/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_PX_IOAPI_H #define _SYS_PX_IOAPI_H #pragma ident "%Z%%M% %I% %E% SMI" #ifdef __cplusplus extern "C" { #endif #ifndef _ASM /* * SUN4V IO Data Definitions * * cpuid - A unique opaque value which represents a target cpu. * * devhandle - Device handle. The device handle uniquely * identifies a SUN4V device. It consists of the * the lower 28-bits of the hi-cell of the first * entry of the SUN4V device's "reg" property as defined * by the SUN4V Bus Binding to Open Firmware. * * devino - Device Interrupt Number. An unsigned integer representing * an interrupt within a specific device. * * sysino - System Interrupt Number. A 64-bit unsigned integer * representing a unique interrupt within a "system". * * intr_state - A flag representing the interrupt state for a * a given sysino. The state values are defined as: * * INTR_IDLE 0 * INTR_RECEIVED 1 * INTR_DELIVERED 2 * * intr_valid_state - A flag representing the 'valid' state for * a given sysino. The state values are defined as: * * INTR_NOTVALID 0 sysino not enabled * INTR_VALID 1 sysino enabled */ typedef uint64_t devhandle_t; typedef uint32_t cpuid_t; typedef uint32_t devino_t; typedef uint64_t sysino_t; typedef enum intr_state { INTR_IDLE_STATE = (uint32_t)0, INTR_RECEIVED_STATE = (uint32_t)1, INTR_DELIVERED_STATE = (uint32_t)2 } intr_state_t; typedef enum intr_valid_state { INTR_NOTVALID = (uint32_t)0, INTR_VALID = (uint32_t)1 } intr_valid_state_t; /* * PCI IO Data Definitions * * tsbnum - TSB Number. Identifies which io-tsb is used. * For this version of the spec, tsbnum must be zero. * * tsbindex - TSB Index. Identifies which entry in the tsb is * is used. The first entry is zero. * * tsbid - A 64-bit aligned data structure which contains * a tsbnum and a tsbindex. * bits 63:32 contain the tsbnum. * bits 31:00 contain the tsbindex. * * io_attributes - IO Attributes for iommu mappings. * Attributes for iommu mappings. One or more of the * following attribute bits stored in a 64-bit unsigned int. * * PCI_MAP_ATTR_READ 0x01 - xfr direction is from memory * PCI_MAP_ATTR_WRITE 0x02 - xfr direction is to memory * * Bits 63:2 are unused and must be set to zero for this * version of the specification. * * Note: For compatibility with future versions of this * specification, the caller must set 63:2 to zero. * The implementation shall ignore bits 63:2 * * r_addr - 64-bit Real Address. * * io_addr - 64-bit IO Address. * * pci_device - PCI device address. A PCI device address * identifies a specific device on a specific PCI * bus segment. A PCI device address is a 32-bit unsigned * integer with the following format: * * 00000000.bbbbbbbb.dddddfff.00000000 * * Where: * * bbbbbbbb is the 8-bit pci bus number * ddddd is the 5-bit pci device number * fff is the 3-bit pci function number * * 00000000 is the 8-bit literal zero. * * pci_config_offset - PCI Configuration Space offset. * * For conventional PCI, an unsigned integer in the range * 0 .. 255 representing the offset of the field in pci config * space. * * For PCI implementations with extended configuration space, * an unsigned integer in the range 0 .. 4095, representing * the offset of the field in configuration space. Conventional * PCI config space is offset 0 .. 255. Extended config space * is offset 256 .. 