Datasheet

Table Of Contents

ColdFire Core

2-2 Freescale Semiconductor

instruction, fetches the required operands and then executes the required function. Because the IFP and

OEP pipelines are decoupled by an instruction buffer serving as a FIFO queue, the IFP is able to prefetch

instructions in advance of their actual use by the OEP thereby minimizing time stalled waiting for

instructions.

The V2 ColdFire core pipeline stages include the following:

• Two-stage instruction fetch pipeline (IFP) (plus optional instruction buffer stage)

— Instruction address generation (IAG) — Calculates the next prefetch address

— Instruction fetch cycle (IC)—Initiates prefetch on the processor’s local bus

— Instruction buffer (IB) — Optional buffer stage minimizes fetch latency effects using FIFO

queue

• Two-stage operand execution pipeline (OEP)

— Decode and select/operand fetch cycle (DSOC)—Decodes instructions and fetches the

required components for effective address calculation, or the operand fetch cycle

— Address generation/execute cycle (AGEX)—Calculates operand address or executes the

instruction

When the instruction buffer is empty, opcodes are loaded directly from the IC cycle into the operand

execution pipeline. If the buffer is not empty, the IFP stores the contents of the fetched instruction in the

IB until it is required by the OEP.

For register-to-register and register-to-memory store operations, the instruction passes through both OEP

stages once. For memory-to-register and read-modify-write memory operations, an instruction is

effectively staged through the OEP twice: the first time to calculate the effective address and initiate the

operand fetch on the processor’s local bus, and the second time to complete the operand reference and

perform the required function defined by the instruction.

The resulting pipeline and local bus structure allow the V2 ColdFire core to deliver sustained high

performance across a variety of demanding embedded applications.

2.2 Memory Map/Register Description

The following sections describe the processor registers in the user and supervisor programming models.

The programming model is selected based on the processor privilege level (user mode or supervisor mode)

as defined by the S bit of the status register (SR). Table 2-1 lists the processor registers.

The user-programming model consists of the following registers:

• 16 general-purpose 32-bit registers (D0–D7, A0–A7)

• 32-bit program counter (PC)

• 8-bit condition code register (CCR)

• EMAC registers :

— Four 48-bit accumulator registers partitioned as follows:

– Four 32-bit accumulators (ACC0–ACC3)

– Eight 8-bit accumulator extension bytes (two per accumulator). These are grouped into two

32-bit values for load and store operations (ACCEXT01 and ACCEXT23).

(described fully in Chapter 3, “Enhanced Multiply-Accumulate Unit (EMAC

MCF5282 and MCF5216 ColdFire Microcontroller User’s Manual, Rev. 3