XIO3130 Data Manual PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Literature Number: SLLS693D May 2007 – Revised August 2008 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Contents 1 2 Features ............................................................................................................................ 11 Introduction ....................................................................................................................... 12 2.1 2.2 2.3 2.4 2.5 2.6 3 3.2 3.3 3.4 3.5 Power-Up/Power-Down Sequencing..................................................................................... 3.1.1 Power-Up Sequence ............................................................................................ 3.1.2 Power-Down Sequence......................................................................................... Express Interface ........................................................................................................... 3.2.1 External Reference Clock ...................................................................................... 3.2.2 Clock Generator ................................................................................................. 3.2.3 Beacon ............................................................................................................ 3.2.4 WAKE ............................................................................................................ 3.2.5 Initial Flow Control Credits ..................................................................................... 3.2.6 PCI Express Message Transactions .......................................................................... GPIO Terminals ............................................................................................................ Serial EEPROM ............................................................................................................ 3.4.1 Serial Bus Interface Implementation .......................................................................... 3.4.2 Serial Bus Interface Protocol................................................................................... 3.4.3 Serial Bus EEPROM Application .............................................................................. 3.4.4 Accessing Serial Bus Devices Through Software ........................................................... Switch Reset Features..................................................................................................... 22 22 23 23 23 23 24 24 24 24 25 25 26 26 28 31 31 XIO3130 Configuration Register Space ................................................................................. 33 4.1 4.2 2 12 12 13 13 14 17 Description ........................................................................................................................ 22 3.1 4 Description .................................................................................................................. Related Documents ........................................................................................................ Document Conventions .................................................................................................... Ordering Information ...................................................................................................... Terminal Assignments ..................................................................................................... Terminal Descriptions ...................................................................................................... PCI Configuration Register Space Overview ........................................................................... PCI Express Upstream Port Registers .................................................................................. 4.2.1 PCI Configuration Space (Upstream Port) Register Map .................................................. 4.2.2 Vendor ID Register .............................................................................................. 4.2.3 Device ID Register .............................................................................................. 4.2.4 Command Registers ............................................................................................ 4.2.5 Status Register .................................................................................................. 4.2.6 Class Code and Revision ID Register ........................................................................ 4.2.7 Cache Line Size Register ...................................................................................... 4.2.8 Primary Latency Timer Register ............................................................................... 4.2.9 Header Type Register .......................................................................................... 4.2.10 BIST Register .................................................................................................... 4.2.11 Primary Bus Number ............................................................................................ 4.2.12 Secondary Bus Number ........................................................................................ 4.2.13 Subordinate Bus Number....................................................................................... 4.2.14 Secondary Latency Timer Register ........................................................................... 4.2.15 I/O Base Register................................................................................................ 4.2.16 I/O Limit Register ................................................................................................ 4.2.17 Secondary Status Register ..................................................................................... 4.2.18 Memory Base Register ......................................................................................... 4.2.19 Memory Limit Register .......................................................................................... 4.2.20 Pre-fetchable Memory Base Register......................................................................... 4.2.21 Pre-Fetchable Memory Limit Register ........................................................................ Contents 33 34 35 36 36 36 37 39 39 39 40 40 40 40 41 41 41 42 42 43 43 43 44 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.22 4.2.23 4.2.24 4.2.25 4.2.26 4.2.27 4.2.28 4.2.29 4.2.30 4.2.31 4.2.32 4.2.33 4.2.34 4.2.35 4.2.36 4.2.37 4.2.38 4.2.39 4.2.40 4.2.41 4.2.42 4.2.43 4.2.44 4.2.45 4.2.46 4.2.47 4.2.48 4.2.49 4.2.50 4.2.51 4.2.52 4.2.53 4.2.54 4.2.55 4.2.56 4.2.57 4.2.58 4.2.59 4.2.60 4.2.61 4.2.62 4.2.63 4.2.64 4.2.65 4.2.66 4.2.67 4.2.68 4.2.69 4.2.70 4.2.71 4.2.72 4.2.73 4.2.74 Pre-Fetchable Base Upper 32 Bits Register ................................................................. Pre-fetchable Limit Upper 32 Bits Register .................................................................. I/O Base Upper 16 Bits Register .............................................................................. I/O Limit Upper 16 Bits Register ............................................................................... Capabilities Pointer Register ................................................................................... Interrupt Line Register .......................................................................................... Interrupt Pin Register ........................................................................................... Bridge Control Register ......................................................................................... Capability ID Register ........................................................................................... Next-Item Pointer Register ..................................................................................... Power Management Capabilities Register ................................................................... Power Management Control/Status Register ................................................................ Power Management Bridge Support Extension Register .................................................. Power Management Data Register ........................................................................... MSI Capability ID Register ..................................................................................... Next-Item Pointer Register ..................................................................................... MSI Message Control Register ................................................................................ MSI Message Address Register ............................................................................... MSI Message Upper Address Register ....................................................................... MSI Message Data Register ................................................................................... Capability ID Register ........................................................................................... Next-Item Pointer Register ..................................................................................... Subsystem Vendor ID Register ................................................................................ Subsystem ID Register ......................................................................................... PCI Express Capability ID Register ........................................................................... Next-Item Pointer Register ..................................................................................... PCI Express Capabilities Register ............................................................................ Device Capabilities Register ................................................................................... Device Control Register ........................................................................................ Device Status Register ......................................................................................... Link Capabilities Register ...................................................................................... Link Control Register ............................................................................................ Link Status Register ............................................................................................. Serial Bus Data Register ....................................................................................... Serial Bus Index Register ...................................................................................... Serial Bus Slave Address Register............................................................................ Serial Bus Control and Status Register ...................................................................... Upstream Port Link PM Latency Register .................................................................... Global Chip Control Register .................................................................................. GPIO A Control Register ....................................................................................... GPIO B Control Register ....................................................................................... GPIO C Control Register ....................................................................................... GPIO D Control Register ....................................................................................... GPIO Data Register ............................................................................................. TI Proprietary Register .......................................................................................... TI Proprietary Register .......................................................................................... TI Proprietary Register .......................................................................................... TI Proprietary Register .......................................................................................... TI Proprietary Register .......................................................................................... TI Proprietary Register .......................................................................................... Subsystem Access Register ................................................................................... General Control Register ....................................................................................... Downstream Ports Link PM Latency Register ............................................................... Contents 44 45 45 45 45 46 46 46 48 48 48 49 50 50 50 50 51 51 52 52 52 52 53 53 53 54 54 54 55 56 57 58 59 59 59 60 60 61 63 64 66 68 70 72 75 75 75 76 76 76 77 77 78 3 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3 4 www.ti.com 4.2.75 Global Switch Control Register ................................................................................ 79 4.2.76 Advanced Error Reporting Capability ID Register ........................................................... 80 4.2.77 Next Capability Offset/Capability Version Register ......................................................... 80 4.2.78 Uncorrectable Error Status Register .......................................................................... 80 4.2.79 Uncorrectable Error Mask Register ........................................................................... 81 4.2.80 Uncorrectable Error Severity Register ........................................................................ 82 4.2.81 Correctable Error Status Register ............................................................................. 83 4.2.82 Correctable Error Mask Register .............................................................................. 84 4.2.83 Advanced Error Capabilities and Control Register .......................................................... 85 4.2.84 Header Log Register ............................................................................................ 85 PCI Express Downstream Port Registers ............................................................................... 86 4.3.1 PCI Configuration Space (Downstream Port) Register Map ............................................... 86 4.3.2 Vendor ID Register .............................................................................................. 87 4.3.3 Device ID Register .............................................................................................. 87 4.3.4 Command Register .............................................................................................. 87 4.3.5 Status Register .................................................................................................. 88 4.3.6 Class Code and Revision ID Register ........................................................................ 89 4.3.7 Cache Line Size Register ...................................................................................... 90 4.3.8 Primary Latency Timer Register ............................................................................... 90 4.3.9 Header Type Register .......................................................................................... 90 4.3.10 BIST Register .................................................................................................... 90 4.3.11 Primary Bus Number ............................................................................................ 91 4.3.12 Secondary Bus Number ........................................................................................ 91 4.3.13 Subordinate Bus Number....................................................................................... 91 4.3.14 Secondary Latency Timer Register ........................................................................... 91 4.3.15 I/O Base Register................................................................................................ 92 4.3.16 I/O Limit Register ................................................................................................ 92 4.3.17 Secondary Status Register ..................................................................................... 92 4.3.18 Memory Base Register ......................................................................................... 93 4.3.19 Memory Limit Register .......................................................................................... 94 4.3.20 Pre-fetchable Memory Base Register......................................................................... 94 4.3.21 Pre-fetchable Memory Limit Register ......................................................................... 94 4.3.22 Pre-fetchable Base Upper 32 Bits Register .................................................................. 95 4.3.23 Pre-fetchable Limit Upper 32 Bits Register .................................................................. 95 4.3.24 I/O Base Upper 16 Bits Register .............................................................................. 96 4.3.25 I/O Limit Upper 16 Bits Register ............................................................................... 96 4.3.26 Capabilities Pointer Register ................................................................................... 96 4.3.27 Interrupt Line Register .......................................................................................... 97 4.3.28 Interrupt Pin Register ........................................................................................... 97 4.3.29 Bridge Control Register ......................................................................................... 97 4.3.30 Capability ID Register ........................................................................................... 99 4.3.31 Next-Item Pointer Register ..................................................................................... 99 4.3.32 Power Management Capabilities Register ................................................................... 99 4.3.33 Power Management Control/Status Register............................................................... 100 4.3.34 Power Management Bridge Support Extension Register ................................................. 101 4.3.35 Power Management Data Register .......................................................................... 101 4.3.36 MSI Capability ID Register .................................................................................... 101 4.3.37 Next-Item Pointer Register.................................................................................... 101 4.3.38 MSI Message Control Register............................................................................... 102 4.3.39 MSI Message Address Register ............................................................................. 102 4.3.40 MSI Message Upper Address Register ..................................................................... 103 4.3.41 MSI Message Data Register.................................................................................. 103 4.3.42 Capability ID Register ......................................................................................... 103 Contents Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.43 4.3.44 4.3.45 4.3.46 4.3.47 4.3.48 4.3.49 4.3.50 4.3.51 4.3.52 4.3.53 4.3.54 4.3.55 4.3.56 4.3.57 4.3.58 4.3.59 4.3.60 4.3.61 4.3.62 4.3.63 4.3.64 4.3.65 4.3.66 4.3.67 4.3.68 4.3.69 4.3.70 4.3.71 4.3.72 5 104 104 104 104 105 105 105 106 107 108 109 110 110 112 114 115 115 116 116 118 118 119 119 119 120 121 122 123 123 124 PCI Hot Plug Implementation Overview ............................................................................... 125 5.1 5.2 6 Next-Item Pointer Register.................................................................................... Subsystem Vendor ID Register .............................................................................. Subsystem ID Register ........................................................................................ PCI Express Capability ID Register ......................................................................... Next-Item Pointer Register.................................................................................... PCI Express Capabilities Register ........................................................................... Device Capabilities Register .................................................................................. Device Control Register ....................................................................................... Device Status Register ........................................................................................ Link Capabilities Register ..................................................................................... Link Control Register .......................................................................................... Link Status Register ........................................................................................... Slot Capabilities Register ..................................................................................... Slot Control Register .......................................................................................... Slot Status Register............................................................................................ TI Proprietary Register ........................................................................................ TI Proprietary Register ........................................................................................ TI Proprietary Register ........................................................................................ General Control Register...................................................................................... L0s Idle Timeout Register..................................................................................... General Slot Info Register .................................................................................... Advanced Error Reporting Capabilities ID Register ....................................................... Next Capability Offset/Capability Version Register ........................................................ Uncorrectable Error Status Register......................................................................... Uncorrectable Error Mask Register .......................................................................... Uncorrectable Error Severity Register ...................................................................... Correctable Error Status Register ........................................................................... Correctable Error Mask Register............................................................................. Advanced Error Capabilities and Control Register ........................................................ Header Log Register .......................................................................................... PCI Hot Plug Architecture Overview ................................................................................... PCI Hot Plug Timing ...................................................................................................... 5.2.1 Power-Up Cycle ................................................................................................ 5.2.1.1 NonPCI Hot Plug Power-Up Cycle ................................................................ 5.2.1.2 PCI Hot Plug Power-Up Cycle With PWRGDn Feedback ..................................... 5.2.1.3 PCI Hot Plug Power-Up Cycle With No PWRGDn Feedback ................................. 5.2.2 Power-Down Cycles ........................................................................................... 5.2.2.1 Normal Power-Down ................................................................................ 5.2.2.2 Surprise Removal ................................................................................... 5.2.2.3 PWRGDn De-Assertion ............................................................................ 5.2.3 PMI_Turn_Off and PME_To_Ack Messages ............................................................... 5.2.4 Debounce Circuits ............................................................................................. 5.2.5 HP_INTX Pin ................................................................................................... 125 126 126 127 127 127 128 128 129 129 129 130 130 Electrical Characteristics ................................................................................................... 131 6.1 6.2 6.3 6.4 6.5 6.6 6.7 Absolute Maximum Ratings ............................................................................................. Recommended Operating Conditions .................................................................................. PCI Express Differential Transmitter Output Ranges ................................................................ PCI Express Differential Receiver Input Ranges ..................................................................... PCI Express Differential Reference Clock Input Ranges ............................................................ PCI Express Reference Clock Output Requirements ................................................................ 3.3-V I/O Electrical Characteristics ..................................................................................... Contents 131 131 132 133 134 135 136 5 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 6.8 6 www.ti.com POWER CONSUMPTION ............................................................................................... 136 Contents Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 List of Figures 3-1 Block Diagram ..................................................................................................................... 22 3-2 Power-Up Sequence Diagram ................................................................................................... 23 3-3 Power-Down Sequence Diagram ............................................................................................... 23 3-4 Serial EEPROM Applications .................................................................................................... 26 3-5 Serial-Bus Start/Stop Conditions and Bit Transfers .......................................................................... 27 3-6 Serial-Bus Protocol Acknowledge............................................................................................... 27 3-7 Serial-Bus Protocol – Byte Write ................................................................................................ 27 3-8 Serial-Bus Protocol – Byte Read ................................................................................................ 28 3-9 Serial-Bus Protocol – Multiple-Byte Read 4-1 5-1 5-2 5-3 5-4 5-5 5-6 ..................................................................................... 28 XIO3130 Enumerations Topology............................................................................................... 34 NonPCI Hot Plug Power-Up Cycle ............................................................................................ 127 PCI Hot Plug Power-Up Cycle With PWFRDn Feedback .................................................................. 127 PCI Hot Plug Power-Up Cycle With No PWGRDn Feedback ............................................................. 128 Normal Power-Down ............................................................................................................ 128 Surprise Removal ................................................................................................................ 129 Effect When PWFRGn Goes Low ............................................................................................. 129 List of Figures 7 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com List of Tables 2-1 2-2 2-3 2-4 2-5 2-6 2-7 2-8 2-9 2-10 2-11 3-1 3-2 3-3 3-4 3-5 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9 4-10 4-11 4-12 4-13 4-14 4-15 4-16 4-17 4-18 4-19 4-20 4-21 4-22 4-23 8 ................................................................................................ XIO3130 Terminals Sorted Alphanumerically ................................................................................. XIO3130 Signal Names Sorted Alphabetically ................................................................................ Power Supply Terminals ......................................................................................................... Combined Power Terminals ..................................................................................................... Ground Terminals ................................................................................................................. PCI Express Reference Clock Terminals ...................................................................................... PCI Express Terminals ........................................................................................................... PCI Hot Plug Strapping Terminals .............................................................................................. GPIO Terminals ................................................................................................................... Miscellaneous Terminals ......................................................................................................... Initial Flow Control Credit Advertisements ..................................................................................... Messages Supported by the XIO3130 ......................................................................................... EEPROM Register Loading Map................................................................................................ Register for Programming Serial-Bus Devices ................................................................................ Switch Reset Options ............................................................................................................. PCI Express Upstream Port Configuration Register Map (Type 1)......................................................... Extended Configuration Space (Upstream Port) .............................................................................. Bit Descriptions – Command Register ......................................................................................... Bit Descriptions – Status Register .............................................................................................. Bit Descriptions – Class Code and Revision ID Register .................................................................... Bit Descriptions – I/O Base Register ........................................................................................... Bit Descriptions – I/O Limit Register ............................................................................................ Bit Descriptions – Secondary Status Register ................................................................................ Bit Descriptions – Memory Base Register ..................................................................................... Bit Descriptions – Memory Limit Register...................................................................................... Bit Descriptions – Pre-fetchable Memory Base Register .................................................................... Bit Descriptions – Pre-fetchable Memory Limit Register ..................................................................... Bit Descriptions – Pre-fetchable Base Upper 32 Bits Register.............................................................. Bit Descriptions – Pre-fetchable Limit Upper 32 Bits Register .............................................................. Bit Descriptions – I/O Base Upper 16 Bits Register .......................................................................... Bit Descriptions – I/O Limit Upper 16 Bits Register .......................................................................... Bit Descriptions – Bridge Control Register..................................................................................... Bit Descriptions – Power Management Capabilities Register ............................................................... Bit Descriptions – Power Management Control/Status Register ............................................................ Bit Descriptions – PM Bridge Support Extension Register .................................................................. Bit Descriptions – MSI Message Control Register ............................................................................ Bit Descriptions – MSI Message Address Register........................................................................... Bit Descriptions – MSI Data Register........................................................................................... XIO3130 Terminal Assignments List of Tables 14 15 16 17 17 18 18 19 19 20 21 24 25 29 31 32 35 36 37 38 39 41 42 42 43 43 43 44 44 45 45 45 47 48 49 50 51 51 52 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4-24 Bit Descriptions – PCI Express Capabilities Register ........................................................................ 54 4-25 Bit Descriptions – Device Capabilities Register ............................................................................... 55 4-26 Bit Descriptions – Device Control Register .................................................................................... 55 4-27 Bit Descriptions – Device Status Register ..................................................................................... 56 4-28 Bit Descriptions – Link Capabilities Register .................................................................................. 57 4-29 Bit Descriptions – Link Control Register 4-30 4-31 4-32 4-33 4-34 4-35 4-36 4-37 4-38 4-39 4-40 4-41 4-42 4-43 4-44 4-45 4-46 4-47 4-48 4-49 4-50 4-51 4-52 4-53 4-54 4-55 4-56 4-57 4-58 4-59 4-60 4-61 4-62 4-63 4-64 ....................................................................................... Bit Descriptions – Link Status Register ........................................................................................ Bit Descriptions – Serial Bus Slave Address Register ....................................................................... Bit Descriptions – Serial Bus Control and Status Register .................................................................. Bit Descriptions – Upstream Port Link PM Latency Register................................................................ Bit Descriptions – Global Chip Control Register .............................................................................. Bit Descriptions – GPIO A Control Register ................................................................................... Bit Descriptions – GPIO B Control Register ................................................................................... Bit Descriptions – GPIO C Control Register ................................................................................... Bit Descriptions – GPIO D Control Register ................................................................................... Bit Descriptions – GPIO Data Register......................................................................................... Bit Descriptions – Subsystem Access Register ............................................................................... Bit Descriptions – General Control Register ................................................................................... Bit Descriptions – Downstream Ports Link PM Latency Register ........................................................... Bit Descriptions – Global Switch Control Register ............................................................................ Uncorrectable Error Status Register ............................................................................................ Uncorrectable Error Mask Register ............................................................................................. Uncorrectable Error Severity Register.......................................................................................... Correctable Error Status Register............................................................................................... Correctable Error Mask Register ................................................................................................ Advanced Error Capabilities and Control Register ........................................................................... PCI Express Downstream Port Configuration Register Map (Type 1) ..................................................... Extended Configuration Space (Downstream Port) .......................................................................... Bit Descriptions – Command Register ......................................................................................... Bit Descriptions – Status Register .............................................................................................. Bit Descriptions – Class Code and Revision ID Register .................................................................... Bit Descriptions – I/O Base Register ........................................................................................... Bit Descriptions – I/O Limit Register ............................................................................................ Bit Descriptions – Secondary Status Register ................................................................................ IBit Descriptions – Memory Base Register .................................................................................... Bit Descriptions – Memory Limit Register...................................................................................... Descriptions – Pre-fetchable Memory Base Register ........................................................................ Bit Descriptions – Pre-fetchable Memory Limit Register ..................................................................... Bit Descriptions – Pre-fetchable Base Upper 32 Bits Register.............................................................. Descriptions – Pre-fetchable Limit Upper 32 Bits Register .................................................................. Bit Descriptions – I/O Base Upper 16 Bits Register .......................................................................... List of Tables 58 59 60 60 61 63 65 67 69 71 72 77 77 78 79 80 81 82 83 84 85 86 87 88 88 89 92 92 93 93 94 94 95 95 95 96 9 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 4-65 4-66 4-67 4-68 4-69 4-70 4-71 4-72 4-73 4-74 4-75 4-76 4-77 4-78 4-79 4-80 4-81 4-82 4-83 4-84 4-85 4-86 4-87 4-88 4-89 4-90 5-1 5-2 5-3 10 www.ti.com .......................................................................... 