HD6417750RF240DV Renesas Electronics America, HD6417750RF240DV Datasheet - Page 329

HD6417750RF240DV

Manufacturer Part Number

HD6417750RF240DV

Description

MPU 3V 16K I-TEMP,PB-FREE 208-QF

Manufacturer

Renesas Electronics America

Series

SuperH® SH7750r

Datasheet

1.D6417750RBP240DV.pdf (1164 pages)

Specifications of HD6417750RF240DV

Core Processor

SH-4

Core Size

32-Bit

Speed

240MHz

Connectivity

EBI/EMI, FIFO, SCI, SmartCard

Peripherals

DMA, POR, WDT

Number Of I /o

Program Memory Type

ROMless

Ram Size

48K x 8

Voltage - Supply (vcc/vdd)

1.4 V ~ 1.6 V

Oscillator Type

External

Operating Temperature

-40°C ~ 85°C

Package / Case

208-QFP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Eeprom Size

Program Memory Size

Data Converters

Available stocks

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Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

HD6417750RF240DV

Manufacturer:

HITACHI

Quantity:

7 287

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The instruction execution sequence is expressed as a combination of the execution patterns shown

in figure 8.2. One instruction is separated from the next by the number of machine cycles for its

issue rate. Normally, execution, data access, and write-back stages cannot be overlapped onto the

same stages of another instruction; the only exception is when two instructions are executed in

parallel under parallel-executability conditions. Refer to (a) through (d) in figure 8.3 for some

simple examples.

Latency is the interval between issue and completion of an instruction, and is also the interval

between the execution of two instructions with an interdependent relationship. When there is

interdependency between two instructions fetched simultaneously, the latter of the two is stalled

for the following number of cycles:

• (Latency) cycles when there is flow dependency (read-after-write)

• (Latency - 1) or (latency - 2) cycles when there is output dependency (write-after-write)

• 5 or 2 cycles when there is anti-flow dependency (write-after-read), as in the following cases:

In the case of flow dependency, latency may be exceptionally increased or decreased, depending

on the combination of sequential instructions (figure 8.3 (e)).

• When a floating-point (FP) computation is followed by an FP register store, the latency of the

• If there is a load of the shift amount immediately before an SHAD/SHLD instruction, the

• If an instruction with a latency of less than 2 cycles, including write-back to an FP register, is

The number of cycles in a pipeline stall due to flow dependency will vary depending on the

combination of interdependent instructions or the fetch timing (see figure 8.3. (e)).

Output dependency occurs when the destination operands are the same in a preceding FE group

instruction and a following LS group instruction.

For the stall cycles of an instruction with output dependency, the longest latency to the last write-

back among all the destination operands must be applied instead of “latency” (see figure 8.3 (f)).

A stall due to output dependency with respect to FPSCR, which reflects the result of an FP

⎯ Single/double-precision FDN, FSQRT is the preceding instruction (latency – 1) cycles

⎯ The other FE group is the preceding instruction (latency – 2) cycles

⎯ FTRV is the preceding instruction (5 cycle)

⎯ A double-precision FADD, FSUB, or FMUL is the preceding instruction (2 cycles)

FP computation may be decreased by 1 cycle.

latency of the load is increased by 1 cycle.

followed by a double-precision FP instruction, FIPR, or FTRV, the latency of the first

instruction is increased to 2 cycles.

Rev.7.00 Oct. 10, 2008 Page 243 of 1074

Section 8 Pipelining

REJ09B0366-0700

HD6417750RF240DV Renesas Electronics America, HD6417750RF240DV Datasheet - Page 329

HD6417750RF240DV

Specifications of HD6417750RF240DV

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