tristan/ZealOS
1
0
Fork 0
mirror of https://github.com/Zeal-Operating-System/ZealOS.git synced 2024-12-29 08:46:31 +00:00
Code Issues Projects Releases Packages Wiki Activity Actions
ZealOS/docs/Home/Net/Drivers/E1000.ZC.html
TomAwezome 48d4f999cb Update documentation.
2021-12-11 06:10:58 -05:00

665 lines
63 KiB
HTML
Executable file
Raw Blame History

<!DOCTYPE HTML>
<html>
<head>
<meta http-equiv="Content-Type" content="text/html;charset=US-ASCII">
<meta name="generator" content="ZealOS V1.07">
<style type="text/css">
body {background-color:#1f1f1f;}
.cF0{color:#e3e3e3;background-color:#1f1f1f;}
.cF1{color:#4f84a6;background-color:#1f1f1f;}
.cF2{color:#73a255;background-color:#1f1f1f;}
.cF3{color:#297582;background-color:#1f1f1f;}
.cF4{color:#b34f4b;background-color:#1f1f1f;}
.cF5{color:#8a52c3;background-color:#1f1f1f;}
.cF6{color:#b7822f;background-color:#1f1f1f;}
.cF7{color:#444444;background-color:#1f1f1f;}
.cF8{color:#6d6d6d;background-color:#1f1f1f;}
.cF9{color:#94bfde;background-color:#1f1f1f;}
.cFA{color:#a1ce97;background-color:#1f1f1f;}
.cFB{color:#6db4be;background-color:#1f1f1f;}
.cFC{color:#e88e88;background-color:#1f1f1f;}
.cFD{color:#ca94e8;background-color:#1f1f1f;}
.cFE{color:#d4b475;background-color:#1f1f1f;}
.cFF{color:#1f1f1f;background-color:#1f1f1f;}
</style>
</head>
<body>
<pre style="font-family:monospace;font-size:12pt">
<a name="l1"></a><span class=cF2>/*</span><span class=cF0> </span><span class=cF2>Intel(R) E1000 Driver</span><span class=cF0>
<a name="l2"></a> </span><span class=cF2>Author: TomAwezome</span><span class=cF0>
<a name="l3"></a>
<a name="l4"></a> </span><span class=cF2>Driver is based on:</span><span class=cF0>
<a name="l5"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>01000101's example i825xx driver</span><span class=cF0>
<a name="l6"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>OSDev Intel(R) 8254x documentation</span><span class=cF0>
<a name="l7"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>Intel(R) PCI/PCI-X Family of Gigabit Ethernet Controllers Software Developer's Manual</span><span class=cF0>
<a name="l8"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>Linux E1000 driver</span><span class=cF0>
<a name="l9"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>any other useful sources.</span><span class=cF0>
<a name="l10"></a>
<a name="l11"></a> </span><span class=cF2>Guidelines:</span><span class=cF0>
<a name="l12"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>Magic numbers are bad. #defines are good.</span><span class=cF0>
<a name="l13"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>Understandability over LOC.</span><span class=cF0>
<a name="l14"></a> </span><span class=cF2>-</span><span class=cF0> </span><span class=cF2>Clear documentation.</span><span class=cF0>
<a name="l15"></a></span><span class=cF2>*/</span><span class=cF0>
<a name="l16"></a>
<a name="l17"></a></span><span class=cF2>// TODO: clean up entire driver</span><span class=cF0>
<a name="l18"></a>
<a name="l19"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_CTRL </span><span class=cFE>0x0000</span><span class=cF0>
<a name="l20"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_EERD </span><span class=cFE>0x0014</span><span class=cF0> </span><span class=cF2>// EEPROM Read</span><span class=cF0>
<a name="l21"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_ICR </span><span class=cFE>0x00C0</span><span class=cF0> </span><span class=cF2>// Interrupt Cause Read</span><span class=cF0>
<a name="l22"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_IMS </span><span class=cFE>0x00D0</span><span class=cF0>
<a name="l23"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RCTL </span><span class=cFE>0x0100</span><span class=cF0>
<a name="l24"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TCTL </span><span class=cFE>0x0400</span><span class=cF0>
<a name="l25"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RDBAL </span><span class=cFE>0x2800</span><span class=cF0>
<a name="l26"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RDBAH </span><span class=cFE>0x2804</span><span class=cF0>
<a name="l27"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RDLEN </span><span class=cFE>0x2808</span><span class=cF0>
<a name="l28"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RDH </span><span class=cFE>0x2810</span><span class=cF0>
<a name="l29"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_RDT </span><span class=cFE>0x2818</span><span class=cF0>
<a name="l30"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TDBAL </span><span class=cFE>0x3800</span><span class=cF0>
<a name="l31"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TDBAH </span><span class=cFE>0x3804</span><span class=cF0>
