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llvm-project/lldb/source/Utility/StdStringExtractor.cpp
Kate Stone b9c1b51e45 *** This commit represents a complete reformatting of the LLDB source code 
*** to conform to clang-format’s LLVM style.  This kind of mass change has
*** two obvious implications:

Firstly, merging this particular commit into a downstream fork may be a huge
effort.  Alternatively, it may be worth merging all changes up to this commit,
performing the same reformatting operation locally, and then discarding the
merge for this particular commit.  The commands used to accomplish this
reformatting were as follows (with current working directory as the root of
the repository):

    find . \( -iname "*.c" -or -iname "*.cpp" -or -iname "*.h" -or -iname "*.mm" \) -exec clang-format -i {} +
    find . -iname "*.py" -exec autopep8 --in-place --aggressive --aggressive {} + ;

The version of clang-format used was 3.9.0, and autopep8 was 1.2.4.

Secondly, “blame” style tools will generally point to this commit instead of
a meaningful prior commit.  There are alternatives available that will attempt
to look through this change and find the appropriate prior commit.  YMMV.

llvm-svn: 280751
2016-09-06 20:57:50 +00:00

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//===-- StdStringExtractor.cpp ----------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "lldb/Utility/StdStringExtractor.h"
// C Includes
#include <stdlib.h>
// C++ Includes
// Other libraries and framework includes
// Project includes
static inline int xdigit_to_sint(char ch) {
if (ch >= 'a' && ch <= 'f')
return 10 + ch - 'a';
if (ch >= 'A' && ch <= 'F')
return 10 + ch - 'A';
if (ch >= '0' && ch <= '9')
return ch - '0';
return -1;
}
//----------------------------------------------------------------------
// StdStringExtractor constructor
//----------------------------------------------------------------------
StdStringExtractor::StdStringExtractor() : m_packet(), m_index(0) {}
StdStringExtractor::StdStringExtractor(const char *packet_cstr)
: m_packet(), m_index(0) {
if (packet_cstr)
m_packet.assign(packet_cstr);
}
//----------------------------------------------------------------------
// StdStringExtractor copy constructor
//----------------------------------------------------------------------
StdStringExtractor::StdStringExtractor(const StdStringExtractor &rhs)
: m_packet(rhs.m_packet), m_index(rhs.m_index) {}
//----------------------------------------------------------------------
// StdStringExtractor assignment operator
//----------------------------------------------------------------------
const StdStringExtractor &StdStringExtractor::
operator=(const StdStringExtractor &rhs) {
if (this != &rhs) {
m_packet = rhs.m_packet;
m_index = rhs.m_index;
}
return *this;
}
//----------------------------------------------------------------------
// Destructor
//----------------------------------------------------------------------
StdStringExtractor::~StdStringExtractor() {}
char StdStringExtractor::GetChar(char fail_value) {
if (m_index < m_packet.size()) {
char ch = m_packet[m_index];
++m_index;
return ch;
}
m_index = UINT64_MAX;
return fail_value;
}
//----------------------------------------------------------------------
// If a pair of valid hex digits exist at the head of the
// StdStringExtractor they are decoded into an unsigned byte and returned
// by this function
//
// If there is not a pair of valid hex digits at the head of the
// StdStringExtractor, it is left unchanged and -1 is returned
//----------------------------------------------------------------------
int StdStringExtractor::DecodeHexU8() {
SkipSpaces();
if (GetBytesLeft() < 2) {
return -1;
}
const int hi_nibble = xdigit_to_sint(m_packet[m_index]);
const int lo_nibble = xdigit_to_sint(m_packet[m_index + 1]);
if (hi_nibble == -1 || lo_nibble == -1) {
return -1;
}
m_index += 2;
return (uint8_t)((hi_nibble << 4) + lo_nibble);
}
