An information processing device includes: a memory that stores a program; and a processor that executes the program to perform operations, wherein the operations includes: specifying a first register which is allocated to scalar data and satisfies a condition that a survival interval of the scalar data includes a survival interval of first data to which any register is not allocated; and allocating an empty area of the first register to the first data.

A computer processor that implements pre-translation of virtual addresses with target registers is disclosed. The computer processor may include a register file comprising one or more registers. The computer processor may include processing logic. The processing logic may receive a value to store in a register of one or more registers. The processing logic may store the value in the register. The processing logic may designate the received value as a virtual instruction address, the virtual instruction address having a corresponding virtual base page number. The processing logic may translate the virtual base page number to a corresponding real base page number and zero or more real page numbers corresponding to zero or more virtual page numbers adjacent to the virtual base page number. The processing logic may further store in the register of the one or more registers the real base page number and the zero or more real page numbers.

A processor includes a register to store an encoded pointer to a memory location in memory and the encoded pointer is to include an encrypted portion. The processor further includes circuitry to determine a first data encryption factor based on a first data access instruction, decode the encoded pointer to obtain a memory address of the memory location, use the memory address to access an encrypted first data element, and decrypt the encrypted first data element using a cryptographic algorithm with first inputs to generate a decrypted first data element. The first inputs include the first data encryption factor based on the first data access instruction and a second data encryption factor from the encoded pointer.

A processor includes a decode unit to decode a three source floating point addition instruction indicating a first source operand having a first floating point data element, a second source operand having a second floating point data element, and a third source operand having a third floating point data element. An execution unit is coupled with the decode unit. The execution unit, in response to the instruction, stores a result in a destination operand indicated by the instruction. The result includes a result floating point data element that includes a first floating point rounded sum. The first floating point rounded sum represents an additive combination of a second floating point rounded sum and the third floating point data element. The second floating point rounded sum represents an additive combination of the first floating point data element and the second floating point data element.

A computer system, processor, and method for processing information is disclosed that includes at least one computer processor; a main register file associated with the at least one processor, the main register file having a plurality of entries for storing data, one or more write ports to write data to the main register file entries, and one or more read ports to read data from the main register file entries; one or more execution units including a dense math execution unit; and at least one accumulator register file having a plurality of entries for storing data. The results of the dense math execution unit in an aspect are written to the accumulator register file, preferably to the same accumulator register file entry multiple times, and the data from the accumulator register file is written to the main register file.

The vector data path is divided into smaller vector lanes. A register such as a memory mapped control register stores a vector lane number (VLX) indicating the number of vector lanes to be powered. A decoder converts this VLX into a vector lane control word, each bit controlling the ON of OFF state of the corresponding vector lane. This number of contiguous least significant vector lanes are powered. In the preferred embodiment the stored data VLX indicates that 2.sup.VLX contiguous least significant vector lanes are to be powered. Thus the number of vector lanes powered is limited to an integral power of 2. This manner of coding produces a very compact controlling bit field while obtaining substantially all the power saving advantage of individually controlling the power of all vector lanes.

The present disclosure is related to performing speculation in, for example, a memory device or a computing system that includes a memory device. Speculation can be used to identify data that is accessed together or to predict data that will be accessed with greater frequency. The identified data can be organized to improve efficiency in providing access to the data.

Systems and methods for utilizing virtual memory with a high-level programming language are provided. Multiple address spaces are created in virtual memory, wherein each of the multiple address spaces include data entries, each of which have a value. A machine executable software program is operated which utilizes each of said multiple address spaces. At least a first one of the address spaces is independent from at least a second one of said address spaces, and at least a third one of the address spaces is electronically associated with at least a fourth one of the address spaces.

Fine-grained enablement at sub-function granularity. An instruction encapsulates different sub-functions of a function, in which the sub-functions use different sets of registers of a composite register file, and therefore, different sets of functional units. At least one operand of the instruction specifies which set of registers, and therefore, which set of functional units, is to be used in performing the sub-function. The instruction can perform various functions (e.g., move, load, etc.) and a sub-function of the function specifies the type of function (e.g., move-floating point; move-vector; etc.).

Embodiments are directed to a computer implemented method for executing machine instructions in a central processing unit. The executing includes loading a first operand into a first operand register, and loading a second operand into a second operand register. The executing further includes shifting either the first operand or the second operand to form a shifted operand. The executing further includes adding or subtracting the first operand and the second operand to obtain a sum or a difference, and loading the sum or the difference having a least significant bit into a third register or a memory. The executing further includes performing a probability analysis on least significant bits of the shifted operand or the non-shifted operand, and initiating a rounding operation on the least significant bit of the sum or the difference based at least in part on the probability analysis.