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402 lines
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ReStructuredText
402 lines
13 KiB
ReStructuredText
.. bddisasm documentation master file, created by
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sphinx-quickstart on Wed Jul 8 13:39:28 2020.
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You can adapt this file completely to your liking, but it should at least
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contain the root `toctree` directive.
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Welcome to bddisasm's documentation!
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====================================
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.. toctree::
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:maxdepth: 2
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:caption: Contents:
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About
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=====
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The Bitdefender x86 disassembler (https://github.com/bitdefender/bddisasm) is a complete x86/x64 instruction decoder,
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capable of providing full information about each decoded instruction. The
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library is written entirely in C, with some Python 3 code for the instruction
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tables generation. It has no external dependencies, and it is thread safe
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by design. It can be easily integrated in any environment - we use it in
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user mode on both Windows and Linux, in kernel mode on Windows and inside
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VMX root of our own Napoca hypervisor.
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This documentation provides a high-level overview of the project and
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how to use it. The information is bound to standard x86 instruction
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semantics, hence there is no official Doxygen documentation Instead, the source
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code and the header files contain rich comments, which provided detailed relevant
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information.
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Project goals
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=============
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When we first started the project more than 5 years ago, there were no good
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disassemblers available which werecapable of providing extensive information about the
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decoded instructions. We decided to create, from scratch, such a disassembler,
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which would then be used by all the projects that require one. The first
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requirement was, therefore, that the library should be OS agnostic. We then
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considered the main use-cases, where we decode and analyze instructions
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in real time (for example, an instruction that just triggered a memory fault).
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This meant that the decoder had to be very fast. Of course, having to be able
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to integrate the library in any mode of operation and on any operating system
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meant that it should be thread-safe by design, and no memory should be allocated.
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We then considered that some of our use-cases required instruction emulation,
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so the decoder must provide as much information about each instruction as
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possible. Finally, given the latest ISA extensions proposed by Intel, the
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disassembler must also be designed in a way that allows programmers to easily
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add support for new instructions. The requirements, in a nutshell, are, therefore:
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.. hlist::
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:columns: 1
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* OS and operating mode agnostic (Windows/Linux, user/kernel/VMX root)
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* Speed (less than 500 clocks/decoded instruction)
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* No memory overhead (no memory is allocated by the disassembler)
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* Thread-safe (no global variables written, no threads created)
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* Full instruction information
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* Easy to extend
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We managed to achieve all of these goals.
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The library is successfully being
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used in various user/kernel/VMX root projects, on both Windows and Linux.
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On an Intel Core i7-8650U, it takes roughly 300 clocks to decode one instruction.
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There is no memory overhead, the library is thread safe and it provides pretty
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much all known information about each instruction. Finally, the instructions are
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defined in an easy to understand, well documented textual format - adding support
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for a new instruction requires describing the instruction in one
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of these files, and re-building the tables.
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Using the disassembler
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======================
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Using the disassembler is very easy. Include the **bddisasm.h** header file
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and link with the disassembler library (which is **bddisasm.lib** on Windows or
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**libbddisasm.a** on Linux). Once this has been done, make sure the **nd_vsnprintf_s** and
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**nd_memset** functions are defined. For example, do the following:
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.. code-block:: c
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:linenos:
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int nd_vsnprintf_s(
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char *buffer,
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size_t sizeOfBuffer,
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size_t count,
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const char *format,
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va_list argptr
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)
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{
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return _vsnprintf_s(buffer, sizeOfBuffer, count, format, argptr);
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}
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void* nd_memset(void *s, int c, size_t n)
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{
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return memset(s, c, n);
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}
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These are required to allow the integrator to use whatever implementation of
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vsnprintf and memset they wish. Once this has been done, decoding an instruction is as
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simple as calling one of the decoding API:
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.. code-block:: c
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:linenos:
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#include "bddisasm/disasmtypes.h"
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#include "bddisasm/bddisasm.h"
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int main()
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{
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INSTRUX ix;
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unsigned char ins[2] = { 0x33, 0xC0 };
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NDSTATUS status;
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status = NdDecodeEx(&ix, ins, sizeof(ins), ND_CODE_64, ND_DATA_64);
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if (!ND_SUCCESS(status))
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{
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printf("Decoding failed with error 0x%08x!\n", status);
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return -1;
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}
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printf("Decoded instruction with length %d!\n", ix.Length);
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}
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When decoding an instruction, all the possible information is stored in the
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output **INSTRUX** structure. There is no need to call any other helper functions.
