Intel Switch IXF1104 User Manual

Transmit and Global Configuration

Renamed and modified T a ble 121 “RX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x594 –

0x597)”

[old register name: RX FIFO Number of Frames Removed Ports 0 to 3; renamed bit names to

match register names; removed “This register gets updated after one cycle of sw reset is applied”

under Description].

Modified T able 123 “RX FIFO Errored Frame Drop Enable ($0x59F)” [renamed bit names to match

195

197

Renamed/modified T a ble 125 “RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2 - 0x5A5)”

on page 197 [older register name: RX FIFO Dropped Packet Counter for Ports 0 to 3; renamed bit

names to match register name].

Modified T able 126 “RX FIFO SPI3 Loopback Enable for Ports 0 - 3 ($0x5B2)” [renamed heading

and bit name; changed description and type for bits 7:0].

198

200

Renamed T a ble 128 “RX FIFO Transfer Threshold Port 0 ($0x5B8)” on page 200 [from “RX FIFO

Jumbo Packet Size; changed bit names and edited/added text under description].

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Revision Date: March 25, 2004

(Sheet 5 of 5)

Page # Description

Modified T a ble 136 “Loop RX Data to TX FIFO (Line-Side Loopback) Ports 0 - 3 ($0x61F)”

[renamed heading and bit name].

206

207

Modified T a ble 138 “TX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x621 – 0x624)”

[renamed from TX FIFO Number of Frames Removed Ports 3 - 0].

Modified T able 139 “TX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x625 – 0x629)” [renamed

from TX FIFO Number of Dropped Packets Ports 0-3 and text under the description].

Modified T a ble 141 “TX FIFO Port Drop Enable ($0x63D)” [changed description for bits 3:0].

Modified T a ble 142 “MDIO Single Command ($0x680)” [changed default; changed description and

default for bits 9:8; changed default for bits 4:0].

Modified T a ble 144 “Autoscan PHY Address Enable ($0x682)” [added note to register description].

Modified T a ble 146 “SPI3 Transmit and Global Configuration ($0x700)” [broke out bits 19:16, 7:4,

and 3:0 and changed description text].

Modified T a ble 147 “SPI3 Receive Configuration ($0x701)” [broke out bits and modified all text

adding SPHY and MPHY modes].

214

220

Modified T a ble 152 “Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)” [deleted

second paragraph of the Register Description; renamed bits to match caption; changed text under

Description].

221

Added note under Section 8.4.11, “Optical Module Register Overview”.

Modified T a ble 153 “Optical Module Status Ports 0-3 ($0x799)” [edited register description].

Modified T a ble 154 “Optical Module Control Ports 0 - 3 ($0x79A)” [changed register description].

Removed/Reserved Table 190 “TX and RX AC/DC Coupling Selection ($7x780)”.

Deleted old Figure 19, “Typical GBIC Module Functional Diagram” under Section 5.7, “Optical

Module Interface”.

Removed old Section 5.1.1.5, “Pause Command Frames.”

Removed old Table 13. TX FIFO Mini Frame Size for MAC and Padding Enable Port 0 to 3 Register

(Addr: 0x63E) and replaced with Reserved.

180(old)

Revision Number: 006

Revision Date: August 21, 2003

(Sheet 1 of 2)

Page #

Description

Modified Table 1 “Intel^®IXF1104 Signal Descriptions”

Modified Section 5.1.1.1, “Padding of Undersized Frames on Transmit”.

Modified text for etherStatsCollision in Table 9 “RMON Additional Statistics”.

Modified Table 17 “Intel^®IXF1104-to-Optical Module Interface Connections”

Modified first paragraph under Section 5.3.1.2, “Clock Rates”.

Modified Section 5.8.2.1, “High-Speed Serial Interface”.

100

110

113

119

125

Modified Figure 27 “Microprocessor — External and Internal Connections”.

Changed PECL to LVDS under Section 6.1, “DC Specifications”.

Modified table note 4 in Table 32 “SPI3 Receive Interface Signal Parameters”.

Modified Table 37 “SerDes Timing Parameters”.

Modified Table 40 “Microprocessor Interface Write Cycle AC Signal Parameters”.

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Contents

Revision Number: 006

Revision Date: August 21, 2003

(Sheet 2 of 2)

Page #

Description

Modified Table 53 “IPG Receive and Transmit Time Register (Addr: Port_Index + 0x0A – +

0x0C)”.

140

143

145

148

163

164

169

170

171

172

Modified Table 60 “Short Runts Threshold Register (Addr: Port_Index + 0x14)”.

Modified Table 61 “Discard Unknown Control Frame Register (Addr: Port_Index + 0x15)”.

Modified Table 62 “RX Config Word Register Bit Definition (Addr: Port_Index + 0x16)”.

Modified Table 64 “DiverseConfigWrite Register (Addr: Port_Index + 0x18)”.

Modified Table 67 “RX Statistics Registers (Addr: Port_Index + 0x20 – + 0x39)”.

Modified Table 82 “Microprocessor Interface Register (Addr: 0x508)”.

Modified Table 84 “LED Flash Rate Register (Addr: 0x50A)”.

Modified Table 93 “RX FIFO Errored Frame Drop Enable Register (Addr: 0x59F)”.

Modified Table 96 “RX FIFO Loopback Enable for Ports 0 - 3 Register (Addr: 0x5B2)”.

Added Table 98 “RX FIFO Jumbo Packet Size 0-3 Register (Addr: 0x5B8 – 0x5BB”.

Added Table 99 “RX FIFO Jumbo Packet Size Port 0 Register Bit Definitions (Addr: 0x5B8)”.

Added Table 100 “RX FIFO Jumbo Packet Size Port 1 Register Bit Definitions (Addr: 0x5B9)”.

Added Table 101 “RX FIFO Jumbo Packet Size Port 2 Register Bit Definitions (Addr: 0x5BA)”.

Added Table 102 “RX FIFO Jumbo Packet Size Port 3 Register Bit Definitions (Addr: 0x5BB)”.

Modified Table 110 “TX FIFO Number of Dropped Packets Register Ports 0-3 (Addr: 0x625 –

0x629)”.

178

177

Modified Table 108 “TX FIFO Port Reset Register (Addr: 0x620)”.

Modified Table 107 “Loop RX Data to TX FIFO Register Ports 0 - 3 (Addr: 0x61F)”.

Added Table 111 “TX FIFO Occupancy Counter for Ports 0 - 3 Registers (Addr: 0x62D –

0x630)”.

179

180

181

186

194

Added Table 112 “TX FIFO Port Drop Enable Register (Addr: 0x63D)”.

Modified Table 114 “MDI Single Command Register (Addr: 0x680)”.

Added Table 122 “Tx and Rx Power-Down Register (Addr: 0x787)”.

Replaced Figure 53 “Intel^®IXF1104 Example Package Marking”.

Revision 005

Revision Date: April 30, 2003

Page #

Description

Initial external release.

Revisions 001 through 004

Revision Date: April 2001 – December 2002

Page #

Description

Internal releases.

Datasheet

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Contents

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

1.0

Introduction

This document contains information on the Intel^®IXF1104 4-Port 10/100/1000 Mbps Ethernet

Media Access Controller (MAC).

1.1

What You Will Find in This Document

This document contains the following sections:

• Section 2.0, “General Description” on page 20 provides the block diagram system

architecture.

• Section 3.0, “Ball Assignments and Ball List Tables” on page 22 shows the signal naming

methodology and signal descriptions.

• Section 4.0, “Ball Assignments and Signal Descriptions” on page 36 illustrates and lists the

IXF1104 ball grid diagram with two ball list tables (by signal name and ball location)

• Section 5.0, “Functional Descriptions” on page 65 gives detailed information about the

operation of the IXF1104 including general features, and interface types and descriptions.

• Section 7.0, “Electrical Specifications” on page 131 provides information on the product-

operating parameters, electrical specifications, and timing parameters.

• Section 8.0, “Register Set” on page 154 illustrates and lists the memory map, detailed

descriptions, default values for the register set, and detailed information on each register.

• Section 9.0, “Mechanical Specifications” on page 223 illustrates the packaging information.

• Section 10.0, “Product Ordering Information” on page 227 provides ordering information.

1.2

Related Documents

Document

Number

Document

Intel^®IXF1104 Media Access Controller Design and Layout Guide

Intel^®IXF1104 Media Access Controller Thermal Design Considerations

Intel^®IXF1104 Media Access Controller Development Kit Manual

Intel^®IXF1104 Media Access Controller Specification Update

278696

278751

278785

278756

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

2.0

General Description

The IXF1104 provides up to a 4.0 Gbps interface to four individual 10/100/1000 Mbps full-duplex

or 10/100 Mbps half-duplex-capable Ethernet Media Access Controllers (MACs). The network

processor is supported through a System Packet Interface Phase 3 (SPI3) media interface. The

following PHY interfaces are selected on a per-port basis:

• Serializer/Deserializer (SerDes) with Optical Module Interface support

• Gigabit Media Independent Interface (GMII)

• Reduced Gigabit Media Independent Interface (RGMII).

Figure 1 illustrates the IXF1104 block diagram.

Figure 1. Block Diagram

CPU

uP IF

PHY 1 Device

PHY 2 Device

PHY 3 Device

PHY 4 Device

Intel^®

IXF1104 MAC

SPI3

MDIO

B3175-01

Datasheet

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Figure 2 illustrates the IXF1104 internal architecture.

Figure 2. Internal Architecture

CPU Interface

RMON Statistics

RGMII/GMII Interface

10/100/1000 MAC

PMA Layer

SerDes

Packet

Buffer

RGMII/GMII Interface

Packet

Buffer

PMA Layer

SerDes

Packet

Buffer

SPI3 Interface

RGMII/GMII Interface

Packet

Buffer

PMA Layer

SerDes

RGMII/GMII Interface

Clock Control Block

Clock Register Block

MDIO

PMA Layer

SerDes

OMI

PLLs

B3176-01

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

3.0

Ball Assignments and Ball List Tables

3.1

Ball Assignments

See Figure 3, T a ble 1 “Ball List in Alphanumeric Order by Signal Name” on page 23, and Table 2

“Ball List in Alphanumeric Order by Ball Location” on page 29 for the IXF1104 ball assignments.

Figure 3. Intel^®IXF1104 552-Ball CBGA Assignments (Top View)

AD AC AB AA

AC1 AB1 AA1 Y1

AD1

AD2

AB2 AA2 Y2

AC2

AD3 AC3 AB3 AA3 Y3

AD4 AC4 AB4 AA4 Y4

AD5 AC5 AB5 AA4 Y5

P13 N3

AD6 AC6 AB6 AA6

AD7 AC7 AB7 AA7 Y7

B28

AD8 AC8 AB8 AA8 Y8

AD9 AC9 AB9 AA9 Y9

AD10 AC10 AB10 AA10 Y10 W10 V10 U10 T10 R10 P10 N10 M10 L10 K10 J10 H10 G10 F10 E10 D10 C10 B10 A10

AD11 AC11 AB11 AA11 Y11 W11 V11 U11 T11 R11 P11 N11 M11 L11 K11 J11 H11 G11 F11 E11 D11 C11 B11 A11

AD12 AC12 AB12 AA12 Y12 W12 V12 U12 T12 R12 P12 N12 M12 L12 K12 J12 H12 G12 F12 E12 D12 C12 B12 A12

AD13 AC13 AB13 AA13 Y13 W13 V13 U13 T13 R13 P13 N13 M13 L13 K13 J13 H13 G13 F13 E13 D13 C13 B13 A13

AD14 AC14 AB14 AA14 Y14 W14 V14 U14 T14 R14 P14 N14 M14 L14 K14 J14 H14 G14 F14 E14 D14 C14 B14 A14

AD15 AC15 AB15 AA15 Y15 W15 V15 U15 T15 R15 P15 N15 M15 L15 K15 J15 H15 G15 F15 E15 D15 C15 B15 A15

16 ^{AD16 AC16 AB16 AA16}Y16 W16 V16 U16 T16 R16 P16 N16 M16 L16 K16 J16 H16 G16 F16 E16 D16 C16 B16 ^A1616

AD17 AC17 AB17 AA17 Y17 W17

V17 U17 T17 R17 P17 N17 M17 L17 K17 J17 H17 G17 F17 E17 D17 C17 B17 A17

AD18 AC18 AB18 AA18 Y18 W18 V18 U18 T18 R18 P18 N18 M18 L18 K18 J18 H18 G18 F18 E18 D18 C18 B18 A18

AD19 AC19 AB19 AA19 Y19 W19 V19 U19 T19 R19 P19 N19 M19 L19 K19 J19 H19 G19 F19 E19 D19 C19 B19 A19

AD20 AC20 AB20 AA20 Y20 W20 V20 U20 T20 R20 P20 N20 M20 L20 K20 J20 H20 G20 F20 E20 D20 C20 B20 A20

AD21 AC21 AB21 AA21 Y21 W21 V21 U21 T21 R21 P21 N121 M21 L21 K21 J21 H21 G21 F21 E21 D21 C21 B21 A21

AD22 AC22 AB22 AA22

W22 V22 U22 T22 R22 P22 N22 M22 L22 K22 J22 H22 G22 F22 E22 D22 C22 B22 A22

Y22

AD23 AC23 AB23 AA23 Y23 W23 V23 U23 T23 R23 P23 N23 M23 L23 K23 J23 H23 G23 F23 E23 D23 C23 B23 A23

AD24 AC24 AB24 AA24 Y24 W24 V24 U24 T24 R24 P24 N24 M24 L24 K24 J24 H24 G24 F24 E24 D24 C24 B24 A24

AD AC AB AA

= No Pad (A1)

= No Ball (A2, A3, A22, A23, A24, B1, B2, B23, B24, C1, C24, AB1, AB24, AC1, AC2, AC23, AC24, AD1, AD2, AD3,

AD22, AD23, AD24)

B1458-01

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

3.2

Ball List Tables

3.2.1

Balls Listed in Alphabetic Order by Signal Name

T a ble 1 shows the ball locations and signal names arranged in alphanumeric order by signal name.

The following table notes relate to T a ble 1 and T a ble 2:

1. GMII Ball Connection:

See Table 16 for connection in RGMII or fiber mode.

2. SPI3 Ball Connection:

See Table 17 for proper SPHY and MPHY connection.

3. Fiber Mode Ball Connection:

See Table 16 for use in RGMII and GMII (copper mode).

Table 1. Ball List in Alphanumeric Order by Signal Name

Ball

Location

Ball

Location

Ball

Location

Signal Name

GND

K14

K16

K19

K23

L10

L12

L13

L15

AVDD1P8_1

AVDD1P8_2

AVDD2P5_1

AVDD2P5_2

CLK125

A20

T23

D12

D13

D17

D21

AB16

AD20

R18

U14

AD19

AB6

AB10

AD15

AB17

AA5

AA9

AB15

AC16

COL_0¹

F10

F15

F19

F23

COL_1¹

COL_2¹

M11

M14

M17

M21

COL_3¹

CRS_0¹

CRS_1¹

CRS_2¹

H12

H13

H17

H21

J10

J15

CRS_3¹

DTPA_0²

DTPA_1²

DTPA_2²

DTPA_3²

GND

N11

N14

N17

N21

P10

P12

P13

P15

GND

B10

B15

B19

GND

K11

GND

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

GND

A21

AD21

L23

L24

M24

N24

P24

K24

M22

L22

W24

V21

N22

D24

E12

F11

G15

P18

GND

I²C_CLK

R10

R12

R13

R15

R20

R11

R14

R16

R19

R23

T10

T15

I²C_DATA_0³

I²C_DATA_1³

I²C_DATA_2³

I²C_DATA_3³

LED_CLK

LED_DATA

LED_LATCH

MDC⁴

MDIO⁴

T21

T22

U12

U13

U17

U21

MOD_DEF_INT

U11

U18

W10

W15

W19

W23

AA4

AA8

AA12

AA13

AA17

AA21

AC6

AC10

AC15

AC19

AC14

L20

H18

J21

V10

V11

V13

AB18

AD4

AD5

K18

K20

K22

L18

L19

L21

No Ball

A22

A23

A24

M18

M20

N18

B23

B24

C24

AB1

AB24

AB12

P17

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

No Ball

AC1

AC2

AC23

AC24

AD1

AD2

AD3

AD22

AD23

AD24

RDAT_26²

RDAT_27²

RDAT_28²

RDAT_29²

RDAT_30²

RDAT_31²

RENB_0²

RENB_1²

RENB_2²

RENB_3²

REOP_0²

REOP_1²

REOP_2²

REOP_3²

RERR_0²

RERR_1²

RERR_2²

RERR_3²

RFCLK²

G20

G21

G22

G23

G24

F24

A13

A18

C19

E24

C16

D18

C23

J19

RX_ER_0¹

RX_ER_1¹

RX_ER_2¹

RX_ER_3¹

RX_LOS_INT³

RX_N_0³

RX_N_1³

RX_N_2³

RX_N_3³

RX_P_0³

RX_P_1³

RX_P_2³

RX_P_3³

RXC_0¹

Y12

AA22

U20

P19

R22

U22

R24

V24

P22

V22

T24

U24

No Ball

No Pad

PTPA²

B11

RDAT_0²

RDAT_1²

RDAT_2²

RDAT_3²

RDAT_4²

RDAT_5²

RDAT_6²

RDAT_7²

RDAT_8²

RDAT_9²

RDAT_10²

RDAT_11²

RDAT_12²

RDAT_13²

RDAT_14²

RDAT_15²

RDAT_16²

RDAT_17²

RDAT_18²

RDAT_19²

RDAT_20²

RDAT_21²

RDAT_22²

RDAT_23²

RDAT_24²

RDAT_25²

A15

A14

B14

C14

C13

D14

E14

F14

A16

G17

D20

H20

A19

G14

G13

E15

G16

E20

F20

B16

C18

E23

J18

RXC_1¹

AD11

AA24

V23

RXC_2¹

RXC_3¹

RXD0_0¹

RXD0_1¹

RXD0_2¹

RXD0_3¹

RXD1_0¹

RXD1_1¹

RXD1_2¹

RXD1_3¹

RXD2_0¹

RXD2_1¹

RXD2_2¹

RXD2_3¹

RXD3_0¹

RXD3_1¹

RXD3_2¹

RXD3_3¹

RXD4_0¹

RXD4_1¹

RXD4_2¹

RXD4_3¹

RXD5_0¹

RMOD0²

RMOD1²

RPRTY_0²

RPRTY_1²

RPRTY_2²

RPRTY_3²

RSOP_0²

RSOP_1²

RSOP_2²

RSOP_3²

RSX²

Y20

Y17

A17

C17

D16

E16

F16

Y11

Y21

Y18

E17

E18

F18

W11

Y22

Y19

B20

B22

C20

C21

C22

D22

E22

E21

G18

G19

E13

C15

B18

E19

F22

RVAL_0²

RVAL_1²

RVAL_2²

RVAL_3²

RX_DV_0¹

RX_DV_1¹

RX_DV_2¹

RX_DV_3¹

Y23

W18

AD10

W22

T16

AB11

Y24

V18

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

RXD5_1¹

RXD5_2¹

RXD5_3¹

RXD6_0¹

RXD6_1¹

RXD6_2¹

RXD6_3¹

RXD7_0¹

RXD7_1¹

RXD7_2¹

RXD7_3¹

STPA²

AC11

V20

T17

AB5

AA11

V19

T18

AC5

Y10

W20

T19

C11

AD12

A11

A12

J22

TDAT22²

TDAT23²

TDAT24²

TDAT25²

TDAT26²

TDAT27²

TDAT28²

TDAT29²

TDAT30²

TDAT31²

TDI

TX_EN_0¹

TX_EN_1¹

TX_EN_2¹

TX_EN_3¹

TX_ER_0¹

TX_ER_1¹

TX_ER_2¹

TX_ER_3¹

TX_FAULT_INT³

TX_N_0³

TX_N_1³

TX_N_2³

TX_N_3³

TX_P_0³

TX_P_1³

TX_P_2³

TX_P_3³

TXC_0¹

AB2

AC22

V12

AD6

AD17

AB13

P23

Y14

J24

H24

AD14

Y16

TDO

SYS_RST_L

TADR0²

TADR1²

TCLK

TENB_0²

TENB_1²

TENB_2²

TENB_3²

TEOP_0²

TEOP_1²

TEOP_2²

TEOP_3²

TERR_0²

TERR_1²

TERR_2²

TERR_3²

TFCLK²

AD18

Y13

AD13

W16

AC18

AA1

AD7

AC20

AB14

TDAT0²

TDAT1²

TDAT2²

E11

TXC_1¹

TDAT3²

TXC_2¹

TDAT4²

TXC_3¹

TDAT5²

TXD0_0¹

TXD0_1¹

TXD0_2¹

TXD0_3¹

TXD1_0¹

TXD1_1¹

TXD1_2¹

TXD1_3¹

TXD2_0¹

TXD2_1¹

TXD2_2¹

TXD2_3¹

TXD3_0¹

TXD3_1¹

TXD3_2¹

TXD3_3¹

TXD4_0¹

TDAT6²

AC7

AB20

V14

TDAT7²

TDAT8²

H22

TDAT9²

TMOD0²

TMOD1²

TMS

TDAT10²

TDAT11²

TDAT12²

TDAT13²

TDAT14²

TDAT15²

TDAT16²

TDAT17²

TDAT18²

TDAT19²

TDAT20²

TDAT21²

AB7

AB21

V15

TPRTY_0²

TPRTY_1²

TPRTY_2²

TPRTY_3²

TRST_L

TSOP_0²

TSOP_1²

TSOP_2²

TSOP_3²

TSX

AB9

AB22

V16

J23

C10

AA3

AD9

AB23

V17

E10

AB3

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

TXD4_1¹

TXD4_2¹

AA7

AD16

AA14

AC3

AB8

AB19

Y15

AB4

AD8

AA20

AA16

UPX_DATA5

UPX_DATA6

UPX_DATA7

UPX_DATA8

UPX_DATA9

UPX_DATA10

UPX_DATA11

UPX_DATA12

UPX_DATA13

UPX_DATA14

UPX_DATA15

UPX_DATA16

UPX_DATA17

UPX_DATA18

UPX_DATA19

UPX_DATA20

UPX_DATA21

UPX_DATA22

UPX_DATA23

UPX_DATA24

UPX_DATA25

UPX_DATA26

UPX_DATA27

UPX_DATA28

UPX_DATA29

UPX_DATA30

UPX_DATA31

UPX_RD_L

UPX_RDY_L

UPX_WIDTH0

UPX_WIDTH1

UPX_WR_L

VDD

VDD2

H10

H15

J11

J14

TXD4_3¹

TXD5_0¹

TXD5_1¹

TXD5_2¹

TXD5_3¹

K17

K21

TXD6_0¹

TXD6_1¹

TXD6_2¹

L11

L14

L16

TXD6_3¹

N10

M10

K10

G10

H11

G11

K12

G12

K13

H14

K15

N15

M15

J16

H16

J17

L17

TXD7_0¹

TXD7_1¹

AC9

AA18

W14

N20

P20

P21

T20

TXD7_2¹

P11

P14

P16

TXD7_3¹

TXPAUSE_ADD0

TXPAUSE_ADD1

TXPAUSE_ADD2

TXPAUSEFR

UPX_ADD0

UPX_ADD1

UPX_ADD2

UPX_ADD3

UPX_ADD4

UPX_ADD5

UPX_ADD6

UPX_ADD7

UPX_ADD8

UPX_ADD9

UPX_ADD10

UPX_BADD0

UPX_BADD1

UPX_CS_L

UPX_DATA0

UPX_DATA1

UPX_DATA2

UPX_DATA3

UPX_DATA4

R17

R21

T11

T14

U10

U15

W21

AA6

AA10

AA15

AA19

C12

D11

J20

A10

U16

VDD

D10

D15

D19

VDD

B12

VDD

F21

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Signal Name

Location

VDD2

VDD3

VDD4

VDD5

F12

VDD5

N12

T12

J12

W12

AA2

AC4

AC8

AC12

M12

B13

B17

B21

D23

F13

F17

H19

H23

J13

M13

M16

M19

M23

N13

N16

N19

N23

T13

U19

U23

W13

W17

AA23

AC13

AC17

AC21

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

3.2.2

Balls Listed in Alphabetic Order by Ball Location

T a ble 2 shows the ball locations and signal names arranged in order by ball location.

Table 2. Ball List in Alphanumeric Order by Ball Location

Ball

Location

Ball

Location

Ball

Location

Signal Name

B10

B11

B12

B13

B14

B15

B16

B17

B18

B19

B20

B21

B22

B23

B24

GND

PTPA²

C20

C21

C22

C23

C24

RDAT_18²

RDAT_19²

RDAT_20²

REOP_2²

No Ball

TDAT3²

VDD2

No Pad

No Ball

VDD2

No Ball

VDD3

GND

RDAT_2²

GND

AVDD1P8_1

TMOD0²

TEOP_0²

TERR_0²

DTPA_2²

VDD

RSOP_0²

VDD3

DTPA_0²

RVAL_1²

GND

TPRTY_0²

VDD

A10

A11

A12

A13

A14

A15

A16

A17

A18

A19

A20

A21

A22

A23

A24

RDAT_16²

VDD3

TADR0²

TADR1²

RENB_0²

RDAT_1²

RDAT_0²

RERR_0²

RDAT_8²

RENB_1²

RFCLK²

AVDD1P8_1

GND

TFCLK²

RDAT_17²

No Ball

GND

TMOD1²

VDD

No Ball

D10

D11

D12

D13

D14

D15

D16

D17

D18

D19

D20

D21

D22

D23

D24

No Ball

VDD

TDAT1²

TDAT2²

TDAT4²

TDAT5²

TDAT7²

TSOP_0²

TDAT23²

TENB_2²

TSOP_2²

STPA²

GND

RDAT_5²

VDD

RDAT_10²

GND

No Ball

REOP_1²

VDD

No Ball

C10

C11

C12

C13

C14

C15

C16

C17

C18

C19

RERR_2²

GND

No Ball

RDAT_21²

VDD3

TDAT0²

VDD

RDAT_4²

RDAT_3²

RVAL_0²

REOP_0²

RDAT_9²

RSOP_1²

RENB_2²

VDD2

TDAT6²

GND

TSX

TENB_1²

TSOP_1²

TEOP_2²

TDAT16²

TENB_0²

VDD2

TPRTY_2²

Datasheet

Document Number: 278757

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

TDAT17²

TDAT18²

TDAT19²

TDAT20²

TDAT21²

TERR_2²

F20

F21

F22

F23

F24

RPRTY_3²

VDD

H10

H11

H12

H13

H14

H15

H16

H17

H18

H19

H20

H21

H22

H23

H24

VDD

UPX_DATA19

GND

RVAL_3²

GND

E10

E11

E12

E13

E14

E15

E16

E17

E18

E19

E20

E21

E22

E23

E24

RDAT_31²

TDAT9²

UPX_DATA24

VDD

TDAT10²

TPRTY_1²

TDAT24²

TDAT25²

TDAT26²

TDAT27²

TDAT28²

TDAT29²

UPX_DATA18

UPX_DATA20

UPX_DATA22

RMOD1²

RMOD0²

UPX_DATA29

GND

RSX²

RDAT_6²

RPRTY_0²

RDAT_11²

RDAT_13²

RDAT_14²

RVAL_2²

RPRTY_2²

RDAT_23²

RDAT_22²

RSOP_2²

RENB_3²

TDAT8²

GND

VDD3

RERR_3²

GND

TMS

VDD3

G10

G11

G12

G13

G14

G15

G16

G17

G18

G19

G20

G21

G22

G23

G24

TDO

TDAT12²

TDAT13²

TDAT14²

TENB_3²

TSOP_3²

TPRTY_3²

DTPA_3²

TERR_3²

UPX_DATA14

GND

RPRTY_1²

RERR_1²

RDAT_24²

RDAT_25²

RDAT_26²

RDAT_27²

RDAT_28²

RDAT_29²

RDAT_30²

TDAT11²

VDD2

TEOP_1²

VDD

TDAT30²

GND

J10

J11

J12

J13

J14

J15

J16

J17

J18

J19

J20

J21

J22

J23

TDAT31²

VDD

VDD2

TDAT22²

GND

VDD3

F10

F11

F12

F13

F14

F15

F16

F17

F18

F19

VDD

GND

VDD2

UPX_DATA28

UPX_DATA30

RSOP_3²

REOP_3²

VDD

VDD3

TDAT15²

RDAT_7²

GND

TEOP_3²

VDD2

RDAT_12²

VDD3

RDAT_15²

GND

TCLK

UPX_DATA13

TRST_L

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

J24

TDI

TERR_1²

GND

L14

L15

L16

L17

L18

L19

L20

L21

L22

L23

L24

VDD

GND

UPX_DATA5

VDD5

VDD

UPX_DATA1

VDD

UPX_DATA31

UPX_DATA11

GND

UPX_DATA7

GND

VDD5

GND

N10

N11

N12

N13

N14

N15

N16

N17

N18

N19

N20

N21

N22

N23

N24

UPX_DATA15

GND

VDD

LED_LATCH

I²C_CLK

I²C_DATA_0³

UPX_RDY_L

VDD2

VDD5

GND

VDD4

K10

K11

K12

K13

K14

K15

K16

K17

K18

K19

K20

K21

K22

K23

K24

UPX_DATA17

GND

UPX_DATA26

VDD4

UPX_DATA21

UPX_DATA23

GND

UPX_DATA3

GND

UPX_DATA25

GND

UPX_DATA6

VDD2

VDD4

TXPAUSE_ADD0

GND

VDD

GND

MOD_DEF_INT

VDD4

GND

VDD2

M10

M11

M12

M13

M14

M15

M16

M17

M18

M19

M20

M21

M22

M23

M24

UPX_DATA16

GND

I²C_DATA_2³

UPX_ADD2

VDD

VDD2

GND

VDD3

UPX_ADD0

LED_CLK

DTPA_1²

UPX_DATA0

UPX_DATA2

UPX_DATA4

GND

UPX_DATA27

VDD3

UPX_DATA8

GND

VDD3

VDD

UPX_DATA9

UPX_DATA10

UPX_DATA12

VDD

P10

P11

P12

P13

P14

P15

P16

P17

GND

VDD

LED_DATA

VDD3

GND

L10

L11

L12

L13

GND

I²C_DATA_1³

UPX_ADD1

VDD5

VDD

GND

VDD

GND

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

P18

P19

P20

P21

P22

P23

P24

RX_LOS_INT³

TXPAUSE_ADD1

TXPAUSE_ADD2

RX_P_0³

TX_FAULT_INT³

I²C_DATA_3³

UPX_ADD3

GND

U22

U23

U24

RX_N_1³

VDD4

T10

T11

T12

T13

T14

T15

T16

T17

T18

T19

T20

T21

T22

T23

T24

GND

RX_P_3³

UPX_ADD6

UPX_ADD7

UPX_ADD8

RXC_0¹

RX_DV_0¹

UPX_RD_L

RXD1_0¹

RXD0_0¹

VDD

VDD5

VDD4

VDD

GND

RXD4_3¹

RXD5_3¹

RXD6_3¹

RXD7_3¹

TXPAUSEFR

UPX_CS_L

VDD

GND

V10

V11

V12

V13

V14

V15

V16

V17

V18

V19

V20

V21

V22

V23

V24

W10

W11

GND

VDD

TX_EN_3¹

GND

AVDD1P8_2

RX_P_2³

UPX_ADD5

VDD5

R10

R11

R12

R13

R14

R15

R16

R17

R18

R19

R20

R21

R22

R23

R24

TXD0_3¹

TXD1_3¹

TXD2_3¹

TXD3_3¹

RX_DV_3¹

RXD6_2¹

RXD5_2¹

MDIO⁴

GND

UPX_ADD9

GND

VDD5

VDD

AVDD2P5_2

GND

RX_P_1³

RXC_3¹

RX_N_3³

TX_ER_0¹

GND

U10

U11

U12

U13

U14

U15

U16

U17

U18

U19

U20

U21

VDD

RX_N_0³

GND

UPX_BADD1

RX_N_2³

UPX_ADD4

UPX_BADD0

UPX_ADD10

UPX_WR_L

UPX_WIDTH1

AVDD2P5_2

VDD

RX_ER_0¹

GND

UPX_WIDTH0

GND

RXD2_0¹

VDD5

VDD4

RXD3_1¹

GND

RX_ER_3¹

GND

RXD2_1¹

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Ball

Location

Ball

Location

Signal Name

W12

W13

W14

W15

W16

W17

W18

W19

W20

W21

W22

W23

W24

VDD5

VDD4

AA2

AA3

VDD5

TXD3_0¹

GND

AB16

AB17

AB18

AB19

AB20

AB21

AB22

AB23

AB24

AC1

AVDD1P8_2

COL_3¹

TXD7_3¹

GND

AA4

AA5

CRS_0¹

TXD5_2¹

TXD0_2¹

TXD1_2¹

TXD2_2¹

TXD3_2¹

No Ball

TXD5_0¹

VDD5

TX_P_2³

VDD4

AA6

VDD

AA7

TXD4_1¹

GND

RXD3_3¹

GND

AA8

AA9

CRS_1¹

RXD7_2¹

VDD

AA10

AA11

AA12

AA13

AA14

AA15

AA16

AA17

AA18

AA19

AA20

AA21

AA22

AA23

AA24

AB1

VDD

RXD6_1¹

GND

RXD4_2¹

GND

AC2

GND

AC3

MDC⁴

TXD4_3¹

VDD

AC4

TXD0_0¹

TXD1_0¹

TXD2_0¹

TXD7_0¹

RXD5_0¹

RXD4_0¹

RXD3_0¹

TX_EN_1¹

RXD0_1¹

RXD7_1¹

RXD1_1¹

RX_ER_1¹

TX_P_0³

TX_N_0³

TXD5_3¹

TX_N_2³

RXD0_3¹

RXD1_3¹

RXD2_3¹

RXD0_2¹

RXD1_2¹

RXD2_2¹

RXD3_2¹

RX_DV_2¹

TXC_0¹

AC5

RXD7_0¹

TXD6_3¹

GND

AC6

GND

AC7

TXD0_1¹

VDD5

TXD7_2¹

VDD

AC8

AC9

TXD7_1¹

TXD6_2¹

GND

AC10

AC11

AC12

AC13

AC14

AC15

AC16

AC17

AC18

AC19

AC20

AC21

AC22

AC23

AC24

AD1

GND

RXD5_1¹

VDD5

RX_ER_2¹

VDD4

Y10

Y11

Y12

Y13

Y14

Y15

Y16

Y17

Y18

Y19

Y20

Y21

Y22

Y23

Y24

AA1

RXC_2¹

No Ball

TX_EN_0¹

TXD4_0¹

TXD6_0¹

RXD6_0¹

COL_0¹

TXD1_1¹

TXD5_1¹

TXD2_1¹

COL_1¹

RX_DV_1¹

GND

AB2

CRS_3¹

VDD4

AB3

AB4

TX_P_3³

GND

AB5

AB6

TXC_2¹

VDD4

AB7

AB8

TX_EN_2¹

No Ball

AB9

AB10

AB11

AB12

AB13

AB14

AB15

AD2

TX_ER_3¹

TXC_3¹

CRS_2¹

AD3

AD4

AD5

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Ball

Location

Signal Name

AD6

AD7

TX_ER_1¹

TXC_1¹

AD8

TXD6_1¹

TXD3_1¹

RXD4_1¹

RXC_1¹

AD9

AD10

AD11

AD12

AD13

AD14

AD15

AD16

AD17

AD18

AD19

AD20

AD21

AD22

AD23

AD24

SYS_RST_L

TX_P_1³

TX_N_1³

COL_2¹

TXD4_2¹

TX_ER_2¹

TX_N_3³

CLK125

AVDD2P5_1

GND

No Ball

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.0

Ball Assignments and Signal Descriptions

4.1

Naming Conventions

4.1.1

Signal Name Conventions

Signal names begin with a Signal Mnemonic, and can also contain one or more of the following

designations: a differential pair designation, a serial designation, a port designation (RGMII

interface), and an active low designation. Signal naming conventions are as follows:

Differential Pair + Port Designation. The positive and negative components of differential pairs

tied to a specific port are designated by the Signal Mnemonic, immediately followed by an

underscore and either P (positive component) or N (negative component), and an underscore

followed by the port designation. For example, SerDes interface signals for port 0 are identified as

TX_P_0 and TX_N_0.

Serial Designation. A set of signals that are not tied to any specific port are designated by the

Signal Mnemonic, followed by a bracketed serial designation. For example, the set of 11 CPU

Address Bus signals is identified as UPX_ADD[10:0].

Port Designation. Individual signals that apply to a particular port are designated by the Signal

Mnemonic, immediately followed by an underscore and the Port Designation. For example,

RGMII Transmit Control signals are identified as TX_CTL_0, TX_CTL_1, TX_CTL_2, and so on.

Port Bus Designation. A set of bus signals that apply to a particular port are designated by the

Signal Mnemonic, immediately followed by a bracketed bus designation, followed by an

underscore and the port designation. For example, RGMII transmit data bus signals are identified

as TD[3:0]_0, TD[3:0]_1, TD[3:0]_2, and so on.

Active Low Designation. A control input or indicator output that is active Low is designated by a

final suffix consisting of an underscore followed by an upper case “L”. For example, the CPU cycle

complete identifier is shown as UPX_RDY_L.

4.1.2

Registers located in on-chip memory are accessed using a register address, which is provided in

Hex notation. A Register Address is indicated by the dollar sign ($), followed by the memory

location in Hex.

Datasheet

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Revision Number: 007

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.2

Interface Signal Groups

This section describes the IXF1104 signals in groups according to the associated interface or

function. Figure 4 shows the various interfaces available on the IXF1104.

Figure 4. Interface Signals

SPHY

MPHY

GMII

RGMII

TXC_0:3

TXC _0: 3

TDAT[7:0]_0:3

TFCLK

TDAT[ 31:0]

TFCLK

TD[3:0]_0

TD[3:0] _1

TD[3:0] _2

TD[3:0]_3

TX_C TL_0: 3

TXD[ 7:0] _0

TXD[ 7:0] _1

TENB_0: 3

TERR _0: 3

TPR TY_0: 3

TENB_0

TERR_0

TPRTY_0

TMOD[1:0]

TSX

TXD[ 7:0] _2

TXD[ 7:0] _3

TX_EN_0:3

TX_ER_0:3

TSOP_0:3

TEOP_0:3

TSOP_0

TEOP_0

RXC_0:3

R XC _0: 3

TADR[1:0]

DTPA_0: 3

TADR[1:0]

DTPA_0:3

STPA

GMII and

RXD[7:0]_3

RD[3:0]_0

RGMII

Interfaces*

SPI3

Interface

RXD[7:0]_2

RXD[7:0]_1

RXD[7:0]_0

RX_D V_0:3

RX_ER_0:3

CRS_0:3

RD[3:0]_1

RD[3:0]_2

RD[3:0]_3

R X_CTL_0:3

PTPA

RDAT[7:0]_0:3

RFCLK

PTPA

R D AT[ 31: 0]

RFCLK

RENB_0:3

RVAL_0: 3

RENB_0

RVAL_0

RERR_0

RPRTY_0

RMOD[1:0]

RSX

COL_0:3

RERR_0:3

RPRTY_0:3

* D at a and clock balls are shared for

GMII and RGMII Interfaces

RSOP_0: 3

REOP_0: 3

RSOP_0

REOP_0

Intel^®IXF1104

Media Access

Controller

TMS

TDI

RX_P/N_0:3

TX_P/N_0:3

SerDes

Interface

JTAG

TDO

TCLK

Interface

TRST_L

MDIO

MDC

MDIO

Interface

TX_D ISABLE_0:3

MOD_DEF_0:3

TX_FAU LT_0:3

RX_LOS_0:3

Pause

Control

Interface

Optical

Module

Interface

Si gnals*

TXPAUSEADD[2:0]

TXPAUSEFR

TX_FAU LT_IN T

RX_LOS_IN T

MOD_DEF_INT

UPX_WIDTH[1:0]

UPX_D ATA[ 31:0]

UPX_ADD[10:0]

UPX_BADD[1:0]

I C_CLK

I C_DATA_0:3

** These optical module signals

are mult iplexed on the GMII balls.

CPU

Interface

UPX_WR_L

UPX_RD_L

UPX_CS_L

UPX_RDY_L

System

Interface

SYS_RES_L

CLK125

LED_CLK

LED

Interface

LED_DATA

LED_LATCH

B3181-01

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.3

Signal Description Tables

The I/O signals, power supplies, or ground returns associated with each IXF1104 connection ball

are described in T a ble 3 through Table 14.

Table 3. SPI3 Interface Signal Descriptions (Sheet 1 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

TDAT31

TDAT30

TDAT29

TDAT28

TDAT27

TDAT26

TDAT25

TDAT24

TDAT7_3

TDAT6_3

TDAT5_3

TDAT4_3

TDAT3_3

TDAT2_3

TDAT1_3

TDAT0_3

Transmit Data Bus.

Carries payload data to the IXF1104 egress

path.

3.3 V

LVTTL

Input

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[31:24]

[7:0] for port 3

TDAT23

TDAT22

TDAT21

TDAT20

TDAT19

TDAT18

TDAT17

TDAT16

TDAT7_2

TDAT6_2

TDAT5_2

TDAT4_2

TDAT3_2

TDAT2_2

TDAT1_2

TDAT0_2

Transmit Data Bus.

Carries payload data to the IXF1104 egress

path.

E10

3.3 V

LVTTL

Input

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[23:16]

[7:0] for port 2

TDAT15

TDAT14

TDAT13

TDAT12

TDAT11

TDAT10

TDAT9

TDAT7_1

TDAT6_1

TDAT5_1

TDAT4_1

TDAT3_1

TDAT2_1

TDAT1_1

TDAT0_1

Transmit Data Bus.

Carries payload data to the IXF1104 egress

path.

3.3 V

LVTTL

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[15:8]

[7:0] for port 1

TDAT8

TDAT7

TDAT6

TDAT5

TDAT4

TDAT3

TDAT2

TDAT1

TDAT0

TDAT7_0

TDAT6_0

TDAT5_0

TDAT4_0

TDAT3_0

TDAT2_0

TDAT1_0

TDAT0_0

Transmit Data Bus.

Carries payload data to the IXF1104 egress

path.

3.3 V

LVTTL

Input

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

7:0]

[7:0] for port 0

Transmit Clock.

TFCLK is the clock associated with all

transmit signals. Data and control lines are

sampled on the rising edge of TFCLK

(frequency operation range 90 - 133 MHz).

3.3 V

LVTTL

TFCLK

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 2 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

Transmit Parity.

TPRTY indicates odd parity for the TDAT

bus. TPRTY is valid only when a channel

asserts either TENB or TSX. Odd parity is

the default configuration; however, even

parity can be selected (see T able 146 “SPI3

TPRTY_0 TPRTY_0

TPRTY_1

3.3 V

LVTTL

Input

TPRTY_2

TPRTY_3

($0x700)” on page 212).