//----------------------------------------------------------------------
// Extract an unsigned character from two hex ASCII chars in the packet
// string, or return fail_value on failure
//----------------------------------------------------------------------
uint8_t StdStringExtractor::GetHexU8(uint8_t fail_value, bool set_eof_on_fail) {
// On success, fail_value will be overwritten with the next
// character in the stream
GetHexU8Ex(fail_value, set_eof_on_fail);
return fail_value;
}
bool StdStringExtractor::GetHexU8Ex(uint8_t &ch, bool set_eof_on_fail) {
int byte = DecodeHexU8();
if (byte == -1) {
if (set_eof_on_fail || m_index >= m_packet.size())
m_index = UINT64_MAX;
// ch should not be changed in case of failure
return false;
}
ch = (uint8_t)byte;
return true;
}
uint32_t StdStringExtractor::GetU32(uint32_t fail_value, int base) {
if (m_index < m_packet.size()) {
char *end = nullptr;
const char *start = m_packet.c_str();
const char *cstr = start + m_index;
uint32_t result = static_cast<uint32_t>(::strtoul(cstr, &end, base));
if (end && end != cstr) {
m_index = end - start;
return result;
}
}
return fail_value;
}
int32_t StdStringExtractor::GetS32(int32_t fail_value, int base) {
if (m_index < m_packet.size()) {
char *end = nullptr;
const char *start = m_packet.c_str();
const char *cstr = start + m_index;
int32_t result = static_cast<int32_t>(::strtol(cstr, &end, base));
if (end && end != cstr) {
m_index = end - start;
return result;
}
}
return fail_value;
}
uint64_t StdStringExtractor::GetU64(uint64_t fail_value, int base) {
if (m_index < m_packet.size()) {
char *end = nullptr;
const char *start = m_packet.c_str();
const char *cstr = start + m_index;
uint64_t result = ::strtoull(cstr, &end, base);
if (end && end != cstr) {
m_index = end - start;
return result;
}
}
return fail_value;
}
int64_t StdStringExtractor::GetS64(int64_t fail_value, int base) {
if (m_index < m_packet.size()) {
char *end = nullptr;
const char *start = m_packet.c_str();
const char *cstr = start + m_index;
int64_t result = ::strtoll(cstr, &end, base);
if (end && end != cstr) {
m_index = end - start;
return result;
}
}
return fail_value;
}
uint32_t StdStringExtractor::GetHexMaxU32(bool little_endian,
uint32_t fail_value) {
uint32_t result = 0;
uint32_t nibble_count = 0;
SkipSpaces();
if (little_endian) {
uint32_t shift_amount = 0;
while (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
// Make sure we don't exceed the size of a uint32_t...
if (nibble_count >= (sizeof(uint32_t) * 2)) {
m_index = UINT64_MAX;
return fail_value;
}
uint8_t nibble_lo;
uint8_t nibble_hi = xdigit_to_sint(m_packet[m_index]);
++m_index;
if (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
nibble_lo = xdigit_to_sint(m_packet[m_index]);
++m_index;
result |= ((uint32_t)nibble_hi << (shift_amount + 4));
result |= ((uint32_t)nibble_lo << shift_amount);
nibble_count += 2;
shift_amount += 8;
} else {
result |= ((uint32_t)nibble_hi << shift_amount);
nibble_count += 1;
shift_amount += 4;
}
}
} else {
while (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
// Make sure we don't exceed the size of a uint32_t...
if (nibble_count >= (sizeof(uint32_t) * 2)) {
m_index = UINT64_MAX;
return fail_value;
}
uint8_t nibble = xdigit_to_sint(m_packet[m_index]);
// Big Endian
result <<= 4;
result |= nibble;
++m_index;
++nibble_count;
}
}
return result;
}
uint64_t StdStringExtractor::GetHexMaxU64(bool little_endian,
uint64_t fail_value) {
uint64_t result = 0;
uint32_t nibble_count = 0;
SkipSpaces();
if (little_endian) {
uint32_t shift_amount = 0;
while (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
// Make sure we don't exceed the size of a uint64_t...
if (nibble_count >= (sizeof(uint64_t) * 2)) {
m_index = UINT64_MAX;
return fail_value;
}
uint8_t nibble_lo;
uint8_t nibble_hi = xdigit_to_sint(m_packet[m_index]);
++m_index;
if (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
nibble_lo = xdigit_to_sint(m_packet[m_index]);
++m_index;
