lldb/test/API/macosx/arm-corefile-regctx/create-arm-corefiles.cpp - llvm-project - Git at Google

 #include <mach-o/loader.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string>
 #include <vector>


 // Normally these are picked up by including <mach/thread_status.h>
 // but that does a compile time check for the build host arch and
 // only defines the ARM register context constants when building on
 // an arm system.  We're creating fake corefiles, and might be
 // creating them on an intel system.
 #define ARM_THREAD_STATE 1
 #define ARM_THREAD_STATE_COUNT 17
 #define ARM_EXCEPTION_STATE 3
 #define ARM_EXCEPTION_STATE_COUNT 3
 #define ARM_THREAD_STATE64 6
 #define ARM_THREAD_STATE64_COUNT 68
 #define ARM_EXCEPTION_STATE64 7
 #define ARM_EXCEPTION_STATE64_COUNT 4


 union uint32_buf {
   uint8_t bytebuf[4];
   uint32_t val;
 };

 union uint64_buf {
   uint8_t bytebuf[8];
   uint64_t val;
 };

 void add_uint64(std::vector<uint8_t> &buf, uint64_t val) {
   uint64_buf conv;
   conv.val = val;
   for (int i = 0; i < 8; i++)
     buf.push_back(conv.bytebuf[i]);
 }

 void add_uint32(std::vector<uint8_t> &buf, uint32_t val) {
   uint32_buf conv;
   conv.val = val;
   for (int i = 0; i < 4; i++)
     buf.push_back(conv.bytebuf[i]);
 }

 std::vector<uint8_t> armv7_lc_thread_load_command() {
   std::vector<uint8_t> data;
   add_uint32(data, LC_THREAD);              // thread_command.cmd
   add_uint32(data, 104);                    // thread_command.cmdsize
   add_uint32(data, ARM_THREAD_STATE);       // thread_command.flavor
   add_uint32(data, ARM_THREAD_STATE_COUNT); // thread_command.count
   add_uint32(data, 0x00010000);             // r0
   add_uint32(data, 0x00020000);             // r1
   add_uint32(data, 0x00030000);             // r2
   add_uint32(data, 0x00040000);             // r3
   add_uint32(data, 0x00050000);             // r4
   add_uint32(data, 0x00060000);             // r5
   add_uint32(data, 0x00070000);             // r6
   add_uint32(data, 0x00080000);             // r7
   add_uint32(data, 0x00090000);             // r8
   add_uint32(data, 0x000a0000);             // r9
   add_uint32(data, 0x000b0000);             // r10
   add_uint32(data, 0x000c0000);             // r11
   add_uint32(data, 0x000d0000);             // r12
   add_uint32(data, 0x000e0000);             // sp
   add_uint32(data, 0x000f0000);             // lr
   add_uint32(data, 0x00100000);             // pc
   add_uint32(data, 0x00110000);             // cpsr

   add_uint32(data, ARM_EXCEPTION_STATE);       // thread_command.flavor
   add_uint32(data, ARM_EXCEPTION_STATE_COUNT); // thread_command.count
   add_uint32(data, 0x00003f5c);                // far
   add_uint32(data, 0xf2000000);                // esr
   add_uint32(data, 0x00000000);                // exception