32-bit Multi-PHY mode: TPRTY_0 is the

parity bit covering all 32 bits.

4 x 8 Single-PHY mode: TPRTY_0:3 bits

correspond to the respective TDAT[3:0]_n

channels.

Transmit Write Enable.

TENB_0:3 asserted causes an attached

PHY to process TDAT[n], TMOD, TSOP,

TEOP and TERR signals.

TENB_0

TENB_1

TENB_2

TENB_3

3.3 V

LVTTL

32-bit Multi-PHY mode: TENB_0 is the

enable bit for all 32 bits.

Input

4 x 8 Single-PHY mode: TENB_0:3 bits

correspond to the respective TDAT[3:0]_n

channels and their associated control and

status signals.

Transmit Error.

TERR indicates that there is an error in the

current packet. TERR is valid when

simultaneously asserted with TEOP and

TENB.

TERR_0

TERR_1

TERR_2

TERR_3

E11

3.3 V

LVTTL

Input

32-bit Multi-PHY mode: TERR_0 is the bit

asserted for all 32 bits.

4 x 8 Single-PHY mode: Each bit of

TERR_0:3 corresponds to the respective

TDAT[3:0]_n channel.

Transmit Start-of-Packet.

TSOP indicates the start of a packet and is

valid when asserted simultaneously with

TENB.

TSOP_0

TSOP_1

TSOP_2

TSOP_3

C10

3.3 V

LVTTL

Input

32-bit Multi-PHY mode: TSOP_0 is the bit

asserted for all 32 bits.

4 x 8 Single-PHY mode: Each bit of

TSOP_0:3 corresponds to the respective

TDAT[3:0]_n channel.

Transmit End-of-Packet.

TEOP indicates the end of a packet and is

valid when asserted simultaneously with

TENB.

TEOP_0

TEOP_1

TEOP_2

TEOP_3

3.3 V

LVTTL

Input

32-bit Multi-PHY mode: TEOP_0 is the bit

asserted for all 32 bits.

4 x 8 Single-PHY mode: Each bit of

TEOP_0:3 corresponds to the respective

TDAT[3:0]_n channel.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 3 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

TMOD[1:0] Transmit Word Modulo.

32-bit Multi-PHY mode: TMOD[1:0]

indicates the valid data bytes of TDAT[31:0].

During transmission, TMOD[1:0] should

always be “00” until the last double word is

transferred on TDAT[31:0]. TMOD[1:0]

specifies the valid bytes of TDAT when

TEOP is asserted:

TMOD[1:0] – Valid Bytes of TDAT

00 =4 bytes [31:0]

TMOD1

TMOD0

3.3 V

LVTTL

Input

01 =3 bytes [31:8]

10 =2 bytes [31:16]

11 = 1 byte [31:24]

TENB must be asserted simultaneously for

TMOD[1:0] to be valid.

4 x 8 Single-PHY mode: MOD[1:0] is not

required.

Transmit Start of Transfer.

32-bit Multi-PHY mode: TSX asserted with

TENB = 1 indicates that the PHY address is

present on TDAT[7:0]. The valid values on

TDAT[7:0] are 3, 2, 1, and 0. When

TENB = 0, TSX is not used by the PHY

device.

3.3 V

LVTTL

TSX

Input

NOTE: Only TDAT[1:0] are relevant; all

other bits are “Don’t Care”.

4 x 8 Single-PHY mode: TSX is not used.

TADR[1:0] Transmit PHY Address.

TADR1

TADR0

TADR1

TADR0

A12

A11

3.3 V

LVTTL

The value on TADR[1:0] selects one of the

PHY ports that drives the PTPA signal after

the rising edge of TFCLK.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 4 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

DTPA_0:3 Direct Transmit Packet

Available.

A direct status indication for transmit FIFOs

of ports 0:3.

When High, DTPA indicates that the amount

of data in the TX FIFO is below the TX FIFO

High watermark. When the High watermark

is crossed, DTPA transitions Low to indicate

that the TX FIFO is almost full. It stays Low

until the amount of data in the TX FIFO

goes back below the TX FIFO Low

watermark. At this point, DTPA transitions

High to indicate that the programmed

number of bytes are now available for data

transfers.

DTPA_0

DTPA_1

DTPA_2

DTPA_3

DTPA_0

DTPA_1

DTPA_2

DTPA_3

3.3 V

LVTTL

Output

NOTE: For more information, see

Table 132 “TX FIFO High

Watermark Ports 0 - 3 ($0x600 –

0x603)” on page 202 and T a ble 133

“TX FIFO Low Watermark Register

Ports 0 - 3 ($0x60A – 0x60D)” on

page 203.

DTPA is updated on the rising edge of

TFCLK.

Selected-PHY Transmit Packet Available.

STPA is only meaningful in a 32-bit multi-

PHY mode.

STPA is a direct status indication for

transmit FIFOs of ports 0:3.

When High, STPA indicates that the amount

of data in the TX FIFO, specified by the

latest in-band address, is below the

TX FIFO High watermark. When the High

watermark is crossed, STPA transitions Low

to indicate the TX FIFO is almost full. It

stays Low until the amount of data in the

TX FIFO goes back below the TX FIFO Low

watermark. At this point, STPA transitions

High to indicate that the programmed

number of bytes are now available for data

transfers.

3.3 V

LVTTL

STPA

C11

Output

NOTE: For more information, see

Table 132 “TX FIFO High

Watermark Ports 0 - 3 ($0x600 –

0x603)” on page 202 and T a ble 133

“TX FIFO Low Watermark Register

Ports 0 - 3 ($0x60A – 0x60D)” on

page 203.

STPA provides the status indication for the

selected port to avoid FIFO overflows while

polling is performed. The port reported by

STPA is updated on the following rising

edge of TFCLK after TSX is sampled as

asserted. STPA is updated on the rising

edge of TFCLK.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 5 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

Polled-PHY Transmit Packet Available.

PTPA allows the polling of the port selected

by the TADR address bus.

When High, PTPA indicates that the amount

of data in the TX FIFO is below the TX FIFO

High watermark. When the High watermark

is crossed, PTPA transitions Low to indicate

that the TX FIFO is almost full. It stays Low

until the amount data in the TX FIFO goes

back below the TX FIFO Low watermark. At

this point, PTPA transitions High to indicate

that the programmed number of bytes are

now available for data transfers.

3.3 V

PTPA

B11

Output

LVTTL

NOTE: For more information, see

Table 132 “TX FIFO High

Watermark Ports 0 - 3 ($0x600 –

0x603)” on page 202 and T able 133

“TX FIFO Low Watermark Register

Ports 0 - 3 ($0x60A – 0x60D)” on

page 203.

The port reported by PTPA is updated on

the following rising edge of TFCLK after the

port address on TADR is sampled by the

PHY device.

PTPA is updated on the rising edge of

TFCLK.

RDAT31

RDAT30

RDAT29

RDAT28

RDAT27

RDAT26

RDAT25

RDAT24

RDAT7_3

RDAT6_3

RDAT5_3

RDAT4_3

RDAT3_3

RDAT2_3

RDAT1_3

RDAT0_3

F24

G24

G23

G22

G21

G20

G19

G18

Receive Data Bus.

RDAT carries payload data and in-band

addresses from the IXF1104.

3.3 V

LVTTL

Output

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[31:24]

[7:0] for port 3

RDAT23

RDAT22

RDAT21

RDAT20

RDAT19

RDAT18

RDAT17

RDAT16

RDAT7_2

RDAT6_2

RDAT5_2

RDAT4_2

RDAT3_2

RDAT2_2

RDAT1_2

RDAT0_2

E21

E22

D22

C22

C21

C20

B22

B20

Receive Data Bus.

RDAT carries payload data and in-band

addresses from the IXF1104.

3.3 V

LVTTL

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[23:16]

[7:0] for port 2

RDAT15

RDAT14

RDAT13

RDAT12

RDAT11

RDAT10

RDAT9

RDAT7_1

RDAT6_1

RDAT5_1

RDAT4_1

RDAT3_1

RDAT2_1

RDAT1_1

RDAT0_1

F18

E18

E17

F16

E16

D16

C17

A17

Receive Data Bus.

RDAT carries payload data and in-band

addresses from the IXF1104.

3.3 V

LVTTL

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[15:8]

[7:0] for port 1

RDAT8

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 6 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

RDAT7

RDAT6

RDAT5

RDAT4

RDAT3

RDAT2

RDAT1

RDAT0

RDAT7_0

RDAT6_0

RDAT5_0

RDAT4_0

RDAT3_0

RDAT2_0

RDAT1_0

RDAT0_0

F14

E14

D14

C13

C14

B14

A14

A15

Receive Data Bus.

RDAT carries payload data and in-band

addresses from the IXF1104.

3.3 V

LVTTL

Output

Mode

Bits

32-bit Multi-PHY

4 x 8 Single-PHY

[7:0]

[7:0] for port 0

Receive Clock.

RFCLK is the clock associated with all

receive signals. Data and controls are

driven on the rising edge of RFCLK

(frequency operation range 90 - 133 MHz).

3.3 V

LVTTL

RFCLK

A19

Input

Receive Parity.

RPRTY indicates odd parity for the RDAT

bus. RPRTY is valid only when a channel

asserts RENB or RSX. Odd parity is the

default configuration; however, even parity

can be selected (see T a ble 147 on

page 214).

RPRTY_0 RPRTY_0

RPRTY_1

E15

G16

E20

F20

3.3 V

LVTTL

Output

RPRTY_2

RPRTY_3

32-bit Multi-PHY mode: RPRTY_0 is the

parity bit for all 32 bits.

4 x 8 Single-PHY mode: Each bit of

RPRTY_0:3 corresponds to the respective

RDAT[3:0]_n channel.

Receive Read Enable.

The RENB signal controls the flow of data

from the receive FIFOs. During data

transfer, RVAL must be monitored as it

indicates if the RDAT[31:0], RPRTY,

RMOD[1:0], RSOP, REOP, RERR, and RSX

are valid. The system may de-assert RENB

at any time if it is unable to accept data from

the IXF1104. When RENB is sampled Low,

a read is performed from the receive FIFO

and the RDAT[31:0], RPRTY, RMOD[1:0],

RSOP, REOP, RERR, RSX and RVAL

signals are updated on the following rising

edge of RFCLK.

RENB_0

RENB_1

RENB_2

RENB_3

A13

A18

C19

E24

3.3 V

LVTTL

Input

When RENB is sampled High by the PHY

device, a read is not performed, and the

RDAT[31:0], RPRTY, RMOD[1:0], RSOP,

REOP, RERR, RSX, and RVAL signals

remain unchanged on the following rising

edge of RFCLK.

32-bit Multi-PHY Mode: RENB_0 covers all

receive bits.

4 x 8 Single-PHY Mode: The RENB_0:3

bits correspond to the per-port data and

control signals.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 7 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

Receive Error.

RERR indicates that the current packet is in

error. RERR is only asserted when REOP is

asserted. Conditions that can cause RERR

to be set include FIFO overflow, CRC error,

code error, and runt or giant packets.

NOTE: RERR can only be set for these

conditions if bit 0 in the “SPI3

RERR_0

RERR_1

RERR_2

RERR_3

A16

G17

D20

H20

Receive Configuration ($0x701)” is

set to 1.

3.3 V

LVTTL

Output

RERR is considered valid only when RVAL

is asserted.

32-bit Multi-PHY mode: RERR_0 covers

all 32 bits.

4 x 8 Single-PHY mode: The RERR_0:3

bits correspond to the RDAT[7:0]_n

channels.

(n = 0, 1, 2, or 3)

Receive Data Valid.

RVAL indicates the validity of the receive

data signals. RVAL is Low between

transfers and assertion of RSX. It is also

Low when the IXF1104 pauses a transfer

due to an empty receive FIFO. When a

transfer is paused by holding RENB High,

RVAL holds its value unchanged, although

no new data is present on RDAT[31:0] until

the transfer resumes. When RVAL is High,

the RDAT[31:0], RMOD[1:0], RSOP, REOP,

and RERR signals are valid. When RVAL is

Low, the RDAT[31:0], RMOD[1:0], RSOP,

REOP, and RERR signals are invalid and

must be disregarded.

RVAL_0

RVAL_1

RVAL_2

RVAL_3

C15

B18

E19

F22

3.3 V

LVTTL

Output

The RSX signal is valid only when RVAL is

Low.

32-bit Multi-PHY mode: RVAL_0 covers all

receive bits.

4 x 8 Single-PHY mode: The RVAL_0:3

bits correspond to the per-port data and

control signals.

Receive Start of Packet.

RSOP indicates the start of a packet when

asserted with RVAL.

RSOP_0

RSOP_1

RSOP_2

RSOP_3

B16

C18

E23

J18

3.3 V

LVTTL

32-bit Multi-PHY mode: RSOP_0 covers

all 32 bits.

Output

4 x 8 Single-PHY mode: The RSOP_0:3

bits correspond to the RDAT[7:0]_n

channels.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 3. SPI3 Interface Signal Descriptions (Sheet 8 of 8)

Signal Name

Ball

Type

Standard

Description

Designator

MPHY

SPHY

Receive End of Packet.

REOP indicates the end of a packet when

asserted with RVAL.

REOP_0

REOP_1

REOP_2

REOP_3

C16

D18

C23

J19

3.3 V

LVTTL

32-bit Multi-PHY mode: REOP_0 covers

all 32 bits.

Output

4 x 8 Single-PHY mode: The REOP_0:3

bits correspond to the RDAT[7:0]_n

channels.

Receive Word Modulo:

32-bit Multi-PHY mode: RMOD[1:0]

indicates the valid bytes of data in

RDAT[31:0]. During transmission, RMOD is

always “00”, except when the last double-

word is transferred on RDAT[31:0].

RMOD[1:0] specifies the valid packet data

bytes on RDAT[31:0] when REOP is

asserted.

RMOD[1:0]

Valid Bytes of RDAT

RMOD1

RMOD0

G13

G14

3.3 V

LVTTL

Output

00 = 4 bytes [31:0]

01 = 3 bytes [31:8]

10 = 2 bytes [31:16]

11 = 1 byte [31:24]

4 x 8 Single-PHY mode: RMOD[1:0] is not

required.

RMOD is considered valid only when RVAL

is simultaneously asserted.

RENB must be asserted for RMOD[1:0] to

be valid.

Receive Start of Transfer.

32-bit Multi-PHY mode: RSX indicates

when the in-band port address is present on

the RDAT bus. When RSX is High and

RVAL = 0, the value of RDAT[7:0] is the

address of the receive FIFO to be selected.

Subsequent data transfers on RDAT are

from the FIFO specified by this in-band

address. Values of 0, 1, 2, and 3 select the

corresponding port. RSX is ignored when

RVAL is de-asserted.

3.3 V

LVTTL

RSX

E13

Output

4 x 8 Single-PHY mode: RSX is ignored.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 4. SerDes Interface Signal Descriptions

Signal Name

Ball Designator

Type

Standard Description

TX_P_0

TX_P_1

TX_P_2

TX_P_3

Y13

AD13

W16

Output

SerDes

Transmit Differential Output, Positive.

AC18

TX_N_0

TX_N_1

TX_N_2

TX_N_3

Y14

AD14

Y16

AD18

Output

Input

Transmit Differential Output, Negative.

Receive Differential Input, Positive.¹

Receive Differential Input, Negative.¹

RX_P_0

RX_P_1

RX_P_2

RX_P_3

P22

V22

T24

U24

RX_N_0

RX_N_1

RX_N_2

RX_N_3

R22

U22

R24

V24

Input

1. Internally terminated differentially with 100 Ω.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 5. GMII Interface Signal Descriptions (Sheet 1 of 2)

Signal Name

Ball Designator

Type

Standard Description

TXD7_0

TXD6_0

TXD5_0

TXD4_0

TXD3_0

TXD2_0

TXD1_0

TXD0_0

AB4

AC3

AB3

AA3

TXD7_1

TXD6_1

TXD5_1

TXD4_1

TXD3_1

TXD2_1

TXD1_1

TXD0_1

AC9

AD8

AB8

AA7

AD9

AB9

AB7

AC7

Transmit Data.

Each bus carries eight data bits [7:0] of

the transmitted data stream to the PHY

device.

RGMII Mode: When a port is

configured in copper mode and the

RGMII interface is selected, only bits

TXD[3:0]_n are used. The data is

transmitted on both edges of TXC_0:3.

2.5 V

CMOS

Output

TXD7_2

TXD6_2

TXD5_2

TXD4_2

TXD3_2

TXD2_2

TXD1_2

TXD0_2

AA18

AA20

AB19

AD16

AB23

AB22

AB21

AB20

Fiber Mode: The following signals

have multiplexed functions when a port

is configured in fiber mode:

TXD4_n: TX_DISABLE_0:3

TXD7_3

TXD6_3

TXD5_3

TXD4_3

TXD3_3

TXD2_3

TXD1_3

TXD0_3

W14

AA16

Y15

AA14

V17

V16

V15

V14

Transmit Enable.

TX_EN_0

TX_EN_1

TX_EN_2

TX_EN_3

AB2

AC22

TX_EN indicates that valid data is

being driven on the corresponding

Transmit Data: TXD_0, TXD_1, TXD_2,

and TXD_3.

2.5 V

CMOS

Output

V12

Transmit Error:

TX_ER_0

TX_ER_1

TX_ER_2

TX_ER_3

AD6

AD17

AB13

2.5 V

CMOS

TX_ER indicates a transmit error in the

corresponding Transmit Data: TXD_0,

TXD_1, TXD_2, and TXD_3.

Source Synchronous Transmit

Clock.

TXC_0

TXC_1

TXC_2

TXC_3

AA1

AD7

AC20

This clock is supplied synchronous to

the transmit data bus in either RGMII or

GMII mode.

2.5 V

CMOS

Output

AB14

NOTE: Shares the same balls as RXC

on the RGMII interface.

NOTE: Refer to the RGMII interface for shared data and clock signals.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 5. GMII Interface Signal Descriptions (Sheet 2 of 2)

Signal Name

Ball Designator

Type

Standard Description

RXD7_0

RXD6_0

RXD5_0

RXD4_0

RXD3_0

RXD2_0

RXD1_0

RXD0_0

AC5

AB5

RXD7_1

RXD6_1

RXD5_1

RXD4_1

RXD3_1

RXD2_1

RXD1_1

RXD0_1

Y10

AA11

AC11

AD10

W11

Y11

Receive Data:

Each bus carries eight data bits [7:0] of

the received data stream.

RGMII Mode: When a port ID is

configured in copper mode and the

RGMII interface is selected, only bits

RXD[3:0]_n are used to receive data.

2.5 V

CMOS

Input

Fiber Mode: The following signals

have multiplexed functions when a port

is configured in fiber mode:

RXD7_2

RXD6_2

RXD5_2

RXD4_2

RXD3_2

RXD2_2

RXD1_2

RXD0_2

W20

V19

V20

W22

Y23

Y22

Y21

Y20

RXD4_n: MOD_DEF_0:3

RXD5_n: TX_FAULT_0:3

RXD6_n: RX_LOS_0:3

RXD7_3

RXD6_3

RXD5_3

RXD4_3

RXD3_3

RXD2_3

RXD1_3

RXD0_3

T19

T18

T17

T16

W18

Y19

Y18

Y17

Receive Data Valid.

RX_DV_0

RX_DV_1

RX_DV_2

RX_DV_3

AB11

Y24

V18

2.5 V

CMOS

RX_DV indicates that valid data is

being driven on Receive Data:

RXD[7:0]_n.

Input

RX_ER_0

RX_ER_1

RX_ER_2

RX_ER_3

Y12

AA22

U20

Receive Error.

2.5 V

CMOS

Input

RX_ER indicates an error in Receive

Data: RXD[7:0]_n.

CRS_0

CRS_1

CRS_2

CRS_3

AA5

AA9

AB15

AC16

Carrier Sense.

2.5 V

CMOS

CRS indicates the PHY device has

detected a carrier.

Receiver Reference Clock.

RXC operates at:

RXC_0

RXC_1

RXC_2

RXC_3

AD11

AA24

V23

2.5 V

CMOS

125 MHz for 1 Gigabit

Input

NOTE: Shares the same balls as RXC

on the RGMII interface.

NOTE: Refer to the RGMII interface for shared data and clock signals.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 6. RGMII Interface Signal Descriptions (Sheet 1 of 2)

Ball

Designator

Signal Name

Type

Standard

Description

TXC_0

TXC_1

TXC_2

TXC_3

AA1

AD7

AC20

Source Synchronous Transmit Clock.

2.5 V

CMOS

Output

This clock is supplied synchronous to the transmit

data bus in either RGMII or GMII mode.

AB14

TD3_0

TD2_0

TD1_0

TD0_0

AA3

TD3_1

TD2_1

TD1_1

TD0_1

AD9

AB9

AB7

AC7

Transmit Data.

Bits [3:0] are clocked on the rising edge of TXC.

Bits [7:4] are clocked on the falling edge of TXC.

2.5 V

CMOS

Output

TD3_2

TD2_2

TD1_2

TD0_2

AB23

AB22

AB21

AB20

NOTE: Shares data signals TXD[3:0]_n with the

GMII interface.

TD3_3

TD2_3

TD1_3

TD0_3

V17

V16

V15

V14

Transmit Control.

TX_CTL is TX_EN on the rising edge of TXC and a

logical derivative of TX_EN and TX_ER on the

falling edge of TXC.

TX_CTL_0

TX_CTL_1

TX_CTL_2

TX_CTL_3

AB2

AC22

2.5 V

CMOS

Output

V12

NOTE: TX_CTL multiplexes with TX_EN_n on the

GMII interface.

Receiver Reference Clock.

Operates at:

125 MHz for 1 Gigabit

25 MHz for 100 Mbps

2.5 MHz for 10 Mbps

RXC_0

RXC_1

RXC_2

RXC_3

AD11

AA24

V23

2.5 V

CMOS

Input

NOTE: Shares the same balls as RXC on the

GMII interface.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 6. RGMII Interface Signal Descriptions (Sheet 2 of 2)

Ball

Designator

Signal Name

Type

Standard

Description

RD3_0

RD2_0

RD1_0

RD0_0

RD3_1

RD2_1

RD1_1

RD0_1

W11

Y11

Receive Data.

Bits [3:0] are clocked on the rising edge of RXC.

Bits [7:4] are clocked on the falling edge of RXC.

2.5 V

CMOS

Input

RD3_2

RD2_2

RD1_2

RD0_2

Y23

Y22

Y21

Y20

NOTE: Shares balls with RXD[3:0]_0 on the GMII

interface.

RD3_3

RD2_3

RD1_3

RD0_3

W18

Y19

Y18

Y17

Receive Control.

RX_CTL is RX_DV on the rising edge of RXC and

a logical derivative of RX_DV and RERR on the

falling edge of RXC.

RX_CTL_0

RX_CTL_1

RX_CTL_2

RX_CTL_3

AB11

Y24

V18

2.5 V

CMOS

Input

NOTE: RX_CTL shares the same balls as RX_DV

on the GMII interface.

Table 7. CPU Interface Signal Descriptions (Sheet 1 of 2)

Ball

Designator

Signal Name

Type

Standard

Description

UPX_ADD10

UPX_ADD9

UPX_ADD8

UPX_ADD7

UPX_ADD6

UPX_ADD5

UPX_ADD4

UPX_ADD3

UPX_ADD2

UPX_ADD1

UPX_ADD0

UPX_ADD is the address bus from the

microprocessor.

Input

3.3 V LVTTL

16-bit mode: The data word select uses

UPX_BADD1.

UPX_BADD1

UPX_BADD0

Input

3.3 V LVTTL

8-bit mode: UPX_BADD[1:0] selects the individual

bytes.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 7. CPU Interface Signal Descriptions (Sheet 2 of 2)

Ball

Designator

Signal Name

Type

Standard

Description

UPX_DATA31

UPX_DATA30

UPX_DATA29

UPX_DATA28

UPX_DATA27

UPX_DATA26

UPX_DATA25

UPX_DATA24

UPX_DATA23

UPX_DATA22

UPX_DATA21

UPX_DATA20

UPX_DATA19

UPX_DATA18

UPX_DATA17

UPX_DATA16

UPX_DATA15

UPX_DATA14

UPX_DATA13

UPX_DATA12

UPX_DATA11

UPX_DATA10

UPX_DATA9

UPX_DATA8

UPX_DATA7

UPX_DATA6

UPX_DATA5

UPX_DATA4

UPX_DATA3

UPX_DATA2

UPX_DATA1

UPX_DATA0

L17

J17

H16

J16

M15

N15

K15

H14

K13

G12

K12

G11

H11

G10

K10

M10

N10

Data bus.

32-bit mode: Uses [31:0]

16-bit mode: Uses [15:0]

8-bit mode: Uses [7:0]

Input/

Output

3.3 V LVTTL

UPX_CS_L

UPX_WR_L

UPX_RD_L

Input

3.3 V LVTTL Chip Select. Active Low.

3.3 V LVTTL Write Strobe. Active Low.

3.3 V LVTTL Read Strobe. Active Low.

Cycle complete indicator.

Active Low.

Open

Drain

Output*

NOTE: An external pull-up resistor is required for

proper operation.

NOTE: *Dual-mode I/O

UPX_RDY_L

3.3 V LVTTL

Normal operation: Open drain output

Boundary Scan Mode: Standard CMOS

output

Data bus width select.

UPX_WIDTH[1:0] specifies the CPU bus width.

UPX_WIDTH1

UPX_WIDTH0

U16

UPX_WIDTH[1:0]

Mode

8-bit

Input

3.3 V LVTTL

16-bit

32-bit

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 8. Transmit Pause Control Interface Signal Descriptions

Ball

Designator

Signal Name

Type

Standard Description

TXPAUSEADD2

TXPAUSEADD1

TXPAUSEADD0

P21

P20

N20

2.5 V

CMOS

TXPAUSEADD[2:0] is the port selection address

for pause frame insertion.

Input

2.5 V

CMOS

TXPAUSEFR

T20

TX Pause Interface Strobe.

Table 9. Optical Module Interface Signal Descriptions (Sheet 1 of 2)

Ball

Designator

Signal Name

Type

Standard Description

Transmit Disable:

TX_DISABLE_0:3 outputs disable the Optical

Module Interface transmitter. An external pull-up

resistor usually resident in an optical module is

required for proper operation.

TX_DISABLE_0

TX_DISABLE_1

TX_DISABLE_2

TX_DISABLE_3

AB3

AA7

AD16

AA14

Open

Drain

Output*

2.5 V

CMOS

NOTE: These signals are multiplexed with the

TXD[4]_n bits of the GMII Interface

NOTE: *Dual-mode I/O

Normal operation: Open drain output

Boundary Scan Mode: Standard CMOS

output

MOD_DEF_0:3 inputs determine when an

Optical Module Interface is present.

MOD_DEF_0

MOD_DEF_1

MOD_DEF_2

MOD_DEF_3

AD10

W22

T16

2.5 V

CMOS

Input

NOTE: These signals are multiplexed with the

RXD[4]_n bits of the GMII interface.

RX_LOS_0:3 inputs determine when the Optical

Module Interface receiver loses synchronization.

RX_LOS_0

RX_LOS_1

RX_LOS_2

RX_LOS_3

AB5

AA11

V19

2.5 V

CMOS

NOTE: These signals are multiplexed with the

RXD[6]_n bits of the GMII interface.

T18

TX_FAULT_0:3 inputs determine an Optical

Module Interface transmitter fault.

TX_FAULT_0

TX_FAULT_1

TX_FAULT_2

TX_FAULT_3

AC11

V20

T17

2.5 V

CMOS

NOTE: These signals are multiplexed with the

RXD[5]_n bits of the GMII Interface.

Receiver Loss of Signal Interrupt.

RX_LOS_INT is an open drain interrupt output to

signal an RX_LOS condition.

Open

Drain

Output*

2.5 V

CMOS

NOTE: An external pull-up resistor is required

for proper operation.

NOTE: *Dual-mode I/O

RX_LOS_INT

P19

Normal operation: Open drain output

Boundary Scan Mode: Standard CMOS

output

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 9. Optical Module Interface Signal Descriptions (Sheet 2 of 2)

Ball

Designator

Signal Name

Type

Standard Description

Transmitter Fault Interrupt.

TX_FAULT_INT is an open drain interrupt output

that signals a TX_FAULT condition.

Open

Drain

Output*

2.5 V

CMOS

NOTE: An external pull-up resistor is

required for proper operation.

NOTE: *Dual-mode I/O

TX_FAULT_INT

P23

Normal operation: Open drain output

Boundary Scan Mode: Standard CMOS

output

Module Definition Interrupt.

MOD_DEF_INT is an open drain interrupt output

that signals a MOD_DEF condition.

Open

Drain

Output*

2.5 V

CMOS

NOTE: An external pull-up resistor is

required for proper operation.

NOTE: *Dual-mode I/O

MOD_DEF_INT

N22

L23

Normal operation: Open drain output

Boundary Scan Mode: Standard CMOS

output

2.5 V

CMOS

I²C_CLK is the clock used for the I²C bus

interface.

I²C_CLK

Output

I²C Data Bus.

I²C DATA_0:3 are the data I/Os for the I²C bus

interface.

I²C DATA_0

I²C DATA_1

I²C DATA_2

I²C DATA_3

L24

M24

N24

P24

Input/

Open

Drain

NOTE: An external pull-up resistor is

required for proper operation.

NOTE: *Dual-mode I/O

Normal operation: Input/ open drain

output

2.5 V

CMOS

Output*

Boundary Scan Mode: Standard CMOS

output

Table 10. MDIO Interface Signal Descriptions

Ball

Designator

Signal Name

Type

Standard Description

MDIO is the management data input and output.

Input/

Output

2.5 V

CMOS

MDIO

MDC

V21

NOTE: An external pull-up resistor is required for

proper operation.

2.5 V

CMOS

W24

Output

MDC is the management clock to external devices.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 11. LED Interface Signal Descriptions

Ball

Designator

Signal Name

Type

Standard Description

2.5 V

CMOS

LED_CLK

K24

Output

LED_CLK is the clock output for the LED block.

2.5 V

CMOS

LED_DATA

LED_LATCH

M22

L22

LED_DATA is the data output for the LED block.

LED_LATCH is the latch enable for the LED block.

2.5 V

CMOS

Table 12. JTAG Interface Signal Descriptions

Ball

Designator

Signal Name

Type

Standard Description

2.5 V

CMOS

TCLK

TMS

J22

Input

JTAG Test Clock

2.5 V

CMOS

H22

J24

H24

J23

Test Mode Select

2.5 V

CMOS

TDI

Input

Test Data Input

2.5 V

CMOS

TDO

Output

Input

Test Data Output

2.5 V

CMOS

TRST_L

Test Reset; reset input for JTAG test

Table 13. System Interface Signal Descriptions

Ball

Designator

Signal Name

Type

Standard Description

2.5 V

CMOS

CLK125 is the input clock to PLL; 125 MHz +/-

50 ppm

CLK125

AD19

Input

2.5 V

CMOS

SYS_RES_L

AD12

SYS_RES_L is the system hard reset (active Low).

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 14. Power Supply Signal Descriptions

Signal Name

Ball Designator

Type

Standard Description

B15

D12

F19

H12

J10

K19

L12

M17

N11

P10

A21

B19

D13

F23

H13

J15

K11

K23

L13

D17

F10

H17

K14

L15

M11

N17

P13

B10

D21

F15

H21

K16

L10

L20

M14

N21

P15

GND

M21

N14

P12

Input

–

Digital ground

R11

R23

U21

W15

AA8

AA21

R14

T10

U12

R16

T15

U13

W23

R19

U17

W10

AA4

W19

AA12 AA13 AA17

AB12 AC6 AC10

AC14 AC15 AC19 AD21

AVDD1P8_1

AVDD1P8_2

AVDD2P5_1

AVDD2P5_2

A20

T23

Input

1.8 V

2.5 V

Analog 1.8 V supply

Analog 2.5 V supply

AB16

AD20

U14

R18

A10

D11

F21

J14

K17

L14

P14

R17

U10

AA6

C12

D15

H10

J20

K21

L16

P16

R21

U15

D19

H15

T11

D10

J11

L11

P11

T14

W21

VDD

Input

1.8 V

Digital 1.8 V supply

AA10 AA15 AA19

J12

F12

B12

VDD2

VDD3

VDD4

VDD5

Input

3.3 V

2.5 V

Digital 3.3 V supply

Digital 2.5 V supply

M12

B13

F13

J13

M23

B17

F17

M13

B21

H19

M16

D23

H23

M19

N13

T13

W17

N16

U19

N19

U23

N23

W13

AA23 AC13 AC17

AC21

T12

W12

AA2

AC4

N12

AC8

AC12

Datasheet

Document Number: 278757

Revision Number: 007

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.4

Ball Usage Summary

Table 15. Ball Usage Summary

Type

Quantity

Inputs

158

126

Outputs

Bi-directional

Total Signals

Power

321

Ground

No Connects

Total

552

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.5

Multiplexed Ball Connections

4.5.1

GMII/RGMII/SerDes/OMI Multiplexed Ball Connections

T a ble 16 lists the balls used for the line-side interfaces (GMII, RGMII, SerDes/OMI) and provides

a guide to connect these balls. Some of these balls are multiplexed depending on the mode of

operation selected for that port.

Note: Do not connect any balls marked as unused (NC).

Table 16. Line Side Interface Multiplexed Balls (Sheet 1 of 2)

Copper Mode

Fiber Mode

Unused Port

Ball Designator

Optical Module/

SerDes Signal

GMII Signal

RGMII Signal

TXC_0:3

AA1

AD7

AC20

AB14

TXD[3:0]_0

TXD[3:0]_1

TXD[3:0]_2

TXD[3:0]_3

TD[3:0]_0

TD[3:0]_1

TD[3:0]_2

TD[3:0]_3

AA3

AD9

AB23

V17

AB9

AB22

V16

AB7

AB21

V15

AC7

AB20

V14

TXD4_0:3

TX_DISABLE_0:3²

AB3

AA7

AD16

AA14

TXD[7:5]_0

TXD[7:5]_1

TXD[7:5]_2

TXD[7:5]_3

AB4

AD8

AA20

AC3

AB8

AB19

AC9

AA18

W14

AA16

Y15

TX_EN_0:3

TX_ER_0:3

RXC_0:3

TX_CTL_0:3

AB2

AC22

AD17

AA24

V12

AB13

V23

AD6

AD11

RXC_0:3

GND

RXD[3:0]_0

RXD[3:0]_1

RXD[3:0]_2

RXD[3:0]_3

RD[3:0]_0

RD[3:0]_1

RD[3:0]_2

RD[3:0]_3

Y23

W18

W11

Y22

Y19

Y20

Y17

Y11

Y21

Y18

GND

RXD4_0:3

RXD5_0:3

RXD6_0:3

RXD7_0:3

RX_DV_0:3

RX_ER_0:3

CRS_0:3

COL_0:3

GND

RX_CTL_0:3

GND

MOD_DEF_0:3¹

TX_FAULT_0:3¹

RX_LOS_0:3¹

GND

AD10

AC11

AA11

Y10

W22

V20

T16

T17

AB5

AC5

V19

T18

W20

Y24

T19

GND

AB11

Y12

V18

GND

AA22

AB15

AD15

T24

U20

GND

AA5

AB6

P22

R22

Y13

Y14

AA9

AC16

AB17

U24

GND

AB10

V22

RX_P_0:3

RX_N_0:3

TX_P_0:3

TX_N_0:3

GND

U22

R24

V24

AD13

AD14

W16

Y16

AC18

AD18

1. An external pull-up resistor is required with most optical modules.

2. An open drain I/O, external 4.7 k Ω pull-up resistor is required.

Datasheet

Document Number: 278757

Revision Number: 007

Revision Date: March 25, 2004

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 16. Line Side Interface Multiplexed Balls (Sheet 2 of 2)

Copper Mode

Fiber Mode

Unused Port

Ball Designator

Optical Module/

SerDes Signal

GMII Signal RGMII Signal

TX_FAULT_INT²

RX_LOS_INT²

MOD_DEF_INT²

P23

P19

N22

W24

V21

L23

L24

MDC

MDIO²

MDC

MDIO²

I²C_CLK

I²C_DATA_0:3²

M24

N24

P24

1. An external pull-up resistor is required with most optical modules.

2. An open drain I/O, external 4.7 k Ω pull-up resistor is required.

4.5.2

SPI3 MPHY/SPHY Ball Connections

T a ble 17 lists the balls used for the SPI3 Interface and provides a guide to connect these balls in

MPHY and SPHY mode.

Table 17. SPI3 MPHY/SPHY Interface (Sheet 1 of 3)

SPI3 Signals

Ball Number

Comments

MPHY

SPHY

TDAT[31:24]

TDAT[7:0]_3

E10

MPHY: Consists of a single 32-bit data

bus

TDAT[23:16]

TDAT[15:8]

TDAT[7:0]

TDAT[7:0]_2

TDAT[7:0]_1

TDAT[7:0]_0

SPHY: Separate 8-bit data bus for each

Ethernet port

To achieve maximum bandwidth, set

TFCLK as follows:

TFCLK

MPHY: 133 Mhz

SPHY: 125 Mhz.

TPRTY_0

GND

TPRTY_0

TPRTY_1

TPRTY_2

TPRTY_3

TENB_0

TENB_1

TENB_2

TENB_3

MPHY: Use TPRTY_0 as the TPRTY

signal.

SPHY: Each port has its own dedicated

TPRTY_n signal.

GND

TENB_0

VDD2

MPHY: Use TENB_0 as the TENB

signal.

SPHY: Each port has its own dedicated

TENB_n signal.

Datasheet

Document Number: 278757

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 17. SPI3 MPHY/SPHY Interface (Sheet 2 of 3)

SPI3 Signals

MPHY SPHY

TERR_0 TERR_0

Ball Number

Comments

E11

MPHY: Use TERR_0 as the TERR

GND

TERR_1

TERR_2

TERR_3

TSOP_0

TSOP_1

TSOP_2

TSOP_3

TEOP_0

TEOP_1

TEOP_2

TEOP_3

GND

signal.

SPHY: Each port has its own dedicated

TERR_n signal

GND

TSOP_0

GND

C10

MPHY: Use TSOP_0 as the TSOP

signal.

SPHY: Each port has a dedicated

TSOP_n signal.

GND

TEOP_0

GND

MPHY: Use TEOP_0 as the TEOP

signal.

SPHY: Each port has a dedicated

TEOP_n signal.

GND

A12

GND

TMOD[1:0]

TSX

TSX and TMOD[1:0] are only applicable

in MPHY mode.

GND

TADR[1:0]

A11

Used to address port for PTPA signal.

PTPA can be used in MPHY and SPHY

modes.

PTPA

B11

DTPA is available on a per-port basis in

both MPHY and SPHY modes.

DTPA_0:3

STPA

DTPA_0:3

C11

STPA is only applicable in MPHY mode.

F24

G21

G24

G20

G23

G19

G22

G18

RDAT[31:24]

RDAT[7:0]_3

E21

C21

E22

C20

D22

B22

C22

B20

MPHY: Consists of a single 32 bit data

bus.

RDAT[23:16]

RDAT[15:8]

RDAT[7:0]

RDAT[7:0]_2

RDAT[7:0]_1

RDAT[7:0]_0

SPHY: Separate 8-bit data bus for each

Ethernet port.

F18

E16

E18

D16

E17

C17

F16

A17

F14

C14

E14

B14

D14

A15

C13

A14,

To achieve maximum bandwidth, set

RFCLK as follows:

RFCLK

A19

MPHY: 133 Mhz.

SPHY: 125 Mhz.

RPRTY_0

RPRTY_1

RPRTY_2

RPRTY_3

RENB_0

RENB_1

RENB_2

RENB_3

E15

G16

E20

F20

A13

A18

C19

E24

MPHY: Use RPRTY_0 as the RPRTY

signal.

SPHY: Each port has a dedicated

RPRTY_n signal.

RENB_0

VDD2

MPHY: Use RENB_0 as the RENB

signal.

SPHY: Each port has a dedicated

RENB_n signal

Datasheet

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 17. SPI3 MPHY/SPHY Interface (Sheet 3 of 3)

SPI3 Signals

Ball Number

Comments

MPHY

SPHY

RERR_0

A16

G17

D20

H20

C15

B18

E19

F22

B16

C18

E23

J18

MPHY: Use RERR_0 as the RERR

signal.

RERR_1

RERR_2

RERR_3

RVAL_0

RVAL_1

RVAL_2

RVAL_3

RSOP_0

RSOP_1

RSOP_2

RSOP_3

REOP_0

REOP_1

REOP_2

REOP_3

SPHY: Each port has a dedicated

RERR_n signal

RVAL_0

MPHY: Use RVAL_0 as the RVAL

signal.

SPHY: Each port has a dedicated

RVAL_n signal.

RSOP_0

MPHY: Use TSOP_0 as the TSOP

signal.

SPHY: Each port has a dedicated

TSOP_n signal.

REOP_0

C16

D18

C23

J19

MPHY: Use TEOP_0 as the TEOP

signal.

SPHY: Each port has a dedicated

TEOP_n signal.

RMOD[1:0]

RSX

G13

E13

G14

RSX and RMOD[1:0] are applicable

only in MPHY mode.

4.6

Ball State During Reset

Table 18. Definition of Output and Bi-directional Balls During Hardware Reset (Sheet 1 of 2)

Interface

Ball Name

DTPA_0:3

Ball Reset State Comment

0x0

–

STPA

PTPA

0x0

RDAT[31:0]

RVAL_0:3

RERR_0:3

RPRTY_0:3

RMOD[1:0]

RSX

0x00000000

0x0

SPI3

0x0

RSOP_0:3

REOP_0:3

0x0

NOTE: Z = High impedance.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 18. Definition of Output and Bi-directional Balls During Hardware Reset (Sheet 2 of 2)

Interface

JTAG

Ball Name

TDO

Ball Reset State Comment

0x0

High Z

0x0

–

MDIO

Bi-directional

MDIO

CPU

MDC

–

UPX_DATA[31:0]

UPX_RDY_L

LED_CLK

LED_DATA

LED_LATCH

High Z

0X1

Bi-directional

Open-drain output, requires an external pull-up

0x0

–

LED

0x0

Fiber mode is the default. Copper interfaces are

disabled.

TXC_0:3

High Z

Fiber mode is the default.

TXD[7:0]_0

Bit 4 is driven by the optical module as MOD_DEF_0.

Fiber mode is the default.

TXD[7:0]_1

TXD[7:0]_2

TXD[7:0]_3

High Z

Bit 4 is driven by the optical module as MOD_DEF_1.

Fiber mode is the default.

GMII/RGMII

Bit 4 is driven by the optical module as MOD_DEF_2.