<a name="l32"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TDLEN </span><span class=cFE>0x3808</span><span class=cF0>
<a name="l33"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TDH </span><span class=cFE>0x3810</span><span class=cF0>
<a name="l34"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_TDT </span><span class=cFE>0x3818</span><span class=cF0>
<a name="l35"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_REG_MTA </span><span class=cFE>0x5200</span><span class=cF0> </span><span class=cF2>// Multicast Table Array</span><span class=cF0>
<a name="l36"></a>
<a name="l37"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_CTRLf_SLU </span><span class=cFE>6</span><span class=cF0> </span><span class=cF2>// Set Link Up ?</span><span class=cF0>
<a name="l38"></a>
<a name="l39"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_CTRLF_SLU (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_CTRLf_SLU) </span><span class=cF2>// Set Link Up ?</span><span class=cF0>
<a name="l40"></a>
<a name="l41"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_EN </span><span class=cFE>1</span><span class=cF0>
<a name="l42"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_SBP </span><span class=cFE>2</span><span class=cF0>
<a name="l43"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_UPE </span><span class=cFE>3</span><span class=cF0>
<a name="l44"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_MPE </span><span class=cFE>4</span><span class=cF0>
<a name="l45"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_LPE </span><span class=cFE>5</span><span class=cF0>
<a name="l46"></a></span><span class=cF2>//#define E1000_RCTLf_RDMTS_HALF</span><span class=cF0>
<a name="l47"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_RDMTS_QUARTER </span><span class=cFE>8</span><span class=cF0>
<a name="l48"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_RDMTS_EIGHTH </span><span class=cFE>9</span><span class=cF0>
<a name="l49"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_BAM </span><span class=cFE>15</span><span class=cF0>
<a name="l50"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_BSIZE_1024 </span><span class=cFE>16</span><span class=cF0>
<a name="l51"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_BSIZE_512 </span><span class=cFE>17</span><span class=cF0>
<a name="l52"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_BSIZE_256 </span><span class=cFE>18</span><span class=cF0>
<a name="l53"></a></span><span class=cF2>//#define E1000_RCTLf_BSIZE_2048</span><span class=cF0>
<a name="l54"></a></span><span class=cF2>//#define E1000_RCTLf_BSIZE_4096</span><span class=cF0>
<a name="l55"></a></span><span class=cF2>//#define E1000_RCTLf_BSIZE_8192</span><span class=cF0>
<a name="l56"></a></span><span class=cF2>//#define E1000_RCTLf_BSIZE_16384</span><span class=cF0>
<a name="l57"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLf_SECRC </span><span class=cFE>26</span><span class=cF0>
<a name="l58"></a>
<a name="l59"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_EN (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_EN)
<a name="l60"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_SBP (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_SBP)
<a name="l61"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_UPE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_UPE)
<a name="l62"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_MPE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_MPE)
<a name="l63"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_LPE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_LPE)
<a name="l64"></a></span><span class=cF2>//#define E1000_RCTLF_RDMTS_HALF</span><span class=cF0>
<a name="l65"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_RDMTS_QUARTER (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_RDMTS_QUARTER)
<a name="l66"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_RDMTS_EIGHTH (</span><span class=cFE>2</span><span class=cF0> &lt;&lt; E1000_RCTLf_RDMTS_QUARTER)
<a name="l67"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_BAM (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_BAM)
<a name="l68"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_BSIZE_1024 (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_BSIZE_1024)
<a name="l69"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_BSIZE_512 (</span><span class=cFE>2</span><span class=cF0> &lt;&lt; E1000_RCTLf_BSIZE_1024)
<a name="l70"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_BSIZE_256 (</span><span class=cFE>3</span><span class=cF0> &lt;&lt; E1000_RCTLf_BSIZE_1024)
<a name="l71"></a></span><span class=cF2>//#define E1000_RCTLF_BSIZE_2048</span><span class=cF0>
