/src/ProtoToGif.cpp

Source
#include "ProtoToGif.h"

using namespace gifProtoFuzzer;
using namespace std;

constexpr unsigned char ProtoConverter::m_sig[];
constexpr unsigned char ProtoConverter::m_ver89a[];
constexpr unsigned char ProtoConverter::m_ver87a[];

string ProtoConverter::gifProtoToString(GifProto const &proto)
{
  visit(proto);
  return m_output.str();
}

void ProtoConverter::visit(GifProto const &gif)
{
  visit(gif.header());
  visit(gif.lsd());
  if (m_hasGCT)
    visit(gif.gct());
  for (auto const &chunk : gif.chunks())
    visit(chunk);
  visit(gif.trailer());
}

void ProtoConverter::visit(Header const &header)
{
  // Signature GIF
  m_output.write((const char *)m_sig, sizeof(m_sig));

  switch (header.ver())
  {
  case Header::ENA:
    m_output.write((const char *)m_ver89a, sizeof(m_ver89a));
    break;
  case Header::ESA:
    m_output.write((const char *)m_ver87a, sizeof(m_ver87a));
    break;
  // We simply don't write anything if it's an invalid version
  // Bytes that follow (LSD) will be interpreted as version
  case Header::INV:
    break;
  }
}

void ProtoConverter::visit(LogicalScreenDescriptor const &lsd)
{
  writeWord(extractWordFromUInt32(lsd.screenwidth()));
  writeWord(extractWordFromUInt32(lsd.screenheight()));

  uint8_t packedByte = extractByteFromUInt32(lsd.packed());
  // If MSB of packed byte is 1, GCT follows
  if (packedByte & 0x80)
  {
    m_hasGCT = true;
    // N: 2^(N+1) colors in GCT
    m_globalColorExp = packedByte & 0x07;
  }
  writeByte(packedByte);
  writeByte(extractByteFromUInt32(lsd.backgroundcolor()));
  writeByte(extractByteFromUInt32(lsd.aspectratio()));
}

void ProtoConverter::visit(GlobalColorTable const &gct)
{
  //[TODO 27/04/2019 VU]: Should it really be exactly the same size? Or do we want some deterministic randomness here?
  // TODO BS: We never overflow expected table size due to the use of min
  uint32_t tableSize = min((uint32_t)gct.colors().size(), tableExpToTableSize(m_globalColorExp));
  m_output.write(gct.colors().data(), tableSize);
}

void ProtoConverter::visit(GraphicControlExtension const &gce)
{
  writeByte(0x21); // Extension Introducer
  writeByte(0xF9); // Graphic Control Label
  writeByte(4); // Block size
  uint8_t packedByte = extractByteFromUInt32(gce.packed());
  // packed byte
  writeByte(packedByte);
  // Delay time is 2 bytes
  writeWord(extractWordFromUInt32(gce.delaytime()));
  // Transparent color index is 1 byte
  writeByte(extractByteFromUInt32(gce.transparentcolorindex()));
  writeByte(0x0); // Block Terminator
}

void ProtoConverter::visit(ImageChunk const &chunk)
{
  switch (chunk.chunk_oneof_case())
  {
  case ImageChunk::kBasic:
    visit(chunk.basic());
    break;
  case ImageChunk::kPlaintext:
    visit(chunk.plaintext());
    break;
  case ImageChunk::kAppExt:
    visit(chunk.appext());
    break;
  case ImageChunk::kComExt:
    visit(chunk.comext());
    break;
  case ImageChunk::CHUNK_ONEOF_NOT_SET:
    break;
  }
}

void ProtoConverter::visit(const BasicChunk &chunk)
{
  // Visit GCExt if necessary
  if (chunk.has_gcext())
    visit(chunk.gcext());
  visit(chunk.imdescriptor());
  if (m_hasLCT)
    visit(chunk.lct());
  visit(chunk.img());
}