96 Bit Descriptions – Bridge Control Register..................................................................................... 97 Bit Descriptions – Power Management Capabilities Register ............................................................... 99 Bit Descriptions – Power Management Control/Status Register .......................................................... 100 Bit Descriptions – PM Bridge Support Extension Register ................................................................. 101 Bit Descriptions – MSI Message Control Register .......................................................................... 102 Bit Descriptions – MSI Message Address Register ......................................................................... 102 Bit Descriptions – MSI Data Register ......................................................................................... 103 Bit Descriptions – PCI Express Capabilities Register....................................................................... 105 Bit Descriptions – Device Capabilities Register ............................................................................. 106 Bit Descriptions – Device Control Register................................................................................... 106 Bit Descriptions – Device Status Register .................................................................................... 107 Bit Descriptions – Link Capabilities Register ................................................................................. 108 Bit Descriptions – Link Control Register ...................................................................................... 109 Bit Descriptions – Link Status Register ....................................................................................... 110 Bit Descriptions – Slot Capabilities Register ................................................................................. 110 Bit Descriptions – Slot Control Register ...................................................................................... 112 Bit Descriptions – Slot Status Register ....................................................................................... 114 Bit Descriptions – General Control Register ................................................................................. 116 Bit Descriptions – General Slot Info Register ................................................................................ 118 Uncorrectable Error Status Register .......................................................................................... 119 Uncorrectable Error Mask Register ........................................................................................... 120 Uncorrectable Error Severity Register ........................................................................................ 121 Correctable Error Status Register ............................................................................................. 122 Correctable Error Mask Register .............................................................................................. 123 Advanced Error Capabilities and Control Register .......................................................................... 124 GPIO Matrix ...................................................................................................................... 125 PCI Hot Plug Sideband Signals................................................................................................ 126 Pins Assigned to GPIO Control Registers .................................................................................... 126 Bit Descriptions – I/O Limit Upper 16 Bits Register List of Tables Submit Documentation Feedback XIO3130 www.ti.com 1 • • • • • • • • SLLS693D – MAY 2007 – REVISED AUGUST 2008 Features PCI Express Base Specification, Revision 1.1 PCI Express Card Electromechanical Specification, Revision 1.1 PCI-to-PCI Bridge Architecture Specification, Revision 1.1 PCI Bus Power Management Interface Specification, Revision 1.2 PCI Express Fanout Switch With One ×1 Upstream Port and Three ×1 Downstream Ports Packet Transmission Starts While Reception Still in Progress (Cut-Through) 256-Byte Maximum Data Payload Size Peer-to-Peer Support • • • • • • • • • Wake Event and Beacon Support Support for D1, D2, D3hot, and D3cold Active State Power Management (ASPM) Using Both L0s and L1 Low-Power PCI Express Transmitter Mode Integrated AUX Power Switch Drains VAUX Power Only When Main Power Is Off Integrated PCI Hot Plug Support Integrated REFCLK Buffers for Switch Downstream Ports 3.3-V Multifunction I/O Pins for PCI Hot Plug Status and Control or General Purpose I/Os Optional Serial EEPROM for System-Specific Configuration Register Initialization Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this document. PCI Express, PCI Hot Plug are trademarks of others. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2007–2008, Texas Instruments Incorporated XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 2 www.ti.com Introduction The Texas Instruments XIO3130 switch is an integrated PCI Express fanout switch solution with one upstream x1 port and three downstream x1 ports. This high-performance integrated solution provides the latest in PCI Express switch technology including cut-through architecture, integrated reference clock buffers for downstream ports, integrated main power/VAUX power switch, and downstream port PCI Hot Plug® support. The reader is assumed to have prior knowledge of the PCI Express interface and associated terminology and of the PCI-SIG specifications. 2.1 Description The Texas Instruments XIO3130 switch is a PCI Express ×1 3-port fanout switch. The XIO3130 provides a single x1 upstream port supporting full 250-MB/s packet throughput in each direction simultaneously. Three independently configurable ×1 downstream ports are provided that also support full 250-MB/s packet throughput in each direction simultaneously. A cut-through architecture is implemented to reduce the latency associated with packets moving through the PCI Express fabric. As soon as the address or routing information is decoded within the header of a packet entering an ingress port, the packet is directed to the egress port for forwarding. Packet poisoning using the EDB framing signal is supported in circumstances where packet errors are detected after the transmission of the egress packet begins. The downstream ports may be configured to support PCI Hot Plug slot implementations. In this scenario, the system designer may decide to use the integrated PCI Hot Plug-compliant controller. This feature is available through the classic PCI configuration space under the PCI Express Capability Structure. When enabled, the downstream ports provide the PCI Hot Plug standard mechanism to apply and remove power to the slot or socket. Power-management features include Active State Power Management, PME mechanisms, the Beacon/Wake protocol, and all conventional PCI D-states. When ASPM is enabled, each link automatically saves power when idle using the L0s and L1 states. PME messages are supported along with the PME_Turn_Off/PME_TO_Ack protocol. When enabled, the upstream port supports Beacon transmission as well as the WAKE side band signal to wake the system as the result of a PCI Hot Plug event. Furthermore, the downstream ports may be configured to detect Beacon from downstream devices and forward this upstream. The switch also supports the translation and forwarding of WAKE from a downstream device into Beacon on the upstream port for cabled implementations. 2.2 Related Documents Trademarks PCI Express, PCI Hot Plug are trademarks of others. 12 Introduction Submit Documentation Feedback XIO3130 www.ti.com 2.3 SLLS693D – MAY 2007 – REVISED AUGUST 2008 Document Conventions Throughout this data manual, several conventions are used to convey information. These conventions are listed below: 1. To identify a binary number or field, a lower case b follows the numbers. For example: 000b is a 3-bit binary field. 2. To identify a hexadecimal number or field, a lower case h follows the numbers. For example: 8AFh is a 12-bit hexadecimal field. 3. All other numbers that appear in this document that do not have either a b or h following the number are assumed to be decimal format. 4. If the signal or terminal name has a bar above the name (for example, GRST), then this indicates the logical NOT function. When asserted, this signal is a logic low, 0, or 0b. 5. Differential signal names end with P, N, +, or – designators. The P or + designators signify the positive signal associated with the differential pair. The N or – designators signify the negative signal associated with the differential pair. 6. RSVD indicates that the referenced item is reserved. 7. In Sections 4 through 6, the configuration space for the bridge is defined. For each register bit, the software-access method is identified in an access column. The legend for this access column includes the following entries: – r – read access by software – u – updates by the bridge internal hardware – w – write access by software – c – clear an asserted bit with a write-back of 1b by software. Write of zero to the field has no effect – s – the field may be set by a write of one. Write of zero to the field has no effect. – na – not accessible or not applicable 8. The XIO2213 consists of a PCI-Express to PCI translation bridge where the secondary PCI bus is internally connected to a 1394b OHCI with a 3-port PHY. When describing functionality that is specific to the PCI-Express to PCI translation bridge, the term bridge is used to reduce text. The term 1394b OHCI is used to reduce text when describing the 1394b OHCI with 3-port PHY function. 9. LLC is used to refer to the 1394 link layer controller. 2.4 Ordering Information ORDERING NUMBER TEMPERATURE PACKAGE XIO3130 0°C to 70°C 196-terminal ZHC Submit Documentation Feedback Introduction 13 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 2.5 www.ti.com Terminal Assignments The XIO3130 is packaged in a 196-ball ZHC MicroStar™ BGA. Table 2-1. XIO3130 Terminal Assignments A B C D E F G H J K L M N P 14 GPIO12 SCL VDD15 GPIO4 VSSA (2) DN2_ PERn VSSA (2) DN2_ Petn DN2_ REFCKOn DN2_ REFCKOp VDD15 GPIO15 VDD15 VDD15 13 RSVD GPIO13 VDD15 SDA VDD15 DN2_ PERp VDD15 DN2_ PETp VSSA (2) VSSA (2) DN2_ DPSTRP GPIO6 VDD15 GPIO7 12 GPIO2 RSVD GPIO3 VDD33 VSS VSSA (2) VDDA15 (2) VSSA (2) VDDA15 (2) VDD33 GPIO5 VDD15 GPIO14 GPIO16 VDDA15 (2) VDDA15 (2) VDDA15 (2) VSS VSS VDD15 GPIO11 VDD33 11 VDD33 GPIO1 VDD15 VSS VSS VSSA (2) 10 VSSA (1) VDD15 DN1_ DPSTRP VSS VSS VSS VSS VSS VSS VSS VSS GPIO8 VDD15 VSSA (3) 9 DN1_ REFCK Op DN1_ REFCK On VSSA (1) VDDA15 (1) VSS VSS VSS VSS VSS VSS VSSA (3) VSSA (3) DN3_ PERp DN3_ PERn 8 DN1_ PETp DN1_ PETn VSSA (1) VDDA15 (1) VSS VSS VSS VSS VSS VSS VDDA15 (3) VDDA15 (3) VDD15 VSSA (3) 7 VDDA15 (1) VDD15 VSSA (1) VDDA15 (1) VSS VSS VSS VSS VSS VSS VDDA15 (3) VSSA (3) DN3_ PETp DN3_ PETn 6 DN1_ PERp DN1_ PERn GPIO0 VSS VSS VSS VSS VSS VSS VSS VDDA15 (3) VDDA15 (3) VSSA (3) DN3_ REFCKOn 5 VSSA (1) DN1_ PERST VDD15 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSSA (3) DN3_ REFCKOp 4 VDD15 VDD33 RSVD RSVD VSSA REF VDD COMB 33 VDDA15 (0) VDDA15 (0) VDDA15 (0) VDD15 VSS VDD33 DN3_ DPSTRP VDD15 3 VDD33 VDD15 WAKE VDD COMBIO REFR1 VDD15 REF VSSA (0) VDD15 VDDA33 VDDA15 (0) GPIO18 GPIO17 GPIO9 VDD15 2 DN2_ PERST VDD15 GRST REFR0 VDD33 REF VDD15 UP_ PETn VDDA15 (0) UP_ PERn VSS UP_ REFCKIn VDD15 CLKREQ _UP GPIO10 1 DN3_ PERST UP_ PERST VDD COMB15 VSSD REF VAUX33 REF VDD15 UP_ PETp VSSA (0) UP_ PERp VSSA (0) UP_ REFCKIp VDD15 VDD33 RSVD 14 Introduction Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 2-2. XIO3130 Terminals Sorted Alphanumerically Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name A01 DN3_PERST C13 VDD15 F11 VSSA(2) J08 VSS M06 VDDA15(3) A02 DN2_PERST C14 VDD15 F12 VSSA(2) J09 VSS M07 VSSA(3) A03 VDD33 D01 VSSDREF F13 DN2_PERp J10 VSS M08 VDDA15(3) A04 VDD15 D02 REFR0 F14 DN2_PERn J11 VDDA15(2) M09 VSSA(3) A05 VSSA(1) D03 VDDCOMBIO G01 UP_PETp J12 VDDA15(2) M10 GPIO8 A06 DN1_PERp D04 RSVD G02 UP_PETn J13 VSSA(2) M11 VDD15 A07 VDDA15(1) D05 VSS G03 VSSA(0) J14 DN2_REFCKOn M12 VDD15 A08 DN1_PETp D06 VSS G04 VDDA15(0) K01 VSSA(0) M13 GPIO6 A09 DN1_REFCKOp D07 VDDA15(1) G05 VSS K02 VSS M14 GPIO15 A10 VSSA(1) D08 VDDA15(1) G06 VSS K03 VDDA15(0) N01 VDD33 A11 VDD33 D09 VDDA15(1) G07 VSS K04 VDD15 N02 CLKREQ_UP A12 GPIO2 D10 VSS G08 VSS K05 VSS N03 GPIO9 A13 RSVD D11 VSS G09 VSS K06 VSS N04 DN3_DPSTRP A14 GPIO12 D12 VDD33 G10 VSS K07 VSS N05 VSSA(3) B01 UP_PERST D13 SDA G11 VDDA15(2) K08 VSS N06 VSSA(3) B02 VDD15 D14 GPIO4 G12 VDDA15(2) K09 VSS N07 DN3_PETp B03 VDD15 E01 VAUX33REF G13 VDD15 K10 VSS N08 VDD15 B04 VDD33 E02 VDD33REF G14 VSSA(2) K11 VSS N09 DN3_PERp B05 DN1_PERST E03 REFR1 H01 VSSA(0) K12 VDD33 N10 VDD15 B06 DN1_PERn E04 VSSAREF H02 VDDA15(0) K13 VSSA(2) N11 GPIO11 B07 VDD15 E05 VSS H03 VDD15 K14 DN2_REFCKOp N12 GPIO14 B08 DN1_PETn E06 VSS H04 VDDA15(0) L01 UP_REFCKIp N13 VDD15 B09 DN1_REFCKOn E07 VSS H05 VSS L02 UP_REFCKIn N14 VDD15 B10 VDD15 E08 VSS H06 VSS L03 GPIO18 P01 RSVD B11 GPIO1 E09 VSS H06 VSS L04 VSS P02 GPIO10 B12 RSVD E10 VSS H07 VSS L05 VSS P03 VDD15 B13 GPIO13 E11 VSS H08 VSS L06 VDDA15(3) P04 VDD15 B14 SCL E12 VSS H09 VSS L07 VDDA15(3) P05 DN3_REFCKOp C01 VDDCOMB15 E13 VDD15 H10 VSS L08 VDDA15(3) P06 DN3_REFCKOn C02 GRST E14 VSSA(2) H11 VDDA15(2) L09 VSSA(3) P07 DN3_PETn C03 WAKE F01 VDD15 H12 VSSA(2) L10 VSS P08 VSSA(3) C04 RSVD F02 VDD15 H13 DN2_PETp L11 VSS P09 DN3_PERn C05 VDD15 F03 VDD15REF H14 DN2_PETn L12 GPIO5 P10 VSSA(3) C06 GPIO0 F04 VDDCOMB33 J01 UP_PERp L13 DN2_DPSTRP P11 VDD33 C07 VSSA(1) F05 VSS J02 UP_PERn L14 VDD15 P12 GPIO16 C08 VSSA(1) F06 VSS J03 VDDA33 M01 VDD15 P13 GPIO7 C09 VSSA(1) F07 VSS J04 VDDA15(0) M02 VDD15 P14 VDD15 C10 DN1_DPSTRP F08 VSS J05 VSS M03 GPIO17 C11 VDD15 F09 VSS J06 VSS M04 VDD33 C12 GPIO3 F10 VSS J07 VSS M05 VSS Submit Documentation Feedback Introduction 15 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 2-3. XIO3130 Signal Names Sorted Alphabetically Signal Name Ball Signal Name Ball CLKREQ_UP N02 GPIO5 L12 DN1_DPSTRP C10 GPIO6 M13 DN1_PERn B06 GPIO7 P13 DN1_PERp A06 GPIO8 M10 DN1_PERST B05 GPIO9 N03 DN1_PETn B08 GRST C02 DN1_PETp A08 Suggested Program Value REFR0 D02 DN1_REFCKOn B09 REFR1 E03 DN1_REFCKOp A09 RSVD A13, B12, C04, D04, P01 DN2_DPSTRP L13 SCL B14 DN2_PERn F14 SDA D13 DN2_PERp F13 UP_PERn J02 DN2_PERST A02 UP_PERp J01 DN2_PETn H14 UP_PERST B01 DN2_PETp H13 UP_PETn G02 DN2_REFCKOn J14 UP_PETp G01 DN2_REFCKOp K14 UP_REFCKIn L02 DN3_DPSTRP N04 UP_REFCKIp L01 DN3_PERn P09 VAUX33REF E01 A04, B02, B03, B07, B10, C05, C11, C13, C14, E13, F01, F02, G13, H03, K04, L14, M01, M02, M11, M12, N08, N10, N13, N14, P03, P04, P14 DN3_PERp N09 VDD15 DN3_PERST A01 VDDA15(0) G04, H02, H04, J04, K03 DN3_PETn P07 VDDA15(1) A07, D07, D08, D09 DN3_PETp N07 VDDA15(2) G11, G12, H11, J11, J12 DN3_REFCKOn P06 VDDA15(3) L06, L07, L08, M06, M08 DN3_REFCKOp P05 VDD15REF F03 GPIO0 C06 VDD33 GPIO1 B11 VDD33REF GPIO10 P02 VDDA33 J03 GPIO11 N11 VDDCOMB15 C01 GPIO12 A14 VDDCOMB33 F04 GPIO13 B13 VDDCOMBIO D03 A03, A11, B04, D12, K12, M04, N01, P11 E02 D05, D06, D10, D11, E05, E06, E07, E08, E09, E10, E11, E12, F05, F06, F07, F08, F09, F10, G05, G06, G07, G08, G09, G10, H05, H06, H07, H08, H09, H10, J05, J06, J07, J08, J09, J10, K02, K05, K06, K07, K08, K09, K10, K11, L04, L05, L10, L11, M05 GPIO14 N12 VSS GPIO15 M14 VSSA(0) G03, H01, K01 GPIO16 P12 VSSA(1) A05, A10, C07, C08, C09 GPIO17 M03 VSSA(2) E14, F11, F12, G14, H12, J13, K13 GPIO18 L03 VSSA(3) L09, M07, M09, N05, N06, P08, P10 GPIO2 A12 VSSAREF E04 GPIO3 C12 VSSDREF D01 GPIO4 D14 WAKE C03 16 Introduction Submit Documentation Feedback XIO3130 www.ti.com 2.6 SLLS693D – MAY 2007 – REVISED AUGUST 2008 Terminal Descriptions Table 2-4. Power Supply Terminals Signal Ball I/O Type External parts Description VDDA15(0) G04, H02, H04, J04, K03 PWR Filter 1.5-V analog power terminals for PCI-Express upstream port 0 VDDA15(1) A07, D07, D08, D09 PWR Filter 1.5-V analog power terminals for PCI-Express downstream port 1 VDDA15(2) G11, G12, H11, J11, J12 PWR Filter 1.5-V analog power terminals for PCI-Express downstream port 2 VDDA15(3) L06, L07, L08, M06, M08 PWR Filter 1.5-V analog power terminals for PCI-Express downstream port 3 VDD15 A04, B02, B03, B07, B10, C05, C11, C13, C14, E13, F01, F02, G13, H03, K04, L14, M01, M02, M11, M12, N08, N10, N13, N14, P03, P04, P14 PWR Bypass capacitors 1.5-V digital core power terminals VDD33 A03, A11, B04, D12, K12, M04, N01, P11 PWR Bypass capacitors 3.3-V digital I/O power terminals J03 PWR Filter 3.3-V analog power terminal 3.3-V digital VAUX power terminal VDDA33 VAUX33REF E01 PWR Bypass capacitors VDD15REF F03 PWR Filter 1.5-V PCI-Express reference power terminal VDD33REF E02 PWR Filter 3.3-V PCI-Express reference power terminal Table 2-5. Combined Power Terminals Signal Ball I/O Type External Parts VDDCOMBIO D03 Passive Bypass capacitors Internally combined 3.3-V main and VAUX power output for external bypass capacitor filtering. Supplies all internal 3.3-V input and output circuitry powered during D3 cold. Caution: Do not use this terminal to supply external power to other devices. VDDCOMB33 F04 Passive Bypass capacitors Internally combined 3.3-V main and VAUX power output for external bypass capacitor filtering. Supplies all internal 3.3-V circuitry powered during D3 cold. Caution: Do not use this terminal to supply external power to other devices. VDDCOMB15 C01 Passive Bypass capacitors Internally combined 1.5-V main and VAUX power output for external bypass capacitor filtering. Supplies all internal 1.5-V circuitry powered during D3 cold. Caution: Do not use this terminal to supply external power to other devices. Submit Documentation Feedback Description Introduction 17 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 2-6. Ground Terminals Signal Ball I/O Type D05, D06, D10, D11, E05, E06, E07, E08, E09, E10, E11, E12, F05, F06, F07, F08, F09, F10, G05, G06, G07, G08, G09, G10, H05, H06, H07, H08, H09, H10, J05, J06, J07, J08, J09, J10, K02, K05, K06, K07, K08, K09, K10, K11, L04, L05, L10, L11, M05 GND Digital ground terminals VSSA(0) G03, H01, K01 GND Analog ground terminals for upstream Port 0 VSSA(1) A05, A10, C07, C08, C09 GND Analog ground terminals for downstream Port 1 VSSA(2) E14, F11, F12, G14, H12, J13, K13 GND Analog ground terminals for downstream Port 2 VSSA(3) L09, M07, M09, N05, N06, P08, P10 GND Analog ground terminals for downstream Port 3 VSSAREF E04 GND 1.5-V PCI-Express analog reference ground terminal VSSDREF D01 GND 1.5-V PCI-Express digital reference ground terminal VSS Description Table 2-7. PCI Express Reference Clock Terminals Signal Ball I/O Type External Parts Description UP_REFCKIp UP_REFCKIn L01 L02 HS DIFF IN DN1_REFCKOp DN1_REFCKOn A09 B09 HS DIFF OUT 100 MHz differential reference clock outputs for downstream port 1 DN2_REFCKOp DN2_REFCKOn K14 J14 HS DIFF OUT 100 MHz differential reference clock outputs for downstream port 2 DN3_REFCKOp DN3_REFCKOn P05 P06 HS DIFF OUT 100 MHz differential reference clock outputs for downstream port 3 18 Introduction Reference clock inputs. REFCKIp and REFCKIn comprise the differential input pair for the 100-MHz system reference clock. Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 2-8. PCI Express Terminals Ball I/O Type External Parts UP_PETp UP_PETn Signal G01 G02 HS DIFF OUT Description Series capacitors High-speed differential transmit pair for upstream port 0 DN1_PETp DN1_PETn A08 B08 HS DIFF OUT Series capacitors High-speed differential transmit pair for downstream port 1 DN2_PETp DN2_PETn H13 H14 HS DIFF OUT Series capacitors High-speed differential transmit pair for downstream port 2 DN3_PETp DN3_PETn N07 P07 HS DIFF OUT Series capacitors High-speed differential transmit pair for downstream port 3 UP_PERp UP_PERn J01 J02 HS DIFF IN High-speed differential receiver pair for upstream port 0 DN1_PERp DN1_PERn A06 B06 HS DIFF IN High-speed differential receiver pair for downstream port 1 DN2_PERp DN2_PERn F13 F14 HS DIFF IN High-speed differential receiver pair for downstream port 2 DN3_PERp DN3_PERn N09 P09 HS DIFF IN High-speed differential receiver pair for downstream port 3 REFR0 REFR1 D02 E03 Passive External bias resistor External reference resistor terminals for setting TX driver current. An external resistor is connected between these terminals. UP_PERST B01 LV CMOS IN System-side pullup resistor PCI-Express reset input. When logic high, the PERST signal identifies that the system power is stable. When logic low, the PERST signal generates an internal power-on reset. DN1_PERST B05 LV CMOS O Pulldown resistor PCI-Express reset output for downstream port 1. DN2_PERST A02 LV CMOS O Pulldown resistor PCI-Express reset output for downstream port 2. DN3_PERST A01 LV CMOS O Pulldown resistor PCI-Express reset output for downstream port 3. WAKE C03 LV CMOS I/O System-side pullup resistor Note: The UP_PERST input buffer has hysteresis. WAKE is an active low signal that is driven low to reactivate the PCI-Express link hierarchy’s main power rails and reference clocks. Note: Since WAKE is an open-drain output buffer, a system-side pullup resistor is required. Table 2-9. PCI Hot Plug Strapping Terminals Signal DN1_DPSTR P DN2_DPSTR P DN3_DPSTR P Ball C10 L13 N04 I/O Type LV CMOS IN LV CMOS IN LV CMOS IN Submit Documentation Feedback External Parts Description Pullup or pulldown resistor Downstream Port 1 Strap. This pin is pulled high at the de-assertion of reset. GPIO0, GPIO1, and GPIO2 are used as PCI Hot Plug terminals for downstream port 1 and are no longer available for use as GPIOs. The three terminals become PRESENT, PWR_ON, and PWR_GOOD respectively. These GPIOs are available for normal use if this terminal is pulled low at the de-assertion of reset. Pullup or pulldown resistor Downstream Port 2 Strap. This pin is pulled high at the de-assertion of reset. GPIO4, GPIO5, and GPIO6 are used as PCI Hot Plug terminals for downstream port 2 and are no longer available for use as GPIOs. The three terminals become PRESENT, PWR_ON, and PWR_GOOD respectively. These GPIOs are available for normal use if this terminal is pulled low at the de-assertion of reset. Pullup or pulldown resistor Downstream Port 3 Strap. This pin is pulled high at the de-assertion of reset. GPIO8, GPIO9, and GPIO10 are used as PCI Hot Plug terminals for downstream port 3 and are no longer available for use as GPIOs. The three terminals become PRESENT, PWR_ON, and PWR_GOOD respectively. These GPIOs are available for normal use if this terminal is pulled low at the de-assertion of reset. Introduction 19 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 2-10. GPIO Terminals Signal GPIO0 Ball C06 GPIO1 B11 I/O Type External Parts Description LV CMOS I/O GPIO 0. If the DN1_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PRSNT hotplug pin for downstream port 1. Otherwise this pin’s function is programmed with the GPIO A Control register. LV CMOS I/O GPIO 1. If the DN1_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the POWERON hotplug pin for downstream port 1. Otherwise this pin’s function is programmed with the GPIO A Control register. GPIO2 A12 LV CMOS I/O GPIO 2. If the DN1_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PWRGD hotplug pin for downstream port 1. Otherwise this pin’s function is programmed with the GPIO A Control register GPIO3 C12 LV CMOS I/O GPIO 3. This pin’s function is programmed with the GPIO A Control register. GPIO4 D14 LV CMOS I/O GPIO 4. If the DN2_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PRSNT hotplug pin for downstream port 2. Otherwise this pin’s function is programmed with the GPIO A Control register. GPIO5 L12 LV CMOS I/O GPIO 5. If the DN2_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the POWERON hotplug pin for downstream port 2. Otherwise this pin’s function is programmed with the GPIO A Control register. GPIO6 M13 LV CMOS I/O GPIO 6. If the DN2_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PWRGD hotplug pin for downstream port 2. Otherwise this pin’s function is programmed with the GPIO A Control register. GPIO7 P13 LV CMOS I/O GPIO 7. This pin’s function is programmed with the GPIO A Control register. GPIO8 M10 LV CMOS I/O GPIO 8. If the DN3_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PRSNT hotplug pin for downstream port 3. Otherwise this pin’s function is programmed with the GPIO B Control register. GPIO9 N03 LV CMOS I/O GPIO 9. If the DN3_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the POWERON hotplug pin for downstream port 3. Otherwise this pin’s function is programmed with the GPIO B Control register. GPIO10 P02 LV CMOS I/O GPIO 10. If the DN3_DPSTRP pin is pulled high at the de-assertion of reset, this pin functions as the PWRGD hotplug pin for downstream port 3. Otherwise this pin’s function is programmed with the GPIO B Control register. GPIO11 N11 LV CMOS I/O GPIO 11. This pin’s function is programmed with the GPIO B Control register. GPIO12 A14 LV CMOS I/O GPIO 12. This pin’s function is programmed with the GPIO B Control register. GPIO13 B13 LV CMOS I/O GPIO 13. This pin’s function is programmed with the GPIO B Control register. GPIO14 N12 LV CMOS I/O GPIO 14. This pin’s function is programmed with the GPIO B Control register. GPIO15 M14 LV CMOS I/O GPIO 15. This pin’s function is programmed with the GPIO B Control register. GPIO16 P12 LV CMOS I/O GPIO16. This pin’s function is programmed with the GPIO C Control register. GPIO17 M03 LV CMOS I/O GPIO 17. This pin’s function is programmed with the GPIO C Control register. GPIO18 L03 LV CMOS I/O GPIO 18. This pin’s function is programmed with the GPIO C Control register. 20 Introduction Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 2-11. Miscellaneous Terminals Signal Ball I/O Type C02 LV CMOS IN GRST SDA SCL External Parts See description Description Global power-on reset input. Note: a pullup to Vaux (if supported) or VDD3.3 (if not) is required unless this terminal is always driven by the upstream device. D13 LV CMOS I/O Serial Data. This pin is the serial data pin for the EEPROM interface. B14 LV CMOS O Serial Clock. This pin is the serial clock pin for the EEPROM interface. N02 LV CMOS O Upstream Clock Request. When asserted low, requests upstream device restart clock in cases where upstream clock may be removed in L1 CLKREQ_UP RSVD A13, B12, RSVD C04, P01 RSVD D04 Submit Documentation Feedback Reserved. These terminals must tied to VDD15. Reserved. This terminal must be tied to GND. See description Reserved. Pullup to Vaux (if supported) or VDD3.3 (if not) Introduction 21 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 3 www.ti.com Description Figure 3-1 is the block diagram of the XIO3130. Clock Distribution/ Reset Logic PCI Express X1 Phy GPIO Port 0 (Up) Logic PCI Hot Plug Virtual PCI to PCI Bridge EEPROM Virtual PCI to PCI Bridge Bridge Virtual PCI to PCI Bridge Bridge Virtual PCI to PCI Bridge Bridge Port 1 (Down) Logic Port 2 (Down) Logic Port 3 (down) logic PCI Express x1 Phy PCI Express x1 Phy PCI Express x1 Phy Figure 3-1. Block Diagram 3.1 Power-Up/Power-Down Sequencing The following sections describe the procedures to power up and power down the XIO3130 switch. 3.1.1 Power-Up Sequence 1. Assert PERST to the device. 2. Apply 1.5-V and 3.3-V voltages in any order with any time relationship and with any ramp rate. 3. Apply a stable PCI Express reference clock. To meet PCI Express specification requirements, PERST cannot be de-asserted until the following two delay requirements are satisfied: • Wait a minimum of 100 µs after applying a stable PCI Express reference clock. The 100-µs limit satisfies the requirement for stable device clocks by the de-assertion of PERST. • Wait a minimum of 100 ms after applying power. The 100-ms limit satisfies the requirement for stable power by the de-assertion of PERST. See Figure 3-2, Power-Up Sequence Diagram. 22 Description Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Figure 3-2. Power-Up Sequence Diagram 3.1.2 Power-Down Sequence • • • Assert PERST to the device. Remove the reference clock. Remove 3.3-V and 1.5-V voltages. See the power-down sequence diagram in Figure 3-3. If the VAUX33REF terminal is to remain powered after a system shutdown, the switch power-down sequence is exactly the same as shown in Figure 3-3. Figure 3-3. Power-Down Sequence Diagram 3.2 3.2.1 Express Interface External Reference Clock The Texas Instruments XIO3130 switch requires a differential 100 MHz common clock reference. The clock reference must meet all PCI Express electrical specification requirements for frequency tolerance, spread spectrum clocking, and signal electrical characteristics. 3.2.2 Clock Generator The clock generator is responsible for generating all internal and external clocks from the PCI Express reference clock. This includes the PHY transmitter serial link clock, the three downstream reference clock outputs, the 60-kHz serial bus interface clock, and all internal clock domains. Submit Documentation Feedback Description 23 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 3.2.3 www.ti.com Beacon The XIO3130 supports the PCI Express in-band beacon feature. Beacon is driven on the PCI Express link by the XIO3130 to request the re-application of main power when in the L2 link state. Once beacon is activated, the XIO3130 continues to send the beacon signal until main power is restored as indicated by PERST going inactive. At this time, the beacon signal is deactivated. 3.2.4 WAKE The XIO3130 supports the PCI Express sideband WAKE feature. WAKE is an active-low signal driven by the XIO3130 to request the re-application of main power when in the L2 link state. Since WAKE is an open-collector output, a system-side pullup resistor is required to prevent the signal from floating. If WAKE to Beacon translation is enabled (see section 3.2.60), the XIO3130 detects when WAKE is asserted and transmits beacon to alert the system. This enables support for devices that use the WAKE protocol in a system that does not support it. 3.2.5 Initial Flow Control Credits The XIO3130 flow control credits are initialized using the rules defined in the PCI Express Base Specification. Table 3-1 identifies the initial flow control credit advertisement for the XIO3130. The initial advertisement is exactly the same for both upstream and downstream ports. Table 3-1. Initial Flow Control Credit Advertisements Credit Type 3.2.6 Initial Advertisement Hex Decimal Posted Request Headers (PH) 10 16 Posted Request Data (PD) 80 128 Non-Posted Header (NPH) 10 16 Non-Posted Data (NPD) 10 16 Completion Header (CPLH) 10 16 Completion Data (CPLD) 80 128 PCI Express Message Transactions PCI Express messages are initiated by, received by and passed through the XIO3130. Table 3-2 outlines message support within the switch. 24 Description Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 3-2. Messages Supported by the XIO3130 Message Supported XIO3130 Action Assert_INTx Yes Passed through upstream Deassert_INTx Yes Passed through upstream PM_Active_State_Nak Yes Received and processed PM_PME Yes Passed through upstream Downstream PCI Hot Plug Event: Initiated upstream PME_Turn_Off Yes Received and processed Passed through downstream PME_TO_Ack Yes Downstream port: Received and processed Downstream ports: Initiated upstream ERR_COR Yes Passed through upstream Initiated upstream ERR_NONFATAL Yes Passed through upstream Initiated upstream ERR_FATAL Yes Passed through upstream Initiated upstream Unlock Yes Received and processed Passed through downstream Set_Slot_Power_Limit Yes Upstream port: Received and processed Downstream port: Initiated downstream Advanced Switching Messages No Discarded Vendor Defined Type 0 Yes Upstream port: Unsupported request Passed through downstream Vendor Defined Type 1 Yes Upstream port: Discarded Passed through downstream All supported message transactions are processed according to the PCI Express Base Specification. 3.3 GPIO Terminals Up to 19 general-purpose input/output (GPIO) terminals are provided for system customization. These GPIO terminals are 3.3-V tolerant. The exact number of GPIO terminals available varies based on the implementation of various supported functions that share GPIO terminals. When any of the shared functions are enabled, the associated GPIO terminal is disabled. When pulled high, the DPSTRP terminals cause some GPIO terminals to be mapped to PCI Hot Plug functions for specific ports. Additional information can be found in the DPSTRP pin descriptions and in Chapter 4. All GPIO terminals are individually configurable as either inputs or outputs by writing the corresponding bits in the GPIOA, GPIOB, GPIOC, or GPIOD Control Registers. The GPIO data register is used to monitor GPIO terminals defined as inputs or to set the state of GPIO terminals defined as outputs. For more information on GPIO terminals, see sections Section 4.2.61 through Section 4.2.65. 3.4 Serial EEPROM The XIO3130 provides a two-wire serial-bus interface to load subsystem identification information and specific register defaults from an external EEPROM. This interface supports slow, fast, and high-speed EEPROM speed options. Submit Documentation Feedback Description 25 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 3.4.1 www.ti.com Serial Bus Interface Implementation To enable the serial bus interface, a pullup resistor must be implemented on the SDA signal. At the rising edge of PERST or GRST, whichever occurs last, the SDA terminal is checked for a pullup resistor. If one is detected, bit 3 (SBDETECT) in the serial bus control and status register (see Table 4-32) is set. Software may disable the serial bus interface at any time by writing a zero to the SBDETECT bit. If no external EEPROM is required, the serial bus interface is permanently disabled by attaching a pulldown resistor to the SDA signal. The XIO3130 implements a two-terminal serial interface with one clock signal (SCL) and one data signal (SDA). The SCL signal is a unidirectional output from the XIO3130 and the SDA signal is bidirectional. Both are open-drain signals and require pullup resistors. The XIO3130 is a bus master device and drives SCL at approximately 60 kHz during data transfers and places SCL in a high-impedance state during bus idle states. The serial EEPROM is a bus slave device and must acknowledge a slave address equal to 1010_000X binary. Figure 3-4 illustrates a sample application implementing the two-wire serial bus. VDD33 XIO3130 SERIAL EEPROM SCL SCL A2 A1 SDA A0 SDA Figure 3-4. Serial EEPROM Applications 3.4.2 Serial Bus Interface Protocol All data transfers are initiated by the serial bus master. The beginning of a data transfer is indicated by a start condition, which is signaled when the SDA line transitions to a low state while SCL is in the high state, as illustrated in Figure 3-5. The end of a requested data transfer is indicated by a stop condition, which is signaled by a low-to-high transition of SDA while SCL is in the high state, as shown in Figure 3-5. Data on SDA must remain stable during the high state of the SCL signal because changes on the SDA signal during the high state of SCL are interpreted as control signals (i.e., a start or a stop condition). 26 Description Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Figure 3-5. Serial-Bus Start/Stop Conditions and Bit Transfers Data is transferred serially in 8-bit bytes. During a data transfer operation, an unlimited number of bytes are transmitted. However, each byte must be followed by an acknowledge bit to continue the data transfer operation. An acknowledge (ACK) is indicated by the data byte receiver pulling the SDA signal low, so that it remains low during the high state of the SCL signal. Figure 3-6 illustrates the acknowledge protocol. Figure 3-6. Serial-Bus Protocol Acknowledge The XIO3130 performs three basic serial bus operations: single-byte reads, single-byte writes, and multiple-byte reads. The single-byte operations occur under software control. The multiple-byte read operations are performed by the serial EEPROM initialization circuitry immediately after a PCI Express Reset. For details on how the XIO3130 automatically loads the subsystem identification and other register defaults from the serial-bus EEPROM, see Section 3.4.3, Serial Bus EEPROM Application. Figure 3-7 illustrates a single-byte write. The XIO3130 issues a start condition and sends the 7-bit slave device address and the R/W command bit equal to zero. A zero in the R/W command bit indicates that the data transfer is a write. The slave device acknowledges that it recognizes the slave address. If the XIO3130 receives no acknowledgment, the SB_ERR status bit is set in the serial-bus control and status register (PCI offset B3h; see Table 4-32). Next, the XIO3130 sends the EEPROM word address, and another slave acknowledgment is expected. Then the XIO3130 delivers the data byte (MSB first) and expects a final acknowledgment before issuing the stop condition. Figure 3-7. Serial-Bus Protocol – Byte Write Figure 3-8 illustrates a single-byte read. The XIO3130 issues a start condition and sends the 7-bit slave device address and the R/W command bit equal to zero (write). The slave device acknowledges that it recognizes the slave address. Next, the XIO3130 sends the EEPROM word address, and another slave Submit Documentation Feedback Description 27 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com acknowledgment is expected. Then, the XIO3130 issues a restart condition followed by the 7-bit slave address and the R/W command bit equal to one (read). Once again, the slave device responds with acknowledge. Next, the slave device sends the 8-bit data byte, MS bit first. Since this is a one-byte read, the XIO3130 responds with no acknowledge (logic high), indicating the last data byte. Finally, the XIO3130 issues a stop condition. Word Address Slave Address S b6 b5 b4 b3 b2 b1 b0 Start 0 A b7 b6 b5 b4 b3 b2 b1 b0 A R/W Slave Address S b6 b5 b4 b3 b2 Data Byte b1 Restart b0 1 A b7 b6 b5 b4 b3 b2 b1 b0 M P R/W A = Slave Acknowledgement M = Master Acknowledgement S/P = Start/Stop Condition Figure 3-8. Serial-Bus Protocol – Byte Read Figure 3-9 illustrates the serial interface protocol during a multiple-byte serial EEPROM download. The serial bus protocol starts exactly the same way as a one-byte read. The only difference is that multiple data bytes are transferred. The number of transferred data bytes is controlled by the XIO3130 master. After each data byte, if more data bytes are requested, the XIO3130 master issues acknowledge (logic low). The transfer ends after an XIO3130 master no acknowledge (logic high), followed by a stop condition. Figure 3-9. Serial-Bus Protocol – Multiple-Byte Read The PROT_SEL bit (bit 7) in the Serial Bus Control and Status register changes the serial bus protocol. Each of the three previous serial-bus protocol figures illustrates the PROT_SEL bit default (logic low). When this control bit is asserted, the word address and corresponding acknowledge are removed from the serial bus protocol. This feature allows the system designer a second serial bus protocol option when selecting external EEPROM devices. 