CP3BT26 Datasheet, PDF(15/278 Page) National Semiconductor (TI) – Reprogrammable Connectivity Processor with Bluetooth-R, USB, and CAN Interfaces

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CP3BT26 Datasheet, PDF (15/278 Pages) National Semiconductor (TI) – Reprogrammable Connectivity Processor with Bluetooth-R, USB, and CAN Interfaces

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5.0 CPU Architecture

The CP3BT26 uses the CR16C third-generation 16-bit

CompactRISC processor core. The CPU implements a Re-

duced Instruction Set Computer (RISC) architecture that al-

lows an effective execution rate of up to one instruction per

clock cycle. For a detailed description of the CPU16C archi-

tecture, see the CompactRISC CR16C Programmerâs Ref-

erence Manual which is available on the National

Semiconductor web site (http://www.nsc.com).

The CR16C CPU core includes these internal registers:

Â General-purpose registers (R0-R13, RA, and SP)

Â Dedicated address registers (PC, ISP, USP, and INT-

BASE)

Â Processor Status Register (PSR)

Â Configuration Register (CFG)

The R0-R11, PSR, and CFG registers are 16 bits wide. The

R12, R13, RA, SP, ISP and USP registers are 32 bits wide.

The PC register is 24 bits wide. Figure 2 shows the CPU

registers.

Dedicated Address Registers

23 15

0

General-Purpose Registers

15

0

31

PC

R0

ISPH

ISPL

R1

USPH

USPL

R2

INTBASEH

INTBASEL

R3

R4

R5

Processor Status Register

R6

15

0

R7

PSR

R8

Configuration Register

R9

15

0

R10

CFG

31

R11

R12

R13

Â When the CFG.SR bit is clear, register pairs are grouped

in the manner used by native CR16C software: (R1,R0),

(R2,R1) ... (R11,R10), (R12_L, R11), R12, R13, RA, SP.

R12, R13, RA, and SP are 32-bit registers for holding ad-

dresses greater than 16 bits.

With the recommended calling convention for the architec-

ture, some of these registers are assigned special hardware

and software functions. Registers R0 to R13 are for general-

purpose use, such as holding variables, addresses, or index

values. The SP register holds a pointer to the program run-

time stack. The RA register holds a subroutine return ad-

dress. The R12 and R13 registers are available to hold base

addresses used in the index addressing mode.

If a general-purpose register is specified by an operation

that is 8 bits long, only the lower byte of the register is used;

the upper part is not referenced or modified. Similarly, for

word operations on register pairs, only the lower word is

used. The upper word is not referenced or modified.

5.2 DEDICATED ADDRESS REGISTERS

The CR16C has four dedicated address registers to imple-

ment specific functions: the PC, ISP, USP, and INTBASE

registers.

5.2.1 Program Counter (PC) Register

The 24-bit value in the PC register points to the first byte of

the instruction currently being executed. CR16C instruc-

tions are aligned to even addresses, therefore the least sig-

nificant bit of the PC is always 0. At reset, the PC is

initialized to 0 or an optional predetermined value. When a

warm reset occurs, value of the PC prior to reset is saved in

the (R1,R0) general-purpose register pair.

RA

SP

DS004

Figure 2. CPU Registers

Some register bits are designated as âreserved.â Software

must write a zero to these bit locations when it writes to the

register. Read operations from reserved bit locations return

undefined values.

5.1 GENERAL-PURPOSE REGISTERS

The CompactRISC CPU features 16 general-purpose regis-

ters. These registers are used individually as 16-bit oper-

ands or as register pairs for operations on addresses

greater than 16 bits.

Â General-purpose registers are defined as R0 through

R13, RA, and SP.

Â Registers are grouped into pairs based on the setting of

the Short Register bit in the Configuration Register

(CFG.SR). When the CFG.SR bit is set, the grouping of

register pairs is upward-compatible with the architecture

of the earlier CR16A/B CPU cores: (R1,R0), (R2,R1) ...

(R11,R10), (R12_L, R11), (R13_L, R12_L), (R14_L,

R13_L) and SP. (R14_L, R13_L) is the same as

(RA,ERA).

5.2.2 Interrupt Stack Pointer (ISP)

The 32-bit ISP register points to the top of the interrupt

stack. This stack is used by hardware to service exceptions

(interrupts and traps). The stack pointer may be accessed

as the ISP register for initialization. The interrupt stack can

be located anywhere in the CPU address space. The ISP

cannot be used for any purpose other than the interrupt

stack, which is used for automatic storage of the CPU reg-

isters when an exception occurs and restoration of these

registers when the exception handler returns. The interrupt

stack grows downward in memory. The least significant bit

and the 8 most significant bits of the ISP register are always

0.

5.2.3 User Stack Pointer (USP)

The USP register points to the top of the user-mode pro-

gram stack. Separate stacks are available for user and su-

pervisor modes, to support protection mechanisms for

multitasking software. The processor mode is controlled by

the U bit in the PSR register (which is called PSR.U in the

shorthand convention). Stack grow downward in memory. If

the USP register points to an illegal address (any address

greater than 0x00FF_FFFF) and the USP is used for stack

access, an IAD trap is taken.

15

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