Texas Instruments TMS320DM646x Manuale Utente
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2.16.2
MDIO Module Interrupt Events and Requests
2.16.2.1
Link Change Interrupt
2.16.2.2
User Access Completion Interrupt
2.16.3
Proper Interrupt Processing
2.16.4
Interrupt Multiplexing
Architecture
The MDIO module generates two interrupt events:
•
LINKINT: Serial interface link change interrupt. Indicates a change in the state of the PHY link
•
USERINT: Serial interface user command event complete interrupt
The MDIO module asserts a link change interrupt (LINKINT) if there is a change in the link state of the
PHY corresponding to the address in the PHYADRMON bit in the MDIO user PHY select register n
(USERPHYSELn), and if the LINKINTENB bit is also set in USERPHYSELn. This interrupt event is also
captured in the LINKINTRAW bit in the MDIO link status change interrupt register (LINKINTRAW).
LINKINTRAW bits 0 and 1 correspond to USERPHYSEL0 and USERPHYSEL1, respectively.
PHY corresponding to the address in the PHYADRMON bit in the MDIO user PHY select register n
(USERPHYSELn), and if the LINKINTENB bit is also set in USERPHYSELn. This interrupt event is also
captured in the LINKINTRAW bit in the MDIO link status change interrupt register (LINKINTRAW).
LINKINTRAW bits 0 and 1 correspond to USERPHYSEL0 and USERPHYSEL1, respectively.
When the interrupt is enabled and generated, the corresponding LINKINTMASKED bit is also set in the
MDIO link status change interrupt register (LINKINTMASKED). The interrupt is cleared by writing back
the same bit to LINKINTMASKED (write to clear).
MDIO link status change interrupt register (LINKINTMASKED). The interrupt is cleared by writing back
the same bit to LINKINTMASKED (write to clear).
When the GO bit in one of the MDIO user access registers (USERACCESSn) transitions from 1 to 0
(indicating completion of a user access) and the corresponding USERINTMASKSET bit in the MDIO
user command complete interrupt mask set register (USERINTMASKSET) corresponding to
USERACCESS0 or USERACCESS1 is set, a user access completion interrupt (USERINT) is asserted.
This interrupt event is also captured in the USERINTRAW bit in the MDIO user command complete
interrupt register (USERINTRAW). USERINTRAW bits 0 and bit 1 correspond to USERACCESS0 and
USERACCESS1, respectively.
(indicating completion of a user access) and the corresponding USERINTMASKSET bit in the MDIO
user command complete interrupt mask set register (USERINTMASKSET) corresponding to
USERACCESS0 or USERACCESS1 is set, a user access completion interrupt (USERINT) is asserted.
This interrupt event is also captured in the USERINTRAW bit in the MDIO user command complete
interrupt register (USERINTRAW). USERINTRAW bits 0 and bit 1 correspond to USERACCESS0 and
USERACCESS1, respectively.
When the interrupt is enabled and generated, the corresponding USERINTMASKED bit is also set in
the MDIO user command complete interrupt register (USERINTMASKED). The interrupt is cleared by
writing back the same bit to USERINTMASKED (write to clear).
the MDIO user command complete interrupt register (USERINTMASKED). The interrupt is cleared by
writing back the same bit to USERINTMASKED (write to clear).
All the interrupts signaled from the EMAC and MDIO modules are level driven, so if they remain active,
their level remains constant; the CPU core requires edge-triggered interrupts. In order to properly
convert the level-driven interrupt signal to an edge-triggered signal, the application software must make
use of the interrupt control logic contained in the EMAC control module.
their level remains constant; the CPU core requires edge-triggered interrupts. In order to properly
convert the level-driven interrupt signal to an edge-triggered signal, the application software must make
use of the interrupt control logic contained in the EMAC control module.
discusses the interrupt control contained in the EMAC control module. For safe interrupt
processing, upon entry to the ISR, the software application should disable interrupts using the EMAC
control module interrupt control registers (CMRXTHRESHINTEN, CMRXINTEN, CMTXINTEN, and
CMMISCINTEN), and then reenable them upon leaving the ISR. If any interrupt signals are active at
that time, this creates another rising edge on the interrupt signal going to the CPU interrupt controller,
thus triggering another interrupt. The EMAC control module also implements the optional interrupt
pacing.
control module interrupt control registers (CMRXTHRESHINTEN, CMRXINTEN, CMTXINTEN, and
CMMISCINTEN), and then reenable them upon leaving the ISR. If any interrupt signals are active at
that time, this creates another rising edge on the interrupt signal going to the CPU interrupt controller,
thus triggering another interrupt. The EMAC control module also implements the optional interrupt
pacing.
The EMAC control module combines all the different interrupt signals from both the EMAC and MDIO
modules and generates four separate interrupt signals (
modules and generates four separate interrupt signals (
) that are wired to the ARM interrupt
controller (AINTC), as seen in
. Once this interrupt is generated, the reason for the interrupt
can be read from the MAC input vector register (MACINVECTOR) located in the EMAC memory map.
MACINVECTOR combines the status of the following 28 interrupt signals: TXPENDn, RXPENDn,
RXTHRESHPENDn, STATPEND, HOSTPEND, LINKINT, and USERINT.
MACINVECTOR combines the status of the following 28 interrupt signals: TXPENDn, RXPENDn,
RXTHRESHPENDn, STATPEND, HOSTPEND, LINKINT, and USERINT.
For more details on the ARM interrupt controller (AINTC), see the TMS320DM646x DMSoC ARM
Subsystem Reference Guide (
Subsystem Reference Guide (
SPRUEQ6 – December 2007
Ethernet Media Access Controller (EMAC)/Management Data Input/Output (MDIO)
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