4095 * * Note: For pci config space accesses, the offset must be 'size' * aligned. * * error_flag - Error flag * * A return value specifies if the action succeeded * or failed, where: * * 0 - No error occurred while performing the service. * non-zero - Error occurred while performing the service. * * io_sync_direction - "direction" definition for pci_dma_sync * * A value specifying the direction for a memory/io sync * operation, The direction value is a flag, one or both * directions may be specified by the caller. * * 0x01 - For device (device read from memory) * 0x02 - For cpu (device write to memory) * * io_page_list - A list of io_page_addresses. An io_page_address * is an r_addr. * * io_page_list_p - A pointer to an io_page_list. */ typedef uint32_t tsbnum_t; typedef uint32_t tsbindex_t; typedef uint64_t tsbid_t; typedef uint64_t r_addr_t; typedef uint64_t io_addr_t; typedef uint64_t io_page_list_t; typedef uint32_t pages_t; typedef uint32_t error_flag_t; typedef uint32_t pci_config_offset_t; typedef uint64_t pci_device_t; #define PCI_TSB_INDEX 0 #define PCI_TSB_INDEX_MASK 0xFFFFFFFF #define PCI_TSB_NUM 32 #define PCI_TSB_NUM_MASK 0xFFFFFFFF #define PCI_TSBID(tsbnum, tsbindex) \ ((((tsbid_t)tsbnum & PCI_TSB_NUM_MASK) << PCI_TSB_NUM) | \ (((tsbid_t)tsbindex & PCI_TSB_INDEX_MASK) << PCI_TSB_INDEX)) #define PCI_TSBID_TO_TSBNUM(tsbid) \ ((tsbid >> PCI_TSB_NUM) & PCI_TSB_NUM_MASK) #define PCI_TSBID_TO_TSBINDEX(tsbid) \ ((tsbid >> PCI_TSB_INDEX) & PCI_TSB_INDEX_MASK) typedef enum io_attributes { PCI_MAP_ATTR_READ = (uint32_t)0x01, PCI_MAP_ATTR_WRITE = (uint32_t)0x02 } io_attributes_t; typedef enum io_sync_direction { IO_SYNC_DEVICE = (uint32_t)0x01, IO_SYNC_CPU = (uint32_t)0x02 } io_sync_direction_t; typedef enum pci_config_size { PCI_CFG_SIZE_BYTE = 0, PCI_CFG_SIZE_WORD, PCI_CFG_SIZE_DWORD } pci_config_size_t; typedef union pci_cfg_data { uint8_t b; uint16_t w; uint32_t dw; uint64_t qw; } pci_cfg_data_t; /* * MSI Definitions * * MSI - Message Signaled Interrupt * * Message Signaled Interrupt as defined in the PCI Local Bus * Specification and the PCI Express Base Specification. * A device signals an interrupt via MSI using a posted * write cycle to an address specified by system software * using a data value specified by system software. * The MSI capability data structure contains fields for * the PCI address and data values the device uses when * sending an MSI message on the bus. MSI-X is an extended * form of MSI, but uses the same mechanism for signaling * the interrupt as MSI. For the purposes of this document, * the term "MSI" refers to MSI or MSI-X. * * Root complexes that support MSI define an address range * and set of data values that can be used to signal MSIs. * * SUN4V/pci requirements for MSI: * * The root complex defines two address ranges. One in * the 32-bit pci memory space and one in the 64-bit * pci memory address space used as the target of a posted * write to signal an MSI. * * The root complex treats any write to these address * ranges as signaling an MSI, however, only the data * value used in the posted write signals the MSI. * * * MSI EQ - MSI Event Queue * * The MSI Event Queue is a page-aligned main memory data * structure used to store MSI data records. * * Each root port supports several MSI EQs, and each EQ has a * system interrupt associated with it, and can be targeted * (individually) to any cpu. The number of MSI EQs supported * by a root complex is described by a property defined in [3]. * Each MSI EQ must be large enough to contain all possible MSI * data records generated by any one PCI root port. The number * of entries in each MSI EQ is described by a property defined * in [3]. * * Each MSI EQ is compliant with the definition of interrupt * queues described in [5], however, instead of accessing the * queue head/tail registers via ASI-based registers, an API * is provided to access the head/tail registers. * * The SUN4V/pci compliant root complex has the ability to * generate a system interrupt when the MSI EQ is non-empty. * * MSI/Message/INTx Data Record format * * Each data record consists of 64 bytes of data, aligned * on a 64-byte boundary. * * The data record is defined as follows: * * * 