Source/cmCryptoHash.cxx - third_party/cmake - Git at Google

 /* Distributed under the OSI-approved BSD 3-Clause License.  See accompanying
    file Copyright.txt or https://cmake.org/licensing for details.  */
 #include "cmCryptoHash.h"

 #include "cm_sha2.h"

 #include <cmsys/FStream.hxx>
 #include <cmsys/MD5.h>
 #include <string.h>

 CM_AUTO_PTR<cmCryptoHash> cmCryptoHash::New(const char* algo)
 {
   if (strcmp(algo, "MD5") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashMD5);
   }
   if (strcmp(algo, "SHA1") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA1);
   }
   if (strcmp(algo, "SHA224") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA224);
   }
   if (strcmp(algo, "SHA256") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA256);
   }
   if (strcmp(algo, "SHA384") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA384);
   }
   if (strcmp(algo, "SHA512") == 0) {
     return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA512);
   }
   return CM_AUTO_PTR<cmCryptoHash>(CM_NULLPTR);
 }

 bool cmCryptoHash::IntFromHexDigit(char input, char& output)
 {
   if (input >= '0' && input <= '9') {
     output = char(input - '0');
     return true;
   }
   if (input >= 'a' && input <= 'f') {
     output = char(input - 'a' + 0xA);
     return true;
   }
   if (input >= 'A' && input <= 'F') {
     output = char(input - 'A' + 0xA);
     return true;
   }
   return false;
 }

 std::string cmCryptoHash::ByteHashToString(
   const std::vector<unsigned char>& hash)
 {
   // Map from 4-bit index to hexadecimal representation.
   static char const hex[16] = { '0', '1', '2', '3', '4', '5', '6', '7',
                                 '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };

   std::string res;
   for (std::vector<unsigned char>::const_iterator vit = hash.begin();
        vit != hash.end(); ++vit) {
     res.push_back(hex[(*vit) >> 4]);
     res.push_back(hex[(*vit) & 0xF]);
   }
   return res;
 }

 std::vector<unsigned char> cmCryptoHash::ByteHashString(
   const std::string& input)
 {
   this->Initialize();
   this->Append(reinterpret_cast<unsigned char const*>(input.c_str()),
                static_cast<int>(input.size()));
   return this->Finalize();
 }

 std::vector<unsigned char> cmCryptoHash::ByteHashFile(const std::string& file)
 {
   cmsys::ifstream fin(file.c_str(), std::ios::in | std::ios::binary);
   if (fin) {
     this->Initialize();
     {
       // Should be efficient enough on most system:
       cm_sha2_uint64_t buffer[512];
       char* buffer_c = reinterpret_cast<char*>(buffer);
       unsigned char const* buffer_uc =
         reinterpret_cast<unsigned char const*>(buffer);
       // This copy loop is very sensitive on certain platforms with
       // slightly broken stream libraries (like HPUX).  Normally, it is
       // incorrect to not check the error condition on the fin.read()
       // before using the data, but the fin.gcount() will be zero if an
       // error occurred.  Therefore, the loop should be safe everywhere.
       while (fin) {
         fin.read(buffer_c, sizeof(buffer));
         if (int gcount = static_cast<int>(fin.gcount())) {
           this->Append(buffer_uc, gcount);
         }
       }
     }
     if (fin.eof()) {
       // Success
       return this->Finalize();
     }
     // Finalize anyway
     this->Finalize();
   }
   // Return without success
   return std::vector<unsigned char>();
 }

 std::string cmCryptoHash::HashString(const std::string& input)
 {
   return ByteHashToString(this->ByteHashString(input));
 }

 std::string cmCryptoHash::HashFile(const std::string& file)
 {
   return ByteHashToString(this->ByteHashFile(file));
 }

 cmCryptoHashMD5::cmCryptoHashMD5()
   : MD5(cmsysMD5_New())
 {
 }

 cmCryptoHashMD5::~cmCryptoHashMD5()
 {
   cmsysMD5_Delete(this->MD5);
 }

 void cmCryptoHashMD5::Initialize()
 {
   cmsysMD5_Initialize(this->MD5);
 }

 void cmCryptoHashMD5::Append(unsigned char const* buf, int sz)
 {
   cmsysMD5_Append(this->MD5, buf, sz);
 }

 std::vector<unsigned char> cmCryptoHashMD5::Finalize()
 {
   std::vector<unsigned char> hash(16, 0);
   cmsysMD5_Finalize(this->MD5, &hash[0]);
   return hash;
 }

 #define cmCryptoHash_SHA_CLASS_IMPL(SHA)                                      \
   cmCryptoHash##SHA::cmCryptoHash##SHA()                                      \
     : SHA(new SHA_CTX)                                                        \
   {                                                                           \
   }                                                                           \
   cmCryptoHash##SHA::~cmCryptoHash##SHA() { delete this->SHA; }               \
   void cmCryptoHash##SHA::Initialize() { SHA##_Init(this->SHA); }             \
   void cmCryptoHash##SHA::Append(unsigned char const* buf, int sz)            \
   {                                                                           \
     SHA##_Update(this->SHA, buf, sz);                                         \
   }                                                                           \
   std::vector<unsigned char> cmCryptoHash##SHA::Finalize()                    \
   {                                                                           \
     std::vector<unsigned char> hash(SHA##_DIGEST_LENGTH, 0);                  \
     SHA##_Final(&hash[0], this->SHA);                                         \
     return hash;                                                              \
   }

 cmCryptoHash_SHA_CLASS_IMPL(SHA1) cmCryptoHash_SHA_CLASS_IMPL(SHA224)
   cmCryptoHash_SHA_CLASS_IMPL(SHA256) cmCryptoHash_SHA_CLASS_IMPL(SHA384)
     cmCryptoHash_SHA_CLASS_IMPL(SHA512)
	/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
	file Copyright.txt or https://cmake.org/licensing for details. */
	#include "cmCryptoHash.h"