3.4.3 Serial Bus EEPROM Application The registers and corresponding bits that are loaded through the EEPROM are provided in Table 3-3. Note the following: • EEPROM bytes 00h through 1Dh affect the general control options for the XIO3130. • EEPROM bytes 1Eh through 27h affect the operation of the upstream port (port 0). • Bytes 00h through 27h are loaded into the configuration registers for the upstream virtual bridge or port 0 (see Figure 4-1). • EEPROM bytes 28h through 35h correspond to and are loaded into the configuration space for the first downstream virtual bridge or port 1 (see Figure 4-1). 28 Description Submit Documentation Feedback XIO3130 www.ti.com • • SLLS693D – MAY 2007 – REVISED AUGUST 2008 EEPROM bytes 36h through 43h correspond to and are loaded into the configuration space for the second downstream virtual bridge or port 2 (see Figure 4-1). EEPROM bytes 44h through 51h correspond to and are loaded into the configuration space for the third downstream virtual bridge or port 3 (see Figure 4-1). Table 3-3. EEPROM Register Loading Map EEPROM Byte Address (hex) Suggested Programmed Value (hex) CONFIG Register Address (hex) Register Description 0 4C NA Global Switch/Upstream Port Function Indicator (1) 1 0 NA TI Proprietary register (1) 2 24 0B4 Upstream Port Link PM Latency register 3 0 0B5 Upstream Port Link PM Latency register 4 0 0B8 Global Chip Control register 5 0 0B9 Global Chip Control register 6 0 0BA Global Chip Control register 7 0 0BB Global Chip Control register 8 0 0BC GPIOA register 9 0 0BD GPIOA register 0A 0 0BE GPIOB register 0B 0 0BF GPIOB register 0C 0 0C0 GPIOC register 0D 0 0C1 GPIOC register 0E 0 0C2 GPIOD register 0F 0 0C3 GPIOD register 10 0 0C4 GPIO Data register 11 0 0C5 GPIO Data register 12 0 0C6 GPIO Data register 13 0 0C7 GPIO Data register 14 01 0C8 TI Proprietary register (1) 15 0 0CC TI Proprietary register (1) 16 0 0CD TI Proprietary register (1) 17 0 0D0 TI Proprietary register (1) 18 0 0D1 TI Proprietary register (1) 19 14 0D2 TI Proprietary register (1) 1A 32 0D3 TI Proprietary register (1) 1B 2 0DC TI Proprietary register (1) 1C 0 0DE TI Proprietary register (1) 1D 0 0DF TI Proprietary register (1) 1E 0 NA Global Switch/Upstream Port 0 Function Indicator 1F 0 NA Not used 20 XX 0E0 Subsystem Access Vendor ID register 21 XX 0E1 Subsystem Access Vendor ID register 22 XX 0E2 Subsystem Access Subsys ID register 23 XX 0E3 Subsystem Access Subsys ID register 24 0 0E4 General Control register 25 24 0E8 Downstream Port Link PM Latency register 26 3F 0E9 Downstream Port Link PM Latency register 27 4 0EA Global Switch Control register 28 1 NA Downstream Port 1 Function Indicator (1) Required program value Submit Documentation Feedback Description 29 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 3-3. EEPROM Register Loading Map (continued) 30 EEPROM Byte Address (hex) Suggested Programmed Value (hex) CONFIG Register Address (hex) 29 0 NA Not used 2A 01 0C8 TI Proprietary register (1) 2B 0 0CC TI Proprietary register (1) 2C 0 0CD TI Proprietary register (1) 2D 0 0D0 TI Proprietary register (1) 2E 0 0D1 TI Proprietary register (1) 2F 14 0D2 TI Proprietary register (1) 30 32 0D3 TI Proprietary register (1) 31 10 0D4 General Control register 32 60 0D5 General Control register 33 1A 0EC L0s Timeout register 34 0 0EE General Slot Info register 35 0 0EF General Slot Info register 36 2 NA Downstream Port 2 Function Indicator Register Description 37 0 NA Not used 38 01 0C8 TI Proprietary register (1) 39 0 0CC TI Proprietary register (1) 3A 0 0CD TI Proprietary register (1) 3B 0 0D0 TI Proprietary register (1) 3C 0 0D1 TI Proprietary register (1) 3D 14 0D2 TI Proprietary register (1) 3E 32 0D3 TI Proprietary register (1) 3F 10 0D4 General Control register 40 60 0D5 General Control register 41 1A 0EC L0s Timeout register 42 0 0EE General Slot Info register 43 0 0EF General Slot Info register 44 2 NA Downstream Port 3 Function Indicator 45 0 NA Not used 46 01 0C8 TI Proprietary register (1) 47 0 0CC TI Proprietary register (1) 48 0 0CD TI Proprietary register (1) 49 0 0D0 TI Proprietary register (1) 4A 0 0D1 TI Proprietary register (1) 4B 14 0D2 TI Proprietary register (1) 4C 32 0D3 TI Proprietary register (1) 4D 10 0D4 General Control register 4E 60 0D5 General Control register 4F 1A 0EC L0s Timeout register 50 0 0EE General Slot Info register 51 0 0EF General Slot Info register Description Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 This download table must be explicitly followed for the XIO3130 to correctly load initialization values from a serial EEPROM. All byte locations must be considered when programming the EEPROM. The XIO3130 addresses the serial EEPROM using a default slave address of 1010_000X binary. For an EEPROM download operation that occurs immediately after PERST, this address is fixed. The serial EEPROM in the sample application circuit (Figure 3-4) assumes the 1010b high-address nibble. The lower three address bits are terminal inputs to the chip, and the sample application shows these terminal inputs tied to VSS to match the least-significant three address bits. During an EEPROM download operation, bit 4 (ROMBUSY) in the serial-bus control and status register is asserted. After the download is finished, bit 4 is negated. At that time, bit 0 (ROM_ERR) in the serial-bus control and status register may be monitored to verify a successful download. 3.4.4 Accessing Serial Bus Devices Through Software The XIO3130 provides a programming mechanism to control serial bus devices through system software. The programming is accomplished through a doubleword of PCI configuration space at offset B0h. Table 3-4 lists the registers used to program a serial-bus device through software. Table 3-4. Register for Programming Serial-Bus Devices PCI Offset Register Name Description B0h Serial-bus data This register contains the data byte to send on write commands or the received data byte on read commands. B1h Serial-bus word address The content of this register is sent as the word address on byte writes or reads. This register is not used in the quick command protocol. B2h Serial-bus slave address Write transactions to this register initiate a serial-bus transaction. The slave device address and the R/W command selector are programmed through this register. B3h Control and Status Serial interface enable, busy, and error status are communicated through this register. In addition, the protocol-select bit and serial bus test bit are programmed through this register. To access the serial EEPROM through the software interface, the software performs five steps: 1. Reads the Control and Status Byte to verify that the EEPROM interface is enabled (SBDETECT asserted) and not busy (REQBUSY and ROMBUSY negated). 2. Loads the Serial Bus word address. If the access is a write, the data byte is also loaded. 3. Writes the Serial Bus slave address and read/write command selector byte. 4. Monitors REQBUSY until this bit is negated. 5. Checks SB_ERR to verify that the serial bus operation completed without error. If the operation is a read, after REQBUSY is negated, the serial bus data byte is valid. 3.5 Switch Reset Features Four XIO3130 reset options are available: • Internally-generated power-on reset • A global reset generated by asserting GRST input terminal • A PCI Express reset generated by asserting PERST input terminal • Software-initiated resets that are controlled by sending a PCI Express training control hot reset Table 3-5 identifies these reset sources and describes how the XIO3130 responds to each reset. Submit Documentation Feedback Description 31 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 3-5. Switch Reset Options Reset Option XIO3130 Feature Reset Response Internally-generated power-on reset During a power-on cycle, the XIO3130 asserts an internal reset and monitors the VDDCOMB15 (N01) terminal. When this terminal reaches 90% of the nominal input voltage specification, power is considered stable. After stable power, the XIO3130 monitors the PCI Express reference clock (REFCLKI) and waits 10 µs after active clocks are detected. Then, internal power-on reset is de-asserted. When the internal power-on reset is asserted, all control registers, state machines, sticky register bits, and power management state machines are initialized to their default state. Global reset input GRST (C02) When GRST is asserted low, an internal power-on reset occurs. This reset is asynchronous and functions during both normal power states and VAUX power states. When GRST is asserted low, all control registers, state machines, sticky register bits, and power management state machines are initialized to their default state. When the rising edge of GRST occurs, the switch samples the state of all static control inputs and latches the information internally. If an external serial EEPROM is detected, then a download cycle is initiated. Also, the process to configure and initialize the PCI Express link is started. The switch starts link training within 80 ms after PERST or GRST is de-asserted. PCI Express reset input PERST (C01) When PERST is asserted low, all control register This XIO3130 input terminal is used by an upstream bits that are not sticky are reset. Also, all state PCI Express device to generate a PCI Express reset machines that are not associated with sticky and to signal a system power good condition. functionality or VAUX power management are reset. When PERST is asserted low, all control register When the rising edge of PERST occurs, the switch bits that are not sticky are reset. Also, all state samples the state of all static control inputs and machines that are not associated with sticky latches the information internally. If an external functionality or VAUX power management are reset. serial EEPROM is detected, then a download cycle When the rising edge of PERST occurs, the switch is initiated. Also, the process to configure and samples the state of all static control inputs and initialize the PCI Express link is started. The switch latches the information internally. If an external starts link training within 80 ms after PERST or serial EEPROM is detected, then a download cycle GRST is de-asserted. is initiated. Also, the process to configure and initialize the PCI Express link is started. The switch starts link training within 80 ms after PERST or GRST is de-asserted. Note: The system must assert PERST before power is removed, before REFCLKI is removed, or before REFCLKI becomes unstable. PCI Express training control hot reset 32 Description The XIO3130 responds to a training control hot reset received on the PCI Express interface. After a training control hot reset, the PCI Express interface enters the DL_DOWN state. In the DL_DOWN state, all remaining configuration register bits and state machines are reset. All remaining bits exclude sticky bits and EEPROM loadable bits. All remaining state machines exclude sticky functionality, EEPROM functionality, and VAUX power management. Submit Documentation Feedback XIO3130 www.ti.com 4 SLLS693D – MAY 2007 – REVISED AUGUST 2008 XIO3130 Configuration Register Space This chapter specifies the configuration registers that are used to enumerate the XIO3130 device within a PC system. An overview of the configuration register space is provided along with a detailed description of the register bits associated with the upstream and downstream ports of the XIO3130. 4.1 PCI Configuration Register Space Overview Each PCI Express port contains a set of PCI configuration registers. One of the upstream port registers, the Global Chip Control register, is used to control functions across the entire XIO3130. For downstream ports, only one register set is specified, but this register set is duplicated for each downstream port. Figure 4-1 illustrates the enumeration topology. The XIO3130 must appear as a hierarchy of PCI-to-PCI bridges in the manner outlined by the PCI Express base specification. NOTE This numbering scheme is typical but not ensured. Bus numbers are assigned within the Type 01h configuration header during the initial enumeration of the PCI bus by the system at power-up. Submit Documentation Feedback XIO3130 Configuration Register Space 33 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Port# 0 Device# 0 Bus# N** Upstream Port Header Type 01h PCI Capability Structures / Proprietary Register Space 000h 03Fh 040h 0FFh 100h Extended Configuration Space / PCI Express Capability Structures FFFh Virtual Internal PCI Bus (Bus# N+1**) Device# 0 Downstream Port Header Type 01h PCI Capability Structures / Proprietary Register Space Device# 1 000h Downstream Port Header Type 01h 03Fh PCI Capability Structures / Proprietary Register Space 040h 0FFh 100h Extended Configuration Space / PCI Express Capability Structures 000h 03Fh 040h 0FFh Device# 2 Downstream Port Header Type 01h PCI Capability Structures / Proprietary Register Space FFFh Port# 1 Bus# N+2** 03Fh 040h 0FFh 100h 100h Extended Configuration Space / PCI Express Capability Structures 000h Extended Configuration Space / PCI Express Capability Structures FFFh FFFh Port# 2 Bus# N+3** Port# 3 Bus# N+4** ** Example values. Actual bus numbers may change based on system hierarchy. Figure 4-1. XIO3130 Enumerations Topology 4.2 PCI Express Upstream Port Registers The default reset domain for all upstream port registers is IPRST. The internal IPRST reset signal is asserted when the internally-generated power-on reset is asserted, when GRST is asserted, when PERST is asserted, or when PCI Express training control hot reset is asserted. Some register fields are placed in a reset domain different from the default reset domain; all bit or field descriptions identify any unique reset domains. Generally, all sticky bits are placed in the GRST domain and all (non-sticky) EEPROM loadable bits are placed in the PERST domain. 34 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com 4.2.1 SLLS693D – MAY 2007 – REVISED AUGUST 2008 PCI Configuration Space (Upstream Port) Register Map Table 4-1. PCI Express Upstream Port Configuration Register Map (Type 1) Register Name Offset Device ID Vendor ID 000h Status Command 004h Class Code BIST Header Type Secondary Latency Timer Subordinate Bus Number Revision ID 008h Latency Timer Cache Line Size 00Ch Secondary Bus Number Primary Bus Number 018h I/O Limit I/O Base 01Ch Reserved 010h-014h Secondary Status Memory Limit Memory Base 020h Pre-fetchable Memory Limit Pre-fetchable Memory Base 024h Pre-fetchable Base Upper 32 Bits 028h Pre-fetchable Limit Upper 32 Bits 02Ch I/O Limit Upper 16 Bits I/O Base Upper 16 Bits Reserved Capabilities Pointer 034h Interrupt Line 03Ch Reserved 038h Bridge Control Interrupt Pin Reserved Power Management Capabilities PM Data (RSVD) 040h-04Ch Next-item Pointer PMCSR_BSE PM CAP ID Power Management CSR Reserved MSI Message Control 054h Next-item Pointer MSI CAP ID 070h MSI Message Address 074h MSI Upper Message Address 078h MSI Message Data Reserved Next-item Pointer Subsystem ID SSID/SSVID CAP ID Subsystem Vendor ID Reserved PCI Express Capabilities Register Next-item Pointer 080h 084h PCI Express Capability ID 090h 094h Device Status Device Control Link Capabilities 098h 09Ch Link Status Link Control 0A0h Reserved Serial Bus Slave Address 07Ch 088h-08Ch Device Capabilities 0A4h-0ACh Serial Bus Index Upstream Port L1 Idle Serial Bus Data GPIO B Control GPIO D Control 0B0h Upstream Port Link PM Latency 0B4h GPIO A Control 0BCh GPIO C Control 0C0h Global Chip Control 0B8h GPIO Data 0C4h TI Proprietary 0C8h-0DCh Subsystem Access 0E0h General Control Global Switch Control 0E4h Downstream Ports Link PM Latency Reserved Submit Documentation Feedback 050h 058h-06Ch Reserved SB Control and Status 030h 0E8h 0ECh-0FCh XIO3130 Configuration Register Space 35 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-2. Extended Configuration Space (Upstream Port) Register Name Next Capability Offset / Capability Version Offset PCI Express Advanced Error Reporting Capabilities ID 100h Uncorrectable Error Status Register 4.2.2 104h Uncorrectable Error Mask Register 108h Uncorrectable Error Severity Register 10Ch Correctable Error Status Register 110h Correctable Error Mask 114h Advanced Error Capabilities and Control 118h Header Log Register 11Ch Header Log Register 120h Header Log Register 124h Header Log Register 128h Reserved 12Ch-FFCh Vendor ID Register This 16-bit read-only register contains the value 104Ch, which is the vendor ID assigned to Texas Instruments. PCI register offset: 00h Register type: Read-only Default value: BIT NUMBER RESET STATE 4.2.3 104Ch 15 0 14 0 13 0 12 1 11 0 10 0 9 0 8 0 7 0 6 1 5 0 4 0 3 1 2 1 1 0 0 0 Device ID Register This 16-bit read-only register contains the value 8232h, which is the device ID assigned by TI to the XIO3130 upstream port function. PCI register offset: 02h Register type: Read-only Default value: 8232Ch BIT NUMBER RESET STATE 4.2.4 14 0 13 0 12 0 11 0 10 0 9 1 8 0 7 0 6 0 5 1 4 1 3 0 2 0 1 1 0 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Command Registers PCI register offset: 04h Register type: Read/Write; Read-only Default value: 0000h BIT NUMBER RESET STATE 36 15 1 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-3. Bit Descriptions – Command Register BIT FIELD NAME ACCESS 15:11 RSVD r 10 INT_DISABLE rw 9 FBB_ENB r DESCRIPTION Reserved. When read, these bits return zeros. INTx disable. This bit is used to enable device-specific interrupts. The XIO3130 upstream port does not generate any interrupts internally, so this bit is ignored. The XIO3130 does forward INTx messages from downstream ports to the upstream port. Fast back-to-back enable. This bit does not apply to PCI-Express, and returns zero when read. SERR enable. When set, the XIO3130 can signal fatal and nonfatal errors on the upstream PCI Express interface. 8 SERR_ENB rw 7 STEP_ENB r 0 – Disable the reporting of nonfatal errors and fatal errors. 1 – Enable the reporting of nonfatal errors and fatal errors. Address/data stepping control. This bit does not apply to PCI-Express and is hardwired to 0. Parity error response enable. Mask bit for the DATAPAR bit in the Status Register. 6 PERR_ENB 0 – The upstream bridge must ignore any address or data parity errors that it detects and continue normal operation. rw 1 – The upstream bridge must detect address or data parity errors and report them by setting the DATAPAR bit in the Status Register. 5 VGA_ENB r VGA palette snoop enable. The XIO3130 does not support VGA palette snooping, thus this bit returns zero when read. 4 MWI_ENB r Memory write and invalidate enable. This bit does not apply to PCI-Express, and is hardwired to zero. 3 SPECIAL r Special cycle enable. This bit does not apply to PCI-Express and is hardwired to zero. Bus master enable. When set, the XIO3130 is enabled to initiate cycles on the upstream PCI Express interface. 2 MASTER_ENB 0 – Upstream PCI Express interface cannot initiate transactions. The bridge must disable response to memory and I/O transactions on the PCI interface. rw 1 – Upstream PCI Express interface can initiate transactions. The bridge can forward memory and I/O transactions from the secondary interface. 1 MEMORY_ENB rw Memory response enable. Setting this bit enables the XIO3130 to respond to memory transactions on the upstream PCI Express interface. 0 IO_ENB rw I/O space enable. Setting this bit enables the XIO3130 to respond to I/O transactions on the upstream PCI Express interface. 4.2.5 Status Register The Status register provides information about the primary interface to the system. PCI register offset: 06h Register type: Read Only; Cleared by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 0010h 15 0 Submit Documentation Feedback 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 1 3 0 2 0 1 0 XIO3130 Configuration Register Space 0 0 37 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-4. Bit Descriptions – Status Register BIT 15 FIELD NAME PAR_ERR ACCESS rcu DESCRIPTION Detected parity error. This bit is set when the PCI Express interface receives a poisoned TLP on the upstream port. This bit is set regardless of the state of the Parity Error Response bit in the Command Register. 0 – No parity error detected. 1 – Parity Error detected. Signaled system error. This bit is set when the XIO3130 sends an ERR_FATAL or ERR_NONFATAL message upstream, and the SERR Enable bit in the Command Register is set. 14 SYS_ERR rcu 0 – No error signaled. 1 – ERR_FATAL or ERR_NONFATAL signaled. Received master abort. This bit is set when the upstream PCI Express interface of the XIO3130 receives a Completion with Unsupported Request Status 13 MABORT rcu 0 – Unsupported Request not received. 1 – Unsupported Request received on. Received target abort. This bit is set when the upstream PCI Express interface of the XIO3130 receives a Completion with Completer Abort Status 12 TABORT_REC rcu 0 – Completer Abort not received. 1 – Completer Abort received. Signaled target abort. This bit is set when the upstream PCI Express interface completes a Request with Completer Abort Status. 11 TABORT_SIG rcu 10:9 PCI_SPEED r 8 DATAPAR rcu Master data parity error. This bit is set when the XIO3130 receives a poisoned completion or poisons a write request on the upstream PCI Express interface. This bit is never set if the parity error response enable bit in the Command register is clear. 7 FBB_CAP r Fast back-to-back capable. This bit does not have a meaningful context for a PCI Express device and is hardwired to 0. 6 RSVD r Reserved. When read, this bit returns zero. 5 66MHZ r 66 MHz capable. This bit does not have a meaningful context for a PCI Express device and is hardwired to 0. 4 CAPLIST r Capabilities list. This bit returns 1 when read, indicating that the XIO3130 supports additional PCI capabilities. 3 INT_STATUS r Interrupt status. This bit reflects the interrupt status of the function. This bit is read-only zero since the XIO3130 upstream port does not generate any interrupts internally. The XIO3130 does forward INTx messages from downstream ports to the upstream port (see INTx Support section). 2:0 RSVD r Reserved. When read, these bits return zeros. 0 – Completer Abort not signaled. 1 – Completer Abort signaled. 38 DEVSEL timing. These bits are read only zero because they do not apply to PCI Express. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com 4.2.6 SLLS693D – MAY 2007 – REVISED AUGUST 2008 Class Code and Revision ID Register This read-only register categorizes the Base Class, Sub Class, and Programming Interface of the XIO3130. The Base Class is 06h, identifying the device as bridge device. The Sub Class is 04h, identifying the function as a PCI-to-PCI bridge, and the Programming Interface is 00h. Also, the TI chip revision is indicated in the lower byte (02h). PCI register offset: 08h Register type: Read only Default value: 0604 0002h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 1 25 1 24 0 23 0 22 0 21 0 20 0 19 0 18 1 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 Table 4-5. Bit Descriptions – Class Code and Revision ID Register BIT FIELD NAME ACCESS 31:24 BASECLASS r Base Class. This field returns 06h when read, which classifies the function as a Bridge device. 23:16 SUBCLASS r Sub Class. This field returns 04h when read, which specifically classifies the function as a PCI-to-PCI bridge. 15:8 PGMIF r Programming Interface. This field returns 00h when read. 7:0 CHIPREV r Silicon Revision. This field returns the silicon revision. 4.2.7 DESCRIPTION Cache Line Size Register The Cache Line Size Register is implemented by PCI Express devices as a read-write field for legacy compatibility purposes but has no impact on any PCI Express device functionality. PCI register offset: 0Ch Register type: Read/Write Default value: BIT NUMBER RESET STATE 4.2.8 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Primary Latency Timer Register This read-only register has no meaningful context for a PCI Express device and returns zeros when read. PCI register offset: 0Dh Register type: Read Only Default value: 00h BIT NUMBER RESET STATE 7 0 Submit Documentation Feedback 6 0 5 0 4 0 3 0 2 0 1 0 0 0 XIO3130 Configuration Register Space 39 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.9 www.ti.com Header Type Register This read-only register indicates that this function has a type one PCI header. Bit seven of this register is a zero, indicating that the upstream port is a single device. PCI register offset: 0Eh Register type: Read Only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.2.10 BIST Register Since the XIO3130 does not support a built-in self test (BIST), this read-only register returns the value of 00h when read. PCI register offset: 0Fh Register type: Read Only Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.11 Primary Bus Number This read/write register specifies the bus number of the PCI bus segment to which the upstream PCI Express interface is connected. PCI register offset: 18h Register type: Read/Write Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.12 Secondary Bus Number This read/write register specifies the bus number of the PCI bus segment for the XIO3130’s internal PCI bus. The XIO3130 uses this register to determine how to respond to a Type 1 configuration transaction. PCI register offset: 19h Register type: Read/Write Default value: 00h BIT NUMBER RESET STATE 40 7 0 6 0 5 0 XIO3130 Configuration Register Space 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.13 Subordinate Bus Number This register specifies the bus number of the highest number PCI bus segment that is downstream of the XIO3130’s upstream port. The XIO3130 uses this register to determine how to respond to a Type 1 configuration transaction. PCI register offset: 1Ah Register type: Read/Write Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.14 Secondary Latency Timer Register This register does not apply to PCI-Express. It is hardwired to zero. PCI register offset: 1Bh Register type: Read Only Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.15 I/O Base Register This read/write register specifies the lower limit of the I/O addresses that the XIO3130 forwards downstream. PCI register offset: 1Ch Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 01h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-6. Bit Descriptions – I/O Base Register BIT FIELD NAME ACCESS DESCRIPTION 7:4 IOBASE rw I/O base. These bits define the bottom address of the I/O address range that is used to determine when to forward I/O transactions from one interface to the other. These bits correspond to address bits [15:12] in the I/O address. The lower 12 I/O address bits are assumed to be 0. The 16 bits corresponding to address bits [31:16] of the I/O address are defined in the I/O Base Upper 16 Bits register. 3:0 IOTYPE r Submit Documentation Feedback I/O type. This field is read-only 01h, indicating that the XIO3130 supports 32-bit I/O addressing. XIO3130 Configuration Register Space 41 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.16 I/O Limit Register This read/write register specifies the upper limit of the I/O addresses that the XIO3130 forwards downstream. PCI register offset: 1Dh Register type: Read/Write; Read Only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-7. Bit Descriptions – I/O Limit Register BIT FIELD NAME ACCESS DESCRIPTION I/O limit. These bits define the top address of the I/O address range used to determine when to forward I/O transactions from one interface to the other. These bits correspond to address bits [15:12] in the I/O address. The lower 12 I/O address bits are assumed to be FFFh. The 16 bits corresponding to address bits [31:16] of the I/O address are defined in the I/O Limit Upper 16 Bits register. 7:4 IOLIMIT rw 3:0 IOTYPE r I/O type. This field is read-only 01h, indicating that the XIO3130 supports 32-bit I/O addressing. 4.2.17 Secondary Status Register The Secondary Status register provides information about the XIO3130’s internal PCI bus between the upstream port and the downstream ports. PCI register offset: 1Eh Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-8. Bit Descriptions – Secondary Status Register BIT 42 FIELD NAME ACCESS DESCRIPTION 15 PAR_ERR r Detected parity error. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 14 SYS_ERR r Received system error. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 13 MABORT r Received master abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 12 TABORT_REC r Received target abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 11 TABORT_SIG r Signaled target abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 10:9 PCI_SPEED r DEVSEL timing. These bits are hardwired to 00. These bits do not apply to PCI Express. 8 DATAPAR r Master data parity error. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus. 7 FBB_CAP r Fast back-to-back capable. This bit is hardwired to zero. This bit does not apply to PCI Express. 6 RSVD r Reserved. When read, this bit returns zero. 5 66MHZ r 66 MHz capable. This bit is hardwired to zero. This bit does not apply to PCI Express. 4:0 RSVD r Reserved. When read, these bits return zeros. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.18 Memory Base Register This read/write register specifies the lower limit of the memory addresses that the XIO3130 forwards downstream. PCI register offset: 20h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-9. Bit Descriptions – Memory Base Register BIT FIELD NAME ACCESS 15:4 MEMBASE rw 3:0 RSVD r DESCRIPTION Memory base. This field defines the bottom address of the memory address range used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be 0. Reserved. When read, these bits return zeros. 4.2.19 Memory Limit Register This read/write register specifies the upper limit of the memory addresses that the XIO3130 forwards downstream. PCI register offset: 22h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-10. Bit Descriptions – Memory Limit Register BIT FIELD NAME ACCESS 15:4 MEMLIMIT rw 3:0 RSVD r DESCRIPTION Memory limit. This field defines the top address of the memory address range used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be FFFFFh. Reserved. When read, these bits return zeros. 4.2.20 Pre-fetchable Memory Base Register This read/write register specifies the lower limit of the pre-fetchable memory addresses that the XIO3130 forwards downstream. PCI register offset: 24h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 0001h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-11. Bit Descriptions – Pre-fetchable Memory Base Register BIT 15:4 FIELD NAME ACCESS DESCRIPTION rw Pre-fetchable memory base. This field defines the bottom address of the pre-fetchable memory address range that is used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be 0. The Pre-fetchable Base Upper 32 Bits register is used to specify the bit [63:32] of the 64-bit pre-fetchable memory address. PREBASE Submit Documentation Feedback XIO3130 Configuration Register Space 43 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-11. Bit Descriptions – Pre-fetchable Memory Base Register (continued) BIT 3:0 FIELD NAME ACCESS DESCRIPTION r 64-bit memory indicator. These read-only bits indicate that 64-bit addressing is supported for this memory window. 64BIT 4.2.21 Pre-Fetchable Memory Limit Register This read/write register specifies the upper limit of the pre-fetchable memory addresses that the XIO3130 forwards downstream. PCI register offset: 26h Register type: Read/Write; Read Only Default value: 0001h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-12. Bit Descriptions – Pre-fetchable Memory Limit Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 PRELIMIT rw Pre-fetchable memory limit. These bits define the top address of the pre-fetchable memory address range used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be FFFFFh. The Pre-fetchable Limit Upper 32 Bits register is used to specify the bit [63:32] of the 64-bit pre-fetchable memory address. 3:0 64BIT r 64-bit memory indicator. These read-only bits indicate that 64-bit addressing is supported for this memory window. 4.2.22 Pre-Fetchable Base Upper 32 Bits Register This read/write register specifies the upper 32 bits of the Pre-fetchable Memory Base register. PCI register offset: 28h Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-13. Bit Descriptions – Pre-fetchable Base Upper 32 Bits Register BIT 31:0 44 FIELD NAME PREBASE ACCESS rw DESCRIPTION Pre-fetchable memory base upper 32 bits. This field defines the upper 32 bits of the bottom address of the pre-fetchable memory address range that is used to determine when to forward memory transactions downstream. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.23 Pre-fetchable Limit Upper 32 Bits Register This read/write register specifies the upper 32 bits of the Pre-fetchable Memory Limit register. PCI register offset: 2Ch Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-14. Bit Descriptions – Pre-fetchable Limit Upper 32 Bits Register BIT FIELD NAME ACCESS 31:0 PRELIMI T rw DESCRIPTION Pre-fetchable memory limit upper 32 bits. This field defines the upper 32 bits of the top address of the pre-fetchable memory address range used to determine when to forward memory transactions downstream. 4.2.24 I/O Base Upper 16 Bits Register This read/write register specifies the upper 16 bits of the I/O Base register. PCI register offset: 30h Register type: Read/Write Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-15. Bit Descriptions – I/O Base Upper 16 Bits Register BIT 15:0 FIELD NAME ACCESS IOBASE rw DESCRIPTION I/O base upper 16 bits. This field defines the upper 16 bits of the bottom address of the I/O address range that is used to determine when to forward I/O transactions downstream. 4.2.25 I/O Limit Upper 16 Bits Register This read/write register specifies the upper 16 bits of the I/O Limit register. PCI register offset: 32h Register type: Read/Write Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-16. Bit Descriptions – I/O Limit Upper 16 Bits Register BIT FIELD NAME ACCESS 15:0 IOLIMIT rw DESCRIPTION I/O limit upper 16 bits. This field defines the upper 16 bits of the top address of the I/O address range used to determine when to forward I/O transactions downstream. 4.2.26 Capabilities Pointer Register This read-only register provides a pointer into the PCI configuration header where the PCI power management block resides. Since the PCI power management registers begin at 50h, this register is hardwired to 50h. Submit Documentation Feedback XIO3130 Configuration Register Space 45 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com PCI register offset: 34h Register type: Read only Default value: 50h BIT NUMBER RESET STATE 7 0 6 1 5 0 4 1 3 0 2 0 1 0 0 0 4.2.27 Interrupt Line Register This read/write register, which is programmed by the system, indicates to the software which interrupt line the XIO3130 has assigned to it. The default value of this register is FFh, which indicates that an interrupt line has not yet been assigned to the function. Since the XIO3130 does not generate interrupts internally, this register is essentially a scratch-pad register; it has no effect on the XIO3130 itself. PCI register offset: 3Ch Register type: Read/Write Default value: FFh BIT NUMBER RESET STATE 7 1 6 1 5 1 4 1 3 1 2 1 1 1 0 1 4.2.28 Interrupt Pin Register The Interrupt Pin register is read-only 00h, which indicates that the XIO3130 upstream port does not generate interrupts. The value of this register has no effect on forwarding interrupts from the downstream ports to the upstream port. PCI register offset: 3Dh Register type: Read Only Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.29 Bridge Control Register The Bridge Control register provides extensions to the Command register that are specific to a bridge. PCI register offset: 3Eh Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 46 0000h 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-17. Bit Descriptions – Bridge Control Register BIT FIELD NAME ACCESS 15:12 RSVD r Reserved. When read, these bits return zeros. 11 DTSERR r Discard timer SERR enable. This bit is hardwired to zero. This bit does not apply to PCI Express. 10 DTSTATUS r Discard timer status. This bit is hardwired to zero. This bit does not apply to PCI Express. 9 SEC_DT r Secondary discard timer. This bit is hardwired to zero. This bit does not apply to PCI Express. 8 PRI_DEC r Primary discard timer. This bit is hardwired to zero. This bit does not apply to PCI Express. 7 FBB_EN r Fast back-to-back enable. This bit is hardwired to zero. This bit does not apply to PCI Express. 6 SRST rw DESCRIPTION Secondary bus reset. This bit is set when software wishes to reset all devices downstream of the XIO3130. Setting this bit causes all of the downstream ports to be reset, and all of the downstream ports to send a reset via a training sequence. 0 – Downstream ports not in Reset state. 1 – Downstream ports in Reset state. 5 MAM r Master abort mode. This bit is hardwired to zero. This bit does not apply to PCI Express. VGA 16-bit decode. This bit enables the XIO3130 to provide full 16-bit decoding for VGA I/O addresses. This bit only has meaning if the VGA enable bit is set. 4 VGA16 rw 0 – Ignore address bits [15:10] when decoding VGA I/O addresses. 1 – Decode address bits [15:10] when decoding VGA I/O addresses. VGA enable. This bit modifies the response by the XIO3130 to VGA-compatible addresses. If this bit is set, the XIO3130 positively decodes and forwards the following accesses on the primary interface to the secondary interface (and, conversely, blocks the forwarding of these addresses from the secondary to primary interface): • Memory accesses in the range 000A 0000h to 000BFFFFh • I/O addresses in the first 64 KB of the I/O address space (Address bits [31:16] are 0000h) and where address bits [9:0] is in the range of 3B0h to 3BBh or 3C0h to 3DFh (inclusive of ISA address aliases – Address bits [15:10] may possess any value and is not used in the decoding). 