6666555555555544444444443333333333222222222211111111110000000000 * 3210987654321098765432109876543210987654321098765432109876543210 * * 0x00: VVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVxxxxxxxxxxxxxxxxxxxxxxxxTTTTTTTT * 0x08: IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII * 0x10: xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx * 0x18: SSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS * 0x20: xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxRRRRRRRRRRRRRRRR * 0x28: AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA * 0x30: DDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDD * 0x38: xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx * * Where, * * xx..xx are unused bits and must be ignored by sw. * * VV..VV is the version number of this data record * * For this release of the spec, the version number * field must be zero. * * TTTTTTTT is the data record type: * * Upper 4 bits are reserved, and must be zero * * 0000 - Not an MSI data record - reserved for sw use. * 0001 - MSG * 0010 - MSI32 * 0011 - MSI64 * 0010 - Reserved * ... * 0111 - Reserved * 1000 - INTx * 1001 - Reserved * ... * 1110 - Reserved * 1111 - Not an MSI data record - reserved for sw use. * * All other encodings are reserved. * * II..II is the sysino for INTx (sw defined value), * otherwise zero. * * SS..SS is the message timestamp if available. * If supported by the implementation, a non-zero * value in this field is a copy of the %stick register * at the time the message is created. * * If unsupported, this field will contain zero. * * RR..RR is the requester ID of the device that initiated the MSI/MSG * and has the following format: * * bbbbbbbb.dddddfff * * Where bb..bb is the bus number, * dd..dd is the device number * and fff is the function number. * * Note that for PCI devices or any message where * the requester is unknown, this may be zero, * or the device-id of an intermediate bridge. * * For intx messages, this field should be ignored. * * AA..AA is the MSI address. For MSI32, the upper 32-bits must be zero. * (for data record type MSG or INTx, this field is ignored) * * DD..DD is the MSI/MSG data or INTx number * * For MSI-X, bits 31..0 contain the data from the MSI packet * which is the msi-number. bits 63..32 shall be zero. * * For MSI, bits 15..0 contain the data from the MSI message * which is the msi-number. bits 63..16 shall be zero * * For MSG data, the message code and message routing code * are encoded as follows: * * 63:32 - 0000.0000.0000.0000.0000.0000.GGGG.GGGG * 32:00 - 0000.0000.0000.0CCC.0000.0000.MMMM.MMMM * * Where, * * GG..GG is the target-id of the message in the * following form: * * bbbbbbbb.dddddfff * * where bb..bb is the target bus number. * ddddd is the target deviceid * fff is the target function number. * * CCC is the message routing code as defined by [4] * * MM..MM is the message code as defined by [4] * * For INTx data, bits 63:2 must be zero and * the low order 2 bits are defined as follows: * * 00 - INTA * 01 - INTB * 10 - INTC * 11 - INTD * * cpuid - A unique opaque value which represents a target cpu. * * devhandle - Device handle. The device handle uniquely identifies a * SUN4V device. It consists of the the lower 28-bits of the hi-cell * of the first entry of the SUN4V device's "reg" property as defined * by the SUN4V Bus Binding to Open Firmware. * * msinum - A value defining which MSI is being used. * * msiqhead - The index value of the current head index for a given * MSI-EQ. * * msiqtail - The index value of the current tail index for a given * MSI-EQ. * * msitype - Type specifier for MSI32 or MSI64 * 0 - type is MSI32 * 1 - type is MSI64 * * msiqid - A number from 0 .. 