Fiber mode is the default.

Bit 4 is driven by the optical module as MOD_DEF_3.

Fiber mode is the default.

Copper interfaces are disabled.

TX_EN_0:3

TX_ER_0:3

TX_CTL_0:3

High Z

Fiber mode is the default.

Copper interfaces are disabled.

Fiber mode is the default.

Copper interfaces are disabled.

RGMII

TX_P_0:3

0x0

–

SerDes

TX_N_0:3

–

TX_FAULT_INT

RX_LOS_INT

High Z

0x1

Open-drain output, requires external pull-up.

–

Optical Module MOD_DEF_INT

I²C_CLK

I²C_DATA_0:3

0xF

Open-drain output, requires external pull-up.

NOTE: Z = High impedance.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

4.7

Power Supply Sequencing

Follow the power-up and power-down sequences described in this section to ensure correct

IXF1104 operation. The sequence described in Section 4.7 covers all IXF1104 digital and analog

supplies.

Caution: Failure to follow the sequence described in this section might damage the IXF1104.

4.7.1

Power-Up Sequence

Ensure that the 1.8 V analog and digital supplies are applied and stable prior to application of the

2.5 V analog and digital supplies.

4.7.2

Power-Down Sequence

Remove the 2.5 V supplies prior to removing the 1.8 V power supplies (the reverse of the power-up

sequence).

Caution: Damage can occur to the ESD structures within the analog I/Os if the 2.5 V digital and analog

supplies exceed the 1.8 V digital and analog supplies by more than 2.0 V during power-up or

power-down.

Figure 5 and T a ble 19 provide the IXF1104 power supply sequencing.

Figure 5. Power Supply Sequencing

2.5 V Supplies Stable

1.8 V Supplies Stable

Time

Sys_Res

AVDD2P5_1 and AVDD2P5_2

t=0

Apply VDD, AVDD1P8_1, and

Apply VDD4, VDD5,

AVDD1P8_2

NOTE: The 3.3 V supply (VDD2 and VDD3) can be applied at any point during this sequence.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 19. Power Supply Sequencing

Time Delta to

Power Supply

Power-Up Order

Notes

Next Supply¹

VDD, AVDD1P8_1,

First

1.8 V supplies

AVDD1P8_2

VDD4, VDD5,

AVDD2P5_1,

AVDD2P5_2

Second

10 µs

2.5 V supplies

1. The value of 10 µs given is a nominal value only. The exact time difference between the application of the 2.5 V analog

supply is determined by a number of factors, depending on the power management method used. To avoid damage to the

IXF1104, the TXAV25 supply must not exceed the VDD supply by more than 2 V at any time during the power-up or

power-down sequence.

NOTE: The 3.3 V supply (VDD2 and VDD3) can be applied at any point during this sequence.

4.8

Pull-Up/Pull-Down Ball Guidelines

The signals shown in Table 20 require the addition of a pull-up or pull-down resistor to the board

design for normal operation. Any balls marked as unused (NC) should be unconnected.

Table 20. Pull-Up/Pull-Down and Unused Ball Guidelines

Pin Name

Pull-Up/Pull-Down

Comments

TX_FAULT_INT

RX_LOS_INT

MOD_DEF_INT

TDI

Pull-up

Pull-down

Pull-up

4.7 k Ω to 2.5 V. Optical module signal with open-drain I/O.

10 k Ω to 3.3 V. JTAG test pin.

4.7 k Ω to 2.5 V

TDO

TMS

TCLK

TRST_L

MDIO

UPX_RDY_L

I²C_DATA_0:3

TX_DISABLE_0:3

4.7 k Ω to 3.3 V

4.7 k Ω to 2.5 V

4.9

Analog Power Filtering

Figure 21 illustrates an analog power supply filter network and Table 21 lists the analog power

balls.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Figure 6. Analog Power Supply Filter Network

2.5 or 1.8 V

VDD

Analog

Power Ball

0.1 µF

Table 21. Analog Power Balls

Ball

Designator

Signal Name

Comments

AVDD1P8_1

AVDD2P5_1

AVDD1P8_2

AVDD2P5_2

AD20

AB16 T23

U14 R18

A20

Need to provide a filter (see Figure 6).

R: AVDD1P8_1 and AVDD2P5_1 = 5.6 Ω resistor.

Need to provide a filter (see Figure 6).

R: AVDD1P8_2 and AVDD2P5_2 = 1.0 Ω resistor.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.0

Functional Descriptions

5.1

Media Access Controller (MAC)

The IXF1104 main functional block consists of four independent 10/100/1000 Mbps Ethernet

MACs, which support interfaces for fiber and copper connectivity.

• Copper Mode:

— RGMII for 10/100/1000 Mbps full-duplex operation and 10/100 Mbps half-duplex

operation

— GMII for 1000 Mbps full-duplex operation

• Fiber Mode:

— Integrated SerDes/OMI interface for direct connection to optical modules

— 1000 Mbps full-duplex operation in fiber mode

The following features support copper and fiber modes:

• Programmable Options:

— Automatic padding of transmitted packets that are less than the minimum frame size

— Broadcast, multicast, and unicast address filtering on frames received

— Filter and drop packets with errors

— Pre-padded RX frames with two bytes (aligns the Ethernet payload on SPI3 and in

network processor memories)

— Remove CRC from RX frames

— Append CRC to transmitted frames

• Performance Monitoring and Diagnostics:

— Loopback modes

— Detection of runt and overly large packets

— Cyclic Redundancy Check (CRC) calculation and error detection

— RMON statistics for dropped packets, packets with errors, etc.

• Compliant with IEEE Spec 802.3x standard for flow control

— Receive and execute PAUSE Command Frames

• Support for non-standard packet sizes up to 10 KB including loss-less flow control

Note: The IXF1104 does not support 10/100 Mbps operation when configured in GMII mode

The MAC is fully integrated, designed for use with Ethernet 802.3 frame types, and compliant to

all of the IEEE 802.3 MAC requirements.

The MAC adds preamble and Start-of-Frame Delimiter (SFD) to all frames sent to it (transmit

path) and removes preamble and SFD on all frames received by it (receive path). A CRC check is

also applied to all transmit and receive packets. CRC is optionally appended to transmit packets.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

CRC is removed optionally from receive packets after validation, and is not forwarded to SPI3.

Packets with a bad CRC are marked, counted in the statistics block, and may be optionally

dropped. A bad packet may be signaled with RERR on the SPI3 interface if it is not dropped.

The MAC operates only in full-duplex mode at 1000 Mbps rates on both SerDes and GMII

interface connections. The MAC is capable of operation at 1000 Mbps, full-duplex in RGMII

mode, and at full-duplex and half-duplex operation for 10/100 Mbps links.

5.1.1

Features for Fiber and Copper Mode

Section 5.1.1.1 through Section 5.1.1.4 cover MAC functions that are independent of the line-side

interface.

5.1.1.1

Padding of Undersized Frames on Transmit

The padding feature allows Ethernet frames smaller than 64 bytes to be transferred from the SPI3

interface to the TX MAC and padded up to 64 bytes automatically by the MAC. This feature is

enabled by setting bit 7 of the “Diverse Config Write ($ Port_Index + 0x18)".

Note: When the user selects the padding function, the MAC core adds an automatically calculated CRC

to the end of the transmitted packet.

5.1.1.2

Automatic CRC Generation

Automatic CRC Generation is used in conjunction with the padding feature to generate and append

a correct CRC to any transmit frame. This feature is enabled by setting bit 6 of the “Diverse Config

Write ($ Port_Index + 0x18)".

5.1.1.3

Filtering of Receive Packets

This feature allows the MAC to filter receive packets under various conditions and drop the

packets through an interaction with the Receive FIFO control.

5.1.1.3.1 Filter on Unicast Packet Match

This feature is enabled when bit 0 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 1.

Any frame received in this mode that does not match the Station Address (MAC address) is marked

by the MAC to be dropped. The frame is dropped if the appropriate bit in the “RX FIFO Errored

Frame Drop Enable ($0x59F)" = 1. Otherwise, the frame is sent out the SPI3 interface and may

optionally be signaled with an RERR (see bit 0 in “SPI3 Receive Configuration ($0x701)” on

page 214).

When bit 0 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 0, all unicast frames are sent

out the SPI3 interface.

Note: The VLAN filter overrides the unicast filter. Therefore, a VLAN frame cannot be filtered based on

the unicast address.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.1.1.3.2 Filter on Multicast Packet Match

This feature is enabled when bit 1 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 1.

Any frame received in this mode that does not match the Port Multicast Address (reserved

multicast address recognized by MAC) is marked by the MAC to be dropped. The frame is dropped

if the appropriate bit in the “RX FIFO Errored Frame Drop Enable ($0x59F)" = 1. Otherwise, the

frame is sent out the SPI3 interface and may optionally be signaled with an RERR (see bit 0 in

“SPI3 Receive Configuration ($0x701)” on page 214).

When bit 1 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 0, all multicast frames are

sent out the SPI3 interface.

5.1.1.3.3 Filter Broadcast Packets

This feature is enabled when bit 2 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 1.

Any broadcast frame received in this mode is marked by the MAC to be dropped. The frame is

dropped if the appropriate bit in the “RX FIFO Errored Frame Drop Enable ($0x59F)" = 1.

Otherwise, the frame is sent out the SPI3 interface and may optionally be signaled with an RERR

(see bit 0 in “SPI3 Receive Configuration ($0x701)” on page 214).

When bit 2 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 0, all broadcast frames are

sent out the SPI3 interface.

5.1.1.3.4 Filter VLAN Packets

This feature is enabled when bit 3 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 1.

VLAN frames received in this mode are marked by the MAC to be dropped. The frame is dropped

if the appropriate bit in the “RX FIFO Errored Frame Drop Enable ($0x59F)" = 1. Otherwise, the

VLAN frame is sent out the SPI3 interface and may optionally be signaled with an RERR (see bit 0

in “SPI3 Receive Configuration ($0x701)” on page 214).

When bit 3 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 0, all VLAN frames are sent

out the SPI3 interface.

5.1.1.3.5 Filter Pause Packets

This feature is enabled when bit 4 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 0.

Pause frames received in this mode are marked by the MAC to be dropped. The frame is dropped if

the appropriate bit in the “RX FIFO Errored Frame Drop Enable ($0x59F)" = 1. Otherwise, the

pause frame is sent out the SPI3 interface and may optionally be signaled with an RERR (see bit 0

in “SPI3 Receive Configuration ($0x701)” on page 214).

When bit 4 of the “RX Packet Filter Control ($ Port_Index + 0x19)" = 1, all pause frames are sent

out the SPI3 interface.

Note: Pause packets are not filtered if flow control is disabled in the “FC Enable ($ Port_Index + 0x12)”.

5.1.1.3.6 Filter CRC Error Packets

This feature is enabled when bit 5 of the “RX Packet Filter Control ($ Port_Index + 0x19)” = 0.

Frames received with an errored CRC are marked as bad frames and may optionally be dropped in

the RX FIFO. Otherwise, the frames are sent to the SPI3 interface and may be optionally signaled

with an RERR (see T a ble 22 “CRC Errored Packets Drop Enable Behavior” on page 68).

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

When the CRC Error Pass Filter bit = 0 (“RX Packet Filter Control ($ Port_Index + 0x19)”), it

takes precedence over the other filter bits. Any packet (Pause, Unicast, Multicast or Broadcast

packet) with a CRC error will be marked as a bad frame when the CRC Error Pass Filter bit = 0.

Table 22. CRC Errored Packets Drop Enable Behavior

RX FIFO Errored-

CRC Error

Pass¹

RERR

Frame Drop

Actions

Enable³

Enable²

When CRC Errored PASS = 1, CRC errored packets

are not filtered and are passed to the SPI3 interface.

They are not marked as bad, cannot be dropped, and

cannot be signaled with RERR.

Packets are marked as bad but not dropped in the

RX FIFO. These packets are sent to the SPI3

interface, and are signaled with an RERR to the

switch or Network Processor.

Packets are marked as bad but not dropped in the

RX FIFO. These packets are sent to the SPI3

interface, and are not signaled with an RERR.

CRC errored packets are marked as bad, dropped in

the RX FIFO, and never appear at the SPI3 interface.

NOTE: Packet sizes above the RX FIFO Transfer

Threshold (see T a ble 128 through T able 131)

cannot be dropped in the RX FIFO and are

passed to the SPI3 interface. These packets

can optionally be signaled with RERR on the

SPI3 interface if the RERR Enable bit = 1.

1. See T a ble 91 “RX Packet Filter Control ($ Port_Index + 0x19)” on page 171.

2. See T a ble 123 “RX FIFO Errored Frame Drop Enable ($0x59F)” on page 195.

3. See T a ble 147 “SPI3 Receive Configuration ($0x701)” on page 214.

NOTE: x = “DON’T CARE”

5.1.1.4

5.1.2

CRC Error Detection

Frames received by the MAC are checked for a correct CRC. When an incorrect CRC is detected

on a received frame, the RX FCSError RMON statistic counter is incremented for each CRC

errored frame. Received frames with CRC errors may optionally be dropped in the RX FIFO (refer

to Section 5.1.1.3.6, “Filter CRC Error Packets” on page 67). Otherwise, the frames are sent to the

SPI3 interface and may be dropped by the switch or system controller.

Frames transmitted by the MAC are also checked for correct CRC. When an incorrect CRC is

detected on a transmitted frame, the TX CRCError RMON statistic counter is incremented for each

incorrect frame.

Flow Control

Flow Control is an IEEE 802.3x-defined mechanism for one network node to request that its link

partner take a temporary “Pause” in packet transmission. This allows the requesting network node

to prevent FIFO overruns and dropped packets, by managing incoming traffic to fit its available

memory. The temporary pause allows the device to process packets already received or in transit,

thus freeing up the FIFO space allocated to those packets.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

The IXF1104 MAC implements the IEEE 802.3x standard RX FIFO threshold-based Flow Control

in copper and fiber modes. When appropriately programmed, the MAC can both generate and

respond to IEEE standard pause frames in full-duplex operation. The IXF1104 also supports

externally triggered flow control through the Transmit Pause Control interface.

In half-duplex operation, the MAC generates collisions instead of sending pause frames to manage

the incoming traffic from the link partner

5.1.2.1

802.3x Flow Control (Full-Duplex Operation)

The IEEE 802.3x standard identifies four options related to system flow control:

• No Pause

• Symmetric Pause (both directions)

• Asymmetric Pause (Receive direction only)

• Asymmetric Pause (Transmit direction only)

The IXF1104 supports all four options on a per-port basis. Bits 2:0 of the “FC Enable ($ Port_Index

+ 0x12)” on page 167 provide programmable control for enabling or disabling flow control in each

direction independently.

The IEEE 802.3x flow control mechanism is accomplished within the MAC sublayer, and is based

on RX FIFO thresholds called watermarks. The RX FIFO level rises and falls as packets are

received and processed. When the RX FIFO reaches a watermark (either exceeding a High or

dropping below a Low after exceeding a High), the IXF1104 control sublayer signals an internal

state machine to transmit a PAUSE frame. The FIFOs automatically generate PAUSE frames (also

called control frames) to initiate the following:

• Halt the link partner when the High watermark is reached.

• Restart the link partner when the data stored in the FIFO falls below the Low watermark.

Figure 7 illustrates the IEEE 802.3 FIFO flow control functions.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 7. Packet Buffering FIFO

MDI

SPI3 Interface

High Watermark

TX FIFO

TX Side

MAC

Data Flow

MAC Transfer Threshold

Low Watermark

High Watermark

Low Watermark

Data Flow

RX FIFO

RX Side

MAC

RX FIFO High

802.3 Flow

Control

TXPAUSEFR (External

Strobe)

802.3x Pause Frame Generation

B3231-01

5.1.2.1.1 Pause Frame Format

PAUSE frames are MAC control frames that are padded to the minimum size (64 bytes). Figure 8

and Figure 9 illustrate the frame format and contents.

Figure 8. Ethernet Frame Format

Number of bytes

46-1500

Data

Type/

Length

Preamble

FCS

Ethernet Frame

Note: 64 Byte Minimum / 1518 bytes Maximum

B2277-01

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 9. PAUSE Frame Format

Number of bytes

DA* or

01-80-

C2-00-

00-01

Pause

Opcode

(00-01)

Pause

Length (with 0s)

Pad

Preamble

88-08

FCS

64 Bytes

Note: In the Intel^®IXF1104 architecture, the TX block of the MAC sets this as the pause multicast address.

The RX interface of the MAC will process this as the pause multicast or the MAC address.

B3218-01

An IEEE 802.3 MAC PAUSE frame is identified by detecting all of the following:

• OpCode of 00-01

• Length/Type field of 88-08

• DA matching the unique multicast address (01-80-C2-00-00-01)

XOFF. A PAUSE frame informs the link partner to halt transmission for a specified length of time.

The PauseLength octets specify the duration of the no-transmit period. If this time is greater than

zero, the link partner must stop sending any further packets until this time has elapsed. This is

referred to as XOFF.

XON. The MAC continues to transmit PAUSE frames with the specified Pause Length as long as

the FIFO level exceeds the threshold. If the FIFO level falls below the threshold before the Pause

Length time expires, the MAC sends another PAUSE frame with the Pause Length time specified

as zero. This is referred to as XON and informs the link partner to resume normal transmission of

packets.

5.1.2.1.2 Pause Settings

The MAC must send PAUSE frames repeatedly to maintain the link partner in a Pause state. The

following two inter-related variables control this process:

• Pause Length is the amount of time, measured in multiples of 512 bit times, that the MAC

requests the link partner to halt transmission for.

• Pause Threshold is the amount of time, measured in multiples of 512 bit times, prior to the

expiration of the Pause Length that the MAC transmits another Pause frame to maintain the

link partner in the pause state.

The transmitted Pause Length in the IXF1104 is set by the “FC TX Timer V a lue ($ Port_Index +

0x07)” on page 163.

The IXF1104 PAUSE frame transmission interval is set by the “Pause Threshold ($ Port_Index +

0x0E)” on page 165.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.1.2.1.3 Response to Received PAUSE Command Frames

When Flow Control is enabled in the receive direction (bit 0 in the “FC Enable ($ Port_Index +

0x12)"), the IXF1104 responds to PAUSE Command frames received from the link partner as

follows:

1. The IXF1104 checks the entire frame to verify that it is a valid PAUSE control frame

addressed to the Multicast Address 01-80-C2-00-00-01 (as specified in IEEE 802.3, Annex

31B) or has a Destinations Address matching the address programmed in the “Station Address

($ Port_Index +0x00 – +0x01)".

2. If the PAUSE frame is valid, the transmit side of the IXF1104 pauses for the required number

of PAUSE Quanta, as specified in IEEE 802.3, Clause 31.

3. PAUSE does not begin until completion of the frame currently being transmitted.

The IXF1104 response to valid received PAUSE frames is independent of the PAUSE frame filter

settings. Refer to Section 5.1.1.3.5, “Filter Pause Packets” on page 67 for additional details.

Note: Pause packets are not filtered if flow control is disabled in bit 0 of the “FC Enable ($ Port_Index +

0x12)”.

5.1.2.1.4 Half-Duplex Operation

Transmit flow control is implemented only in half-duplex operation. Upon entering the flow

control state, the MAC generates a collision for all subsequent receive packets until exiting the

flow control state. Any receive packet in progress when the MAC enters the flow control state will

not be collided with but could be lost due if there is insufficient FIFO depth to complete packet

reception. Bit 2 of the “FC Enable ($ Port_Index + 0x12)" enables the transmit flow control

function.

5.1.2.1.5 Transmit Pause Control Interface

The Transmit Pause Control interface allows an external device to trigger the generation of pause

frames. The Transmit Pause Control interface is completely asynchronous. It consists of three

address signals (TXPAUSEADD[2:0]) and a strobe signal (TXPAUSEFR). The required address

for this interface operation is placed on the TXPAUSEADD[2:0] signals and the TXPAUSEFR is

pulsed High and returned Low. Refer to Figure 10 “Transmit Pause Control Interface” on page 73

and Table 55 “Transmit Pause Control Interface Timing Parameters” on page 150. T a ble 23 shows

the valid decodes for the TXPAUSEADD[2:0] signals. Figure 10 illustrates the transmit pause

control interface.

Note: Flow control must be enabled in the “FC Enable ($ Port_Index + 0x12)” for Transmit Pause

Control interface operation.

Note: There are two additional decodes provided that allow the user to generate either an XOFF frame or

XON frame from all ports simultaneously.

The default pause quanta for each port is held by the “FC TX Timer Value ($ Port_Index + 0x07)").

The default value of this register is 0x05E after reset is applied.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Table 23. Valid Decodes for TXPAUSEADD[2:0]

TXPAUSEADD_2:0

Operation of TX Pause Control Interface

Transmits a PAUSE frame on every port with a pause_time = ZERO (XON)

(Cancels all previous pause commands).

0x0

Transmits a PAUSE frame on port 0 with pause_time equal to the value programmed

in the port 0 “FC TX Timer Value ($ Port_Index + 0x07)" (XOFF).

0x1

Transmits a PAUSE frame on port 1 with pause_time equal to the value programmed

in the port 1 “FC TX Timer Value ($ Port_Index + 0x07)" (XOFF).

0x2

Transmits a PAUSE frame on port 2 with pause_time equal to the value programmed

in the port 2 “FC TX Timer Value ($ Port_Index + 0x07)" (XOFF).

0x3

Transmits a PAUSE frame on port 3 with pause_time equal to the value programmed

in the port 3 “FC TX Timer Value ($ Port_Index + 0x07)" (XOFF).

0x4

Reserved. Do not use these addresses. The TX Pause Control interface will not

operate under these conditions.

0x5 to 0x6

Transmits a PAUSE frame on every port with pause_time equal to the value

programmed in the “FC TX Timer V a lue ($ Port_Index + 0x07)" for each port

(XOFF).

0x7

Figure 10. Transmit Pause Control Interface

TXPAUSEFR

TXPAUSEADD0

TXPAUSEADD1

TXPAUSEADD2

This example shows the following conditions:

Strobe 1:

Port 0: Transmit Pause Packet (XOFF)

Strobe 2:

All Ports: Transmit Pause Packet with pause_time = 0 (XON)

Strobe 3:

Port 3: Transmit Pause Packet (XOFF)

B3234-01

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.1.3

Mixed-Mode Operation

The Intel^®IXF1104 gives the user the option of configuring each port for 10/100 Mbps half-duplex

copper, 10/100/1000 Mbps full-duplex copper, or 1000 Mbps full-duplex fiber operation. This

gives the Intel^®IXF1104 the ability to support both copper and fiber operation line-side interfaces

operating at the same time within a single device. (Refer to Figure 16 “Line Side Interface

Multiplexed Balls” on page 57.)

The Intel^®IXF1104 provides complete flexibility in line-side connectivity by offering RGMII,

integrated SerDes, and GMII.

5.1.3.1

Configuration of the IXF1104

The memory maps (Table 59 “MAC Control Registers ($ Port Index + Offset)” on page 155

through T a ble 69 “Optical Module Registers ($ 0x799 - 0x79F)” on page 161) are logically split

into the following two distinct regions:

• Per-Port Registers

• Global Registers

To achieve a desired configuration for a given port, the relevant per-port registers must be

configured correctly by the user. The Table 59 through T a ble 69 also contain registers that affect

the operation of all ports, such as the SPI3 interface configuration.

See Section 8.0, “Register Set” on page 154 for a complete description of IXF1104 configuration

and status registers. The Register Maps (T a ble 59 through T a ble 69) present a summary of

important configuration registers.

Note: The initialization sequence provided in Section 6.1, “Change Port Mode Initialization Sequence”

on page 129 must be followed for proper configuration of the IXF1104.

5.1.3.2

Key Configuration Registers

The following key registers select the operational mode of a given port:

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Table 24. Operational Mode Configuration Registers

Address

Description

0x002 – Port 0

0x082 – Port 1

0x102 – Port 2

0x182 – Port 3

The “Desired Duplex ($ Port_Index + 0x02)” on page 162 defines

whether a port is to be configured for full-duplex or half-duplex

operation.

NOTE: Half-duplex operation is only valid for 10/100 speeds where the

RGMII line interface has been selected.

“Desired Duplex

($ Port_Index +

0x02)"

The “MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)” on

page 166 determines the MAC operational frequency and mode for a

given port.

NOTE: Set the “Clock and Interface Mode Change Enable Ports 0 - 3

($0x794)” on page 220 to 0x0 prior to any change in the

frequency is controlled correctly. If the “Clock and Interface

Mode Change Enable Ports 0 - 3 ($0x794)" is not used

correctly, the IXF1104 may not be configured to the proper

mode.

“MAC IF Mode

and RGMII

Speed ($

Port_Index +

0x10)"

0x010 – Port 0

0x090 – Port 1

0x110 – Port 2

0x190 – Port 3

0x500

Bit 0 – Port 0

Bit 1 – Port 1

Bit 2 – Port 2

Bit 3 – Port 3

Each “Port Enable ($0x500)" bit relates to a port. Set the appropriate bit

to 0x1 to enable a port. This should be the last step in the configuration

process for a port.

“Port Enable

($0x500)"

The “Interface Mode ($0x501)" selects whether a port operates with a

copper (RGMII or GMII) line-side interface an integrated SerDes fiber

line-side interface.

0x501

Bit 0 – Port 0

Bit 1 – Port 1

Bit 2 – Port 2

Bit 3 – Port 3

“Interface Mode

($0x501)"

For copper operation for a given port, set the relevant bit to 0x1.

For fiber operation for a given port, set the relevant bit to 0x0.

NOTE: All ports are configured for fiber operation in the IXF1104

default mode of operation.

The “Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)"

indicates to an internal clock generator when to sample the new value

of the “MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)" and the

“Interface Mode ($0x501)" (copper/fiber).

0x794

“Clock and

Interface Mode

Bit 0 – Port 0

Change Enable Bit 1 – Port 1

Ports 0 - 3

($0x794)"

When any of these two configuration values are changed for a port, the

corresponding bits must be kept in this register under reset by writing

0x0 to the relevant bit.

Bit 2 – Port 2

Bit 3 – Port 3

NOTE: The initialization sequence provided in Section 6.1, “Change Port Mode Initialization

Sequence” on page 129 must be followed for proper configuration of the IXF1104.

5.1.4

Fiber Mode

When the IXF1104 is configured for fiber mode, the TX Data path from the MAC is an internal

10-bit interface as described in the IEEE 802.3z specification. It is connected directly to an internal

SerDes block for serialization/deserialization and transmission/reception on the fiber medium to

and from the link partner.

The MAC contains all of the PCS (8B/10B encoding and 10B/8B decoding) required to encode and

decode the data. The MAC also supports auto-negotiation per the IEEE 802.3z specification via

access to the “TX Config Word ($ Port_Index + 0x17)", “RX Config Word ($ Port_Index + 0x16)",

and “Diverse Config Write ($ Port_Index + 0x18)".

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When configured for fiber mode, the full set of Optical Module interface control and status signals

is presented through re-use of GMII signals on a per-port basis (see Table 4.5 “Multiplexed Ball

Connections” on page 57). Fiber mode supports only full-duplex Gigabit operation.

5.1.4.1

Fiber Auto-Negotiation

Auto-negotiation is performed by using the “TX Config Word ($ Port_Index + 0x17)", “RX Config

Word ($ Port_Index + 0x16)", and “Diverse Config Write ($ Port_Index + 0x18)". When

autoneg_enable (“Diverse Config Write ($ Port_Index + 0x18)") is set, the IXF1104 performs

hardware-defined auto-negotiation with the “TX Config Word ($ Port_Index + 0x17)" used as an

“Auto-Negotiation Advertisement ($ Port Index + 0x64)" and the “RX Config Word ($ Port_Index

+ 0x16)" used as an “Auto-Negotiation Link Partner Base Page Ability ($ Port Index + 0x65)".

Note: While the MAC supports auto-negotiation functions, the IXF1104 does not automatically configure

the MAC or other device blocks to be consistent with the auto-negotiation results. This

configuration is done by the user and system software.

5.1.4.2

Determining If Link Is Established in Auto-Negotiation Mode

A valid link is established when the AN_complete bit is set and the RX_Sync bit reports that

synchronization has occurred. Both register bits are located in the “RX Config Word ($ Port_Index

+ 0x16)".

If the link goes down after auto-negotiation is completed, RX_Sync indicates that a loss of

synchronization occurred. The IXF1104 restarts auto-negotiation and attempts to reestablish a link.

Once a link is reestablished, the AN_complete bit is set and the RX_Sync bit shows that

synchronization has occurred.

To manually restart auto-negotiation, bit 5 of the “Diverse Config Write ($ Port_Index + 0x18)”

(AN_enable) must be de-asserted, then re-asserted.

5.1.4.3

Fiber Forced Mode

The MAC fiber operation can be forced to operate at 1000 Mbps full-duplex without completion of

the auto-negotiation function. In this mode, the MAC RX path must achieve synchronization with

the link partner. Once achieved, the MAC TX path is enabled to allow data transmission. This

forced mode is limited to operation with a link partner that operates with a full-duplex link at

1000 Mbps.

5.1.4.4

5.1.5

Determination of Link Establishment in Forced Mode

When the IXF1104 is in forced mode operation, the “RX Config Word ($ Port_Index + 0x16)” bit

20 RX Sync indicates when synchronization occurs and a valid link establishes.

Note: The RX Sync bit indicates a loss of synchronization when the link is down.

Copper Mode

In copper mode, the IXF1104 transmits data on the egress path of the RGMII or GMII interface,

depending on the port configuration defined by the user. The copper MAC receives data on the

ingress path of the RGMII or GMII interface, depending on the port configuration defined by the

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user. The RGMII interface supports operation at 10/100/1000 Mbps when a full-duplex link is

established, and supports 10/100 Mbps when a half-duplex link is established. The GMII interface

only supports a 1000 Mbps full-duplex link.

5.1.5.1

Speed

The copper MAC supports 10 Mbps, 100 Mbps, and 1000 Mbps. All required speed adjustments,

clocks, etc., are supplied by the MAC. The operating speed of the MAC is programmable through

the “MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)" (MAC_IF_Mode). The IXF1104

speed setting must be programmed by the system software to match the speed of the attached PHY

for proper IXF1104 operation.

Note: When the IXF1104 is configured to use the GMII interface, the only mode of operation that is

supported is 1000 Mbps full-duplex.

If 10/100 Mbps operation is required in either full-duplex or half-duplex, the IXF1104 must be

configured to use the RGMII interface.

5.1.5.2

5.1.5.3

Duplex

The MAC supports full-duplex or half-duplex depending on the line-side interface that is

configured by the “MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)" (MAC_IF_Mode).

The duplex of the MAC is set in the “Desired Duplex ($ Port_Index + 0x02)” on page 162. The

IXF1104 duplex setting must be programmed by the system software to match the attached PHY

duplex for proper IXF1104 operation.

Copper Auto-Negotiation

In the copper MAC, auto-negotiation and all other controls of the PHY devices are achieved

through the MDIO interface, and are independent of the MAC controller. See Section 5.5, “MDIO

Control and Interface” on page 98 for further operation details.

Note: In copper mode, auto-negotiation is accomplished by the attached PHY, not the IXF1104. Thus, the

IXF1104 does not automatically configure the MAC or other blocks in the device to be consistent

with attached PHY auto-negotiation results. This must be accomplished by the user and system

software.

5.1.6

Jumbo Packet Support

The IXF1104 supports jumbo frames. The jumbo frame length is dependent on the application and

the IXF1104 design is optimized for a 9.6 KB jumbo frame length. Larger lengths can be

programmed, but limited system performance may lead to data loss during certain flow-control

conditions

The value programmed into the“Max Frame Size (Addr: Port_Index + 0x0F)" determines the

maximum length frame size the MAC can receive or transmit without activating any error counters,

and without truncation.

The“Max Frame Size (Addr: Port_Index + 0x0F)" bits 13:0 set the frame length. The default value

programmed into this register is 0x05EE (1518). The value is internally adjusted by +4 if the frame

has a VLAN tag. The overall programmable maximum is 0x3FFF or 16383 bytes.

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The register should be programmed to 0x2667 for the 9.6 KB length jumbo frame, optimized for

the IXF1104. The RMON counters are also implemented for jumbo frame support as follows:

5.1.6.1

Rx Statistics

• RxOctetsTotalOK (Addr: Port_Index + 0x20)

• RxPkts1519toMaxOctets (Addr: Port_Index + 0x2B)

• RxFCSErrors (Addr: Port_Index + 0x2C)

• RxDatatError (Addr: Port_Index = 0x02E)

• RxAlignErrors (Addr: Port_Index + 0x2F)

• RxLongErrors (Addr: Port_Index + 0x30)

• RxJabberErrors (Addr: Port_Index + 0x31)

• RxVeryLongErrors (Addr: Port_Index + 0x34)

5.1.6.2

TX Statistics

• OctetsTransmittedOK (Addr: Port_Index + 0x40)

• TxPkts1519toMaxOctets (Addr: Port_Index + 0x4B)

• TxExcessiveLengthDrop (Addr: Port_Index + 0x53)

• TxCRCError (Addr: Port_Index + 0x56)

The IXF1104 checks the CRC for all legal-length jumbo frames (frames between 1519 and the

Max Frame Size). On transmission, the MAC can be programmed to append the CRC to the frame

or check the CRC and increment the appropriate counter. On reception, the MAC transmits these

frames across the SPI3 interface (jumbo frames above the setting in the “RX FIFO Transfer

Threshold Port 0 ($0x5B8)” with a bad CRC cannot be dropped and are sent across the SPI3

interface). If the receive frame has a bad CRC, the appropriate counter is incremented and the

RxERR flag is asserted on the SPI3 receive interface.

Jumbo frames also impact flow control. The maximum frame size needs to be taken into account

when determining the FIFO watermarks. The current transmission must be completed before a

Pause frame is transmitted (needed when the receiver FIFO High watermark is exceeded). If the

current transmission is a jumbo frame, the delay may be significant and increase data loss due to

insufficient available FIFO space.

5.1.6.3

Loss-less Flow Control

The IXF1104 supports loss-less flow control when the size of a Jumbo packet is restricted to

9.6 k bytes. If this condition is met, the IXF1104 has sufficient memory resources allocated to each

MAC port to ensure that, if both the IXF1104 and link partner are required to send Pause packets

simultaneously during jumbo packet transfers across a medium of five kilometers of fiber, no

packet data should be lost due to FIFO overflows.

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5.1.7

Packet Buffer Dimensions

5.1.7.1

TX and RX FIFO Operation

5.1.7.1.1 TX FIFO

The IXF1104 TX FIFOs are implemented with 10 KB for each channel. This provides enough

space for at least one maximum size (10 KB) packet per-port storage and ensures that no under-run

conditions occur, assuming that the sending device can supply data at the required data rate.

A transfer to MAC Threshold parameter, which is user-programmable, determines when the FIFO

signals to the MAC that it has data to send. This is configured for specific block sizes, and the user

must ensure that an under-run does not occur. Also, the threshold can be set above the maximum

size of a normal Ethernet packet. This causes the FIFO to send only data to the MAC when this

threshold is exceeded or when the End-of-Packet marker is received. This second condition

eliminates the possibility of under-run, except when the controlling switch device fails. It can,

however, cause idle times on the media.

5.1.7.1.2 RX FIFO

The IXF1104 RX FIFOs are provisioned so that each port has its own 32 KB of memory space.

This is enough memory to ensure that there is never an over-run on any channel while transferring

normal Ethernet frame size data.

The FIFOs automatically generate Pause control frames to halt the link partner when the High

watermark is reached and to restart the link partner when the data stored in the FIFO falls below the

low-watermark. The RX and TX FIFOs have been sized to support lossless flow control with

9.6 KB packets. The RX FIFO has a programmable transfer threshold that sets the threshold at

which packets become “cut through” and starts transitioning to the SPI3 interface before the EOP

is received. Packets sizes below this threshold are treated as “store and forward.” Once a packet

size exceeds the RX FIFO transfer threshold, it can no longer be dropped by the RX FIFO even if it

is marked to be dropped by the MAC.

5.1.8

RMON Statistics Support

The IXF1104 supplies RMON statistics through the CPU interface. These statistics are available in

the form of counter values that can be accessed at specific addresses in the register maps (Table 59

through T a ble 69). Once read, these counters automatically reset and begin counting from zero. A

separate set of RMON statistics is available for each MAC device in the IXF1104.

Implementation of the RMON Statistics block is similar to the functionality provided by existing

Intel switch and router products. This implementation allows the IXF1104 to provide all of the

RMON Statistics group as defined by RFC2819. The IXF1104 supports the RMON RFC2819

Group 1 statistics counters. T a ble 25 notes the differences and additional statistics registers

supported by the IXF1104 that are outside the scope of the RMON RFC2819 document.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Table 25. RMON Additional Statistics (Sheet 1 of 2)

Definition of RMON

Versus IXF1104

Documentation

RMON Ethernet Statistics

Group 1 Statistics

IXF1104-Equivalent

Statistics

Type

etherStatsindex

Integer 32 NA

Object

etherStatsDataSource

identifier

RX Number of Frames

Removed/

TX Number of Frames

Counter

etherStatsDropEvents

Counter 32 See table note 1

Removed

The IXF1104 has two

counters for receive

and transmit that use

different naming

RxOctetsTotalOK

RxOctetsBad

conventions for the

Counter 32 total Octets and

Octets Bad. These

Counter

etherStatsOctets

OctetsTransmittedOK

OctetsTransmittedBad

counters must be

combined to meet

the RMON definition

for this statistic.

The IXF1104 has

three counters for the

etherStatsPkts that

RxUCPkts/TxUCPkts

etherStatsPkts

Counter32 RxBCPkts/TxBCPkts

RxMCPkts/TxMCPkts

Counter 32 must be combined to

give the total packets

as defined by the

RMON specification.

Same as RMON

Counter 32

etherStatsBroadcastPkts

etherStatsMulticastPkts

Counter32 RxBCPkts/TxBCPkts

Counter32 RxMCPkts/TxMCPkts

specification

Counter 32 See table note 2

The IXF1104 has two

counters for the

alignment and CRC

errors for the RX side

RxAlignErrors

Counter32 RxFCSErrors

TxCRCError

etherStatsCRCAlignErrors

Counter 32

only.

The IXF1104 has a

CRC Error counter

for the TX side.

The IXF1104 has two

counters, one for

Runt errors and one

for ShortErrors.

RxRuntErrors

Counter32 RxShortErrors

Rx Statistics ONLY

etherStatsUndersizedPkts

etherStatsOversizePkts

Counter 32

RxLongErrors

Counter32

Same as RMON

Counter 32

specification

TxExcessiveLength Drop

NOTE: The RMON specification requires that this is, “The total number of events where packets were dropped

by the probe due to a lack of resources. This number is not necessarily the number of packets dropped;

it is the number of times this condition is detected." The “RX FIFO Overflow Frame Drop Counter Ports 0

- 3 ($0x594 – 0x597)" and “TX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x621 – 0x624)" in the

IXF1104 support this and increment when either an RX FIFO or TX FIFO overflows. If any IXF1104

programmable packet filtering is enabled, the “RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2

- 0x5A5)" and “TX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x625 – 0x629)" increment with every

frame removed in addition to the existing frames counted due to FIFO overflow.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Table 25. RMON Additional Statistics (Sheet 2 of 2)

Definition of RMON

Versus IXF1104

Documentation

RMON Ethernet Statistics

Group 1 Statistics

IXF1104-Equivalent

Statistics

Type

Same as RMON

specification

etherStatsFragments

etherStatsJabbers

Counter32 RuntErrors

Counter32 JabberErrors

TxSingleCollision

Counter 32

Same as RMON

specification

The TxTotalCollision

count value is

equivalent to the

RMON specification

minus the

TxMultipleCollision

Counter32

etherStatsCollisions

Counter 32

TxLateCollision

TxTotalCollision

TxLateCollision

RxPkts64Octets/

Counter32

Same as RMON

specification

etherStatsPkts64Octets

Counter 32

Counter32

TxPkts64Octets

RxPkts65to127Octets/

Counter32

Same a RMON

specification

etherStatsPkts65to127Octets

etherStatsPkts128to255Octets

etherStatsPkts256to511Octets

TxPkts65to127Octets

RxPkts128to255Octets/

Counter32

Same a RMON

specification

TxPkts128to255Octets

RxPkts256to511Octets/

Counter32

Same a RMON

specification

TxPkts256to511Octets

RxPkts512to1023Octets/

TxPkts512to1023Octets

Same a RMON

specification

etherStatsPkts512to1023Octets Counter32

etherStatsPkts1023to1518Octets Counter32

RxPkts1023to1518Octets/

TxPkts1023to1518Octets

Same as RMON

specification

Owner

etherStatOwner

String

Entry

etherStatsStatus

Status

NOTE: The RMON specification requires that this is, “The total number of events where packets were dropped

by the probe due to a lack of resources. This number is not necessarily the number of packets dropped;

it is the number of times this condition is detected." The “RX FIFO Overflow Frame Drop Counter Ports 0

- 3 ($0x594 – 0x597)" and “TX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x621 – 0x624)" in the

IXF1104 support this and increment when either an RX FIFO or TX FIFO overflows. If any IXF1104

programmable packet filtering is enabled, the “RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2

- 0x5A5)" and “TX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x625 – 0x629)" increment with every

frame removed in addition to the existing frames counted due to FIFO overflow.

5.1.8.1

Conventions

The following conventions are used throughout the RMON Management Information Base (MIB)

and its companion documents.

• Good Packets: Error-free packets that have a valid frame length. For example, on Ethernet,

good packets are error-free packets that are between 64 and 1518 octets long. They follow the

form defined in IEEE 802.3, Section 3.2.

• Bad Packets: Bad packets are packets that have proper framing and recognized as packets, but

contain errors within the packet or have an invalid length. For example, on Ethernet, bad

packets have a valid preamble and SFD, but have a bad CRC, or are either shorter than 64

octets or longer than 1518 octets.

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5.1.8.2

IXF1104 Advantages

The following lists additional IXF1104 registers that support features not documented in RMON:

• MAC (flow) control frames

• VLAN Tagged

• Sequence Errors

• Symbol Errors

• CRC Error

These additional counters allow for differentiation beyond standard RMON probes.

Note: In fiber mode, a packet transfer with an invalid 10-bit symbol does not always update the statistics

registers correctly.

• Behavior: The IXF1104 8B10B decoder substitutes a valid code word octet in its place. The

packet transfer is aborted and marked as bad. The new internal length of the packet is equal to

the byte position where the invalid symbol was. No packet fragments are seen at the next

packet transfer.

• Issue: If the invalid 10-bit code is inserted in a byte position of 64 or greater, expected RX

statistics are reported. However, if the invalid code is inserted in a byte position of less than

64, expected RX statistics are not stored.