<a name="l72"></a></span><span class=cF2>//#define E1000_RCTLF_BSIZE_4096</span><span class=cF0>
<a name="l73"></a></span><span class=cF2>//#define E1000_RCTLF_BSIZE_8192</span><span class=cF0>
<a name="l74"></a></span><span class=cF2>//#define E1000_RCTLF_BSIZE_16384</span><span class=cF0>
<a name="l75"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RCTLF_SECRC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RCTLf_SECRC)
<a name="l76"></a>
<a name="l77"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TCTLf_EN </span><span class=cFE>1</span><span class=cF0>
<a name="l78"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TCTLf_PSP </span><span class=cFE>3</span><span class=cF0>
<a name="l79"></a>
<a name="l80"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TCTLF_EN (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TCTLf_EN)
<a name="l81"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TCTLF_PSP (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TCTLf_PSP)
<a name="l82"></a>
<a name="l83"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RDESC_STATUSf_EOP </span><span class=cFE>1</span><span class=cF0> </span><span class=cF2>// End of Packet: Last Descriptor for an incoming packet</span><span class=cF0>
<a name="l84"></a>
<a name="l85"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RDESC_STATUSF_EOP (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_RDESC_STATUSf_EOP)
<a name="l86"></a>
<a name="l87"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_EERDf_DONE </span><span class=cFE>4</span><span class=cF0>
<a name="l88"></a>
<a name="l89"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_EERDF_DONE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_EERDf_DONE)
<a name="l90"></a>
<a name="l91"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDf_EOP </span><span class=cFE>0</span><span class=cF0> </span><span class=cF2>// End of Packet: Last Descriptor making up the packet</span><span class=cF0>
<a name="l92"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDf_IFCS </span><span class=cFE>1</span><span class=cF0> </span><span class=cF2>// Insert FCS/CRC field in Ethernet packets</span><span class=cF0>
<a name="l93"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDf_RS </span><span class=cFE>3</span><span class=cF0> </span><span class=cF2>// Report Status: Ethernet controller needs to report status info</span><span class=cF0>
<a name="l94"></a>
<a name="l95"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDF_EOP (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_CMDf_EOP)
<a name="l96"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDF_IFCS (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_CMDf_IFCS)
<a name="l97"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_CMDF_RS (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_CMDf_RS)
<a name="l98"></a>
<a name="l99"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSf_DD </span><span class=cFE>0</span><span class=cF0> </span><span class=cF2>// Descriptor Done: descriptor is finished and written-back</span><span class=cF0>
<a name="l100"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSf_EC </span><span class=cFE>1</span><span class=cF0> </span><span class=cF2>// Excess Collisions: packet hit too many collisions; not transmitted.</span><span class=cF0>
<a name="l101"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSf_LC </span><span class=cFE>2</span><span class=cF0> </span><span class=cF2>// Late Collision: late collision occurred (only for half-duplex mode)</span><span class=cF0>
<a name="l102"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSf_TU </span><span class=cFE>3</span><span class=cF0> </span><span class=cF2>// Transmit Underrun</span><span class=cF0>
<a name="l103"></a>
<a name="l104"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSF_DD (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_STATUSf_DD)
<a name="l105"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSF_EC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_STATUSf_EC)
<a name="l106"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSF_LC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_STATUSf_LC)
<a name="l107"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TDESC_STATUSF_TU (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_TDESC_STATUSf_TU)
<a name="l108"></a>
<a name="l109"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_TXDW </span><span class=cFE>0</span><span class=cF0> </span><span class=cF2>// Transmit Descriptor Written Back</span><span class=cF0>
<a name="l110"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_TXQE </span><span class=cFE>1</span><span class=cF0> </span><span class=cF2>// Transmit Queue Empty</span><span class=cF0>