3 VGA rw If the VGA Enable bit is set, forwarding of VGA addresses is independent of the value of the ISA Enable bit (located in the Bridge Control register), the I/O address range and memory address ranges defined by the I/O Base and Limit registers, the Memory Base and Limit registers, and the Pre-fetchable Memory Base and Limit registers of the bridge. The forwarding of VGA addresses is qualified by the I/O Enable and Memory Enable bits in the Command register. 0 – Do not forward VGA-compatible memory and I/O addresses from the primary to secondary interface (addresses defined above) unless they are enabled for forwarding by the defined I/O and memory address ranges. 1 – Forward VGA-compatible memory and I/O addresses (addresses defined above) from the primary interface to the secondary interface (if the I/O Enable and Memory Enable bits are set) independent of the I/O and memory address ranges and independent of the ISA Enable bit. 2 ISA rw ISA enable. This bit modifies the response by the XIO3130 to ISA I/O addresses. This bit applies only to I/O addresses that are enabled by the I/O Base and I/O Limit registers and are in the first 64 KB of PCI I/O address space (0000 0000h to 0000 FFFFh). If this bit is set, the bridge blocks any forwarding from primary to secondary of I/O transactions addressing the last 768 bytes in each 1 KB block. In the opposite direction (secondary to primary), I/O transactions are forwarded if they address the last 768 bytes in each 1K block. 0 – Forward downstream all I/O addresses in the address range defined by the I/O Base and I/O Limit registers. 1 – Forward upstream ISA I/O addresses in the address range defined by the I/O Base and I/O Limit registers that are in the first 64 KB of PCI I/O address space (top 768 bytes of each 1 KB block). SERR enable. This bit controls forwarding of system error events upstream from the secondary interface to the primary interface. The XIO3130 forwards system error events when: • This bit is set. 1 SERR_EN rw • The SERR enable bit in the upstream port command register is set. • SERR is asserted on the secondary interface. 0 – Disable the forwarding of system error events. 1 – Enable the forwarding of system error events. Submit Documentation Feedback XIO3130 Configuration Register Space 47 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-17. Bit Descriptions – Bridge Control Register (continued) BIT 0 FIELD NAME ACCESS DESCRIPTION rw Parity error response enable. It is assumed that the relevant error checking is unnecessary for the XIO3130’s internal PCI bus; therefore, setting this bit has no effect. PERR_EN 4.2.30 Capability ID Register This read-only register identifies the linked list item as the register for PCI power management. The register returns 01h when read. PCI register offset: 50h Register type: Read only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.2.31 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130. This register reads 70h, which points to the MSI Capabilities registers. PCI register offset: 51h Register type: Read only Default value: 70h BIT NUMBER RESET STATE 7 0 6 1 5 1 4 1 3 0 2 0 1 0 0 0 4.2.32 Power Management Capabilities Register This register indicates the capabilities of the XIO3130 related to PCI power management. PCI register offset: 52h Register type: Read only Default value: XX03h BIT NUMBER RESET STATE 15 y 14 1 13 1 12 x 11 1 10 1 9 x 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 1 0 1 Table 4-18. Bit Descriptions – Power Management Capabilities Register BIT FIELD NAME ACCESS DESCRIPTION 15:11 PME_SUPPORT r PME support. This five-bit field indicates the power states from which the (upstream) port may assert PME. These five bits return a value of 5’by11x1, indicating that the XIO3130 can assert PME from D0, D2, D3hot, maybe D3cold (i.e., depending on y), and maybe D1 (i.e., depending on x). The bit defining this for D3cold (i.e., y) is controlled by the AUX_PRSNT bit in the Global Chip Control register. The bit defining this for D1 (i.e., x) is controlled by the D1_SUPPORT bit in the Global Switch Control register. 10 D2_SUPPORT r D2 device power state support. This bit returns a 1 when read, which indicates that the function supports the D2 device power state. 9 D1_SUPPORT r D1 device power state support. This bit indicates whether the function supports the D1 device power state. This bit is controlled by the D1_SUPPORT bit in the Global Switch Control register. The default value x refers to whatever the default value is for the D1_SUPPORT bit in the Global Switch Control register. 8:6 AUX_CURRENT r 3.3-VAUX auxiliary current requirements. This field is hardwired to 3’b000. See PCI Power Management Specification Revision 1.2, Section 3.2.3, Page 26, for mapping this field to specific current consumption values. 5 DSI r Device-specific initialization. This bit returns 0 when read, which indicates that the XIO3130 does not require special initialization beyond the standard PCI configuration header before a generic class driver is able to use it. 48 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-18. Bit Descriptions – Power Management Capabilities Register (continued) BIT FIELD NAME ACCESS 4 RSVD r Reserved. When read, this bit returns zero. DESCRIPTION 3 PME_CLK r PME clock. This bit returns zero, which indicates that the PCI clock is not needed to generate PME. 2:0 PM_VERSION r Power management version. This field returns 3’b011, which indicates Revision 1.2 compatibility. 4.2.33 Power Management Control/Status Register This register determines and changes the current power state of the XIO3130. PCI register offset: 54h Register type: Read/Write; Read Only Default value: 0008h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 1 2 0 1 0 0 0 Table 4-19. Bit Descriptions – Power Management Control/Status Register BIT FIELD NAME ACCESS DESCRIPTION 15 PME_STAT r PME status. This bit is hardwired to 0b since the XIO3130’s upstream port does not generate PME regardless of PME_SUPPORT field setting. 14:13 DATA_SCALE r Data scale. This 2-bit field returns 0’s when read since the XIO3130 does not use the Data Register. 12:9 DATA_SEL r Data select. This 4-bit field returns 0’s when read since the XIO3130 does not use the Data Register 8 PME_EN r PME enable. This bit enables PME signaling. This bit is hardwired to 0b since the XIO3130’s upstream port does not generate PME. 7:4 RSVD r Reserved. When read, these bits return zeros. 3 NO_SOFT_RST r No soft reset. This bit controls whether the transition from D3hot to D0 resets the state according to the PCI Power Management Specification Revision 1.2. This bit is hardwired to 1’b1. 0 – D3hot to D0 transition causes reset. 1 – D3hot to D0 transition does not cause reset. 2 RSVD r Reserved. When read, this bit returns zero. Power state. This 2-bit field is used both to determine the current power state of the function and to set the function into a new power state. This field is encoded as follows: 00 = D0 1:0 PWR_STATE rw 01 = D1 10 = D2 11 = D3hot See the Power Management section of this document for information about what the XIO3130 does in these different power states. Submit Documentation Feedback XIO3130 Configuration Register Space 49 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.34 Power Management Bridge Support Extension Register This read-only register is used to indicate to host software the state of the secondary bus when the XIO3130 is placed in D3. PCI register offset: 56h Register type: Read only Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-20. Bit Descriptions – PM Bridge Support Extension Register BIT FIELD NAME ACCESS DESCRIPTION 7 BPCC r Bus power/Clock control enable. This bit is read-only zero. This bit does not apply to PCI Express. 6 BSTATE r B2/B3 support. This bit is read-only zero. This bit does not apply to PCI Express. 5:0 RSVD r Reserved. When read, these bits return zeros. 4.2.35 Power Management Data Register This read-only register is not applicable to the XIO3130 and returns 00h when read. PCI register offset: 57h Register type: Read only Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.36 MSI Capability ID Register This read-only register identifies the linked list item as the register for Message Signaled Interrupts (MSI) Capabilities. The register returns 05h when read. PCI register offset: 70h Register type: Read only Default value: BIT NUMBER RESET STATE 05h 7 0 6 0 5 0 4 0 3 0 2 1 1 0 0 1 4.2.37 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130. This register reads 80h, which points to the Subsystem ID and Subsystem Vendor ID Capabilities registers. PCI register offset: 71h Register type: Read only Default value: 80h BIT NUMBER RESET STATE 50 7 1 6 0 5 0 XIO3130 Configuration Register Space 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.38 MSI Message Control Register This register is used to control the sending of MSI messages. PCI register offset: 72h Register type: Read/Write; Read Only Default value: 0080h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 1 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-21. Bit Descriptions – MSI Message Control Register BIT FIELD NAME ACCESS DESCRIPTION 15:8 RSVD r Reserved. When read, these bits return zeros. 7 64CAP r 64-bit message capability. This bit is read-only 1, which indicates that the XIO3130 supports 64-bit MSI message addressing. Multiple message enable. This bit indicates the number of distinct messages that the XIO3130 is allowed to generate. 000 – 1 Message 001 – 2 Messages 010 – 4 Messages 6:4 MM_EN rw 011 – 8 Messages 100 – 16 Messages 101 – 32 Messages 110 – Reserved 111 – Reserved 3:1 MM_CAP Multiple message capabilities. This field indicates the number of distinct messages that the XIO3130 is capable of generating. This field is read-only 000, which indicates that the XIO3130 can signal one interrupt. r MSI enable. This bit is used to enable MSI interrupt signaling. MSI signaling must be enabled by software for the XIO3130 to send MSI messages. 0 MSI_EN rw 0 – MSI signaling is prohibited. 1 – MSI signaling is enabled. 4.2.39 MSI Message Address Register This register contains the lower 32 bits of the address that a MSI message shall be written to when an interrupt is to be signaled. PCI register offset: 74h Register type: Read/Write; Read Only Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-22. Bit Descriptions – MSI Message Address Register BIT FIELD NAME ACCESS 31:2 ADDRESS rw 1:0 RSVD r Submit Documentation Feedback DESCRIPTION System Specified Message Address. Reserved. When read, these bits return zeros. XIO3130 Configuration Register Space 51 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.40 MSI Message Upper Address Register This register contains the upper 32 bits of the address that a MSI message shall be written to when an interrupt is to be signaled. If this register is 0000 0000h, 32-bit addressing is used; otherwise, 64-bit addressing is used. PCI register offset: 78h Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 PCI register offset: 56h Register type: Read only Default value: 00h 4.2.41 MSI Message Data Register This register contains the data that software programmed the device to send when it sends a MSI message. PCI register offset: 7Ch Register type: Read/Write Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-23. Bit Descriptions – MSI Data Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 MSG rw System-specific message. This field contains the portion of the message that the XIO3130 can never modify. 3:0 MSG_NUM rw Message number. This portion of the message field may be modified to contain the message number if multiple messages are enabled. Since the XIO3130 only generates one MSI type, these bits are not modified by XIO3130 hardware. 4.2.42 Capability ID Register This read-only register identifies the linked list item as the register for Subsystem ID and Subsystem Vendor ID Capabilities. The register returns 0Dh when read. PCI register offset: 80h Register type: Read only Default value: BIT NUMBER RESET STATE 0Dh 7 0 6 0 5 0 4 0 3 1 2 1 1 0 0 1 4.2.43 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130. This register reads 90h, which points to the PCI Express Capabilities registers. PCI register offset: 52 81h XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Register type: Read only Default value: 90h BIT NUMBER RESET STATE 7 1 6 0 5 0 4 1 3 0 2 0 1 0 0 0 4.2.44 Subsystem Vendor ID Register This register, which is used for system and option card identification purposes, may be required for certain operating systems. This read-only register is a direct reflection of the Subsystem Access register, which is read/write and is initialized through the EEPROM (if present). PCI register offset: 84h Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.45 Subsystem ID Register This register, which is used for system and option card identification purposes, may be required for certain operating systems. This read-only register is a direct reflection of the Subsystem Access register, which is read/write and is initialized through the EEPROM (if present). PCI register offset: 86h Register type: Read only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.46 PCI Express Capability ID Register This read-only register identifies the linked list item as the register for PCI Express Capabilities. The register returns 10h when read. PCI register offset: 90h Register type: Read only Default value: BIT NUMBER RESET STATE 10h 7 0 Submit Documentation Feedback 6 0 5 0 4 1 3 0 2 0 1 0 0 0 XIO3130 Configuration Register Space 53 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.47 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130. This register reads 00h, which indicates that no additional capabilities are supported. PCI register offset: 91h Register type: Read only Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.48 PCI Express Capabilities Register This register indicates the capabilities of the upstream port of the XIO3130 related to PCI Express. PCI register offset: 92h Register type: Read only Default value: BIT NUMBER RESET STATE 0051h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 1 5 0 4 1 3 0 2 0 1 0 0 1 Table 4-24. Bit Descriptions – PCI Express Capabilities Register BIT FIELD NAME ACCESS 15:14 RSVD r Reserved. When read, these bits return zeros. DESCRIPTION 13:9 INT_NUM r Interrupt message number. This field is used for MSI support and is implemented as read-only zero in the XIO3130. 8 SLOT r Slot implemented. This bit is invalid for the upstream port on the XIO3130 and is read-only zero. 7:4 DEV_TYPE r Device/Port type. This read-only field returns 0101b, which indicates that the device is an upstream port of a PCI Express XIO3130. 3:0 VERSION r Capability version. This field returns 0001b, which indicates revision 1 of the PCI Express capability. 4.2.49 Device Capabilities Register The Device Capabilities register indicates the device-specific capabilities of the XIO3130. 54 PCI register offset: 94h Register type: Read Only; Hardware Update Default value: 0000 8001h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-25. Bit Descriptions – Device Capabilities Register BIT FIELD NAME ACCESS 31:28 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Captured slot power limit scale. The value in this register is programmed by the host by issuing a Set_Slot_Power_Limit Message. When a Set_Slot_Power_Limit Message is received, bits 9:8 are written to this field. The value in this register specifies the scale used for the Slot Power Limit. 27:26 CSPLS ru 00 – 1.0x 01 – 0.1x 10 – 0.01x 11 – 0.001x 25:18 CSPLV ru Captured slot power limit value. The value in this register is programmed by the host by issuing a Set_Slot_Power_Limit Message. When a Set_Slot_Power_Limit Message is received, bits 7:0 are written to this field. The value in this register, in combination with the Slot power limit scale value, specifies the upper limit of power supplied to the slot. The power limit is calculated by multiplying the value in this field by the value in the Slot power limit scale field. 17:16 RSVD r Reserved. When read, these bits return zeros. 15 RBER r Role-based error reporting. This field is set to 1b to indicate support for role-based error reporting. 14:6 RSVD r Reserved. When read, these bits return zeros. 5 ETFS r Extended tag field supported. This field indicates the size of the tag field supported. This bit is hardwired to zero, indicating support for 5-bit tag fields. 4:3 PFS r Phantom functions supported. This field is read-only 00b, indicating that function numbers are not used for phantom functions. 2:0 MPSS r Max payload size supported. This field indicates the maximum payload size that the device can support for TLPs. This field is encoded as 001b, which indicates that the maximum payload size for a TLP is 256 bytes. 4.2.50 Device Control Register The Device Control register controls PCI Express device-specific parameters. PCI register offset: 98h Register type: Read/Write; Read Only Default value: 2000h BIT NUMBER RESET STATE 15 0 14 0 13 1 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-26. Bit Descriptions – Device Control Register BIT FIELD NAME ACCESS 15 RSVD r DESCRIPTION Reserved. When read, this bit returns zero. Max read request size. This field is programmed by the host software to set the maximum size of a read request that the XIO3130 can generate. The XIO3130 uses this field in conjunction with the cache line size register to determine how much data to fetch on a read request. This field is encoded as: 000 – 128B 001 – 256B 14:12 MRRS rw 010 – 512B 011 – 1024B 100 – 2048B 101 – 4096B 110 – Reserved 111 – Reserved 11 ENS Submit Documentation Feedback r Enable no snoop. Since the XIO3130 does not initiate such transactions, this bit is read-only zero. XIO3130 Configuration Register Space 55 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-26. Bit Descriptions – Device Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 10 APPE r Auxiliary power PM enable. This bit is read-only zero, since the XIO3130 requires a minimal amount of AUX power when PME is disabled. 9 PFE r Phantom function enable. Since the XIO3130 part does not support phantom functions, this bit is read-only zero. 8 ETFE r Extended tag field enable. Since the XIO3130 part does not support extended tags, this bit is read-only zero. Max payload size. This field is programmed by the host software to set the maximum size of posted writes or read completions that the XIO3130 can initiate. This field is encoded as: 000 – 128B 001 – 256B 010 – 512B 7:5 MPS rw 011 – 1024B 100 – 2048B 101 – 4096B 110 – Reserved 111 – Reserved 4 3 ERO Enable relaxed ordering. Since the XIO3130 part does not support relaxed ordering, this bit is read-only zero. r URRE Unsupported request reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_NONFATAL messages to the root complex when an unsupported request is received by the upstream port. rw 0 – Do not report unsupported requests to the root complex. 1 – Report unsupported requests to the root complex. Fatal error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_FATAL messages to the root complex when a system error event occurs. 2 FERE rw 0 – Do not report fatal errors to the root complex. 1 – Report fatal errors to the root complex. Nonfatal error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_NONFATAL messages to the root complex when a system error event occurs. 1 NFERE rw 0 – Do not report nonfatal errors to the root complex. 1 – Report nonfatal errors to the root complex. Correctable error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_CORR messages to the root complex when a system error event occurs. 0 CERE rw 0 – Do not report correctable errors to the root complex. 1 – Report correctable errors to the root complex. 4.2.51 Device Status Register The Device Status register controls PCI Express device-specific parameters. PCI register offset: 9Ah Register type: Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 00X0h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 x 3 0 2 0 1 0 0 0 Table 4-27. Bit Descriptions – Device Status Register BIT FIELD NAME ACCESS 15:6 RSVD r Reserved. When read, these bits return zeros. 5 PEND ru Transaction PENDING. This bit is set when the XIO3130 has issued a non-posted transaction that has not been completed yet. 56 DESCRIPTION XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-27. Bit Descriptions – Device Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION AUX power detected. This bit indicates that AUX power is present. This bit is a direct reflection of the AUX_PRSNT bit in the Global Chip Control register and has the same default value. 4 APD ru 0 – No AUX power detected. 1 – AUX power detected. 3 URD rcu Unsupported request detected. This bit is asserted when a request is received that results in sending a completion with an Unsupported Request status). Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 2 FED rcu Fatal error detected. This bit is set by the XIO3130 when a fatal error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 1 NFED rcu Nonfatal error detected. This bit is set by the XIO3130 when a nonfatal error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 0 CED rcu Correctable error detected. This bit is set by the XIO3130 when a correctable error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 4.2.52 Link Capabilities Register The Link Capabilities register indicates the link-specific capabilities of the device. PCI register offset: 9Ch Register type: Read only Default value: 000X XX11h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 1 17 y 16 y BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE y z z z x 1 0 0 0 0 0 1 0 0 0 1 Table 4-28. Bit Descriptions – Link Capabilities Register BIT FIELD NAME ACCESS 31:24 PORT_NUM r Port number. This field indicates the port number for the PCI Express link. This field is read-only zero. 23:19 RSVD r Reserved. When read, these bits return zeros. 18 CLK_PM r Clock power management. This field is read-only 1b, which indicates that CLKREQ is supported on the upstream port. r L1 exit latency. This field indicates the time that it takes to transition from the L1 state to the L0 state. This field is a direct reflection of the Upstream Port Link PM Latency register L1_EXIT_LAT field, which is a read/write field that is loaded from EEPROM (if present). The default value of this field, yyy, is the same as the default value of the Link PM Latency register L1_EXIT_LAT field. 17:15 L1_LATENCY DESCRIPTION 14:12 L0S_LATENCY r L0s exit latency. This field indicates the time that required to transition from the L0s state to the L0 state. This field is a direct reflection of the Upstream Port Link PM Latency register L0S_EXIT_LAT field, which is a read/write field that is loaded from EEPROM (if present). The default value of this field, zzz, is the same as the default value of the Link PM Latency register L0S_EXIT_LAT field. 11:10 ASLPMS r Active state link PM support. This field reads either 01b or 11b, which indicates that the device supports L0s and may or may not support ASPM-based L1 for Active State Link PM. ASPM-based L1 support is controlled by the ASPM_L1_EN field in the Global Chip Control register. 9:4 MLW r Maximum link width. This field is encoded 000001b to indicate that the device only supports an x1 PCI Express link. 3:0 MLS r Maximum link speed. This field is encoded 0001b to indicate that the device supports a maximum link speed of 2.5 Gb/s. Submit Documentation Feedback XIO3130 Configuration Register Space 57 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.53 Link Control Register The Link Control register is used to control link-specific behavior. PCI register offset: A0h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-29. Bit Descriptions – Link Control Register BIT FIELD NAME ACCESS 15:9 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Clock power management enable. When CLKREQ support is enabled, the EP_LI_LAT field in the Upstream Ports Link PM Latency register increases due to link PLL locking requirements. 8 CPM_EN rw 0 – Disable CLKREQ on upstream port 1 – Enable CLKREQ on upstream port Extended synch. This bit is used to force the device to extend the transmission of FTS ordered sets and an extra TS2 when exiting from L1 before entering to L0. 7 ES rw 0 – Normal synch 1 – Extended synch Common clock configuration. This bit is set when a common clock is provided to both ends of the PCI Express link. This bit can be used to change the L0s and L1 exit latencies. 6 CCC rw 5 RL r Retrain link. This bit has no function for upstream ports and is read-only zero. 4 LD r Link disable. This bit has no function for upstream ports and is read-only zero. r Read completion boundary. This bit specifies the minimum size read completion packet that the XIO3130 can send when breaking a read request into multiple completion packets. This field is not applicable to XIO3130 switches; i.e., the XIO3130 does not break up completion packets and is hardwired to zero. 0 – Reference clock is asynchronous. 1 – Reference clock is synchronous. 3 RCB 0 – 64 bytes 1 – 128 bytes 2 RSVD r Reserved. When read, this bit returns zero. Active state link PM control. This field is used to enable and disable active state PM. 00 – Active state PM disabled 1:0 ASLPMC rw 01 – L0s entry enabled 10 – Reserved 11 – L0s and L1 entry enable 58 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.54 Link Status Register The Link Status register indicates the current state of the PCI Express Link. PCI register offset: A2h Register type: Read only Default value: 1X11h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 1 11 0 10 x 9 0 8 0 7 0 6 0 5 0 4 1 3 0 2 0 1 0 0 1 Table 4-30. Bit Descriptions – Link Status Register BIT FIELD NAME ACCESS DESCRIPTION 15:13 RSVD r Reserved. When read, these bits return zeros. 12 SCC r Slot clock configuration. This bit reflects the reference clock configurations and is read-only 1, indicating that a 100 MHz common clock reference is used. 11 LT r Link training in progress. This bit has no function for upstream ports and is read-only zero. 10 UNDEF r Undefined. The value read from this bit is undefined. 9:4 NLW r Negotiated link width. This field is read-only 000001b, which indicates that the lane width is x1. 3:0 LS r Link speed. This field is read-only 0001b, which indicates that the link speed is 2.5Gb/s. 4.2.55 Serial Bus Data Register The Serial Bus Data register is used to read and write data on the serial bus interface, e.g., for use with a serial EEPROM. When writing data to the serial bus, this register must be written before writing to the Serial Bus Address register to initiate the cycle. When reading data from the serial bus, this register contains the data read after the REQBUSY (bit 5 Serial Bus Control register) bit is cleared. This register is reset with PERST. PCI register offset: B0h Register type: Read/Write Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.56 Serial Bus Index Register The value written to the Serial Bus Index register represents the byte address of the byte being read or written from the serial bus device. The Serial Bus Index register must be written before initiating a serial bus cycle by writing to the Serial Bus Slave Address register. This register is reset with PERST. PCI register offset: B1h Register type: Read/Write Default value: BIT NUMBER RESET STATE 00h 7 0 Submit Documentation Feedback 6 0 5 0 4 0 3 0 2 0 1 0 0 0 XIO3130 Configuration Register Space 59 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.57 Serial Bus Slave Address Register The Serial Bus Slave Address register is used to indicate the address of the device being targeted by the serial bus cycle. This register also indicates whether the cycle will be a read or a write cycle. Writing to this register initiates the cycle on the serial interface. This register is reset with PERST. The default value corresponds to a serial EEPROM slave address of 7’b101_0000. PCI register offset: B2h Register type: Read/Write Default value: A0h BIT NUM BER RESET STATE 7 1 6 0 5 1 4 0 3 0 2 0 1 0 0 0 Table 4-31. Bit Descriptions – Serial Bus Slave Address Register BIT FIELD NAME ACCESS 7:1 SLAVE_ADDR rw DESCRIPTION Serial bus slave address. This bit field represents the slave address for a read/write transaction on the serial interface. This field is reset with PERST. Read/Write command. This bit is used to determine whether the serial bus cycle is a read or a write cycle. 0 RW_CMD 0 – A single byte write is requested. rw 1 – A single byte read is requested. This field is reset with PERST. 4.2.58 Serial Bus Control and Status Register The Serial Bus Control and Status register is used to control the behavior of the serial bus interface. This register also provides status information about the state of the serial bus. PCI register offset: B3h Register type: Read/Write; Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-32. Bit Descriptions – Serial Bus Control and Status Register BIT FIELD NAME ACCESS DESCRIPTION Protocol select. This bit is used to select the serial bus address mode used. 7 PROT_SEL rw 6 RSVD r 0 – Slave address and byte address are sent on the serial bus. 1 – Only the slave address is sent on the serial bus. This field is reset with PERST. Reserved. When read, this bit returns zero. Requested serial bus access busy. This bit is set when a serial bus cycle is in progress. 5 REQBUSY ru 0 – No serial bus cycle 1 – Serial bus cycle in progress This field is reset with PERST. Serial EEPROM access busy. This bit is set when the serial EEPROM circuitry in the XIO3130 device is downloading register defaults from a serial EEPROM. 4 ROMBUSY ru 0 – No EEPROM activity 1 – EEPROM download in progress This field is reset with PERST. 60 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-32. Bit Descriptions – Serial Bus Control and Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Serial EEPROM detected. This bit is automatically set when a serial EEPROM is detected via the strapping option. For more information on strapping options, see section 1.9.1. The value of this bit is used to enable the serial bus interface and to control whether the EEPROM load occurs. Note that a serial EEPROM is only detected once following PERST or GRST. 0 – No EEPROM present, EEPROM load process does not occur. 3 SBDETECT rwu 1 – EEPROM present, EEPROM load process occurs. Note that even if a serial EERPOM is not detected following PERST, system software can still set this bit to enable the serial bus interface. For more information on system software setting the bit, see section 1.9.4. This field is reset with PERST. 2 RSVD r Reserved. When read, this bit returns zero. Serial bus error. This bit is set when an error occurs during a software-initiated serial bus cycle. 1 SB_ERR 0 – No error rc 1 – Serial bus error This field is reset with PERST. Serial EEPROM load error. This bit is set when an error occurs while downloading registers from a serial EEPROM. 0 ROM_ERR 0 – No error rc 1 – EEPROM load error This field is reset with PERST. 4.2.59 Upstream Port Link PM Latency Register This read/write register is used to program L0s and L1 exit latencies for the upstream port. PCI register offset: B4h Register type: Read/Write; Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 0024h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 1 4 0 3 0 2 1 1 0 0 0 Table 4-33. Bit Descriptions – Upstream Port Link PM Latency Register BIT FIELD NAME ACCESS 15:14 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Endpoint L0s acceptable latency. This field is used to program the maximum acceptable latency when exiting the L0s state. This field is used to set the L0s Acceptable Latency field in the Device Capabilities register. 000 – Less than 64 ns (default) 001 – 64 ns up to less than 128 ns 010 – 128 ns up to less than 256 ns 13:11 EP_L0S_LAT rw 011 – 256 ns up to less than 512 ns 100 – 512 ns up to less than 1 µs 101 – 1 µs up to less than 2 µs 110 – 2 µs to 4 µs 111 – More than 4 µs This field is loaded from EEPROM (when present) and reset with PERST. Submit Documentation Feedback XIO3130 Configuration Register Space 61 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-33. Bit Descriptions – Upstream Port Link PM Latency Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Endpoint L1 acceptable latency. This field is used to program the maximum acceptable latency when exiting the L1 state. This field is used to set the L1 Acceptable Latency field in the Device Capabilities register. 000 – Less than 1 µs (default) 001 – 1 µs up to less than 2 µs 010 – 2 µs up to less than 4 µs 10:8 EP_L1_LAT rw 011 – 4 µs up to less than 8 µs 100 – 8 µs up to less than 16 µs 101 – 16 µs up to less than 32 µs 110 – 32 µs to 64 µs 111 – More than 64 µs This field is loaded from EEPROM (when present) and reset with PERST. 7:6 RSVD r Reserved. When read, these bits return zeros. L0s exit latency. This field is used to program the maximum latency for the PHY to exit the L0s state. This field is used to set the L0s Exit Latency field in the Link Capabilities register. 000 – Less than 64 ns 001 – 64 ns up to less than 128 ns 010 – 128 ns up to less than 256 ns 011 – 256 ns up to less than 512 ns 100 – 512 ns up to less than 1 µs (default) 101 – 1 µs up to less than 2 µs 5:3 L0S_EXIT_LAT rw 110 – 2 µs to 4 µs 111 – More than 4 µs Define writtenBySW to default to false, be set to true whenever the software or serial EEPROM writes this field to a value that is different from its current state, and can only be subsequently set to false as a result of a reset. When writtenBySW is false, this field is set to 011b when the CCC bit in the Link Control register is asserted (i.e., common clock mode) and set to 100b when the CCC bit is de-asserted (i.e., non-common clock mode). When writtenBySW is true, this field is the value that was last written by the software. This field is loaded from EEPROM (when present) and reset with PERST. This field may be programmed differently depending on the values programmed in the DEFER_L_EXIT and SMART_L_EXIT fields in the Global Switch Control register. L1 exit latency. This field is used to program the maximum latency for the PHY to exit the L1 state. This field is used to set the L1 Exit Latency field in the Link Capabilities register. 000 – Less than 1 µs 001 – 1 µs up to less than 2 µs 010 – 2 µs up to less than 4 µs 011 – 4 µs up to less than 8 µs 100 – 8 µs up to less than 16 µs (default) 2:0 L1_EXIT_LAT rw 101 – 16 µs up to less than 32 µs 110 – 32 µs to 64 µs 111 – More than 64 µs Define writtenBySW to default to false, be set to true when the software or serial EEPROM writes this field to a value that is different from its current state, and can only be subsequently set to false as a result of a reset. When writtenBySW is false, this field is set to 100b. When writtenBySW is true, this field is the value last written by the software. This field is loaded from EEPROM (when present) and reset with PERST. This field may be programmed differently depending on the values programmed in the DEFER_L_EXIT and SMART_L_EXIT fields in the Global Switch Control register. 62 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.60 Global Chip Control Register This read/write register is used to control various functionalities across the entire device. PCI register offset: B8h Register type: Read/Write; Read Only; Hardware Update; Sticky Default value: 0000 000Xh BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 x Table 4-34. Bit Descriptions – Global Chip Control Register BIT FIELD NAME ACCESS 31 RSVD r DESCRIPTION Reserved. When read, this bit returns zero. ASPM-based L1 PLL disable. This bit enables or disables PLL during ASPM-based L1 for all PHYs on the XIO3130. This setting does not affect D-state-based L1, for which PLLs must be shut off during L1. 30 ASPM_L1_PLL_DIS rw 0 – Enable PLL during ASPM-based L1. 1 – Disable PLL during ASPM-based L1. This field is loaded from EEPROM (when present) and reset with PERST. ASPM-based L1 enable. This bit enables ASPM-based L1 on the PCI Express chip-level upstream port. This field controls whether the ASPM Support field in the Link Capabilities register reports support for ASPM-based L1 for all functions in a multifunction device. 29 ASPM_L1_EN rw 0 – Disable ASPM based L1. 1 – Enable ASPM based L1. This field is loaded from EEPROM (when present) and reset with PERST. 28 RSVD rw 27:22 RSVD r This bit is a reserved diagnostic bit and must be set to 0 for proper operation. If an EEPROM is used, the corresponding bit in the EEPROM must be set to 0. Reserved. When read, these bits return zeros. Minimum power scale. This value is programmed to indicate the scale of the Minimum Power Value field. 00 – 1.0x 21:20 MIN_POWER_SCA LE rw 01 – 0.1x 10 – 0.01x 11 – 0.001x This field is loaded from EEPROM (when present) and reset with PERST. 19:12 MIN_POWER_VAL UE rw Minimum power value. This value is programmed to indicate the minimum power requirements for all circuitry powered by a slot, and is not applicable for motherboard down applications (i.e., must be programmed to zero in that case). This value is multiplied by the Minimum Power Scale field. When the value is non-zero, the resultant power figure is compared against information conveyed in Set_Slot_Power_Limit Messages received on the upstream port. When the value is zero, the comparison is ignored as if there is no power limit. This field is loaded from EEPROM (when present) and reset with PERST. Submit Documentation Feedback XIO3130 Configuration Register Space 63 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-34. Bit Descriptions – Global Chip Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Power override. This field is used to determine how the device responds when the slot power limit (via Set_Slot_Power_Limit Message received) is greater than the amount of power programmed in the MIN_SLOT_POWER field of this register. This power comparison is disabled when the MIN_SLOT_POWER field of the register is zero. 00 – Ignore slot power limit. 11:10 PWR_OVRD 01 – Assert the PWR_OVER pin. rw 10 – Assert the PWR_OVER pin and respond with Unsupported request to all transactions except configuration transactions (Type 0 or Type 1) and Set_Slot_Power_Limit Messages. 11 – Reserved This field is loaded from EEPROM (when present) and reset with PERST. 9:3 RSVD r Reserved. When read, these bits return zeros. Wake or beacon. This bit controls whether wake events are signaled using the WAKE pin or a beacon transmission. 2 WAKE_OR_BCN rwh 0 – Beacon mode. 1 – WAKE mode. This field is reset with GRST and is loaded from EEPROM (when present). Wake to beacon enable. This bit enables externally generated wake events detected on the WAKE pin to cause a beacon to be transmitted. This field is ignored if WAKE_OR_BCN is set to WAKE mode. 1 WAKE2BCN rwh 0 – WAKE input to beacon translation disabled. 