/* $Id: xipif_v1_23_b.h,v 1.1.1.1 2008-12-15 11:39:22 wokes Exp $ */ /****************************************************************************** * * XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS" * AS A COURTESY TO YOU, SOLELY FOR USE IN DEVELOPING PROGRAMS AND * SOLUTIONS FOR XILINX DEVICES. BY PROVIDING THIS DESIGN, CODE, * OR INFORMATION AS ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE, * APPLICATION OR STANDARD, XILINX IS MAKING NO REPRESENTATION * THAT THIS IMPLEMENTATION IS FREE FROM ANY CLAIMS OF INFRINGEMENT, * AND YOU ARE RESPONSIBLE FOR OBTAINING ANY RIGHTS YOU MAY REQUIRE * FOR YOUR IMPLEMENTATION. XILINX EXPRESSLY DISCLAIMS ANY * WARRANTY WHATSOEVER WITH RESPECT TO THE ADEQUACY OF THE * IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO ANY WARRANTIES OR * REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE FROM CLAIMS OF * INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE. * * (c) Copyright 2002 Xilinx Inc. * All rights reserved. * ******************************************************************************/ /****************************************************************************** * * FILENAME: * * xipif.h * * DESCRIPTION: * * The XIpIf component encapsulates the IPIF, which is the standard interface * that IP must adhere to when connecting to a bus. The purpose of this * component is to encapsulate the IPIF processing such that maintainability * is increased. This component does not provide a lot of abstraction from * from the details of the IPIF as it is considered a building block for * device drivers. A device driver designer must be familiar with the * details of the IPIF hardware to use this component. * * The IPIF hardware provides a building block for all hardware devices such * that each device does not need to reimplement these building blocks. The * IPIF contains other building blocks, such as FIFOs and DMA channels, which * are also common to many devices. These blocks are implemented as separate * hardware blocks and instantiated within the IPIF. The primary hardware of * the IPIF which is implemented by this software component is the interrupt * architecture. Since there are many blocks of a device which may generate * interrupts, all the interrupt processing is contained in the common part * of the device, the IPIF. This interrupt processing is for the device level * only and does not include any processing for the interrupt controller. * * A device is a mechanism such as an Ethernet MAC. The device is made * up of several parts which include an IPIF and the IP. The IPIF contains most * of the device infrastructure which is common to all devices, such as * interrupt processing, DMA channels, and FIFOs. The infrastructure may also * be referred to as IPIF internal blocks since they are part of the IPIF and * are separate blocks that can be selected based upon the needs of the device. * The IP of the device is the logic that is unique to the device and interfaces * to the IPIF of the device. * * In general, there are two levels of registers within the IPIF. The first * level, referred to as the device level, contains registers which are for the * entire device. The second level, referred to as the IP level, contains * registers which are specific to the IP of the device. The two levels of * registers are designed to be hierarchical such that the device level is * is a more general register set above the more specific registers of the IP. * The IP level of registers provides functionality which is typically common * across all devices and allows IP designers to focus on the unique aspects * of the IP. * * Critical Sections * * It is the responsibility of the device driver designer to use critical * sections as necessary when calling functions of the IPIF. This component * does not use critical sections and it does access registers using * read-modify-write operations. Calls to IPIF functions from a main thread * and from an interrupt context could produce unpredictable behavior such that * the caller must provide the appropriate critical sections. * * Mutual Exclusion * * The functions of the IPIF are not thread safe such that the caller of all * functions is responsible for ensuring mutual exclusion for an IPIF. Mutual * exclusion across multiple IPIF components is not necessary. * * NOTES: * * None. * * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- ----------------------------------------------- * 1.23b jhl 02/27/01 Repartioned to minimize size * ******************************************************************************/ #ifndef XIPIF_H /* prevent circular inclusions */ #define XIPIF_H /* by using protection macros */ /***************************** Include Files *********************************/ #include "xbasic_types.h" #include "xstatus.h" #include "xversion.h" /************************** Constant Definitions *****************************/ /* the following constants define the register offsets for the registers of the * IPIF, there are some holes in the memory map for reserved addresses to allow * other registers to be added and still match the memory map of the interrupt * controller registers */ #define XIIF_V123B_DISR_OFFSET 0UL /* device interrupt status register */ #define XIIF_V123B_DIPR_OFFSET 4UL /* device interrupt pending register */ #define XIIF_V123B_DIER_OFFSET 8UL /* device