'\" t .\" Title: yasm_arch .\" Author: Peter Johnson .\" Generator: DocBook XSL Stylesheets v1.76.1 .\" Date: October 2006 .\" Manual: Yasm Supported Architectures .\" Source: Yasm .\" Language: English .\" .TH "YASM_ARCH" "7" "October 2006" "Yasm" "Yasm Supported Architectures" .\" ----------------------------------------------------------------- .\" * Define some portability stuff .\" ----------------------------------------------------------------- .\" ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .\" http://bugs.debian.org/507673 .\" http://lists.gnu.org/archive/html/groff/2009-02/msg00013.html .\" ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .ie \n(.g .ds Aq \(aq .el .ds Aq ' .\" ----------------------------------------------------------------- .\" * set default formatting .\" ----------------------------------------------------------------- .\" disable hyphenation .nh .\" disable justification (adjust text to left margin only) .ad l .\" ----------------------------------------------------------------- .\" * MAIN CONTENT STARTS HERE * .\" ----------------------------------------------------------------- .SH "NAME" yasm_arch \- Yasm Supported Target Architectures .SH "SYNOPSIS" .HP \w'\fByasm\fR\ 'u \fByasm\fR \fB\-a\ \fR\fB\fIarch\fR\fR [\fB\-m\ \fR\fB\fImachine\fR\fR] \fB\fI\&.\&.\&.\fR\fR .SH "DESCRIPTION" .PP The standard Yasm distribution includes a number of modules for different target architectures\&. Each target architecture can support one or more machine architectures\&. .PP The architecture and machine are selected on the \fByasm\fR(1) command line by use of the \fB\-a \fR\fB\fIarch\fR\fR and \fB\-m \fR\fB\fImachine\fR\fR command line options, respectively\&. .PP The machine architecture may also automatically be selected by certain object formats\&. For example, the \(lqelf32\(rq object format selects the \(lqx86\(rq machine architecture by default, while the \(lqelf64\(rq object format selects the \(lqamd64\(rq machine architecture by default\&. .SH "X86 ARCHITECTURE" .PP The \(lqx86\(rq architecture supports the IA\-32 instruction set and derivatives and the AMD64 instruction set\&. It consists of two machines: \(lqx86\(rq (for the IA\-32 and derivatives) and \(lqamd64\(rq (for the AMD64 and derivatives)\&. The default machine for the \(lqx86\(rq architecture is the \(lqx86\(rq machine\&. .SS "BITS Setting" .PP The x86 architecture BITS setting specifies to Yasm the processor mode in which the generated code is intended to execute\&. x86 processors can run in three different major execution modes: 16\-bit, 32\-bit, and on AMD64\-supporting processors, 64\-bit\&. As the x86 instruction set contains portions whose function is execution\-mode dependent (such as operand\-size and address\-size override prefixes), Yasm cannot assemble x86 instructions correctly unless it is told by the user in what processor mode the code will execute\&. .PP The BITS setting can be changed in a variety of ways\&. When using the NASM\-compatible parser, the BITS setting can be changed directly via the use of the \fBBITS xx\fR assembler directive\&. The default BITS setting is determined by the object format in use\&. .SS "BITS 64 Extensions" .PP The AMD64 architecture is a new 64\-bit architecture developed by AMD, based on the 32\-bit x86 architecture\&. It extends the original x86 architecture by doubling the number of general purpose and SIMD registers, extending the arithmetic operations and address space to 64 bits, as well as other features\&. .PP Recently, Intel has introduced an essentially identical version of AMD64 called EM64T\&. .PP When an AMD64\-supporting processor is executing in 64\-bit mode, a number of additional extensions are available, including extra general purpose registers, extra SSE2 registers, and RIP\-relative addressing\&. .PP Yasm extends the base NASM syntax to support AMD64 as follows\&. To enable assembly of instructions for the 64\-bit mode of AMD64 processors, use the directive \fBBITS 64\fR\&. As with NASM\*(Aqs BITS directive, this does not change the format of the output object file to 64 bits; it only changes the assembler mode to assume that the instructions being assembled will be run in 64\-bit mode\&. To specify an AMD64 object file, use \fB\-m amd64\fR on the Yasm command line, or explicitly target a 64\-bit object format such as \fB\-f win64\fR or \fB\-f elf64\fR\&. \fB\-f elfx32\fR can be used to select 32\-bit ELF object format for AMD64 processors\&. .