5.2

SPI3 Interface

The IXF1104 SPI3 Interface is implemented to the System Packet Interface Level 3 (SPI3)

Physical Layer Interface standard. The interface function allows the IXF1104 MAC blocks to

interface to higher-layer network processors or switch fabric.

The transmit interface allows data flows from a network processor or switch fabric device to the

IXF1104. The receive interface allows data to flow from the IXF1104 to the network processor or

switch fabric device.

This interface receives and transmits data between the MAC and the Network Processor with

compliant SPI3 interfaces. The SPI3 interface operation is defined in the OIF-SPI3-01.0 (available

from the Optical Internet Working Forum [www.oiforum.com]). The OIF specification defines

operation for the transfer of data at data rates of up to 3.2 Gbps when operating at a frequency of

104 MHz. The IXF1104 defines operation for the transfer of data at data rates of up to 4.256 Gbps

when operating at a maximum frequency of 133 MHz in MPHY mode and 125 MHz in SPHY

Mode.

There is no guarantee of the number of bytes available since the size of packets is variable. An

IXF1104 port-transmit packet available status is provided on signals DTPA, STPA or PTPA,

indicating the TX FIFO is nearly full.

In the receive direction, RVAL indicates if valid data is available on the receive data bus and is

defined so that data transfers can be aligned with packet boundaries.

The SPI3 interface supports the following two modes of operation:

• MPHY or 32 bit mode (one 32-bit data bus)

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• SPHY or 4 x 8 mode (four individual 8-bit data buses)

5.2.1

MPHY Operation

The MPHY operation mode is selected when bit 21 of the“SPI3 Transmit and Global Configuration

($0x700)” is set to 0 and bit 7 of the “SPI3 Receive Configuration ($0x701)" is set to 1.

Data Path

The IXF1104 SPI3 interface has a single 32-bit data path in the MPHY configuration mode (see

Figure 13). The bus interface is point-to-point (one output driving only one input load), so a 32-bit

data bus would support only one IXF1104.

To support variable-length packets, the RMOD[1:0]/TMOD[1:0] signals are defined to specify

valid bytes in the 32-bit data bus structure. Each double-word must contain four valid bytes of

packet data until the last double-word of the packet transfer, which is marked with the end of

packet REOP/TEOP signal. This last double-word of the transfer contains up to four valid bytes

specified by the RMOD[1:0]/TMOD[1:0] signals.

The IXF1104 port selection is performed using in-band addressing. In the transmit direction, the

network processor device selects an IXF1104 port by sending the address on the TDAT[1:0] bus

marked with the TSX signal active and TENB signal inactive. All subsequent TDAT[1:0] bus

operations marked with the TSX signal inactive and the TENB active are packet data for the

specified port.

In the receive direction, the IXF1104 specifies the selected port by sending the address on the

RDAT[1:0] bus marked with the RSX signal active and RVAL signal inactive. All subsequent

RDAT[1:0] bus operations marked with RSX inactive and RVAL active are packet data from the

specified port.

Note: See Table 17 “SPI3 MPHY/SPHY Interface” on page 58 for a complete list of the MPHY mode

signals. The control signals with the port designator for Port 0 are the only ones used in MPHY

mode and they apply to all 4 ports. T a ble 3 “SPI3 Interface Signal Descriptions” on page 38

provides a comprehensive list of SPI3 signal descriptions.

5.2.1.1

SPI3 RX Round Robin Data Transmission

The IXF1104 uses a round-robin protocol to service each of the 4 ports dependent upon the enable

status of the port and if there is data available to be taken from the RX FIFO. The round robin order

goes from port 0, port 1, port 2, port 3, and back to port 0. A port is skipped and the next port is

serviced if it has no available transmit data. The data transfer bursts are user-configurable burst

lengths of 64, 128, or 256 bytes. The IXF1104 also has a configurable pause interval between data

transfer bursts on the receive side of the interface. The RX SPI3 burst lengths and the pause

interval can be set in the “SPI3 Receive Configuration ($0x701)").

5.2.2

MPHY Logical Timing

The SPI3 interface AC timing for MPHY can be found in Section 7.2, “SPI3 AC Timing

Specifications” on page 136. Logical timing in the following diagrams illustrates all signals

associated with MPHY mode.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.2.2.1

Transmit Timing

In MPHY mode a packet transmission starts with the TSX signal indicating port address

information is on the data bus. The next clock cycle TENB and TSOP indicate present data on the

bus is the first word in the packet and all subsequent clocks will contain valid data as long as TENB

is active or until TEOP is asserted. Data transmission can be temporally halted when TENB goes

high then resumed when TENB is low. The valid bytes in the final word, during an active TEOP,

are indicated by state of TMOD [1:0].

Figure 11. MPHY Transmit Logical Timing

TFCLK

TENB

TSOP

TEOP

TMOD[1:0]

TERR

TSX

0000

B1-B4

B5-B8

B41-B44 B45-B48 B49-B52

B53-B56

B57

TDAT[31:0]

TPRTY

B0001

TPA

B3216-01

1. Applies to all transmit packet available signals (STPA, PTPA, DTPA_0:3).

5.2.2.2

Receive Timing

A packet is received when RSX indicates port address information on the data bus followed by

RSOP to indicate the data bus contains the first word of a packet. All subsequent data is valid only

while RVAL is High and until REOP is asserted. Receive data can be temporarily halted when

RENB is de-asserted and starts again on the second rising edge of RFCLK following the assertion

of RENB. RMOD indicates the number of valid bytes in the last transfer when REOP is asserted.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 12. MPHY Receive Logical Timing

TFCLK

RENB

RSX

RSOP

REOP

RERR

RMOD[1:0]

RDAT[31:0]

RPRTY

0000

B1-B4

B5-B8

B9-B12

B13-B16

B45-B48

B52-B55 B56-B57 B0001

RVAL

B3217-01

Figure 13. MPHY 32-Bit Interface

SPI3 Bus

Network Processor

IXF1104 MPHY

Mode

Line-Side Interface

TFCLK

TENB

TFCLK

Transceiver

TENB_0

Port 0

TDAT[31:0]

TMOD[1:0]

TPRTY

TDAT[31:0]

TMOD[1:0]

TPRTY_0

TSOP_0

TSOP

TEOP

TEOP_0

Port 1

TERR

TSX

TERR_0

TSX

DTPA_0:3

STPA

DTPA_0:3

STPA

PTPA

TADR[1:0]

PTPA

TADR[1:0]

Port 2

Port 3

RFCLK

RENB

RFCLK

RENB_0

RDAT[31:0]

RMOD[1:0]

RDAT[31:0]

RMOD[1:0]

RPRTY

RVAL

RSOP

REOP

RPRTY_0

RVAL_0

RSOP_0

REOP_0

RERR

RSX

RERR_0

RSX

B0660-02

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.2.2.3

Clock Rates

In MPHY mode, the TFCLK and RFCLK can be independent of each other. TFCLK and RFCLK

should be common to the IXF1104 and the Network Processor. The IXF1104 requires a single

clock source for the transmit path and a single clock source for the receive path.

To allow all four IXF1104 ports to operate at 1 Gbps, the IXF1104 is designed to allow this

interface to be overclocked. This allows operation for data transfer at data rates of up to 4.256 Gbps

when operating at an overclocked frequency of 133 MHz.

Note: MPHY mode operates at a maximum clock frequency of 133 MHz (TFCLK and RFCLK).

5.2.2.4

Parity

The IXF1104 can be odd or even (the IXF1104 is odd by default) when calculating parity on the

data bus. This can be changed to accommodate even parity if desired, and can be set for transmit

and receive independently. The RX Parity is set in bit 12 of the “SPI3 Receive Configuration

($0x701)” and the TX Parity is set in bit 4 of the “SPI3 Transmit and Global Configuration

($0x700)”.

5.2.2.5

SPHY Mode

The SPHY operation mode is selected when bit 21 of the Table 146 “SPI3 Transmit and Global

Configuration ($0x700)” on page 212 is set to 1. The SPHY mode is the default operation for the

IXF1104 SPI3 interface.

5.2.2.5.1 Data Path

The IXF1104 SPI3 interface has four 8-bit data paths that can support four independent 8-bit point-

to-point connections in SPHY mode (see Figure 16). Since each MAC port has its own dedicated

8-bit SPI3 data bus, each port has it own status signal (unlike MPHY). See the For a detailed list of

all the signals refer to the SPI3 pin multiplexing table....

Furthermore since each port has it own dedicated bus the in band port addressing is not needed.

The 8 bit data bus eliminates the need to have separate control signals determine the number of

valid bytes on an EOP.Therefore TSX, RSX, TMOD[1:0] RMOD[1:0] are not used in SPHY mode.

Note: See Table 17 “SPI3 MPHY/SPHY Interface” on page 58 for a complete list of the SPHY mode

signals. Unlike MPHY mode, each port has a dedicated control signal associated with each of the

per-port 8-bit data buses. T a ble 3 “SPI3 Interface Signal Descriptions” on page 38 provides signal

descriptions for all SPI3 signals.

5.2.2.5.2 Receive Data Transmission

Packets are transmitted on each port as they become available from the RX FIFO. The burst length

is determined by the setting of per port burst size and the B2B pause settings in the “SPI3 Receive

Configuration ($0x701)". If the B2B pause setting is zero pause cycles inserted, then the entire

packet will be burst without any pauses unless the Network Processor de-asserts RENB. If the

B2B_Pause setting calls for the insertion of two pause cycles on a port, these are inserted after each

data burst for that port. The data bursts are user configurable for each port in the “SPI3 Receive

Configuration ($0x701)".

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.2.2.6

SPHY Logical Timing

SPI3 interface AC timing for SPHY can be found in Section 7.2, “SPI3 AC Timing Specifications”

on page 136. Logical timing in the following diagrams illustrates all signals associated with SPHY

mode. SPHY mode is similar to MPHY mode except the following signals are not used:

• TMOD[1:0]

• RMOD[1:0]

• TSX

• RSX

• Address Data appearing on the data bus

5.2.2.7

Transmit Timing (SPHY)

Packet transmission starts when TENB and TSOP indicate present data on the bus is the first word

in the packet. All subsequent clocks will contain valid data as long as TENB is active or until

TEOP is asserted. Data transmission can be temporally halted when TENB goes high then resumed

when TENB is low.

Figure 14. SPHY Transmit Logical Timing

TFCLK

TENB

TSOP

TEOP

TERR

B60

B61

B62

B63

B64

TDAT[7:0]_n

TPRTY

DTPA_n

B3249-01

5.2.2.8

Receive Timing (SPHY)

A packet is received when RSOP is asserted to indicate the data bus contains the first word of the

packet. All subsequent data is valid only while RVAL is high and until REOP is asserted. Receive

data can be temporarily halted when RENB is de-asserted and starts again on the second rising

edge of RFCLK following the assertion of RENB. When REOP is asserted RMOD indicates the

number of valid bytes in the last transfer.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 15. SPHY Receive Logical Timing

RFCLK

RENB

RSOP

REOP

RERR

RDAT[7:0]_n

RPRTY

B62

B63

B64

RVAL

B3250-01

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 16. SPHY Connection for Two IXF1104 Ports (8-Bit Interface)

SPI3 Bus

Intel^®IXF1104

Port 0

Network Processor

TFCLK

TENB[0]

TFCLK

TENB_0

TDAT[7:0][0]

TPRTY[0]

TSOP[0]

TDAT[7:0]_0

TPRTY_0

TSOP_0

TEOP[0]

TEOP_0

TERR[0]

TERR_0

DTPA[0]

DTPA_0

Line-Side

Interface

Transceiver

Port 0

RFCLK

RENB[0]

RENB_0

RDAT[7:0][0]

RPRTY[0]

RVAL[0]

RDAT[7:0]_0

RPRTY_0

RVAL_0

RSOP[0]

REOP[0]

RERR[0]

RSOP_0

REOP_0

RERR_0

SPI3

Flow Control

PTPA

TADR[1:0]

PTPA

TADR[1:0]

Port 1

TFCLK

TENB[1]

TENB_1

TDAT[7:0]_1

TPRTY_1

TSOP_1

TEOP_1

TDAT[7:0][1]

TPRTY[1]

TSOP[1]

TEOP[1]

TERR_1

DTPA_1

TERR[1]

DTPA[1]

Line-Side

Interface

Transceiver

Port 1

RFCLK

RENB[1]

RENB_1

RDAT[7:0]_1

RPRTY_1

RDAT[7:0][1]

RPRTY[1]

RVAL[1]

RVAL_1

RSOP_1

REOP_1

RERR_1

RSOP[1]

REOP[1]

RERR[1]

B0659-02

5.2.2.8.1 Clock Rates

The TFCLK and RFCLK can be independent of each other in SPHY mode operation. TFCLK and

RFCLK should be common to all the Network Processor devices. The IXF1104 requires an

individual single clock source for the device transmit path and a single clock source for the device

receive path.

The IXF1104 allows this interface to be overclocked so that all four IXF1104 ports can operate at

1 Gbps. This allows data transfer at data rates of up to 4.0 Gbps when operating at an overclocked

frequency of 125 MHz.

Note: SPHY operates at a maximum frequency of 125Mhz.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.2.2.8.2 Parity

The IXF1104 can be odd or even (the IXF1104 defaults to odd) when calculating parity on the data

bus. This can be changed to accommodate even parity if desired, and can be set for transmit and

receive ports independently. The RX and TX parity sense bits have a direct relationship to the port

parity in SPHY mode.

The per port RX parity is set in the “SPI3 Receive Configuration ($0x701)" and the per port TX

Parity is set in the “SPI3 Transmit and Global Configuration ($0x700)".

5.2.2.9

SPI3 Flow Control

The SPI3 packet interface supports transmit and receive data transfers at clock rates independent of

the line bit rate. As a result, the IXF1104 supports packet rate decoupling using internal FIFOs.

These FIFOs are 10 KB per port in the transmit direction (egress from the IXF1104 to the line

interfaces) and 32 KB per port in the receive direction (ingress to the IXF1104 from the line

interfaces).

Control signals are provided to the network processor and the IXF1104 to allow either one to

exercise flow control. Since the bus interface is point-to-point, the receive interface of the IXF1104

pushes data to the link-layer device. For the transmit interface, the packet available status

granularity is byte-based.

5.2.2.9.1 RX SPI3 Flow Control

In the receive direction, when the IXF1104 has stored an end-of-packet (a complete small packet or

the end of a larger packet) or some predefined number of bytes in its receive FIFO, it sends the in-

band address followed by FIFO data to the link-layer device (in MPHY mode). The data on the

interface bus is marked with the valid signal (RVAL) asserted. The network processor device can

pause the data flow by de-asserting the Receive Read Enable (RENB) signal.

RENB_0:3

RENB_0:3 controls the flow of data from the IXF1104 RX FIFOs. In SPHY mode, there is a

dedicated RENB for each port. In MPHY mode, RENB_0 is used as the global signal covering all

ports. When RENB is sampled Low, the network processor can accept data. A read is performed

from the RX FIFO and the RDAT, RPRTY, RMOD[1:0], RSOP, REOP, RERR, RSX, and RVAL

signals are updated on the following rising edge of RFCLK.

RENB can be asserted High by the Network Processor at any time if it is unable to accept any more

data. When the RENB is sampled High by the IXF1104, a read of the RX FIFO is not performed,

and the RDAT, RPRTY, RMOD[1:0], RSOP, REOP, RERR, RSX and RVAL signals remain

unchanged on the following rising edge of RFCLK.

5.2.2.9.2 TX SPI3 Flow Control

In the transmit direction, when the IXF1104 has space for some predefined number of bytes in its

transmit FIFO, it informs the Network Processor device by asserting one of the Transmit Packet

Available (TPA) signals. The Network Processor device writes the in-band address followed by

packet data to the IXF1104 using an enable signal (TENB). The network processor device monitors

the TPA signals for a High-to-Low transition, which indicates that the transmit FIFO is almost full

(the number of bytes left in the FIFO is user-selectable by setting the “TX FIFO High Watermark

Ports 0 - 3 ($0x600 – 0x603)", and suspends data transfer to avoid an overflow. The Network

Processor device can pause the data flow by de-asserting the enable signal (TENB).

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

The IXF1104 provides the following three types of TPA signals:

• Dedicated per port Direct Transmit Packet Available (DTPA)

• Selected-PHY Transmit Packet Available (STPA), which is based on the current in-band port

address in MPHY mode.

• Polled-PHY Transmit packet Available (PTPA), which provides FIFO information on the port

selected by the TADR[1:0] signals.

The following three TPA signals (DTPA_0:3, STPA, and PTPA) provide flow control based on the

programmable TX FIFO High and Low watermarks. Refer to T a ble 132 “TX FIFO High

Watermark Ports 0 - 3 ($0x600 – 0x603)” on page 202 and Table 133 “TX FIFO Low Watermark

DTPA_0:3:

A direct status indication for the TX FIFOs of ports [0:3]. When DTPA is High, it indicates the

amount of data in the TX FIFO is below the TX FIFO High watermark. When the High watermark

is crossed, DTPA transitions Low to indicate the TX FIFO is almost full. It stays low until the

amount data in the TX FIFO goes back below the TX FIFO Low watermark. At this point, DTPA

transitions High to indicate the programmed number of bytes are now available for data transfers.

DTPA_0:3 is updated on the rising edge of the TFCLK.

STPA:

STPA provides TX FIFO status for the currently selected port in MPHY mode. When High, STPA

indicates that the amount of data in the TX FIFO for the port selected, specified by the latest in-

band address, is below the TX FIFO High watermark. When the High watermark is crossed, STPA

transitions Low to indicate the TX FIFO is almost full. It stays Low until the amount of data in the

TX FIFO goes back below the TX FIFO Low watermark. At this point, STPA transitions High to

indicate the programmed number of bytes are now available for data transfers.

The port reported by STPA is updated on the rising edge of TFCLK after TSX is sampled as

asserted. STPA is updated on the rising edge of TFCLK.

Note: STPA is only used when the IXF1104 is configured for MPHY mode of operation.

PTPA:

PTPA provides status of the TX FIFO based on the port selected by the TADR[1:0] address bus.

When High, PTPA indicates that the amount of data in the TX FIFO for the port selected is below

the TX FIFO High watermark. When the High watermark is crossed, PTPA transitions Low to

indicate the TX FIFO is almost full. It stays Low until the amount of data in the TX FIFO goes

back below the TX FIFO Low watermark. PTPA then transitions High to indicate the programmed

number of bytes are now available for data transfers.

The port reported by PTPA is updated on the rising edge of TFCLK after the TADR{1:0] port

address is sampled.

PTPA is updated on the rising edge of TFCLK.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.2.3

Pre-Pending Function

The IXF1104 implements a pre-pending feature to allow 1518-byte Ethernet packets to be pre-

padded with two additional bytes of data so that the packet becomes low-word aligned. The 2-byte

pre-pend value is all zeros and is inserted before the destination address of the packet being pre-

pended. This value is fixed and cannot be changed.

This function is enabled by writing the appropriate data to the “RX FIFO Padding and CRC Strip

Enable ($0x5B3)" for each port.

A standard 1518-byte Ethernet packet occupies 379 long words (four bytes) with two additional

bytes left over (1518/4 = 379.5). To eliminate the memory-management problems for a network

processor or switch fabric, the two remaining bytes are dealt with by the addition of two bytes to

the start of a packet. This results in a standard 1518-byte Ethernet packet received by the IXF1104

being forwarded to the higher-layer device as a 380-long-word packet. The upper-layer device is

responsible for stripping the additional two bytes.

This feature was added to the IXF1104 to assist in the design of higher-layer memory management.

The addition of the two extra bytes is not the default operation of the IXF1104 and must be enabled

by the user. The default operation of the IXF1104 SPI3 receive interface forwards data exactly as it

is received by the IXF1104 line interface.

5.3

Gigabit Media Independent Interface (GMII)

The IXF1104 supports a subset of the GMII interface standard as defined in IEEE 802.3 2000

Edition for 1 Gbps operation only. This subset is limited to operation at 1000 Mbps full-duplex.

The GMII Interface operates as a source synchronous interface only and does not accept a TXC

clock provided by a PHY device when operating at 10/100 Mbps speeds.

Note: The RGMII interface must be used for applications that require 10/100/1000 Mbps operation.

The IXF1104 does NOT support 10/100 Mbps copper PHY devices that are implemented using the

MII Interface.

Note: MII operation is not supported by the IXF1104.

The user can select GMII, RGMII, or Optical Module/SerDes functionality on a per-port basis.

This mode of operation is controlled through a configuration register.

While IEEE 802.3 specifies 3.3 V operation of GMII devices, most PHYs use 2.5 V signaling. The

IXF1104 provides a 2.5 V drive and is 3.3 V-tolerant on inputs.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Figure 17. MAC GMII Interconnect

TXC_3:0

TXD[7:0]_0

TXD[7:0]_1

TXD[7:0]_2

TXD[7:0]_3

TX_EN_3:0

TX_ER_3:0

TXC_3:0

TXD[7:0]_0

TXD[7:0]_1

TXD[7:0]_2

TXD[7:0]_3

TX_EN_3:0

TX_ER_3:0

RXC_3:0

RXD[7:0]_0

RXD[7:0]_1

RXD[7:0]_2

RXD[7:0]_3

RX_EN_3:0

RX_ER_3:0

CRS_3:0

RXC_3:0

RXD[7:0]_0

RXD[7:0]_1

RXD[7:0]_2

RXD[7:0]_3

RX_EN_3:0

RX_ER_3:0

CRS_3:0

COL_3:0

B3203-01

5.3.1

5.3.2

GMII Signal Multiplexing

The GMII balls are reassigned when using the RGMII mode or fiber mode. T a ble 16 “Line Side

Interface Multiplexed Balls” on page 57 specifies the multiplexing of GMII balls in these modes.

See Section 5.1.3, “Mixed-Mode Operation” on page 74 for proper configuration of the IXF1104 in

GMII mode.

GMII Interface Signal Definition

T a ble 26 “GMII Interface Signal Definitions” on page 94 provides the GMII interface signal

definitions. For information on 1000BASE-T GMII transmit and receive timing diagrams and

tables, please refer to Table 49 “GMII 1000BASE-T Transmit Signal Parameters” on page 141,

Figure 38 “1000BASE-T Transmit Interface Timing” on page 141, Figure 39 “1000BASE-T

Receive Interface Timing” on page 142, and T a ble 50 “GMII 1000BASE-T Receive Signal

Parameters” on page 142

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

Table 26. GMII Interface Signal Definitions

IXF1104

Signal

GMII Standard

Signal

Source

Description

TXC_0

TXC_1

TXC_2

TXC_3

Transmit Reference Clock:

125 MHz for Gigabit operation.

GTX_CLK

TXD[7:0]

TX_EN

IXF1104

MII operation for 10/100 Mbps operation is not

supported.

TXD[7:0]_0

TXD[7:0]_1

TXD[7:0]_2

TXD[7:0]_3

Transmit Data Bus:

Width of this synchronous output bus varies with the

speed/mode of operation. In 1000 Mbps mode, all 8

bits are used.

IXF1104

PHY

TX_EN_0

TX_EN_1

TX_EN_2

TX_EN_3

Transmit Enable:

Synchronous input that indicates Valid data is being

driven on the TXD[7:0] data bus.

TX_ER_0

TX_ER_1

TX_ER_2

TX_ER_3

Transmit Error:

TX_ER

Synchronous input to PHY causes the transmission of

error symbols in 1000 Mbps links.

RXC_0

RXC_1

RXC_2

RXC_3

Receive Clock:

RX_CLK

Continuous reference clock is 125 MHz +/– 100 ppm.

Receive Data Bus:

RXD[7:0]_0

RXD[7:0]_1

RXD[7:0]_2

RXD[7:0]_3

Width of the bus varies with the speed and mode of

operation. In 1000 Mbps mode, all 8 bits are driven by

the PHY device.

RXD<3:0>

PHY

Note: MII operation at 10/100 Mbps is not supported.

RX_DV_0

RX_DV_1

RX_DV_2

RX_DV_3

Receive Data Valid:

RX_DV

RX_ER

CRS

PHY

This signal is asserted when valid data is present on

the corresponding RXD bus.

RX_ER_0

RX_ER_1

RX_ER_2

RX_ER_3

Receive Error:

In 1000 Mbps mode, asserted when error symbols or

carrier extension symbols are received.

Always synchronous to RX_CLK.

CRS_0

CRS_1

CRS_2

CRS_3

Carrier Sense:

Asserted when valid activity is detected at the line-

side interface.

COL_0

COL_1

COL_2

COL_3

Collision:

Asserted when a collision is detected and remains

asserted for the duration of the collision event. In full-

duplex mode, the PHY should force this signal Low.

COL

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.4

Reduced Gigabit Media Independent Interface (RGMII)

The IXF1104 supports the RGMII interface standard as defined in the RGMII Version 1.2

specification. The RGMII interface is an alternative to the IEEE 802.3u MII interface.

The RGMII interface is intended as an alternative to the IEEE 802.3u MII and the IEEE 802.3z

GMII. The principle objective of the RGMII is to reduce the number of balls (from a maximum of

28 balls to 12 balls) required to interconnect the MAC and the PHY. This reduction is both cost-

effective and technology-independent. To accomplish this objective, the data paths and all

associated control signals are reduced, control signals are multiplexed together, and both edges of

the clock are used.

• 1000 Mbps operation – clocks operate at 125 MHz

• 100 Mbps operation – clocks operate at 25 MHz

• 10 Mbps operation – clocks operate at 2.5 MHz.

Note: The IXF1104 RGMII interface is multiplexed with signals from the GMII interface. See T a ble 16

“Line Side Interface Multiplexed Balls” on page 57 for detailed information.

Figure 18. RGMII Interface

TXC_3:0

TXD[3:0]_3

TXD[3:0]_2

TXD[3:0]_1

TXD[3:0]_0

TX_CTL_3:0

TXC_3:0

TXD[3:0]_3

TXD[3:0]_2

TXD[3:0]_1

TXD[3:0]_0

TX_CTL_3:0

RXC_3:0

RXD[3:0]_3

RXD[3:0]_2

RXD[3:0]_1

RXD[3:0]_0

RX_CTL_3:0

RXC_3:0

RXD[3:0]_3

RXD[3:0]_2

RXD[3:0]_1

RXD[3:0]_0

RX_CTL_3:0

B3203-01

5.4.1

Multiplexing of Data and Control

Multiplexing of data and control information is achieved by utilizing both edges of the reference

clocks and sending the lower four bits on the rising edge and the upper four bits on the falling edge.

Control signals are multiplexed into a single clock cycle using the same technique. For further

information on timing parameters, see Figure 37 “RGMII Interface Timing” on page 140 and

T a ble 48 “RGMII Interface Timing Parameters” on page 140.

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IXF1104 Quad-Port 10/100/1000 Mbps Ethernet Media Access Controller

5.4.2

5.4.3

Timing Specifics

The IXF1104 RGMII complies with RGMII Rev1.2a requirements. T a ble 27 provides the timing

specifics.

TX_ER and RX_ER Coding

To reduce interface power, the transmit error condition (TX_ER) and the receive error condition

(RX_ER) are encoded on the RGMII interface to minimize transitions during normal network

operation (refer to Table 28 on page 96 for the encoding method). T a ble 27 provides signal

definitions for RGMII.

Table 27. RGMII Signal Definitions

RGMII

Standard Source

Signal

IXF1104

Signal

Description

Depending on speed, the transmit reference clock is 125 MHz, 25 MHz,

or 2.5 MHz +/– 50ppm.

TXC_0:3

TXC

MAC

Contains register bits 3:0 on the rising edge of TXC and register bits 7:4

on the falling edge of TXC.

TD[3:0]_n

TD<3:0>

TXEN is on the leading edge of TXC.

TX_EN

TX_CTL

MAC

TX_EN xor TX_ER is on the falling edge of TXC.

Continuous reference clock is 125 MHz, 25 MHz, or 2.5 MHz +/– 50

ppm.

RXC_0:3

RXC

PHY

Contains register bits 3:0 on the leading edge of RXC and register bits

7:4 on the trailing edge of RXC.

RD[3:0]_n

RD<3:0>

RX_DV is on the leading edge of RXC.

RX_DV

RX_CTL

PHY

RX_DV or RXERR is the falling edge of RXC.

The value of RGMII_TX_ER and RGMII_TX_EN are valid at the rising edge of the clock while

TX_ER is presented on the falling edge of the clock. RX_ER coding behaves in the same way (see

T a ble 28, Figure 19, and Figure 20).

Table 28. TX_ER and RX_ER Coding Description

Condition

Description

RX_ER = false

Receiving valid frame,

no errors

RX_DV = true

Logic High on rising edge of RXC

Logic High on the falling edge of RXC

Receiving valid frame,

with errors

RX_DV = true

Logic High on rising edge of RXC

RX_ER = true

Logic Low on the falling edge of RXC

Receiving invalid frame

(or no frame)

RX_DV = false

Logic Low on rising edge of RXC

RX_ER = false

Logic Low on the falling edge of RXC

TX_EN = true

TX_ER =false

Transmitting valid frame,

no errors

Logic High on rising edge of TXC

Logic High on the falling edge of TXC

TX_EN = true

TX_ER = true

Transmitting valid frame

with errors

Logic High on rising edge of TXC

Logic Low on the falling edge of TXC

TX_EN = false

TX_ER = false

Transmitting invalid

frame (or no frame)

Logic Low on rising edge of TXC

Logic low on the falling edge of TXC

NOTE: Refer to Figure 19 for TX_CTL behavior, and Figure 20 for RX_CTL behavior.

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Figure 19. TX_CTL Behavior

Valid Frame

TXC_0:3

(at Transmitter)

TD[3:0]

TD[7:4]

TD[3:0]_0:3

TX_CTL_0:3

TX_EN=True TX_ER=False

End-of-Frame

TX_EN=False TX_ER=False

Frame with Error

TXC_0:3

(at Transmitter)

TD[3:0]

TD[7:4]

TD[3:0]_0:3

TX_CTL_0:3

TX_EN=True TX_ER=False

TX_EN=False TX_ER=False

End-of-Frame

B0616-02

Figure 20. RX_CTL Behavior

Valid Frame

RXC_0:3

(at PHY)

RD[3:0]

RD[7:4]

RD[3:0]_0:3

RX_CTL_0:3

RX_DV=True RX_ER=False

RX_DV=False RX_ER=False

End-of-Frame

Frame with Error

RXC_0:3

(at PHY)

RD[3:0]

RD[7:4]

RD[3:0]_0:3

RX_CTL_0:3

RX_DV=True RX_ER=True

RX_DV=False RX_ER=False

End-of-Frame

B3237-01

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5.4.3.1

In-Band Status

Carrier Sense (CRS) is generated by the PHY when a packet is received from the network

interface. CRS is indicated when:

• RXDV = true.

• RXDV = false, RXERR = true, and a value of FF exists on the RXD[7:0] bits simultaneously.

• Carrier Extend, Carrier Extend Error, or False Carrier occurs (please reference the Hewlett-

Packard* Version 1.2a RGMII Specification for details.).

Carrier Extend and Carrier Extend Error are applicable to Gigabit speeds only. Collision is

determined at the MAC by the assertion of TXEN being true while either CRS or RXDV are true.

The PHY will not assert CRS as a result of TXEN being true.

5.4.4

10/100 Mbps Functionality

The RGMII interface implements the 10/100 Mbps Ethernet Media Independent Interface (MII) by

reducing the clock rate to 25 MHz for 100 Mbps operation and 2.5 MHz for 10 Mbps. The TXC is

generated by the MAC and the RXC is generated by the PHY. During packet reception, the RXC is

stretched on either the positive or negative pulse to accommodate transition from the free-running

clock to a data-synchronous clock domain. When the speed of the PHY changes, a similar

stretching of the positive or negative pulses is allowed. No glitching of the clocks is allowed during

speed transitions.

This interface operates at 10 Mbps and 100 Mbps speeds in the same manner as 1000 Mbps speed,

although the data may be duplicated on the falling edge of the appropriate clock. The MAC holds

TX_CTL Low until it is operating at the same speed as the PHY.

Note: The IXF1104 does not support 10/100 Mbps operation when configured in GMII mode

5.5

MDIO Control and Interface

The IXF1104 supports the IEEE 802.3 MII Management Interface, also known as the Management

Data Input/Output (MDIO) Interface. This interface allows the IXF1104 to monitor and control

each of the PHY devices that are connected to the four ports of IXF1104 when those ports are in

copper mode.

The MDIO Master Interface block is implemented once in the IXF1104. The MDIO Interface block

contains the logic through which the user accesses the registers in PHY devices connected to the

MDIO/MDC interface, which is controlled by each port.

The MDIO Master Interface block supports the management frame format, specified by IEEE

802.3, clause 22.2.4.5. This block also supports single MDI access through the CPU interface and

an autoscan mode. Autoscan allows the MDIO master to read all 32 registers of the per-port copper

PHYs and store the contents in the IXF1104. This provides external-CPU-ready access to the PHY

MDIO data bus for each register access.

Scan of a single register with low-frequency operation takes approximately 25.6 µs. Scan of a 32-

until approximately 19.2 µs after enabling scan. These numbers scale by 7/50 for high-frequency

operation.

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5.5.1

5.5.2

MDIO Address

The 5-bit PHY address for the MDIO transactions can be set in the “MDIO Single Command

($0x680)". Bits 5:2 of the PHY address are fixed to a value of 0. Bits 1 and 0 are programmable in

bits 9 and 8 of “MDIO Single Command ($0x680)".

MDIO Register Descriptions

For complete information on the MDI registers, refer to the Table 142 “MDIO Single Command

($0x680)” on page 210, T a ble 143 “MDIO Single Read and Write Data ($0x681)” on page 210,

T a ble 144 “Autoscan PHY Address Enable ($0x682)” on page 211, and T a ble 145 “MDIO Control

($0x683)” on page 211.

5.5.3

Clear When Done

The MDI Command register bit, in the “MDIO Single Command ($0x680)", clears upon command

completion and is set by the user to start the requested single MDIO Read or Write operation. This

bit is cleared automatically upon operation completion.

5.5.4

MDC Generation

The MDC clock is used for the MDIO/MDC interface. The frequency of the MDC clock is

selectable by setting bit 0, MDC Speed, in an IXF1104 configuration register (see Table 145

“MDIO Control ($0x683)” on page 211).

5.5.4.1

MDC High-Frequency Operation

The high-frequency MDC is 18 MHz, derived from the 125-MHz system clock by dividing the

frequency by 7.

The duty cycle is as follows:

• MDC High duration: 3 x (1/125 MHz) = 3 x 8 ns = 24 ns

• MDC Low duration: 4 x (1/125 MHz) = 4 x 8 ns = 32 ns

• MDC runs continuously after reset

Refer to Figure 41 “MDC High-Speed Operation Timing” on page 144 for the high-frequency

MDC timing diagram.

5.5.4.2

MDC Low-Frequency Operation

The low-frequency MDC is 2.5 MHz, which is derived from the 125-MHz system clock by

dividing the frequency by 50.

The duty cycle is as follows:

• MDC High duration: 25 x (1/125 MHz) = 25 x 8 ns = 200 ns

• MDC Low duration: 25 x (1/125 MHz) = 25 x 8 ns = 200 ns

• MDC runs continuously after reset

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Refer to Figure 42 “MDC Low-Speed Operation Timing” on page 144 for the low frequency MDC

timing diagram.

5.5.5

Management Frames

The Management Interface serializes the external register access information into the format

specified by IEEE 802.3, Section 22.2.4.5 (see Figure 21).

Figure 21. Management Frame Structure (Single-Frame Format)

Start

2 Bits

Op Code PHY Addr REG Addr Turnaround

2 Bits 5 Bits 5 Bits 2 Bits

Data

16 Bits

Preamble

32 Bits

First Bit Transmitted

Last Bit Transmitted

5.5.6

Single MDI Command Operation

The Management Data Interface is accessed through the “MDIO Single Command ($0x680)" and

the “MDIO Single Read and Write Data ($0x681)". A single management frame is sent by setting

The Write data is first set up in Register 1, bits 15:0 for Write operation. Register 0 is initialized

with the appropriate control information (start, op code, etc.) and Register 0, bit 20 is set to logic 1.

The steps are identical for Read operation except that in Register 1, bits 15:0, the data is ignored.

The data received from the MDIO is read by the CPU interface from Register 1, bits 31:16.

5.5.7

MDI State Machine

The MDI State Machine sequences the information sent to it by the MDIO control registers and

keeps track of the current sequence bit count, enabling or disabling the MDIO driver output (see

Figure 22.

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Figure 22. MDI State

MDOE = 0

MDO = 0

MDC_EN = 0

Idle

Go = 1

Cnt > 32

Cnt < 32

MDOE = 1

MDO = 1

Preamble

MDC_EN = 1

Cnt = 32

Cnt > 2

Cnt < 2

MDOE = 1

MDO = Reg_Bit_St(Cnt)

Start Bits

MDC_EN = 1

Cnt = 2

Cnt > 2

Cnt < 2

MDOE = 1

MDO = Reg_Bit_Op(Cnt)

Op Code

MDC_EN = 0

Cnt = 2

Cnt > 5

Cnt < 5

MDOE = 1

MDO = Reg_Bit_PA(Cnt)

Phy Addr

MDC_EN = 1

Cnt = 5

Cnt > 5

Cnt < 5

MDOE = 1

MDO = Reg_Bit_RA(Cnt)

Reg Addr

MDC_EN = 1

Cnt = 5

Cnt > 2

Cnt < 2

MDOE = Wr_Op

MDO = Reg_Bit_WO(Cnt)

Turn Around

MDC_EN = 1

Cnt = 2

Cnt < 16

MDOE = Wr_Op

MDO = Data(Cnt)

MDC_EN = 1

Data

Cnt > 16

or (Cnt = 16 and

Go = 0)

Cnt = 16 And Go = 1

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5.5.8

Autoscan Operation

The autoscan function allows the 32 registers in each external PHY (up to four) to be stored

internally in the IXF1104. Autoscan is enabled by setting bit 1 of the MDI Control register. When

enabled, autoscan runs continuously, reading each PHY register. When a PHY register access is

instigated through the CPU interface, the current autoscan register Read is completed before the

CPU register access starts. Upon completion of the CPU-induced access, the autoscan functionality

restarts from the last autoscan register access.

The“Autoscan PHY Address Enable ($0x682)" determines which PHY addresses are being

occupied for each IXF1104 port. The least significant bit (LSB) that is set in the register is Port 0,

the next significant bit that is set is assumed to be port 1, and so on. If more than four bits are set,

the bits beyond the fourth bit are ignored. If less than four bits are set, the round-robin process

returns to the port identified by the LSB being set.

5.6

SerDes Interface

The IXF1104 integrates four integrated Serializer/Deserializer (SerDes) devices that allow direct

connection to optical modules and remove the requirement for external SerDes devices. This

increases integration, which reduces the size of the PCB area required to implement this function,

reduces total power, reduces silicon and manufacturing costs, and improves reliability. Each

SerDes interface is identical and fully compliant with the relevant IEEE 802.3 Specifications,

including auto-negotiation. Each port is also compliant with and supports the requirements of the

Small Form Factor Pluggable (SFP) Multi-Source Agreement (MSA), see Section 5.7, “Optical

Module Interface” on page 106.

The following sections describe the operations supported by each interface, the configurable

options, and the register bits that control these options. A full list of the register addresses and full

bit definitions are found in the register maps (Table 59 through Table 69).

5.6.1

Features

The SerDes cores are designed to operate in point-to-point data transmission applications. While

the core can be used across various media types, such as PCB or backplanes, it is configured

specifically for use in 1000BASE-X Ethernet fiber applications in the IXF1104. The following

features are supported.

• 10-bit data path, which connects to the output/input of the 8B/10B encoder/decoder PCS that

resides in the MAC controller

• Data frequency of 1.25 GHz

• Low power: <200 mW per SerDes port

• Asynchronous clock data recovery

5.6.2

Functional Description

The SerDes transmit interface sends serialized data at 1.25 GHz. The interface is differential with

two signals for transmit operation. The transmit interface is designed to operate in a 100 Ω

differential environment and all the terminations are included on the device. The outputs are high-

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speed SerDes and are capable of operating in either an AC- or DC-coupled environment. AC

coupling is recommended for this interface to ensure that the correct input bias current is supplied

at the receiver.

The SerDes receive interface receives serialized data at 1.25 GHz. The interface is differential with

two signals for the receive operation. The equalizer receives a differential signal that is equalized

for the assumed media channel. The SerDes transmit and receive interfaces are designed to operate

within a 100 Ω differential environment and all terminations are included on the device. The

SerDes is capable of operating in either AC- or DC-coupled environments.

5.6.2.1

Transmitter Operational Overview

The transmit section of the IXF1104 has to serialize the Ten Bit Interface (TBI) data from the

IXF1104 MAC section and outputs this data at 1.25 GHz differential signal levels. The 1.25 GHz

differential SerDes signals are compliant with the Small Form Factor Pluggable (SFP) Multi-

Source Agreement (MSA).

The transmitter section takes the contents of the data register within the MAC and synchronously

transfers the data out, ten bits at a time – Least Significant Bit (LSB) first, followed by the next

Most Significant Bit (MSB). When these ten bits have been serialized and transmitted, the next

word of 10-bit data from the MAC is ready to be serialized for transmission.

The data is transmitted by the high-speed current mode differential SerDes output stage using an

internal 1.25 GHz clock generated from the 125 MHz clock input.

5.6.2.2

Transmitter Programmable Driver-Power Levels

The IXF1104 SerDes core has programmable transmitter power levels to enhance usability in any

given application.The SerDes Registers are programmable to allow adjustment of the transmit core

driver output power. When driving a 100 Ω differential terminated network, these output power

settings effectively establish the differential voltage swings at the driver output.

The “TX Driver Power Level Ports 0 - 3 ($0x784)" allows the selection of four discrete power

settings. The selected power setting of these inputs is applied to each of the transmit core drivers on

a per-port basis. T a ble 29 “SerDes Driver TX Power Levels” lists the normalized power settings of

the transmit drivers as a function of the Driver Power Control inputs. The normalized current

setting is 10 mA, which corresponds to the normalized power setting of 1.0. This is the default

setting of the IXF1104 SerDes interface. Other values listed in the Normalized Driver Power

Setting column are multiples of 10 mA. For example, with inputs at 1110, the driver power is the

following:

.5 x 10 mA = 5 mA.

Table 29. SerDes Driver TX Power Levels

Normalized

Driver Power

Setting

DRVPWRx[3] DRVPWRx[2] DRVPWRx[1] DRVPWRx[0]

Driver Power

1.33

13.3 mA

NOTE: All other values are reserved.

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Table 29. SerDes Driver TX Power Levels

Normalized

DRVPWRx[3] DRVPWRx[2] DRVPWRx[1] DRVPWRx[0]

Driver Power

Setting

2.0

1.0

0.5

20 mA

10 mA

5 mA

NOTE: All other values are reserved.