<a name="l111"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_LSC </span><span class=cFE>2</span><span class=cF0> </span><span class=cF2>// Link Status Change</span><span class=cF0>
<a name="l112"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_RXDMT </span><span class=cFE>4</span><span class=cF0> </span><span class=cF2>// Receive Descriptor Minimum Threshold Reached</span><span class=cF0>
<a name="l113"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_RXO </span><span class=cFE>6</span><span class=cF0> </span><span class=cF2>// Receive Data FIFO Overrun</span><span class=cF0>
<a name="l114"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRf_RXT </span><span class=cFE>7</span><span class=cF0> </span><span class=cF2>// Receive Timer Interrupt</span><span class=cF0>
<a name="l115"></a>
<a name="l116"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_TXDW (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_TXDW)
<a name="l117"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_TXQE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_TXQE)
<a name="l118"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_LSC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_LSC)
<a name="l119"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_RXDMT (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_RXDMT)
<a name="l120"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_RXO (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_RXO)
<a name="l121"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_ICRF_RXT (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_ICRf_RXT)
<a name="l122"></a>
<a name="l123"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_TXDW </span><span class=cFE>0</span><span class=cF0>
<a name="l124"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_TXQE </span><span class=cFE>1</span><span class=cF0>
<a name="l125"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_LSC </span><span class=cFE>2</span><span class=cF0>
<a name="l126"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_RXSEQ </span><span class=cFE>3</span><span class=cF0>
<a name="l127"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_RXDMT </span><span class=cFE>4</span><span class=cF0>
<a name="l128"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_RXO </span><span class=cFE>6</span><span class=cF0>
<a name="l129"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_RXT </span><span class=cFE>7</span><span class=cF0>
<a name="l130"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_MDAC </span><span class=cFE>9</span><span class=cF0>
<a name="l131"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_RXCFG </span><span class=cFE>10</span><span class=cF0>
<a name="l132"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_PHYINT </span><span class=cFE>12</span><span class=cF0>
<a name="l133"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_GPI </span><span class=cFE>13</span><span class=cF0> </span><span class=cF2>// 13-14</span><span class=cF0>
<a name="l134"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_TXDLOW </span><span class=cFE>15</span><span class=cF0>
<a name="l135"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSf_SRPD </span><span class=cFE>16</span><span class=cF0>
<a name="l136"></a>
<a name="l137"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_TXDW (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_TXDW)
<a name="l138"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_TXQE (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_TXQE)
<a name="l139"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_LSC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_LSC)
<a name="l140"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_RXSEQ (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_RXSEQ)
<a name="l141"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_RXDMT (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_RXDMT)
<a name="l142"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_RXO (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_RXO)
<a name="l143"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_RXT (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_RXT)
<a name="l144"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_MDAC (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_MDAC)
<a name="l145"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_RXCFG (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_RXCFG)
<a name="l146"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_PHYINT (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_PHYINT)
<a name="l147"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_GPI (</span><span class=cFE>2</span><span class=cF0> &lt;&lt; E1000_IMSf_GPI) </span><span class=cF2>// flag sets both bits</span><span class=cF0>