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBRegister Changes\fR .RS 4 .PP The additional 64\-bit general purpose registers are named r8\-r15\&. There are also 8\-bit (rXb), 16\-bit (rXw), and 32\-bit (rXd) subregisters that map to the least significant 8, 16, or 32 bits of the 64\-bit register\&. The original 8 general purpose registers have also been extended to 64\-bits: eax, edx, ecx, ebx, esi, edi, esp, and ebp have new 64\-bit versions called rax, rdx, rcx, rbx, rsi, rdi, rsp, and rbp respectively\&. The old 32\-bit registers map to the least significant bits of the new 64\-bit registers\&. .PP New 8\-bit registers are also available that map to the 8 least significant bits of rsi, rdi, rsp, and rbp\&. These are called sil, dil, spl, and bpl respectively\&. Unfortunately, due to the way instructions are encoded, these new 8\-bit registers are encoded the same as the old 8\-bit registers ah, dh, ch, and bh\&. The processor tells which is being used by the presence of the new REX prefix that is used to specify the other extended registers\&. This means it is illegal to mix the use of ah, dh, ch, and bh with an instruction that requires the REX prefix for other reasons\&. For instance: .sp .if n \{\ .RS 4 .\} .nf add ah, [r10] .fi .if n \{\ .RE .\} .PP (NASM syntax) is not a legal instruction because the use of r10 requires a REX prefix, making it impossible to use ah\&. .PP In 64\-bit mode, an additional 8 SSE2 registers are also available\&. These are named xmm8\-xmm15\&. .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fB64 Bit Instructions\fR .RS 4 .PP By default, most operations in 64\-bit mode remain 32\-bit; operations that are 64\-bit usually require a REX prefix (one bit in the REX prefix determines whether an operation is 64\-bit or 32\-bit)\&. Thus, essentially all 32\-bit instructions have a 64\-bit version, and the 64\-bit versions of instructions can use extended registers \(lqfor free\(rq (as the REX prefix is already present)\&. Examples in NASM syntax: .sp .if n \{\ .RS 4 .\} .nf mov eax, 1 ; 32\-bit instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, 1 ; 64\-bit instruction .fi .if n \{\ .RE .\} .PP Instructions that modify the stack (push, pop, call, ret, enter, and leave) are implicitly 64\-bit\&. Their 32\-bit counterparts are not available, but their 16\-bit counterparts are\&. Examples in NASM syntax: .sp .if n \{\ .RS 4 .\} .nf push eax ; illegal instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf push rbx ; 1\-byte instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf push r11 ; 2\-byte instruction with REX prefix .fi .if n \{\ .RE .\} .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBImplicit Zero Extension\fR .RS 4 .PP Results of 32\-bit operations are implicitly zero\-extended to the upper 32 bits of the corresponding 64\-bit register\&. 16 and 8 bit operations, on the other hand, do not affect upper bits of the register (just as in 32\-bit and 16\-bit modes)\&. This can be used to generate smaller code in some instances\&. Examples in NASM syntax: .sp .if n \{\ .RS 4 .\} .nf mov ecx, 1 ; 1 byte shorter than mov rcx, 1 .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf and edx, 3 ; equivalent to and rdx, 3 .fi .if n \{\ .RE .\} .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBImmediates\fR .RS 4 .PP For most instructions in 64\-bit mode, immediate values remain 32 bits; their value is sign\-extended into the upper 32 bits of the target register prior to being used\&. The exception is the mov instruction, which can take a 64\-bit immediate when the destination is a 64\-bit register\&. Examples in NASM syntax: .sp .if n \{\ .RS 4 .\} .nf add rax, 1 ; optimized down to signed 8\-bit .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, dword 1 ; force size to 32\-bit .