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However, the textual representation (the actual *disassembly*) of the instruction
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has to be obtained by calling the **NdToText** API:
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.. code-block:: c
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:linenos:
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#include "bddisasm/disasmtypes.h"
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#include "bddisasm/bddisasm.h"
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int main()
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{
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INSTRUX ix;
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unsigned char ins[2] = { 0x33, 0xC0 };
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NDSTATUS status;
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char txt[ND_MIN_BUF_SIZE];
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status = NdDecodeEx(&ix, ins, sizeof(ins), ND_CODE_64, ND_DATA_64);
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if (!ND_SUCCESS(status))
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{
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printf("Decoding failed with error 0x%08x!\n", status);
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return -1;
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}
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NdToText(&ix, 0, sizeof(txt), txt);
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printf("Decoded instruction %s!\n", txt);
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}
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The disassembler provides the **NdToText** function, but this function only
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supports Intel style syntax. If one wishes to implement a different output
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formatter, it can do so, by implementing a different **NdToText** function
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(the existing function can be used as a template).
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Instruction information
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=======================
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The information provided inside the **INSTRUX** structure covers all the known information
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about the instruction. There are several categories of info offered:
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.. hlist::
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:columns: 1
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* Instruction encoding information - prefixes, opcodes, modrm, sib, immediates, displacement
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* Operand information, for both explicit and implicit operands - type, size, access, encoding
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* Instruction meta information - instruction set, instruction type, instruction class
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* Accepted prefixes - lock, rep, hle, etc.
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* Valid modes for the instruction - real, protected, long, ring 0/1/2/3, etc.
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* CPUID leaf information - allows to directly test if the instruction is available or not
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* Flags access - for each flag, access type (tested, modified, cleared, set to 1, undefined)
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* FPU flags access - for FPU instructions
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* For VEX/SSE instructions - exception class
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* For EVEX instructions - decorator info, tuple type, exception class
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For memory operands, the following information is provided:
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.. hlist::
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:columns: 1
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* Segment
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* Base register
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* Index register, with scale
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* Displacement
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* VSIB information - index size, element size, element count
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* Extended addressing information - address generation, mib, sibmem, string operation indicator, stack access indicator, bitbase, etc.
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This is the most relevant information provided by it. For more info,
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look at the **bddisasm.h** file, which contains all the definitions,
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together with ample comments describing each one of them.
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Examples
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========
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Assuming we have already decoded an instruction as follows:
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.. code-block:: c
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:linenos:
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#include "bddisasm/disasmtypes.h"
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#include "bddisasm/bddisasm.h"
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int main()
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{
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INSTRUX ix;
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unsigned char ins[2] = { 0x33, 0xC0 };
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NDSTATUS status;
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char txt[ND_MIN_BUF_SIZE];
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status = NdDecodeEx(&ix, ins, sizeof(ins), ND_CODE_64, ND_DATA_64);
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if (!ND_SUCCESS(status))
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{
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printf("Decoding failed with error 0x%08x!\n", status);
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return -1;
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}
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}
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we will provide some examples of how we can obtain specific information about the instruction.
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Determining the length of an instruction
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----------------------------------------
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.. code-block:: c
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:linenos:
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ix.Length; // Length in bytes.
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Determining the number of operands of an instruction
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----------------------------------------------------
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.. code-block:: c
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:linenos:
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ix.OperandsCount; // Total operands count.
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ix.ExpOperandsCount; // Explicit operands count.
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Determining the operand and address size
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----------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.OpMode == ND_OPSZ_16) // 16 bit operand size.
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if (ix.OpMode == ND_OPSZ_32) // 32 bit operand size.
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if (ix.OpMode == ND_OPSZ_64) // 64 bit operand size.