   return data;
 }

 std::vector<uint8_t> arm64_lc_thread_load_command() {
   std::vector<uint8_t> data;
   add_uint32(data, LC_THREAD);                // thread_command.cmd
   add_uint32(data, 312);                      // thread_command.cmdsize
   add_uint32(data, ARM_THREAD_STATE64);       // thread_command.flavor
   add_uint32(data, ARM_THREAD_STATE64_COUNT); // thread_command.count
   add_uint64(data, 0x0000000000000001);       // x0
   add_uint64(data, 0x000000016fdff3c0);       // x1
   add_uint64(data, 0x000000016fdff3d0);       // x2
   add_uint64(data, 0x000000016fdff510);       // x3
   add_uint64(data, 0x0000000000000000);       // x4
   add_uint64(data, 0x0000000000000000);       // x5
   add_uint64(data, 0x0000000000000000);       // x6
   add_uint64(data, 0x0000000000000000);       // x7
   add_uint64(data, 0x000000010000d910);       // x8
   add_uint64(data, 0x0000000000000001);       // x9
   add_uint64(data, 0xe1e88de000000000);       // x10
   add_uint64(data, 0x0000000000000003);       // x11
   add_uint64(data, 0x0000000000000148);       // x12
   add_uint64(data, 0x0000000000004000);       // x13
   add_uint64(data, 0x0000000000000008);       // x14
   add_uint64(data, 0x0000000000000000);       // x15
   add_uint64(data, 0x0000000000000000);       // x16
   add_uint64(data, 0x0000000100003f5c);       // x17
   add_uint64(data, 0x0000000000000000);       // x18
   add_uint64(data, 0x0000000100003f5c);       // x19
   add_uint64(data, 0x000000010000c000);       // x20
   add_uint64(data, 0x000000010000d910);       // x21
   add_uint64(data, 0x000000016fdff250);       // x22
   add_uint64(data, 0x000000018ce12366);       // x23
   add_uint64(data, 0x000000016fdff1d0);       // x24
   add_uint64(data, 0x0000000000000001);       // x25
   add_uint64(data, 0x0000000000000000);       // x26
   add_uint64(data, 0x0000000000000000);       // x27
   add_uint64(data, 0x0000000000000000);       // x28
   add_uint64(data, 0x000000016fdff3a0);       // fp
   add_uint64(data, 0x000000018cd97f28);       // lr
   add_uint64(data, 0x000000016fdff140);       // sp
   add_uint64(data, 0x0000000100003f5c);       // pc
   add_uint32(data, 0x80001000);               // cpsr

   add_uint32(data, 0x00000000); // padding

   add_uint32(data, ARM_EXCEPTION_STATE64);       // thread_command.flavor
   add_uint32(data, ARM_EXCEPTION_STATE64_COUNT); // thread_command.count
   add_uint64(data, 0x0000000100003f5c);          // far
   add_uint32(data, 0xf2000000);                  // esr
   add_uint32(data, 0x00000000);                  // exception

   return data;
 }

 enum arch { unspecified, armv7, arm64 };

 int main(int argc, char **argv) {
   if (argc != 3) {
     fprintf(stderr,
             "usage: create-arm-corefiles [armv7|arm64] <output-core-name>\n");
     exit(1);
   }

   arch arch = unspecified;

   if (strcmp(argv[1], "armv7") == 0)
     arch = armv7;
   else if (strcmp(argv[1], "arm64") == 0)
     arch = arm64;
   else {
     fprintf(stderr, "unrecognized architecture %s\n", argv[1]);
     exit(1);
   }

   // An array of load commands (in the form of byte arrays)
   std::vector<std::vector<uint8_t>> load_commands;

   // An array of corefile contents (page data, lc_note data, etc)
   std::vector<uint8_t> payload;

   // First add all the load commands / payload so we can figure out how large
   // the load commands will actually be.
   if (arch == armv7)
     load_commands.push_back(armv7_lc_thread_load_command());
   else if (arch == arm64)
     load_commands.push_back(arm64_lc_thread_load_command());

   int size_of_load_commands = 0;
   for (const auto &lc : load_commands)
     size_of_load_commands += lc.size();

   int header_and_load_cmd_room =
       sizeof(struct mach_header_64) + size_of_load_commands;

   // Erase the load commands / payload now that we know how much space is
   // needed, redo it.
   load_commands.clear();
   payload.clear();

   if (arch == armv7)
     load_commands.push_back(armv7_lc_thread_load_command());
   else if (arch == arm64)
     load_commands.push_back(arm64_lc_thread_load_command());

   struct mach_header_64 mh;
   mh.magic = MH_MAGIC_64;
   if (arch == armv7) {
     mh.cputype = CPU_TYPE_ARM;
     mh.cpusubtype = CPU_SUBTYPE_ARM_V7M;
   } else if (arch == arm64) {
     mh.cputype = CPU_TYPE_ARM64;
     mh.cpusubtype = CPU_SUBTYPE_ARM64_ALL;
   }
   mh.filetype = MH_CORE;
   mh.ncmds = load_commands.size();
   mh.sizeofcmds = size_of_load_commands;
   mh.flags = 0;
   mh.reserved = 0;

   FILE *f = fopen(argv[2], "w");

   if (f == nullptr) {
     fprintf(stderr, "Unable to open file %s for writing\n", argv[2]);
     exit(1);
   }

   fwrite(&mh, sizeof(struct mach_header_64), 1, f);

   for (const auto &lc : load_commands)
     fwrite(lc.data(), lc.size(), 1, f);

   fseek(f, header_and_load_cmd_room, SEEK_SET);

   fwrite(payload.data(), payload.size(), 1, f);

   fclose(f);
 }
	#include <mach-o/loader.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string>
	#include <vector>


