DLX Floating Special

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QuadCore Team – DLX ISA David Bild Greg Bok Jake Czyz Brandon Keao

description

DLX programacion

Transcript of DLX Floating Special

QuadCore Team – DLX ISA

David Bild Greg Bok Jake Czyz Brandon Keao

Floating-Point Instructions

There are three categories for the DLX floating-point instructions: Arithmetic Conversion Set-on-comparison

All operation occur in the floating-point registers and are in the R-type format.

DLX ISA

Floating-Point Instructions: Arithmetic

Brandon Keao

Floating-Point Instructions: Arithmetic

These intructions preform arithmetic operations on two floating-point registers

Always R-format There are 2 categories of floating-point

arithmetic instructions: Single-precision Double-precision

Floating-Point Instructions: Arithmetic

SP operations interpret the values in the two registers as SP FP values

The result is rounded to a SP value and stored in a FP register ADDF- Adds two SP values SUBF - Subtracts two SP values MULTF - Multiplies two SP values DIVF - Divides two SP values

Floating-Point Instructions: Arithmetic

DP operations interpret the values of two even/odd pairs of FP registers as DP FP values.

The result if rounded to a DP value and stored in an even/odd pair of FP registers. ADDD - Adds two DP values SUBD - Subtracts two DP values MULTD - Multiplies two DP values DIVD - Divides two DP values

DLX ISA

Floating-Point Instructions: Conversion

And Special Instructions

Greg Bok

Floating-Point Instructions: Conversion

Sometimes need to convert between precisions or integer/floating-point

The DLX ISA includes 6 such instructions R-format Double-precision FP register operands

must be even-numbered FP registers 32-bit integers used

Floating-Point Instructions: Conversion

1. CVT2DF: double-precision to single-precision

2. CVTD2I: double-precision to integer

3. CVTF2D: single-precision to double-precision

4. CVTF2I: single-precision to integer

5. CVTI2D: integer to double-precision

6. CVTI2F: integer to single-precision

Special Instructions: TRAP J-type, unconditional branch 26-bit name field zero-extended to 32-

bits to obtain target address Moves PC + 8 to IAR (interrupt address

register)

Special Instructions: RFE Return From Exception J-type, unconditional Returns to code that was executing

before TRAP instruction Moves value in IAR register to PC

Special Instructions: NOP R-type Performs no operation -- hardware state

is unaffected Typically used to fill branch delay slots

when no useful instruction will work

DLX ISA

Floating-Point Instructions: Set-on-Comparison

David Bild

Floating-Point Instructions: Set-On-Comparison

Compares two floating point numbers (SP or DP)

Sets FPSR (Floating Point Status Register) to ‘1’ if comparison is true, ‘0’ if false

6 comparisons are provided: <, >, =. <=, >=, ~=

DLX ISA

Load & Store Instructions

Jake Czyz

Load and Store Instructions For loading/storing data from/to memory Handle data of size:

Byte Halfword Word Double (for floating point only)

Load and Store Instructions Byte and Halfword instructions always

load/store the least significant byte or halfword, respectively.

Loads and Stores may be done with any of the general purpose registers, except that loading R0 has no effect (it always stores the value 0x00000000).

Load and Store Instructions All are I-Type

Bit #'s 0 5 6 10 11 15 16 31

Opcode rs1 rd Immediate

Width 6 5 5 16

Data always moved between memory and the register(s) specified by rd

Load and Store Instructions Load/Store Address Calculations:

Load lw rd rs1 imm rd = Mem(Sign_Extend(imm) + rs1)

Store sw rd rs1 imm Mem(Sign_Extend(imm) + rs1) = rd

Load Instructions LB Loads a byte (w/ sign ext.) LBU Loads a byte (w/ zero ext.) LH Loads a halfword (w/ sign ext.) LHU Loads a halfword (w/ zero ext.) LW Loads a word LF Loads a single precision float LD Loads a double precision float*

*to/from a pair of even/odd registers

Store Instructions

SB Stores a byte SH Stores a halfword SW Stores a word SF Stores a single precision float SD Stores a double precision float*

*to/from a pair of even/odd registers

Thank You