5.6.2.3

Receiver Operational Overview

The receiver structure performs Clock and Data Recovery (CDR) on the incoming serial data

stream. The quality of this operation is a dominant factor for the Bit Error Rate (BER) system

performance. Feed forward and feedback controls are combined in one receiver architecture for

enhanced performance. The data is over-sampled and a digital circuit detects the edge position in

the data stream. A signal is not generated if an edge is not found. A feedback loop takes care of

low-frequency jitter phenomenon of unlimited amplitude, while a feed forward section suppresses

high-frequency jitter having limited amplitude. The static edge position is held at a constant

position in the over-sampled by a constant adjustment of the sampling phases with the early and

late signals.

5.6.2.4

5.6.2.5

Selective Power-Down

The IXF1104 offers the ability to selectively power-down any of the SerDes TX or RX ports that

are not being used. This is done via “TX and RX Power-Down ($0x787)” on page 219.

Receiver Jitter Tolerance

The SerDes receiver architecture is designed to track frequency mismatch, recover phase, and is

tolerant of low-frequency data jitter. Figure 23 specifies the SerDes core receiver sinusoidal jitter

tracking capabilities.

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Figure 23. SerDes Receiver Jitter Tolerance

Sinusoidal Jitter Mask

16 ui

375 Hz 16 ui

10+1

22.5836 kHz 8.5 ui

1.9195 MHz 0.1 ui

10-1

Frequency

B0745-02

Note: UI = Unit interval.

5.6.2.6

Transmit Jitter

The SerDes core total transmit jitter, including contributions from the intermediate frequency PLL,

is comprised of the following two components:

• A deterministic component attributed to the SerDes core’s architectural characteristics

• A random component attributed to random thermal noise effects

Since the thermal noise component is random and statistical in nature, the SerDes core total

transmit jitter must be specified as a function of BER.

5.6.2.7

Receive Jitter

The SerDes core total receiver jitter, including contributions from the intermediate frequency PLL,

is comprised of the following two components:

• A deterministic component attributed to the SerDes core architectural characteristics

• A random component attributed to random thermal noise effects.

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5.7

Optical Module Interface

This section describes the connection of the IXF1104 ports to an Optical Module Interface and

details the minimal connections that are supported for correct operation. The registers used for

write control and read status information are documented.

The Optical Module Interface allows the IXF1104 a seamless connection to the Small Form Factor

Optical Modules (SFP) that form the system’s physical media connection, eliminating the need for

any FPGAs or CPUs to process data. All required optical module information is available to the

system CPU through the IXF1104 CPU interface, leading to a more integrated, reliable, and cost-

effective system.

The IXF1104 supports all the functions required for the Small Form Factor pluggable Multi-Source

Agreement (MSA).

There are specific mechanical and electrical requirements for the size, form factor, and connections

supported on all Optical Module Interfaces. There are also specific requirements for each Optical

Module Interface that supports a particular media requirement or interface configuration. These

requirements are detailed in the relevant specifications or manufacturers’ datasheets.

5.7.1

IXF1104-Supported Optical Module Interface Signals

To describe the Optical Module Interface operation, three supported signal subgroups are required,

allowing a more explicit definition of each function and implementation. The three subgroups are

as follows:

• High-Speed Serial Interface

• Low-Speed Status Signaling Interface

• I²C Module Configuration Interface

T a ble 30 provides descriptions for IXF1104-to-SFP optical module connection signals.

Table 30. IXF1104-to-SFP Optical Module Interface Connections (Sheet 1 of 2)

IXF1104

Signal Names

SFP Signal

Names

Description

Notes

TX_P_0:3

TX_N_0:3

RX_P_0:3

RX_N_0:3

TD+

TD-

Transmit Data, Differential LVDS

Receive Data, Differential LVDS

Output from the IXF1104

Input to the IXF1104

RD+

RD-

Input to the IXF1104

I²C_CLK output from the IXF1104

(SCL)

I²C_CLK

MOD-DEF1

MOD-DEF2

MOD-DEF0

Output from the IXF1104

Input/Output

I²C_DATA_0:3

MOD_DEF_0:3

I²C_DATA I/O (SDA)

MOD_DEF_0 is TTL Low level during

normal operation.

Input to the IXF1104

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Table 30. IXF1104-to-SFP Optical Module Interface Connections (Sheet 2 of 2)

IXF1104

Signal Names

SFP Signal

Names

Description

Notes

Transmitter disable, logic High, open

collector compatible

TX_DISABLE_0:3 TX DISABLE

Output from the IXF1104

Input to the IXF1104

Transmitter fault, logic High, open

collector compatible

TX_FAULT_0:3

RX_LOS_0:3

TX FAULT

LOS

Receiver loss-of-signal, logic High,

open collector compatible

5.7.2

Functional Descriptions

High-Speed Serial Interface

5.7.2.1

These signals are responsible for transfer of the actual data at 1.25 Gbps. Table 41 “Intel®

IXF1104 MAC DC Specifications” on page 133 shows the data is 8B/10B encoded and transmitted

differentially.

The following signals are required to implement the high-speed serial interface:

• TX_P_0:3

• TX_N_0:3

• RX_P_0:3

• RX_N_0:3

5.7.2.2

Low-Speed Status Signaling Interface

The following Low-Speed signals indicate the state of the line through the Optical Module

Interface:

• MOD_DEF_0:3

• TX_FAULT_0:3

• RX_LOS_0:3

• TX_DISABLE_0:3

• MOD_DEF_INT

• TX_FAULT_INT

• RX_LOS_INT

5.7.2.2.1 MOD_DEF_0:3

MOD_DEF_0:3 are direct inputs to the IXF1104 and are pulled to a logic Low level during normal

operation, indicating that a module is present for each channel respectively. If a module is not

present, a logic High is received, which is achieved by an external pull-up resistor at the IXF1104

device pad.

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The status of each bit (one for each port) is found in bits [3:0] of the “Optical Module Status Ports

0-3 ($0x799)” on page 221). Any change in the state of these bits causes a logic Low level on the

MOD_DEF_INT output if this operation is enabled.

5.7.2.2.2 TX_FAULT_0:3

TX_FAULT_0:3 are inputs to the IXF1104. These signals are pulled to a logic Low level by the

optical module during normal operation. A logic Low level on these signals indicates no fault

condition exists. If a fault is present, a logic High is received through the use of an external pull-up

resistor at the IXF1104 pad.

The status of each bit (one for each port) can be found in bits [13:10] of the “Optical Module Status

Ports 0-3 ($0x799)” on page 221. Any change in the state of these bits causes a logic Low level on

the TX_FAULT_INT output if this operation is enabled.

5.7.2.2.3 RX_LOS_0:3

RX_LOS_0:3 are inputs to the IXF1104. These signals are pulled to a logic Low level by the

optical module during normal operation, which indicates that no loss-of-signal exists. If a loss-of-

signal occurs, a logic High is received on these inputs through the use of an external pull-up

resistor at the IXF1104 device pad.

The status of each bit (one for each port) is found in “Optical Module Status Ports 0-3 ($0x799)"

bits [23:20]. Any change in the state of these bits causes a logic Low level on the RX_LOS_INT

output if this operation is enabled.

5.7.2.2.4 TX_DISABLE_0:3

TX_DISABLE_0:3 are outputs from the IXF1104. These signals are driven to a logic Low level by

the IXF1104 during normal operation. This indicates that the optical module transmitter is enabled.

If the optical module transmitter is disabled, this signal is switched to a logic High level. On the

IXF1104, these outputs are open drain types and pulled up by the 4.7 k to 10 k pull-up resistor at

the Optical Module Interface. Each of these signals is controlled through bits 3:0 respectively of

the “Optical Module Control Ports 0 - 3 ($0x79A)".

5.7.2.2.5 MOD_DEF_INT

MOD_DEF_INT is a single output, open-drain type signal and is active Low. A change in state of

any MOD_DEF_0:3 inputs causes this signal to switch Low and remain in this state until a read of

the “Optical Module Status Ports 0-3 ($0x799)". The signal then returns to an inactive state.

5.7.2.2.6 TX_FAULT_INT

TX_FAULT_INT is a single output, open-drain type signal and is active Low. A change in state of

any TX_FAULT_0:3 inputs causes this signal to switch Low and remain in this state until a read of

the “Optical Module Status Ports 0-3 ($0x799)". The signal then returns to an inactive state.

5.7.2.2.7 RX_LOS_INT

RX_LOS_INT is a single output, open-drain type signal and is active low. A change in state of any

of the RX_LOS_3:0 inputs causes this signal to switch low and remain in this state until a Read of

the “Optical Module Status Ports 0-3 ($0x799)" has taken place. The signal returns to an inactive

state.

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Note: MOD_DEF_INT, TX_FAULT_INT, and RX_LOS_INT are open-drain type outputs. With the

three signals on the device, the system can decide which “Optical Module Status Ports 0-3

($0x799)" bits to look at to identify the interrupt condition source port. However, this is achieved at

the expense of the three device signals.

5.7.3

I²C Module Configuration Interface

The I²C interface is supported on SFP optical modules. Details of the operation are found in the

SFP Multi-Source Agreement, which details the contents of the registers and addresses accessible

on a given Optical Module Interface supporting this interface.

The SFP MSA identifies up to 512 8-bit registers that are accessible in each optical module. The

Optical Module Interface is read-only and supports either sequential or random access to the 8-bit

parameters. The maximum clock rate of the interface is 100 kHz. All address-select signals on the

internal E²PROM are tied Low to give a device address equal to zero (00h).

Several PHY vendors may offer copper/CAT5-based SFP optical compliant modules. To program

the internal configuration registers of these modules, the IXF1104 I²C interface needs to provide

the capability to write data to the SFP modules.

The IXF1104 I²C interface is designed to allow individual writes of byte-wide data to the SFP.

The specific interface in the IXF1104 supports only a subset of the full I²C interface, and only the

features required to support the Optical Module Interfaces are implemented. This leads to the

following support features.

• Single I²C_CLK pin connected to all optical modules and implemented to save unnecessary

signals use.

• Four per-port I²C_DATA signals (I²C Data[3:0]) are required because of the optical module

requirement that all modules must be addressed as 00h.

• The interface has both read and write functionality.

• Due to the single internal optical module controller, only one optical module may be accessed

at any one time. Each access contains a single register Read. Since these register accesses will

most likely be done during power-up or discovery of a new module, these restrictions should

not affect normal operation.

• The I²C interface supports byte write accesses to the full address range.

5.7.3.1

5.7.3.2

I²C Control and Data Registers

In the IXF1104, the entire I²C interface is controlled through the following two registers:

• “I2C Control Ports 0 - 3 ($0x79B)” on page 222

• “I2C Data Ports 0 - 3 ($0x79F)” on page 222

These registers can be programmed by system software using the CPU interface.

I²C Read Operation

To perform a read operation using the I²C interface, use the following sequence:

1. Initialize the Control register by setting the following values:

a. Enable the I²C Controller by setting bit [25] to 0x1.

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b. Initiate the I²C transfer by setting bit [24] of the control register to 0x1.

c. Select the port by using bits [17:16].

d. Select the Read mode of operation by setting bit [15] to 0x1.

e. Select the Device ID by setting bits [14:11].

f. Select the register address by setting bits [10:0].

2. Set the Device ID field to 0xA and the register address (bits 10:8) to 0x0 to access the fiber

module serial E2PROM. Setting the Device ID field to 0xA and the Register Address [10:8] to

0x0 permits read-only access.

3. Set the Device ID field to 0xA and the Register Address [10:8] between the values of 0x1 and

0x7 to access the PHY registers.

4. Poll the Read_Valid field, bit 20. The read data is available when this bit is set to 0x1.

Figure 24 shows an 8-bit read access.

Note: The user software ensures the order of the contiguous accesses required to read the High and Low

bytes of 16-bit-wide PHY registers.

Figure 24. I²C Random Read Transaction

DEVICE

ADDRESS

WORD

ADDRESS

DEVICE

ADDRESS

I²C_Data Line

B W

DATAn

DUMMY WRITE

(* = DON'T CARE bit for 1k)

Note: Only one optical module I²C access sequence can be run at any given time. If a second write is

carried out to the “I2C Control Ports 0 - 3 ($0x79B)" and “I2C Data Ports 0 - 3 ($0x79F)" before a

result is returned for the previous write, the data for the first write is lost. An internal state machine

completes the Optical Module Interface register access for the first write. It attempts to place the

data in the DataRead field and checks to see if the WriteCommand bit is 00h. If it is not 00h, it

discards the data and signals the I²C access state machine to begin a new cycle using the data from

the second write.

5.7.3.3

I²C Write Operation

The following sequence provides an example of writing data to Register Address 0xFF for Port 3:

1. Program the “I2C Control Ports 0 - 3 ($0x79B)" with the following information:

a. Enable the I²C block by setting Register bit 25 to 0x1.

b. Set the port to be accessed by setting Register bits 17:16 to 0x3.

c. Select a Write access by setting Register bit 15 to 0x0.

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d. Set the Device ID Register bits 14:11 to Ah (Atmel compatible).

e. Set the 11-bit register address (Register bits 10:0) to 0FFh.

f. Enable the I²C controller by setting Register bit 2 to 0x1.

g. Initiate the I²C transfer by setting Register bit 24 to 0x1.

All other bits in this register should be set to 0x0.

This data is written into the “I2C Control Ports 0 - 3 ($0x79B)" in a single cycle via the CPU

interface.

2. When this register is written and the I²C Start bit is at a Logic 1, the I²C access state machine

examines the Port Address Select and enables the I²C_DATA_0:3 output for the selected port.

3. The state machines uses the data in the Device ID and Register Address fields to build the data

frame to be sent to the optical module

4. The I²C_DATA_WRITE_FSM internal state machine takes over the task of transferring the

actual data between the IXF1104 and the selected optical module (refer to the details in

Section 5.7.3.4, “I²C Protocol Specifics” on page 111).

5. The I²C_DATA_WRITE_FSM internal state machine uses the data from the Write_Data field

bits [23:16] of the “I2C Data Ports 0 - 3 ($0x79F)” on page 222 and sets the Write_Complete

Access is complete.

6. The data is written through the CPU interface. The CPU must poll the Write_Complete bit

until it is set to 0x1. It is safe to request a new access only when this bit is set.

Note: Only one optical module I²C access sequence can be run at any given time. The data for the first

Write is lost if a second Write is carried out to the “I2C Control Ports 0 - 3 ($0x79B)" before a

result is returned for the previous Write. Make sure Write complete = 0x1 before starting the next

Write sequence to ensure that no data is lost.

5.7.3.4

I²C Protocol Specifics

Section 5.7.3.4 describes the IXF1104 I²C Protocol behavior, which is controlled by an internal

state machine. Specific protocol states are defined below, with an additional description of the

hardware signals used on the interface.

The Serial Clock Line (I²C_CLK) is an output from the IXF1104. The serial data is synchronous

with this clock and is driven off the rising edge by the IXF1104 and off the falling edge by the

optical module. The IXF1104 has only one I²C_CLK line that drives all of the optical modules.

I²C_CLK runs continuously when enabled (I²C Enable = 01h0).

The Serial Data (I²C_DATA_3:0) signals (one per port) are bi-directional for serial data transfer.

These signals are open drain.

5.7.3.5

5.7.3.6

Port Protocol Operation

Clock and Data Transitions

The I²C_DATA is normally pulled High with an extra device. Data on the I²C_DATA pin changes

only during the I²C_CLK Low time periods (see Figure 25). Data changes during I²C_CLK High

periods indicate a start or stop condition.

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Figure 25. Data Validity Timing

I²C_Data

I²C_Clk

DATA STABLE

DATA

CHANGE

5.7.3.6.1 Start Condition

A High-to-Low transition of I²C_DATA, with I²C_CLK High, is a start condition that must

precede any other command (see Figure 26).

5.7.3.6.2 Stop Condition

A Low-to-High transition of the I²C_DATA with I²C_CLK High is a stop condition. After a Read

sequence, the stop command places the E²PROM and the optical module in a standby power mode

(see Figure 26).

Figure 26. Start and Stop Definition Timing

I²C_Data

STOP

START

5.7.3.6.3 Acknowledge

All addresses and data words are serially transmitted to and from the optical module in 8-bit words.

The optical module E²PROM sends a zero to acknowledge that it has received each word, which

happens during the ninth clock cycle (see Figure 27).

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Figure 27. Acknowledge Timing

I²C_Data

DATA IN

DATA OUT

START

ACKNOWLEDGE

5.7.3.6.4 Memory Reset

After an interruption in protocol, power loss, or system reset, any 2-wire optical module can be

reset by following three steps:

1. Clock up to 9 cycles

2. Wait for I²C_DATA High in each cycle while I²C_CLK is High

3. Initiate a start condition.

5.7.3.6.5 Device Addressing

All E²PROMs in SFP optical module devices require an 8-bit device address word following a start

condition to enable the chip to read or write. The device address word consists of a mandatory one,

zero sequence for the four most-significant bits. This is common to all devices. The next three bits

are the A2, A1, and A0 device address bits that are tied to zero in an optical module. The eighth bit

of the device address is the Read/Write operation select bit. A Read operation is initiated if this bit

is High and a Write operation is initiated if this bit is Low.

Upon comparison of the device address, the optical module outputs a zero. If a comparison is not

made, the optical module E²PROM returns to a standby state.

5.7.3.6.6 Random Read Operation

A random Read requires a “dummy” Byte/Write sequence to load the data word address. The

“dummy” write is achieved by first sending the device address word with the Read/Write bit

cleared to Low, which signals a Write operation. The optical module acknowledges receipt of the

device address word. The IXF1104 sends the data word address, which is again acknowledged by

the optical module. The IXF1104 generates another start condition. This completes the “dummy”

write and sets the optical module E²PROM pointers to the desired location.

The IXF1104 initiates a current address read by sending a device address with the Read/Write bit

set High. The optical module acknowledges the device address and serially clocks out the data

word. The IXF1104 does not respond with a zero but generates a stop condition (see Figure 28).

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Figure 28. Random Read

DEVICE

ADDRESS

WORD

ADDRESS

DEVICE

ADDRESS

I²C_Data Line

B W

DATAn

DUMMY WRITE

(* = DON'T CARE bit for 1k)

5.8

LED Interface

The IXF1104 uses a Serial interface, consisting of three signals, to provide LED data to some form

of external driver. This provides the data for 12 separate direct drive LEDs and allows three LEDs

per MAC port.

There are two modes of operation, each with its own separate LED decode mapping. Modes of

operation and LEDs are detailed in the following sections.

5.8.1

Modes of Operation

There are two modes of operation: Mode 0 and Mode 1. Mode selection is accomplished by using

the LED_SEL_MODE bit. This bit is globally selected and controls the operation of all ports (see

T a ble 109 “LED Control ($0x509)” on page 189).

Mode 0: (LED_SEL_MODE = 0 [Default]): This mode selects operations compatible with the

SGS Thompson M5450 LED Display Driver device. This device converts the serial data stream,

output by the IXF1104, into 30 direct-drive LED outputs. Although the LED interface is capable of

driving all 30 LEDs, only twelve will be driven in the four-port IXF1104, three LEDs per port.

Mode 1: (LED_SEL_MODE = 1): This mode is used with standard TTL (74LS599) or HCMOS

(74HC599) octal shift registers with latches, providing the most general and cost-effective

implementation of the serial data stream conversion.

In addition to these physical modes of operation, there are two types of specific LED data decodes

available for fiber and copper modes. This option is a global selection and controls the operation of

all ports (see T a ble 109 “LED Control ($0x509)” on page 189).

5.8.2

LED Interface Signal Description

The IXF1104 LED interface consists of three output signal signals that are 2.5 V CMOS level pads.

T a ble 31 provides LED signal names, pin numbers, and descriptions.

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Table 31. LED Interface Signal Descriptions

Pin Name

Pin #

Pin Description

This signal is an output that provides a continuous clock synchronous to the

serial data stream output on the LED_DATA pin. This clock has a maximum

speed of 720 Hz.

LED_CLK

K24

The behavior of this signal remains constant in all modes of operation.

This signal provides the data, in various formats, as a serial bit stream. The data

must be valid on the rising edge of the LED_CLK signal.

LED_DATA

M22

L22

In Mode 0, the data presented on this pin is TRUE (Logic 1 = High).

In Mode 1, the data presented on this pin is INVERTED (Logic 1 = Low).

This is an output pin, and the signal is used only in Mode 1 as the Latch enable

for the shift register chain.

LED_LATCH

This signal is not used in Mode 0, and should be left unconnected.

5.8.3

Mode 0: Detailed Operation

Note: Please refer to the SGS Thompson* M5450 datasheet for device-operation information.

The operation of the LED Interface in Mode 0 is based on a 36-bit counter loop. The data for each

LED is placed in turn on the serial data line and clocked out by the LED_CLK. Figure 29 shows the

basic timing relationship and relative positioning in the data stream of each bit.

Figure 29 shows the 36 clocks that are output on the LED_CLK pin. The data is changed on the

falling edge of the clock and is valid for almost the entire clock cycle. This ensures that the data is

valid during the rising edge of the LED_CLK, which clocks the data into the M5450 device.

The actual data shown in Figure 29 consists of a chain of 36 bits, 12 of which are valid LED

DATA. The 36-bit data chain is built up as follows:

Figure 29. Mode 0 Timing

25 26 27 28 29 30 31 32 33 34 35

22 23 24 25 26 27 28 29 30

LED_CLK

LED_DATA

LED_LATCH

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Table 32. Mode 0 Clock Cycle to Data Bit Relationship

LED_DATA

Name

LED_CLK Cycle

LED_DATA Description

This bit synchronizes the M5450 device to expect 35 bits of data to

follow.

START BIT

These bits are used only as fillers in the data stream to extend the

length from the actual 12-bit LED DATA to the required 18-bit frame

length. These bits should always be a logic 0.

2:3

4:15

36:38

PAD BITS

These bits are the actual data transmitted to the M5450 device. The

decode for each individual bit in each mode is defined in T able 34 on

page 118.

LED DATA 1-12

PAD BITS

The data is TRUE. Logic 1 (LED ON) = High

These bits are used as fillers in the data stream to extend the length

from the actual 30-bit LED DATA to the required 36-bit frame length.

These bits should always be a logic 0.

When implemented on the board with the M5450 device, the LED DATA bit 1 appears on Output

bit 3 of the M5450 and the LED DATA bit 2 appears on Output bit 4, etc. This means that Output

bits 1, 2, and 15 through 35 will never have valid data and should not be used.

5.8.4

Mode 1: Detailed Operation

Note: Please refer to generic specifications for 74LS/HC599 for information on device operation.

The operation of the LED Interface in Mode 1 is based on a 36-bit counter loop. The data for each

LED is placed in turn on the serial data line and clocked out by the LED_CLK. Figure 30 on

page 117 shows the basic timing relationship and relative positioning in the data stream of each bit.

Figure 30 on page 117 shows the 36 clocks which are output on the LED_CLK pin. The data is

changed on the falling edge of the clock and is valid for the almost the entire clock cycle. This

ensures that the data is valid during the rising edge of the LED_CLK, which clocks the data into the

shift register chain devices.

The LED_LATCH signal is required in Mode 1, and latches the data shifted into the shift register

chain into the output latches of the 74HC599 device. Figure 30 shows that the LED_LATCH signal

is active High during the Low period on the 35th LED_CLK cycle. This avoids any possibility of

trying to latch data as it is shifting through the register.

When this operation mode is implemented on a board with a shift register chain containing three

74HC599 devices, the LED DATA bit 1 is output on Shift register bit 1, and so on up the chain.

Only Shift register bits 31 and 32 do not contain valid data.

The actual data shown in Figure 30 consists of a 36-bit chain, of which 12 bits are valid LED

DATA. The 36-bit data chain is built up as shown in Figure 30.

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Note: The LED_DATA signal is now inverted from the state in Mode 0.

Figure 30. Mode 1 Timing

25 26 27 28 29 30 31 32 33 34 35

22 23 24 25 26 27 28 29 30

LED_CLK

LED_DATA

LED_LATCH

Table 33. Mode 1 Clock Cycle to Data Bit Relationship

LED_CLK Cycle LED_DATA Name LED_DATA Description

This bit has no meaning in Mode 1 operation and is shifted out of

START BIT

PAD BITS

the 16-stage shift register chain before the LED_LATCH signal is

asserted.

These bits have no meaning in Mode 1 operation and are shifted

out of the 16-stage shift register chain before the LED_LATCH

signal is asserted.

2:3

These bits are the actual data to be transmitted to the 16-stage shift

Table 34 on page 118.

4:15

LED DATA 1-12

PAD BITS

The data is INVERTD. Logic 1 (LED ON) = Low.

These bits have no meaning in Mode 1 operation and are latched

into positions 31 and 32 in the shift register chain. These bits are

not considered as valid data and should be ignored. They should

always be a Logic 0 = High.

36:38

5.8.5

5.8.6

Power-On, Reset, Initialization

The LED interface is disabled at power-on or reset. The system software controller must enable the

LED interface. The internal state machines and output signals are held in reset until the full

IXF1104 4-Port Gigabit Ethernet Media Access Controller device configuration is completed. This

is done by setting the LED_ENABLE bit to a logic 1 (see Table 109 “LED Control ($0x509)” on

page 189). The power-on default for this bit is logic 0.

LED DATA Decodes

The data transmitted on the LED_DATA line is determined by programming the global operation

mode as either fiber or copper. T a ble 34 shows the data decode of the data for both fiber and copper

MACs.

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Note: The data decode of the LED bits is independent of the Physical mode selection.

Table 34. LED_DATA# Decodes

LED_DATA# MAC Port #

Fiber Designation

Copper Designation

Rx LED—Amber

Rx LED—Green

TX LED—Green

Rx LED—Amber

Rx LED—Green

TX LED—Green

Rx LED—Amber

Rx LED—Green

TX LED—Green

Rx LED—Amber

Rx LED—Green

TX LED—Green

Link LED—Amber

Link LED—Green

Activity LED—Green

Link LED—Amber

Link LED—Green

Activity LED—Green

Link LED—Amber

Link LED—Green

Activity LED—Green

Link LED—Amber

Link LED—Green

Activity LED—Green

5.8.6.1

LED Signaling Behavior

Operation in each mode for the decoded LED data in Table 34 is detailed in Table 35 and Table 36.

5.8.6.1.1 Fiber LED Behavior

Table 35. LED Behavior (Fiber Mode)

Type

Status

Description

Synchronization occurs but no packets are received

and the “Link LED Enable ($0x502)” is not set.

Off

RX Synchronization has not occurred or no optical

signal exists.

Amber On

The port has remote fault and the “Link LED Enable

($0x502)” is not set (based on remote fault bit setting

received in Rx_Config word).

RXLED

Amber Blinking

RX Synchronization occurs and the “Link LED Enable

($0x502)” bit is set.

Green On

Green Blinking

Off

RX Synchronization occurs and the port is receiving

data.

The port is not transmitting data or the “Link LED

Enable ($0x502)” is not set.

TXLED

The port is transmitting data and the “Link LED Enable

($0x502)” bit is set

Green Blinking

NOTE: T able 35 assumes the port is enabled in the “Port Enable ($0x500)” and the LEDs are enabled in the

“LED Control ($0x509)”. If a port is not enabled, all the LEDs for that port will be off. If the LEDs are not

enabled, all of the LEDs will be off.

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5.8.6.1.2 Copper LED Behavior

Table 36. LED Behavior (Copper Mode)

Type

Status

Description

Port does not have a remote fault and “LED Control

($0x509)” on page 189 bit is not set.

Off

Port has an RGMII RXERR condition detected and

“LED Control ($0x509)” on page 189 bit is set

Amber On

Amber Blinking

Link LED

Port has a remote fault and “LED Fault Disable

($0x50B)” on page 190 is not set.

“LED Control ($0x509)” on page 189 bit is set and port

does not have an RGMII RXERR error or remote fault

condition present.

Green On

Off

Port is not transmitting and receiving data.

“LED Control ($0x509)” on page 189 set: Port is

transmitting and/or receiving.

Activity LED - Green

Blinking

“LED Control ($0x509)” on page 189 not set: Port is

receiving data.

NOTE: T a ble 34 “LED_DATA# Decodes” assumes the port is enabled in the “Port Enable ($0x500)” on

page 187 and the LEDs are enabled in the “LED Control ($0x509)” on page 189. If a port is not

enabled, all the LEDs for that port are off. If the LEDs are not enabled, all of the LEDs are off.

5.9

CPU Interface

The CPU interface block provides access to registers and statistics in the IXF1104. The interface is

asynchronous externally and operates within the 125 MHz clock domain internally. The interface

provides access to the following:

• Receive statistics registers

• Transmit statistics registers

• Receive FIFO registers

• Transmit FIFO registers

• Global configuration and control registers

• MAC_0 to MAC_3 registers

The CPU interface width can be configured with the two strap signals (UPX_WIDTH[1:0]) to

operate as an 8-bit, 16-bit, or 32-bit bus. All internal accesses to registers are 32-bit (4, 2, or 1 data

cycles respectively are required to fully access a register). When operating in 8-bit or 16-bit mode,

read data for bytes [3:1] is strobed into read holding registers when byte [0] is read. Subsequent

reads of bytes {1, 2, 3} in byte mode or of bytes {2,3} in 16-bit mode are supplied from the holding

{0, 1, 2} is similarly captured in internal write holding registers and the complete 32-bit write is

committed when byte[3] is written to the IXF1104. When writing in 16-bit mode, bytes [1:0] are

captured, and the double-word is committed when bytes [3:2] are written. The complete address for

write is ignored (except for the write which causes the commit operation).

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5.9.1

Functional Description

Read Access

5.9.1.1

Read access involves the following:

• Detect assertion of asynchronous Read control signal and latch address

• Generate internal Read strobe

• Drive valid data onto processor bus

• Assert asynchronous Ready signal for required length of time

Figure 31 shows the timing of the asynchronous interface for Read access.

Figure 31. Read Timing Diagram - Asynchronous Interface

TCAS

TCAH

uPx_ADD[12:0]

TCRR

uPx_CsN

uPx_RdN

TCRH

uPx_Data[31:0]

uPx_RdyN

TCDRS

TCDRH

TCDRD

5.9.1.2

Write Access

Write process involves the following:

• Detect assertion of asynchronous Write control signal and latch address

• Detect de-assertion of asynchronous Write control signal and latch data

• Generate internal Write strobe

• Assert asynchronous Ready signal for required length of time

Figure 32 shows the timing of the asynchronous interface for Write accesses.

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Figure 32. Write Timing Diagram - Asynchronous Interface

TCAS

TCAH

uPx_Add[12:0]

uPx_CsN

uPx_WrN

TCWL

TCWH

TCDWH

uPx_Data[31:0]

uPx_RdyN

TCDWS

TCYD

TCDWD

5.9.1.3

5.9.2

CPU Timing Parameters

For information on the CPU interface Read and Write cycle AC timing parameters, refer to Figure

47 “CPU Interface Read Cycle AC Timing” on page 148, Figure 48 “CPU Interface Write Cycle

AC Timing” on page 148, and Table 54 “CPU Interface Write Cycle AC Signal Parameters” on

page 149.

Endian

The Endian of the CPU interface may be changed to allow connection of various CPUs to the

IXF1104 4-Port Gigabit Ethernet Media Access Controller. The Endian selection is determined by

setting the Endian bit in the “CPU Interface ($0x508)".

The following describes Endianness control:

• There is a byte swapper between the internal 32-bit bus and the external 32-bit bus.

• In 8-bit or 16-bit mode operation, the byte packer/byte unpacker holding registers sink and

source data just like the 32-bit external bus in 32-bit mode.

• The “CPU Interface ($0x508)" selects Big-Endian or Little-Endian mode.

• The byte swapper causes the behavior seen in Table 37 for accessing a register with data bits

data[31:0].

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Table 37. Byte Swapper Behavior

Little Endian

Big Endian

16-bit

UPX_BADD

[1:0]

32-bit

16-bit

8-bit¹

32-bit

8-bit¹

UPX_DATA_ UPX_DATA_ UPX_DATA

UPX_DATA

[31:0]

UPX_DATA

[15:0]

UPX_DATA

[7:0]

[31:0]

[15:0]

[7:0]

[15:8]

[23:16

[31:24]

[7:0]

[15:8]

[31:0]

[15:0]

[7:0]

–

[31:16]

–

[15:8]

[23:16]

[31:24]

–

[15:8]

[23:16]

[31:24]

[23:16]

[31:24]

–

1. In 8-bit mode, data is output in Little Endian format regardless of the IXF1104 Endian setting.

5.10

TAP Interface (JTAG)

The IXF1104 includes an IEEE 1149.1 compliant Test Access Port (TAP) interface used during

boundary scan testing. The interface consists of the following five signals:

• TDI – Serial Data Input

• TMS – Test Mode Select

• TCLK – TAP Clock

• TRST_L – Active Low asynchronous reset for the TAP

• TDO – Serial Data Output

TDI and TMS require external pull-up resistors to float the signals High per the IEEE 1149.1

specification. Pull-ups are recommended on TCK and TDO. For normal operation, TRST_L can be

pulled Low, permanently disabling the JTAG interface. If the JTAG interface is used, the TAP

controller must be reset as described in Section 5.10.1, “TAP State Machine” on page 122 and

returned to a logic High.

5.10.1

TAP State Machine

The TAP signals drive a TAP controller, which implements the 16-state state machine specified by

the IEEE 1149.1 specification. Following power-up, the TAP controller must be reset by one of

following two mechanisms:

• Asynchronous reset

• Synchronous reset

Asynchronous reset is achieved by pulsing or holding TRST_L Low. Synchronous reset is

achieved by clocking TCLK with five clock pulses while TMS is held or floats High. This ensures

that the boundary scan cells do not block the pin to core connections in the IXF1104.

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5.10.2

Instruction Register and Supported Instructions

The instruction register is a 4-bit register that enacts the boundary scan instructions. After the state

machine resets, the default instruction is IDCODE. The decode logic in the TAP controller selects

the appropriate data register and configures the boundary scan cells for the current instruction.

T a ble 38 shows the supported boundary-scan instructions.

Table 38. Instruction Register Description

Instruction

Code

Description

Data Register

BYPASS

EXTEST

SAMPLE

IDCODE

HIGHZ

1111

0000

0001

0110

0101

0111

1-bit Bypass

Bypass

External Test

Boundary Scan

Sample Boundary

ID Code Inspection

Float Boundary

Clamp Boundary

Bypass

CLAMP

Bypass

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5.10.3

5.10.4

ID Register

The ID register is a 32-bit register. The IDCODE instruction connects this register between TDI

and TDO. See Table 112 “JTAG ID ($0x50C)” on page 191 for detailed information.

Boundary Scan Register

The Boundary Scan register is a shift register made up of all the boundary scan cells associated

with the device signals. The number, type, and order of the boundary scan cells are specified in the

IXF1104 BSDL file. The EXTEST and SAMPLE instructions connect this register between TDI

and TDO.

5.10.5

Bypass Register

The Bypass register is a 1-bit register that bypasses the IXF1104 to reduce the JTAG chain length

when accessing other devices on the chain besides the IXF1104. The BYPASS, HIGHZ, and

CLAMP instructions connect this register between TDI and TDO.

5.11

Loopback Modes

The IXF1104 provides two loopback modes for device diagnostic testing when it has been

integrated into a user system. A line-side loopback allows the line-side receive interface to be

looped back to the transmit line-side interface. A SPI3 loopback mode allows the SPI3 transmit

interface to be looped back to the SPI3 receive interface.

5.11.1

SPI3 Interface Loopback

To provide a diagnostic loopback feature on the SPI3 interface, it is possible to configure the

IXF1104 to loop back any data written to the IXF1104 through the SPI3 transmit interface back to

the SPI3 receive interface. This is accomplished using the data path shown in Figure 33.

Note: Loopback packets also appear on the line side TX interface.

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Figure 33. SPI3 Interface Loopback Path

SPI3 Internal Loopback

TX FIFO

SPI3 Interface

Block

Line Side

Interface

MAC

RX FIFO

B3229-01

Note: There is a restriction when using this loopback mode. At least one clock cycle is required between

a TEOP assertion and a TSOP assertion. This is required when the pre-pend feature of the receive

FIFO is enabled to allow the addition of the extra two bytes to the data sent on the transmit

interface. Where the pre-pend feature has not been enabled, data can be sent back-to-back on the

transmit SPI3 interface with TSOP following TEOP on the next cycle.

To configure the IXF1104 to use the SPI3 loopback mode, the “RX FIFO SPI3 Loopback Enable

for Ports 0 - 3 ($0x5B2)" must be configured. Each IXF1104 port has a unique bit in this register

designated to control loopback. It is possible to have individual ports in a loopback mode while

other ports continue to operate in a normal mode.

5.11.2

Line Side Interface Loopback

To provide a diagnostic loopback feature on the line-side interfaces, the IXF1104 can be configured

to loop back any data received by the IXF1104 through one of the line interfaces back to the

corresponding transmit line interface. This is done by using the data path shown in Figure 34. The

line-side interface can be either SerDes, RGMII or GMII. Please note that it is not possible to loop

one line-side interface back to a different one (for example, Rx SerDes looped back to transmit

RGMII).

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Figure 34. Line Side Interface Loopback Path

Line Side Internal Loopback

TX FIFO

SPI3 Interface

Line Side

Interface

MAC

Block

RX FIFO

B3230-01

When the IXF1104 is configured in this loopback mode, all of the MAC functions and features are

available, including flow control and pause-packet generation.

To configure the IXF1104 to use the line-side loopback mode, the “Loop RX Data to TX FIFO

(Line-Side Loopback) Ports 0 - 3 ($0x61F)" must be configured. Each IXF1104 port has a unique

bit in this register designated to control the loopback. It is possible to have individual ports in a

loopback mode while other ports continue to operate in a normal mode.

Note: Line side interface loopback packets also appear at the SPI3 interface.

5.12

Clocks

The IXF1104 system interface has several reference clocks, including the following:

• SPI3 data path input clocks

• RGMII input and output clocks

• MDIO output clock

• JTAG input clock

• I²C clock

• LED output clock.

This section details the unique clock source requirements.

5.12.1

System Interface Reference Clocks

The following system interface clock is required by the IXF1104:

• CLK125

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5.12.1.1

CLK125

The system interface clock, which supplies the clock to the majority of the internal circuitry, is the

125 MHz clock. The source of this clock must meet the following specifications:

• 2.5 V CMOS drive

• +/- 50 ppm

• Maximum duty cycle distortion 40/60

5.12.2

SPI3 Receive and Transmit Clocks

The IXF1104 transmit clock requirements include the following:

• 3.3 V LVTTL drive

• +/- 50 ppm

• Maximum frequency of 133 MHz in MPHY mode

• Maximum frequency of 125 MHz in SPHY mode

• Maximum duty cycle distortion 45/55

The IXF1104 meets the following specifications for the receive clock:

• 3.3 V LVTTL drive

• +/- 50 ppm

• Maximum frequency of 133 MHz in MPHY mode

• Maximum frequency of 125 MHz in SPHY mode

• Maximum duty cycle distortion 45/55

5.12.3

RGMII Clocks

The RGMII interface is governed by the Hewlett-Packard* 1.2a specification. The IXF1104

compliant to this specification with the following:

• 2.5 V CMOS drive

• Maximum duty cycle distortion 40/60

• +/- 100 ppm

• 125 MHz for 1000 Mbps, 25 MHz for 100 Mbps and 2.5 MHz for 10 Mbps

5.12.4

MDC Clock

The IXF1104 supports the IEEE 802.3 MII Management Interface, also known as the Management

Data Input/Output (MDIO) Interface. The IXF1104 meets the following specifications for this

clock:

• 2.5 V CMOS drive

• 2.5/18 MHz operation (selectable by the MDC speed bit in the “MDIO Control ($0x683)")

• 50/50 duty cycle for 2.5 MHz operation

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• 43/57 duty cycle for 18 MHz operation

5.12.5

JTAG Clock

The IXF1104 supports JTAG. The source of this clock must meet the following specifications:

• 3.3 V CMOS drive

• Maximum clock frequency 11 MHz

• Maximum duty cycle distortion 40/60

5.12.6

5.12.7

I²C Clock

The IXF1104 supports a single-output I²C clock to support all ten Optical Module interfaces. The

IXF1104 meets the following specifications for this clock:

• 2.5 V CMOS drive

• Maximum clock frequency of 100 KHz

LED Clock

The IXF1104 supports a serial LED data stream and meets the following specifications for this

clock:

• 2.5 V CMOS drive

• Maximum frequency of 720 Hz

• Maximum duty cycle distortion 50/50

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6.0

Applications

6.1

Change Port Mode Initialization Sequence

Use the change port mode initialization sequence after power-up and anytime a port is configured

into or switching between fiber or copper mode, switching to/from RGMII and GMII modes, or

switching speeds and duplex in RGMII mode.

The following sequence applies to all four ports and can be done simultaneously for all ports or as

a subset of the ports.

1. Place the MAC in reset for the port(s) which require a change by asserting (set to 1) the “MAC

Soft Reset ($0x505)”.

2. Place the TX FIFO in reset for the port(s) which require a change by asserting (set to 1) the

“TX FIFO Port Reset ($0x620)”.

3. Disable the port(s) which require change by de-asserting (set to 0) the appropriate bits in the

“Port Enable ($0x500)”.

4. Wait 1 µs.

5. De-assert (set to 0) “Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)” for the

ports being changed.

6. Set the speed, mode, and duplex as follows for the ports being changed:

a. Copper mode:

Select copper mode for the “Interface Mode ($0x501)” ports.

Set the per-port “MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)” to the

appropriate speed and RGMII/GMII interface setting.

Set the per-port “Desired Duplex ($ Port_Index + 0x02)”.

Note: Half-duplex is supported only when RGMII 10 Mbps or 100 Mbps is selected in the

“MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)”.

b. Fiber mode:

Select fiber mode by setting the appropriate bit to 0 in the “Interface Mode ($0x501)”

ports.

7. Assert (set to 1) “Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)” for the ports

being changed.

8. Wait 1 µs.

9. De-assert (set to 0) “MAC Soft Reset ($0x505)” for the ports being changed.

10. De-assert (set to 0) “TX FIFO Port Reset ($0x620)” for the ports being changed.

11. Wait 1 to 2 µs.

12. Set the “Diverse Config Write ($ Port_Index + 0x18)” to the appropriate value as follows:

a. Copper mode:

Write the reserved bits to the default value.

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Enable packet padding and CRC appending on transmitted packets in bits 6 and 7, as

needed.

Set bit 5 to 0x0.

b. Fiber Mode:

Write the reserved bits to the default value.

Enable Packet padding and CRC Appending on transmitted packets in bits 6 and 7, as

needed.

Set bit 5 to 1 to enable auto-negotiation.

Set bit 5 to 0 to enable forced mode operation.