<a name="l148"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_TXDLOW (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_TXDLOW)
<a name="l149"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_IMSF_SRPD (</span><span class=cFE>1</span><span class=cF0> &lt;&lt; E1000_IMSf_SRPD)
<a name="l150"></a>
<a name="l151"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_RX_BUFF_COUNT </span><span class=cFE>32</span><span class=cF0> </span><span class=cF2>// 01000101's driver uses 768 for each of these...</span><span class=cF0>
<a name="l152"></a>#</span><span class=cF1>define</span><span class=cF0> E1000_TX_BUFF_COUNT </span><span class=cFE>8</span><span class=cF0>
<a name="l153"></a>
<a name="l154"></a></span><span class=cF1>class</span><span class=cF0> CE1000DescriptorEntryRX
<a name="l155"></a>{
<a name="l156"></a> </span><span class=cF9>U64</span><span class=cF0> address;
<a name="l157"></a> </span><span class=cF9>U16</span><span class=cF0> length;
<a name="l158"></a> </span><span class=cF9>U16</span><span class=cF0> checksum;
<a name="l159"></a> </span><span class=cF1>U8</span><span class=cF0> status;
<a name="l160"></a> </span><span class=cF1>U8</span><span class=cF0> errors;
<a name="l161"></a> </span><span class=cF9>U16</span><span class=cF0> special;
<a name="l162"></a>};
<a name="l163"></a>
<a name="l164"></a></span><span class=cF1>class</span><span class=cF0> CE1000DescriptorEntryTX
<a name="l165"></a>{
<a name="l166"></a> </span><span class=cF9>U64</span><span class=cF0> address;
<a name="l167"></a> </span><span class=cF9>U16</span><span class=cF0> length;
<a name="l168"></a> </span><span class=cF1>U8</span><span class=cF0> cso;
<a name="l169"></a> </span><span class=cF1>U8</span><span class=cF0> cmd;
<a name="l170"></a> </span><span class=cF1>U8</span><span class=cF0> sta;
<a name="l171"></a> </span><span class=cF1>U8</span><span class=cF0> css;
<a name="l172"></a> </span><span class=cF9>U16</span><span class=cF0> special;
<a name="l173"></a>};
<a name="l174"></a>
<a name="l175"></a></span><span class=cF1>class</span><span class=cF0> CE1000
<a name="l176"></a>{
<a name="l177"></a> </span><span class=cF9>CPCIDev</span><span class=cF0> *pci;
<a name="l178"></a>
<a name="l179"></a> </span><span class=cF1>U8</span><span class=cF0> mac_address[</span><span class=cFE>6</span><span class=cF0>];
<a name="l180"></a> </span><span class=cF9>U64</span><span class=cF0> mmio_address;
<a name="l181"></a>
<a name="l182"></a> </span><span class=cF9>I64</span><span class=cF0> current_rx_de_index; </span><span class=cF2>// Current Receive DE being processed. Gets incremented, wrapped to 0 at max of E1000_RX_BUFF_COUNT.</span><span class=cF0>
<a name="l183"></a> </span><span class=cF9>I64</span><span class=cF0> current_tx_de_index; </span><span class=cF2>// Current Transmit DE being processed. Gets incremented, wrapped to 0 at max of E1000_TX_BUFF_COUNT.</span><span class=cF0>
<a name="l184"></a>
<a name="l185"></a> </span><span class=cF1>U8</span><span class=cF0> *rx_de_buffer; </span><span class=cF2>// Uncached-alias of pointer to the buffer of RX Descriptor Entries.</span><span class=cF0>
<a name="l186"></a> </span><span class=cF1>U8</span><span class=cF0> *tx_de_buffer; </span><span class=cF2>// Uncached-alias of pointer to the buffer of TX Descriptor Entries.</span><span class=cF0>
<a name="l187"></a> </span><span class=cF1>U8</span><span class=cF0> *rx_de_buffer_phys; </span><span class=cF2>// Pointer to the buffer of RX Descriptor Entries. (Code Heap, lower 2Gb)</span><span class=cF0>
<a name="l188"></a> </span><span class=cF1>U8</span><span class=cF0> *tx_de_buffer_phys; </span><span class=cF2>// Pointer to the buffer of TX Descriptor Entries. (Code Heap, lower 2Gb)</span><span class=cF0>
<a name="l189"></a>
<a name="l190"></a> </span><span class=cF9>U64</span><span class=cF0> rx_buffer_addr; </span><span class=cF2>// Uncached-alias of address of receive buffers.</span><span class=cF0>
<a name="l191"></a> </span><span class=cF9>U64</span><span class=cF0> tx_buffer_addr; </span><span class=cF2>// Uncached-alias of address of transmit buffers.</span><span class=cF0>
<a name="l192"></a> </span><span class=cF9>U64</span><span class=cF0> rx_buffer_addr_phys; </span><span class=cF2>// Physical address of actual receive buffers (&lt; 4 Gb)</span><span class=cF0>
<a name="l193"></a> </span><span class=cF9>U64</span><span class=cF0> tx_buffer_addr_phys; </span><span class=cF2>// Physical address of actual transmit buffers (&lt; 4 Gb)</span><span class=cF0>
<a name="l194"></a>
<a name="l195"></a>
<a name="l196"></a>} e1000; </span><span class=cF2>// e1000 is the global variable we store all of this into.</span><span class=cF0>