interrupt enable register */ #define XIIF_V123B_DIIR_OFFSET 24UL /* device interrupt ID register */ #define XIIF_V123B_DGIER_OFFSET 28UL /* device global interrupt enable reg */ #define XIIF_V123B_IISR_OFFSET 32UL /* IP interrupt status register */ #define XIIF_V123B_IIER_OFFSET 40UL /* IP interrupt enable register */ #define XIIF_V123B_RESETR_OFFSET 64UL /* reset register */ #define XIIF_V123B_RESET_MASK 0xAUL /* the following constant is used for the device global interrupt enable * register, to enable all interrupts for the device, this is the only bit * in the register */ #define XIIF_V123B_GINTR_ENABLE_MASK 0x80000000UL /* the following constants contain the masks to identify each internal IPIF * condition in the device registers of the IPIF, interrupts are assigned * in the register from LSB to the MSB */ #define XIIF_V123B_ERROR_MASK 1UL /* LSB of the register */ /* The following constants contain interrupt IDs which identify each internal * IPIF condition, this value must correlate with the mask constant for the * error */ #define XIIF_V123B_ERROR_INTERRUPT_ID 0 /* interrupt bit #, (LSB = 0) */ #define XIIF_V123B_NO_INTERRUPT_ID 128 /* no interrupts are pending */ /**************************** Type Definitions *******************************/ /***************** Macros (Inline Functions) Definitions *********************/ /****************************************************************************** * * MACRO: * * XIIF_V123B_RESET * * DESCRIPTION: * * Reset the IPIF component and hardware. This is a destructive operation that * could cause the loss of data since resetting the IPIF of a device also * resets the device using the IPIF and any blocks, such as FIFOs or DMA * channels, within the IPIF. All registers of the IPIF will contain their * reset value when this function returns. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ /* the following constant is used in the reset register to cause the IPIF to * reset */ #define XIIF_V123B_RESET(RegBaseAddress) \ XIo_Out32(RegBaseAddress + XIIF_V123B_RESETR_OFFSET, XIIF_V123B_RESET_MASK) /****************************************************************************** * * MACRO: * * XIIF_V123B_WRITE_DISR * * DESCRIPTION: * * This function sets the device interrupt status register to the value. * This register indicates the status of interrupt sources for a device * which contains the IPIF. The status is independent of whether interrupts * are enabled and could be used for polling a device at a higher level rather * than a more detailed level. * * Each bit of the register correlates to a specific interrupt source within the * device which contains the IPIF. With the exception of some internal IPIF * conditions, the contents of this register are not latched but indicate * the live status of the interrupt sources within the device. Writing any of * the non-latched bits of the register will have no effect on the register. * * For the latched bits of this register only, setting a bit which is zero * within this register causes an interrupt to generated. The device global * interrupt enable register and the device interrupt enable register must be set * appropriately to allow an interrupt to be passed out of the device. The * interrupt is cleared by writing to this register with the bits to be * cleared set to a one and all others to zero. This register implements a * toggle on write functionality meaning any bits which are set in the value * written cause the bits in the register to change to the opposite state. * * This function writes the specified value to the register such that * some bits may be set and others cleared. It is the caller's responsibility * to get the value of the register prior to setting the value to prevent a * destructive behavior. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * Status contains the value to be written to the interrupt status register of * the device. The only bits which can be written are the latched bits which * contain the internal IPIF conditions. The following values may be used to * set the status register or clear an interrupt condition. * * XIIF_V123B_ERROR_MASK Indicates a device error in the IPIF * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_WRITE_DISR(RegBaseAddress, Status) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_DISR_OFFSET, (Status)) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_DISR * * DESCRIPTION: * * This function gets the device interrupt status register contents. * This register indicates the status of interrupt sources for a device * which contains the IPIF. The status is independent of whether interrupts * are enabled and could be used for polling a device at a higher level. * * Each bit of the register correlates to a specific interrupt source within the * device which contains the IPIF. With the exception of some internal IPIF * conditions, the contents of this register are not latched but indicate * the live status of the interrupt sources within the device. * * For only the latched bits of this register, the interrupt may be cleared by * writing to these bits in the status register. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * A status which contains the value read from the interrupt status register of * the device. The bit definitions are specific to the device with * the exception of the latched internal IPIF condition bits. The following * values may be used to detect internal IPIF conditions in the status. * * XIIF_V123B_ERROR_MASK Indicates a device error in the IPIF * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_READ_DISR(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_DISR_OFFSET) /****************************************************************************** * * MACRO: * * XIIF_V123B_WRITE_DIER * * DESCRIPTION: * * This function sets the device interrupt enable register contents. * This register controls which interrupt sources of the device are allowed to * generate an interrupt. The device global interrupt enable register must also * be set appropriately for an interrupt to be passed out of the device. * * Each bit of the register correlates to a specific interrupt source within the * device which contains the IPIF. Setting a bit in this register enables that * interrupt source to generate an interrupt. Clearing a bit in this register * disables interrupt generation for that interrupt source. * * This function writes only the specified value to the register such that * some interrupts source may be enabled and others disabled. It is the * caller's responsibility to get the value of the interrupt enable register * prior to setting the value to prevent an destructive behavior. * * An interrupt source may not be enabled to generate an interrupt, but can * still be polled in the interrupt status register. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * Enable contains the value to be written to the interrupt enable register * of the device. The bit definitions are specific to the device with * the exception of the internal IPIF conditions. The following * values may be used to enable the internal IPIF conditions interrupts. * * XIIF_V123B_ERROR_MASK Indicates a device error in the IPIF * * RETURN VALUE: * * None. * * NOTES: * * Signature: u32 XIIF_V123B_WRITE_DIER(u32 RegBaseAddress, * u32 Enable) * ******************************************************************************/ #define XIIF_V123B_WRITE_DIER(RegBaseAddress, Enable) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_DIER_OFFSET, (Enable)) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_DIER * * DESCRIPTION: * * This function gets the device interrupt enable register contents. * This register controls which interrupt sources of the device * are allowed to generate an interrupt. The device global interrupt enable * register and the device interrupt enable register must also be set * appropriately for an interrupt to be passed out of the device. * * Each bit of the register correlates to a specific interrupt source within the * device which contains the IPIF. Setting a bit in this register enables that * interrupt source to generate an interrupt if the global enable is set * appropriately. Clearing a bit in this register disables interrupt generation * for that interrupt source regardless of the global interrupt enable. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * The value read from the interrupt enable register of the device. The bit * definitions are specific to the device with the exception of the internal * IPIF conditions. The following values may be used to determine from the * value if the internal IPIF conditions interrupts are enabled. * * XIIF_V123B_ERROR_MASK Indicates a device error in the IPIF * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_READ_DIER(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_DIER_OFFSET) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_DIPR * * DESCRIPTION: * * This function gets the device interrupt pending register contents. * This register indicates the pending interrupt sources, those that are waiting * to be serviced by the software, for a device which contains the IPIF. * An interrupt must be enabled in the interrupt enable register of the IPIF to * be pending. * * Each bit of the register correlates to a specific interrupt source within the * the device which contains the IPIF. With the exception of some internal IPIF * conditions, the contents of this register are not latched since the condition * is latched in the IP interrupt status register, by an internal block of the * IPIF such as a FIFO or DMA channel, or by the IP of the device. This register * is read only and is not latched, but it is necessary to acknowledge (clear) * the interrupt condition by performing the appropriate processing for the IP * or block within the IPIF. * * This register can be thought of as the contents of the interrupt status * register ANDed with the contents of the interrupt enable register. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * The value read from the interrupt pending register of the device. The bit * definitions are specific to the device with the exception of the latched * internal IPIF condition bits. The following values may be used to detect * internal IPIF conditions in the value. * * XIIF_V123B_ERROR_MASK Indicates a device error in the IPIF * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_READ_DIPR(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_DIPR_OFFSET) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_DIIR * * DESCRIPTION: * * This function gets the device interrupt ID for the highest priority interrupt * which is pending from the interrupt ID register. This function provides * priority resolution such that faster interrupt processing is possible. * Without priority resolution, it is necessary for the software to read the * interrupt pending register and then check each interrupt source to determine * if an interrupt is pending. Priority resolution becomes more important as the * number of interrupt sources becomes larger. * * Interrupt priorities are based upon the bit position of the interrupt in the * interrupt pending register with bit 0 being the highest priority. The * interrupt ID is the priority of the interrupt, 0 - 31, with 0 being the * highest priority. The interrupt ID register is live rather than latched such * that multiple calls to this function may not yield the same results. A * special value, outside of the interrupt priority range of 0 - 31, is * contained in the register which indicates that no interrupt is pending. This * may be useful for allowing software to continue processing interrupts in a * loop until there are no longer any interrupts pending. * * The interrupt ID is designed to allow a function pointer table to be used * in the software such that the interrupt ID is used as an index into that * table. The function pointer table could contain an instance pointer, such * as to DMA channel, and a function pointer to the function which handles * that interrupt. This design requires the interrupt processing of the device * driver to be partitioned into smaller more granular pieces based upon * hardware used by the device, such as DMA channels and FIFOs. * * It is not mandatory that this function be used by the device driver software. * It may choose to read the pending register and resolve the pending interrupt * priorities on it's own. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * An interrupt ID, 0 - 31, which identifies the highest priority interrupt * which is pending. A value of XIIF_NO_INTERRUPT_ID indicates that there is * no interrupt pending. The following values may be used to identify the * interrupt ID for the internal IPIF interrupts. * * XIIF_V123B_ERROR_INTERRUPT_ID Indicates a device error in the IPIF * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_READ_DIIR(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_DIIR_OFFSET) /****************************************************************************** * * MACRO: * * XIIF_V123B_GLOBAL_INTR_DISABLE * * DESCRIPTION: * * This function disables all interrupts for the device by writing to the global * interrupt enable register. This register provides the ability to disable * interrupts without any modifications to the interrupt enable register such * that it is minimal effort to restore the interrupts to the previous enabled * state. The corresponding function, XIpIf_GlobalIntrEnable, is provided to * restore the interrupts to the previous enabled state. This function is * designed to be used in critical sections of device drivers such that it is * not necessary to disable other device interrupts. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_GINTR_DISABLE(RegBaseAddress) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_DGIER_OFFSET, 0) /****************************************************************************** * * MACRO: * * XIIF_V123B_GINTR_ENABLE * * DESCRIPTION: * * This function writes to the global interrupt enable register to enable * interrupts from the device. This register provides the ability to enable * interrupts without any modifications to the interrupt enable register such * that it is minimal effort to restore the interrupts to the previous enabled * state. This function does not enable individual interrupts as the interrupt * enable register must be set appropriately. This function is designed to be * used in critical sections of device drivers such that it is not necessary to * disable other device interrupts. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_GINTR_ENABLE(RegBaseAddress) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_DGIER_OFFSET, \ XIIF_V123B_GINTR_ENABLE_MASK) /****************************************************************************** * * MACRO: * * XIIF_V123B_IS_GINTR_ENABLED * * DESCRIPTION: * * This function determines if interrupts are enabled at the global level by * reading the gloabl interrupt register. This register provides the ability to * disable interrupts without any modifications to the interrupt enable register * such that it is minimal effort to restore the interrupts to the previous * enabled state. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * XTRUE if interrupts are enabled for the IPIF, XFALSE otherwise. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_IS_GINTR_ENABLED(RegBaseAddress) \ (XIo_In32((RegBaseAddress) + XIIF_V123B_DGIER_OFFSET) == \ XIIF_V123B_GINTR_ENABLE_MASK) /****************************************************************************** * * MACRO: * * XIIF_V123B_WRITE_IISR * * DESCRIPTION: * * This function sets the IP interrupt status register to the specified value. * This register indicates the status of interrupt sources for the IP of the * device. The IP is defined as the part of the device that connects to the * IPIF. The status is independent of whether interrupts are enabled such that * the status register may also be polled when interrupts are not enabled. * * Each bit of the register correlates to a specific interrupt source within the * IP. All bits of this register