void ProtoConverter::visit(LocalColorTable const &lct)
{
  //[TODO 27/04/2019 VU]: Should it really be exactly the same size? Or do we want some deterministic randomness here?
  // TODO BS: We never overflow expected table size due to the use of min
  uint32_t tableSize = min((uint32_t)lct.colors().size(), tableExpToTableSize(m_localColorExp));
  m_output.write(lct.colors().data(), tableSize);
}

void ProtoConverter::visit(ImageDescriptor const &descriptor)
{
  // TODO: Remove seperator from proto since it is always 2C
  writeByte(0x2C);
  writeWord(extractWordFromUInt32(descriptor.left()));
  writeWord(extractWordFromUInt32(descriptor.top()));
  writeWord(extractWordFromUInt32(descriptor.height()));
  writeWord(extractWordFromUInt32(descriptor.width()));
  uint8_t packedByte = extractByteFromUInt32(descriptor.packed());
  if (packedByte & 0x80)
  {
    m_hasLCT = true;
    m_localColorExp = packedByte & 0x07;
  }
  else
    m_hasLCT = false;
}

void ProtoConverter::visit(SubBlock const &block)
{
  uint8_t len = extractByteFromUInt32(block.len());
  if (len == 0)
  {
    writeByte(0x00);
  }
  else
  {
    // TODO BS: We never overflow expected block size due to the use of min
    uint32_t write_len = min((uint32_t)len, (uint32_t)block.data().size());
    m_output.write(block.data().data(), write_len);
  }
}

void ProtoConverter::visit(ImageData const &img)
{
  // TODO: Verify we are writing the image data correctly
  // LZW
  writeByte(extractByteFromUInt32(img.lzw()));
  // Sub-blocks
  for (auto const &block : img.subs())
    visit(block);
  // NULL sub block signals end of image data
  writeByte(0x00);
}

void ProtoConverter::visit(PlainTextExtension const &ptExt)
{
  // Visit GCExt if necessary
  if (ptExt.has_gcext())
    visit(ptExt.gcext());

  // First two bytes are 0x21 0x01
  writeByte(0x21);
  writeByte(0x01);
  // Skip zero bytes
  writeByte(0x00);
  for (auto const &block : ptExt.subs())
    visit(block);
  // NULL sub block signals end
  writeByte(0x00);
}

void ProtoConverter::visit(CommentExtension const &comExt)
{
  // First two bytes are 0x21 0xFE
  writeByte(0x21);
  writeByte(0xFE);
  // Sub-blocks
  for (auto const &block : comExt.subs())
    visit(block);
  // NULL sub block signals end of image data
  writeByte(0x00);
}

void ProtoConverter::visit(ApplicationExtension const &appExt)
{
  // First two bytes are 0x21 0xFF
  writeByte(0x21);
  writeByte(0xFF);
  // Next, we write "11" decimal or 0x0B
  writeByte(0x0B);
  writeLong(appExt.appid());
  // We hardcode the auth code to 1.0 or 0x31 0x2E 0x30
  writeByte(0x31);
  writeByte(0x2E);
  writeByte(0x30);
  // Sub-blocks
  for (auto const &block : appExt.subs())
    visit(block);
  // NULL sub block signals end of image data
  writeByte(0x00);
}

void ProtoConverter::visit(Trailer const &)
{
  writeByte(0x3B);
}

// =============================================================
// Utility functions
// =============================================================
void ProtoConverter::writeByte(uint8_t x)
{
  m_output.write((char *)&x, sizeof(x));
}

void ProtoConverter::writeWord(uint16_t x)
{
  m_output.write((char *)&x, sizeof(x));
}

void ProtoConverter::writeInt(uint32_t x)
{
  m_output.write((char *)&x, sizeof(x));
}

void ProtoConverter::writeLong(uint64_t x)
{
  m_output.write((char *)&x, sizeof(x));
}

uint16_t ProtoConverter::extractWordFromUInt32(uint32_t a)
{
  uint16_t first_byte = (a & 0xFF);
  uint16_t second_byte = ((a >> 8) & 0xFF) << 8;
  return first_byte | second_byte;
}

uint8_t ProtoConverter::extractByteFromUInt32(uint32_t a)
{
  uint8_t byte = a & 0x80;
  return byte;
}

