdb.lookup_type(
- str(val_type) + "::iterator").strip_typedefs()
- node_ptr_type = set_it_type.template_argument(1)
- return node_ptr_type
-
- def display_hint(self):
- return "array"
-
- def _get_key_value(self, node):
- key_value = node.cast(self.util.cast_type).dereference()["__value_"]
- return [key_value]
-
-
-class AbstractRBTreeIteratorPrinter(object):
- """Abstract super class for std::(multi)map, and std::(multi)set iterator."""
-
- def _initialize(self, val, typename):
- self.typename = typename
- self.val = val
- self.addr = self.val["__ptr_"]
- cast_type = self.val.type.template_argument(1)
- self.util = RBTreeUtils(cast_type, None)
- if self.addr:
- self.node = self.addr.cast(cast_type).dereference()
-
- def _is_valid_node(self):
- if not self.util.parent(self.addr):
- return False
- return self.util.is_left_child(self.addr) or \
- self.util.is_right_child(self.addr)
-
- def to_string(self):
- if not self.addr:
- return "%s is nullptr" % self.typename
- return "%s " % self.typename
-
- def _get_node_value(self, node):
- raise NotImplementedError
-
- def __iter__(self):
- addr_str = "[%s]" % str(self.addr)
- if not self._is_valid_node():
- yield addr_str, " end()"
- else:
- yield addr_str, self._get_node_value(self.node)
-
- def children(self):
- return self if self.addr else iter(())
-
-
-class MapIteratorPrinter(AbstractRBTreeIteratorPrinter):
- """Print a std::(multi)map iterator."""
-
- def __init__(self, val):
- self._initialize(val["__i_"],
- _remove_generics(_prettify_typename(val.type)))
-
- def _get_node_value(self, node):
- return node["__value_"]["__cc"]
-
-
-class SetIteratorPrinter(AbstractRBTreeIteratorPrinter):
- """Print a std::(multi)set iterator."""
-
- def __init__(self, val):
- self._initialize(val, _remove_generics(_prettify_typename(val.type)))
-
- def _get_node_value(self, node):
- return node["__value_"]
-
-
-class StdFposPrinter(object):
- """Print a std::fpos or std::streampos."""
-
- def __init__(self, val):
- self.val = val
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- offset = self.val["__off_"]
- state = self.val["__st_"]
- count = state["__count"]
- value = state["__value"]["__wch"]
- return "%s with stream offset:%s with state: {count:%s value:%s}" % (
- typename, offset, count, value)
-
-
-class AbstractUnorderedCollectionPrinter(object):
- """Abstract super class for std::unordered_(multi)[set|map]."""
-
- def __init__(self, val):
- self.val = val
- self.table = val["__table_"]
- self.sentinel = self.table["__p1_"]
- self.size = int(_value_of_pair_first(self.table["__p2_"]))
- node_base_type = self.sentinel.type.template_argument(0)
- self.cast_type = node_base_type.template_argument(0)
-
- def _list_it(self, sentinel_ptr):
- next_ptr = _value_of_pair_first(sentinel_ptr)["__next_"]
- while str(next_ptr.cast(_void_pointer_type)) != "0x0":
- next_val = next_ptr.cast(self.cast_type).dereference()
- for key_value in self._get_key_value(next_val):
- yield "", key_value
- next_ptr = next_val["__next_"]
-
- def to_string(self):
- typename = _remove_generics(_prettify_typename(self.val.type))
- if self.size:
- return "%s with %d elements" % (typename, self.size)
- return "%s is empty" % typename
-
- def _get_key_value(self, node):
- """Subclasses should override to return a list of values to yield."""
- raise NotImplementedError
-
- def children(self):
- return self if self.cast_type and self.size > 0 else iter(())
-
- def __iter__(self):
- return self._list_it(self.sentinel)
-
-
-class StdUnorderedSetPrinter(AbstractUnorderedCollectionPrinter):
- """Print a std::unordered_(multi)set."""
-
- def _get_key_value(self, node):
- return [node["__value_"]]
-
- def display_hint(self):
- return "array"
-
-
-class StdUnorderedMapPrinter(AbstractUnorderedCollectionPrinter):
- """Print a std::unordered_(multi)map."""
-
- def _get_key_value(self, node):
- key_value = node["__value_"]["__cc"]
- return [key_value["first"], key_value["second"]]
-
- def display_hint(self):
- return "map"
-
-
-class AbstractHashMapIteratorPrinter(object):
- """Abstract class for unordered collection iterators."""
-
- def _initialize(self, val, addr):
- self.val = val
- self.typename = _remove_generics(_prettify_typename(self.val.type))
- self.addr = addr
- if self.addr:
- self.node = self.addr.cast(self.cast_type).dereference()
-
- def _get_key_value(self):
- """Subclasses should override to return a list of values to yield."""
- raise NotImplementedError
-
- def to_string(self):
- if not self.addr:
- return "%s = end()" % self.typename
- return "%s " % self.typename
-
- def children(self):
- return self if self.addr else iter(())
-
- def __iter__(self):
- for key_value in self._get_key_value():
- yield "", key_value
-
-
-class StdUnorderedSetIteratorPrinter(AbstractHashMapIteratorPrinter):
- """Print a std::(multi)set iterator."""