are latched. Setting a bit which is zero * within this register causes an interrupt to be generated. The device global * interrupt enable register and the device interrupt enable register must be set * appropriately to allow an interrupt to be passed out of the device. The * interrupt is cleared by writing to this register with the bits to be * cleared set to a one and all others to zero. This register implements a * toggle on write functionality meaning any bits which are set in the value * written cause the bits in the register to change to the opposite state. * * This function writes only the specified value to the register such that * some status bits may be set and others cleared. It is the caller's * responsibility to get the value of the register prior to setting the value * to prevent an destructive behavior. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * Status contains the value to be written to the IP interrupt status * register. The bit definitions are specific to the device IP. * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_WRITE_IISR(RegBaseAddress, Status) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_IISR_OFFSET, (Status)) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_IISR * * DESCRIPTION: * * This function gets the contents of the IP interrupt status register. * This register indicates the status of interrupt sources for the IP of the * device. The IP is defined as the part of the device that connects to the * IPIF. The status is independent of whether interrupts are enabled such * that the status register may also be polled when interrupts are not enabled. * * Each bit of the register correlates to a specific interrupt source within the * device. All bits of this register are latched. Writing a 1 to a bit within * this register causes an interrupt to be generated if enabled in the interrupt * enable register and the global interrupt enable is set. Since the status is * latched, each status bit must be acknowledged in order for the bit in the * status register to be updated. Each bit can be acknowledged by writing a * 0 to the bit in the status register. * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * A status which contains the value read from the IP interrupt status register. * The bit definitions are specific to the device IP. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_READ_IISR(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_IISR_OFFSET) /****************************************************************************** * * MACRO: * * XIIF_V123B_WRITE_IIER * * DESCRIPTION: * * This function sets the IP interrupt enable register contents. This register * controls which interrupt sources of the IP are allowed to generate an * interrupt. The global interrupt enable register and the device interrupt * enable register must also be set appropriately for an interrupt to be * passed out of the device containing the IPIF and the IP. * * Each bit of the register correlates to a specific interrupt source within the * IP. Setting a bit in this register enables the interrupt source to generate * an interrupt. Clearing a bit in this register disables interrupt generation * for that interrupt source. * * This function writes only the specified value to the register such that * some interrupt sources may be enabled and others disabled. It is the * caller's responsibility to get the value of the interrupt enable register * prior to setting the value to prevent an destructive behavior. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * Enable contains the value to be written to the IP interrupt enable register. * The bit definitions are specific to the device IP. * * RETURN VALUE: * * None. * * NOTES: * * None. * ******************************************************************************/ #define XIIF_V123B_WRITE_IIER(RegBaseAddress, Enable) \ XIo_Out32((RegBaseAddress) + XIIF_V123B_IIER_OFFSET, (Enable)) /****************************************************************************** * * MACRO: * * XIIF_V123B_READ_IIER * * DESCRIPTION: * * * This function gets the IP interrupt enable register contents. This register * controls which interrupt sources of the IP are allowed to generate an * interrupt. The global interrupt enable register and the device interrupt * enable register must also be set appropriately for an interrupt to be * passed out of the device containing the IPIF and the IP. * * Each bit of the register correlates to a specific interrupt source within the * IP. Setting a bit in this register enables the interrupt source to generate * an interrupt. Clearing a bit in this register disables interrupt generation * for that interrupt source. * * ARGUMENTS: * * RegBaseAddress contains the base address of the IPIF registers. * * RETURN VALUE: * * The contents read from the IP interrupt enable register. The bit definitions * are specific to the device IP. * * NOTES: * * Signature: u32 XIIF_V123B_READ_IIER(u32 RegBaseAddress) * ******************************************************************************/ #define XIIF_V123B_READ_IIER(RegBaseAddress) \ XIo_In32((RegBaseAddress) + XIIF_V123B_IIER_OFFSET) /************************** Function Prototypes ******************************/ /* * Initialization Functions */ XStatus XIpIfV123b_SelfTest(u32 RegBaseAddress, u8 IpRegistersWidth); #endif /* end of protection macro */