<a name="l197"></a>
<a name="l198"></a></span><span class=cF9>CPCIDev</span><span class=cF0> *E1000PCIDevFind()
<a name="l199"></a>{</span><span class=cF2>// Find and return E1000 card as a CPCIDev pointer.</span><span class=cF0>
<a name="l200"></a>
<a name="l201"></a> </span><span class=cF9>CPCIDev</span><span class=cF0> *pci = </span><span class=cF5>PCIDevFind</span><span class=cF0>(</span><span class=cF3>PCIC_NETWORK</span><span class=cF0>,, PCIV_E1000);
<a name="l202"></a>
<a name="l203"></a> </span><span class=cF1>if</span><span class=cF0> (!pci)
<a name="l204"></a> </span><span class=cF1>return</span><span class=cF0> </span><span class=cF3>NULL</span><span class=cF0>;
<a name="l205"></a>
<a name="l206"></a> </span><span class=cF5>ClassRep</span><span class=cF0>(pci);
<a name="l207"></a>
<a name="l208"></a> </span><span class=cF1>switch</span><span class=cF0> (pci-&gt;device_id)
<a name="l209"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l210"></a> </span><span class=cF1>case</span><span class=cF0> PCID_82545EM:
<a name="l211"></a> </span><span class=cF1>break</span><span class=cF0>;
<a name="l212"></a>
<a name="l213"></a> </span><span class=cF1>default</span><span class=cF0>:
<a name="l214"></a> pci = </span><span class=cF3>NULL</span><span class=cF0>;
<a name="l215"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l216"></a>
<a name="l217"></a> </span><span class=cF1>return</span><span class=cF0> pci;
<a name="l218"></a>}
<a name="l219"></a>
<a name="l220"></a></span><span class=cF9>U32</span><span class=cF0> E1000MMIORead(</span><span class=cF9>U32</span><span class=cF0> </span><span class=cF1>offset</span><span class=cF0>)
<a name="l221"></a>{
<a name="l222"></a> </span><span class=cF9>U32</span><span class=cF0> *val = e1000.mmio_address + </span><span class=cF1>offset</span><span class=cF0>;
<a name="l223"></a>
<a name="l224"></a> </span><span class=cF1>return</span><span class=cF0> *val;
<a name="l225"></a>}
<a name="l226"></a>
<a name="l227"></a></span><span class=cF1>U0</span><span class=cF0> E1000MMIOWrite(</span><span class=cF9>U32</span><span class=cF0> </span><span class=cF1>offset</span><span class=cF0>, </span><span class=cF9>U32</span><span class=cF0> val)
<a name="l228"></a>{
<a name="l229"></a> </span><span class=cF9>U32</span><span class=cF0> *addr = e1000.mmio_address + </span><span class=cF1>offset</span><span class=cF0>;
<a name="l230"></a>
<a name="l231"></a> *addr = val;
<a name="l232"></a>}
<a name="l233"></a>
<a name="l234"></a></span><span class=cF9>U16</span><span class=cF0> E1000EEPROMRead(</span><span class=cF1>U8</span><span class=cF0> word)
<a name="l235"></a>{ </span><span class=cF2>// word arg is which U16 to read</span><span class=cF0>
<a name="l236"></a> </span><span class=cF9>U16</span><span class=cF0> data;
<a name="l237"></a> </span><span class=cF9>U32</span><span class=cF0> temp;
<a name="l238"></a>
<a name="l239"></a> E1000MMIOWrite(E1000_REG_EERD, </span><span class=cFE>1</span><span class=cF0> | word &lt;&lt; </span><span class=cFE>8</span><span class=cF0>);
<a name="l240"></a>
<a name="l241"></a> temp = E1000MMIORead(E1000_REG_EERD);
<a name="l242"></a> </span><span class=cF1>while</span><span class=cF0> (!</span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;temp, E1000_EERDf_DONE</span><span class=cF7>)</span><span class=cF0>)
<a name="l243"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l244"></a> </span><span class=cF5>Sleep</span><span class=cF0>(</span><span class=cFE>1</span><span class=cF0>);
<a name="l245"></a> temp = E1000MMIORead(E1000_REG_EERD);
<a name="l246"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l247"></a>
<a name="l248"></a> data = temp.u16[</span><span class=cFE>1</span><span class=cF0>];
<a name="l249"></a> </span><span class=cF1>return</span><span class=cF0> data;
<a name="l250"></a>}
<a name="l251"></a>
<a name="l252"></a></span><span class=cF1>U0</span><span class=cF0> E1000MACGet()
<a name="l253"></a>{
<a name="l254"></a> </span><span class=cF9>I64</span><span class=cF0> i;
<a name="l255"></a> </span><span class=cF9>U16</span><span class=cF0> mac;
<a name="l256"></a>
<a name="l257"></a> NetLog(</span><span class=cF6>&quot;E1000 MAC GET: Getting MAC Address.&quot;</span><span class=cF0>);
<a name="l258"></a>
<a name="l259"></a> </span><span class=cF1>for</span><span class=cF0> (i = </span><span class=cFE>0</span><span class=cF0>; i &lt; </span><span class=cFE>3</span><span class=cF0>; i++)
<a name="l260"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l261"></a> mac = E1000EEPROMRead(i);
<a name="l262"></a> e1000.mac_address[</span><span class=cFE>2</span><span class=cF0>*i] = mac.u8[</span><span class=cFE>0</span><span class=cF0>];