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, 0xffffffff ; sign\-extended 32\-bit .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, \-1 ; same as above .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, 0xffffffffffffffff ; truncated to 32\-bit (warning) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov eax, 1 ; 5 byte .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rax, 1 ; 5 byte (optimized to signed 32\-bit) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rax, qword 1 ; 10 byte (forced 64\-bit) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rbx, 0x1234567890abcdef ; 10 byte .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, 0xffffffff ; 10 byte (does not fit in signed 32\-bit) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov ecx, \-1 ; 5 byte, equivalent to above .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, sym ; 5 byte, 32\-bit size default for symbols .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, qword sym ; 10 byte, override default size .fi .if n \{\ .RE .\} .PP The handling of mov reg64, unsized immediate is different between YASM and NASM 2\&.x; YASM follows the above behavior, while NASM 2\&.x does the following: .sp .if n \{\ .RS 4 .\} .nf add rax, 0xffffffff ; sign\-extended 32\-bit immediate .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, \-1 ; same as above .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, 0xffffffffffffffff ; truncated 32\-bit (warning) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf add rax, sym ; sign\-extended 32\-bit immediate .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov eax, 1 ; 5 byte (32\-bit immediate) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rax, 1 ; 10 byte (64\-bit immediate) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rbx, 0x1234567890abcdef ; 10 byte instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, 0xffffffff ; 10 byte instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov ecx, \-1 ; 5 byte, equivalent to above .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov ecx, sym ; 5 byte (32\-bit immediate) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, sym ; 10 byte instruction .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov rcx, qword sym ; 10 byte (64\-bit immediate) .fi .if n \{\ .RE .\} .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBDisplacements\fR .RS 4 .PP Just like immediates, displacements, for the most part, remain 32 bits and are sign extended prior to use\&. Again, the exception is one restricted form of the mov instruction: between the al/ax/eax/rax register and a 64\-bit absolute address (no registers allowed in the effective address)\&. In NASM syntax, use of the 64\-bit absolute form requires \fB[qword]\fR\&. Examples in NASM syntax: .sp .if n \{\ .RS 4 .\} .nf mov eax, [1] ; 32 bit, with sign extension .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov al, [rax\-1] ; 32 bit, with sign extension .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov al, [qword 0x1122334455667788] ; 64\-bit absolute .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov al, [0x1122334455667788] ; truncated to 32\-bit (warning) .fi .if n \{\ .RE .\} .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBRIP Relative Addressing\fR .RS 4 .PP In 64\-bit mode, a new form of effective addressing is available to make it easier to write position\-independent code\&. Any memory reference may be made RIP relative (RIP is the instruction pointer register, which contains the address of the location immediately following the current instruction)\&. .PP In NASM syntax, there are two ways to specify RIP\-relative addressing: .sp .if n \{\ .RS 4 .\} .nf mov dword [rip+10], 1 .fi .if n \{\ .RE .\} .PP stores the value 1 ten bytes after the end of the instruction\&. \fB10\fR can also be a symbolic constant, and will be treated the same way\&. On the other hand, .sp .if n \{\ .RS 4 .\} .nf mov dword [symb wrt rip], 1 .fi .if n \{\ .RE .\} .PP stores the value 1 into the address of symbol \fBsymb\fR\&. This is distinctly different than the behavior of: .sp .if n \{\ .RS 4 .