13. Assert (set to 1) “Port Enable ($0x500)”.

14. Wait 1 to 2 µs.

15. Perform additional device configurations, as needed.

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7.0

Electrical Specifications

T a ble 39 through Table 58 “LED Interface AC Timing Parameters” on page 153 and Figure 35

“SPI3 Receive Interface Timing” on page 136 through Figure 52 “LED AC Interface Timing” on

page 153 represent the target specifications of the following IXF1104 interfaces:

— SPI3

— JTAG

— MDIO

— Pause Control

— CPU

— LED

— System

— GMII and RGMII

— SerDes

— Optical Module

These specifications are not guaranteed and are subject to change without notice. Minimum and

maximum values listed in T a ble 41 “Intel® IXF1104 MAC DC Specifications” on page 133

through T a ble 58 “LED Interface AC Timing Parameters” on page 153 apply over the

recommended operating conditions specified in Table 40.

Table 39. Absolute Maximum Ratings

Parameter

Symbol

Min

Max

Units

Comments

VDD

-0.3

-40

2.2

4.25

2.2

volts

°C

Core digital power

I/O digital power

Analog power

Copper mode

Fiber mode

VDD2, VDD3

VDD4, VDD5

AVDD1P8_1/2

AVDD2P5_1/2

TOPA

Supply voltage

4.25

+85

+70

+150

Ambient

Operating

temperature

TOPA

0.0

°C

Storage temperature

TST

-40

°C

–

Caution: Exceeding these values may cause permanent damage to the device. Functional

operation under these conditions is not implied. Exposure to maximum rating

conditions for extended periods may affect device reliability.

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Table 40. Recommended Operating Conditions

Parameter

Symbol

VDD

Min

Typ

Max

Units

1.65

3.0

–

1.95

3.6

Volts

VDD2, VDD3

VDD4, VDD5

2.3

2.7

Recommended supply voltage

AVDD1P8_1

AVDD1P8_2

1.65

2.3

–

1.95

2.7

Volts

AVDD2P5_1

AVDD2P5_2

VDD

AVDD1P8_1

AVDD1P8_2

–

0.780

0.050

–

Amps

SerDes Operation

VDD4

VDD5

AVDD2P5_1

AVDD2P5_2

Transmitting and

receiving in

1000 Mbps mode

Operating Current

VDD2, VDD3

–

0.246

0.757

–

Amps

VDD

AVDD1P8_1

AVDD1P8_2

RGMII Operation

VDD4

VDD5

Transmitting and

receiving in

Operating Current

–

0.224

–

Amps

AVDD2P5_1

AVDD2P5_2

1000 Mbps mode

VDD2, VDD3

TOPA

–

0.208

–

0.235

Amps

°C

Ambient

Recommended

operating

temperature

Case with heat

sink

TOPC-HS

–

122

121

°C

Case without heat

sink

TOPC-NHS

SerDes Operation

Transmitting and

receiving in

1000 Mbps mode

–

2.23

2.84

2.72

3.4

Watts

Power

consumption

RGMII Operation

Transmitting and

receiving in

1000 Mbps mode

7.1

DC Specifications

The IXF1104 supports the following I/O buffer types:

• 2.5 V CMOS

• 3.3 V LVTTL

• SerDes

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See Section 5.1.7, “Packet Buffer Dimensions” on page 79 for additional information regarding I/O

buffer types. The related driver characteristics are described in this section.

Caution: IXF1104 input signals are not 5 V tolerant. Devices driving the IXF1104 must provide 3.3 V signal

levels or use level-shifting buffers to provide 3.3 V compatible levels. Otherwise, damage to the

IXF1104 will occur.

Table 41. Intel® IXF1104 MAC DC Specifications

Parameter

Symbol

Min

Typ

Max

Units

Comments

2.5 V CMOS I/O Cells

Input High voltage

Input low voltage

Output High voltage

Output low voltage

VIH

VIL

1.7

–

0.7

–

2.5 V I/Os

VOH

VOL

2.0

–

0.4

3.3 V I/O Cells

Input High voltage

Input low voltage

Output High voltage

Output low voltage

VIH

VIL

1.7

–

0.7

–

3.3 V LVTTL I/Os

VOH

VOL

2.4

–

0.4

Table 42. SerDes Transmit Characteristics (Sheet 1 of 2)

Normalized

Power

Parameter

Symbol

Min

Typ Max

Units

Comments

Drive

Settings¹

0.50

1.00

1.33

2.00

0.50

1.00

1.33

2.00

180

350

425

600

230

440

580

325

700

900

Transmit differential

signal level

AVDD1P8_2 terminated

to 1.8V; Rload = 50 Ω

TxDfPP

mVpp diff

770 1050

1300 1600 1940

1000 1400 1870

AVDD1P8_2 terminated

to 1.8V; RLoad = 50

ohms; FIR coeffs = 0

Transmit common

mode voltage range

TxCMV

800

700

1300 1825

1100 1760

Differential signal rise/ Diff rise/

Rload = 50 Ω; 20% to

1.00

–

132

150

fall time

fall

80% max

Differential output

impedance

Nominal value = 100 Ω

differential

TxDiffZ

105

Ω diff

Receiver differential

voltage requirement at

center of receive eye

mVp-p

diff

RxDiffV

–

200

–

1. Refer to Section 5.6.2.2, “Transmitter Programmable Driver-Power Levels” on page 103.

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Table 42. SerDes Transmit Characteristics (Sheet 2 of 2)

Normalized

Power

Parameter

Symbol

Min

Typ

Max

Units

Comments

Drive

Settings¹

Receiver common

mode voltage range

RxCMV

–

900

1275 1650

–

Receiver termination

impedance

RxZ

–

62.5

Ω

–

Signal detect level

RxSigDet

125

200 mVp-pdiff

1. Refer to Section 5.6.2.2, “Transmitter Programmable Driver-Power Levels” on page 103.

Table 43. Intel® IXF1104 MAC SerDes Receive Characteristics

Normalized

Power

Parameter

Symbol

Min

Typ

Max

Units

Comments

Drive

Settings

Receiver differential

voltage requirement at

center of receive eye

RxDiffV

RxCMV

–

200

900

–

mVp-p diff

–

Receiver common

mode voltage range

1275 1650

Receiver termination

impedance

RxZ

–

62.5

Ω

–

Signal detect level

RxSigDet

125

200 mVp-pdiff

7.1.1

Undershoot / Overshoot Specifications

The overshoot figures given in this section represent the maximum voltage that can be applied

without affecting the reliability of the device (see T a ble 44).

Caution: If these limits are exceeded, damage to the device will occur.

Table 44. Undershoot / Overshoot Limits

Pin Type

Undershoot

Overshoot

2.5 V CMOS

3.3 V LVTTL

-0.60 V

3.9 V

7.1.2

RGMII Electrical Characteristics

The RGMII signals (including MDIO/MDC) are based on 2.5V CMOS interface voltages, as

defined by JEDEC EIA/JESD8-5 (see T a ble 45).

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Table 45. RGMII Power

Symbol

Parameter

Conditions

Min

Max

Units

VOH

VOL

VIH

VIL

IIH

Output High Voltage

Output Low Voltage

Input High Voltage

Input Low Voltage

Input High Current

Input Low Current

IOH = -1.0 MA; VCC = MIN

IOL = 1.0 MA; VCC = MIN

VIH > VIH_MIN; VCC = MIN

VIL < VIL_MAX; VCC = MIN

VCC = MAX; VIN = 2.5V

VCC = MAX; VIN = 0.4V

2.0

VDD +.3

GND -.3

0.40

–

.70

–

µA

IIL

-15

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7.2

SPI3 AC Timing Specifications

7.2.1

Receive Interface Timing

Figure 35 and Table 46 illustrate and provide SPI3 receive interface timing information.

Figure 35. SPI3 Receive Interface Timing

RFCLK

THrenb

RENB

TSrenb

RDAT[31:0]

RPRY

TPrdat

TPrprty

TPrmod

TPrsop

TPreop

TPrerr

TPrval

TPrsx

RMOD

RSOP

REOP

RERR

RVAL

RSX

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Table 46. SPI3 Receive Interface Signal Parameters

Symbol

Parameter

Min

Max

Units

–

RFCLK frequency

RFCLK duty cycle

–

133

MHz

–

Tsrenb

Threnb

TPrdat

TPrprty

TPrsop

TPreop

TPrmod

TPrerr

TPrval

TPrsx

RENB setup time to RFCLK

RENB hold time to RFCLK

RFCLK High to RDAT valid

RFCLK High to RPRTY valid

RFCLK High to RSOP valid

RFCLK High to REOP valid

RFCLK High to RMOD valid

RFCLK High to RERR valid

RFCLK High to RVAL valid

RFCLK High to RSX valid

1.8

0.5

1.5

–

3.7

NOTES: Receive I/O Timing

1. When a setup time is specified between an input and a clock, the setup time is the time in nanoseconds

from the 1.4-volt point of the input to the 1.4-volt point of the clock.

2. When a hold time is specified between an input and a clock, the hold time is the time in nanoseconds from

the 1.4-volt point of the clock to the 1.4-volt point of the input.

3. Output propagation time is the time in nanoseconds from the 1.4-volt point of the reference signal to the

1.4-volt point of the output.

4. Maximum propagation delays are measured with a 30 pF load when operating OIF-SPI3 standard 104

MHz. Over-clocked rates of 125 MHz or higher are measured using a load of 20 pF.

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7.2.2

Transmit Interface Timing

Figure 36 and Table 47 illustrate and provide SPI3 transmit interface timing information.

Figure 36. SPI3 Transmit Interface Timing

TFCLK

TENB

TStenb

THtenb

TDAT[31:0]

TPRTY

TStdat

THtdat

THtprty

THtmod

THtsop

TStrpty

TStmod

TStsop

TMOD[1:0]

TSOP

TEOP

TSteop

TSterr

TStadr

TStsx

THteop

THterr

THtadr

THtsx

TERR

TADR

TSX

DTPA

TPdtpa

STPA

PTPA

TPstpa

TPptpa

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Table 47. SPI3 Transmit Interface Signal Parameters

Symbol

Parameter

Min

Max

Units

–

TFCLK frequency

TFCLK duty cycle

–

133

–

MHz

–

TStenb

THtenb

TStdat

THtdat

TStprty

THtprty

TStsop

THtsop

TSteop

THteop

TStmod

THtmod

TSterr

THterr

TStsx

TENB setup time to TFCLK

TENB hold time to TFCLK

TDAT[31:0] setup time to TFCLK

TDAT[31:0} hold time to TFCLK

TRPTY setup time to TFCLK

TPRTY hold time to TFCLK

TSOP setup time to TFCLK

TSOP hold time to TFCLK

TEOP setup time to TFCLK

TEOP hold time to TFCLK

TMOD setup time to TFCLK

TMOD hold time to TFCLK

TERR setup time to TFCLK

TERR hold time to TFCLK

TSX setup time to TFCLK

TSX hold time to TFCLK

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.8

0.5

1.5

–

THtsx

–

TStadr

THtadr

TPdtpa

TPstpa

TPptpa

TADR setup time to TFCLK

TADR hold time to TFCLK

TFCLK High to DTPA valid

TFCLK High to STPA valid

TFCLK High to PTPA valid

–

3.7

NOTES:Transmit I/O Timing:

1. When a setup time is specified between an input and a clock, the setup time is the time in nanoseconds

from the 1.4 V point of the input to the 1.4-volt point of the clock.

2. When a hold time is specified between an input and clock, the hold time is the time in nanoseconds from

the 1.4 V point of the clock to the 1.4-volt point of the input.

3. Output propagation delay time is the time in nanoseconds from the 1.4 V point of the reference signal to the

1.4 V point of the output.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.3

RGMII AC Timing Specification

Figure 37 and Table 48 provide RGMII interface timing parameters.

Figure 37. RGMII Interface Timing

TXC

(at Transmitter)

TSkewT

TD[3:0]

TXEN

TD[7:4]

TXERR

TD[3:0]

TSkewR

TX_CTL[n]

TXC

(at Receiver)

RXC

(at Transmitter)

TSkewT

RD[3:0]

RXDV

RD[7:4]

RXERR

RD[3:0]

TSkewR

RX_CTL

RXC

(at Receiver)

B3251-01

Table 48. RGMII Interface Timing Parameters

Symbol

Parameter

Min

Typ

Max

Unit

TskewT

TskewR

Tcyc

Data-to-Clock Output Skew (at Transmitter)

Data-to-Clock Input Skew (at Receiver)¹

Clock Cycle Duration²

-500

–

500

2.8

8.8

7.2

–

Duty_T

Duty_G

Tr/Tf

Duty Cycle for Gigabit²

–

Duty Cycle for 10/100T³

Rise/Fall Time (20–80%)

.75

1. This implies that PC board design requires clocks to be routed so that an additional trace delay of greater

than 1.5 ns is added to the associated clock signal.

2. For 10 Mbps and 100 Mbps Tcyc scales to 400 ns +/– 40 ns and 40 ns +/– 4 ns respectively.

3. Duty cycle may be stretched/shrunk during speed changes or while transitioning to a received packet’s

clock domain, as long as minimum duty cycle is not violated and stretching occurs for no more than three

Tcyc of the lowest speed transitioned between.

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7.4

GMII AC Timing Specification

7.4.1

1000 Base-T Operation

Figure 38 and Figure 39 and Table 49 and Table 50 provide GMII AC timing specifications.

7.4.1.1

1000 BASE-T Transmit Interface

Figure 38. 1000BASE-T Transmit Interface Timing

GTX_CLK

TXEn

TXD[7:0]

TXER

CPS

B0634-01

Table 49. GMII 1000BASE-T Transmit Signal Parameters

Symbol

Parameter

Min

Typ¹

Max

Unit²

TXD[7:0], TXEN, TXER Set-up to TXC High

TXD[7:0], TXEN, TXER Hold from TXC High

TXEN sampled to CRS asserted

2.5

0.5

–

TXEN sampled to CRS de-asserted

–

1. Typical values are at 25^oC and are for design aid only; not guaranteed and not subject to production

testing.

2. Bit Time (BT) is the duration of one bit as transferred to/from the PHY and is the reciprocal of bit rate. BT for

1000BASE-T = 10^-9or 1 ns.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.4.1.2

1000BASE-T Receive Interface

Figure 39. 1000BASE-T Receive Interface Timing

RX_CLK

RxDV

RXD[7:0]

CRS

Table 50. GMII 1000BASE-T Receive Signal Parameters

Symbol

Parameter

Min

Typ¹

Max

Unit²

RXD[7:0], RX_DV, RXER Setup to Rx_CLK High

RXD[7:0], RX_DV, RXER Hold after Rx_CLK High

2.0

0.0

–

1. Typical values are at 25^oC and are for design aid only; not guaranteed and not subject to production

testing.

2. Bit Time (BT) is the duration of one bit as transferred to/from the PHY and is the reciprocal of bit rate. BT for

1000BASE-T = 10^-9or 1 ns.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.5

SerDes AC Timing Specification

Figure 40. SerDes Timing Diagram

Table 51. SerDes Timing Parameters

Symbol

Parameter

Min

Max

Units

Transmit eye width

Receiver eye width

Transmit amplitude

Receiver amplitude

800

280

–

1000

200

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.6

MDIO AC Timing Specification

The MDIO Interface on the IXF1104 can operate in two modes – low-speed and high-speed. In

low-speed mode, the MDC clock signal operates at a frequency of 2.5 MHz. In high-speed mode,

the MDC clock signal operates at a frequency of 18 MHz. (See Figure 41 through Figure 44 and

T a ble 52.)

7.6.1

MDC High-Speed Operation Timing

Figure 41. MDC High-Speed Operation Timing

24 ns

32 ns

(4 X 125 MHz clocks)

(3 X 125 MHz clocks)

MDC

56 ns (17.85 MHz)

7.6.2

MDC Low-Speed Operation Timing

Figure 42. MDC Low-Speed Operation Timing

200 ns

(25 X 125 MHz clocks) (25 X 125 MHz clocks)

MDC

400 ns (2.5 MHz)

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.6.3

MDIO AC Timing

Figure 43. MDIO Write Timing Diagram

V_MAX

MDC

V_MIN

MDIO

Figure 44. MDIO Read Timing Diagram

V_MAX

MDC

MDIO

Table 52. MDIO Timing Parameters

Parameter

Symbol

Min

Typ¹

Max

Units

Test Conditions

–

MDC = 17.8 MHz

MDC = 2.5 MHz

MDC = 17.8 MHz

MDC = 2.5 MHz

MDC = 17.8 MHz

MDC = 2.5 MHz

MDIO Setup before MDC.

–

MDIO Hold after MDC.

–

200

MDC to MDIO Output delay

1. Typical values are at 25 ^oC and are for design aid only; not guaranteed and not subject to production

testing.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.7

Optical Module and I²C AC Timing Specification

7.7.1

I²C Interface Timing

Figure 45 and Figure 46 illustrate bus timing and write cycle, and Table 53 shows the I²C Interface

AC timing characteristics.

Figure 45. Bus Timing Diagram

HIGH

LOW

I²C_Clk

SU.STO

HD.DAT

SU.DAT

HD.STA

SV.SAT

I²C_Data In

BUF

I²C_Data Out

Figure 46. Write Cycle Diagram

I²C_Clk

8th

BIT

I²C_Data

ACK

WORD n

(1)

STOP

CONDITION

START

CONDITION

Table 53. I²C AC Timing Characteristics (Sheet 1 of 2)

Symbol

Parameter

Min

Max

Units

Clock frequency, SCL

Clock pulse width low

Clock pulse width High

Noise suppression

100

kHz

µs

SCL

4.7

4.0

LOW

HIGH

100

Clock low to data valid out

0.1

4.5

Time the bus must be free before a new transmission starts

Start hold time

4.7

4.0

BUF

HD.STA

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Table 53. I²C AC Timing Characteristics (Sheet 2 of 2)

Symbol

t_SU.STA

Parameter

Min

Max

Units

Start setup time

Data in hold time

Data in setup time

Inputs rise time

Inputs fall time

4.7

–

µs

t_HD.DAT

t_SU.DAT

t_R

200

–

1.0

300

–

t_F

–

t_SU.STO

t_DH

Stop setup time

Data out hold time

Write cycle time

4.7

100

–

t_WR

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.8

CPU AC Timing Specification

7.8.1

CPU Interface Read Cycle AC Timing

Figure 47, Figure 48, and Table 54 illustrate the CPU interface read and write cycle AC timing.

Figure 47. CPU Interface Read Cycle AC Timing

TCAS

TCAH

uPx_ADD[12:0]

TCRR

uPx_CsN

uPx_RdN

TCRH

uPx_Data[31:0]

uPx_RdyN

TCDRS

TCDRH

TCDRD

7.8.2

CPU Interface Write Cycle AC Timing

Figure 48. CPU Interface Write Cycle AC Timing

TCAS

TCAH

uPx_Add[12:0]

uPx_CsN

uPx_WrN

TCWL

TCWH

TCDWH

uPx_Data[31:0]

uPx_RdyN

TCDWS

TCYD

TCDWD

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Table 54. CPU Interface Write Cycle AC Signal Parameters

Symbol

Parameter

Min

Max

Tcas

Tcah

Tcrr

Address, chip select setup time

Address, chip select hold time

Ready assertion to read de-assertion

Read High width

5 ns

10 ns

24 ns

10 ns

8 ns

–

Tcrh

–

Tcdrs

Tcdrh

Tcdrd

Tcwl

Read data setup time to ready assertion

Read data hold time after read de-assertion

Read data driving delay

–

32 ns

355 ns

–

24 ns

40 ns

16 ns

10 ns

5 ns

Write assertion width

Tcwh

Tcdws

Tcdwh

Tcdwd

Tcyd

Ready assertion to write assertion

Write data setup to write de-assertion

Write data hold time after ready assertion

Write data sampling delay

–

8 ns

32 ns

40 ns

Ready width in write cycle

24 ns

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.9

Transmit Pause Control AC Timing Specification

Figure 49 and Table 55 show the pause control AC timing specifications. The Pause Control

interface operates as an asynchronous interface relative to the main system clock (CLK125). There

is, however, a relationship between the TXPAUSEADD bus and the strobe signal (TXPAUSEFR).

Figure 49. Pause Control Interface Timing

TXPAUSEADD[2:0]

TxPauseAdd[1:0]

TxPauseFr

Tpw(min) = 16 ns

Thold(min) = 16 ns

Tsu(min) = 16 ns

000

001

010

011

100

: XON packet on all ports

: XOFF Port0

: XOFF Port1

: XOFF Port2

: XOFF Port3

110-101 : Reserved

111 : XOFF on all ports

Table 55. Transmit Pause Control Interface Timing Parameters

Symbol

Parameter

Min

Max

Units

Tsu

Tpw

TXPAUSEADD stable prior to TXPAUSEFR High

TXPAUSEFR pulse width

–

Thold

TXPAUSEADD stable after TXPAUSEFR High

150

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.10

JTAG AC Timing Specification

Figure 50 and T a ble 56 provide the JTAG AC timing specifications.

Figure 50. JTAG AC Timing

Table 56. JTAG AC Timing Parameters

Symbol

Parameter

Min

Max

Units

Tjc

Tjh

TCLK cycle time

TCLK High time

TCLK low time

0.4 x Tjc 0.6 x Tjc

Tjl

Tjval

Tjsu

Tjsh

TCLK falling edge to TDO valid

TMS/TDI setup to TCLK

TMS/TDI hold from TCLK

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.11

System AC Timing Specification

Figure 51 and Table 57 illustrate the system reset AC timing specifications.

Figure 51. System Reset AC Timing

Table 57. System Reset AC Timing Parameters

Symbol

Parameter

Min

Max

Units

Trw

Trt

Reset pulse width

1.0

µs

Reset recovery time

200

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

7.12

LED AC Timing Specification

Figure 52 and T a ble 58 provide the LED AC timing specifications.

Figure 52. LED AC Interface Timing

Tcyc

Tlow

LED_CLK

LED_DATA

LED_LATCH

Thi

Tdatd

Thatl

Tlath

Table 58. LED Interface AC Timing Parameters

Symbol

Parameter

Min

Max

Units

Tcyc

Thi

LED_CLK cycle time

LED_CLK High time

LED_CLK low time

1.36

680

1.40

700

µs

Tlow

Tdatd

Tlath

Tlatl

LED_CLK falling edge to LED_DATA valid

LED_CLK rising edge to LED_LATCH rising edge

LED_CLK falling edge to LED_LATCH falling edge

690

700

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.0

8.1

8.2

The registers shown in this section provide access for configuration, alarm monitoring, and control

of the chip. T a ble 59 “MAC Control Registers ($ Port Index + Offset)” on page 155 through

T a ble 69 “Optical Module Registers ($ 0x799 - 0x79F)” on page 161 provide register map details.

The registers are listed by ascending address in the table.

Document Structure

The following sections are structured to provide a general overview of the register map. Later

sections provide detailed descriptions of each register segment or bit.

All registers are accessed and addressed as 32-bit doublewords. When accessed using 8- or 16-bit

accesses, the CPU interface packs or unpacks the partial accesses into a 32-bit register value.

Graphical Representation

Figure 53 represents an overview of the IXF1104 global control status registers that are used to

configure or report on all ports. All register locations shown in Figure 53 represent a 32-bit double

word.

Figure 53. Memory Overview Diagram

0x7FF

Global Configuration

- RX Block Configuration

- TX Block Configuration

0x500

0x480

0x400

0x380

Reserved

0x300

0x280

0x200

0x180

Port 3 MAC Control & Statistics

Port 2 MAC Control & Statistics

Port 1 MAC Control & Statistics

Port 0 MAC Control & Statistics

0x100

0x080

0x000

B0744-01

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8.3

Per Port Registers

Section 8.4 covers all of the registers that are replicated in each port of the IXF1104. These

registers perform an identical function in each port.

The address vector for the IXF1104 is 11 bits wide. This allows for 7 bits of port-specific access

and a 4-bit vector to address each port and all global registers. The address format is shown in

Figure 54.

Figure 54. Register Overview Diagram

Port Select & Global Registers

Per-Port Registers

8.4

T a ble 59 through Table 69 “Optical Module Registers ($ 0x799 - 0x79F)” on page 161 present the

IXF1104 memory map details. Global control and status registers are used to configure or report on

all ports, and some registers are replicated on a per-port basis.

Note: All IXF1104 registers are 32 bits.

Table 59. MAC Control Registers ($ Port Index + Offset) (Sheet 1 of 2)

Bit Size

Mode¹

Ref Page

Offset

“Station Address ($ Port_Index +0x00 – +0x01)” Low

“Station Address ($ Port_Index +0x00 – +0x01)” High

“Desired Duplex ($ Port_Index + 0x02)”

“FD FC Type ($ Port_Index + 0x03)”

R/W

162

–

0x00

0x01

0x02

0x03

0x04

0x05

0x06

0x07

Reserved

“Collision Distance ($ Port_Index + 0x05)”

“Collision Threshold ($ Port_Index + 0x06)”

“FC TX Timer Value ($ Port_Index + 0x07)”

R/W

163

“FD FC Address ($ Port_Index + 0x08 – + 0x09)”

FDFCAddressLow

R/W

163

0x08

0x09

“FD FC Address ($ Port_Index + 0x08 – + 0x09)”

FDFCAddressHigh

“IPG Receive Time 1 ($ Port_Index + 0x0A)”

“IPG Receive Time 2 ($ Port_Index + 0x0B)”

“IPG Transmit Time ($ Port_Index + 0x0C)”

Reserved

–

R/W

164

–

0x0A

0x0B

0x0C

0x0D

0x0E

“Pause Threshold ($ Port_Index + 0x0E)”

R/W

165

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Table 59. MAC Control Registers ($ Port Index + Offset) (Sheet 2 of 2)

Bit Size

Mode¹

Ref Page

Offset

“Max Frame Size (Addr: Port_Index + 0x0F)”

“MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)”

“Flush TX ($ Port_Index + 0x11)”

R/W

0x0F

0x10

0x11

0x12

0x13

0x14

“FC Enable ($ Port_Index + 0x12)”

“FC Back Pressure Length ($ Port_Index + 0x13)”

“Short Runts Threshold ($ Port_Index + 0x14)”

“Discard Unknown Control Frame ($ Port_Index +

0x15)”

R/W

168

0x15

“RX Config Word ($ Port_Index + 0x16)”

“TX Config Word ($ Port_Index + 0x17)”

“Diverse Config Write ($ Port_Index + 0x18)”

“RX Packet Filter Control ($ Port_Index + 0x19)”

R/W

0x16

0x17

0x18

0x19

“Port Multicast Address ($ Port_Index +0x1A – +0x1B)”

PortMulticastAddressLow

R/W

172

0x1A

0x1B

“Port Multicast Address ($ Port_Index +0x1A – +0x1B)”

PortMulticastAddressHigh

Table 60. MAC RX Statistics Registers ($ Port Index + Offset) (Sheet 1 of 2)

Bit Size

Mode¹

Ref Page

Offset

RxOctetsTotalOK

RxOctetsBAD

173

0x20

0x21

0x22

0x23

0x24

0x25

0x26

0x27

0x28

0x29

0x2A

0x2B

0x2C

0x2D

0x2E

0x2F

0x30

0x31

0x32

RxUCPckts

RxMCPkts

RxBCPkts

RxPkts64Octets

RxPkts65to127Octets

RxPkts128to255Octets

RxPkts256to511Octets

RxPkts512to1023Octets

RxPkts1024to1518Octets

RxPkts1519toMaxOctets

RxFCSErrors

RxTagged

RxDataError

RxAlign Errors

RxLongErrors

RxJabberErrors

PauseMacControlReceivedCounter

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Table 60. MAC RX Statistics Registers ($ Port Index + Offset) (Sheet 2 of 2)

Bit Size

Mode¹

Ref Page

Offset

RxUnknownMacControlFrameCounter

RxVeryLongErrors

RxRuntErrors

173

0x33

0x34

0x35

0x36

0x37

0x38

0x39

RxShortErrors

RxCarrierExtendError

RxSequenceErrors

RxSymbolErrors

Table 61. MAC TX Statistics Registers ($ Port Index + Offset)

Bit Size

Mode¹

Ref Page

Offset

OctetsTransmittedOK

OctetsTransmittedBad

TxUCPkts

177

0x40

0x41

0x42

0x43

0x44

0x45

0x46

0x47

0x48

0x49

0x4A

0x4B

0x4C

0x4D

0x4E

0x4F

0x50

0x51

0x52

0x53

0x54

0x55

0x56

0x57

0x58

TxMCPkts

TxBCPkts

TxPkts64Octets

TxPkts65to127Octets

TxPkts128to255Octets

TxPkts256to511Octets

TxPkts512to1023Octets

TxPkts1024to1518Octets

TxPkts1519toMaxOctets

TxDeferred

TxTotalCollisions

TxSingleCollisions

TxMultipleCollisions

TxLateCollisions

TxExcessiveCollisionErrors

TxExcessiveDeferralErrors

TxExcessiveLengthDrop

TxUnderrun

TxTagged

TxCRCError

TxPauseFrames

TxFlowControlCollisionsSend

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Table 62. PHY Autoscan Registers ($ Port Index + Offset)

Bit Size

Mode¹

Ref Page

Offset

“PHY Control ($ Port Index + 0x60)”

0x60

0x61

0x62

0x63

0x64

“PHY Status ($ Port Index + 0x61)”

“PHY Identification 1 ($ Port Index + 0x62)”

“PHY Identification 2 ($ Port Index + 0x63)”

“Auto-Negotiation Advertisement ($ Port Index + 0x64)”

“Auto-Negotiation Link Partner Base Page Ability ($ Port

–

0x65

0x66

“Auto-Negotiation Expansion ($ Port Index + 0x66)”

“Auto-Negotiation Next Page Transmit ($ Port Index +

0x67)”

0x67

Reserved

0x68 - 0x6F

Table 63. Global Status and Configuration Registers ($ 0x500 - 0X50C)

Bit Size

Mode¹

Ref Page

Address

“Port Enable ($0x500)”

“Interface Mode ($0x501)”

“Link LED Enable ($0x502)”

Reserved

R/W

187

188

–

0x500

0x501

0x502

0x503 - 0x504

0x505

“MAC Soft Reset ($0x505)”

“MDIO Soft Reset ($0x506)”

Reserved

R/W

188

189

–

0x506

0x507

“CPU Interface ($0x508)”

“LED Control ($0x509)”

“LED Flash Rate ($0x50A)”

“LED Fault Disable ($0x50B)”

R/W

0x508

0x509

0x50A

0x50B

0x50C

Table 64. RX FIFO Registers ($ 0x580 - 0x5BF) (Sheet 1 of 2)

Bit Size

Mode¹

Ref Page

Address

“RX FIFO High Watermark Port 0 ($0x580)”

“RX FIFO High Watermark Port 1 ($0x581)”

“RX FIFO High Watermark Port 2 ($0x582)”

“RX FIFO High Watermark Port 3 ($0x583)”

Reserved

R/W

192

193

–

0x580

0x581

0x582

0x583

0x584 - 0x589

0x58A

“RX FIFO Low Watermark Port 0 ($0x58A)”

“RX FIFO Low Watermark Port 1 ($0x58B)”

“RX FIFO Low Watermark Port 2 ($0x58C)”

R/W

193

“RX FIFO Low Watermark Port 3 ($0x58D)”

0x58B

0x58C

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Table 64. RX FIFO Registers ($ 0x580 - 0x5BF) (Sheet 2 of 2)

Bit Size

Mode¹

Ref Page

Address

Reserved

R/W

–

0x58D

0x58E - 0x593

0x594

RX FIFO Overflow Frame Drop Counter Port 0

RX FIFO Overflow Frame Drop Counter Port 1

RX FIFO Overflow Frame Drop Counter Port 2

RX FIFO Overflow Frame Drop Counter Port 3

Reserved

“RX FIFO Port Reset ($0x59E)”

–

0x595

0x596

0x597

R/W

0x598 - 0x59D

0x59E

195

196

–

“RX FIFO Errored Frame Drop Enable ($0x59F)”

“RX FIFO Overflow Event ($0x5A0)”

Reserved

0x59F

0x5A0

0x5A1 - 0x5A5

0x5A2

RX FIFO Errored Frame Drop Counter Port 0

RX FIFO Errored Frame Drop Counter Port 1

RX FIFO Errored Frame Drop Counter Port 2

RX FIFO Errored Frame Drop Counter Port 3

Reserved

197

–

0x5A3

0x5A4

0x5A5

0x5A6 - 0x5B1

“RX FIFO SPI3 Loopback Enable for Ports 0 - 3

($0x5B2)”

R/W

198

0x5B2

“RX FIFO Padding and CRC Strip Enable ($0x5B3)”

Reserved

R/W

199

–

0x5B3

0x5B4 - 0x5B7

0x5B8

“RX FIFO Transfer Threshold Port 0 ($0x5B8)”

“RX FIFO Transfer Threshold Port 1 ($0x5B9)”

“RX FIFO Transfer Threshold Port 2 ($0x5BA)”

“RX FIFO Transfer Threshold Port 3 ($0x5BB)”

Reserved

R/W

200

201

–

0x5B9

0x5BA

0x5BB

0x5BC - 0x5BF

Table 65. TX FIFO Registers ($ 0x600 - 0x63E) (Sheet 1 of 2)

Bit Size

Mode¹

Ref Page

Address

TX FIFO High Watermark Port 0

TX FIFO High Watermark Port 1

TX FIFO High Watermark Port 2

TX FIFO High Watermark Port 3

Reserved

R/W

202

–

0x600

0x601

0x602

0x603

0x604 - 0x609

0x60A

TX FIFO Low Watermark Port 0

TX FIFO Low Watermark Port 1

TX FIFO Low Watermark Port 2

TX FIFO Low Watermark Port 3

R/W

203

0x60B

0x60C

0x60D

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 65. TX FIFO Registers ($ 0x600 - 0x63E) (Sheet 2 of 2)

Bit Size

Mode¹

Ref Page

Address

Reserved

–

R/W

–

0x60E - 0x613

0x614

TX FIFO MAC Threshold Port 0

TX FIFO MAC Threshold Port 1

TX FIFO MAC Threshold Port 2

TX FIFO MAC Threshold Port 3

Reserved

204

–

0x615

0x616

0x617

0x618 - 0x61D

0x61E

TX FIFO Overflow/Underflow Event/Out of Sequence

Loop RX Data to TX FIFO

–

R/W

0x61F

TX FIFO Port Reset

0x620

TX FIFO Overflow Frame Drop Counter Port 0

TX FIFO Overflow Frame Drop Counter Port 1

TX FIFO Overflow Frame Drop Counter Port 2

TX FIFO Overflow Frame Drop Counter Port 3

TX FIFO Errored Frame Drop Counter Port 0

TX FIFO Errored Frame Drop Counter Port 1

TX FIFO Errored Frame Drop Counter Port 2

TX FIFO Errored Frame Drop Counter Port 3

Reserved

0x621

0x622

0x623

0x624

0x625

0x626

0x627

0x628

0x629 - 0x62C

0x62D

TX FIFO Occupancy Counter for Port 0

TX FIFO Occupancy Counter for Port 1

TX FIFO Occupancy Counter for Port 2

TX FIFO Occupancy Counter for Port 3

Reserved

209

–

0x62E

0x62F

0x630

0x631 - 0x63E

Table 66. MDIO Registers ($ 0x680 - 0x683)

Bit Size

Mode¹

Ref Page

Address

“MDIO Single Command ($0x680)”

“MDIO Single Read and Write Data ($0x681)”

“Autoscan PHY Address Enable ($0x682)”

“MDIO Control ($0x683)”

R/W

210

211

0x680

0x681

0x682

0x683

Table 67. SPI3 Registers ($ 0x700 - 0x716) (Sheet 1 of 2)

Bit Size

Mode¹

Ref Page

Address

“SPI3 Transmit and Global Configuration ($0x700)”

“SPI3 Receive Configuration ($0x701)”

R/W

212

214

0x700

0x701

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 67. SPI3 Registers ($ 0x700 - 0x716) (Sheet 2 of 2)

Bit Size

Mode¹

Ref Page

Address

Reserved

–

218

–

0x702 - 0x709

0x70A

“Address Parity Error Packet Drop Counter ($0x70A)”

Reserved

0x70B - 0x716

Table 68. SerDes Registers ($ 0x780 - 0x798)

Bit Size

Mode¹

Ref Page

Address

Reserved

R/W

–

219

–

0x780 - 0x783

0x784

“TX Driver Power Level Ports 0 - 3 ($0x784)”

Reserved

0x785 - 0x786

0x787

“TX and RX Power-Down ($0x787)"

Reserved

R/W

219

–

0x788 - 0x792

0x793

“RX Signal Detect Level Ports 0 - 3 ($0x793)”

R/W

219

“Clock and Interface Mode Change Enable Ports 0 - 3

($0x794)”

R/W

220

–

0x794

Reserved

0x795 - 0x798

Table 69. Optical Module Registers ($ 0x799 - 0x79F)

Bit Size

Mode¹

Ref Page

Address

“Optical Module Status Ports 0-3 ($0x799)”

“Optical Module Control Ports 0 - 3 ($0x79A)”

“I2C Control Ports 0 - 3 ($0x79B)”

Reserved

221

222

–

0x799

0x79A

R/W

0x79B

0x79C - 0x79E

0x79F

“I2C Data Ports 0 - 3 ($0x79F)”

R/W

222

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.1

MAC Control Registers

T a ble 70 through T a ble 92 “Port Multicast Address ($ Port_Index +0x1A – +0x1B)” on page 172

provide details on the control and status registers associated with each MAC port. The register

address is ‘Port_index + 0x**’, where the port index is set at any value from 0x0 through 0x5. All

registers are 32-bit. The unused bits of the registers are read-only and are set permanently to zero.

Table 70. Station Address ($ Port_Index +0x00 – +0x01)

Name

Description

Address

Type¹

Default

Source MAC address bit 31-0.

This address is inserted in the source address

field when transmitting pause frames, and is also

used to compare against unicast pause frames

at the receiving side.

Station Address

Low

Port_Index

+ 0x00

R/W

0x0000000

Source MAC address bit 47-32.

This address is inserted in the source address

Station Address

High

field when transmitting pause frames, and is also Port_Index

R/W

0x00000000

used to compare against unicast pause frames

at the receiving side. Bits 15:0 of this register are

assigned to bits 47:32 of the station address.

+ 0x01

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 71. Desired Duplex ($ Port_Index + 0x02)

Bit

Name

Description

Type¹

Default

100 Mbps or 10 Mbps mode only.

0x00000001

0x00000000

This register must be set to the default value of 1 and must not be changed when operating in

RGMII 1000 Mbps, GMII, or fiber mode.

31:1 Reserved

Reserved

0 = Half-duplex

1 = Full-duplex

NOTE: Half-duplex operation applies only to

10/100 Mbps speed on copper media in RGMII

mode only. Gigabit speed on either media requires

full-duplex.

Duplex Select

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 72. FD FC Type ($ Port_Index + 0x03)

Name

Description

Address

Type¹

Default

This value fills the Type field of the Transmitted

Pause frames. Only bits 15:0 of this register are

used.

Port_Index

+ 0x03

FD FC Type

R/W

0x00008808

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 73. Collision Distance ($ Port_Index + 0x05)

Name

Description

Address

Type¹

Default

This is a 10-bit value that sets the limit for late

collision. Collisions happening at byte times

beyond the configured value are considered to be

late collisions. (Only valid in half-duplex).

Collision

Distance

Port_Index

+ 0x05

R/W

0x00000043

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

Table 74. Collision Threshold ($ Port_Index + 0x06)

Name

Description

Address

Type¹

Default

This is a 4-bit value that sets the limit for

excessive collisions. When the number of

transmission attempts performed for a packet

exceeds this value, it is considered to be an

excessive collision and the frame is dropped.

(Only valid in half-duplex).

Collision

Threshold

Port_Index

+ 0x06

R/W

0x0000000F

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

Table 75. FC TX Timer Value ($ Port_Index + 0x07)

Name

Description

Address

Type¹

Default

The 16-bit pause length inserted in the flow

control pause frame sent to the receiving

station. The value is in 512-bit times.

FC TX Timer

Value

Port_Index

+ 0x07

R/W

0x0000005E

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 76. FD FC Address ($ Port_Index + 0x08 – + 0x09)

Name

Description

Address

Type¹

Default

The lowest 32 bits of the 48-bit globally

FD FC Address Low assigned multicast pause frame destination

Port_Index

+ 0x08

R/W

0xC2000001

address.

The highest 16 bits (47:32) of the globally

assigned multicast pause frame destination

address. The higher 16-bit address is

Port_Index

+ 0x09

FD FC Address High

R/W

0x00000180

derived from bits 15:0 of this register.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 77. IPG Receive Time 1 ($ Port_Index + 0x0A)

Name

Description

Address

Type¹

Default

This timer is used during half-duplex operation

when there is a packet waiting for

transmission from the MAC. This timer starts

after CRS is de-asserted. If CRS is asserted

during this time, no transmission is initiated

and the counter restarts once CRS is de-

asserted again.

Port_Index

+ 0x0A

IPG Receive Time 1

R/W

0x00000008

The value specified in this register is

calculated as follows: (register_value * 8) =

RXIPG1 in terms of bit times. Therefore, a

default value of 8 gives the following: (8 * 8 =

64 bit times for the default).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 78. IPG Receive Time 2 ($ Port_Index + 0x0B)

Name

Description

Address

Type¹

Default

This is only used in half-duplex operation. It

starts counting at the same time as RXIPG1.

Once RXIPG1 expires, a frame is transmitted

when RXIPG2 expires regardless of the CRS

value. If CRS is asserted before RXIPG1

expires, no transmission occurs and both

RXIPG1 an RXIPG2 are reset once CRS is

de-asserted again.

Port_Index

+ 0x0B

IPG Receive Time 2

R/W

0x00000007

The value specified in this register is

calculated as follows: (register_value +5) * 8 =

RXIPG2 in terms of bit times. Therefore, a

default of 7 gives the following:

(7+5) * 8 = 96 bit times for default.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 79. IPG Transmit Time ($ Port_Index + 0x0C)

Name

Description

Address

Type¹

Default

This is a 10-bit value configuring IPG time for

back-to-back transmissions.

The value specified in this register is

calculated as follows: (register_value +4) * 8 = Port_Index

IPG Transmit Time

R/W

0x00000008

TXIPG in terms of bit times. Therefore, a

default value of 8 gives the following:

(8+4) * 8 = 96 bit times for the default.

+ 0x0C

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 80. Pause Threshold ($ Port_Index + 0x0E)

Name

Description

Address

Type¹

Default

When a pause frame has been sent, an internal

timer checks when the next pause frame must

be scheduled for transmission to keep the link

partner in pause mode (this is required only if

the flow control has to be extended for one more

session). The pause threshold value is a 16-bit

value that sets the time in terms of 512-bit

quantum after the previous pause frame when

the next pause frame has to be sent. This

ensures that the link partner is kept in pause

mode continuously.