<a name="l263"></a> e1000.mac_address[</span><span class=cFE>2</span><span class=cF0>*i+</span><span class=cFE>1</span><span class=cF0>] = mac.u8[</span><span class=cFE>1</span><span class=cF0>];
<a name="l264"></a> NetLog(</span><span class=cF6>&quot; %02X %02X&quot;</span><span class=cF0>, mac.u8[</span><span class=cFE>0</span><span class=cF0>], mac.u8[</span><span class=cFE>1</span><span class=cF0>]);
<a name="l265"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l266"></a>
<a name="l267"></a>}
<a name="l268"></a>
<a name="l269"></a></span><span class=cF9>I64</span><span class=cF0> E1000PacketReceive(</span><span class=cF1>U8</span><span class=cF0> **packet_buffer_out, </span><span class=cF9>U16</span><span class=cF0> *packet_length_out)
<a name="l270"></a>{
<a name="l271"></a> </span><span class=cF9>I64</span><span class=cF0> de_index = e1000.current_rx_de_index;
<a name="l272"></a> CE1000DescriptorEntryRX *entry = &amp;e1000.rx_de_buffer[de_index * </span><span class=cF1>sizeof</span><span class=cF0>(CE1000DescriptorEntryRX)];
<a name="l273"></a> </span><span class=cF1>Bool</span><span class=cF0> drop = </span><span class=cF3>FALSE</span><span class=cF0>;
<a name="l274"></a>
<a name="l275"></a> </span><span class=cF1>if</span><span class=cF0> (entry-&gt;length &lt; </span><span class=cFE>60</span><span class=cF0>)
<a name="l276"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l277"></a> NetErr(</span><span class=cF6>&quot;E1000 PACKET RECEIVE: Short Packet&quot;</span><span class=cF0>);
<a name="l278"></a> drop = </span><span class=cF3>TRUE</span><span class=cF0>;
<a name="l279"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l280"></a>
<a name="l281"></a> </span><span class=cF1>if</span><span class=cF0> (</span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;entry-&gt;status, E1000_RDESC_STATUSf_EOP</span><span class=cF7>)</span><span class=cF0>)
<a name="l282"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l283"></a> NetErr(</span><span class=cF6>&quot;E1000 PACKET RECEIVE: No EOP Set&quot;</span><span class=cF0>);
<a name="l284"></a> drop = </span><span class=cF3>TRUE</span><span class=cF0>;
<a name="l285"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l286"></a>
<a name="l287"></a> </span><span class=cF1>if</span><span class=cF0> (entry-&gt;errors)
<a name="l288"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l289"></a> NetErr(</span><span class=cF6>&quot;E1000 PACKET RECEIVE: RX DE Error Bits Set&quot;</span><span class=cF0>);
<a name="l290"></a> drop = </span><span class=cF3>TRUE</span><span class=cF0>;
<a name="l291"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l292"></a>
<a name="l293"></a> e1000.current_rx_de_index = (e1000.current_rx_de_index + </span><span class=cFE>1</span><span class=cF0>) &amp; (E1000_RX_BUFF_COUNT - </span><span class=cFE>1</span><span class=cF0>);
<a name="l294"></a>
<a name="l295"></a> </span><span class=cF1>if</span><span class=cF0> (!drop)
<a name="l296"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l297"></a> *packet_buffer_out = entry-&gt;address;
<a name="l298"></a> *packet_length_out = entry-&gt;length;
<a name="l299"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l300"></a> </span><span class=cF1>else</span><span class=cF0>
<a name="l301"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l302"></a> NetErr(</span><span class=cF6>&quot;E1000 PACKET RECEIVE: Dropping packet.&quot;</span><span class=cF0>);
<a name="l303"></a> de_index = -</span><span class=cFE>1</span><span class=cF0>;
<a name="l304"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l305"></a>
<a name="l306"></a> </span><span class=cF1>return</span><span class=cF0> de_index;
<a name="l307"></a>}
<a name="l308"></a>
<a name="l309"></a></span><span class=cF1>U0</span><span class=cF0> E1000ReceivePacketRelease(</span><span class=cF9>I64</span><span class=cF0> de_index)
<a name="l310"></a>{
<a name="l311"></a> CE1000DescriptorEntryRX *entry = &amp;e1000.rx_de_buffer[de_index * </span><span class=cF1>sizeof</span><span class=cF0>(CE1000DescriptorEntryRX)];
<a name="l312"></a> entry-&gt;status = </span><span class=cFE>0</span><span class=cF0>;
<a name="l313"></a>
<a name="l314"></a> E1000MMIOWrite(E1000_REG_RDT, e1000.current_rx_de_index);
<a name="l315"></a>}
<a name="l316"></a>
<a name="l317"></a></span><span class=cF1>Bool</span><span class=cF0> E1000DriverOwnsRX(CE1000DescriptorEntryRX *entry)
<a name="l318"></a>{
<a name="l319"></a> </span><span class=cF1>return</span><span class=cF0> </span><span class=cF5>Bt</span><span class=cF0>(&amp;entry-&gt;status, </span><span class=cFE>0</span><span class=cF0>); </span><span class=cF2>// ?? TODO #define</span><span class=cF0>
<a name="l320"></a>}
<a name="l321"></a>