1 – WAKE input to beacon translation enabled. This field is reset with GRST and is loaded from EEPROM (when present). 0 AUX_PRSNT AUX power present. This bit reflects the state of a 3.3-VAUX presence detection circuit output in the PCI Express reference macro. This bit controls the AUX Power Detected bit in the Device Status register (i.e., whether AUX power is present) for all ports. ru 0 – AUX power is not present. 1 – AUX power is present. 4.2.61 GPIO A Control Register This register is used to control the function of the PCIE_GPIO 0 – 4 pins. PCI register offset: BCh Register type: Read/Write; Read Only; Hardware Update; Sticky Default value: BIT NUMBER RESET STATE 64 0000h 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-35. Bit Descriptions – GPIO A Control Register BIT FIELD NAME ACCESS 15 RSVD r DESCRIPTION Reserved. Reads back zero. GPIO 4 Control. This field controls the GPIO4 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_BTN0 011 – Port 3 ACT_BTN2 100 – Port 1 PWRFLT0 101 – Port 3 PWRFLT2 14:12 PCIE_GPIO4_CTL rw 110 – Port 1 EMIL_ENG0 111 – Port 3 EMIL_ENG2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN2_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO4 terminal is directly mapped as the PRESENT PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. GPIO 3 Control. This field controls the GPIO3 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 CLKREQ0 011 – Port 1 MRLS_DET0 11:9 PCIE_GPIO3_CTL rw 100 – Port 2 PWRFLT1 101 – Port 3 PWRFLT2 110 – Port 2 MRLS_DET1 111 – Port 3 MRLS_DET2, See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 2 Control. This field controls the GPIO2 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 2 ACT_BTN1 011 – Port 3 ACT_BTN2 100 – Port 2 PWRFLT1 101 – Port 3 PWRFLT2 8:6 PCIE_GPIO2_CTL rw 110 – Port 2 MRLS_DET1 111 – Port 3 MRLS_DET2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN1_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO2 terminal is directly mapped as the PWR_GOOD PCI Hot Plug terminal for port 2 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. Submit Documentation Feedback XIO3130 Configuration Register Space 65 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-35. Bit Descriptions – GPIO A Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION GPIO 1 Control. This field controls the GPIO1 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 2 EMIL_CTL1 011 – Port 3 EMIL_CTL2 100 – Port 2 ATN_LED1 101 – Port 3 ATN_LED2 5:3 PCIE_GPIO1_CTL rw 110 – Port 2 PWR_LED1 111 – Port 3 PWR_LED2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN1_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO1 terminal is directly mapped as the PWR_ON PCI Hot Plug terminal for port 2 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. GPIO 0 Control. This field controls the GPIO0 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 2 ACT_BTN1 011 – Port 3 ACT_BTN2 100 – Port 2 PWRFLT1 101 – Port 3 PWRFLT2 2:0 PCIE_GPIO0_CTL rw 110 – Port 2 EMIL_ENG1 111 – Port 3 EMIL_ENG2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN1_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO1 terminal is directly mapped as the PWR_ON PCI Hot Plug terminal for port 2 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. 4.2.62 GPIO B Control Register This register is used to control the function of the PCIE_GPIO 5 – 9 pins. PCI register offset: BEh Register type: Read/Write Default value: BIT NUMBER RESET STATE 66 0000h 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-36. Bit Descriptions – GPIO B Control Register BIT FIELD NAME ACCESS 15 RSVD r DESCRIPTION Reserved, reads back zero GPIO 9 Control. This field controls the GPIO9 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 EMIL_CTL0 011 – Port 2 EMIL_CTL2 100 – Port 1 ATN_LED0 101 – Port 2 ATN_LED1 14:12 PCIE_GPIO9_CTL rw 110 – Port 1 PWR_LED0 111 – Port 2 PWR_LED1 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN3_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO9 terminal is directly mapped as the PWR_ON PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. GPIO 8 Control. This field controls the GPIO8 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_BTN0 011 – Port 2 ACT_BTN1 100 – Port 1 PWRFLT0 101 – Port 2 PWRFLT1 11:9 PCIE_GPIO8_CTL rw 110 – Port 1 EMIL_ENG0 111 – Port 2 EMIL_ENG1 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN3_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO8 terminal is directly mapped as the PRESENT PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. GPIO 7 Control. This field controls the GPIO7 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 2 CLKREQ1 011 – Port 2 MRLS_DET1 8:6 PCIE_GPIO7_CTL rw 100 – Port 1 PWRFLT0 101 – Port 3 PWRFLT2 110 – Port 1 MRLS_DET0 111 – Port 3 MRLS_DET2, See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. Submit Documentation Feedback XIO3130 Configuration Register Space 67 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-36. Bit Descriptions – GPIO B Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION GPIO 6 Control. This field controls the GPIO6 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_BTN0 011 – Port 3 ACT_BTN2 100 – Port 1 PWRFLT0 101 – Port 3 PWRFLT2 5:3 PCIE_GPIO6_CTL 110 – Port 1 MRLS_DET0 rw 111 – Port 3 MRLS_DET2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If DPSTRP[1] == 1, this bit field is read only and reads back zero. If the DN2_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO6 terminal is directly mapped as the PWR_GOOD PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. GPIO 5 Control. This field controls the GPIO5 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 EMIL_CTL0 011 – Port 3 EMIL_CTL2 100 – Port 1 ATN_LED0 101 – Port 3 ATN_LED2 2:0 PCIE_GPIO5_CTL 110 – Port 1 PWR_LED0 rw 111 – Port 3 PWR_LED2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If DPSTRP[1] == 1, this bit field is read only and reads back zero. If the DN2_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO5 terminal is directly mapped as the PWR_ON PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. 4.2.63 GPIO C Control Register This register is used to control the function of the PCIE_GPIO 10 – 13 pins. PCI register offset: C0h Register type: Read/Write; Sticky Default value: 0000h BIT NUMBER RESET STATE 68 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-37. Bit Descriptions – GPIO C Control Register BIT FIELD NAME ACCESS 15 RSVD r DESCRIPTION Reserved. Reads back zero. GPIO 14 Control. This field controls the GPIO14 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_LED0 011 – Port 2 ACT_LED1 14:12 PCIE_GPIO14_CTL rw 100 – Port 3 ACT_LED2 101 – Port 1 PWR_LED0 110 – Port 2 PWR_LED1 111 – Port 3 PWRFLT2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 12 Control. This field controls the GPIO12 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_LED0 011 – Port 2 ACT_LED1 11:9 PCIE_GPIO13_CTL rw 100 – Port 3 ACT_LED2 101 – Port 1 ATN_LED0 110 – Port 2 PWR_LED1 111 – Port 3 PWR_LED2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 12 Control. This field controls the GPIO12 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_LED0 011 – Port 2 ACT_LED1 8:6 PCIE_GPIO12_CTL rw 100 – Port 3 ACT_LED2 101 – Port 1 PWR_LED0 110 – Port 2 ATN_LED1 111 – Port 3 ATN_LED2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 11 Control. This field controls the GPIO11 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 3 CLKREQ2 011 – Port 3 MRLS_DET2 5:3 PCIE_GPIO11_CTL rw 100 – Port 1 PWRFLT0 101 – Port 2 PWRFLT1 110 – Port 1 MRLS_DET0 111 – Port 2 MRLS_DET1, See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. Submit Documentation Feedback XIO3130 Configuration Register Space 69 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-37. Bit Descriptions – GPIO C Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION GPIO 10 Control. This field controls the GPIO10 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ACT_BTN0 011 – Port 2 ACT_BTN1 100 – Port 1 PWRFLT0 101 – Port 2 PWRFLT1 2:0 PCIE_GPIO10_CTL rw 110 – Port 1 MRLS_DET0 111 – Port 2 MRLS_DET1 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. If the DN3_DPSTRP terminal is pulled high at the de-assertion of reset, the GPIO10 terminal is directly mapped as the PWR_GOOD PCI Hot Plug terminal for port 3 and is no longer available for use as a GPIO. In this situation these bits have no meaning and should be left at their default value. 4.2.64 GPIO D Control Register This register is used to control the function of the PCIE_GPIO 15–19 pins. 70 PCI register offset: C2h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-38. Bit Descriptions – GPIO D Control Register BIT FIELD NAME ACCESS 15:10 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. GPIO 18 Control. This field controls the GPIO18 pin as follows: 00 – General Purpose Input (default) 01 – General Purpose Output 9:8 PCIE_GPIO18_CTL rw 10 – HP_INTX, PCI Hot Plug Interrupt Output 11 – PD_CHG, Presence Detect Changed Output See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 17 Control. This field controls the GPIO19 pin as follows: 00 – General Purpose Input (default) 01 – General Purpose Output 7:6 PCIE_GPIO17_CTL rw 10 – General Purpose Input 11 – PWR_OVER, Power Limits exceeded See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 16 Control. This field controls the GPIO16 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ATN_LED0 011 – Port 2 ATN_LED1 5:3 PCIE_GPIO16_CTL rw 100 – Port 3 ATN_LED2 101 – Port 1 PWRFLT0 110 – Port 2 PWRFLT1 111 – Port 3 PWRFLT2 See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. GPIO 15 Control. This field controls the GPIO15 pin as follows: 000 – General Purpose Input (default) 001 – General Purpose Output 010 – Port 1 ATN_LED0 011 – Port 2 ATN_LED1 2:0 PCIE_GPIO15_CTL rw 100 – Port 3 PWR_LED2 101 – Port 1 PWRFLT0 110 – Port 2 PWRFLT1 111 – Port 3 PWRFLT2. See GPIO Data register for a detailed description of this field. This field is loaded from EEPROM (if present), and reset with FRST. Submit Documentation Feedback XIO3130 Configuration Register Space 71 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.65 GPIO Data Register This register is used to read the state of the GPIO pins and to change the state of GPIO pins that are in output mode. Reads to this register return the state of the GPIO pins, regardless of PCI Hot Plug strapping or GPIO configuration. Writes to this register only affect pins that are configured as a general purpose output. PCI register offset: C4h Register type: Read/Write; Read Only Default value: 00000 0000h BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-39. Bit Descriptions – GPIO Data Register BIT FIELD NAME ACCESS 31:19 RSVD r DESCRIPTION GPIO 18 data. HP_INTX / PD_CHG / GPIO 18 data. HP_INTX output mode: Reads indicate current state of pin Writes have no affect PD_CHG output mode: 18 PCIE_GPIO18_DATA rw Reads indicate current state of pin Writes have no affect PD_CHG is asserted whenever all of the following are true for any given slot: PDC[n] bit is asserted in the Slot Status register for switch downstream port n, and PDC_EN[n] bit is asserted in Slot Control Register for switch downstream port n GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This field is loaded from EEPROM (if present), and reset with FRST. PWR_OVER / GPIO 17 data. PWR_OVER mode: reads state of pin; writes have no affect PWR_OVER pin is asserted whenever any of the following conditions are true: PERST is asserted 17 PCIE_GPIO17_DATA rw Conditions are met for exceeding slot power limit (see PWR_OVRD field in Global Chip Control Register) GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This field is loaded from EEPROM (if present), and reset with FRST. GP Input mode: reads state of pin; writes have no affect 16 PCIE_GPIO16_DATA rw GP Output mode: reads and also controls state of pin This field is loaded from EEPROM (if present), and reset with FRST. GPIO 15 data. 15 PCIE_GPIO15_DATA rw GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This field is loaded from EEPROM (if present), and reset with FRST. 72 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-39. Bit Descriptions – GPIO Data Register (continued) BIT FIELD NAME ACCESS DESCRIPTION GPIO 14 data. 14 PCIE_GPIO14_DATA rw GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This field is loaded from EEPROM (if present), and reset with FRST. GPIO 13 data. LED driver (see GPIO C Controls) 13 PCIE_GPIO13_DATA rw GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This bit field is loaded from EEPROM (if present), and reset with FRST. GPIO 12 data. LED driver (see GPIO C Controls) 12 PCIE_GPIO12_DATA rw GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin This bit field is loaded from EEPROM (if present), and reset with FRST. GPIO 11 data. GP Input mode: reads state of pin; writes have no affect 11 PCIE_GPIO11_DATA rw GP Output mode: reads and also controls state of pin Program-selectable HP input or output pin This bit field is loaded from EEPROM (if present), and reset with FRST. GPIO 10 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 10 PCIE_GPIO10_DATA rw Program-selectable HP input pin This field is valid only if DN3_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 9 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 9 PCIE_GPIO9_DATA rw Program-selectable HP input pin This field is valid only if DN3_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 8 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 8 PCIE_GPIO8_DATA rw Program-selectable HP output pin This field is valid only if DN3_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 7 data. GP Input mode: reads state of pin; writes have no affect 7 PCIE_GPIO7_DATA rw GP Output mode: reads and also controls state of pin GP Output mode: reads and also controls state of pin This bit field is loaded from EEPROM (if present), and reset with FRST. Submit Documentation Feedback XIO3130 Configuration Register Space 73 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-39. Bit Descriptions – GPIO Data Register (continued) BIT FIELD NAME ACCESS DESCRIPTION GPIO 6 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 6 PCIE_GPIO6_DATA rw Program-selectable HP input pin This field is valid only if DN2_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 5 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 5 PCIE_GPIO5_DATA rw Program-selectable HP input pin This field is valid only if DN2_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 4 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 4 PCIE_GPIO4_DATA rw Program-selectable HP output pin This field is valid only if DN2_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 3 data. GP Input mode: reads state of pin; writes have no affect 3 PCIE_GPIO3_DATA rw GP Output mode: reads and also controls state of pin Program-selectable HP Input or Output pin This bit field is loaded from EEPROM (if present), and reset with FRST. GPIO 2 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 2 PCIE_GPIO2_DATA rw Program-selectable HP input pin This field is valid only if DN1_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 1 data. GP Input mode: reads state of pin; writes have no affect GP Output mode: reads and also controls state of pin 1 PCIE_GPIO1_DATA rw Program-selectable HP input pin This field is valid only if DN1_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. GPIO 0 data. GP Input mode: reads state of pin; writes have no effect GP Output mode: reads and also controls state of pin 0 PCIE_GPIO0_DATA rw Program-selectable HP output pin This field is valid only if DN1_DPSTRP == 0. If this bit field is valid then it is loaded from EEPROM (if present), and reset with FRST. If this field is invalid, it is a read-only bit field. 74 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.66 TI Proprietary Register This read/write TI proprietary register is located at offset C8h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 00000001h. PCI register offset: C8h Register type: Read/Write Default value: xxxx 0001h BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 4.2.67 TI Proprietary Register This read/write TI proprietary register is located at offset CCh and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 00000000h. PCI register offset: CCh Register type: Read/Write Default value: 0000 0000h BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 4.2.68 TI Proprietary Register This read/write TI proprietary register is located at offset D0h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 32140000h. PCI register offset: D0h Register type: Read/Write Default value: 3214 0000h BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 1 1 0 0 1 0 0 0 0 1 0 1 0 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Submit Documentation Feedback XIO3130 Configuration Register Space 75 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.69 TI Proprietary Register This read/write TI proprietary register is located at offset D4h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for register D5h must be 10h. PCI register offset: D4h Register type: Read/Write Default value: 0000 0010 BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 4.2.70 TI Proprietary Register This read/write TI proprietary register is located at offset D8h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. PCI register offset: D8h Register type: Read/Write Default value: 0000 0000h BIT NUMBER 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.71 TI Proprietary Register This read/write TI proprietary register is located at offset DCh and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. PCI register offset: DCh Register type: Read/Write Default value: 76 0000 0002h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.72 Subsystem Access Register This register is a read/write register. The contents of this register are aliased to the Subsystem Vendor ID and Subsystem ID registers at PCI Offsets 84h and 86h for all PCI Express ports. PCI register offset: E0h Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-40. Bit Descriptions – Subsystem Access Register BIT FIELD NAME ACCESS DESCRIPTION 31:16 SubsystemID rw Subsystem ID. The value written to this field is aliased to the Subsystem ID register at PCI Offset 66h. This field is loaded from EEPROM (when present) and reset with PERST. 15:0 SubsystemVendorID rw Subsystem Vendor ID. The value written to this field is aliased to the Subsystem Vendor ID register at PCI Offset 64h. This field is loaded from EEPROM (when present) and reset with PERST. 4.2.73 General Control Register This register is a read/write register that is used to control various functions of the XIO3130. PCI register offset: E4h Register type: Read/Write; Read Only Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-41. Bit Descriptions – General Control Register BIT FIELD NAME ACCESS 31:3 RSVD r 2 TI_PROPRIETARY rw TI proprietary. This bit must not be changed from the specified default value. L1 disable. This bit may be used to disable software-directed L1 entry when in lower D-states (D1-D3). The value of L1_DISABLE is 0 (the default). Link power states are managed in accordance with the PCI Express base specification. When L1_DISABLE is 1, the upstream port of the XIO3130 does not enter L1 even when directed to do so through software. 1 L1_DISABLE rw 0 RSVD r Submit Documentation Feedback DESCRIPTION Reserved. When read, these bits return zeros. Reserved. When read, this bit returns zero. XIO3130 Configuration Register Space 77 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.74 Downstream Ports Link PM Latency Register This read/write register is used to program L0s and L1 exit latencies for all XIO3130 downstream ports. Similar information is provided in a separate register for the upstream port. PCI register offset: E8h Register type: Read/Write; Read Only Default value: 3F24h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-42. Bit Descriptions – Downstream Ports Link PM Latency Register BIT FIELD NAME ACCESS 15:14 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Endpoint L0s acceptable latency. This field is used to program the maximum acceptable latency when exiting the L0s state. This field is used to set the L0s Acceptable Latency field in the Device Capabilities register. 000 – Less than 64 ns 001 – 64 ns up to less than 128 ns 010 – 128 ns up to less than 256 ns 13:11 EP_L0S_LAT rw 011 – 256 ns up to less than 512 ns 100 – 512 ns up to less than 1 µs 101 – 1 µs up to less than 2 µs 110 – 2 µs to 4 µs 111 – More than 4 µs (default) This field is loaded from EEPROM (when present) and reset with PERST. Endpoint L1 acceptable latency. This field is used to program the maximum acceptable latency when exiting the L1 state. This field is used to set the L1 Acceptable Latency field in the Device Capabilities register. 000 – Less than 1 µs 001 – 1 µs up to less than 2 µs 010 – 2 µs up to less than 4 µs 10:8 EP_L1_LAT rw 011 – 4 µs up to less than 8 µs 100 – 8 µs up to less than 16 µs 101 – 16 µs up to less than 32 µs 110 – 32 µs to 64 µs 111 – More than 64 µs (default) This field is loaded from EEPROM (when present) and reset with PERST. 7:6 RSVD r Reserved. When read, these bits return zeros. L0s exit latency. This field is used to program the maximum latency for the PHY to exit the L0s state. This is used to set the L0s Exit Latency field in the Link Capabilities register. 000 – Less than 64 ns 001 – 64 ns up to less than 128 ns 010 – 128 ns up to less than 256 ns 5:3 L0S_EXIT_LAT rw 011 – 256 ns up to less than 512 ns 100 – 512 ns up to less than 1 µs (default) 101 – 1 µs up to less than 2 µs 110 – 2 µs to 4 µs 111 – More than 4 µs 78 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-42. Bit Descriptions – Downstream Ports Link PM Latency Register (continued) BIT FIELD NAME ACCESS DESCRIPTION L1 exit latency. This field is used to program the maximum latency for the PHY to exit the L1 state. This is used to set the L1 Exit Latency field in the Link Capabilities register. 000 – Less than 1 µs 001 – 1 µs up to less than 2 µs 010 – 2 µs up to less than 4 µs 2:0 L1_EXIT_LAT rw 011 – 4 µs up to less than 8 µs 100 – 8 µs up to less than 16 µs (default) 101 – 16 µs up to less than 32 µs 110 – 32 µs to 64 µs 111 – More than 64 µs 4.2.75 Global Switch Control Register This read/write register is used to control various functions across the entire XIO3130. PCI register offset: EAh Register type: Read/Write; Read Only; Clear by a Write of One; Sticky Default value: BIT NUMBER RESET STATE 0004h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-43. Bit Descriptions – Global Switch Control Register BIT FIELD NAME ACCESS 15:7 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Downstream ports L0s independence 6 DP_L0S_IND rw 0 – Downstream ports (all) Tx L0s entry dependent on whether upstream Rx is in L0s according to PCI Express Base Specification, section 5.4.1.1.1. 1 – Downstream ports Tx L0s entry not dependent on whether upstream Rx is in L0s. 5 RSVD r 4 DEFER_L_EXIT rw 3 RSVD r Reserved. When read, this bit returns zero. Defer L0s, L1 exit. This bit configures logic to not automatically power up all downstream ports when the upstream port receives a downstream flowing packet. This field is loaded from EEPROM (when present) and reset with PERST. 2 D1_SUPPORT rw Reserved. When read, this bit returns zero. D1 support. This bit enables whether all PCI Express XIO3130 functions are capable of D1 support. The field controls (1) the D1_SUPPORT bit in the Power Management Capabilities register for all XIO3130 ports, and (2) bit 1 in the 5-bit PME_SUPPORT field in the Power Management Capabilities register for all XIO3130 ports. 0 – D1 not supported 1 – D1 supported This field is loaded from EEPROM (when present) and reset with PERST. PCI Hot Plug PME message enable. This bit enables PME_Turn_Off/PME_TO_Ack messages when power is shut off to a slot using the PC_CTL bit in the Slot Control register for downstream ports. 1 HP_PME_MSG _EN rw 0 – Disable PME_Turn_Off / PME_TO_Ack messages for slot power control 1 – Enable PME_Turn_Off / PME_TO_Ack messages for slot power control This field is loaded from EEPROM (when present) and reset with PERST. Beacon detect disable. This bit disables beacon detection on all downstream ports and allows the reference macro to be placed in low power state during D3cold. 0 BCN_DET_DIS rwh 0 – Beacon detection enabled 1 – Beacon detection disabled This field is loaded from EEPROM (when present) and reset with GRST. Submit Documentation Feedback XIO3130 Configuration Register Space 79 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.2.76 Advanced Error Reporting Capability ID Register This read-only register identifies the linked list item as the register for PCI Express Advanced Error Reporting Capabilities. The register returns 0001h when read. PCI register offset: 100h Register type: Read only Default value: 0001h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.2.77 Next Capability Offset/Capability Version Register This read-only register returns the value 0000h to indicate that this extended capability block represents the end of the linked list of extended capability structures. The least significant four bits identify the revision of the current capability block as 1h. PCI register offset: 102h Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.2.78 Uncorrectable Error Status Register This register reports the status of individual errors as they occur. Software may clear these bits only by writing a 1 to the desired location. PCI register offset: 104h Register type: Read Only, Cleared by a Write of one Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-44. Uncorrectable Error Status Register 80 BIT FIELD NAME ACCESS 31:21 RSVD r 20 UR_ERROR rcuh Unsupported Request error. This bit is asserted when an Unsupported Request error is detected (i.e., when a request is received that results in the sending of a completion with an Unsupported Request status). 19 ECRC_ERROR rcuh Extended CRC error. This bit is asserted when an Extended CRC error is detected. 18 MAL_TLP rcuh Malformed TLP. This bit is asserted when a malformed TLP is detected. 17 RX_OVERFLOW rcuh Receiver overflow. This bit is asserted when the flow control logic detects that the transmitting device has illegally exceeded the number of credits that were issued. 16 UNXP_CPL rcuh Unexpected completion. This bit is asserted when a completion packet is received that does not correspond to an issued request. 15 CPL_ABORT rcuh Completer abort. This bit is asserted when the completion to a pending request arrives with Completer Abort status. 14 CPL_TIMEOUT rcuh Completion timeout. This bit is asserted when no completion has been received for an issued request before the timeout period. 13 FC_ERROR rcuh Flow control error. This bit is asserted when a flow control protocol error is detected either during initialization or during normal operation. XIO3130 Configuration Register Space DESCRIPTION Reserved. Return zeros when read. Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-44. Uncorrectable Error Status Register (continued) BIT 12 FIELD NAME ACCESS PSN_TLP DESCRIPTION Poisoned TLP. This bit is asserted when an outgoing packet (request or completion) has been poisoned by setting the poison bit and has inverted the extended CRC attached to the end of the packet. rcuh 11:6 RSVD r 5 SD_ERROR rcuh Reserved. Return zeros when read. Surprise down error. See Surprise Down ECN for a description of this error condition. 4 DLL_ERROR rcuh Data link protocol error. This bit is asserted if a data link layer protocol error is detected. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r The value read from this bit is undefined. 4.2.79 Uncorrectable Error Mask Register The Uncorrectable Error Mask register controls the reporting of individual errors as they occur. When a bit is set to one, the error status bits are still affected, but the error is not logged and no error reporting message is sent upstream. PCI register offset: 108h Register type: Read Only, Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-45. Uncorrectable Error Mask Register BIT FIELD NAME ACCESS 31:21 RSVD r 20 UR_ERROR_MASK rwh DESCRIPTION Reserved. Return zeros when read. Unsupported Request error mask. 0 - Error condition is unmasked. 1 - Error condition is masked. Extended CRC error mask. 19 ECRC_ERROR_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Malformed TLP mask. 18 MAL_TLP_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Receiver Overflow mask. 17 RX_OVERFLOW_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Unexpected Completion mask. 16 UNXP_CPL_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Completer Abort mask. 15 CPL_ABORT_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Completion Timeout mask. 14 CPL_TIMEOUT_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Submit Documentation Feedback XIO3130 Configuration Register Space 81 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-45. Uncorrectable Error Mask Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Flow Control error mask. 13 FC_ERROR_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Poisoned TLP mask. 12 PSN_TLP_MASK rwh 11:6 RSVD r 5 SD_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Reserved. Return zeros when read. Surprise Down error mask. 0 - Error condition is unmasked. 1 - Error condition is masked. Data Link Protocol error mask. 4 DLL_ERROR_MASK rwh 0 - Error condition is unmasked. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r The value read from this bit is undefined. 1 - Error condition is masked. 4.2.80 Uncorrectable Error Severity Register The Uncorrectable Error Severity register controls the reporting of individual errors as ERR_FATAL or ERR_NONFATAL. When a bit is set, the corresponding error condition is identified as fatal. When a bit is clear, the corresponding error condition is identified as nonfatal. PCI register offset: 10Ch Register type: Read Only, Read/Write Default value: 0003 2030h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 1 17 1 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 1 0 0 0 0 0 0 0 1 1 0 0 0 0 Table 4-46. Uncorrectable Error Severity Register BIT FIELD NAME ACCESS 31:21 RSVD r DESCRIPTION Reserved. Return zeros when read. Unsupported Request error severity. 20 UR_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Extended CRC error severity. 19 ECRC_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Malformed TLP severity. 18 MAL_TLP_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Receiver Overflow severity. 17 RX_OVERFLOW_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. 82 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-46. Uncorrectable Error Severity Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Unexpected Completion severity. 16 UNXP_CPL_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Completer Abort severity. 15 CPL_ABORT_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Completion Timeout severity. 14 CPL_TIMEOUT_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Flow Control error severity. 13 FC_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Poisoned TLP severity. 12 PSN_TLP_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. 11:6 RSVD r 5 SD_ERROR_SEVR rwh Reserved. Return zeros when read. Surprise Down error severity. 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Data Link Protocol error severity. 4 DLL_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r The value read from this bit is undefined. 4.2.81 Correctable Error Status Register The Correctable Error Status register reports the status of individual errors as they occur. Software may clear these bits only by writing a 1 to the desired location. PCI register offset: 110h Register type: Read Only, Cleared by a Write of one Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-47. Correctable Error Status Register BIT FIELD NAME ACCESS DESCRIPTION 31:14 RSVD r 13 ANFES rcuh Advisory nonfatal error status. 12 REPLAY_TMOUT rcuh Replay timer timeout. This bit is asserted when the replay timer expires for a pending request or completion that has not been acknowledged. 11:9 RSVD r 8 REPLAY_ROLL rcuh Submit Documentation Feedback Reserved. Return zeroes when read. Reserved. Return zeroes when read. REPLAY_NUM rollover. This bit is asserted when the replay counter rolls over when a pending request of completion has not been acknowledged. XIO3130 Configuration Register Space 83 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-47. Correctable Error Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 7 BAD_DLLP rcuh Bad DLLP error. This bit is asserted when an 8b/10n error is detected by the PHY during reception of a DLLP. 6 BAD_TLP rcuh Bad TLP error. This bit is asserted when an 8b/10b error is detected by the PHY during reception of a TLP. 5:1 RSVD r 0 RX_ERROR rcuh Reserved. Return zeros when read. Receiver error. This bit is asserted when an 8b/10b error is detected by the PHY at any time. 4.2.82 Correctable Error Mask Register The Correctable Error Mask register controls the reporting of individual errors as they occur. When a bit is set to one, error status bits are still affected, but the error is not logged and no error reporting message is sent upstream. PCI register offset: 114h Register type: Read Only, Read/Write Default value: 0000 2000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-48. Correctable Error Mask Register BIT FIELD NAME ACCESS 31:14 RSVD r DESCRIPTION Reserved. Return zeros when read. Advisory nonfatal error mask. This bit is set by default to enable compatibility with software that does not comprehend role-based error reporting. 13 ANFEM rwh 0 – Error condition is unmasked 1 – Error condition is masked Replay timer timeout mask. 12 REPLAY_TMOUT_MASK rwh 0 – Error condition is unmasked 1 – Error condition is masked 11:9 RSVD r 8 REPLAY_ROLL_MASK rwh Reserved. Return zeros when read. REPLAY_NUM rollover mask. 0 – Error condition is unmasked 1 – Error condition is masked Bad DLLP error mask. 7 BAD_DLLP_MASK rwh 0 – Error condition is unmasked 1 – Error condition is masked Bad TLP error mask. 6 BAD_TLP_MASK rwh 0 – Error condition is unmasked 1 – Error condition is masked 5:1 RSVD r 0 RX_ERROR_MASK rwh Reserved. Return zeros when read. Receiver error mask. 0 – Error condition is unmasked 1 – Error condition is masked 84 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.2.83 Advanced Error Capabilities and Control Register The Advanced Error Capabilities and Control register allows the system to monitor and control the advanced error reporting capabilities. PCI register offset: 118h Register type: Read Only, Read/Write Default value: 0000 00A0h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 Table 4-49. Advanced Error Capabilities and Control Register BIT FIELD NAME ACCESS 31:9 RSVD r 8 ECRC_CHK_EN rwh DESCRIPTION Reserved. Return zeros when read. Extended CRC check enable. 0 – Extended CRC checking is disabled 1 – Extended CRC checking is enabled 7 ECRC_CHK_CAPABLE Extended CRC check capable. This read-only bit returns a value of ‘1’ indicating that the bridge is capable of checking extended CRC information. r Extended CRC generation enable. 6 ECRC_GEN_EN rwh 0 – Extended CRC generation is disabled 1 – Extended CRC generation is enabled 5 ECRC_GEN_CAPABLE r Extended CRC generation capable. This read-only bit returns a value of ‘1’ indicating that the bridge is capable of generating extended CRC information. 4:0 FIRST_ERR rh First error pointer. This five-bit value reflects the bit position within the Uncorrectable Error Status register corresponding to the class of the first error condition that was detected. 4.2.84 Header Log Register The Header Log register stores the TLP header for the packet that lead to the most recently detected error condition. Offset 11Ch contains the first DWORD. Offset 128h contains the last DWORD (in the case of a 4DW TLP header). PCI register offset: 11Ch – 128h Register type: Read only Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Submit Documentation Feedback XIO3130 Configuration Register Space 85 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3 www.ti.com PCI Express Downstream Port Registers The default reset domain for all downstream port registers is SBRST. Some register fields are placed in a different reset domain from the default reset domain; all bit and field descriptions identify any unique reset domains. Generally, all sticky bits are placed in the GRST domain and all (non-sticky) EEPROM loadable bits are placed in the PERST domain. 4.3.1 PCI Configuration Space (Downstream Port) Register Map Table 4-50. PCI Express Downstream Port Configuration Register Map (Type 1) Register Name Offset Device ID Vendor ID Status 000h Command 004h Class Code BIST Header Type Secondary Latency Timer Subordinate Bus Number Revision ID 008h Latency Timer Cache Line Size 00Ch Secondary Bus Number Primary Bus Number 018h I/O Limit I/O Base 01Ch Reserved 010h-014h Secondary Status Memory Limit Memory Base 020h Pre-fetchable Memory Limit Pre-fetchable Memory Base 024h Pre-fetchable Base Upper 32 Bits 028h Pre-fetchable Limit Upper 32 Bits 02Ch I/O Limit Upper 16 Bits I/O Base Upper 16 Bits Reserved 030h Capabilities Pointer Reserved Bridge Control 038h Interrupt Pin Interrupt Line Reserved Power Management Capabilities PM Data (RSVD) Next-item Pointer PM CAP ID Power Management CSR 058h-06Ch Next-item Pointer MSI CAP ID MSI Message Address 078h MSI Message Data Next-item Pointer Subsystem ID 07Ch SSID/SSVID CAP ID Subsystem Vendor ID 088h-08Ch Next-item Pointer PCI Express Capability ID Device Capabilities Device Status 090h 094h Device Control 098h Link Capabilities 09Ch Link Status Link Control 0A0h Slot Capabilities A4h Slot Status Slot Control A8h Reserved 0ACh-0C4h TI Proprietary 0C8h-0D0h General Control 0D4h Reserved 0D8h-0E8h General Slot Info Reserved Reserved XIO3130 Configuration Register Space 080h 084h Reserved 86 070h 074h MSI Upper Message Address Reserved PCI Express Capabilities Register 050h 054h Reserved Reserved 03Ch 040h-04Ch PMCSR_BSE MSI Message Control 034h LOs Idle Timeout 0ECh 0F0h-0FCh Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-51. Extended Configuration Space (Downstream Port) Register Name Next Capability Offset / Capability Version Offset PCI Express Advanced Error Reporting Capabilities ID 100h Uncorrectable Error Status Register 4.3.2 104h Uncorrectable Error Mask Register 108h Uncorrectable Error Severity Register 10Ch Correctable Error Status Register 110h Correctable Error Mask 114h Advanced Error Capabilities and Control 118h Header Log Register 11Ch Header Log Register 120h Header Log Register 124h Header Log Register 128h Reserved 12Ch-FFCh Vendor ID Register This 16-bit read-only register contains the value 104Ch, which is the vendor ID assigned to Texas Instruments. PCI register offset: 00h Register type: Read only Default value: BIT NUMBER RESET STATE 4.3.3 104Ch 15 0 14 0 13 0 12 1 11 0 10 0 9 0 8 0 7 0 6 1 5 0 4 0 3 1 2 1 1 0 0 0 Device ID Register This 16-bit read-only register contains the device ID assigned by TI to the XIO3130. The value in this register is the same for all downstream ports, as defined in the following table. PCI register offset: 02h Register type: Read only Default value: 8233h BIT NUMBER RESET STATE 4.3.4 15 1 14 0 13 0 12 0 11 0 10 0 9 1 8 0 7 0 6 0 5 1 4 1 3 0 2 0 1 1 0 1 Command Register The Command register controls the way the downstream port bridge behaves on its primary interface; i.e., the internal PCI bus between the upstream and downstream ports. PCI register offset: 04h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 0000h 15 0 Submit Documentation Feedback 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 XIO3130 Configuration Register Space 0 0 87 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-52. Bit Descriptions – Command Register BIT FIELD NAME ACCESS 15:11 RSVD r DESCRIPTION 10 INT_DISABLE rw 9 FBB_ENB r 8 SERR_ENB rw SERR enable. The relevant error checking is unnecessary for the XIO3130 internal PCI bus. When set, this bit enables the transmission by the primary interface of ERR_NONFATAL and ERR_FATAL messages forwarded from the secondary interface. This bit does not affect transmission of ERR_COR messages. 