	// Normally these are picked up by including <mach/thread_status.h>
	// but that does a compile time check for the build host arch and
	// only defines the ARM register context constants when building on
	// an arm system. We're creating fake corefiles, and might be
	// creating them on an intel system.
	#define ARM_THREAD_STATE 1
	#define ARM_THREAD_STATE_COUNT 17
	#define ARM_EXCEPTION_STATE 3
	#define ARM_EXCEPTION_STATE_COUNT 3
	#define ARM_THREAD_STATE64 6
	#define ARM_THREAD_STATE64_COUNT 68
	#define ARM_EXCEPTION_STATE64 7
	#define ARM_EXCEPTION_STATE64_COUNT 4


	union uint32_buf {
	uint8_t bytebuf[4];
	uint32_t val;
	};

	union uint64_buf {
	uint8_t bytebuf[8];
	uint64_t val;
	};

	void add_uint64(std::vector<uint8_t> &buf, uint64_t val) {
	uint64_buf conv;
	conv.val = val;
	for (int i = 0; i < 8; i++)
	buf.push_back(conv.bytebuf[i]);
	}

	void add_uint32(std::vector<uint8_t> &buf, uint32_t val) {
	uint32_buf conv;
	conv.val = val;
	for (int i = 0; i < 4; i++)
	buf.push_back(conv.bytebuf[i]);
	}

	std::vector<uint8_t> armv7_lc_thread_load_command() {
	std::vector<uint8_t> data;
	add_uint32(data, LC_THREAD); // thread_command.cmd
	add_uint32(data, 104); // thread_command.cmdsize
	add_uint32(data, ARM_THREAD_STATE); // thread_command.flavor
	add_uint32(data, ARM_THREAD_STATE_COUNT); // thread_command.count
	add_uint32(data, 0x00010000); // r0
	add_uint32(data, 0x00020000); // r1
	add_uint32(data, 0x00030000); // r2
	add_uint32(data, 0x00040000); // r3
	add_uint32(data, 0x00050000); // r4
	add_uint32(data, 0x00060000); // r5
	add_uint32(data, 0x00070000); // r6
	add_uint32(data, 0x00080000); // r7
	add_uint32(data, 0x00090000); // r8
	add_uint32(data, 0x000a0000); // r9
	add_uint32(data, 0x000b0000); // r10
	add_uint32(data, 0x000c0000); // r11
	add_uint32(data, 0x000d0000); // r12
	add_uint32(data, 0x000e0000); // sp
	add_uint32(data, 0x000f0000); // lr
	add_uint32(data, 0x00100000); // pc
	add_uint32(data, 0x00110000); // cpsr

	add_uint32(data, ARM_EXCEPTION_STATE); // thread_command.flavor
	add_uint32(data, ARM_EXCEPTION_STATE_COUNT); // thread_command.count
	add_uint32(data, 0x00003f5c); // far
	add_uint32(data, 0xf2000000); // esr
	add_uint32(data, 0x00000000); // exception