Pause

Threshold

Port_Index

+ 0x0E

R/W

0x0000002F

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 81. Max Frame Size (Addr: Port_Index + 0x0F)

Name

Description

Address

Type¹

Default

This is a 14-bit value configuring the maximum

frame size the MAC can receive or transmit

without activating any error counters, and

without truncation.

This value is excluding the 4-byte CRC in the

transmit direction when CRC append is

enabled in the MAC. Hence, this value has to

be set four bytes less when CRC append is

enabled in the MAC.

Port_Inde

x + 0x0F

Max Frame Size

R/W

0x000005EE

The maximum frame size is internally adjusted

by +4 if the frame is VLAN tagged.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 82. MAC IF Mode and RGMII Speed ($ Port_Index + 0x10)

Bit

Name

Description

Type¹

Default

per port.

Changes to the data setting of this register must be made in conjunction with the “Clock and

Interface Mode Change Enable Ports 0 - 3 ($0x794)" to ensure a safe transition to a new

operational mode. Changes to this register must follow a proper sequence. Refer to Section

6.1, “Change Port Mode Initialization Sequence” on page 129 for the proper sequence for

changing the port mode and speed.

0x00000003

0x00000000

31:3 Reserved

Reserved

These bits are used to define the clock mode and

the RGMII/GMII mode of operation.

000 = Reserved

001 = Reserved

010 = GMII 1000 Mbps operation

011 = Reserved

2:0

Port Mode

R/W

011

100 = RGMII 10 Mbps operation

101 = RGMII 100 Mbps operation

11x = RGMII 1000 Mbps operation

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 83. Flush TX ($ Port_Index + 0x11)

Bit

Name

Description

Type¹

Default

stopped.

0x00000000

31:1 Reserved

Flush TX

Reserved

This bit flushes all TX data and is used if all the

traffic sent to a port should be stopped.

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 84. FC Enable ($ Port_Index + 0x12)

Bit

Name

Description

Type¹

Default

0x00000007

0x00000000

31:3 Reserved

Reserved

When TX HDFC is enabled (half-duplex mode

only), the MAC generates deliberate collisions on

incoming packets when the RX FIFO occupancy

crosses the High Watermark (flow control).

TX HDFC

R/W

0 = Disable TX half-duplex flow control

1 = Enable TX half-duplex flow control

0 = Disable TX full-duplex flow control [the MAC

will not generate internally any flow control

frames based on the RX FIFO watermarks or

the Transmit Pause Control interface

1 = Enable TX full-duplex flow control [enables

the MAC to send flow control frames to the

link partner based on the RX FIFO

TX FDFC

R/W

programmable watermarks or the Transmit

Pause Control interface]

0 = Disable RX full-duplex flow control [the MAC

will not respond to flow control frames sent to

it by the link partner]

1 = Enable RX full-duplex flow control [MAC will

respond to flow control frames sent by the link

partner and will stop packet transmission for

the time specified in the flow control frame]

RX FDFC

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 85. FC Back Pressure Length ($ Port_Index + 0x13)

Name

Description

Address

Type¹

Default

This register sets number the byte cycles

for which the collision has to be applied.

The 6-bit configuration holds the value in

bytes, which applies to the minimum

length/duration of back pressure in half-

duplex mode. Flow control in the receive

path is executed by deliberately colliding

the incoming packets in half-duplex mode.

FC Back Pressure

Length

Port Add +

0x13

R/W

0x0000000C

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 86. Short Runts Threshold ($ Port_Index + 0x14)

Name

Description

Address

Type¹

Default

The 5-bit configuration holds the value in bytes,

which applies to the threshold in determining

between runts and short. The bits 4:0 of this

A received packet is reported as a short packet

when the length (excluding Preamble and

SFD) is less than this value.

Short Runts

Threshold

Port_Index +

0x14

A received packet is reported as a runt packet

when the length (excluding Preamble and

SFD) is equal to or greater than this value and

less than 64-bytes.

R/W

0x00000008

NOTE: This register is only relevant when the

IXF1104 port is configured for copper

operation (the line side interface is

configured for either RGMII or GMII).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 87. Discard Unknown Control Frame ($ Port_Index + 0x15)

Bit

Name

Description

Type¹

Default

are pause frames.

0x00000000

31:1 Reserved

Discard Unknown

Reserved

0 = Forward unknown control frames

1 = Discard unknown control frames

R/W

Control Frame

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 88. RX Config Word ($ Port_Index + 0x16) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

the receive status. The lower 16 bits of this register are the “config_reg” received from the link

partner, as described in IEEE 802.3 2000 Edition, Section 37.2.1.

0x00000000

0x000

31:22 Reserved

Reserved

Auto-negotiation complete. This bit remains

cleared from the time auto-negotiation is reset until

auto-negotiation reaches the “LINK_OK” state. It

remains set until auto-negotiation is disabled or

restarted.

An_complete

This bit is only valid if auto-negotiation is enabled.

0 = Loss of synchronization

Rx Sync

1 = Bit synchronization. The bit remains Low until

the register is read.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

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Table 88. RX Config Word ($ Port_Index + 0x16) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

0 = Receiving idle/data stream

1 = Receiving /C/ ordered sets

RX Config

0 = RxConfigWord has changed since last read

1 = RxConfigWord has not changed since last

read.

Config Changed

This bit remains High until the register is read.

0 = Have not received an invalid symbol

1 = Have received an invalid symbol

Invalid Word

This bit remains High until the register is read.

0 = Device is not receiving idle characters; carrier

sense is true.

1 = Device is receiving idle characters; carrier

Carrier Sense

sense is false.

Reserved

Next Page request

Reserved

Remote fault definitions:

00 = No error, link okay

01 = Offline

13:12²Remote Fault [1:0]

R/W

10 = Link failure

11 = Auto-negotiation_Error

11:9

Reserved

000

Asym Pause

Asym Pause. The ability to send pause frames.

Sym Pause. The ability to send and receive pause

frames.

Sym Pause

Half Duplex

Full Duplex

Reserved

Half-duplex

Full-duplex

Reserved

4:0

0x0

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

Table 89. TX Config Word ($ Port_Index + 0x17) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

contents of this register are sent as the config_word. The contents of this register are the

“config_reg” sent to the link partner, as described in IEEE 802.3 2000 Edition, subclause 37.2.1.

0x0001A0

31:16 Reserved

Reserved

R/W

0x0000

Reserved

Next Page request

Write as 0, ignore on read

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

NOTE: A value of 0x0 must be written to all reserved bits of the “TX Config Word ($ Port_Index + 0x17)”

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Table 89. TX Config Word ($ Port_Index + 0x17) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

Remote fault definitions:

00 = No error, link okay

01 = Offline

13:12²Remote Fault [1:0]

R/W

10 = Link failure

11 = Auto-negotiation_Error

11:9

Reserved

Write as 0, ignore on Read

R/W

000

Asym Pause

Asym Pause. The ability to send pause frames.

Sym Pause. The ability to send and receive pause

frames.

Sym Pause

R/W

Half Duplex

Full Duplex

Reserved

Half-duplex

R/W

Full-duplex

4:0

Write as 0, ignore on read

0x00

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

NOTE: A value of 0x0 must be written to all reserved bits of the “TX Config Word ($ Port_Index + 0x17)”

Table 90. Diverse Config Write ($ Port_Index + 0x18) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

0x00110D

0x0000

31:19 Reserved

18:13 Reserved

Reserved

R/W

Write as 0, ignore on Read.

Write as 1, ignore on Read.

Write as 0, ignore on Read.

Write as 1, ignore on Read.

11-9 Reserved²

Reserved²

0x0

Reserved²

0 = Normal operation

1 = Enable padding of undersized packets

pad_enable

R/W

NOTE: Assertion of this bit results in the

automatic addition of a CRC to the

padded packet.

0 = Normal operation

1 = Enable automatic CRC appending

crc_add

Enable auto-negotiation (used for fiber mode only)

to be performed by the hardware state machines

in the MAC.

The hardware auto-negotiation (AN) state

machine controls the config words transmitted

when this bit is set.

NOTE: In copper mode, this bit must be set to 0

(reserved).

AN_enable

Reserved

R/W

4²

Write as 0, ignore on Read.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. Reserved bits must be written to the default value for proper operation.

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Table 90. Diverse Config Write ($ Port_Index + 0x18) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

3:2²Reserved

Write as 1, ignore on Read.

Write as 0, ignore on Read.

Write as 1, ignore on Read.

R/W

1²

0²

Reserved

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. Reserved bits must be written to the default value for proper operation.

Table 91. RX Packet Filter Control ($ Port_Index + 0x19) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

and is used in conjunction with the “RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2 0x00000000

- 0x5A5)”.

31:6 Reserved

Reserved

This bit enables a Global filter on frames with a

CRC Error.

0 = When CRC Error Pass = 0, all frames with a

CRC Error are marked as bad.²

1 = Frames with a CRC Error are not marked as

bad and are passed to the SPI3 interface for

transfer as good frames, regardless of the

state of the bits in the “RX FIFO Errored

Frame Drop Enable ($0x59F)”.

CRC Error Pass

R/W

NOTE: When the CRC Error Pass Filter bit = 0, it

takes precedence over the other filter bits.

Any packet, whether is a Pause, Unicast,

Multicast or Broadcast packet with a CRC

error, is marked as a bad frame when

CRC Error Pass = 0

This bit enables a Global filter on Pause frames.

0 = All pause frames are dropped.²

1 = All pause frames are passed to the SPI3

Interface.

Pause Frame Pass

R/W

NOTE: Pause Frames can only be filtered if

RXFD flow control is enabled in the “FC

Enable ($ Port_Index + 0x12)”.

This bit enables a global filter on VLAN frames.

0 = All VLAN frames are passed to the SPI3

Interface.

VLAN Drop En

1 = All VLAN frames are dropped.²

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

2. Used in conjunction with the “RX FIFO Errored Frame Drop Enable ($0x59F)” on page 195. This allows the

frame to be dropped in the RX FIFO. Otherwise, the frame is sent out the SP3 interface and may be

optionally signaled with an RERR (see bit 0 of “SPI3 Receive Configuration ($0x701)”.

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Table 91. RX Packet Filter Control ($ Port_Index + 0x19) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

This bit enables a Global filter on broadcast

frames.

B/Cast Drop En

R/W

0 = All broadcast frames are passed to the SPI3

Interface.

1 = All broadcast frames are dropped.²

This bit enables a filter on multicast frames.

0 = All muticast frames are good and passed to

the SPI3 Interface.

1 = Only multicast frames with a destination

address that matches the

M/Cast Match En

R/W

PortMulticastAddress are forwarded. All other

muticast frames are dropped.²

This bit enables a filter on unicast frames.

0 = All unicast frames are good and are passed

to the SPI3 Interface.

1 = Only unicast frames with a Destination

Address that matches the Station Address

are forwarded. All other unicast frames are

dropped.²

U/Cast Match En²

R/W

NOTE: The VLAN filter overrides the unicast filter.

Therefore, a VLAN frame cannot be

filtered based on the unicast address.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

2. Used in conjunction with the “RX FIFO Errored Frame Drop Enable ($0x59F)” on page 195. This allows the

frame to be dropped in the RX FIFO. Otherwise, the frame is sent out the SP3 interface and may be

optionally signaled with an RERR (see bit 0 of “SPI3 Receive Configuration ($0x701)”.

Table 92. Port Multicast Address ($ Port_Index +0x1A – +0x1B)

Name

Description

Address

Type^*

Default

This address compares against multicast frames

at the receiving side if multicast filtering is

enabled.

Port Multicast

Address Low

Port_Index

+ 0x1A

R/W

0x0000000

This register contains bits 31:0 of the address.

This address compares against multicast frames

at the receiving side if Multicast filtering is

enabled.

Port Multicast

Address High

Port_Index

+ 0x1B

R/W

0x00000000

This register contains bits 47:32 of the address.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.2

MAC RX Statistics Register Overview

The MAC RX Statistics registers contain the MAC receiver statistic counters and are cleared when

read. The software polls these registers and accumulates values to ensure that the counters do not

wrap. The 32-bit counters wrap after approximately 30 seconds.

T a ble 93 covers the RX statistics for the four MAC ports. Port_Index is the port number (0, 1, 2, or

3).

Table 93. MAC RX Statistics ($ Port_Index + 0x20 – + 0x39) (Sheet 1 of 4)

Name

Description

Address

Type¹

Default

Counts the bytes received in all legal frames,

including all bytes from the destination MAC

address to and including the cyclic redundancy

check (CRC). The initial preamble and Start of

Frame Delimiter (SFD) bytes are not counted.

Port_Index

+ 0x20

RxOctetsTotalOK

0x00000000

Counts the bytes received in all bad frames with

legal size (frames with CRC error, alignment

errors, or code violations), including all bytes

from the destination MAC address to (and

including) the CRC. The initial preamble and

SFD bytes are not counted. Frames with illegal

size do not add to this counter (shorts, runts,

longs, jabbers, and very longs).

Port_Index

+ 0x21

RxOctetsBAD²

0x00000000

Note: This register does not count octets on

undersized received packets.

The total number of unicast packets received

(excluding bad packets).

Note: This count includes non-pause control and

VLAN packets, which are also counted in other

counters. These packet types are counted twice.

Take care when summing register counts for

reporting Management Information Base (MIB)

information.

Port_Index

+ 0x22

RxUCPkts

RxMCPkts

0x00000000

The total number of multicast packets received

(excluding bad packets)

Note: This count includes pause control packets,

which are also counted in the PauseMacControl-

ReceivedCounter. These packet types are

counted twice. Take care when summing register

counts for reporting MIB information.

Port_Index

+ 0x23

The total number of Broadcast packets received

(excluding bad packets).

Port_Index

+ 0x24

RxBCPkts

0x00000000

The total number of packets received (including

bad packets) that were 64 octets in length.

Incremented for tagged packets with a length of

64 bytes, including tag field.

Port_Index

+ 0x25

RxPkts64Octets

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. When sending in large frames, the counters can only handle certain limits. The behavior of the LongErrors

and VeryLongErrors counters is as follows: VeryLongErrors counts frames that are 2*maxframesize,

dependent upon where maxframesize is set. If maxframesize sets greater than half of the available count in

RxOctetsBad (2^14-1), VeryLongErrors is never incremented, but LongErrors is incremented. This is due to

a limitation in the counter size, which means that an accurate count will not occur in the RxOctetsBAD

counter if the frame is larger than 2^14-1.

3. This register is relevant only when configured for copper operation.

4. This register is relevant only when configured for fiber operation (line side interface is SerDes).

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Table 93. MAC RX Statistics ($ Port_Index + 0x20 – + 0x39) (Sheet 2 of 4)

Name

Description

Address

Type¹

Default

The total number of packets received (including

bad packets) that were 65-127 octets in length.

Incremented for tagged packets with a length of

65-127 bytes, including tag field.

RxPkts65to127

Octets

Port_Index

+ 0x26

0x00000000

The total number of packets received (including

bad packets) that were 128-255 octets in length.

Incremented for tagged packets with a length of

128-255 bytes, including tag field.

RxPkts128t0255

Octets

Port_Index

+ 0x27

0x00000000

The total number of packets received (including

bad packets) that were 256-511 octets in length.

Incremented for tagged packets with a length of

256-511 bytes, including tag field.

RxPkts256to511

Octets

Port_Index

+ 0x28

The total number of packets received (including

RxPkts512to1023O bad packets) that were 512-1023 octets in

Port_Index

+ 0x29

ctets

length. Incremented for tagged packets with a

length of 512-1023 bytes, including tag field.

The total number of packets received (including

RxPkts1024to1518 bad packets) that were 1024-1518 octets in

Port_Index

+ 0x2A

Octets

length. Incremented for tagged packet with a

length between 1024-1522, including the tag.

The total number of packets received (including

bad packets) that were greater than 1518 octets

in length. Incremented for tagged packet with a

length between 1523-max frame size, including

the tag.

RxPkts1519toMaxO

ctets

Port_Index

+ 0x2B

0x00000000

Number of frames received with legal size, but

with wrong CRC field (also called Frame Check

Sequence (FCS) field).

NOTE: Legal size is 64 bytes through the value

programmed in the “Max Frame Size

(Addr: Port_Index + 0x0F)” on

Port_Index

+ 0x2C

RxFCSErrors

page 165.

Number of OK frames with VLAN tag.

(Type field = 0x8100)

Port_Index

+ 0x2D

RxTagged

0x00000000

Number of frames received with legal length,

containing a code violation (signaled with

RX_ERR on RGMII).

Port_Index

+ 0x2E

RxDataError³

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. When sending in large frames, the counters can only handle certain limits. The behavior of the LongErrors

and VeryLongErrors counters is as follows: VeryLongErrors counts frames that are 2*maxframesize,

dependent upon where maxframesize is set. If maxframesize sets greater than half of the available count in

RxOctetsBad (2^14-1), VeryLongErrors is never incremented, but LongErrors is incremented. This is due to

a limitation in the counter size, which means that an accurate count will not occur in the RxOctetsBAD

counter if the frame is larger than 2^14-1.

3. This register is relevant only when configured for copper operation.

4. This register is relevant only when configured for fiber operation (line side interface is SerDes).

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Table 93. MAC RX Statistics ($ Port_Index + 0x20 – + 0x39) (Sheet 3 of 4)

Name

Description

Address

Type¹

Default

Frames with a legal frame size, but containing

less than eight additional bits. This occurs when

the frame is not byte aligned. The CRC of the

frame is wrong when the additional bits are

stripped. If the CRC is OK, then the frame is not

counted but treated as an OK frame. This

counter increments in 10 Mbps or 100 Mbps

RGMII mode only.

Port_Index

+ 0x2F

RxAlignErrors³

0x00000000

NOTE: This counter increments in 10 or 100

Mbps RGMII mode only.

Frames bigger than the maximum allowed, with

both OK CRC and the integral number of octets.

Default maximum allowed is 1518 bytes

untagged and 1522 bytes tagged, but the value

can be changed by a register.

Port_Index

+ 0x30

RxLongErrors²

0x00000000

Frames bigger than the larger of

2*maxframesize and 50,000 bits are not counted

here, but they are counted in the VeryLongError

counter.

Frames bigger than the maximum allowed, with

either a bad CRC or a non-integral number of

octets. The default maximum allowed is 1518

bytes untagged and 1522 bytes tagged, but the

value can be changed by a register.

Port_Index

+ 0x31

RxJabberErrors

0x00000000

Frames bigger than the larger of

2*maxframesize and 50,000 bits are not counted

here, but they are counted in the VeryLongError

counter.

Number of Pause MAC control frames received.

This statistic register increments on any valid 64-

byte pause frame with a valid CRC and also

increments on a 64-byte pause frame with an

invalid CRC if bit 5 of the “RX Packet Filter

Control ($ Port_Index + 0x19)” is set to 1.

RxPauseMacContr

olReceivedCounter

Port_Index

+ 0x32

RxUnknownMac

ControlFrame

Counter

Number of MAC control frames received with an

op code different from 0001 (Pause).

Port_Index

+ 0x33

0x00000000

Frames bigger than the larger of

2*maxframesize and 50,000 bits

Port_Index

+ 0x34

RxVeryLongErrors²

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. When sending in large frames, the counters can only handle certain limits. The behavior of the LongErrors

and VeryLongErrors counters is as follows: VeryLongErrors counts frames that are 2*maxframesize,

dependent upon where maxframesize is set. If maxframesize sets greater than half of the available count in

RxOctetsBad (2^14-1), VeryLongErrors is never incremented, but LongErrors is incremented. This is due to

a limitation in the counter size, which means that an accurate count will not occur in the RxOctetsBAD

counter if the frame is larger than 2^14-1.

3. This register is relevant only when configured for copper operation.

4. This register is relevant only when configured for fiber operation (line side interface is SerDes).

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Table 93. MAC RX Statistics ($ Port_Index + 0x20 – + 0x39) (Sheet 4 of 4)

Name

Description

Address

Type¹

Default

The total number of packets received that are

less than 64 octets in length, but longer than or

equal to 96 bit times, which corresponds to a 4-

byte frame with a well-formed preamble and

SFD. This is the shortest fragment and can be

transmitted in case of a collision event on a half-

duplex segment. This counter indicates fragment

sizes, which is expected on half-duplex

segments but not on full-duplex links, and the

counter is only fully updated after receipt of a

good frame following a fragment.

NOTE: The ShortRuntsThreshold register

Port_Index

+ 0x35

RxRuntErrors³

controls the byte count used to

0x00000000

determine the difference between Runts

and Shorts and therefore controls which

counter is incremented for a given frame

size. This counter is only updated after

receipt of two good frames.

NOTE: This counter is only valid when the

selected port within the IXF1104 is

operating in copper (RGMII or GMII)

mode. The RuntError counter is not

updated when the selected port within

the IXF1104 is configured to operated in

fiber (SerDes) mode.

The total number of packets received that are

less than 96 bit times, which corresponds to a 4-

byte frame with a well-formed preamble and

SFD. This counter indicates fragment sizes

illegal in all modes and is only fully updated after

reception of a good frame following a fragment.

NOTE: This register is only relevant when the

IXF1104 port is configured for copper

operation (the line side interface is

Port_Index

+ 0x36

RxShort Errors³

0x00000000

configured for either RGMII or GMII

operation). This register will not

increment when the IXF1104 port is

configured for fiber operation using the

SerDes interface.

RxCarrier Extend

Error

Port_Index

+ 0x37

Not applicable.

0x00000000

Records the number of sequencing errors that

occur in fiber mode.

Port_Index

+ 0x38

RxSequenceErrors⁴

RxSymbolErrors⁴

Records the number of symbol errors

encountered by the PHY.

Port_Index

+ 0x39

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

2. When sending in large frames, the counters can only handle certain limits. The behavior of the LongErrors

and VeryLongErrors counters is as follows: VeryLongErrors counts frames that are 2*maxframesize,

dependent upon where maxframesize is set. If maxframesize sets greater than half of the available count in

RxOctetsBad (2^14-1), VeryLongErrors is never incremented, but LongErrors is incremented. This is due to

a limitation in the counter size, which means that an accurate count will not occur in the RxOctetsBAD

counter if the frame is larger than 2^14-1.

3. This register is relevant only when configured for copper operation.

4. This register is relevant only when configured for fiber operation (line side interface is SerDes).

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8.4.3

MAC TX Statistics Register Overview

The MAC TX Statistics registers contain all the MAC transmit statistic counters and are cleared

when read. The software must poll these registers to accumulate values and to ensure that the

counters do not wrap. The 32-bit counters wrap after approximately 30 seconds.

T a ble 94 covers all four MAC ports TX statistics. Port_Index is the port number (0, 1, 2, or 3).

Table 94. MAC TX Statistics ($ Port_Index +0x40 – +0x58) (Sheet 1 of 4)

Name

Description

Address

Type¹

Default

Counts the bytes transmitted in all legal

frames. The count includes all bytes

from the destination MAC address to

and including the CRC. The initial

preamble and SFD bytes are not

counted. Any initial collided

Port_Index +

0x40

OctetsTransmittedOK

0x00000000

transmission attempts before a

successful frame transmission do not

add to this counter.

Counts the bytes transmitted in all bad

frames. The count includes all bytes

from the destination MAC address to

and including the CRC. The initial

preamble and SFD bytes are not

counted.

Late collision counted: The count is

close to the actual number of bytes

transmitted before the frame is

discarded.

Excessive collision counted: The count

is close to the actual number of bytes

transmitted before the frame is

discarded.

Port_Index +

0x41

OctetsTransmittedBad

0x00000000

TX under-run counted: The count is

expected to match the number of bytes

actually transmitted before the frame is

discarded.

TX CRC error counted: All bytes not

sent with success are counted by this

counter.

Any initial collided transmission

attempts before a successful frame

transmission do not add to this counter.

The total number of unicast packets

transmitted (excluding bad packets).

Port_Index +

0x42

TxUCPkts

TxMCPkts

0x00000000

The total number of multicast packets

transmitted (excluding bad packets).

NOTE: This count includes pause

control packets, which are also

counted in the

Port_Index +

0x43

TxPauseFrames Counter.

Thus, these types of packets

are counted twice. Take care

when summing register counts

for reporting MIB information.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 94. MAC TX Statistics ($ Port_Index +0x40 – +0x58) (Sheet 2 of 4)

Name

Description

Address

Type¹

Default

The total number of broadcast packets

transmitted (excluding bad packets).

Port_Index +

0x44

TxBCPkts

0x00000000

The total number of packets

transmitted (including bad packets) that

were 64 octets in length. Incremented

for tagged packets with a length of 64

bytes, including tag field.

Port_Index +

0x45

TxPkts64Octets

0x00000000

The total number of packets

transmitted (including bad packets) that

were 65-127 octets in length.

Incremented for tagged packets with a

length of 65-127 bytes, including tag

field.

Port_Index +

0x46

Txpkts65to127Octets

The total number of packets

transmitted (including bad packets) that

were 128-255 octets in length.

Incremented for tagged packets with a

length of 128-255 bytes, including tag

field.

Port_Index +

0x47

Txpkts128to255Octets

Txpkts256to511Octets

Txpkts512to1023Octets

Txpkts1024to1518Octets

Txpkts1519toMaxOctets

0x00000000

The total number of packets

transmitted (including bad packets) that

were 256-511 octets in length.

Incremented for tagged packets with a

length of 256-511 bytes, including tag

field.

Port_Index +

0x48

The total number of packets

transmitted (including bad packets) that

were 512-1023 octets in length.

Incremented for tagged packets with a

length of 512-1023 bytes, including tag

field.

Port_Index +

0x49

The total number of packets

transmitted (including bad packets) that

were 1024-1518 octets in length.

Incremented for tagged packet with a

length between 1024-1522, including

the tag.

Port_Index +

0x4A

The total number of packets

transmitted (including bad packets) that

were greater than 1518 octets in

length. Incremented for tagged packet

with a length between 1523 - max fame

size, including the tag.

Port_Index +

0x4B

Number of times the initial transmission

attempt of a frame is postponed due to

another frame already being

transmitted on the Ethernet network.

TxTotalCollisions.

Port_Index +

0x4C

TxDeferred

0x00000000

NOTE: NA - half-duplex only

Sum of all collision events.

Port_Index +

0x4D

TxTotalCollisions

NOTE: NA - half-duplex only

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 94. MAC TX Statistics ($ Port_Index +0x40 – +0x58) (Sheet 3 of 4)

Name

Description

Address

Type¹

Default

A count of successfully transmitted

frames on a particular interface where

the transmission is inhibited by exactly

one collision. A frame that is counted

by an instance of this object is also

counted by the corresponding instance

of either the UnicastPkts,

Port_Index +

0x4E

TxSingleCollisions

0x00000000

MulticastPkts, or BroadcastPkts, and is

not counted by the corresponding

instance of the MultipleCollisionFrames

object.

NOTE: NA - half-duplex only

A count of successfully transmitted

frames on a particular interface for

which transmission is inhibited by more

than one collision. A frame that is

counted by an instance of this object is

also counted by the corresponding

instance of either the UnicastPkts,

MulticastPkts, or BroadcastPkts, and is

not counted by the corresponding

instance of the SingleCollisionFrames

object.

Port_Index +

0x4F

TxMultipleCollisions

0x00000000

NOTE: NA - half-duplex only

The number of times a collision is

detected on a particular interface later

than 512 bit-times into the transmission

of a packet. Such frame are terminated

and discarded.

Port_Index +

0x50

TxLateCollisions

0x00000000

NOTE: NA - half-duplex only

A count of frames, which collides 16

times and is then discarded by the

MAC. Not effecting xMultipleCollisions

Port_Index +

0x51

TxExcessiveCollisionErrors

NOTE: NA - half-duplex only

Number of times frame transmission is

postponed more than 2*MaxFrameSize

because of another frame already

being transmitted on the Ethernet

network. This causes the MAC to

discard the frame.

Port_Index +

0x52

TxExcessiveDeferralErrors

0x00000000

NOTE: NA - half-duplex only

Frame transmissions aborted by the

MAC because the frame is longer than

maximum frame size. These frames

are truncated by the MAC when the

maximum frame size violation is

detected by the MAC.

Port_Index +

0x53

TxExcessiveLengthDrop

0x00000000

Internal TX error that causes the MAC

to end the transmission before the end

of the frame because the MAC did not

get the needed data in time for

transmission. The frames are lost and

a fragment or a CRC error is

Port_Index +

0x54

TxUnderrun

transmitted.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 94. MAC TX Statistics ($ Port_Index +0x40 – +0x58) (Sheet 4 of 4)

Name

Description

Address

Type¹

Default

Number of OK frames with VLAN tag.

(Type field = 0x8100).

Port_Index +

0x55

TxTagged

0x00000000

Number of frames transmitted with a

legal size but with the wrong CRC field

(also called FCS field).

Port_Index +

0x56

TxCRCError

0x00000000

Number of pause MAC frames

transmitted.

Port_Index +

0x57

TxPauseFrames

Intentionally generates collisions to

curb reception of incoming traffic due to

insufficient memory available for

additional frames. The port must be in

half-duplex mode with flow control

enabled.

TxFlowControlCollisions

Send

Port_Index +

0x58

0x00000000

NOTE: To receive a correct statistic, a

last frame may have to be

transmitted after the last flow

control collisions send.

NOTE: NA - half-duplex only

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

8.4.4

PHY Autoscan Registers

Note: These register hold the current values of the PHY registers only when Autoscan (see Section 5.5.8,

“Autoscan Operation” on page 102) is enabled and the IXF1104 is configured in copper mode.

These registers are not applicable in fiber mode.

Table 95. PHY Control ($ Port Index + 0x60) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

0x0000

PHY Soft Reset. Resets the PHY registers to their

default value.

This register bit self-clears after the reset is

complete.

Reset

0 = Normal Operation

1 = PHY reset

0 = Disable loopback mode

1 = Enable loopback mode

Loopback

0.6 (Speed<1> 0.13 (Speed<0>)

00 =10 Mbps

Speed Selection

01 =100 Mbps

0²

10 =1000 Mbps (manual mode not allowed)

11 = Reserved

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

2. This register is ignored if auto-negotiation is enabled.

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Table 95. PHY Control ($ Port Index + 0x60) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

0 = Disable auto-negotiation process

1 = Enable auto-negotiation process

Auto-Negotiation

Enable

This register bit must be enabled for

1000BASE-T operation.

0 = Normal operation

1 = Power-down

Power-Down

Isolate

0 =

1 = Electrically isolate PHY from GMII

Restart

Auto-Negotiation

0 = Normal operation

1 = Restart auto-negotiation process

0 = Half-duplex mode

1 = Full-duplex mode

Duplex Mode

Collision Test

1²

0 = Disable COL signal test

1 = Enable COL signal test

This register bit is ignored unless loopback is

enabled (Register bit 0.14 = 1)

0.6 (Speed<1>) 0.13 (Speed<0>)

00 = 10 Mbps

Speed Selection

1000 Mbps

01 = 100 Mbps

0²

10 = 1000 Mbps (manual mode now allowed)

11 = Reserved

5:0

Reserved

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

2. This register is ignored if auto-negotiation is enabled.

Table 96. PHY Status ($ Port Index + 0x61) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

0 = PHY not able to operate in 100BASE-T4

1 = PHY able to operate in 100BASE-T4

100BASE-T4

0 = PHY not able to operate in 100BASE-X in full-

duplex mode

1 = PHY able to operate in 100BASE-X in full-

100BASE-X

Full-Duplex

duplex mode

0 = PHY not able to operate in 100BASE-X in

half-duplex mode

1 = PHY able to operate in 100BASE-X in half-

100BASE-X

Half-Duplex

duplex mode

0 = PHY not able to operate in 10 Mbps in full-

duplex mode

1 = PHY able to operate in 10 Mbps in full-duplex

10 Mbps

Full-Duplex

mode

0 = PHY not able to operate in 10 Mbps in half-

duplex mode

1 = PHY able to operate in 10 Mbps in half-

10 Mbps

Half-Duplex

duplex mode

1. R = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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Table 96. PHY Status ($ Port Index + 0x61) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

0 = PHY not able to operate in 10BASE-T2 in full-

duplex mode (not supported)

1 = PHY able to operate in 100BASE-T2 in full-

duplex mode

100BASE-T2

Full-Duplex

0 = PHY not able to operate in 100BASE-T2 in

half-duplex mode

1 = PHY able to operate in 100BASE-T2 in half-

duplex mode

100BASE-T2

Half-Duplex

0 = No extended status information in Register 15

1 = Extended status information in Register 15

Extended Status

Reserved

0 = PHY will not accept management frames with

preamble suppressed

1 = PHY will accept management frames with

MF Preamble

Suppression

preamble suppressed

Reserved

0 =

Remote Fault

1 = Remote fault condition detected

Auto-Negotiation

Ability

0 =

1 = PHY is able to perform auto-negotiation

0 = Link is down

1 = Link is up

Link Status

0 = Jabber condition not detected

1 = Jabber condition detected

Jabber Detect

Extended Capability

0 = No extended register capabilities

1 = Extended register capabilities

1. R = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

Table 97. PHY Identification 1 ($ Port Index + 0x62)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

The PHY identifier is composed of register bits

18.3 of the OUI (Organizationally Unique

Identifier)

15:0

PHY ID Number

h0013

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

Table 98. PHY Identification 2 ($ Port Index + 0x63) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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Table 98. PHY Identification 2 ($ Port Index + 0x63) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

The PHY identifier is composed of register bits

24:19 of the OUI (Organizationally Unique

Identifier)

15:10 PHY ID Number

011110

9:4

3:0

Manufacturer’s Model

Six bits containing the manufacturer’s part number

010000

0000

Manufacturer’s

Revision Number

Four bits containing the manufacturer’s revision

number

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

Table 99. Auto-Negotiation Advertisement ($ Port Index + 0x64) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

0 =

Reserved

1 = Manual control of Next Page (software)

Reserved

0 = No remote fault

1 = Remote fault

Remote Fault

Reserved

Advertise Asymmetric Pause Direction register bit.

This register bit is used in conjunction with Pause

(Register bit 4.10)

ASM_DIR

Pause

0 = Link partner is not capable of asymmetric

pause

1 = Link partner is capable of asymmetric pause

Advertise to link partner that Pause operation is

desired (IEEE 802.3x Standard)

0 = 100BASE-T4 capability is not available

1 = 100BASE-T4 capability is available

The IXF1104 does not support 100BASE-T4, but

allows this register bit to be set to advertise in

auto-negotiation sequence for 100BASE-T4

operation. If this capability is desired, an external

100BASE-T4 transceiver can be switched in.

100BASE-T4

0 = DTE is not 100BASE-TX, full-duplex mode

100BASE-TX

Full-Duplex

capable

1 = DTE is 100BASE-TX, full-duplex mode

capable

0 = DTE is not 100BASE-TX, half-duplex mode

100BASE-TX

Half-Duplex

capable

1 = DTE is 100BASE-TX, half-duplex mode

capable

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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Table 99. Auto-Negotiation Advertisement ($ Port Index + 0x64) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

0 = DTE is not 10BASE-T, full-duplex mode

capable

1 = DTE is 10BASE-T, full-duplex mode capable

10BASE-T

Full-Duplex

0 = DTE is not 10BASE-T, half-duplex mode

capable

1 = DTE is 10BASE-T, half-duplex mode capable

10BASE-T

Half-Duplex

00001 =IEEE 802.3

00010 =IEEE 802.9 ISLAN-16T

00000 =Reserved for future auto-negotiation

development

Selector Field,

S[4:0]

11111 =Reserved for future auto-negotiation

development

4:0

00001

Unspecified or reserved combinations should not

be transmitted

Setting this field to a value other than 00001 will

most likely cause auto-negotiation to fail

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

Table 100. Auto-Negotiation Link Partner Base Page Ability ($ Port Index + 0x65) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

0 = Link partner has no ability to send multiple

pages

1 = Link partner has the ability to send multiple

pages

0 = Link partner has not received Link Code Word

from the IXF1104

1 = Link partner has received Link Code Word

Acknowledge

from the IXF1104

0 = No remote fault

1 = Remote fault

Remote Fault

Reserved

Advertise Asymmetric Pause Direction Register

bit. This register bit is used in conjunction with

Pause (Register bit 4.10)

ASM_DIR

0 = Link partner is not capable of asymmetric

pause

1 = Link partner is capable of asymmetric pause

Link partner wants to utilize Pause Operation as

defined in IEEE 802.3x Standard

Link Partner Pause

1000BASE-T4

0 = Link partner is not 100BASE-T4 capable

1 = Link partner is 100BASE-T4 capable

0 = Link partner is not 100BASE-TX, full-duplex

mode capable

1 = Link partner is 100BASE-TX, full-duplex

100BASE-TX

Full-Duplex

mode capable

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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Table 100. Auto-Negotiation Link Partner Base Page Ability ($ Port Index + 0x65) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

0 = Link partner is not 100BASE-TX, half-duplex

mode capable

1 = Link partner is 100BASE-TX, half-duplex

mode capable

100BASE-TX

Half-Duplex

0 = Link partner is not 10BASE-T, full-duplex

mode capable

1 = Link partner is 10BASE-T, full-duplex mode

capable

10BASE-T

Full-Duplex

0 = Link partner is not 10BASE-T, half-duplex

mode capable

1 = Link partner is 10BASE-T, half-duplex mode

capable

10BASE-T

Half-Duplex

00001 =IEEE 802.3

00010 =IEEE 802.9 ISLAN-16T

00000 =Reserved for future auto-negotiation

development

11111 =Reserved for future auto-negotiation

development

4:0

Selector Field, S[4:0]

00001

Unspecified or reserved combinations should not

be transmitted

Setting this field to a value other than 00001 will

most likely cause auto-negotiation to fail

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

Table 101. Auto-Negotiation Expansion ($ Port Index + 0x66)

Bit

Name

Description

Type¹

Default

31:6 Reserved

Reserved

This register bit indicates the status of the auto-

negotiation variable, base page. It flags

synchronization with the auto-negotiation state

diagram allowing detection of interrupted links.

Base Page

This register bit is only used if Register bit 16.1

(alternate Next Page feature) is set.

0 = base_page = false

1 = base_page = true

Parallel Detection

Fault

0 = Parallel detection fault has not occurred

1 = Parallel detection fault has occurred

Link Partner Next Page 0 = Link partner is not Next Page able

Able

1 = Link partner is Next Page able

0 = Local device is not Next Page able

1 = Local device is Next Page able

Next Page Able

Indicates that a new page has been received and

the received code word has been loaded into

as specified in the EEE 802.3 Standard.

Page Received

This bit clears on Read.

Link Partner Auto-

Negotiation Able

0 = Link partner is not auto-negotiation able

1 = Link partner is auto-negotiation able

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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Table 102. Auto-Negotiation Next Page Transmit ($ Port Index + 0x67)

Bit

Name

Description

Type¹

Default

31:16 Reserved

Reserved

0 = Last page

1 = Additional Next Pages follow

Next Page (NP)

Reserved

0 = Unformatted page

1 = Message page

Message Page (MP)

0 = Cannot comply with message

1 = Complies with message

Acknowledge 2

Toggle (T)

0 = Previous value of the transmitted Link Code

Word was logic one

1 = Previous value of the transmitted Link Code

Word was logic zero

Message/Unformatted 11-bit message code field

Code Field See IEEE 802.3 Annex 28C

10:0

1. RO = Read Only; RR = Clear on Read; W = Write; R/W = Read/Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.5

Global Status and Configuration Register Overview

T a ble 103 through Table 112 “JTAG ID ($0x50C)” on page 191 provide an overview for the Global

Control and Status Registers.

Table 103. Port Enable ($0x500)

Bit

Name

Description

Type^*

Default

the register. To make a port active, the bit must be set High. For example, Port 2 active implies

a register value of 0000.0100. Setting the bit to 0 de-asserts the enable. The default state for

this register is for all four ports to be disabled.

0x00000000

31:4 Reserved

Reserved

0x0000000

Port 3

Port 3 Enable

R/W

0 = Disable

1 = Enable

Port 2

Port 2 Enable

Port 1 Enable

Port 0 Enable

R/W

0 = Disable

1 = Enable

Port 1

0 = Disable

1 = Enable

Port 0

0 = Disable

1 = Enable

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 104. Interface Mode ($0x501)

Bit

Name

Description

Type¹

Default

mode.

0 = Fiber (SerDes/OMI interface)

1 = Copper (GMII or RGMII interface)

0x00000000

Changes to the data setting of this register must be made in conjunction with the “Clock and

Interface Mode Change Enable Ports 0 - 3 ($0x794)" to ensure a safe transition to a new

operational mode (see Section 6.1, “Change Port Mode Initialization Sequence” on page 129).

The Enable clock mode change bit has to be set back to 1 after the configuration change takes

effect.

31:4 Reserved

Reserved

0x0000000

0 = Fiber mode

1 = Copper mode

Port 3 Interface Mode

R/W

0 = Fiber mode

1 = Copper mode

Port 2 Interface Mode

Port 1 Interface Mode

Port 0 Interface Mode

R/W

0 = Fiber mode

1 = Copper mode

0 = Fiber mode

1 = Copper mode

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 105. Link LED Enable ($0x502)

Bit

Name

Description

Type¹

Default

operation of the link LEDs.

0x00000000

0x00000

31:4 Reserved

Reserved

Port 3 link

R/W

Link LED Enable Port 3

0 = No link

1 = Link

Port 2 link

Link LED Enable Port 2

Link LED Enable Port 1

Link LED Enable Port 0

R/W

0 = No link

1 = Link

Port 1 link

0 = No link

1 = Link

Port 0 link

0 = No link

1 = Link

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 106. MAC Soft Reset ($0x505)

Bit

Name

Description

Type¹

Default

0x00000000

0x00000

31:4 Reserved

Reserved

Port 3

R/W

Software Reset MAC 3

0 = Reset inactive

1 = Enable

Port 2

Software Reset MAC 2

Software Reset MAC 1

Software Reset MAC 0

R/W

0 = Reset inactive

1 = Enable

Port 1

0 = Reset inactive

1 = Enable

Port 0

0 = Reset inactive

1 = Enable

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 107. MDIO Soft Reset ($0x506)

Bit

Name

Description

Type¹

Default

0x00000000

31:1 Reserved

Software MDIO Reset

Reserved

0 = Reset inactive

1 = Reset active

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 108. CPU Interface ($0x508)

Bit

Name

Description

Type¹

Default

the CPU interface to allow for various CPUs to be connected to the IXF1104.

0x00000000

0x00

31:25 Reserved

Reserved

R/W

Reserved in Little Endian

Valid in Big endian

CPU Endian

0x000000

0 = Little Endian

1 = Big Endian

23:1 Reserved

Reserved

Reserved in Big Endian

Valid in Little Endian

CPU Endian Control

R/W

0 = Little Endian

1 = Big Endian

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

NOTE: Since the Endianess of the bus is unknown when writing to this register, write 0x01000001 to set the

bit and 0x0 to clear it.