/**
 * Given an exponent, returns the global/local color table size, given by 3*2^(exp+1)
 * @param tableExp The exponent
 * @return The actual color table size
 */
uint32_t ProtoConverter::tableExpToTableSize(uint32_t tableExp)
{
  // 0 <= tableExp <= 7
  // 6 <= tableSize <= 768
  uint32_t tableSize = 3 * (pow(2, tableExp + 1));
  return tableSize;
}

Coverage Report

Created: 2026-01-15 06:10

Line	Count	Source
1		#include "ProtoToGif.h"
2
3		using namespace gifProtoFuzzer;
4		using namespace std;
5
6		constexpr unsigned char ProtoConverter::m_sig[];
7		constexpr unsigned char ProtoConverter::m_ver89a[];
8		constexpr unsigned char ProtoConverter::m_ver87a[];
9
10		string ProtoConverter::gifProtoToString(GifProto const &proto)
11	991	{
12	991	visit(proto);
13	991	return m_output.str();
14	991	}
15
16		void ProtoConverter::visit(GifProto const &gif)
17	991	{
18	991	visit(gif.header());
19	991	visit(gif.lsd());
20	991	if (m_hasGCT)
21	195	visit(gif.gct());
22	991	for (auto const &chunk : gif.chunks())
23	5.32k	visit(chunk);
24	991	visit(gif.trailer());
25	991	}
26
27		void ProtoConverter::visit(Header const &header)
28	991	{
29		// Signature GIF
30	991	m_output.write((const char *)m_sig, sizeof(m_sig));
31
32	991	switch (header.ver())
33	991	{
34	603	case Header::ENA:
35	603	m_output.write((const char *)m_ver89a, sizeof(m_ver89a));
36	603	break;
37	94	case Header::ESA:
38	94	m_output.write((const char *)m_ver87a, sizeof(m_ver87a));
39	94	break;
40		// We simply don't write anything if it's an invalid version
41		// Bytes that follow (LSD) will be interpreted as version
42	294	case Header::INV:
43	294	break;
44	991	}
45	991	}
46
47		void ProtoConverter::visit(LogicalScreenDescriptor const &lsd)
48	991	{
49	991	writeWord(extractWordFromUInt32(lsd.screenwidth()));
50	991	writeWord(extractWordFromUInt32(lsd.screenheight()));
51
52	991	uint8_t packedByte = extractByteFromUInt32(lsd.packed());
53		// If MSB of packed byte is 1, GCT follows
54	991	if (packedByte & 0x80)
55	195	{
56	195	m_hasGCT = true;
57		// N: 2^(N+1) colors in GCT
58	195	m_globalColorExp = packedByte & 0x07;
59	195	}
60	991	writeByte(packedByte);
61	991	writeByte(extractByteFromUInt32(lsd.backgroundcolor()));
62	991	writeByte(extractByteFromUInt32(lsd.aspectratio()));
63	991	}
64
65		void ProtoConverter::visit(GlobalColorTable const &gct)
66	195	{
67		//[TODO 27/04/2019 VU]: Should it really be exactly the same size? Or do we want some deterministic randomness here?
68		// TODO BS: We never overflow expected table size due to the use of min
69	195	uint32_t tableSize = min((uint32_t)gct.colors().size(), tableExpToTableSize(m_globalColorExp));
70	195	m_output.write(gct.colors().data(), tableSize);
71	195	}
72
73		void ProtoConverter::visit(GraphicControlExtension const &gce)
74	421	{
75	421	writeByte(0x21); // Extension Introducer
76	421	writeByte(0xF9); // Graphic Control Label
77	421	writeByte(4); // Block size
78	421	uint8_t packedByte = extractByteFromUInt32(gce.packed());
79		// packed byte