7 STEP_ENB r Address/data stepping control. This bit does not apply to PCI-Express and is hardwired to 0. 6 PERR_ENB rw Parity error response enable. This bit has no impact on hardware behavior. It is assumed that the relevant error checking is unnecessary for the XIO3130 internal PCI bus. 5 VGA_ENB r VGA palette snoop enable. The XIO3130 does not support VGA palette snooping, so this bit returns zero when read. 4 MWI_ENB r Memory write and invalidate enable. This bit does not apply to PCI-Express, so it is hardwired to zero. 3 SPECIAL r Special cycle enable. This bit does not apply to PCI-Express and is hardwired to zero. Reserved. When read, these bits return zeros. INTx disable. This bit is used to enable device-specific INTx interrupts. The XIO3130 downstream ports can generate INTx interrupts due to PCI Hot Plug events. The XIO3130 forwards INTx messages from downstream ports to the upstream port (see INTx Support section) regardless of this bit. Fast back-to-back enable. This bit does not apply to PCI-Express, so it returns zero when read. Bus master enable. When set, the XIO3130 is enabled to initiate cycles on the downstream PCI Express interface. 2 MASTER_ENB 0 – Downstream PCI Express interface cannot initiate transactions. The XIO3130 must disable response to memory and I/O transactions on the downstream interface. rw 1 – Downstream PCI Express interface can initiate transactions. The bridge can forward memory and I/O transactions. 1 MEMORY_ENB rw Memory response enable. Setting this bit enables the downstream port to respond to memory transactions. 0 IO_ENB rw I/O space enable. Setting this bit enables the downstream port to respond to I/O transactions. 4.3.5 Status Register The Status register provides information about the downstream port’s primary interface, i.e., the internal PCI bus between the upstream and downstream ports. PCI register offset: 06h Register type: Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 0010h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-53. Bit Descriptions – Status Register BIT 15 FIELD NAME PAR_ERR ACCESS rcu DESCRIPTION Detected parity error. This bit is set when the virtual internal PCI interface receives a poisoned TLP. This bit is set regardless of the state of the Parity Error Response bit in the Command register. 0 – No parity error detected. 1 – Parity error detected. 14 SYS_ERR rcu Signaled system error. This bit is set when the XIO3130 sends an ERR_FATAL or ERR_NONFATAL message upstream and the SERR Enable bit in the Command register is set. 0 – No error signaled. 1 – ERR_FATAL or ERR_NONFATAL signaled. 13 88 MABORT r Received master abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130 internal PCI bus. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-53. Bit Descriptions – Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 12 TABORT_REC r Received target abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130 internal PCI bus. 11 TABORT_SIG r Signaled target abort. This bit is hardwired to zero. It is assumed that the relevant error checking is unnecessary for the XIO3130 internal PCI bus. 10:9 PCI_SPEED r DEVSEL timing. These bits are read only zero because they do not apply to PCI Express. 8 DATAPAR rcu Master data parity error. This bit is set when the downstream port receives a poisoned completion or poisons a write request on the internal virtual PCI bus. This bit is never set if the parity error response enable bit in the Command register is clear. 7 FBB_CAP r Fast back-to-back capable. This bit does not have a meaningful context for a PCI Express device and is hardwired to zero. 6 RSVD r Reserved. When read, this bit returns zero. 5 66MHZ r 66-MHz capable. This bit does not have a meaningful context for a PCI Express device and is hardwired to zero. 4 CAPLIST r Capabilities list. This bit returns 1 when read, indicating that the XIO3130 supports additional PCI capabilities. 3 INT_STATUS r Interrupt status. This bit reflects the INTx interrupt status of the function. The XIO3130 forwards INTx messages from downstream ports to the upstream port. 2:0 RSVD r Reserved. When read, these bits return zeros. 4.3.6 Class Code and Revision ID Register This read-only register categorizes the Base Class, Sub Class, and Programming Interface of the XIO3130. The Base Class is 06h, which identifies the device as a bridge device. The Sub Class is 04h, which identifies the function as a PCI-to-PCI bridge. The Programming Interface is 00h. In addition, the TI chip revision is indicated in the lower byte (01h). PCI register offset: 08h Register type: Read only Default value: 0604 0001h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 1 25 1 24 0 23 0 22 0 21 0 20 0 19 0 18 1 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 Table 4-54. Bit Descriptions – Class Code and Revision ID Register BIT FIELD NAME ACCESS DESCRIPTION 31:24 BASECLASS r Base class. This field returns 06h when read, which classifies the function as a bridge device. 23:16 SUBCLASS r Subclass. This field returns 04h when read, which specifically classifies the function as a PCI-to-PCI bridge. 15:8 PGMIF r Programming interface. This field returns 00h when read. 7:0 CHIPREV r Silicon revision. This field returns the silicon revision. Submit Documentation Feedback XIO3130 Configuration Register Space 89 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.7 www.ti.com Cache Line Size Register The Cache Line Size register is implemented by PCI Express devices as a read-write field for legacy compatibility, but has no impact on any PCI Express device functionality. PCI register offset: 0Ch Register type: Read/Write Default value: 00h BIT NUMBER RESET STATE 4.3.8 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Primary Latency Timer Register This read-only register has no meaningful context for a PCI Express device, so it returns zeros when read. PCI register offset: 0Dh Register type: Read only Default value: BIT NUMBER RESET STATE 4.3.9 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Header Type Register This read-only register indicates that this function has a Type 1 PCI header. Bit seven of this register is zero, indicating that the XIO3130 downstream port PCI-to-PCI bridge is not a multifunction device. PCI register offset: 0Eh Register type: Read only Default value: BIT NUMBER RESET STATE 01h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.3.10 BIST Register Since the XIO3130 does not support a built-in self test (BIST), this read-only register returns the value 00h when read. PCI register offset: 0Fh Register type: Read only Default value: 00h BIT NUMBER RESET STATE 90 7 0 6 0 5 0 XIO3130 Configuration Register Space 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.11 Primary Bus Number This register specifies the bus number of the PCI bus segment for the downstream port primary interface (i.e., the internal PCI bus). PCI register offset: 18h Register type: Read/Write Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.12 Secondary Bus Number This register specifies the bus number of the PCI bus segment for the downstream port secondary interface (i.e., the PCI Express interface). The XIO3130 uses this register to determine how to respond to a Type 1 configuration transaction. PCI register offset: 19h Register type: Read/Write Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.13 Subordinate Bus Number This register specifies the bus number of the highest number PCI bus segment that is downstream of the XIO3130 downstream port. The XIO3130 uses this register to determine how to respond to a Type 1 configuration transaction. PCI register offset: 1Ah Register type: Read/Write Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.14 Secondary Latency Timer Register This register does not apply to PCI-Express, so it is hardwired to zero. PCI register offset: 1Bh Register type: Read only Default value: 00h BIT NUMBER RESET STATE 7 0 Submit Documentation Feedback 6 0 5 0 4 0 3 0 2 0 1 0 0 0 XIO3130 Configuration Register Space 91 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.15 I/O Base Register This read/write register specifies the lower limit of the I/O addresses that the XIO3130 downstream port forwards downstream. PCI register offset: 1Ch Register type: Read/Write; Read Only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-55. Bit Descriptions – I/O Base Register BIT FIELD NAME ACCESS DESCRIPTION I/O base. This field defines the bottom address of the I/O address range that is used to determine when to forward I/O transactions from one interface to the other. These bits correspond to address bits [15:12] in the I/O address. The lower 12 bits are assumed to be 0. The 16 bits that correspond to address bits [31:16] of the I/O address are defined in the I/O Base Upper 16 Bits register. 7:4 IOBASE rw 3:0 IOTYPE r I/O type. This field is read-only 01h, which indicates 32 bit I/O addressing support. 4.3.16 I/O Limit Register This read/write register specifies the upper limit of the I/O addresses that the XIO3130 downstream port forwards downstream. PCI register offset: 1Dh Register type: Read/Write; Read Only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-56. Bit Descriptions – I/O Limit Register BIT FIELD NAME ACCESS DESCRIPTION I/O limit. This field defines the top address of the I/O address range that is used to determine when to forward I/O transactions from one interface to the other. These bits correspond to address bits [15:12] in the I/O address. The lower 12 bits are assumed to be FFFh. The 16 bits that correspond to address bits [31:16] of the I/O address are defined in the I/O Limit Upper 16 Bits register. 7:4 IOLIMIT rw 3:0 IOTYPE r I/O type. This field is read-only 01h, which indicates 32-bit I/O addressing support. 4.3.17 Secondary Status Register The Secondary Status register provides information about the downstream port PCI Express interface. PCI register offset: 1Eh Register type: Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 92 0000h 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-57. Bit Descriptions – Secondary Status Register BIT 15 FIELD NAME ACCESS PAR_ERR DESCRIPTION Detected parity error. This bit is set when the PCI Express interface receives a poisoned TLP on the downstream port. This bit is set regardless of the state of the Parity Error Response bit in the Bridge Control register. rcu 0 – No parity error detected. 1 – Parity error detected. Received System Error. This bit is set when the XIO3130 sends an ERR_FATAL or ERR_NONFATAL message upstream and the SERR Enable bit in the Command register is set. 14 SYS_ERR rcu 0 – No error signaled. 1 – ERR_FATAL or ERR_NONFATAL signaled. Received master abort. This bit is set when the downstream PCI Express interface of the XIO3130 receives a completion with Unsupported Request Status. 13 MABORT rcu 0 – Unsupported Request not received. 1 – Unsupported Request received on. Received target abort. This bit is set when the downstream PCI Express interface of the XIO3130 receives a completion with Completer Abort Status. 12 TABORT_REC rcu 0 – Completer Abort not received. 1 - Completer Abort received. Signaled target abort. This bit is set when the downstream PCI Express interface completes a Request with Completer Abort Status. 11 TABORT_SIG rcu 10:9 PCI_SPEED r 8 DATAPAR rcu 7 FBB_CAP r Fast back-to-back capable. This bit is hardwired to zero. This bit does not apply to PCI Express. 6 RSVD r Reserved. When read, this bit returns zero. 5 66MHZ r 66-MHz capable. This bit is hardwired to zero. This bit does not apply to PCI Express. 4:0 RSVD r Reserved. When read, these bits return zeros. 0 – Completer Abort not signaled. 1 – Completer Abort signaled. DEVSEL timing. These bits are hardwired to 00. These bits do not apply to PCI Express. Master data parity error. This bit is set when the XIO3130 receives a poisoned completion or poisons a write request on the downstream PCI Express interface. This bit is never set if the parity error response enable bit in the Bridge Control register is clear. 4.3.18 Memory Base Register This read/write register specifies the lower limit of the memory addresses that the downstream port forwards downstream. PCI register offset: 20h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-58. IBit Descriptions – Memory Base Register BIT FIELD NAME ACCESS DESCRIPTION Memory base. This field defines the bottom address of the memory address range that is used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be zero. 15:4 MEMBASE rw 3:0 RSVD r Submit Documentation Feedback Reserved. When read, these bits return zeros. XIO3130 Configuration Register Space 93 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.19 Memory Limit Register This read/write register specifies the upper limit of the memory addresses that the downstream port forwards downstream. PCI register offset: 22h Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-59. Bit Descriptions – Memory Limit Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 MEMLIMIT rw Memory limit. This field defines the top address of the memory address range that is used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be FFFFFh. 3:0 RSVD r Reserved. When read, these bits return zeros. 4.3.20 Pre-fetchable Memory Base Register This read/write register specifies the lower limit of the pre-fetchable memory addresses that the downstream port forwards downstream. PCI register offset: 24h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 0001h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Table 4-60. Descriptions – Pre-fetchable Memory Base Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 PREBASE rw Pre-fetchable memory base. This field defines the bottom address of the pre-fetchable memory address range that is used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be zero. The Pre-fetchable Base Upper 32 Bits register is used to specify the bit [63:32] of the 64-bit pre-fetchable memory address. 3:0 64BIT r 64-bit memory indicator. These read-only bits indicate that 64-bit addressing is supported for this memory window. 4.3.21 Pre-fetchable Memory Limit Register This read/write register specifies the upper limit of the pre-fetchable memory addresses that the downstream port forwards downstream. PCI register offset: 26h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 94 0001h 15 0 14 0 13 0 XIO3130 Configuration Register Space 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-61. Bit Descriptions – Pre-fetchable Memory Limit Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 PRELIMIT rw Pre-fetchable memory limit. This field defines the top address of the pre-fetchable memory address range that is used to determine when to forward memory transactions from one interface to the other. These bits correspond to address bits [31:20] in the memory address. The lower 20 bits are assumed to be FFFFFh. The Pre-fetchable Limit Upper 32 Bits register is used to specify the bit [63:32] of the 64-bit pre-fetchable memory address. 3:0 64BIT r 64-bit memory indicator. These read-only bits indicate that 64-bit addressing is supported for this memory window. 4.3.22 Pre-fetchable Base Upper 32 Bits Register This read/write register specifies the upper 32 bits of the Pre-fetchable Memory Base register. PCI register offset: 28h Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-62. Bit Descriptions – Pre-fetchable Base Upper 32 Bits Register BIT FIELD NAME ACCESS DESCRIPTION 31:0 PREBASE rw Pre-fetchable memory base upper 32 bits. This field defines the upper 32 bits of the bottom address of the pre-fetchable memory address range that is used to determine when to forward memory transactions downstream. 4.3.23 Pre-fetchable Limit Upper 32 Bits Register This read/write register specifies the upper 32 bits of the Pre-fetchable Memory Limit register. PCI register offset: 2Ch Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-63. Descriptions – Pre-fetchable Limit Upper 32 Bits Register BIT FIELD NAME ACCESS DESCRIPTION 31:0 PRELIMIT rw Pre-fetchable memory limit upper 32 bits. This field defines the upper 32 bits of the top address of the pre-fetchable memory address range that is used to determine when to forward memory transactions downstream. Submit Documentation Feedback XIO3130 Configuration Register Space 95 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.24 I/O Base Upper 16 Bits Register This read/write register specifies the upper 16 bits of the I/O Base register. PCI register offset: 30h Register type: Read/Write Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-64. Bit Descriptions – I/O Base Upper 16 Bits Register BIT FIELD NAME ACCESS 15:0 IOBASE rw DESCRIPTION I/O base upper 16 bits. This field defines the upper 16 bits of the bottom address of the I/O address range that is used to determine when to forward I/O transactions downstream. 4.3.25 I/O Limit Upper 16 Bits Register This read/write register specifies the upper 16 bits of the I/O Limit register. PCI register offset: 32h Register type: Read/Write Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-65. Bit Descriptions – I/O Limit Upper 16 Bits Register BIT 15:0 FIELD NAME ACCESS IOLIMIT DESCRIPTION I/O limit upper 16 bits. This field defines the upper 16 bits of the top address of the I/O address range that is used to determine when to forward I/O transactions downstream. rw 4.3.26 Capabilities Pointer Register This read-only register provides a pointer into the PCI configuration header, which is where the PCI power management block resides. Since the PCI power management registers begin at 50h, this register is hardwired to 50h. PCI register offset: 34h Register type: Read only Default value: BIT NUMBER RESET STATE 96 50h 7 0 6 1 5 0 XIO3130 Configuration Register Space 4 1 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.27 Interrupt Line Register This read/write register, which the system programs, indicates to the software which interrupt line that the XIO3130 downstream port has assigned to it. The default value of this register is FFh, which indicates that an interrupt line has not yet been assigned to the function. This register is essentially a scratch-pad register; it has no effect on the XIO3130 itself. PCI register offset: 3Ch Register type: Read/Write Default value: FFh BIT NUMBER RESET STATE 7 1 6 1 5 1 4 1 3 1 2 1 1 1 0 1 4.3.28 Interrupt Pin Register The Interrupt Pin register is read-only, which indicates that the XIO3130 downstream ports generate INTx interrupts as follows: • Downstream port 0 on PCI Interrupt pin INTA (register value of 01h) • Downstream port 1 on PCI Interrupt pin INTA (register value of 01h) • Downstream port 2 on PCI Interrupt pin INTA (register value of 01h) Interrupts originated by XIO3130 downstream ports are associated with the primary side of the downstream port PCI-to-PCI bridge, and as a result are only passed through the upstream port PCI-to-PCI bridge as described in PCI Express Base Specification Revision 1.1, Page 69, Table 2-13. PCI register offset: 3Dh Register type: Read only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.3.29 Bridge Control Register The Bridge Control register provides extensions to the Command register that are specific to a bridge. PCI register offset: 3Eh Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-66. Bit Descriptions – Bridge Control Register BIT FIELD NAME ACCESS 15:12 RSVD r Reserved. When read, these bits return zeros. 11 DTSERR r Discard timer SERR enable. This bit is hardwired to zero. This bit does not apply to PCI Express. 10 DTSTATUS r Discard timer status. This bit is hardwired to zero. This bit does not apply to PCI Express. 9 SEC_DT r Secondary discard timer. This bit is hardwired to zero. This bit does not apply to PCI Express. 8 PRI_DEC r Primary discard timer. This bit is hardwired to zero. This bit does not apply to PCI Express. 7 FBB_EN r Fast back-to-back enable. This bit is hardwired to zero. This bit does not apply to PCI Express. Submit Documentation Feedback DESCRIPTION XIO3130 Configuration Register Space 97 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-66. Bit Descriptions – Bridge Control Register (continued) BIT 6 FIELD NAME SRST ACCESS rw DESCRIPTION Secondary bus reset. This bit is set when the software resets all devices downstream of the XIO3130 downstream port. Setting this bit causes the downstream port to send a reset downstream via a training sequence. 0 – Downstream port not in Reset state 1 – Downstream port in Reset state 5 MAM r Master abort mode. This bit is hardwired to zero. This bit does not apply to PCI Express. VGA 16-bit decode. This bit enables the XIO3130 downstream port to provide full 16-bit decoding for VGA I/O addresses. This bit only has meaning if the VGA enable bit is set. 4 VGA16 rw 0 – Ignore address bits [15:10] when decoding VGA I/O addresses. 1 – Decode address bits [15:10] when decoding VGA I/O addresses. VGA enable. This bit modifies the response by the XIO3130 downstream port to VGA-compatible addresses. If this bit is set, the XIO3130 downstream port positively decodes and forwards the following accesses on the primary interface to the secondary interface (and, conversely, blocks the forwarding of these addresses from the secondary to primary interface): •= Memory accesses in the range 000A 0000h to 000BFFFFh •= I/O addresses in the first 64KB of the I/O address space (address bits [31:16] are 0000h.) and where address bits [9:0] are in the range 3B0h to 3BBh or 3C0h to 3DFh (inclusive of ISA address aliases; address bits [15:10] may possess any value and are not used in the decoding). 3 VGA rw If the VGA Enable bit is set, forwarding of VGA addresses is independent of the value of the ISA Enable bit (located in the Bridge Control register), the I/O address range and memory address ranges defined by the I/O Base and Limit registers, the Memory Base and Limit registers, and the Pre-fetchable Memory Base and Limit registers of the bridge. Forwarding of VGA addresses is qualified by the I/O Enable and Memory Enable bits in the Command register. 0 – Do not forward VGA-compatible memory and I/O addresses from the primary to secondary interface unless they are enabled for forwarding by the defined I/O and memory address ranges. 1 – Forward VGA-compatible memory and I/O addresses from the primary interface to the secondary interface (if the I/O Enable and Memory Enable bits are set) independent of the I/O and memory address ranges and independent of the ISA Enable bit. 2 ISA rw ISA enable. This bit modifies the response by the XIO3130 downstream port to ISA I/O addresses. This bit applies only to I/O addresses that are enabled by the I/O Base and I/O Limit registers and are in the first 64 KB of PCI I/O address space (0000 0000h to 0000 FFFFh). If this bit is set, the bridge blocks any forwarding from primary to secondary of I/O transactions addressing the last 768 bytes in each 1 KB block. In the opposite direction (secondary to primary), I/O transactions are forwarded if they address the last 768 bytes in each 1K block. 0 – Forward downstream all I/O addresses in the address range defined by the I/O Base and I/O Limit registers. 1 – Forward upstream ISA I/O addresses in the address range defined by the I/O Base and I/O Limit registers that are in the first 64 KB of PCI I/O address space (top 768 bytes of each 1 KB block). SERR enable. This bit controls the forwarding of system error events upstream from the secondary interface to the primary interface. The XIO3130’s downstream port forwards system error events upstream when: •= This bit is set. 1 SERR_EN rw •= The SERR enable bit in the downstream port command register is set. •= A nonfatal or fatal error condition is detected on the secondary interface (i.e., the PCI Express interface). 0 – Disable the reporting of nonfatal errors and fatal errors. 1 – Enable the reporting of nonfatal errors and fatal errors. Parity error response enable. For PCI Express, this bit controls responses to poisoned TLPs received on the downstream port. 0 PERR_EN rw 0 – Disable responses to poisoned TLPs. 1 – Enable responses to poisoned TLPs. 98 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.30 Capability ID Register This read-only register identifies the linked list item as the register for PCI power management. It returns 01h when read. PCI register offset: 50h Register type: Read only Default value: 01h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.3.31 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130 downstream port. This register reads 70h, which points to the MSI Capabilities registers. PCI register offset: 51h Register type: Read only Default value: 70h BIT NUMBER RESET STATE 7 0 6 1 5 1 4 1 3 0 2 0 1 0 0 0 4.3.32 Power Management Capabilities Register This register indicates the capabilities of the XIO3130 downstream port related to PCI power management. PCI register offset: 52h Register type: Read only Default value: BIT NUMBER RESET STATE XXX3h 15 y 14 1 13 1 12 x 11 1 10 1 9 x 8 0 7 0 6 y 5 0 4 0 3 0 2 0 1 1 0 1 Table 4-67. Bit Descriptions – Power Management Capabilities Register BIT FIELD NAME ACCESS DESCRIPTION 15:11 PME_SUPPORT r PME support. This 5-bit field indicates the power states from which the downstream port may assert PME. These five bits return a value of 5’by11x1, which indicates that the XIO3130 can assert PME from D0, D2, D3hot, maybe D3cold (i.e., depending on y), and maybe D1 (i.e., depending on x). The bit that defines this power state for D3cold (i.e., y) is controlled by the AUX_PRESENT bit in the Global Chip Control register. The bit defining this power state for D1 (i.e., x) is controlled by the D1_SUPPORT bit in the Global Switch Control register. 10 D2_SUPPORT r This bit returns a 1 when read, which indicates that the function supports the D2 device power state. 9 D1_SUPPORT r This bit indicates whether the function supports the D1 device power state. This bit is controlled by the D1_SUPPORT bit in the Global Switch Control register. The default value x is controlled by the default value for the D1_SUPPORT bit in the Global Switch Control register. 8:6 AUX_CURRENT r 3.3-VAUX auxiliary current requirements. This field reads 3’b00y, i.e., either 3’b001 or 3’b000, depending on the AUX_PRESENT bit in the Global Chip Control register. 3’b001 indicates 55 mA maximum current in D3cold when PME is enabled, according to PCI Power Management Specification Revision 1.2, Section 3.2.3, page 26. 5 DSI r Device-specific initialization. This bit returns 0 when read, which indicates that the XIO3130 does not require special initialization beyond the standard PCI configuration header before a generic class driver is able to use it. 4 RSVD r Reserved. When read, this bit returns zero. Submit Documentation Feedback XIO3130 Configuration Register Space 99 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-67. Bit Descriptions – Power Management Capabilities Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 3 PME_CLK r PME clock. This bit returns zero, which indicates that the PCI clock is not needed to generate PME. 2:0 PM_VERSION r Power management version. This field returns 3’b011, which indicates Revision 1.2 compatibility. 4.3.33 Power Management Control/Status Register This register determines and changes the current power state of the downstream port. PCI register offset: 54h Register type: Read/Write; Read Only; Clear by a Write of One; Hardware Update; Sticky Default value: BIT NUMBER RESET STATE 0008h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 1 2 0 1 0 0 0 Table 4-68. Bit Descriptions – Power Management Control/Status Register BIT FIELD NAME ACCESS DESCRIPTION PME status. PME events are generated due to PCI Hot Plug events. This bit reflects the PME status regardless of the state of PME_EN. 15 PME_STAT rcuh 0 – No PME event pending 1 – PME event pending This bit is reset with GRST. 14:13 DATA_SCALE r Data scale. This 2-bit field returns 0s when read since the XIO3130 does not use the Data register. 12:9 DATA_SEL r Data select. This 4-bit field returns 0s when read since the XIO3130 does not use the Data register. PME enable. This bit enables PME/WAKE signaling, even though the XIO3130 never generates WAKE . 8 PME_EN rwh 0 – Disable PME signaling. 1 – Enable PME signaling. This bit is reset with GRST. 7:4 3 RSVD NO_SOFT_RST r r Reserved. When read, these bits return zeros. No Soft Reset. This bit controls whether the transition from D3hot to D0 resets the state according to PCI Power Management Specification Revision 1.2. This bit is hardwired to 1’b1. 0 – D3hot to D0 transition causes reset. 1 – D3hot to D0 transition does not cause reset. 2 RSVD r Reserved. When read, this bit returns zero. Power state. This 2-bit field is used to determine the current power state of the function and to set the function into a new power state. This field is encoded as follows: 00 = D0 1:0 PWR_STATE rw 01 = D1 10 = D2 11 = D3hot 100 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.34 Power Management Bridge Support Extension Register This read-only register is used to indicate to the host software what the state of the downstream port’s secondary bus will be when the downstream port is placed in D3. PCI register offset: 56h Register type: Read only Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-69. Bit Descriptions – PM Bridge Support Extension Register BIT FIELD NAME ACCESS DESCRIPTION 7 BPCC r Bus power/Clock control enable. This bit is read-only zero. This bit does not apply to PCI Express. 6 BSTATE r B2/B3 support. This bit is read-only zero. This bit does not apply to PCI Express. 5:0 RSVD r Reserved. When read, these bits return zeros. 4.3.35 Power Management Data Register The read-only register is not applicable to the XIO3130 and returns 00h when read. PCI register offset: 57h Register type: Read only Default value: BIT NUMBER RESET STATE 00h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.36 MSI Capability ID Register This read-only register identifies the linked list item as the register for Message Signaled Interrupts Capabilities. The register returns 05h when read. PCI register offset: 70h Register type: Read only Default value: BIT NUMBER RESET STATE 05h 7 0 6 0 5 0 4 0 3 0 2 1 1 0 0 1 4.3.37 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130. This register reads 80h, which points to the Subsystem ID and Subsystem Vendor ID Capabilities registers. PCI register offset: 71h Register type: Read only Default value: 80h BIT NUMBER RESET STATE 7 1 Submit Documentation Feedback 6 0 5 0 4 0 3 0 2 0 1 0 0 0 XIO3130 Configuration Register Space 101 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.38 MSI Message Control Register This register is used to control the sending of MSI messages. PCI register offset: 72h Register type: Read/Write; Read Only Default value: 0080h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 1 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-70. Bit Descriptions – MSI Message Control Register BIT FIELD NAME ACCESS DESCRIPTION 15:8 RSVD r Reserved. When read, these bits return zeros. 7 64CAP r 64-bit message capability. This bit is read-only 1, which indicates that the XIO3130 downstream port supports 64-bit MSI message addressing. Multiple message enable. This field indicates the number of distinct messages that the XIO3130 downstream port is allowed to generate. 000 – 1 message 001 – 2 messages 010 – 4 messages 6:4 MM_EN rw 011 – 8 messages 100 – 16 messages 101 – 32 messages 110 – Reserved 111 – Reserved 3:1 MM_CAP Multiple message capabilities. This field indicates the number of distinct messages that the XIO3130 downstream port can generate. This field is read-only 000, which indicates that the downstream port can signal one interrupt. r MSI Enable. This bit is used to enable MSI interrupt signaling. The software must enable MSI signaling for the XIO3130 downstream port to send MSI messages. 0 MSI_EN rw 0 – MSI signaling is prohibited 1 – MSI signaling is enabled 4.3.39 MSI Message Address Register This register contains the lower 32 bits of the address that an MSI message shall be written to when an interrupt is to be signaled. PCI register offset: 74h Register type: Read/Write; Read Only Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-71. Bit Descriptions – MSI Message Address Register BIT FIELD NAME ACCESS 31:2 ADDRESS rw 1:0 RSVD r 102 XIO3130 Configuration Register Space DESCRIPTION System-specified message address. Reserved. When read, these bits return zeros. Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.40 MSI Message Upper Address Register This read/write register contains the upper 32 bits of the address that a MSI message shall be written to when an interrupt is to be signaled. If this register is 0000 0000h, 32-bit addressing is used in the MSI Message packet. Otherwise, 64-bit addressing is used. PCI register offset: 78h Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 4.3.41 MSI Message Data Register This register contains the data that the software programmed the device to send when it sends an MSI message. PCI register offset: 7Ch Register type: Read/Write Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-72. Bit Descriptions – MSI Data Register BIT FIELD NAME ACCESS DESCRIPTION 15:4 MSG rw System-specific message. This field contains the portion of the message that the XIO3130 can never modify. 3:0 MSG_NUM rw Message number. This portion of the message field may be modified to contain the message number if multiple messages are enabled. Since the XIO3130 downstream port only generates one MSI type, the XIO3130 hardware does not modify these bits. 4.3.42 Capability ID Register This read-only register identifies the linked list item as the register for Subsystem ID and Subsystem Vendor ID Capabilities. This register returns 0Dh when read. PCI register offset: 80h Register type: Read only Default value: 0Dh BIT NUMBER RESET STATE 7 0 Submit Documentation Feedback 6 0 5 0 4 0 3 1 2 1 1 0 0 1 XIO3130 Configuration Register Space 103 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.43 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130 downstream port. This register reads 90h, which points to the PCI Express Capabilities registers. PCI register offset: 81h Register type: Read only Default value: 90h BIT NUMBER RESET STATE 7 1 6 0 5 0 4 1 3 0 2 0 1 0 0 0 4.3.44 Subsystem Vendor ID Register This register is used for system and option card identification and may be required for certain operating systems. This read-only register is a direct reflection of the upstream port’s Subsystem Access register, which is read/write and is initialized through the EEPROM (if present). PCI register offset: 84h Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.45 Subsystem ID Register This register is used for system and option card identification and may be required for certain operating systems. This read-only register is a direct reflection of the upstream port’s Subsystem Access register, which is read/write and is initialized through the EEPROM (if present). PCI register offset: 86h Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.46 PCI Express Capability ID Register This read-only register identifies the linked list item as the register for PCI Express Capabilities. When read, this register returns 10h. PCI register offset: 90h Register type: Read only Default value: 10h BIT NUMBER RESET STATE 104 7 0 6 0 5 0 XIO3130 Configuration Register Space 4 1 3 0 2 0 1 0 0 0 Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.47 Next-Item Pointer Register The contents of this read-only register indicate the next item in the linked list of capabilities for the XIO3130 downstream port. This register reads 00h, which indicates that no additional capabilities are supported. PCI register offset: 91h Register type: Read only Default value: 00h BIT NUMBER RESET STATE 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.48 PCI Express Capabilities Register This register indicates the capabilities of the downstream port of the XIO3130 related to PCI Express. PCI register offset: 92h Register type: Read only Default value: BIT NUMBER RESET STATE 0061h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 1 5 1 4 0 3 0 2 0 1 0 0 1 Table 4-73. Bit Descriptions – PCI Express Capabilities Register BIT FIELD NAME ACCESS 15:14 RSVD r Reserved. When read, these bits return zeros. 13:9 INT_NUM r Interrupt message number. This field is used for MSI support and is implemented as read-only zero. 8 SLOT DESCRIPTION Slot implemented. This bit indicates whether the port is connected to a slot connector (e.g., for PCI Express, ExpressCard™ or other add-in cards). This field can be programmed by writing to the General Control register. r 0 – Port not connected to a slot 1 – Port connected to a slot 7:4 DEV_TYPE r Device/Port type. This read-only field returns 0110b, which indicates that the device is a downstream port of a PCI Express XIO3130. 3:0 VERSION r Capability version. This field returns 0001b, which indicates revision 1 of the PCI Express capability. 