	return data;
	}

	std::vector<uint8_t> arm64_lc_thread_load_command() {
	std::vector<uint8_t> data;
	add_uint32(data, LC_THREAD); // thread_command.cmd
	add_uint32(data, 312); // thread_command.cmdsize
	add_uint32(data, ARM_THREAD_STATE64); // thread_command.flavor
	add_uint32(data, ARM_THREAD_STATE64_COUNT); // thread_command.count
	add_uint64(data, 0x0000000000000001); // x0
	add_uint64(data, 0x000000016fdff3c0); // x1
	add_uint64(data, 0x000000016fdff3d0); // x2
	add_uint64(data, 0x000000016fdff510); // x3
	add_uint64(data, 0x0000000000000000); // x4
	add_uint64(data, 0x0000000000000000); // x5
	add_uint64(data, 0x0000000000000000); // x6
	add_uint64(data, 0x0000000000000000); // x7
	add_uint64(data, 0x000000010000d910); // x8
	add_uint64(data, 0x0000000000000001); // x9
	add_uint64(data, 0xe1e88de000000000); // x10
	add_uint64(data, 0x0000000000000003); // x11
	add_uint64(data, 0x0000000000000148); // x12
	add_uint64(data, 0x0000000000004000); // x13
	add_uint64(data, 0x0000000000000008); // x14
	add_uint64(data, 0x0000000000000000); // x15
	add_uint64(data, 0x0000000000000000); // x16
	add_uint64(data, 0x0000000100003f5c); // x17
	add_uint64(data, 0x0000000000000000); // x18
	add_uint64(data, 0x0000000100003f5c); // x19
	add_uint64(data, 0x000000010000c000); // x20
	add_uint64(data, 0x000000010000d910); // x21
	add_uint64(data, 0x000000016fdff250); // x22
	add_uint64(data, 0x000000018ce12366); // x23
	add_uint64(data, 0x000000016fdff1d0); // x24
	add_uint64(data, 0x0000000000000001); // x25
	add_uint64(data, 0x0000000000000000); // x26
	add_uint64(data, 0x0000000000000000); // x27
	add_uint64(data, 0x0000000000000000); // x28
	add_uint64(data, 0x000000016fdff3a0); // fp
	add_uint64(data, 0x000000018cd97f28); // lr
	add_uint64(data, 0x000000016fdff140); // sp
	add_uint64(data, 0x0000000100003f5c); // pc
	add_uint32(data, 0x80001000); // cpsr

	add_uint32(data, 0x00000000); // padding

	add_uint32(data, ARM_EXCEPTION_STATE64); // thread_command.flavor
	add_uint32(data, ARM_EXCEPTION_STATE64_COUNT); // thread_command.count
	add_uint64(data, 0x0000000100003f5c); // far
	add_uint32(data, 0xf2000000); // esr
	add_uint32(data, 0x00000000); // exception

	return data;
	}

	enum arch { unspecified, armv7, arm64 };

	int main(int argc, char **argv) {
	if (argc != 3) {
	fprintf(stderr,
	"usage: create-arm-corefiles [armv7\|arm64] <output-core-name>\n");
	exit(1);
	}

	arch arch = unspecified;

	if (strcmp(argv[1], "armv7") == 0)
	arch = armv7;
	else if (strcmp(argv[1], "arm64") == 0)
	arch = arm64;
	else {
	fprintf(stderr, "unrecognized architecture %s\n", argv[1]);
	exit(1);
	}

	// An array of load commands (in the form of byte arrays)
	std::vector<std::vector<uint8_t>> load_commands;

	// An array of corefile contents (page data, lc_note data, etc)
	std::vector<uint8_t> payload;

	// First add all the load commands / payload so we can figure out how large
	// the load commands will actually be.
	if (arch == armv7)
	load_commands.push_back(armv7_lc_thread_load_command());
	else if (arch == arm64)
	load_commands.push_back(arm64_lc_thread_load_command());

	int size_of_load_commands = 0;
	for (const auto &lc : load_commands)
	size_of_load_commands += lc.size();

	int header_and_load_cmd_room =
	sizeof(struct mach_header_64) + size_of_load_commands;

	// Erase the load commands / payload now that we know how much space is
	// needed, redo it.
	load_commands.clear();
	payload.clear();

	if (arch == armv7)
	load_commands.push_back(armv7_lc_thread_load_command());
	else if (arch == arm64)
	load_commands.push_back(arm64_lc_thread_load_command());

	struct mach_header_64 mh;
	mh.magic = MH_MAGIC_64;
	if (arch == armv7) {
	mh.cputype = CPU_TYPE_ARM;
	mh.cpusubtype = CPU_SUBTYPE_ARM_V7M;
	} else if (arch == arm64) {
	mh.cputype = CPU_TYPE_ARM64;
	mh.cpusubtype = CPU_SUBTYPE_ARM64_ALL;
	}
	mh.filetype = MH_CORE;
	mh.ncmds = load_commands.size();
	mh.sizeofcmds = size_of_load_commands;
	mh.flags = 0;
	mh.reserved = 0;

	FILE *f = fopen(argv[2], "w");

	if (f == nullptr) {
	fprintf(stderr, "Unable to open file %s for writing\n", argv[2]);
	exit(1);
	}

	fwrite(&mh, sizeof(struct mach_header_64), 1, f);

	for (const auto &lc : load_commands)
	fwrite(lc.data(), lc.size(), 1, f);

	fseek(f, header_and_load_cmd_room, SEEK_SET);

	fwrite(payload.data(), payload.size(), 1, f);

	fclose(f);
	}