80	421	writeByte(packedByte);
81		// Delay time is 2 bytes
82	421	writeWord(extractWordFromUInt32(gce.delaytime()));
83		// Transparent color index is 1 byte
84	421	writeByte(extractByteFromUInt32(gce.transparentcolorindex()));
85	421	writeByte(0x0); // Block Terminator
86	421	}
87
88		void ProtoConverter::visit(ImageChunk const &chunk)
89	5.32k	{
90	5.32k	switch (chunk.chunk_oneof_case())
91	5.32k	{
92	1.72k	case ImageChunk::kBasic:
93	1.72k	visit(chunk.basic());
94	1.72k	break;
95	981	case ImageChunk::kPlaintext:
96	981	visit(chunk.plaintext());
97	981	break;
98	1.32k	case ImageChunk::kAppExt:
99	1.32k	visit(chunk.appext());
100	1.32k	break;
101	633	case ImageChunk::kComExt:
102	633	visit(chunk.comext());
103	633	break;
104	654	case ImageChunk::CHUNK_ONEOF_NOT_SET:
105	654	break;
106	5.32k	}
107	5.32k	}
108
109		void ProtoConverter::visit(const BasicChunk &chunk)
110	1.72k	{
111		// Visit GCExt if necessary
112	1.72k	if (chunk.has_gcext())
113	207	visit(chunk.gcext());
114	1.72k	visit(chunk.imdescriptor());
115	1.72k	if (m_hasLCT)
116	711	visit(chunk.lct());
117	1.72k	visit(chunk.img());
118	1.72k	}
119
120		void ProtoConverter::visit(LocalColorTable const &lct)
121	711	{
122		//[TODO 27/04/2019 VU]: Should it really be exactly the same size? Or do we want some deterministic randomness here?
123		// TODO BS: We never overflow expected table size due to the use of min
124	711	uint32_t tableSize = min((uint32_t)lct.colors().size(), tableExpToTableSize(m_localColorExp));
125	711	m_output.write(lct.colors().data(), tableSize);
126	711	}
127
128		void ProtoConverter::visit(ImageDescriptor const &descriptor)
129	1.72k	{
130		// TODO: Remove seperator from proto since it is always 2C
131	1.72k	writeByte(0x2C);
132	1.72k	writeWord(extractWordFromUInt32(descriptor.left()));
133	1.72k	writeWord(extractWordFromUInt32(descriptor.top()));
134	1.72k	writeWord(extractWordFromUInt32(descriptor.height()));
135	1.72k	writeWord(extractWordFromUInt32(descriptor.width()));
136	1.72k	uint8_t packedByte = extractByteFromUInt32(descriptor.packed());
137	1.72k	if (packedByte & 0x80)
138	711	{
139	711	m_hasLCT = true;
140	711	m_localColorExp = packedByte & 0x07;
141	711	}
142	1.01k	else
143	1.01k	m_hasLCT = false;
144	1.72k	}
145
146		void ProtoConverter::visit(SubBlock const &block)
147	26.2k	{
148	26.2k	uint8_t len = extractByteFromUInt32(block.len());
149	26.2k	if (len == 0)
150	2.22k	{
151	2.22k	writeByte(0x00);
152	2.22k	}
153	24.0k	else
154	24.0k	{
155		// TODO BS: We never overflow expected block size due to the use of min
156	24.0k	uint32_t write_len = min((uint32_t)len, (uint32_t)block.data().size());
157	24.0k	m_output.write(block.data().data(), write_len);
158	24.0k	}
159	26.2k	}
160
161		void ProtoConverter::visit(ImageData const &img)
162	1.72k	{
163		// TODO: Verify we are writing the image data correctly
164		// LZW
165	1.72k	writeByte(extractByteFromUInt32(img.lzw()));
166		// Sub-blocks
167	1.72k	for (auto const &block : img.subs())
168	1.22k	visit(block);