-
- def __init__(self, val):
- self.cast_type = val.type.template_argument(0)
- self._initialize(val, val["__node_"])
-
- def _get_key_value(self):
- return [self.node["__value_"]]
-
- def display_hint(self):
- return "array"
-
-
-class StdUnorderedMapIteratorPrinter(AbstractHashMapIteratorPrinter):
- """Print a std::(multi)map iterator."""
-
- def __init__(self, val):
- self.cast_type = val.type.template_argument(0).template_argument(0)
- self._initialize(val, val["__i_"]["__node_"])
-
- def _get_key_value(self):
- key_value = self.node["__value_"]["__cc"]
- return [key_value["first"], key_value["second"]]
-
- def display_hint(self):
- return "map"
-
-
-def _remove_std_prefix(typename):
- match = re.match("^std::(.+)", typename)
- return match.group(1) if match is not None else ""
-
-
-class LibcxxPrettyPrinter(object):
- """PrettyPrinter object so gdb-commands like 'info pretty-printers' work."""
-
- def __init__(self, name):
- super(LibcxxPrettyPrinter, self).__init__()
- self.name = name
- self.enabled = True
-
- self.lookup = {
- "basic_string": StdStringPrinter,
- "string": StdStringPrinter,
- "tuple": StdTuplePrinter,
- "unique_ptr": StdUniquePtrPrinter,
- "shared_ptr": StdSharedPointerPrinter,
- "weak_ptr": StdSharedPointerPrinter,
- "bitset": StdBitsetPrinter,
- "deque": StdDequePrinter,
- "list": StdListPrinter,
- "queue": StdQueueOrStackPrinter,
- "stack": StdQueueOrStackPrinter,
- "priority_queue": StdPriorityQueuePrinter,
- "map": StdMapPrinter,
- "multimap": StdMapPrinter,
- "set": StdSetPrinter,
- "multiset": StdSetPrinter,
- "vector": StdVectorPrinter,
- "__map_iterator": MapIteratorPrinter,
- "__map_const_iterator": MapIteratorPrinter,
- "__tree_iterator": SetIteratorPrinter,
- "__tree_const_iterator": SetIteratorPrinter,
- "fpos": StdFposPrinter,
- "unordered_set": StdUnorderedSetPrinter,
- "unordered_multiset": StdUnorderedSetPrinter,
- "unordered_map": StdUnorderedMapPrinter,
- "unordered_multimap": StdUnorderedMapPrinter,
- "__hash_map_iterator": StdUnorderedMapIteratorPrinter,
- "__hash_map_const_iterator": StdUnorderedMapIteratorPrinter,
- "__hash_iterator": StdUnorderedSetIteratorPrinter,
- "__hash_const_iterator": StdUnorderedSetIteratorPrinter,
- }
-
- self.subprinters = []
- for name, subprinter in self.lookup.items():
- # Subprinters and names are used only for the rarely used command "info
- # pretty" (and related), so the name of the first data structure it prints
- # is a reasonable choice.
- if subprinter not in self.subprinters:
- subprinter.name = name
- self.subprinters.append(subprinter)
-
- def __call__(self, val):
- """Return the pretty printer for a val, if the type is supported."""
-
- # Do not handle any type that is not a struct/class.
- if val.type.strip_typedefs().code != gdb.TYPE_CODE_STRUCT:
- return None
-
- # Don't attempt types known to be inside libstdcxx.
- typename = val.type.name or val.type.tag or str(val.type)
- match = re.match("^std::(__.*?)::", typename)
- if match is None or match.group(1) in ["__cxx1998",
- "__debug",
- "__7",
- "__g"]:
- return None
-
- # Handle any using declarations or other typedefs.
- typename = _prettify_typename(val.type)
- if not typename:
- return None
- without_generics = _remove_generics(typename)
- lookup_name = _remove_std_prefix(without_generics)
- if lookup_name in self.lookup:
- return self.lookup[lookup_name](val)
- return None
-
-
-_libcxx_printer_name = "libcxx_pretty_printer"
-
-
-# These are called for every binary object file, which could be thousands in
-# certain pathological cases. Limit our pretty printers to the progspace.
-def _register_libcxx_printers(event):
- progspace = event.new_objfile.progspace
- if not getattr(progspace, _libcxx_printer_name, False):
- print("Loading libc++ pretty-printers.")
- gdb.printing.register_pretty_printer(
- progspace, LibcxxPrettyPrinter(_libcxx_printer_name))
- setattr(progspace, _libcxx_printer_name, True)
-
-
-def _unregister_libcxx_printers(event):
- progspace = event.progspace
- if getattr(progspace, _libcxx_printer_name, False):
- for printer in progspace.pretty_printers:
- if getattr(printer, "name", "none") == _libcxx_printer_name:
- progspace.pretty_printers.remove(printer)
- setattr(progspace, _libcxx_printer_name, False)
- break
-
-
-def register_libcxx_printer_loader():
- """Register event handlers to load libc++ pretty-printers."""
- gdb.events.new_objfile.connect(_register_libcxx_printers)
- gdb.events.clear_objfiles.connect(_unregister_libcxx_printers)