MCF5282CVM66 Freescale, MCF5282CVM66 Datasheet - Page 194
MCF5282CVM66
Manufacturer Part Number
MCF5282CVM66
Description
Manufacturer
Freescale
Datasheet
1.MCF5282CVM66.pdf
(766 pages)
Specifications of MCF5282CVM66
Cpu Family
MCF528x
Device Core
ColdFire
Device Core Size
32b
Frequency (max)
66MHz
Interface Type
CAN/I2C/QSPI/UART
Total Internal Ram Size
64KB
# I/os (max)
150
Number Of Timers - General Purpose
12
Operating Supply Voltage (typ)
3.3V
On-chip Adc
8-chx10-bit
Instruction Set Architecture
RISC
Operating Temp Range
-40C to 85C
Operating Temperature Classification
Industrial
Mounting
Surface Mount
Pin Count
256
Package Type
MA-BGA
Program Memory Type
Flash
Program Memory Size
512KB
Lead Free Status / RoHS Status
Compliant
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Interrupt Controller Modules
10.1.1.2 Interrupt Prioritization
As an active request is detected, it is translated into the programmed interrupt level, and the resulting 7-bit
decoded priority level (IRQ[7:1]) is driven out of the interrupt controller. The decoded priority levels from
all the interrupt controllers are logically summed together and the highest enabled interrupt request is then
encoded into a 3-bit priority level that is sent to the processor core during this prioritization phase.
10.1.1.3 Interrupt Vector Determination
Once the core has sampled for pending interrupts and begun interrupt exception processing, it generates
an interrupt acknowledge cycle (IACK). The IACK transfer is treated as a memory-mapped byte read by
the processor, and routed to the appropriate interrupt controller. Next, the interrupt controller extracts the
level being acknowledged from address bits[4:2], and then determines the highest priority interrupt request
active for that level, and returns the 8-bit interrupt vector for that request to complete the cycle. The 8-bit
interrupt vector is formed using the following algorithm:
For INTC0,
For INTC1,
Recall vector_numbers 0 - 63 are reserved for the ColdFire processor and its internal exceptions. Thus, the
following mapping of bit positions to vector numbers applies for the INTC0:
if interrupt source 1 is active and acknowledged,
if interrupt source 2 is active and acknowledged,
...
if interrupt source 8 is active and acknowledged,
if interrupt source 9 is active and acknowledged,
...
if interrupt source 62 is active and acknowledged,
The net effect is a fixed mapping between the bit position within the source to the actual interrupt vector
number.
If there is no active interrupt source for the given level, a special “spurious interrupt” vector
(vector_number = 24) is returned and it is the responsibility of the service routine to handle this error
situation.
Note this protocol implies the interrupting peripheral is not accessed during the acknowledge cycle since
the interrupt controller completely services the acknowledge. This means the interrupt source must be
explicitly disabled in the interrupt service routine. This design provides unique vector capability for all
interrupt requests, regardless of the “complexity” of the peripheral device.
Vector numbers 64-71, and 91-255 are unused.
10.2
The register programming model for the interrupt controllers is memory-mapped to a 256-byte space. In
the following discussion, there are a number of program-visible registers greater than 32 bits in size. For
these control fields, the physical register is partitioned into two 32-bit values: a register “high” (the upper
longword) and a register “low” (the lower longword). The nomenclature <reg_name>H and <reg_name>L
is used to reference these values.
10-4
Memory Map
vector_number = 64 + interrupt source number
vector_number = 128 + interrupt source number
then vector_number =
then vector_number =
then vector_number =
then vector_number =
then vector_number = 126
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