4.3.49 Device Capabilities Register The Device Capabilities register indicates the device-specific capabilities of the XIO3130 downstream port. PCI register offset: 94h Register type: Read Only; Hardware Update Default value: 0000 8XX1h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 1 0 0 0 u u u v v v 0 0 0 0 0 1 Submit Documentation Feedback XIO3130 Configuration Register Space 105 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-74. Bit Descriptions – Device Capabilities Register BIT FIELD NAME ACCESS 31:28 RSVD r Reserved. When read, these bits return zeros. DESCRIPTION 27:26 CSPLS ru Captured slot power limit scale. This field is only applicable to upstream ports and is hardwired to zero. 25:18 CSPLV ru Captured slot power limit value. This field is only applicable to upstream ports and is hardwired to zero. 17:16 RSVD r Reserved. When read, these bits return zeros. 15 RBER r Role-based error reporting. This bit is set to 1b to indicate support for role-based error reporting. 14 PIP r Power indicator present. This bit indicates whether the XIO3130 has a power indicator. This bit is hardwired to zero. 13 AIP r Attention indicator present. This bit indicates whether the XIO3130 has an attention indicator. This bit is hardwired to zero. 12 ABP r Attention button present. This bit indicates whether the XIO3130 has a power button. This bit is hardwired to zero. 11:6 RSVD r Reserved. When read, these bits return zeros. 5 ETFS r Extended tag field supported. This bit indicates the size of the tag field supported. This bit is hardwired to 0, which indicates support for 5-bit tag fields. 4:3 PFS r Phantom functions supported. This field is read-only 00b, which indicates that function numbers are not used for phantom functions. 2:0 MPSS r Max payload size supported. This field indicates the maximum payload size that the device can support for TLPs. This field is encoded as 001b, which indicates that the maximum payload size for a TLP is 256 bytes. 4.3.50 Device Control Register The Device Control register controls PCI Express device-specific parameters. PCI register offset: 98h Register type: Read/Write; Read Only Default value: 2000h BIT NUMBER RESET STATE 15 0 14 0 13 1 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-75. Bit Descriptions – Device Control Register BIT FIELD NAME ACCESS 15 RSVD r DESCRIPTION Reserved. When read, this bit returns zero. Max read request size. This field is programmed by the host software to set the maximum size of a read request that the XIO3130 can generate. The XIO3130 uses this field in conjunction with the Cache Line Size register to determine how much data to fetch on a read request. This field is encoded as: 000 – 128B 001 – 256B 14:12 MRRS rw 010 – 512B (default) 011 – 1024B 100 – 2048B 101 – 4096B 110 – Reserved 111 – Reserved 11 ENS r Enable no snoop. Since the XIO3130 does not support setting the no-snoop attribute, this bit is read-only zero. 10 APPE r Auxiliary power PM enable. This bit is read-only zero, since the XIO3130 requires a minimal amount of AUX power when PME is disabled. 106 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-75. Bit Descriptions – Device Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 9 PFE r Phantom function enable. Since the XIO3130 part does not support phantom functions, this bit is read-only zero. 8 ETFE r Extended tag field enable. Since the XIO3130 part does not support extended tags, this bit is read-only zero. Max payload size. This field is programmed by the host software to set the maximum size of posted writes or read completions that the XIO3130 can initiate. This field is encoded as: 000 – 128B (default) 001 – 256B 010 – 512B 7:5 MPS rw 011 – 1024B 100 – 2048B 101 – 4096B 110 – Reserved 111 – Reserved 4 3 ERO Enable relaxed ordering. Since the XIO3130 part does not support relaxed ordering, this bit is read-only zero. r URRE Unsupported request reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_NONFATAL messages to the root complex when an unsupported request is received by the downstream port. rw 0 – Do not report unsupported requests to the root complex. 1 – Report unsupported requests to the root complex. Fatal error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_FATAL messages to the root complex when a system error event occurs. 2 FERE rw 0 – Do not report fatal errors to the root complex. 1 – Report fatal errors to the root complex. Nonfatal error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_NONFATAL messages to the root complex when a system error event occurs. 1 NFERE rw 0 – Do not report nonfatal errors to the root complex. 1 – Report nonfatal errors to the root complex. Correctable error reporting enable. If this bit is set, the XIO3130 is enabled to send ERR_CORR messages to the root complex when a system error event occurs. 0 CERE rw 0 – Do not report correctable errors to the root complex. 1 – Report correctable errors to the root complex. 4.3.51 Device Status Register The Device Status register controls PCI Express device-specific parameters. PCI register offset: 9Ah Register type: Read Only; Clear by a Write of One; Hardware Update Default value: 00X0h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 x 3 0 2 0 1 0 0 0 Table 4-76. Bit Descriptions – Device Status Register BIT FIELD NAME ACCESS 15:6 RSVD r Reserved. When read, these bits return zeros. 5 PEND ru Transaction pending. This bit is set when the XIO3130 downstream port has issued a non-posted transaction that has not been completed yet. Submit Documentation Feedback DESCRIPTION XIO3130 Configuration Register Space 107 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-76. Bit Descriptions – Device Status Register (continued) BIT 4 FIELD NAME ACCESS APD DESCRIPTION AUX power detected. This bit indicates that AUX power is present. This bit is a direct reflection of the AUX_PRSNT bit in the Global Chip Control register, and it has the same default value. ru 0 – No AUX power detected. 1 – AUX power detected. 3 URD rcu Unsupported Request detected. This bit is asserted when an Unsupported Request error is detected (i.e., when a request is received that results in sending a completion with an Unsupported Request status). Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 2 FED rcu Fatal error detected. This bit is set by the XIO3130 when a fatal error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 1 NFED rcu Nonfatal error detected. This bit is set by the XIO3130 when a nonfatal error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 0 CED rcu Correctable error detected. This bit is set by the XIO3130 when a correctable error is detected. Errors are logged in this bit regardless of whether error reporting is enabled in the Device Control register. 4.3.52 Link Capabilities Register The Link Capabilities register indicates the link-specific capabilities of the XIO3130 downstream port. PCI register offset: 9Ch Register type: Read only Default value: 0XXX XC11h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 x 24 x 23 0 22 0 21 0 20 w 19 w 18 1 17 y 16 y BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE y z z z 1 1 0 0 0 0 0 1 0 0 0 1 Table 4-77. Bit Descriptions – Link Capabilities Register BIT FIELD NAME ACCESS DESCRIPTION 31:24 PORT_NUM r Port number. This field indicates the port number for the PCI Express link. This field is set to 8’h01 for downstream port 0, 8’h02 for downstream port 1, and 8’h03 for downstream port 2. 23:21 RSVD r Reserved. When read, these bits return zeros. r Data link layer link active reporting capable. This bit indicates whether this slot is capable of reporting whether the link is active. This field can be programmed by writing to the General Control register. The default state w is that of the LINK_ACT_RPT_CAP field in the General Control register. 20 DLL_LARC 0 – Incapable of link active reporting 1 – Capable of link active reporting 19 SDERC r Surprise down error reporting capable. This bit indicates whether this slot is capable of detecting and reporting a surprise down error condition. This field can be programmed by writing to the LINK_ACT_RPT_CAP field in the General Control register. The default state w is that of the LINK_ACT_RPT_CAP field in the General Control register. 0 – Incapable of detecting and reporting a surprise down error condition 1 – Capable of detecting and reporting a surprise down error condition 18 17:15 108 CPM L1_LATENCY r Clock power management. This bit is 1b, which indicates support for CLKREQ. r L1 exit latency. This field indicates the time required to transition from the L1 state to the L0 state. This field is a direct reflection of the Downstream Ports Link PM Latency register L1_EXIT_LAT field, which is a read/write field that is loaded from EEPROM (if present). The default value of this field is yyy, which is the same as the default value of the Link PM Latency register L1_EXIT_LAT field. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-77. Bit Descriptions – Link Capabilities Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 14:12 L0S_LATENCY r L0s exit latency. This field indicates the time required to transition from the L0s state to the L0 state. This field is a direct reflection of the Downstream Ports Link PM Latency register L0S_EXIT_LAT field, which is a read/write field that is loaded from EEPROM (if present). The default value of this field is zzz, which is the same as the default value of the Link PM Latency register L0S_EXIT_LAT field. 11:10 ASLPMS r Active State Link PM support. This field reads 11b, which indicates that the XIO3130 supports both L0s and L1 for Active State Link PM. 9:4 MLW r Maximum link width. This field is encoded 000001b to indicate that the XIO3130 downstream port supports only an x1 PCI Express link. 3:0 MLS r Maximum link speed. This field is encoded 0001b to indicate that the XIO3130 downstream port supports a maximum link speed of 2.5 Gb/s. 4.3.53 Link Control Register The Link Control register is used to control link-specific behavior. PCI register offset: A0h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-78. Bit Descriptions – Link Control Register BIT FIELD NAME ACCESS 15:9 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Clock power management enable. When CLKREQ support is enabled, the EP_LI_LAT field in the Downstream Ports Link PM Latency register increases due to link PLL locking requirements. 8 CPM_EN rw 0 – Disables CLKREQ support on downstream port 1 – Enables CLKREQ support on downstream port Extended synch. This bit is used to force the XIO3130 downstream port to extend the transmission of FTS ordered sets and an extra TS2 when exiting from L1 before entering to L0. 7 ES rw 0 – Normal synch 1 – Extended synch 6 CCC rw Common clock configuration. This bit is set when a common clock is provided to both ends of the downstream port’s PCI Express link. This bit can be used to change the L0s and L1 exit latencies. 0 – Reference clock is asynchronous 1 – Reference clock is synchronous Retrain link. This bit initiates link retraining on the downstream port. This bit always returns 0b when read. 5 RL rw 0 – Do not initiate link retraining 1 – Initiate link retraining Link disable. This bit disables the link. Writes to this bit are immediately reflected in the value read from the bit, regardless of the actual link state. 4 LD rw 0 – Link enabled 1 – Link disabled 3 RCB r Read completion boundary. This bit specifies the minimum size read completion packet that the XIO3130 can send when breaking a read request into multiple completion packets. This field is not applicable to XIO3130; i.e., the XIO3130 does not break up completion packets and is hardwired to zero. 0 – 64 bytes 1 – 128 bytes 2 RSVD Submit Documentation Feedback r Reserved. When read, this bit returns zero. XIO3130 Configuration Register Space 109 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-78. Bit Descriptions – Link Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Active State Link PM Control. This field is used to enable and disable active state PM. 00 – Active State PM disabled 1:0 ASLPMC rw 01 – L0s entry enabled 10 – Reserved 11 – L0s and L1 entry enabled 4.3.54 Link Status Register The Link Status register indicates the current state of the PCI Express Link. PCI register offset: A2h Register type: Read Only; Hardware Update Default value: XX11h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 1 11 0 10 x 9 0 8 0 7 0 6 0 5 0 4 1 3 0 2 0 1 0 0 1 Table 4-79. Bit Descriptions – Link Status Register BIT FIELD NAME ACCESS 15:14 RSVD r Reserved. When read, these bits return zeros. DESCRIPTION 13 DLL_ACTV r Data link layer active. When the DLL_LARC field in the Link Capabilities register is asserted, this field returns the value of the following comparison: (Link_State == DL_Active). This field returns zero when the DLL_LARC field in the Link Capabilities register is de-asserted. 12 SCC r Slot clock configuration. This bit reflects the reference clock configurations and is read-only 1, indicating that a 100 MHz common clock reference is used. 11 LT ru Link training in progress. The hardware automatically clears this bit when the LTSSM exits the Configuration/Recovery state. 10 UNDEF r Undefined. The value read from this bit is undefined. 9:4 NLW r Negotiated link width. This field is read-only 000001b, which indicates that the lane width is x1. 3:0 LS r Link speed. This field is read-only 0001b, which indicates that the link speed is 2.5 Gb/s. 4.3.55 Slot Capabilities Register The Slot Capabilities register indicates the slot-specific capabilities of the downstream port. PCI register offset: A4h Register type: Read/Write; Read Only; Hardware Update Default value: 0000 0060h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 Table 4-80. Bit Descriptions – Slot Capabilities Register BIT 31:19 110 FIELD NAME SLOT_NUM ACCESS r XIO3130 Configuration Register Space DESCRIPTION Physical slot number. This field indicates a system-dependent physical slot number that is unique to each slot in the system. This field can be programmed by writing to the General Slot Info register. Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-80. Bit Descriptions – Slot Capabilities Register (continued) BIT 18 FIELD NAME EMILP ACCESS ru DESCRIPTION Electromechanical interlock present. This bit indicates whether an electromechanical interlock is implemented on the chassis for this slot. This bit can be programmed by writing to the General Control register. 0 – Electromechanical interlock not present. 1 – Electromechanical interlock present. No command completed support. This bit is hardwired to zero, which indicates that command completed software notification (i.e., interrupt generation) is always supported. 17 NCCS ru 0 – Command completed support is provided. 1 – Command completed support is not provided. Slot power limit scale. This field Indicates the scale that is used for the slow power limit value. This field may be written only once after any given PERST; the effect when written is to cause the port to send the Set_Slot_Power_Limit message. 00 – 1.0x 16:15 SPLS rw 01 – 0.1x 10 – 0.01x 11 – 0.001x This field is loaded from EEPROM (if present) and reset with PERST. 14:7 SPLV rw Slot power limit value. When multiplied by the SPLS field (see previous row in this table), this field indicates the maximum power in watts that can be consumed by a card plugged into a slot attached to this port,. This field may be written only once after any given PERST; the effect when written is to cause the port to send the Set_Slot_Power_Limit message. This field is loaded from EEPROM (if present) and reset with PERST. 6 HP_CAPABLE r PCI Hot Plug capable. This bit indicates whether this slot is capable of supporting PCI Hot Plug operations. The default setting of this register is defined by the DPSTRP[2,0] strapping. This bit can be programmed by writing to the General Control register bit 14, which is SLOT_HPC. For more information on the General Control register, see section 3.3.61. 0 – Incapable of supporting PCI Hot Plug operations 1 – Capable of supporting PCI Hot Plug operations 5 HP_SURPRISE r PCI Hot Plug surprise. This bit indicates whether a device present in this slot can be removed from the system without any prior notification. This bit can be programmed by writing to the General Control register bit 13, which is SLOT_HPS. For more information on the General Control register, see section 3.3.61. 0 – No device present that can be removed by surprise 1 – Device present that can be removed by surprise 4 PIP r Power indicator present. This bit indicates whether a power indicator is implemented on the chassis for this slot. This bit can be programmed by writing to the General Control register bit 12, which is SLOT_PIP. For more information on the General Control register, see section 3.3.61. 0 – Power indicator not present 1 – Power indicator present 3 AIP r Attention indicator present. This bit indicates whether an attention indicator is implemented on the chassis for this slot. This bit can be programmed by writing to the General Control register bit 11, which is SLOT_AIP. For more information on the General Control register, see section 3.3.61. 0 – Attention indicator not present 1 – Attention indicator present 2 MRLSP r Manual retention latch sensor present. This bit indicates whether a manual retention latch (MRL) sensor is implemented on the chassis for this slot. This bit can be programmed by writing to the General Control register bit 10, which is SLOT_MRLSP. For more information on the General Control register, see section 3.3.61. 0 – MRL sensor not present 1 – MRL sensor present Submit Documentation Feedback XIO3130 Configuration Register Space 111 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-80. Bit Descriptions – Slot Capabilities Register (continued) BIT 1 FIELD NAME ACCESS PCP DESCRIPTION Power controller present. This bit indicates whether a power controller is implemented for this slot. The default setting of this register is defined by the DPSTRP[2,0] strapping. This bit can be programmed by writing to the General Control register bit 9, which is SLOT_PCP. For more information on the General Control Register, see section 3.3.61. If this bit is zero, then the PWRON_EC output signal, which may go to a pin, is forced asserted; there is no such effect on the PWRON output signal. r 0 – Power controller not present 1 – Power controller present 0 ABP Attention button present. This bit indicates whether an attention button is implemented on the chassis for this slot. This bit can be programmed by writing to the General Control register bit 8, which is SLOT_ABP. For more information on the General Control register, see section 3.3.61. r 0 – Attention button not present 1 – Attention button present 4.3.56 Slot Control Register The Slot Control register controls slot-specific parameters. PCI register offset: A8h Register type: Read/Write; Read Only Default value: BIT NUMBER RESET STATE 07C0h 15 0 14 0 13 0 12 0 11 0 10 1 9 1 8 1 7 1 6 1 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-81. Bit Descriptions – Slot Control Register BIT FIELD NAME ACCESS 15:13 RSVD r DESCRIPTION Reserved. When read, these bits return zeros. Data link layer state changed enable. This bit enables software notification (i.e., interrupts) due to an assertion of the DLLSC field in the Slot Status register. 12 DLLSC_EN rw 0 – DLLSC interrupts disabled 1 – DLLSC interrupts enabled 11 10 EMIL_CTL PC_CTL rw rw Electromechanical interlock control. When read, this bit returns zero. A write of 1’b0 has no effect. If the EMILP field in the Slot Capabilities register is asserted, then a write of 1’b1 causes a 100 ms high-going pulse on the EMIL_CTL output pin; otherwise, the write has no effect. Power controller control. When read, this bit indicates the current state of power applied to the slot. Writes set the power state of the slot and control the PWR_ON pin. When this bit transitions from power on to power off, and the HP_PME_MSG_EN bit in the Global Switch Control register is asserted, a PME_Turn_Off message is sent and the PWRON output pin gets de-asserted only after a PME_TO_Ack is received or after a 100 ms timeout. 0 – Power on 1 – Power off Power indicator control. When read, this field indicates the current state of the power indicator. Writes set the power indicator state. When writes cause this field to change, the appropriate POWER_INDICATOR_* messages are sent. This bit controls the PWR_LED output pin. 9:8 PI_CTL rw 00b – Reserved 01b – On 10b – Blinking 11b – Off 112 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-81. Bit Descriptions – Slot Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Attention indicator control. When read, this field indicates the current state of the attention indicator. Writes set the attention indicator state. When writes cause this field to change, the appropriate ATTENTION_INDICATOR_* messages are sent. This bit controls the ATN_LED output pin. 7:6 AI_CTL rw 00b – Reserved 01b – On 10b – Blinking 11b – Off PCI Hot Plug interrupt enable. This bit enables generation of PCI Hot Plug interrupts on enabled PCI Hot Plug events. 5 HPI_EN rw 0 – PCI Hot Plug interrupts disabled 1 – PCI Hot Plug interrupts enabled 4 CCI_EN rw Command-completed interrupt enable. This bit enables generation of an interrupt upon completion of a command by the PCI Hot Plug Controller. HPI_EN, and MSI_EN (see MSI Message Control register) must also be enabled for interrupt generation. A Hot Plug Controller Command is defined as a state change in any of the *_CTL bits in this register (i.e., software writes). 0 – Command-completed interrupts disabled 1 – Command-completed interrupts enabled Presence detect changed enable. This bit enables generation of a •========= PCI Hot Plug interrupt •========= PME when the PDC bit in the Slot Status register is asserted. 3 PDC_EN rw 0 – Disabled 1 – Enabled HPI_EN and MSI_EN (see MSI Message Control register) must also be enabled for interrupt generation. PME_EN must also be enabled for PME signaling during D1, D2, or D3hot. For more information, see section 6.7.7 in PCI Express Base Specification Revision 1.0a. Manual retention latch sensor changed enable. This bit enables generation of a •========= PCI Hot Plug interrupt •========= PME when the MRLSC bit in the Slot Status register is asserted. 2 MRLSC_EN rw 0 – Disabled 1 – Enabled HPI_EN and MSI_EN (see MSI Message Control register) must also be enabled for interrupt generation. PME_EN must also be enabled for PME signaling during D1, D2, or D3hot. For more information, see section 6.7.7 in PCI Express Base Specification Revision 1.0a. Power fault detected enable. This bit enables generation of a •========= PCI Hot Plug interrupt •========= PME when the PFD bit in the Slot Status register is asserted. 1 PFD_EN rw 0 – Disabled 1 – Enabled HPI_EN and MSI_EN (see MSI Message Control register) must also be enabled for interrupt generation. PME_EN must also be enabled for PME signaling during D1, D2, or D3hot. For more information, see section 6.7.7 in PCI Express Base Specification Revision 1.0a. Submit Documentation Feedback XIO3130 Configuration Register Space 113 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-81. Bit Descriptions – Slot Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Attention button pressed enable. This bit enables generation of a •========= PCI Hot Plug interrupt •========= PME when the ABP bit in the Slot Status register is asserted. 0 ABP_EN rw 0 – Disabled 1 – Enabled HPI_EN and MSI_EN (see Table 3 21) must also be enabled for interrupt generation. PME_EN must also be enabled for PME signaling during D1, D2, or D3hot. For more information, see section 6.7.7 in PCI Express Base Specification Revision 1.0a. 4.3.57 Slot Status Register The Slot Status register provides information about slot-specific parameters. PCI register offset: AAh Register type: Read Only; Clear by a Write of One; Hardware Update Default value: BIT NUMBER RESET STATE 0010h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 1 3 0 2 0 1 0 0 0 Table 4-82. Bit Descriptions – Slot Status Register BIT FIELD NAME ACCESS 15:9 RSVD r 8 DLLSC ruc DESCRIPTION Reserved. When read, these bits return zeros. Data link layer state changed. This bit is set when the DLL_ACTV field in the Link Status register changes state. A write of 1’b1 clears this field. A write of 1’b0 has no effect. Electromechanical interlock status. If an electromechanical interlock is implemented for the slot, this field indicates the current status of the electromechanical interlock. 7 EMIL_STAT r 0 – Electromechanical interlock disengaged 1 – Electromechanical interlock engaged 6 PDS ru Presence detect state. This bit indicates whether a card is present in a slot. If the SLOT_PRSNT bit in the General Control register is de-asserted, this bit always reads back asserted. If the SLOT_PRSNT bit is asserted, this bit indicates the state of a de-bounced derivative of the PRSNT input pin. 0 – Card presence detection output de-asserted (i.e., slot empty) 1 – Card presence detection output asserted (i.e., card present in slot) Manual retention latch sensor state. This bit indicates the state of a de-bounced derivative of the MRLS_DET input pin. 5 MRLSS ru 0 – MRLS_DET pin asserted (i.e., MRL closed) 1 – MRLS_DET pin de-asserted (i.e., MRL open) 4 CC ruc Command completed. This bit is set when the PCI Hot Plug Controller is ready to accept another command; it does not ensure that the previous command is completely finished. A Hot Plug controller command is defined as a state change in any of the *_CTL bits in the Slot Control register (i.e., software writes). 0 – PCI Hot Plug controller is not ready to accept a new command. 1 – PCI Hot Plug controller is ready to accept a new command. Presence detect changed. This bit indicates whether the state of the PDS bit has changed. 3 PDC ruc 0 – PDS bit has not changed. 1 – PDS bit has changed. MRL sensor changed. This bit indicates whether the state of the MRLSS bit has changed. 2 MRLSC ruc 0 – MRLSS bit has not changed. 1 – MRLSS bit has changed. 114 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-82. Bit Descriptions – Slot Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Power fault detected. This bit indicates the state of the PWRFLT pin. 1 PFD ruc 0 – PWRFLT pin de-asserted (no power fault at slot). 1 – PWRFLT pin asserted (power fault at slot). Attention button pressed. This bit indicates a de-asserted-to-asserted transition on a de-bounced derivative of the ATN_BTN pin. 0 ABP ruc 0 – Attention button not pressed 1 – Attention button pressed 4.3.58 TI Proprietary Register This read/write TI proprietary register is located at offset C8h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 0000 0001h. PCI register offset: C8h Register type: Read/Write Default value: xxxx 0001 BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 4.3.59 TI Proprietary Register This read/write TI proprietary register is located at offset CCh and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 0000 0000h. PCI register offset: CCh Register type: Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Submit Documentation Feedback XIO3130 Configuration Register Space 115 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 4.3.60 TI Proprietary Register This read/write TI proprietary register is located at offset D0h and controls TI proprietary functions. This register must not be changed from the specified default state. If the default value is changed in error, a PCI Express Reset (PERST) returns this register to a default state. If an EEPROM is used to load configuration registers, the value loaded for this register must be 3214 0000h. PCI register offset: D0h Register type: Read/Write Default value: 3214 0000h BIT NUMBER RESET STATE 31 0 30 0 29 1 28 1 27 0 26 0 25 1 24 0 23 0 22 0 21 0 20 1 19 0 18 1 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 4.3.61 General Control Register This read/write register is used to control various functions of the XIO3130 downstream port. PCI register offset: D4h Register type: Read/Write; Read Only Default value: 0000 x0xx BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 x x 0 0 0 0 0 x 0 0 1 0 0 0 x Table 4-83. Bit Descriptions – General Control Register BIT FIELD NAME ACCESS 31:17 RSVD r 16 TI_PROPRIETARY rw DESCRIPTION Reserved. When read, these bits return zeros. TI proprietary. This bit must not be changed from the specified default state. REFCK power fault control. This bit controls whether REFCK output should be disabled when PWR_FAULT is asserted. 15 RC_PF_CTL rw 0 – REFCK output enable is not a function of PWR_FAULT. 1 – REFCK output enable is a function of PWR_FAULT. This field is loaded from EEPROM (if present) and reset with PERST. PCI Hot Plug capable. This bit indicates whether this slot is capable of PCI Hot Plug operations. This bit is used to control the PCI Hot Plug capable (HPC) field in the Slot Capabilities register. 14 SLOT_HPC rw 0 – Slot is not PCI Hot Plug capable. 1 – Slot is PCI Hot Plug capable. This field is loaded from EEPROM (if present) and reset with PERST. The default value for this bit is that of the DNn_DPSTRP pin for the associated port. PCI Hot Plug surprise. This bit indicates whether a device present in this slot can be removed from the system without prior notification. This bit is used to control the PCI Hot Plug surprise (HPS) field in the Slot Capabilities register. 13 SLOT_HPS rw 0 – No device present that can be removed without prior notification 1 – Device present that can be removed without prior notification. This field is loaded from EEPROM (if present) and reset with PERST. The default value for this bit is that of the DNn_DPSTRP pin for the associated port. 116 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-83. Bit Descriptions – General Control Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Power indicator present. This bit indicates whether a power indicator is implemented on the chassis for this slot. This bit is used to control the PIP field in the Slot Capabilities register. 12 SLOT_PIP rw 0 – Power indicator not implemented 1 – Power indicator implemented This field is loaded from EEPROM (if present) and reset with PERST. Attention indicator present. This bit indicates whether an attention indicator is implemented on the chassis for this slot. This bit is used to control the AIP field in the Slot Capabilities register. 11 SLOT_AIP rw 0 – Attention indicator not implemented 1 – Attention indicator implemented This field is loaded from EEPROM (if present) and reset with PERST. Manual retention latch sensor present. This bit indicates whether an MRL sensor is implemented on the chassis for this slot. This bit is used to control the MRLSP field in the Slot Capabilities register. 10 SLOT_MRLSP rw 0 – MRL sensor not implemented 1 – MRL sensor implemented This field is loaded from EEPROM (if present) and reset with PERST. Power controller present. This bit indicates whether a power controller is implemented for this slot to control power. This bit is used to control the power controller present (PCP) field in the Slot Capabilities register. 9 SLOT_PCP rw 0 – Power controller not implemented 1 – Power controller implemented This field is loaded from EEPROM (if present) and reset with PERST. Attention button present. This bit indicates whether an attention button is implemented on the chassis for this slot. This bit is used to control the attention button present (ABP) field in the Slot Capabilities register. 8 SLOT_ABP rw 0 – Attention button not implemented 1 – Attention button implemented This field is loaded from EEPROM (if present) and reset with PERST. Slot implemented. This bit indicates that the downstream port is connected to an add-in card slot (e.g., PCI Express, ExpressCard, etc.). This bit is used to control the SLOT bit in the PCI Express Capabilities register. 7 SLOT_PRSNT rw 0 – Port not connected to slot 1 – Port connected to slot This field is loaded from EEPROM (if present) and reset with PERST. The default value for this bit is that of the DNn_DPSTRP pin for the associated port. Power fault input present. This bit indicates whether an input pin is used as a power fault detection input for this slot. This bit is used to control whether the power fault input pin is used, e.g., for disabling the REFCLK output buffer. 6 SLOT_PFIP rw 0 – Power fault input not implemented 1 – Power fault input implemented This field is loaded from EEPROM (if present) and reset with PERST. Electromechanical interlock present. This bit indicates whether an electromechanical interlock is implemented on the chassis for this slot. This bit is used to control the EMILP field in the Slot Capabilities register. 5 SLOT_EMILP rw 0 – Electromechanical interlock not implemented 1 – Electromechanical interlock implemented This field is loaded from EEPROM (if present) and reset with PERST. Submit Documentation Feedback XIO3130 Configuration Register Space 117 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-83. Bit Descriptions – General Control Register (continued) BIT FIELD NAME ACCESS LINK_ACT_RPT_CA P 4 DESCRIPTION Link active reporting capable. This bit indicates whether this slot is capable of reporting whether the link is active. This bit is used to control the DLL_LARC field in the Link Capabilities register. This field is used to control the SDERC field in the Link Capabilities register. rw 0 – Slot is not link active reporting capable 1 – Slot is link active reporting capable This field is loaded from EEPROM (if present) and reset with PERST. 3 RSVD rw 2 RSVD r This bit is a reserved diagnostic bit that must be set to 0 for proper operation. If an EEPROM is used, the corresponding bit in the EEPROM must be set to 0. Reserved. When read, this bit returns zero. Reference clock disable. This bit is used to disable the REFCK output. 1 REFCK_DIS 0 – REFCK enabled rw 1 – REFCK disabled This field is loaded from EEPROM (if present) and reset with PERST. Receiver presence detect enable. This bit selects whether the PRSNT pin or receiver detect us used to determine whether the slot is present. 0 – PRSNT pin is used to determine whether slot is present 0 RCVR_PRSNT_EN rw 1 – Receiver detect is used to determine whether slot is present. It is recommended to only use this option when PRSNT is not available and the card is removable. This field is loaded from EEPROM (if present) and reset with PERST. The default value for this bit is the inverse of the DNn_DPSTRP pin for the associated port. 4.3.62 L0s Idle Timeout Register This read/write register controls the idle timeout for initiating L0s entry on the Tx path. The value is in units of 256 ns. The default value is set for just under 7 =s. The minimum timeout is 256 ns. This register is loaded from serial EEPROM and is reset with PERST. PCI register offset: ECh Register type: Read/Write Default value: 1Ah BIT NUMBER RESET STATE 7 0 6 0 5 0 4 1 3 1 2 0 1 1 0 0 4.3.63 General Slot Info Register This read/write register contains information that is used in the slot capabilities and control registers for the downstream port. PCI register offset: EEh Register type: Read/Write; Read Only Default value: 0000h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 Table 4-84. Bit Descriptions – General Slot Info Register BIT FIELD NAME ACCESS DESCRIPTION 15:3 SLOT_NUM rw Slot number. This field is used to program the Physical Slot Number field in the Slot Capabilities register. This field is loaded from EEPROM (if present) and reset with PERST. 2:0 RSVD r 118 Reserved. When read, these bits return zeros. XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 4.3.64 Advanced Error Reporting Capabilities ID Register This read-only register identifies the linked list item as the register for PCI Express Advanced Error Reporting Capabilities. The register returns 0001h when read. PCI register offset: 100h Register type: Read only Default value: 0001h BIT NUMBER RESET STATE 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 1 4.3.65 Next Capability Offset/Capability Version Register This read-only register returns the value 0000h to indicate that this extended capability block represents the end of the linked list of extended capability structures. The least significant four bits identify the revision of the current capability block as 1h. PCI register offset: 102h Register type: Read only Default value: BIT NUMBER RESET STATE 0000h 15 0 14 0 13 0 12 0 11 0 10 0 9 0 8 0 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 4.3.66 Uncorrectable Error Status Register This register reports the status of individual errors as they occur. Software may clear these bits only by writing a 1 to the desired location. PCI register offset: 104h Register type: Read Only, Cleared by a Write of one Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-85. Uncorrectable Error Status Register BIT FIELD NAME ACCESS 31:21 RSVD r 20 UR_ERROR rcuh Unsupported Request error. This bit is asserted when an Unsupported Request error is detected (i.e., when a request is received that results in the sending of a completion with an Unsupported Request status). 19 ECRC_ERROR rcuh Extended CRC error. This bit is asserted when an Extended CRC error is detected. 18 MAL_TLP rcuh Malformed TLP. This bit is asserted when a malformed TLP is detected. 17 RX_OVERFLOW rcuh Receiver Overflow. This bit is asserted when the flow control logic detects that the transmitting device has illegally exceeded the number of credits that were issued. 16 UNXP_CPL rcuh Unexpected Completion. This bit is asserted when a completion packet is received that does not correspond to an issued request. 15 CPL_ABORT rcuh Completer Abort. This bit is asserted when the completion to a pending request arrives with Completer Abort status. 14 CPL_TIMEOUT rcuh Completion Timeout. This bit is asserted when no completion has been received for an issued request before the timeout period. 13 FC_ERROR rcuh Flow Control error. This bit is asserted when a flow control protocol error is detected either during initialization or during normal operation. Submit Documentation Feedback DESCRIPTION Reserved. Return zeros when read. XIO3130 Configuration Register Space 119 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-85. Uncorrectable Error Status Register (continued) BIT 12 FIELD NAME ACCESS PSN_TLP DESCRIPTION Poisoned TLP. This bit is asserted when an outgoing packet (request or completion) has been poisoned by setting the poison bit and has inverted the extended CRC attached to the end of the packet. rcuh 11:6 RSVD r 5 SD_ERROR rcuh Reserved. Return zeros when read. Surprise Down error. See Surprise Down ECN for a description of this error condition. 4 DLL_ERROR rcuh Data Link Protocol error. This bit is asserted if a data link layer protocol error is detected. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r This value read from this bit is undefined. 