169		// NULL sub block signals end of image data
170	1.72k	writeByte(0x00);
171	1.72k	}
172
173		void ProtoConverter::visit(PlainTextExtension const &ptExt)
174	981	{
175		// Visit GCExt if necessary
176	981	if (ptExt.has_gcext())
177	214	visit(ptExt.gcext());
178
179		// First two bytes are 0x21 0x01
180	981	writeByte(0x21);
181	981	writeByte(0x01);
182		// Skip zero bytes
183	981	writeByte(0x00);
184	981	for (auto const &block : ptExt.subs())
185	9.71k	visit(block);
186		// NULL sub block signals end
187	981	writeByte(0x00);
188	981	}
189
190		void ProtoConverter::visit(CommentExtension const &comExt)
191	633	{
192		// First two bytes are 0x21 0xFE
193	633	writeByte(0x21);
194	633	writeByte(0xFE);
195		// Sub-blocks
196	633	for (auto const &block : comExt.subs())
197	12.9k	visit(block);
198		// NULL sub block signals end of image data
199	633	writeByte(0x00);
200	633	}
201
202		void ProtoConverter::visit(ApplicationExtension const &appExt)
203	1.32k	{
204		// First two bytes are 0x21 0xFF
205	1.32k	writeByte(0x21);
206	1.32k	writeByte(0xFF);
207		// Next, we write "11" decimal or 0x0B
208	1.32k	writeByte(0x0B);
209	1.32k	writeLong(appExt.appid());
210		// We hardcode the auth code to 1.0 or 0x31 0x2E 0x30
211	1.32k	writeByte(0x31);
212	1.32k	writeByte(0x2E);
213	1.32k	writeByte(0x30);
214		// Sub-blocks
215	1.32k	for (auto const &block : appExt.subs())
216	2.31k	visit(block);
217		// NULL sub block signals end of image data
218	1.32k	writeByte(0x00);
219	1.32k	}
220
221		void ProtoConverter::visit(Trailer const &)
222	991	{
223	991	writeByte(0x3B);
224	991	}
225
226		// =============================================================
227		// Utility functions
228		// =============================================================
229		void ProtoConverter::writeByte(uint8_t x)
230	28.9k	{
231	28.9k	m_output.write((char *)&x, sizeof(x));
232	28.9k	}
233
234		void ProtoConverter::writeWord(uint16_t x)
235	9.31k	{
236	9.31k	m_output.write((char *)&x, sizeof(x));
237	9.31k	}
238
239		void ProtoConverter::writeInt(uint32_t x)
240	0	{
241	0	m_output.write((char *)&x, sizeof(x));
242	0	}
243
244		void ProtoConverter::writeLong(uint64_t x)
245	1.32k	{
246	1.32k	m_output.write((char *)&x, sizeof(x));
247	1.32k	}
248
249		uint16_t ProtoConverter::extractWordFromUInt32(uint32_t a)
250	9.31k	{
251	9.31k	uint16_t first_byte = (a & 0xFF);
252	9.31k	uint16_t second_byte = ((a >> 8) & 0xFF) << 8;
253	9.31k	return first_byte \| second_byte;
254	9.31k	}
255
256		uint8_t ProtoConverter::extractByteFromUInt32(uint32_t a)
257	33.5k	{
258	33.5k	uint8_t byte = a & 0x80;
259	33.5k	return byte;
260	33.5k	}
261
262		/**
263		* Given an exponent, returns the global/local color table size, given by 3*2^(exp+1)
264		* @param tableExp The exponent
265		* @return The actual color table size
266		*/
267		uint32_t ProtoConverter::tableExpToTableSize(uint32_t tableExp)
268	906	{
269		// 0 <= tableExp <= 7
270		// 6 <= tableSize <= 768
271	906	uint32_t tableSize = 3 * (pow(2, tableExp + 1));
272	906	return tableSize;
273	906	}