	#include "cm_sha2.h"

	#include <cmsys/FStream.hxx>
	#include <cmsys/MD5.h>
	#include <string.h>

	CM_AUTO_PTR<cmCryptoHash> cmCryptoHash::New(const char* algo)
	{
	if (strcmp(algo, "MD5") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashMD5);
	}
	if (strcmp(algo, "SHA1") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA1);
	}
	if (strcmp(algo, "SHA224") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA224);
	}
	if (strcmp(algo, "SHA256") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA256);
	}
	if (strcmp(algo, "SHA384") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA384);
	}
	if (strcmp(algo, "SHA512") == 0) {
	return CM_AUTO_PTR<cmCryptoHash>(new cmCryptoHashSHA512);
	}
	return CM_AUTO_PTR<cmCryptoHash>(CM_NULLPTR);
	}

	bool cmCryptoHash::IntFromHexDigit(char input, char& output)
	{
	if (input >= '0' && input <= '9') {
	output = char(input - '0');
	return true;
	}
	if (input >= 'a' && input <= 'f') {
	output = char(input - 'a' + 0xA);
	return true;
	}
	if (input >= 'A' && input <= 'F') {
	output = char(input - 'A' + 0xA);
	return true;
	}
	return false;
	}

	std::string cmCryptoHash::ByteHashToString(
	const std::vector<unsigned char>& hash)
	{
	// Map from 4-bit index to hexadecimal representation.
	static char const hex[16] = { '0', '1', '2', '3', '4', '5', '6', '7',
	'8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };

	std::string res;
	for (std::vector<unsigned char>::const_iterator vit = hash.begin();
	vit != hash.end(); ++vit) {
	res.push_back(hex[(*vit) >> 4]);
	res.push_back(hex[(*vit) & 0xF]);
	}
	return res;
	}

	std::vector<unsigned char> cmCryptoHash::ByteHashString(
	const std::string& input)
	{
	this->Initialize();
	this->Append(reinterpret_cast<unsigned char const*>(input.c_str()),
	static_cast<int>(input.size()));
	return this->Finalize();
	}

	std::vector<unsigned char> cmCryptoHash::ByteHashFile(const std::string& file)
	{
	cmsys::ifstream fin(file.c_str(), std::ios::in \| std::ios::binary);
	if (fin) {
	this->Initialize();
	{
	// Should be efficient enough on most system:
	cm_sha2_uint64_t buffer[512];
	char* buffer_c = reinterpret_cast<char*>(buffer);
	unsigned char const* buffer_uc =
	reinterpret_cast<unsigned char const*>(buffer);
	// This copy loop is very sensitive on certain platforms with
	// slightly broken stream libraries (like HPUX). Normally, it is
	// incorrect to not check the error condition on the fin.read()
	// before using the data, but the fin.gcount() will be zero if an
	// error occurred. Therefore, the loop should be safe everywhere.
	while (fin) {
	fin.read(buffer_c, sizeof(buffer));
	if (int gcount = static_cast<int>(fin.gcount())) {
	this->Append(buffer_uc, gcount);
	}
	}
	}
	if (fin.eof()) {
	// Success
	return this->Finalize();
	}
	// Finalize anyway
	this->Finalize();
	}
	// Return without success
	return std::vector<unsigned char>();
	}

	std::string cmCryptoHash::HashString(const std::string& input)
	{
	return ByteHashToString(this->ByteHashString(input));
	}

	std::string cmCryptoHash::HashFile(const std::string& file)
	{
	return ByteHashToString(this->ByteHashFile(file));
	}

	cmCryptoHashMD5::cmCryptoHashMD5()
	: MD5(cmsysMD5_New())
	{
	}

	cmCryptoHashMD5::~cmCryptoHashMD5()
	{
	cmsysMD5_Delete(this->MD5);
	}

	void cmCryptoHashMD5::Initialize()
	{
	cmsysMD5_Initialize(this->MD5);
	}

	void cmCryptoHashMD5::Append(unsigned char const* buf, int sz)
	{
	cmsysMD5_Append(this->MD5, buf, sz);
	}

	std::vector<unsigned char> cmCryptoHashMD5::Finalize()
	{
	std::vector<unsigned char> hash(16, 0);
	cmsysMD5_Finalize(this->MD5, &hash[0]);
	return hash;
	}

	#define cmCryptoHash_SHA_CLASS_IMPL(SHA) \
	cmCryptoHash##SHA::cmCryptoHash##SHA() \
	: SHA(new SHA_CTX) \
	{ \
	} \
	cmCryptoHash##SHA::~cmCryptoHash##SHA() { delete this->SHA; } \
	void cmCryptoHash##SHA::Initialize() { SHA##_Init(this->SHA); } \
	void cmCryptoHash##SHA::Append(unsigned char const* buf, int sz) \
	{ \
	SHA##_Update(this->SHA, buf, sz); \
	} \
	std::vector<unsigned char> cmCryptoHash##SHA::Finalize() \
	{ \
	std::vector<unsigned char> hash(SHA##_DIGEST_LENGTH, 0); \
	SHA##_Final(&hash[0], this->SHA); \
	return hash; \
	}

	cmCryptoHash_SHA_CLASS_IMPL(SHA1) cmCryptoHash_SHA_CLASS_IMPL(SHA224)
	cmCryptoHash_SHA_CLASS_IMPL(SHA256) cmCryptoHash_SHA_CLASS_IMPL(SHA384)
	cmCryptoHash_SHA_CLASS_IMPL(SHA512)