Table 109. LED Control ($0x509)

Bit

Name

Description

Type¹

Default

0x00000000

31:2 Reserved

Reserved

0 = Disable LED Block

1 = Enable LED Block

LED Enable

R/W

0 = Enable LED Mode 0 for use with SGS

Thomson M5450 LED driver (Default)

1 = LED Mode 1 for use with Standard Octal Shift

LED Control

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 110. LED Flash Rate ($0x50A)

Bit

Name

Description

Type¹

Default

0x00000000

31:3 Reserved

Reserved

000 =100 ms flash rate

001 =200 ms flash rate

010 =300 ms flash rate

011 = 400 ms flash rate

100 = 500 ms flash rate

101 = Reserved

LED Flash Rate

Control

2:0

R/W

000

110 = Reserved

111 = Reserved

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 111. LED Fault Disable ($0x50B)

Bit

Name

Description

Type¹

Default

faults.

0x00000000

0x0000000

31:4 Reserved

Reserved

Port 3

LED Port 3 Fault

R/W

0 = Fault enabled

1 = Fault disabled

Control

Port 2

LED Port 2 Fault

Control

R/W

0 = Fault enabled

1 = Fault disabled

Port 1

LED Port 1 Fault

Control

0 = Fault enabled

1 = Fault disabled

Port 0

LED Port 0 Fault

Control

0 = Fault enabled

1 = Fault disabled

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 112. JTAG ID ($0x50C)

Bit

Name

Description

Type¹

Default

identification register found in the IEEE 1149.1 specification. The upper four bits correspond to

silicon stepping. The next 16 bits store a Part ID Number. The next 11 bits contain a JEDEC

manufacturer ID. Bit zero = 1 if the chip is the first in a stack. The encoding scheme used for

the Product ID field is implementation-dependent.

0x10450013

0001²

31:28 Version

27:12 Part ID

Version

Part ID

0000010001

010000

JEDEC Continuation

11:8

JEDEC Continuation Characters

0000

Characters

JEDEC ID

Fixed

7:1

JEDEC ID

Fixed

0001001

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

2. These bits vary with stepping.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.6

RX FIFO Register Overview

T a ble 113 through T a ble 131 provide an overview of the RX FIFO registers, which include the RX

FIFO High and Low watermarks.

Table 113. RX FIFO High Watermark Port 0 ($0x580)

Bit

Name

Description

Type¹

Default

equates to 1840 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO exceeds the high watermark, flow control is

automatically initiated within the MAC to avoid an overflow condition.

0x0E6

31:12 Reserved

Reserved

0x00000

0x0E6

The high water mark value.

RX FIFO High

Watermark Port 0

11: 0

R/W

NOTE: Must be greater than the RX FIFO Low

Watermark and RX FIFO transfer threshold.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 114. RX FIFO High Watermark Port 1 ($0x581)

Bit

Name

Description

Type¹

Default

equates to 1840 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO exceeds the high watermark, flow control is

automatically initiated within the MAC to avoid an overflow condition.

0x0E6

31:12 Reserved

Reserved

0x00000

0x0E6

The high water mark value.

RX FIFO High

Watermark Port 1

11: 0

R/W

NOTE: Must be greater than the RX FIFO Low

Watermark and RX FIFO transfer threshold.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 115. RX FIFO High Watermark Port 2 ($0x582)

Bit

Name

Description

Type¹

Default

equates to 1840 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO exceeds the high watermark, flow control is

automatically initiated within the MAC to avoid an overflow condition.

0x0E6

31:12 Reserved

Reserved

0x00000

0x0E6

The high water mark value.

RX FIFO High

Watermark Port 2

11: 0

R/W

NOTE: Must be greater than the RX FIFO Low

Watermark and RX FIFO transfer threshold.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 116. RX FIFO High Watermark Port 3 ($0x583)

Bit

Name

Description

Type¹

Default

equates to 1840 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO exceeds the high watermark, flow control is

automatically initiated within the MAC to avoid an overflow condition.

0x0E6

31:12 Reserved

Reserved

0x00000

0x0E6

The high water mark value.

RX FIFO High

Watermark Port 3

11: 0

R/W

NOTE: Must be greater than the RX FIFO Low

Watermark and RX FIFO transfer threshold.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 117. RX FIFO Low Watermark Port 0 ($0x58A)

Bit

Name

Description

Type¹

Default

equates to 912 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO falls below the Low Watermark, flow control is

automatically de-asserted within the MAC to allow more line-side data to be captured by the

RX FIFO.

0x072

31:12 Reserved

Reserved

0x00000

0x072

The High Watermark value

NOTE: Should never be greater or equal to the

High Watermark.

RX FIFO Low

Watermark Port 0

11: 0

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 118. RX FIFO Low Watermark Port 1 ($0x58B)

Bit

Name

Description

Type¹

Default

equates to 912 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO falls below the Low Watermark, flow control is

automatically de-asserted within the MAC to allow more line-side data to be captured by the

RX FIFO.

0x072

31:12 Reserved

Reserved

0x00000

0x072

The High Watermark value

NOTE: Should never be greater or equal to the

High Watermark.

RX FIFO Low

Watermark Port 1

11: 0

R/W

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 119. RX FIFO Low Watermark Port 2 ($0x58C)

Bit

Name

Description

Type¹

Default

equates to 912 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO falls below the Low Watermark, flow control is

automatically de-asserted within the MAC to allow more line-side data to be captured by the

RX FIFO.

0x072

31:12 Reserved

Reserved

0x00000

0x072

The High Watermark value

NOTE: Should never be greater or equal to the

RX FIFO Low

Watermark Port 2

11: 0

R/W

High Watermark.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 120. RX FIFO Low Watermark Port 3 ($0x58D)

Bit

Name

Description

Type¹

Default

equates to 912 bytes of data. A unit entry in this register equates to 8 bytes of data. When the

amount of data stored in the RX FIFO falls below the Low watermark, flow control is

automatically de-asserted within the MAC to allow more line-side data to be captured by the

RX FIFO.

0x072

31:12 Reserved

Reserved

0x00000

0x072

The High watermark value

RX FIFO Low

Watermark Port 3

11: 0

R/W

NOTE: Should never be greater or equal to the

High Watermark.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 121. RX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x594 – 0x597)

Name

Description

Address

Type¹

Default

RX FIFO Overflow When RX FIFO on port 0 becomes full or

Frame Drop

Counter on port 0

reset, the number of frames lost/dropped on

this port are shown in this register.

0x594

0x00000000

RX FIFO Overflow When RX FIFO on port 1 becomes full or

Frame Drop

reset, the number of frames lost/dropped on

0x595

0x596

0x597

0x00000000

Counter on port 1

this port are shown in this register.

RX FIFO Overflow When RX FIFO on port 2 becomes full or

Frame Drop

Counter on port 2

reset, the number of frames lost/dropped on

this port are shown in this register.

RX FIFO Overflow When RX FIFO on port 3 becomes full or

Frame Drop

reset, the number of frames lost/dropped on

Counter on port 3

this port are shown in this register.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 122. RX FIFO Port Reset ($0x59E)

Bit

Name

Description

Type¹

Default

position in the register. To make the reset active, the bit must be set High. For example, reset

of port 1 implies register value = 0000_0018. Setting the bit to 0 de-asserts the reset.

0x00000000

0x0000000

31:4 Reserved

Reserved

Port 3

Reset RX FIFO for

R/W

0 = De-assert reset

1 = Reset

Port 3

Port 2

Reset RX FIFO for

Port 2

R/W

0 = De-assert reset

1 = Reset

Port 1

Reset RX FIFO for

Port 1

0 = De-assert reset

1 = Reset

Port 0

Reset RX FIFO for

Port 0

0 = De-assert reset

1 = Reset

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 123. RX FIFO Errored Frame Drop Enable ($0x59F)

Bit

Name

Description

Type¹

Default

NOTE: Jumbo packets are not dropped.

0x00000000

0x0000000

31:4 Reserved

Reserved

This bit is used in conjunction with MAC filter bits.

This allows the user to select whether the errored

packets are to be dropped or not.

RX FIFO Errored

Frame Drop Enable

Port 3

R/W

1 = Frame Drop Enable

0 = Frame Drop Disable

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 123. RX FIFO Errored Frame Drop Enable ($0x59F)

Bit

Name

Description

Type¹

Default

This bit is used in conjunction with MAC filter bits.

This allows the user to select whether the errored

packets are to be dropped or not.

RX FIFO Errored

Frame Drop Enable

Port 2

R/W

1 = Frame Drop Enable

0 = Frame Drop Disable

This bit is used in conjunction with MAC filter bits.

This allows the user to select whether the errored

packets are to be dropped or not.

RX FIFO Errored

Frame Drop Enable

Port 1

R/W

1 = Frame Drop Enable

0 = Frame Drop Disable

This bit is used in conjunction with MAC filter bits.

This allows the user to select whether the errored

packets are to be dropped or not.

RX FIFO Errored

Frame Drop Enable

Port 0

1 = Frame Drop Enable

0 = Frame Drop Disable

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 124. RX FIFO Overflow Event ($0x5A0)

Bit

Name

Description

Type¹

Default

example, a FIFO overflow). The bit position equals the port number. This register is cleared on 0x00000000

Read.

31:4 Reserved

Reserved

0x0000000

Port 3

RX FIFO Overflow

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

Event on Port 3

Port 2

RX FIFO Overflow

Event on Port 2

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

Port 1

RX FIFO Overflow

Event on Port 1

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

Port 0

RX FIFO Overflow

Event on Port 0

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 125. RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2 - 0x5A5) (Sheet 1 of 2)

Name

Description

Address

Type

Default

This register counts all frames dropped from the

RX FIFO for port 0 by meeting one of the

following conditions:

• Frames are removed in conjunction

0x19)”.

RX FIFO Errored

Frame Drop Counter

on Port 0

0x5A2

0x00000000

• Frames are greater than the “Max

0x0F)”.

This register is cleared on Read.

This register counts all frames dropped from the

RX FIFO for port 1 by meeting one of the

following conditions:

• Frames are removed in conjunction

0x19)”.

RX FIFO Errored

Frame Drop Counter

on Port 1

0x5A3

0x00000000

• Frames are greater than the “Max

0x0F)”.

This register is cleared on Read.

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Table 125. RX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x5A2 - 0x5A5) (Sheet 2 of 2)

Name

Description

Address

Type

Default

This register counts all frames dropped from the

RX FIFO for port 2 by meeting one of the

following conditions:

• Frames are removed in conjunction

0x19)”.

RX FIFO Errored

Frame Drop Counter

on Port 2

0x5A4

0x00000000

• Frames are greater than the “Max

0x0F)”.

This register is cleared on Read.

This register counts all frames dropped from the

RX FIFO for port 3 by meeting one of the

following conditions:

• Frames are removed in conjunction

0x19)”.

RX FIFO Errored

Frame Drop Counter

on Port 3

0x5A5

0x00000000

• Frames are greater than the “Max

T a ble 149 through Table 152 “Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)” on

0x0F)”.

This register is cleared on Read.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

Table 126. RX FIFO SPI3 Loopback Enable for Ports 0 - 3 ($0x5B2)

Bit

Name

Description

Type¹

Default

into the TX FIFO, creating a SPI3 loopback.

0x00000000

0x00000

0x0

31:12 Reserved

Reserved

SPI3 loopback enable

for Port 3

0 = Disabled

1 = Enabled

R/W

SPI3 loopback enable

for Port 2

0 = Disabled

1 = Enabled

R/W

0x0

SPI3 loopback enable

for Port 1

0 = Disabled

1 = Enabled

SPI3 loopback enable

for Port 0

0 = Disabled

1 = Enabled

R/W

0x0

7:0

Reserved

Write as 0, ignore on Read.

0x00

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 127. RX FIFO Padding and CRC Strip Enable ($0x5B3)

Bit

Name

Description

Type¹

Default

bytes and also enables the CRC stripping of a packet.

0x00000000

0x000000

31:8 Reserved

Reserved

CRC stripping is enabled for Port 3.

CRC Stripping Enable

for Port 3

R/W

0 = Disabled

1 = Enabled

CRC stripping is enabled for Port 2.

CRC Stripping Enable

for Port 2

R/W

0 = Disabled

1 = Enabled

CRC stripping is enabled for Port 1.

CRC Stripping Enable

for Port 1

0 = Disabled

1 = Enabled

CRC stripping is enabled for Port 0.

CRC Stripping Enable

for Port 0

0 = Pre-pending Disabled

1 = Pre-pending Enabled

Enables pre-pending of two bytes at the start of

every packet – Port 3.

Pre-pending Enable²

Port 3

R/W

0 = Disabled

1 = Enabled

Enables pre-pending of two bytes at the start of

every packet – Port 2.

Pre-pending Enable²

Port 2

0 = Disabled

1 = Enabled

Enables pre-pending of two bytes at the start of

every packet – Port 1.

Pre-pending Enable²

Port 1

0 = Disabled

1 = Enabled

Enables pre-pending of two bytes at the start of

every packet – Port 0.

Pre-pending Enable²

Port 0

0 = Disabled

1 = Enabled

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

2. Pre-pending should not be enabled in loopback mode.

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 128. RX FIFO Transfer Threshold Port 0 ($0x5B8)

Bit

Name

Description

Type

Default

0x000000BE

0x00000

31:12 Reserved

Reserved

RX FIFO transfer threshold for port 0. This must

be less than the RX FIFO High water mark.

User definable control register that sets the

threshold where a packet starts transitioning to the

SPI3 interface from the RX FIFO before the EOP

is received. Packets received in the RX FIFO

below this threshold are treated as store and

forward.

RX FIFO Transfer

Threshold - Port 0

11:0

R/W

0x0BE

NOTE: Do not program the RX FIFO transfer

threshold below a setting of 0xBE

(1520bytes).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 129. RX FIFO Transfer Threshold Port 1 ($0x5B9)

Bit

Name

Description

Type

Default

0x000000BE

0x00000

31:12 Reserved

Reserved

RX FIFO transfer threshold for port 1. This must

be less than the RX FIFO High watermark.

User definable control register that sets the

threshold where a packet starts transitioning to

the SPI3 interface from the RX FIFO before the

EOP is received. Packets received in the RX

FIFO below this threshold are treated as store

and forward.

RX FIFO Transfer

Threshold - Port 1

11:0

R/W

0x0BE

NOTE: Do not program the RX FIFO transfer

threshold below a setting of 0xBE

(1520bytes).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 130. RX FIFO Transfer Threshold Port 2 ($0x5BA)

Bit

Name

Description

Type

Default

0x000000BE

0x00000

31:12 Reserved

Reserved

RX FIFO transfer threshold for port 2. This must be

less than the RX FIFO High water mark.

User definable control register that sets the

threshold where a packet starts transitioning to the

SPI3 interface from the RX FIFO before the EOP is

received. Packets received in the RX FIFO below

this threshold are treated as store and forward.

NOTE: Do not program the RX FIFO transfer

threshold below a setting of 0xBE

RX FIFO Transfer

Threshold - Port 2

11:0

R/W

0x0BE

(1520bytes).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 131. RX FIFO Transfer Threshold Port 3 ($0x5BB)

Bit

Name

Description

Type

Default

0x000000BE

0x00000

31:12

11:0

Reserved

RX FIFO transfer threshold for port 3. This must

be less than the RX FIFO High water mark.

User definable control register that sets the

threshold where a packet starts transitioning to the

SPI3 interface from the RX FIFO before the EOP

is received. Packets received in the RX FIFO

below this threshold are treated as store and

forward.

RX FIFO Transfer

Threshold - Port 3

R/W

0x0BE

NOTE: Do not program the RX FIFO transfer

threshold below a setting of 0xBE

(1520bytes).

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.7

TX FIFO Register Overview

T a ble 132 through Table 139 provide an overview of the TX FIFO registers, which include the TX

FIFO High and Low watermark.

Table 132. TX FIFO High Watermark Ports 0 - 3 ($0x600 – 0x603)

Name

Description

Address

Type¹

Default

High watermark for TX FIFO Port 0. The

default value of 0x3E0 represents 992 8-byte

locations. This equates to 7936 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO exceeds the high watermark, flow control

is automatically initiated on the SPI3 interface to

request that the switch fabric stops data

TX FIFO High

Watermark Port 0

0x600

R/W

0x000003E0

transfers to avoid an overflow condition.

High watermark for TX FIFO Port 1. The

default value of 0x3E0 represents 992 8-byte

locations. This equates to 7936 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO exceeds the high watermark, flow control

is automatically initiated on the SPI3 interface to

request that the switch fabric stops data

TX FIFO High

Watermark Port 1

0x601

0x602

0x603

R/W

0x000003E0

transfers to avoid an overflow condition.

High watermark for TX FIFO Port 2. The

default value of 0x3E0 represents 992 8-byte

locations. This equates to 7936 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO exceeds the high watermark, flow control

is automatically initiated on the SPI3 interface to

request that the switch fabric stops data

TX FIFO High

Watermark Port 2

transfers to avoid an overflow condition.

High watermark for TX FIFO Port 3. The

default value of 0x3E0 represents 992 8-byte

locations. This equates to 7936 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO exceeds the high watermark, flow control

is automatically initiated on the SPI3 interface to

request that the switch fabric stops data

TX FIFO High

Watermark Port 3

transfers to avoid an overflow condition.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 133. TX FIFO Low Watermark Register Ports 0 - 3 ($0x60A – 0x60D)

Name

Description

Address

Type¹

Default

Low watermark for TX FIFO Port 0. The

default value of 0x0D0 represents 208 8-byte

locations. This equates to 1664 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO falls below the low watermark, flow control

is automatically de-asserted on the SPI3

interface to allow further data to be sent by the

switch fabric to the IXF1104.

TX FIFO Low

Watermark Port 0

0x60A

R/W

0x000000D0

Low watermark for TX FIFO Port 1. The

default value of 0x0D0 represents 208 8-byte

locations. This equates to 1664 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO falls below the low watermark, flow control

is automatically de-asserted on the SPI3

interface to allow further data to be sent by the

switch fabric to the IXF1104.

TX FIFO Low

Watermark Port 1

0x60B

0x60C

0x60D

R/W

0x000000D0

Low watermark for TX FIFO Port 2. The

default value of 0x0D0 represents 208 8-byte

locations. This equates to 1664 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO falls below the low watermark, flow control

is automatically de-asserted on the SPI3

interface to allow further data to be sent by the

switch fabric to the IXF1104.

TX FIFO Low

Watermark Port 2

Low watermark for TX FIFO Port 3. The

default value of 0x0D0 represents 208 8-byte

locations. This equates to 1664 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO falls below the low watermark, flow control

is automatically de-asserted on the SPI3

interface to allow further data to be sent by the

switch fabric to the IXF1104.

TX FIFO Low

Watermark Port 3

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 134. TX FIFO MAC Threshold Register Ports 0 - 3 ($0x614 – 0x617)

Name

Description

Address

Type¹

Default

MAC threshold for TX FIFO Port 0. The

default value of 0x1BE represents 446 8-byte

locations. This equates to 3568 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

FIFO reaches this threshold, data is forwarded

TX FIFO MAC

0x614

R/W

0x000001BE

Threshold Port 0 to the MAC core and line-side interfaces for

onward transmission. By setting the threshold to

an appropriate value, the user can configure the

TX FIFO to operate in a “cut-through” mode

rather than the default “store and forward”

operation mode.

MAC threshold for TX FIFO Port 1. The

default value of 0x1BE represents 446 8-byte

locations. This equates to 3568 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

TX FIFO MAC

FIFO reaches this threshold, data is forwarded

0x615

0x616

0x617

R/W

0x000001BE

Threshold Port 1 to the MAC core and line-side interfaces for

onward transmission. By setting the threshold to

an appropriate value, the user can configure the

TX FIFO to operate in a “cut-through” mode

rather than the default “store and forward”

operation mode.

MAC threshold for TX FIFO Port 2. The

default value of 0x1BE represents 446 8-byte

locations. This equates to 3568 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

TX FIFO MAC

FIFO reaches this threshold, data is forwarded

Threshold Port 2 to the MAC core and line-side interfaces for

onward transmission. By setting the threshold to

an appropriate value, the user can configure the

TX FIFO to operate in a “cut-through” mode

rather than the default “store and forward”

operation mode.

MAC threshold for TX FIFO Port 3. The

default value of 0x1BE represents 446 8-byte

locations. This equates to 3568 bytes of data. A

unit entry in this register equates to 8 bytes of

data. When the amount of data stored in the TX

TX FIFO MAC

FIFO reaches this threshold, data is forwarded

Threshold Port 3 to the MAC core and line-side interfaces for

onward transmission. By setting the threshold to

an appropriate value, the user can configure the

TX FIFO to operate in a “cut-through” mode

rather than the default “store and forward”

operation mode.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 135. TX FIFO Overflow/Underflow/Out of Sequence Event ($0x61E) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

These register bits provide status information, and indicate if out-of-sequence data has been

received. The bit position equals the port number + 8. These bits are cleared on Read.

0x0

This register provides a status that a FIFO Empty situation has occurred (for example, a FIFO

under-run). The bit position equals the port number + 4. This register is cleared on Read.

0x0

This register provides a status that a FIFO full situation has occurred (for example, a FIFO

overflow). The bit position equals the port number. This register is cleared on Read.

0x0

31:12 Reserved

Reserved

0x00000

Port 3

FOSE3

FOSE2

FOSE1

FOSE0

FUE3

0 = FIFO out of sequence event did not occur

1 = FIFO out of sequence event occurred

Port 2

0 = FIFO out of sequence event did not occur

1 = FIFO out of sequence event occurred

Port 1

0 = FIFO out of sequence event did not occur

1 = FIFO out of sequence event occurred

Port 0

0 = FIFO out of sequence event did not occur

1 = FIFO out of sequence event occurred

Port 3

0 = FIFO underflow event did not occur

1 = FIFO underflow event occurred

Port 2

FUE2

0 = FIFO underflow event did not occur

1 = FIFO underflow event occurred

Port 1

FUE1

0 = FIFO underflow event did not occur

1 = FIFO underflow event occurred

Port 0

FUE0

0 = FIFO underflow event did not occur

1 = FIFO underflow event occurred

Port 3

FOE3

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 135. TX FIFO Overflow/Underflow/Out of Sequence Event ($0x61E) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

Port 2

FOE2

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

Port 1

FOE1

FOE0

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

Port 0

0 = FIFO overflow event did not occur

1 = FIFO overflow event occurred

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 136. Loop RX Data to TX FIFO (Line-Side Loopback) Ports 0 - 3 ($0x61F)

Bit

Name

Description

Type¹

Default

through the MAC to be sent to the TX FIFO and back to the line-side transmit interface.

0x00000000

0x0000000

31:4 Reserved

Reserved

Port 3 Line-Side

Loopback

0 = Disable line-side loopback

1 = Enable line-side loopback

R/W

Port 2 Line-Side

Loopback

0 = Disable line-side loopback

1 = Enable line-side loopback

R/W

Port 1 Line-Side

Loopback

0 = Disable line-side loopback

1 = Enable line-side loopback

Port 0 Line-Side

Loopback

0 = Disable line-side loopback

1 = Enable line-side loopback

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 137. TX FIFO Port Reset ($0x620) (Sheet 1 of 2)

Bit

Name

Description

Type¹

Default

position in the register. To make the port active, the bit must be set to Low. (For example, reset

of Port 3 implies register value = 1000, setting the bit to 1 asserts the port reset).

0x00000000

0x0000000

31:4 Reserved

Reserved

Port 3

Port 3 Reset

R/W

0 = De-assert Reset

1 = Assert Reset

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 137. TX FIFO Port Reset ($0x620) (Sheet 2 of 2)

Bit

Name

Description

Type¹

Default

Port 2

Port 2 Reset

R/W

0 = De-assert Reset

1 = Assert Reset

Port 1

Port 1 Reset

Port 0 Reset

R/W

0 = De-assert Reset

1 = Assert Reset

Port 0

0 = De-assert Reset

1 = Assert Reset

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 138. TX FIFO Overflow Frame Drop Counter Ports 0 - 3 ($0x621 – 0x624)

Name

Description

Address

Type^*

Default

When TX FIFO on Port 0 becomes full or

reset, the number of frames lost or removed

on this port is shown in this register. This

TX FIFO overflow

frame drop counter

on Port 0

0x621

0x00000000

When TX FIFO on Port 1 becomes full or

reset, the number of frames lost or removed

on this port is shown in this register. This

TX FIFO overflow

frame drop counter

on Port 1

0x622

0x623

0x624

0x00000000

When TX FIFO on Port 2 becomes full or

reset, the number of frames lost or removed

on this port is shown in this register. This

TX FIFO overflow

frame drop counter

on Port 2

When TX FIFO on Port 3 becomes full or

reset, the number of frames lost or removed

on this port is shown in this register. This

TX FIFO overflow

frame drop counter

on Port 3

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 139. TX FIFO Errored Frame Drop Counter Ports 0 - 3 ($0x625 – 0x629)

Name

Description

Address

Type^*

Default

This register provides the number of packets

dropped by the TX FIFO due to the following:

Data Parity Errors

Short SOPs (two consecutive SOPs for a port

with no EOP)

TX FIFO errored

frame drop counter

on Port 0

0x625

0x00000000

Small Packets (9-14 bytes)

Frames received that are signaled with TERR

on the SPI3 TX interface.

NOTE: This register is cleared on Read.

This register provides the number of packets

dropped by the TX FIFO due to the following:

Data Parity Errors

Short SOPs (two consecutive SOPs for a port

with no EOP)

TX FIFO errored

frame drop counter

on Port 1

0x626

0x627

0x628

0x00000000

Small Packets (9-14 bytes)

Frames received that are signaled with TERR

on the SPI3 TX interface.

NOTE: This register is cleared on Read.

This register provides the number of packets

dropped by the TX FIFO due to the following:

Data Parity Errors

Short SOPs (two consecutive SOPs for a port

with no EOP)

TX FIFO errored

frame drop counter

on Port 2

Small Packets (9-14 bytes)

Frames received that are signaled with TERR

on the SPI3 TX interface.

NOTE: This register is cleared on Read.

This register provides the number of packets

dropped by the TX FIFO due to the following:

Data Parity Errors

Short SOPs (two consecutive SOPs for a port

with no EOP)

TX FIFO errored

frame drop counter

on Port 3

Small Packets (9-14 bytes)

Frames received that are signaled with TERR

on the SPI3 TX interface.

NOTE: This register is cleared on Read.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 140. TX FIFO Occupancy Counter for Ports 0 - 3 ($0x62D – 0x630)

Name

Description

Address

Type

Default

Occupancy for Tx

FIFO Port 0

This register gives the Occupancy for TX FIFO

Port 0. This is a Read only register

0x62D

0x00000000

Occupancy for Tx

FIFO Port 1

This register gives the Occupancy for TX FIFO

Port 1. This is a Read only register

0x62E

0x62F

0x630

0x00000000

Occupancy for Tx

FIFO Port 2

This register gives the Occupancy for TX FIFO

Port 2. This is a Read only register

Occupancy for Tx

FIFO Port 3

This register gives the Occupancy for TX FIFO

Port 3. This is a Read only register

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 141. TX FIFO Port Drop Enable ($0x63D)

Bit

Name

Description

Type

Default

packets.

0x0000000f

0x000000

31:4

Reserved

0 = Disable the TXFIFO from dropping erroneous packets

1 = Enable the TXFIFO to drop erroneous packets

Port 3 Drop

R/W

0 = Disable the TXFIFO from dropping erroneous packets

1 = Enable the TXFIFO to drop erroneous packets

Port 2 Drop

Port 1 Drop

Port 0 Drop

R/W

0 = Disable the TXFIFO from dropping erroneous packets

1 = Enable the TXFIFO to drop erroneous packets

0 = Disable the TXFIFO from dropping erroneous packets

1 = Enable the TXFIFO to drop erroneous packets

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No clear;

R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.8

MDIO Register Overview

T a ble 142 through T a ble 145 provide an overview of the MDIO registers.

Table 142. MDIO Single Command ($0x680)

Bit

Name

Description

Type¹

Default

accesses to the external PHY for ports that are configured in copper mode.

0x00010000

31:21 Reserved

Reserved

R/W

00000000000

Performs the MDIO operation. Cleared when

done.

MDIO Command

0 = MDIO ready, operation complete

1 = Perform operation

19:18 Reserved

Reserved

MDIO Op Code; two bits identify operation to be

performed:

00 =Reserved

01 =Write operation (as defined in IEEE 802.3,

clause 22.2.4.5)

17:16 OP Code

R/W

10 =Read operation (as defined in IEEE 802.3,

clause 22.2.4.5)

11 = Reserved

Reserved

15:10 Reserved

R/W

000000

Sets bits 1:0 of the external PHY address. Bits 4:2

of the PHY address are fixed at 000.

9:8

7:5

4:0

PHY Address

Reserved

000

Five-bit address to one among 32 registers in an

addressed PHY device.

REG Address

R/W

00000

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 143. MDIO Single Read and Write Data ($0x681)

Bit

Name

Description

Type¹

Default

0x00000000

0x0000

31:16 MDIO Read Data

15:0 MDIO Write Data

MDIO Read data from external device.

MDIO Write data from external device.

R/W

0x0000

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 144. Autoscan PHY Address Enable ($0x682)

Bit

Name

Description

Type¹

Default

PHY address.

0x00000000

0 = Disable the PHY address

1 = Enable the PHY address

NOTE: Autoscan is only applicable for the ports in copper mode.

31:4 Reserved

Reserved

0x0000000

1111

Autoscan PHY address enable

Autoscan PHY

Address

3:0

R/W

0 = Disable address

1 = Enable address

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 145. MDIO Control ($0x683)

Bit

Name

Description

Type¹

Default

0x00000000

0x000

31:4 Reserved

Reserved

MDIO progress. This bit reflects the status of

MDIO transaction

MDIO in Progress

0 = MDIO Single command not in progress

1 = MDIO Single Command in progress

Enables the MDIO in progress bit

MDIO in Progress

Enable

R/W

0 = Disable MDIO in progress register bit

1 = Enable MDIO in progress register bit

Autoscan enable

Autoscan Enable

MDC Speed

0 = Disable Autoscan

1 = Enable Autoscan

MDC speed

0 = MDC runs at 2.5 MHz

1 = MDC runs at 18 MHz

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.9

SPI3 Register Overview

T a ble 146 through T a ble 148 “Address Parity Error Packet Drop Counter ($0x70A)” on page 218

provide an overview of the SPI3 registers.

Table 146. SPI3 Transmit and Global Configuration ($0x700) (Sheet 1 of 3)

Bit

Name

Description

Type¹

Default

and Global configuration (4 x 8 mode).

0x0020000F

31:24 Reserved

Reserved

0x00

SPI3 Transmitter Soft

1 = The SPI3 TX block is reset.

R/W

Reset

SPI3 Receiver Soft

Reset

1 = The SPI3 RX block is reset.

R/W

0 = Indicates that SPI3 block operates in 32-bit

MPHY mode.

1 = Indicates that the SPI3 block operates in 4 x 8

SPHY mode.

SPHY/MPHY Mode

Tx_ad_prtyer_drop

R/W

This configuration affects both the SPI3 transmitter

and receiver functionality.

Indicates whether to drop packets received with

parity error during the address selection phase

(Tsx and nTenb High) should be dropped.

0 = Do not drop packets with address parity error

1 = Drop packets with address parity error

R/W

This is applicable only in MPHY mode of

operation. This bit is ignored in SPHY (4 x 8) mode

as there will be no address selection.

SPHY/MPHY Mode:

Indicates whether to drop packets with data parity

error for port 3.

Dat_prtyer_drp Port 3

Dat_prtyer_drp Port 2

Dat_prtyer_drp Port 1

R/W

0x0

0 = Do not drop packets with data parity error

(default)

1 = Drop packets with data parity error

SPHY/MPHY Mode:

Indicates whether to drop packets with data parity

error for port 2.

0 = Do not drop packets with data parity error

(default)

1 = Drop packets with data parity error

SPHY/MPHY Mode:

Indicates whether to drop packets with data parity

error for port 1.

0 = Do not drop packets with data parity error

(default)

1 = Drop packets with data parity error

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 146. SPI3 Transmit and Global Configuration ($0x700) (Sheet 2 of 3)

Bit

Name

Description

Type¹

Default

SPHY/MPHY Mode:

Indicates whether to drop packets with data parity

error for port 0.

Dat_prtyer_drp Port 0

R/W

0 = Do not drop packets with data parity error

(default)

1 = Drop packets with data parity error

15:8 Reserved

Write as 0, ignore on Read.

00000000

SPHY Mode:

Indicates the parity sense to check the parity on

TDAT bus for port 3.

Tx_parity_sense Port 3 0 = Odd Parity

R/W

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

TDAT bus for port 2.

Tx_parity_sense Port 2 0 = Odd Parity

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

TDAT bus for port 1.

Tx_parity_sense Port 1 0 = Odd Parity

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

TDAT bus for port 0.

0 = Odd Parity

1 = Even Parity

Tx_parity_sense Port 0

R/W

MPHY Mode:

Indicates the parity sense to check the parity on

TDAT bus for all ports.

0 = Odd Parity

1 = Even Parity

SPHY Mode:

0 = Disables the selected SPI3TX port 3.

1 = Enables the selected SPI3 TX port 3.

Tx_port_enable Port 3

R/W

MPHY Mode:

0 = Disables the selected SPI3 TX port 3.

1 = Enables the selected SPI3 TX port 3.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 146. SPI3 Transmit and Global Configuration ($0x700) (Sheet 3 of 3)

Bit

Name

Description

Type¹

Default

SPHY Mode:

0 = Disables the selected SPI3 TX port 2

1 = Enables the selected SPI3 TX port 2

Tx_port_enable Port 2

R/W

MPHY Mode:

0 = Disables the selected SPI3 TX port 2

1 = Enables the selected SPI3 TX port 2

SPHY Mode:

0 = Disables the selected SPI3 TX port 1

1 = Enables the selected SPI3 TX port 1

Tx_port_enable Port 1

Tx_port_enable Port 0

R/W

MPHY Mode:

0 = Disables the selected SPI3 TX port 1

1 = Enables the selected SPI3 TX port 1

SPHY Mode:

0 = Disables the selected SPI3 TX port 0

1 = Enables the selected SPI3 TX port 0

MPHY Mode:

0 = Disables the selected SPI3 TX port 0

1 = Enables the selected SPI3 TX port 0

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 147. SPI3 Receive Configuration ($0x701)

Bit

Name

Description

Type¹

Default

0x00000F80

0x0

31:28 Reserved

Reserved

SPHY Mode:

Indicates the number of pause cycles to be

introduced between back-to-back transfers for

port 3.

B2B_PAUSE Port 3

R/W

0 = Zero pause cycles

1 = Two pause cycles

MPHY Mode:

SPHY Mode:

Indicates the number of pause cycles to be

introduced between back-to-back transfers for

port 2.

B2B_PAUSE Port 2

R/W

0 = Zero pause cycles

1 = Two pause cycles

MPHY Mode:

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 147. SPI3 Receive Configuration ($0x701) (Continued)

Bit

Name

Description

Type¹

Default

SPHY Mode:

Indicates the number of pause cycles to be

introduced between back-to-back transfers for

port 1.

B2B_PAUSE Port 1

R/W

0 = Zero pause cycles

1 = Two pause cycles

MPHY Mode:

SPHY Mode:

Indicates the number of pause cycles to be

introduced between back-to-back transfers for

port 0.

0 = Zero pause cycles

1 = Two pause cycles

B2B_PAUSE Port 0

R/W

MPHY Mode:

Indicates the number of pause cycles to be

introduced between back-to-back transfers for all

ports.

0 = Zero pause cycles

1 = Two pause cycles

SPHY Mode:

Selects the maximum burst size on the RX path

for port 3.

0x = 64 bytes maximum burst size

10 = 128 bytes maximum burst size

11 = 256 bytes maximum burst size

MPHY Mode:

23:22 RX_BURST Port 3

21:20 RX_BURST Port 2

19:18 RX_BURST Port 1

R/W

0x0

SPHY Mode:

Selects the maximum burst size on the RX path

for port 2.

0x = 64 bytes maximum burst size

10 = 128 bytes maximum burst size

11 = 256 bytes maximum burst size

MPHY Mode:

SPHY Mode:

Selects the maximum burst size on the RX path

for port 1.

0x = 64 bytes maximum burst size

10 = 128 bytes maximum burst size

11 = 256 bytes maximum burst size

MPHY Mode:

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 147. SPI3 Receive Configuration ($0x701) (Continued)

Bit

Name

Description

Type¹

Default

SPHY Mode:

Selects the maximum burst size on the RX path

for port 0.

0x = 64 bytes maximum burst size

10 = 128 bytes maximum burst size

11 = 256 bytes maximum burst size

MPHY Mode:

17:16 RX_BURST Port 0

R/W

0x0

Selects the maximum burst size on the RX path

for all ports.

0x = 64 bytes maximum burst size

10 = 128 bytes maximum burst size

11 = 256 bytes maximum burst size

SPHY Mode:

Indicates the parity sense to check the parity on

RDAT bus for port 3.

Rx_parity_sense Port 3 0 = Odd Parity

R/W

0x0

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

RDAT bus for port 2.

Rx_parity_sense Port 2 0 = Odd Parity

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

RDAT bus for port 1.

Rx_parity_sense Port 1 0 = Odd Parity

1 = Even Parity

MPHY Mode:

SPHY Mode:

Indicates the parity sense to check the parity on

RDAT bus for port 0.

0 = Odd Parity

1 = Even Parity

Rx_parity_sense Port 0

R/W

0x0

MPHY Mode:

Indicates the parity sense to check the parity on

RDAT bus for all ports.

0 = Odd Parity

1 = Even Parity

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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Table 147. SPI3 Receive Configuration ($0x701) (Continued)

Bit

Name

Description

Type¹

Default

SPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

Rx_port_enable

Port 3

R/W

0xF

MPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

SPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

Rx_port_enable

Port 2

R/W

0xF

MPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

SPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

Rx_port_enable

Port 1

MPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

SPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

Rx_port_enable

Port 0

MPHY Mode:

0 = Disables the selected SPI3 RX port.

1 = Enables the selected SPI3 RX port.

SPHY Mode:

NA. Write as 1, ignore on Read.

MPHY Mode:

Rx_core_enable

R/W

0x1

0 = Disables the RX SPI3 core.

1 = Enables the RX SPI3 core.

SPHY Mode:

NA. Write as 0, ignore on Read.

MPHY Mode:

6:1

IBA[5:0]

0x00

Sets the 6-bit value appended to the 2-bit

address during the port address selection.

SPHY Mode/MPHY Mode:

Frames marked to be filtered (based on the

settings in the “RX Packet Filter Control ($

Port_Index + 0x19)”) or frames above the “Max

Frame Size (Addr: Port_Index + 0x0F)” that are

not dropped in the RX FIFO (see “RX FIFO

Errored Frame Drop Enable ($0x59F)”can be

optionally indicated with an RERR when sent out

the SPI3 interface.

RERR_enable

R/W

0 = Packets not indicated with RERR.

1 = Packets indicated with RERR.

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 148. Address Parity Error Packet Drop Counter ($0x70A)

Bit

Name

Description

Type¹

Default

detection during the address selection cycle.

0x00000000

0x000000

31:8 Reserved

Reserved

This is an 8-bit counter that counts the number of

packets dropped due to parity error detection

during the address selection cycle. This gets

cleared when read and saturates at 8’hFF. There

is only one counter for address parity drop as

address will be used only in MPHY mode of

operation. The counter gets cleared once the

Address Parity Error

Packet Drop Counter

7:0

0x00

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

8.4.10

SerDes Register Overview

page 220 define the contents of the SerDes registers at base location 0x780, which contain the

control and status for the four SerDes interfaces on the IXF1104.

Table 149. TX Driver Power Level Ports 0 - 3 ($0x784)

Bit

Name

Description

Type

Default

SerDes port. Refer to Section 5.6.2.2, “Transmitter Programmable Driver-Power Levels” on

page 103.

0x0000dddd

31:16

15:12

11:8

7:4

Reserved

0x0000

1101

DRVPWR3[3:0]

DRVPWR2[3:0]

DRVPWR1[3:0]

DRVPWR0[3:0]

Encoded input that sets Power Level for Port 3

Encoded input that sets Power Level for Port 2

Encoded input that sets Power Level for Port 1

Encoded input that sets Power Level for Port 0

R/W

1101

3:0

1101

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 150. TX and RX Power-Down ($0x787)

Bit

Name

Description

Type

Default

ports

0x00000000

31:14

13:10

9:4

Reserved

R/W

0x0000000

0000

TPWRDWN[3:0]

Reserved

TX power-down for Ports 3-0 (1 = Power-down)

Reserved

0x00

3:0

RPWRDWN[3:0]

RX Power-down for Ports 3-0 (1 = Power-down)

R/W

0000

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

Table 151. RX Signal Detect Level Ports 0 - 3 ($0x793)

Bit

Name

Description

Type¹

Default

the signal being received from the line. This register is meant for debug and test use.

0x00000000

0x0000000

31:4 Reserved

Reserved

Signal Detect for Ports 0-3

3:0

SIGDET[3:0]

0x0

0 = Noise

1 = Signal

1. RO = Read Only, No clear on Read; R = Read, Clear on Read; W = Write only; R/W = Read/Write, No

clear; R/W/C = Read/Write, Clear on Write

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IXF1104 4-Port Gigabit Ethernet Media Access Controller

Table 152. Clock and Interface Mode Change Enable Ports 0 - 3 ($0x794)

Bit

Name

Description

Type¹

Default

of the IXF1104 is required. This register ensures that when a change is made that the internal

clocking of the IXF1104 is managed correctly and no unexpected effects of the operational or

speed change are observable on the line interfaces.

0x00000000

0x0000000

31:4 Reserved

Reserved

Enables internal clock generator for Port 3 to

($0x501)".

Clock and Interface

0 = Set to zero when changes are being made to

($0x501)".

Mode Change Enable

R/W

Port 3²

1 = Set to 1 for the configuration changes to take

effect.

Enables internal clock generator for Port 2 to

($0x501)".

Clock and Interface

Mode Change Enable

Port 2²

0 = Set to zero when changes are being made to

($0x501)".

R/W

1 = Set to 1 for the configuration changes to take

effect.

Enables internal clock generator for Port 1 to

($0x501)".

Clock and Interface

Mode Change Enable

Port 1²

0 = Set to zero when changes are being made to

($0x501)".

1 = Set to 1 for the configuration changes to take

effect.

Enables internal clock generator for Port 0 to

($0x501)".

Clock and Interface

Mode Change Enable

Port 0²

0 = Set to zero when changes are being made to