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if (ix.AddrMode == ND_ADDR_16) // 16 bit address size.
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if (ix.AddrMode == ND_ADDR_32) // 32 bit address size.
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if (ix.AddrMode == ND_ADDR_64) // 64 bit address size.
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Determining if the instruction has modrm, SIB or displacement
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-------------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.HasModrm) // The instruction has Mod R/M.
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if (ix.HasSib) // The instruction has SIB.
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if (ix.HasDisp) // The instruction has displacement.
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Determining if the first operand is register EAX
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------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ND_IS_OP_REG(&ix.Operands[0], ND_REG_GPR, 4, NDR_EAX))
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Determining if the second operand is the stack
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----------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.Operands[1].Type == ND_OP_MEM &&
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ix.Operands[1].Info.Memory.IsStack)
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Determining if the instruction is a conditional branch
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------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.Category == ND_CAT_COND_BR)
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Determining if the instruction is "ADD" or "SUB"
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------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.Instruction == ND_INS_ADD ||
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ix.Instruction == ND_INS_SUB)
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Determining if the instruction accesses various flags
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-----------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.FlagsAccess.Modified.CF) // Is CF modified?
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if (ix.FlagsAccess.Undefined.OF) // Is OF undefined?
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if (ix.FlagsAccess.Cleared.ZF) // Is ZF cleared?
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if (ix.FlagsAccess.Set.PF) // Is PF set?
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if (ix.FlagsAccess.Tested.CF) // Is CF tested?
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Determining if the instruction is supported on the current CPU
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--------------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.CpuidFlag.Leaf == ND_CFF_NO_LEAF)
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{
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// The instruction is present on pretty much all CPUs,
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// there is no CPUID bit flag test.
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}
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else
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{
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int regs[4];
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int sorted[4];
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if (ix.CpuidFlag.SubLeaf == ND_CFF_NO_SUBLEAF)
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{
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// No subleaf.
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__cpuid(regs, ix.CpuidFlag.Leaf);
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}
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else
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{
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__cpuidex(regs, ix.CpuidFlag.Leaf, ix.CpuidFlag.SubLeaf);
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}
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// regs is defined by MSDN as eax, ebx, ecx, edx, so sort them
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// in Intel order.
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sorted[0] = regs[0]; // eax
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sorted[1] = regs[2]; // ecx
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sorted[2] = regs[3]; // edx
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sorted[3] = regs[1]; // ebx
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if (sorted[ix.CpuidFlag.Reg] & (1ULL << ix.CpuidFlag.Bit))
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{
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// The instruction is supported!
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}
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}
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Determining if the instruction accepts various prefixes
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-------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.ValidPrefixes.Lock) // The instruction accepts LOCK.
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if (ix.ValidPrefixes.Hle) // The instruction accepts hardware lock elision prefix.
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if (ix.ValidPrefixes.Rep) // The instruction accepts unconditional REP prefix.
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Determining if the instruction is valid in various modes
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--------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.ValidModes.Real) // The instruction is valid in real mode.
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if (ix.ValidModes.Long) // The instruction is valid in long mode.
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if (ix.ValidModes.Tsx) // The instruction is valid in a transaction.
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if (!ix.ValidModes.Ring3) // The instruction is not valid in user-mode.
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Determining if the instruction is a branch of any kind
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------------------------------------------------------
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.. code-block:: c
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:linenos:
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if (ix.RipAccess & ND_ACCESS_ANY_WRITE) // Instruction writes RIP.
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Computing the virtual address of a memory operand
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------------------------------------------------
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.. code-block:: c
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:linenos:
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// Note: we don't consider bitbase or VSIB addressing.
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if (memOp->Info.Memory.HasBase)
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{
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gla += ND_TRIM(memOp->Info.Memory.BaseSize, REG(memOp->Info.Memory.Base));
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}
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if (memOp->Info.Memory.HasIndex)
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{
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gla += ND_TRIM(memOp->Info.Memory.IndexSize, REG(memOp->Info.Memory.Index)) * memOp->Info.Memory.Scale;
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}
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if (memOp->Info.Memory.HasDisp)
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{
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gla += memOp->Info.Memory.Disp;
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}
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