\} .nf mov dword [symb+rip], 1 .fi .if n \{\ .RE .\} .PP which takes the address of the end of the instruction, adds the address of \fBsymb\fR to it, then stores the value 1 there\&. If \fBsymb\fR is a variable, this will \fInot\fR store the value 1 into the \fBsymb\fR variable! .PP Yasm also supports the following syntax for RIP\-relative addressing: .sp .if n \{\ .RS 4 .\} .nf mov [rel sym], rax ; RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [abs sym], rax ; not RIP\-relative .fi .if n \{\ .RE .\} .PP The behavior of: .sp .if n \{\ .RS 4 .\} .nf mov [sym], rax .fi .if n \{\ .RE .\} .PP Depends on a mode set by the DEFAULT directive, as follows\&. The default mode is always "abs", and in "rel" mode, use of registers, an fs or gs segment override, or an explicit "abs" override will result in a non\-RIP\-relative effective address\&. .sp .if n \{\ .RS 4 .\} .nf default rel .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [sym], rbx ; RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [abs sym], rbx ; not RIP\-relative (explicit override) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [rbx+1], rbx ; not RIP\-relative (register use) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [fs:sym], rbx ; not RIP\-relative (fs or gs use) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [ds:sym], rbx ; RIP\-relative (segment, but not fs or gs) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [rel sym], rbx ; RIP\-relative (redundant override) .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf default abs .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [sym], rbx ; not RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [abs sym], rbx ; not RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [rbx+1], rbx ; not RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [fs:sym], rbx ; not RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [ds:sym], rbx ; not RIP\-relative .fi .if n \{\ .RE .\} .sp .if n \{\ .RS 4 .\} .nf mov [rel sym], rbx ; RIP\-relative (explicit override) .fi .if n \{\ .RE .\} .RE .sp .it 1 an-trap .nr an-no-space-flag 1 .nr an-break-flag 1 .br .ps +1 \fBMemory references\fR .RS 4 .PP Usually the size of a memory reference can be deduced by which registers you\*(Aqre moving\-\-for example, "mov [rax],ecx" is a 32\-bit move, because ecx is 32 bits\&. YASM currently gives the non\-obvious "invalid combination of opcode and operands" error if it can\*(Aqt figure out how much memory you\*(Aqre moving\&. The fix in this case is to add a memory size specifier: qword, dword, word, or byte\&. .PP Here\*(Aqs a 64\-bit memory move, which sets 8 bytes starting at rax: .sp .if n \{\ .RS 4 .\} .nf mov qword [rax], 1 .fi .if n \{\ .RE .\} .PP Here\*(Aqs a 32\-bit memory move, which sets 4 bytes: .sp .if n \{\ .RS 4 .\} .nf mov dword [rax], 1 .fi .if n \{\ .RE .\} .PP Here\*(Aqs a 16\-bit memory move, which sets 2 bytes: .sp .if n \{\ .RS 4 .\} .nf mov word [rax], 1 .fi .if n \{\ .RE .\} .PP Here\*(Aqs an 8\-bit memory move, which sets 1 byte: .sp .if n \{\ .RS 4 .\} .nf mov byte [rax], 1 .fi .if n \{\ .RE .\} .RE .SH "LC3B ARCHITECTURE" .PP The \(lqlc3b\(rq architecture supports the LC\-3b ISA as used in the ECE 312 (now ECE 411) course at the University of Illinois, Urbana\-Champaign, as well as other university courses\&. See \m[blue]\fB\%http://courses.ece.uiuc.edu/ece411/\fR\m[] for more details and example code\&. The \(lqlc3b\(rq architecture consists of only one machine: \(lqlc3b\(rq\&. .SH "SEE ALSO" .PP \fByasm\fR(1) .SH "BUGS" .PP When using the \(lqx86\(rq architecture, it is overly easy to generate AMD64 code (using the \fBBITS 64\fR directive) and generate a 32\-bit object file (by failing to specify \fB\-m amd64\fR on the command line or selecting a 64\-bit object format)\&. Similarly, specifying \fB\-m amd64\fR does not default the BITS setting to 64\&. An easy way to avoid this is by directly specifying a 64\-bit object format such as \fB\-f elf64\fR\&. .SH "AUTHOR" .PP \fBPeter Johnson\fR <\&peter@tortall\&.net\&> .RS 4 Author. .RE .SH "COPYRIGHT" .br Copyright \(co 2004, 2005, 2006, 2007 Peter Johnson .br