'number of MSI-EQs - 1', defining * which MSI EQ within the device is being used. * * msiqstate - An unsigned integer containing one of the * following values: * * PCI_MSIQSTATE_IDLE 0 # idle (non-error) state * PCI_MSIQSTATE_ERROR 1 # error state * * msiqvalid - An unsigned integer containing one of the * following values: * * PCI_MSIQ_INVALID 0 # disabled/invalid * PCI_MSIQ_VALID 1 # enabled/valid * * msistate - An unsigned integer containing one of the following * values: * * PCI_MSISTATE_IDLE 0 # idle/not enabled * PCI_MSISTATE_DELIVERED 1 # MSI Delivered * * msivalid - An unsigned integer containing one of the * following values: * * PCI_MSI_INVALID 0 # disabled/invalid * PCI_MSI_VALID 1 # enabled/valid * * msgtype - A value defining which MSG type is being used. An unsigned * integer containing one of the following values: * (as per PCIe spec 1.0a) * * PCIE_PME_MSG 0x18 PME message * PCIE_PME_ACK_MSG 0x1b PME ACK message * PCIE_CORR_MSG 0x30 Correctable message * PCIE_NONFATAL_MSG 0x31 Non fatal message * PCIE_FATAL_MSG 0x33 Fatal message */ typedef uint32_t msinum_t; typedef uint32_t msiqid_t; typedef uint32_t msgcode_t; typedef uint64_t msiqhead_t; typedef uint64_t msiqtail_t; /* MSIQ state */ typedef enum pci_msiq_state { PCI_MSIQ_STATE_IDLE = (uint32_t)0, /* idle (non-error) state */ PCI_MSIQ_STATE_ERROR = (uint32_t)1 /* error state */ } pci_msiq_state_t; /* MSIQ valid */ typedef enum pci_msiq_valid_state { PCI_MSIQ_INVALID = (uint32_t)0, /* disabled/invalid */ PCI_MSIQ_VALID = (uint32_t)1 /* enabled/valid */ } pci_msiq_valid_state_t; /* MSIQ Record data structure */ typedef struct msiq_rec { uint64_t msiq_rec_version : 32, /* DW 0 - 63:32 */ msiq_rec_rsvd0 : 24, /* DW 0 - 31:09 */ msiq_rec_type : 8; /* DW 0 - 07:00 */ uint64_t msiq_rec_intx; /* DW 1 */ uint64_t msiq_rec_rsvd1; /* DW 2 */ uint64_t msiq_rec_timestamp; /* DW 3 */ uint64_t msiq_rec_rsvd2 : 48, /* DW 4 - 63:16 */ msiq_rec_rid : 16; /* DW 4 - 15:00 */ uint64_t msiq_rec_msi_addr; /* DW 5 - 63:00 */ union { struct { uint64_t msix_rsvd0 : 32, /* DW 6 - 63:32 */ msix_data : 32; /* DW 6 - 31:00 */ } msix; struct { uint64_t msi_rsvd0 : 48, /* DW 6 - 63:16 */ msi_data: 16; /* DW 6 - 15:00 */ } msi; struct { uint64_t msg_rsvd0: 24, /* DW 6 - 63:40 */ msg_targ: 8, /* DW 6 - 39:32 */ msg_rsvd1: 13, /* DW 6 - 31:19 */ msg_route: 3, /* DW 6 - 18:16 */ msg_rsvd2: 8, /* DW 6 - 15:08 */ msg_code: 8; /* DW 6 - 07:00 */ } msg; } msiq_rec_data; uint64_t msiq_rec_rsvd3; /* DW 7 */ } msiq_rec_t; /* MSIQ Record type */ typedef enum msiq_rec_type { MSG_REC = (uint32_t)1, /* PCIe message record */ MSI32_REC = (uint32_t)2, /* MSI32 record */ MSI64_REC = (uint32_t)3, /* MSI64 record */ INTX_REC = (uint32_t)8 /* INTx record */ } msiq_rec_type_t; /* MSIQ Record type */ typedef enum msi_type { MSI32_TYPE = (uint32_t)0, /* MSI32 type */ MSI64_TYPE = (uint32_t)1 /* MSI64 type */ } msi_type_t; /* MSI state */ typedef enum pci_msi_state { PCI_MSI_STATE_IDLE = (uint32_t)0, /* idle/not enabled */ PCI_MSI_STATE_DELIVERED = (uint32_t)1 /* MSI delivered */ } pci_msi_state_t; /* MSI valid */ typedef enum pci_msi_valid_state { PCI_MSI_INVALID = (uint32_t)0, /* disabled/invalid */ PCI_MSI_VALID = (uint32_t)1 /* enabled/valid */ } pci_msi_valid_state_t; /* MSG valid */ typedef enum pcie_msg_valid_state { PCIE_MSG_INVALID = (uint32_t)0, /* disabled/invalid */ PCIE_MSG_VALID = (uint32_t)1 /* enabled/valid */ } pcie_msg_valid_state_t; /* PCIe MSG types */ typedef enum pcie_msg_type { PCIE_PME_MSG = (uint64_t)0x18, /* PME message */ PCIE_PME_ACK_MSG = (uint64_t)0x1b, /* PME ACK message */ PCIE_CORR_MSG = (uint64_t)0x30, /* Correctable message */ PCIE_NONFATAL_MSG = (uint64_t)0x31, /* Non fatal message */ PCIE_FATAL_MSG = (uint64_t)0x33 /* Fatal message */ } pcie_msg_type_t; #endif /* _ASM */ #ifdef __cplusplus } #endif #endif /* _SYS_PX_IOAPI_H */