4.3.67 Uncorrectable Error Mask Register The Uncorrectable Error Mask register controls the reporting of individual errors as they occur. When a bit is set to one, the error status bits are still affected, but the error is not logged and no error reporting message is sent upstream. PCI register offset: 108h Register type: Read Only, Read/Write Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-86. Uncorrectable Error Mask Register BIT FIELD NAME ACCESS 31:21 RSVD r 20 UR_ERROR_MASK rwh DESCRIPTION Reserved. Return zeros when read. Unsupported Request error mask. 0 - Error condition is unmasked. 1 - Error condition is masked. Extended CRC error mask. 19 ECRC_ERROR_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Malformed TLP mask. 18 MAL_TLP_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Receiver Overflow mask. 17 RX_OVERFLOW_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Unexpected Completion mask. 16 UNXP_CPL_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Completer Abort mask. 15 CPL_ABORT_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Completion Timeout mask. 14 CPL_TIMEOUT_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. 120 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-86. Uncorrectable Error Mask Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Flow Control error mask. 13 FC_ERROR_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Poisoned TLP mask. 12 PSN_TLP_MASK rwh 11:6 RSVD r 5 SD_MASK rwh 0 - Error condition is unmasked. 1 - Error condition is masked. Reserved. Return zeros when read. Surprise Down error mask. 0 - Error condition is unmasked. 1 - Error condition is masked. Data Link Protocol error mask. 4 DLL_ERROR_MASK rwh 0 - Error condition is unmasked. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r This value read from this bit is undefined. 1 - Error condition is masked. 4.3.68 Uncorrectable Error Severity Register The Uncorrectable Error Severity register controls the reporting of individual errors as ERR_FATAL or ERR_NONFATAL. When a bit is set, the corresponding error condition is identified as fatal. When a bit is clear, the corresponding error condition is identified as nonfatal. PCI register offset: 10Ch Register type: Read Only, Read/Write Default value: 0003 2030h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 1 17 1 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 1 0 0 0 0 0 0 0 1 1 0 0 0 0 Table 4-87. Uncorrectable Error Severity Register BIT FIELD NAME ACCESS 31:21 RSVD r DESCRIPTION Reserved. Return zeros when read. Unsupported Request error severity. 20 UR_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Extended CRC error severity. 19 ECRC_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Malformed TLP severity. 18 MAL_TLP_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Receiver Overflow severity. 17 RX_OVERFLOW_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Submit Documentation Feedback XIO3130 Configuration Register Space 121 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Table 4-87. Uncorrectable Error Severity Register (continued) BIT FIELD NAME ACCESS DESCRIPTION Unexpected Completion severity. 16 UNXP_CPL_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Completer Abort severity. 15 CPL_ABORT_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Completion Timeout severity. 14 CPL_TIMEOUT_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Flow Control error severity. 13 FC_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Poisoned TLP severity. 12 PSN_TLP_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. 11:6 RSVD r Reserved. Return zeros when read. 5 SD_ERROR_SEVR rwh Surprise Down error severity. 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. Data Link Protocol error severity. 4 DLL_ERROR_SEVR rwh 0 - Error condition is signaled using ERR_NONFATAL. 1 - Error condition is signaled using ERR_FATAL. 3:1 RSVD r Reserved. Return zeros when read. 0 Undefined r This value read from this bit is undefined. 4.3.69 Correctable Error Status Register The Correctable Error Status register reports the status of individual errors as they occur. Software may clear these bits only by writing a 1 to the desired location. PCI register offset: 110h Register type: Read Only, Cleared by a Write of one Default value: 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-88. Correctable Error Status Register BIT FIELD NAME ACCESS DESCRIPTION 31:14 RSVD r 13 ANFES rcuh Advisory nonfatal error status. 12 REPLAY_TMOUT rcuh Replay timer timeout. This bit is asserted when the replay timer expires for a pending request or completion that has not been acknowledged. 11:9 RSVD r 8 REPLAY_ROLL rcuh 122 XIO3130 Configuration Register Space Reserved. Return zeroes when read. Reserved. Return zeroes when read. REPLAY_NUM rollover. This bit is asserted when the replay counter rolls over when a pending request of completion has not been acknowledged. Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 Table 4-88. Correctable Error Status Register (continued) BIT FIELD NAME ACCESS DESCRIPTION 7 BAD_DLLP rcuh Bad DLLP error. This bit is asserted when an 8b/10n error is detected by the PHY during reception of a DLLP. 6 BAD_TLP rcuh Bad TLP error. This bit is asserted when an 8b/10b error is detected by the PHY during reception of a TLP. 5:1 RSVD r 0 RX_ERROR rcuh Reserved. Return zeros when read. Receiver error. This bit is asserted when an 8b/10b error is detected by the PHY at any time. 4.3.70 Correctable Error Mask Register The Correctable Error Mask register controls the reporting of individual errors as they occur. When a bit is set to one, error status bits are still affected, but the error is not logged and no error reporting message is sent upstream. PCI register offset: 114h Register type: Read Only, Read/Write Default value: 0000 2000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 4-89. Correctable Error Mask Register BIT FIELD NAME ACCESS 31:14 RSVD r 13 ANFEM rwh 12 REPLAY_TMOUT_MASK rwh 11:9 RSVD r 8 REPLAY_ROLL_MASK rwh DESCRIPTION Reserved. Return zeros when read. Advisory nonfatal error mask. This bit is set by default to enable compatibility with software that does not comprehend role-based error reporting. Replay timer timeout mask. 0 – Error condition is unmasked 1 – Error condition is masked Reserved. Return zeros when read. REPLAY_NUM rollover mask. 0 – Error condition is unmasked 1 – Error condition is masked Bad DLLP error mask. 7 BAD_DLLP_MASK rwh 0 – Error condition is unmasked 1 – Error condition is masked Bad TLP error mask. 6 BAD_TLP_MASK rwh 5:1 RSVD r 0 RX_ERROR_MASK rwh 0 – Error condition is unmasked 1 – Error condition is masked Reserved. Return zeros when read. Receiver error mask. 0 – Error condition is unmasked 1 – Error condition is masked 4.3.71 Advanced Error Capabilities and Control Register The Advanced Error Capabilities and Control register allows the system to monitor and control the advanced error reporting capabilities. PCI register offset: Submit Documentation Feedback 118h XIO3130 Configuration Register Space 123 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com Register type: Read Only, Read/Write Default value: 0000 00A0h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 1 0 0 0 0 0 1 0 1 0 0 0 0 0 Table 4-90. Advanced Error Capabilities and Control Register BIT FIELD NAME ACCESS 31:9 RSVD r 8 ECRC_CHK_EN rwh DESCRIPTION Reserved. Return zeros when read. Extended CRC check enable. 0 – Extended CRC checking is disabled 1 – Extended CRC checking is enabled Extended CRC check capable. This read-only bit returns a value of ‘1’ indicating that the bridge is capable of checking extended CRC information. 7 ECRC_CHK_CAPABLE r 6 ECRC_GEN_EN rwh Extended CRC generation enable. 0 – Extended CRC generation is disabled 1 – Extended CRC generation is enabled 5 ECRC_GEN_CAPABLE r Extended CRC generation capable. This read-only bit returns a value of ‘1’ indicating that the bridge is capable of generating extended CRC information. 4:0 FIRST_ERR rh First error pointer. This five-bit value reflects the bit position within the Uncorrectable Error Status register corresponding to the class of the first error condition that was detected. 4.3.72 Header Log Register The Header Log register stores the TLP header for the packet that lead to the most recently detected error condition. Offset 11Ch contains the first DWORD. Offset 128h contains the last DWORD (in the case of a 4DW TLP header). PCI register offset: 11Ch – 128h Register type: Read only Default value: 124 0000 0000h BIT NUMBER RESET STATE 31 0 30 0 29 0 28 0 27 0 26 0 25 0 24 0 23 0 22 0 21 0 20 0 19 0 18 0 17 0 16 0 BIT NUMBER 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 RESET STATE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 XIO3130 Configuration Register Space Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 5 PCI Hot Plug Implementation Overview 5.1 PCI Hot Plug Architecture Overview The PCI Express architecture is designed to natively support both hot-add and hot-removal (collectively Hot-Plug) of adapters. The architecture also provides a ‘toolbox’ of mechanisms that allow different user/operator models to be supported using a self-consistent infrastructure. PCI Express defines the registers necessary to support the integration of a PCI Hot Plug controller within individual root and switch ports. Under PCI Hot-Plug software control, the PCI Hot-Plug controllers and the associated port interface within the root or switch port must control the card interface signals to ensure orderly power-down and power-up as cards are removed and replaced. Table 5-1. GPIO Matrix GPIO[#] 0 PRSNT1 S PWRON1 1 2 3 4 5 6 7 6 6 8 9 10 11 6 6 14 2 2 2 15 16 2 2 5 5 3 3 6 6 S CLKREQ1 2 MRLSDET1 3 ACTLED1 PWRLED1 6 6 ATNLED1 4 4 ATNBTN1 2 2 PWRFLT1 4 4 EMILCTL1 2 4 6 PRSNT2 S PWRON2 5 5 5 2 4 2 EMILENG1 4 4 7 7 2 6 S PWRGD2 S CLKREQ2 2 MRLSDET2 6 6 3 ACTLED2 3 PWRLED2 6 7 ATNLED2 4 5 ATNBTN2 2 PWRFLT2 4 EMILCTL2 2 4 3 4 3 3 6 6 6 3 5 2 5 5 3 6 7 PRSNT3 S PWRON3 S PWRGD3 S CLKREQ3 2 MRLSDET3 7 7 7 7 ACTLED3 3 4 PWRLED3 7 ATNLED3 7 5 3 3 PWRFLT3 5 5 EMILCTL3 5 Submit Documentation Feedback 4 4 7 3 3 5 5 3 7 4 7 5 ATNBTN3 EMILENG3 13 S PWRGD1 EMILENG2 12 5 4 7 7 7 3 7 PCI Hot Plug Implementation Overview 125 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com In Table 2-11, S indicates a strapping option. If the appropriate DNn_DPSTRP pin is pulled high, the GPIO is mapped to this value and is no longer mapped by the GPIO Control register. Each downstream port of the XIO3130 is assigned one dedicated sideband pin, DNn_PERST. Three additional sideband pins may be dedicated to each port for PCI Hot Plug support. The DNn_DPSTRP pins are set for the corresponding ports to indicate support for PCI Hot Plug. When the DNn_DPSTRP pin strapping defines a GPIO pin as a PCI Hot Plug support pin, that pin is associated with the Slot Capability, Slot Status, and Slot Control registers of the corresponding downstream port. These registers are defined in sections Section 4.3.55, Section 4.3.56, and Section 4.3.57, respectively. When the DPSTRP[2:0] pin strapping defines a GPIO pin as a GPIO pin, that pin is mapped to a bit field in the GPIO Configuration registers and Data register. These registers are defined in section Section 4.2.61 through Section 4.2.65. Table 5-2. PCI Hot Plug Sideband Signals Signal I/O Function Dn_PERST O Port n PE Reset. The PCI Hot Plug card or device is held in a reset state when this signal is low. PRSNTn I PWRONn O Port n Power On. Power is applied to the PCI Hot Plug card or device attached to the port when this signal is low. PWRGDn I Port n Power Good: The power to the PCI Hot Plug card or device is adequate and it is alright to enable REFCLK to the card or device and de-assert DNn_PERST. When this signal transitions to a low state, the XIO3130 switch asserts DNn_PERST low and turns off REFCLK. Port n Present. A PCI Hot Plug card or device is attached to a port when this signal is low. This signal is reported in the PDC bit of the Slot Status register. When this signal is in a de-asserted high state, the DNn_PERST pin is asserted low, REFCLK is disabled, and PWRONn is de-asserted high. Additional GPIO pins may be allocated to PCI Hot Plug support via programming by assigning the pins to PCI Hot Plug pin functionality in the GPIO Control registers defined in sections Section 4.2.62 through Section 4.2.65. Table 5-3. Pins Assigned to GPIO Control Registers Signal I/O Function CLKREQn I Port n CLK REQ. This signal is used to disable the clock during normal operation. If PWRONn is high or PRSNTn is high or PWRGDn is low, this signal is ignored by the XIO3130. ACT_LEDn O Port n Activity. This pin toggles at anytime activity is detected on the port interface. Otherwise, this pin is high. PWR_LEDn O Port n Power Indicator: See PI_CTL bit field in Slot Control register (section Section 4.3.56). ATN_LEDn O Port n Attention Indicator: See AI_CTL bit field in Slot Control register (section Section 4.3.56). ATN_BTNn I Port n Attention Push button: See ABP bit field in Slot Status register (section Section 4.3.57). MRLS_DETn I Port n Manually-Operated Retention Latch (MRL): See MRLSS bit field in Slot Status register (section Section 4.3.57). EMIL_CTLn O Port n Electromechanical Interlock: See EMIL_CTL bit field in Slot Control register (section Section 4.3.56). EMIL_ENGn I Port n Electromechanical Interlock status: See EMIL_STAT bit field in Slot Status register (section Section 4.3.57). 5.2 5.2.1 PCI Hot Plug Timing Power-Up Cycle The XIO3130 switch can be powered up numerous ways depending on the way the DPSTRP[2:0] strapping defines the port. The different power-up cycles are: nonPCI Hot Plug power-up cycle, PCI Hot Plug power-up cycle with PWRGDn feedback, and PCI Hot Plug power-up cycle without PWRGDn feedback. 126 PCI Hot Plug Implementation Overview Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 5.2.1.1 NonPCI Hot Plug Power-Up Cycle For nonPCI Hot Plug power-up cycles, there are no PWRONn, PWRGDn, or PRSNTn signals, and the Slot Control register is not used to power the port up. As soon as the REFCLKn output is stable on the port, the PERSTn signal is de-asserted high. If no device is detected on the port before Link Training times out, the PERSTn signal is asserted low and REFCLKn is disabled. PERST# PERSTn# REFCLKn Unstable Stable <100 ms Figure 5-1. NonPCI Hot Plug Power-Up Cycle 5.2.1.2 PCI Hot Plug Power-Up Cycle With PWRGDn Feedback For PCI Hot Plug power up cycles with PWRGDn feedback, the PWRONn signal going low gates the power-up cycle. The XIO3130 switch asserts PWRONn and waits for the PWRGDn signal to transition high, indicating that power to the slot is now stable. When PWRGDn goes high, REFCLKn is enabled and a 100 ms time-out starts. After the 100 ms time-out completes, PERSTn is de-asserted. If the port has been programmed (see GPIO Control Registers in sections Section 4.2.61 through Section 4.2.64) to have a CLKREQn input when PERSTn de-asserts high, REFCLKn is disabled when CLKREQn is not low. PWRONn# PWRGDn CLKREQn# REFCLKn Unstable Stable PERSTn# >100 ms 100 ms Figure 5-2. PCI Hot Plug Power-Up Cycle With PWFRDn Feedback 5.2.1.3 PCI Hot Plug Power-Up Cycle With No PWRGDn Feedback This application requires the PWRGDn signal to be tied high. The PWRONn signal going low gates the power-up cycle. The XIO3130 switch asserts PWRONn and because the PWRGDn signal is tied high, the power-up cycle starts as soon as PWRONn is asserted. After 100 ms, REFCLKn is enabled, and a 100 ms time-out starts. After the 100 ms time-out completes, PERSTn is de-asserted. If the port has been programmed (see GPIO Control registers in sections Section 4.2.61 through Section 4.2.64) to have a CLKREQn input when PERSTn de-asserts high, REFCLKn is disabled when CLKREQn is not low. Submit Documentation Feedback PCI Hot Plug Implementation Overview 127 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com PWRONn# PWRGDn CLKREQn# REFCLKn Unstable Stable PERSTn# 100 ms >100 ms 100 ms Figure 5-3. PCI Hot Plug Power-Up Cycle With No PWGRDn Feedback 5.2.2 Power-Down Cycles Various conditions cause the assertion of PERSTn, which also cause REFCLKn to stop a short time later. 5.2.2.1 Normal Power-Down For PCI Hot Plug ports, other conditions may also power-down the port. Software can power the port down by de-asserting the PC_CTL bit in the Slot Control register. This invokes a normal power-down cycle, which is the same power-down cycle invoked by the upstream PERST being asserted. PWRONn# PWRGDn CLKREQn# REFCLKn Stable PERSTn# < 100 ms Figure 5-4. Normal Power-Down 128 PCI Hot Plug Implementation Overview Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 5.2.2.2 Surprise Removal Another PCI Hot Plug Port power-down condition occurs when the PRSNTn pin is de-asserted, indicating that the card or device has been removed without warning (i.e., surprise removal). PRSNTn# PWRONn# CLKREQn# Stable REFCLKn PERSTn# PWRGDn <500 ns <100 ms Figure 5-5. Surprise Removal In the case of surprise removal, the XIO3130 switch de-asserts PERST within 500 ns after a de-bounced PRSNTn de-asserted state exists. Then REFCLKn is disabled, and the PWRONn signal is de-asserted within 100 µs. 5.2.2.3 PWRGDn De-Assertion Another situation that forces a PCI Hot Plug port to power-down is the de-assertion of PWRGDn. If PWRGDn is de-asserted, the XIO3130 switch disables REFCLKn but does not de-assert PWRONn. PWRGDn PWRONn# CLKREQn# REFCLKn Stable Unstable Stable PERSTn# <500 ns 100 ms >100 ms Figure 5-6. Effect When PWFRGn Goes Low Note that once PERSTn goes low, it must remain low for at least 100 ms. 5.2.3 PMI_Turn_Off and PME_To_Ack Messages For information on the PME_Turn_Off and PME_To_Ack messages, see section Section 3.2.6. Submit Documentation Feedback PCI Hot Plug Implementation Overview 129 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 5.2.4 www.ti.com Debounce Circuits Integrated de-bounce circuits are provided for the following input pins: • PRSNT[2:0] present detects for each downstream port; used with PCI Express or ExpressCard (formerly NEWCARD) slots. • ATN_BTN[2:0], which are attention button inputs, are MUXed onto GPIO pins; de-bounce is only needed when the relevant GPIO pins are programmed to this mode. • MRLS_DET[2:0], which are manual retention latch detection inputs, are MUXed onto GPIO pins; de-bounce is only needed when the relevant GPIO pins are programmed to this mode. A timeout of approximately 10 ms is used. 5.2.5 HP_INTX Pin The HP_INTX output signal is asserted when a PCI Hot Plug interrupt occurs within the switch, but only asserted due to PCI Hot Plug events. This signal is typically be connected on system boards to an SCI (System Control Interrupt) input, which invokes an interrupt service routine included in the system BIOS; other system implementations may connect HP_INTX to a PCI bus interrupt pin. 130 PCI Hot Plug Implementation Overview Submit Documentation Feedback XIO3130 www.ti.com 6 SLLS693D – MAY 2007 – REVISED AUGUST 2008 Electrical Characteristics This chapter describes the electrical characteristics of the XIO3130. Absolute Maximum Ratings (1) 6.1 over operating free-air temperature range (unless otherwise noted) VDDRC, VAUX33REF, VDD33REF VDDAREF, VDDA, VDDD, VDD15 Input voltage range VO Output voltage range (2) (3) V –0.5 to 1.65 V –0.6 to 0.6 V –0.5 to VDD_15 V Miscellaneous 3.3 – VIO –0.5 to VDD_33 V PCI Express (PET) –0.5 to VDD_15 V PCI Express REFCKO –0.5 to VDD_15 V Miscellaneous 3.3 – VIO –0.5 to VDD_33 V ±20 mA ±20 mA –65 to 150 °C Output clamp current, (VO < 0 or VO > VDD) (3) (1) –0.5 to 3.6 PCI Express REFCKI (differential) Input clamp current, (VI < 0 or VI > VDD) (2) Tstg UNIT Supply voltage range PCI Express (PER) VI VALUE Storage temperature range Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute–maximum–rated conditions for extended periods may affect device reliability. Applies to external input. VI < 0 or VI > VDD. Applies to external output. VO < 0 or VO > VDD. 6.2 Recommended Operating Conditions OPERATION MIN NOM MAX UNIT Supply voltage 1.5 V 1.35 1.5 1.65 V Supply voltage 3.3 V 3 3.3 3.6 V VDDD VDD15 VDDAREF VDDA VDDRC VDD33 VAUX33REF VDD33REF TA Operating ambient temperature range 0 25 70 °C TJ Virtual junction temperature (1) 0 25 115 °C (1) The junction temperature reflects simulated conditions. The customer is responsible for verifying junction temperature. Submit Documentation Feedback Electrical Characteristics 131 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 6.3 www.ti.com PCI Express Differential Transmitter Output Ranges PARAMETER TERMINALS MIN UI Unit interval PETP, PETN 399.88 VTX-DIFFp-p Differential peak-to-peak output voltage PETP, PETN 0.8 VTX-DE-RATIO De-emphasized differential output voltage (ratio) PETP, PETN –3 TTX-EYE Minimum TX eye width PETP, PETN 0.75 NOM UNIT COMMENTS 400 400.12 ps Each UI is 400 ps ±300 ppm. UI does not account for SSC dictated variations.See (1) 1.2 V VTX-DIFFp-p = 2*|VTXP – VTXN|. See (2) dB This value is the ratio of the VTX-DIFFp-p of the second and following bits after a transition divided by the VTX-DIFFp-p of the first bit after a transition. See (2) UI The maximum transmitter jitter can be derived as TTXMAX- JITTER = 1 – TTX-EYE = 0.25 UI. See (2) (3) UI Jitter is defined as the measurement variation of the crossing points (VTX-DIFFp-p = 0 V) in relation to recovered TX UI. A recovered TX UI is calculated over 3500 consecutive UIs of sample data. Jitter is measured using all edges of the 250 consecutive UIs in the center of the 3500 UIs that are used for calculating the TX UI. See (2) (3) UI See mV VTX-CM-ACp = RMS(|VTXP + VTXN|/2 – VTX-CM-DC) VTX-CM-DC = DC(avg) of |VTXP + VTXN|/2 See (2) –3.5 MAX –4.0 TTX-EYE-MEDIAN-to-MAX-JITTER Maximum time between the jitter median and maximum deviation from the median PETP, PETN TTX-RISE, TTX-FALL Differential TX output rise/fall time PETP, PETN VTX-CM-ACp RMS ac peak common mode output voltage PETP, PETN VTX-CM-DC-ACTIVE-IDLE-DELTA Absolute delta of DC common mode voltage during L0 and electrical idle. PETP, PETN 0 100 mV |VTX-CM-DC – VTX-CM-IDLE-DC| ≤ 100 mV VTX-CM-DC = DC(avg) of |VTXP + VTXN|/2 [during L0] VTX-CM-IDLE-DC = DC(avg) of |VTXP + VTXN|/2 [during electrical idle] See (2) VTX-CM-DC-LINE-DELTA Absolute delta of DC common mode voltage between P and N PETP, PETN 0 25 mV |VTXP-CM-DC – VTXN-CM-DC| ≤ 25 mV when VTXP-CM-DC = DC(avg) of |VTXP| VTXN-CM-DC = DC(avg) of |VTXN| See (2) VTX-IDLE-DIFFp Electrical idle differential peak output voltage PETP, PETN 0 20 mV VTX-IDLE-DIFFp = |VTXP-IDLE – VTXN-IDLE| ≤ 20 mV See (2) VTX-RCV-DETECT The amount of voltage change allowed during receiver detection PETP, PETN 600 mV The total amount of voltage change that a transmitter can apply to sense whether a low impedance receiver is present. VTX-DC-CM The TX DC common mode voltage PETP, PETN 3.6 V ITX-SHORT TX short circuit current limit PETP, PETN 90 mA The total current that the transmitter can provide when shorted to its ground. TTX-IDLE-MIN Minimum time spent in electrical idle PETP, PETN UI Minimum time that a transmitter must be in electrical Idle. The receiver uses this value to start looking for an electrical idle exit after successfully receiving an electrical idle ordered set. TTX-IDLE-SET-to-IDLE Maximum time to transition to a valid electrical idle after sending an electrical idle ordered set PETP, PETN UI After sending an electrical idle ordered set, the transmitter must meet all electrical idle specifications within this time. This is considered a de-bounce time for the transmitter to meet electrical idle after transitioning from L0. (1) (2) (3) (4) 132 0.125 0.125 20 0 50 20 (2) (4) The allowed DC common mode voltage under any condition No test load is necessarily associated with this value. Specified at the measurement point into a timing and voltage compliance test load and measured over any 250 consecutive TX UIs. A TTX-EYE = 0.75 UI provides for a total sum of deterministic and random jitter budget of TTX-JITTER-MAX = 0.25 UI for the transmitter collected over any 250 consecutive TX UIs. The TTX-EYE-MEDIAN-to-MAX-JITTER specification ensures a jitter distribution in which the median and the maximum deviation from the median is less than half of the total TX jitter budget collected over any 250 consecutive TX UIs. It must be noted that the median is not the same as the mean. The jitter median describes the point in time where the number of jitter points on either side is approximately equal as opposed to the averaged time value. Measured between 20% and 80% at transmitter package terminals into a test load for both VTX-D+ and VTX-D–. Electrical Characteristics Submit Documentation Feedback XIO3130 www.ti.com SLLS693D – MAY 2007 – REVISED AUGUST 2008 PCI Express Differential Transmitter Output Ranges (continued) PARAMETER TERMINALS MIN NOM MAX UNIT COMMENTS UI Maximum time to meet all TX specifications when transitioning from electrical idle to sending differential data. This value is considered a de-bounce time for the TX to meet all TX specifications after leaving electrical idle. 10 dB Measured over 50 MHz to 1.25 GHz. See (5) PETP, PETN 6 dB Measured over 50 MHz to 1.25 GHz. See (5) ZTX-DIFF-DC DC differential TX impedance PETP, PETN 80 Ω TX DC differential mode low impedance ZTX-DC Transmitter DC impedance PETP, PETN 40 Ω Required TX-D+ as well as TX-D– DC impedance during all states CTX AC coupling capacitor PETP, PETN 75 nF All transmitters are AC-coupled and capacitors are required on the PWB. TTX-IDLE-to-DIFF-DATA Maximum time to transition to valid TX specifications after leaving an electrical idle condition PETP, PETN RLTX-DIFF Differential return loss PETP, PETN RLTX-CM Common mode return loss (5) 6.4 20 100 120 200 The transmitter input impedance results in a differential return loss greater than or equal to 12 dB and a common mode return loss greater than or equal to 6 dB over a frequency range of 50 MHz to 1.25 GHz. This input impedance requirement applies to all valid input levels. The reference impedance for return loss measurements is 50 Ω to ground for both the P and N lines. Note that the series capacitors CTX is optional for the return loss measurement. PCI Express Differential Receiver Input Ranges PARAMETER VRX-DIFFp-p Differential input peak-to-peak voltage TRX-EYE Minimum receiver eye width TERMINALS PERP, PERN PERP, PERN MIN 0.175 NOM MAX 1.2 0.4 UNIT COMMENTS V VRX-DIFFp-p = 2*|VRX-D+ – VRX-D–| See (1) UI The maximum interconnect media and transmitter jitter that can be tolerated by the Receiver is derived as TRX-MAX- JITTER = 1 - TRX-EYE = .6 UI See (1) (2) (3) TRX-EYE-MEDIAN-to-MAX-JITTER Maximum time between the jitter median and maximum deviation from the median. PERP, PERN 0.3 UI Jitter is defined as the measurement variation of the crossing points (VRX-DIFFp-p = 0 V) in relation to recovered TX UI. A recovered TX UI is calculated over 3500 consecutive unit intervals of sample data. Jitter is measured using all edges of the 250 consecutive UI in the center of the 3500 UI used for calculating the TX UI. See (1) (2) VRX-CM-ACp AC peak common mode input voltage PERP, PERN 150 mV VRX-CM-ACp = RMS( |VRX-D+ + VRX-D–| / 2 – VRX-CM-DC) VRX-CM-DC = DC(avg) of |VRX-D+ + VRX-D-| / 2 See (1) (1) (2) (3) Specified at the measurement point and measured using the clock recovery function specified in PCI Express™ Base Specification Revision 1.1, Section 4.3.3.2. The test load in Figure 4-25 should be used as the RX device when taking measurements (also refer to the Receiver compliance eye diagram shown in Figure 4-26 of the specification). If the clocks to the RX and TX are not derived from the same reference clock, the TX UI recovered using the clock recovery function specified in Section 4.3.3.2 must be used as a reference for the eye diagram. The TRX-EYE-MEDIAN-to-MAX-JITTER specification ensures a jitter distribution in which the median and the maximum deviation from the median is less than half of the total 0.64. It should be noted that the median is not the same as the mean. The jitter median describes the point in time where the number of jitter points on either side is approximately equal as opposed to the averaged time value. The RX UI recovered using the clock recovery function specified in Section 4.3.3.2 must be used as the reference for the eye diagram. This parameter is measured with the equivalent of a zero jitter reference clock. The TRX-EYE measurement is to be met at the target bit error rate. The TRX-EYE-MEDIAN-to-MAX-JITTER specification is to be met using the compliance pattern at a sample size of 1,000,000 UI. See the PCI Express Jitter and BER white paper for more details on the Rx-Eye measurement. Submit Documentation Feedback Electrical Characteristics 133 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com PCI Express Differential Receiver Input Ranges (continued) PARAMETER TERMINALS MIN NOM MAX UNIT COMMENTS RLRX-DIFF Differential return loss PERP, PERN 10 dB Measured over 50 MHz to 1.25 GHz with the P and N lines biased at +300 mV and –300 mV, respectively. See (4) RLRX-CM Common mode return loss PERP, PERN 6 dB Measured over 50 MHz to 1.25 GHz with the P and N lines biased at +300 mV and –300 mV, respectively. See (4). ZRX-DIFF-DC DC differential input impedance PERP, PERN 80 100 120 Ω RX DC differential mode impedance. See (5). ZRX-DC DC input impedance PERP, PERN 40 50 60 Ω Required RX-D+ as well as RX-D– DC impedance (50 Ω ±20% tolerance). See (1) and (5). ZRX-HIGH-IMP-DC Powered-down DC input impedance PERP, PERN 200K Ω Required RX-D+ as well as RX-D– DC impedance when the receiver terminations do not have power. See (6). VRX-IDLE-DET-DIFFp-p Electrical idle detect threshold PERP, PERN 65 TRX-IDLE-DET-DIFF-ENTER-TIME Unexpected electrical idle enter detect threshold integration time PERP, PERN (4) (5) (6) 6.5 VRX-IDLE-DET-DIFFp-p = 2 * |VRX-D+ – VRX-D–| measured at the receiver package pins ms An unexpected electrical idle (VRX-DIFFp-p < VRX-IDLE-DET-DIFFp-p) must be recognized no longer than TRX-IDLE-DET-DIFF-ENTER-TIME to signal an unexpected idle condition. PCI Express Differential Reference Clock Input Ranges (1) TERMINALS fIN-DIFF Differential input frequency REFCKIp REFCKIn VRX-DIFFp-p Differential input peak-to-peak voltage REFCKIp REFCKIn VRX-CM-ACp AC peak common mode input voltage REFCKIp REFCKIn Duty cycle REFCKIp REFCKIn ZRX-DIFF-DC DC differential input impedance REFCKIp REFCKIn 134 10 mV The Receiver input impedance shall result in a differential return loss greater than or equal to 10 dB with a differential test input signal of no less than 200 mV (peak value, 400 mV differential peak to peak) swing around ground applied to D+ and D– lines and a common mode return loss greater than or equal to 6 dB (no bias required) over a frequency range of 50 MHz to 1.25 GHz. This input impedance requirement applies to all valid input levels. The reference impedance for return loss measurements for is 50 Ω to ground for both the D+ and D– line (i.e., as measured by a Vector Network Analyzer with 50 Ω probes; see Figure 4-25 in the specification). Note that the series capacitors CTX is optional for the return loss measurement. Impedance during all LTSSM states. When transitioning from a Fundamental Reset to Detect (the initial state of the LTSSM) there is a 5 ms transition time before receiver termination values must be met on all unconfigured lanes of a port. The RX DC common mode impedance that exists when no power is present or Fundamental Reset is asserted. This helps ensure that the Receiver Detect circuit does not falsely assume a receiver is powered on when it is not. This term must be measured at 200 mV above the RX ground. PARAMETER (1) 175 MIN NOM MAX 100 0.175 40% UNIT MHz 1.2 V 140 mV 60% 20 COMMENTS The input frequency is 100 MHz +300 ppm and –2800=ppm including SSC-dictated variations. VRX-DIFFp-p = 2*|VREFCKp – VREFCKn| VRX-CM-ACp = RMS(|VREFCKp + VREFCKn|/2 – VRX-CM-DC) VRX-CM-DC = DC(avg) of |VREFCKp + VREFCKn|/2 Differential waveform input duty cycle kΩ REFCKIp/ REFCKIn DC differential mode impedance The XIO3130 is compliant with the defined system jitter models for a PCI Express reference clock and associated TX/RX link. These system jitter models are described in the PCI Express Jitter Modeling, Revision 1.0RD document. Any usage of the XIO3130 in a system configuration that does not conform to the defined system jitter models requires the system designer to validate the system jitter budgets. Electrical Characteristics Submit Documentation Feedback XIO3130 www.ti.com 6.6 SLLS693D – MAY 2007 – REVISED AUGUST 2008 PCI Express Reference Clock Output Requirements SYMBOL Rise Edge Rate PARAMETER Rising edge rate 100-MHz INPUT MIN MAX 0.6 4 Fall Edge Rate Falling edge rate 0.6 VIH Differential input high voltage 150 VIL Differential input low voltage VCROSS Absolute crossing point voltage RCROSS DELTA VRB Variation of VCROSS over all rising clock edges Ring-back voltage margin TSTABLE TPERIOD TPERIOD 250 Time before VRB is allowed –100 UNIT NOTES See (1) V/ns See (1) mV See (1) –150 mV See (1) 550 mV See Notes (3) (4) , and (5) (3) (4) , and (6) 4 V/ns and (2) and (2) . mV See Notes 100 mV See (1) See (1) ps ppm . . 140 500 . AVG Average clock period accuracy –300 2800 ABS Absolute period (including jitter and spread spectrum) 9.847 10.203 ns See (1) , , and (7) and (7) See Notes . (1) (8) , , and and (10) 150 ps See (1) VMAX Absolute maximum input voltage 1.15 V See (3) and (11) VMIN Absolute minimum input voltage –0.3 V See (3) and (12) Duty cycle Rising edge rate (REFCKOp) to falling edge rate (REFCKOn) matching ZC-DC Clock source DC impedance (1) (2) (3) (4) (5) (6) (7) (8) (9) (10) (11) (12) (13) (14) 40 40 (9) . . Cycle-to-cycle jitter Rise-Fall Matching . . TCCJITTER Duty Cycle . . . . 60 % See (1) 20 % See (3) and (13) 60 Ω See (3) and (14) . . . Measurement taken from differential waveform. Measured from –150 mV to +150 mV on the differential waveform (derived from REFCKOp minus REFCKOn). The signal must be monotonic through the measurement region for rise and fall time. The 300 mV measurement window is centered on the differential zero crossing. Measurement taken from single-ended waveform. Measured at crossing point where the instantaneous voltage value of the rising edge of REFCKOp equals the falling edge of REFCKOn. Refers to the total variation from the lowest crossing point to the highest, regardless of which edge is crossing. Refers to all crossing points for this measurement. Defined as the total variation of all crossing voltages of rising REFCKOp and falling REFCKOn. This is the maximum allowed variance in VCROSS for any particular system. TSTABLE is the time the differential clock must maintain a minimum ±150 mV differential voltage after rising/falling edges before it is allowed to droop back into the VRB ±100 mV differential range. Refer to Section 4.3.2.1 of the PCI Express Base Specification, Revision 1.1 for information regarding PPM considerations. PPM refers to parts per million and is a DC absolute period accuracy specification. 1 PPM is 1/1,000,000th of 100.000000 MHz exactly or 100 Hz. For 300 PPM then we have a error budget of 100 Hz/PPM * 300 PPM = 30 kHz. The period is to be measured with a frequency counter with measurement window set to 100 ms or greater. The ±300 PPM applies to systems that do not employ Spread Spectrum or that use common clock source. For systems employing Spread Spectrum there is an additional 2500 PPM nominal shift in maximum period resulting from the 0.5% down spread resulting in a maximum average period specification of +2800 PPM. Defines as the absolute minimum or maximum instantaneous period. This includes cycle to cycle jitter, relative PPM tolerance, and spread spectrum modulation. Defined as the maximum instantaneous voltage including overshoot. Defined as the minimum instantaneous voltage including undershoot. Matching applies to rising edge rate for REFCKOp and falling edge rate for REFCKOn. It is measured using a ±75 mV window centered on the median cross point where REFCKOp rising meets REFCKOn falling. The median cross point is used to calculate the voltage thresholds the oscilloscope is to use for the edge rate calculations. The Rise Edge Rate of REFCKOp should be compared to the Fall Edge Rate of REFCKOn, the maximum allowed difference should not exceed 20% of the slowest edge rate. System board compliance measurements must use the recommended test load card. REFCKOp and REFCKOn are to be measured at the load capacitors CL. Single ended probes must be used for measurements requiring single ended measurements. Either single ended probes with math or differential probe can be used for differential measurements. Test load CL = 2 pF. Submit Documentation Feedback Electrical Characteristics 135 XIO3130 SLLS693D – MAY 2007 – REVISED AUGUST 2008 www.ti.com 3.3-V I/O Electrical Characteristics (1) 6.7 MIN MAX UNIT VIH High-level input voltage (See PARAMETER (2) ) VDD33 0.7 VDD33 VDD33 V VIL Low-level input voltage (See (2) ) VDD33 0 0.3 VDD33 V VI Input voltage 0 VDD33 V VO Output voltage (See 0 VDD33 V tπ Input transition time (trise and tfall) 0 25 ns Vhys Input hysteresis (See 0.13 VDD33 V VOH High-level output voltage VDD33 IOH = –4 mA VOL Low-level output voltage VDD33 IOL = 4 mA IOZ High-impedance, output current (See VDD33 IOZP High-impedance, output current with internal pullup or pulldown resistor (See (5)) II Input current (See (1) (2) (3) (4) (5) (6) OPERATIONS TEST CONDITIONS (3) ) (4) ) (3) ) (6) ) 0.8 VDD33 V 0.22 VDD33 V VI = 0 to VDD33 ±20 µA VDD33 VI = 0 to VDD33 ±100 µA VDD33 VI = 0 to VDD33 ±1 µA This table applies to PERST, WAKE, REFCLK_SEL, GRST, and GPIO18:0. Applies to external inputs and bidirectional buffers. Applies to external outputs and bidirectional buffers. Applies to PERST and GRST. Applies to GRST (pullup resistor) and most GPIO (pullup resistor). Applies to external input buffers. POWER CONSUMPTION (1) 6.8 NOM (2) MAX (3) I3.3V 11.21 20.61 mA I1.5V 578.7 725.8 mA PARAMETER MIN UNIT P3.3V 36.99 68.01 mW P1.5V 868.05 1088.7 mW IAUX (4) (1) (2) (3) (4) 136 5.28 mA Measurements taken at 25°C with nominal power supply, 3.3 V and 1.5 V. Nominal conditions are defined as switch only power, no devices downstream, and downstream clocks not running. Maximum power conditions are defined as three downstream devices constantly running traffic and downstream clocks running. Measurement performed with three devices downstream, system in S5. Electrical Characteristics Submit Documentation Feedback PACKAGE OPTION ADDENDUM www.ti.com 25-Sep-2008 PACKAGING INFORMATION Orderable Device Status (1) XIO3130ZHC ACTIVE Package Type BGA MI CROSTA R Package Drawing ZHC Pins Package Eco Plan (2) Qty 196 126 Green (RoHS & no Sb/Br) Lead/Ball Finish SNAGCU MSL Peak Temp (3) Level-3-260C-168 HR (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. 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