result |= ((uint64_t)nibble_hi << (shift_amount + 4));
result |= ((uint64_t)nibble_lo << shift_amount);
nibble_count += 2;
shift_amount += 8;
} else {
result |= ((uint64_t)nibble_hi << shift_amount);
nibble_count += 1;
shift_amount += 4;
}
}
} else {
while (m_index < m_packet.size() && ::isxdigit(m_packet[m_index])) {
// Make sure we don't exceed the size of a uint64_t...
if (nibble_count >= (sizeof(uint64_t) * 2)) {
m_index = UINT64_MAX;
return fail_value;
}
uint8_t nibble = xdigit_to_sint(m_packet[m_index]);
// Big Endian
result <<= 4;
result |= nibble;
++m_index;
++nibble_count;
}
}
return result;
}
size_t StdStringExtractor::GetHexBytes(void *dst_void, size_t dst_len,
uint8_t fail_fill_value) {
uint8_t *dst = (uint8_t *)dst_void;
size_t bytes_extracted = 0;
while (bytes_extracted < dst_len && GetBytesLeft()) {
dst[bytes_extracted] = GetHexU8(fail_fill_value);
if (IsGood())
++bytes_extracted;
else
break;
}
for (size_t i = bytes_extracted; i < dst_len; ++i)
dst[i] = fail_fill_value;
return bytes_extracted;
}
//----------------------------------------------------------------------
// Decodes all valid hex encoded bytes at the head of the
// StdStringExtractor, limited by dst_len.
//
// Returns the number of bytes successfully decoded
//----------------------------------------------------------------------
size_t StdStringExtractor::GetHexBytesAvail(void *dst_void, size_t dst_len) {
uint8_t *dst = (uint8_t *)dst_void;
size_t bytes_extracted = 0;
while (bytes_extracted < dst_len) {
int decode = DecodeHexU8();
if (decode == -1) {
break;
}
dst[bytes_extracted++] = (uint8_t)decode;
}
return bytes_extracted;
}
// Consume ASCII hex nibble character pairs until we have decoded byte_size
// bytes of data.
uint64_t StdStringExtractor::GetHexWithFixedSize(uint32_t byte_size,
bool little_endian,
uint64_t fail_value) {
if (byte_size <= 8 && GetBytesLeft() >= byte_size * 2) {
uint64_t result = 0;
uint32_t i;
if (little_endian) {
// Little Endian
uint32_t shift_amount;
for (i = 0, shift_amount = 0; i < byte_size && IsGood();
++i, shift_amount += 8) {
result |= ((uint64_t)GetHexU8() << shift_amount);
}
} else {
// Big Endian
for (i = 0; i < byte_size && IsGood(); ++i) {
result <<= 8;
result |= GetHexU8();
}
}
}
m_index = UINT64_MAX;
return fail_value;
}
size_t StdStringExtractor::GetHexByteString(std::string &str) {
str.clear();
str.reserve(GetBytesLeft() / 2);
char ch;
while ((ch = GetHexU8()) != '\0')
str.append(1, ch);
return str.size();
}
size_t StdStringExtractor::GetHexByteStringFixedLength(std::string &str,
uint32_t nibble_length) {
str.clear();
uint32_t nibble_count = 0;
for (const char *pch = Peek();
(nibble_count < nibble_length) && (pch != nullptr);
str.append(1, GetHexU8(0, false)), pch = Peek(), nibble_count += 2) {
}
return str.size();
}
size_t StdStringExtractor::GetHexByteStringTerminatedBy(std::string &str,
char terminator) {
str.clear();
char ch;
while ((ch = GetHexU8(0, false)) != '\0')
str.append(1, ch);
if (Peek() && *Peek() == terminator)
return str.size();
str.clear();
return str.size();
}
bool StdStringExtractor::GetNameColonValue(std::string &name,
std::string &value) {
// Read something in the form of NNNN:VVVV; where NNNN is any character
// that is not a colon, followed by a ':' character, then a value (one or
// more ';' chars), followed by a ';'
if (m_index < m_packet.size()) {
const size_t colon_idx = m_packet.find(':', m_index);
if (colon_idx != std::string::npos) {
const size_t semicolon_idx = m_packet.find(';', colon_idx);
if (semicolon_idx != std::string::npos) {
name.assign(m_packet, m_index, colon_idx - m_index);
value.assign(m_packet, colon_idx + 1, semicolon_idx - (colon_idx + 1));
m_index = semicolon_idx + 1;
return true;
}
}
}
m_index = UINT64_MAX;
return false;
}
void StdStringExtractor::SkipSpaces() {
const size_t n = m_packet.size();
while (m_index < n && isspace(m_packet[m_index]))
++m_index;
}
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