<a name="l322"></a></span><span class=cF9>I64</span><span class=cF0> E1000TransmitPacketAllocate(</span><span class=cF1>U8</span><span class=cF0> **packet_buffer_out, </span><span class=cF9>I64</span><span class=cF0> length)
<a name="l323"></a>{ </span><span class=cF9>I64</span><span class=cF0> de_index = e1000.current_tx_de_index;
<a name="l324"></a>
<a name="l325"></a> CE1000DescriptorEntryTX *entry = &amp;e1000.tx_de_buffer[de_index * </span><span class=cF1>sizeof</span><span class=cF0>(CE1000DescriptorEntryTX)];
<a name="l326"></a>
<a name="l327"></a> *packet_buffer_out = e1000.tx_buffer_addr + de_index * ETHERNET_FRAME_SIZE;
<a name="l328"></a>
<a name="l329"></a> </span><span class=cF5>MemSet</span><span class=cF0>(*packet_buffer_out, </span><span class=cFE>0</span><span class=cF0>, ETHERNET_FRAME_SIZE); </span><span class=cF2>// Clear buffer contents in advance.</span><span class=cF0>
<a name="l330"></a>
<a name="l331"></a> entry-&gt;address = *packet_buffer_out;
<a name="l332"></a> entry-&gt;length = length;
<a name="l333"></a> </span><span class=cF5>Bts</span><span class=cF0>(&amp;entry-&gt;cmd, E1000_TDESC_CMDf_EOP);
<a name="l334"></a> </span><span class=cF5>Bts</span><span class=cF0>(&amp;entry-&gt;cmd, E1000_TDESC_CMDf_IFCS);
<a name="l335"></a> </span><span class=cF5>Bts</span><span class=cF0>(&amp;entry-&gt;cmd, E1000_TDESC_CMDf_RS);
<a name="l336"></a>
<a name="l337"></a> NetLog(</span><span class=cF6>&quot;E1000 ALLOCATE TX PACKET: de_index: %X.&quot;</span><span class=cF0>, de_index);
<a name="l338"></a> </span><span class=cF1>return</span><span class=cF0> de_index;
<a name="l339"></a>}
<a name="l340"></a>
<a name="l341"></a></span><span class=cF1>U0</span><span class=cF0> E1000TransmitPacketFinish(</span><span class=cF9>I64</span><span class=cF0> de_index)
<a name="l342"></a>{
<a name="l343"></a> CE1000DescriptorEntryTX *entry = &amp;e1000.tx_de_buffer[de_index * </span><span class=cF1>sizeof</span><span class=cF0>(CE1000DescriptorEntryTX)];
<a name="l344"></a>
<a name="l345"></a> e1000.current_tx_de_index = (e1000.current_tx_de_index + </span><span class=cFE>1</span><span class=cF0>) &amp; (E1000_TX_BUFF_COUNT - </span><span class=cFE>1</span><span class=cF0>);
<a name="l346"></a> E1000MMIOWrite(E1000_REG_TDT, e1000.current_tx_de_index);
<a name="l347"></a>
<a name="l348"></a> </span><span class=cF5>ClassRep</span><span class=cF0>(entry);
<a name="l349"></a>
<a name="l350"></a> </span><span class=cF1>while</span><span class=cF0> (!</span><span class=cF7>(</span><span class=cF0>entry-&gt;sta &amp; (E1000_TDESC_STATUSF_DD | E1000_TDESC_STATUSF_EC |
<a name="l351"></a> E1000_TDESC_STATUSF_LC | E1000_TDESC_STATUSF_TU)</span><span class=cF7>)</span><span class=cF0>)
<a name="l352"></a> </span><span class=cF5>Yield</span><span class=cF0>;
<a name="l353"></a>
<a name="l354"></a> NetLog(</span><span class=cF6>&quot;E1000 FINISH TX PACKET: TX DE index: %X.&quot;</span><span class=cF0>, de_index);
<a name="l355"></a>}
<a name="l356"></a>
<a name="l357"></a></span><span class=cF1>U0</span><span class=cF0> EthernetFrameFinish(</span><span class=cF9>I64</span><span class=cF0> de_index)
<a name="l358"></a>{</span><span class=cF2>//Alias for driver Finish TX function.</span><span class=cF0>
<a name="l359"></a> E1000TransmitPacketFinish(de_index);
<a name="l360"></a>}
<a name="l361"></a>
<a name="l362"></a></span><span class=cF1>interrupt</span><span class=cF0> </span><span class=cF1>U0</span><span class=cF0> E1000IRQ()
<a name="l363"></a>{ </span><span class=cF2>// TODO need #defines</span><span class=cF0>
<a name="l364"></a> </span><span class=cF9>U32</span><span class=cF0> icr = E1000MMIORead(E1000_REG_ICR);
<a name="l365"></a> </span><span class=cF1>Bool</span><span class=cF0> poll = </span><span class=cF3>FALSE</span><span class=cF0>;
<a name="l366"></a> CE1000DescriptorEntryRX *entry = e1000.rx_de_buffer;
<a name="l367"></a> </span><span class=cF1>U8</span><span class=cF0> *packet_buffer;
<a name="l368"></a> </span><span class=cF9>U16</span><span class=cF0> packet_length;
<a name="l369"></a> </span><span class=cF9>I64</span><span class=cF0> de_index;
<a name="l370"></a>
<a name="l371"></a> icr &amp;= ~(E1000_ICRF_TXDW | E1000_ICRF_TXQE);
<a name="l372"></a>
<a name="l373"></a> </span><span class=cF1>if</span><span class=cF0> (</span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;icr, E1000_ICRf_LSC</span><span class=cF7>)</span><span class=cF0>) </span><span class=cF2>// 'link status change' ?</span><span class=cF0>
<a name="l374"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l375"></a> </span><span class=cF5>Btr</span><span class=cF0>(&amp;icr, E1000_ICRf_LSC);
<a name="l376"></a> E1000MMIOWrite(E1000_REG_CTRL, E1000MMIORead</span><span class=cF7>(</span><span class=cF0>E1000_REG_CTRL</span><span class=cF7>)</span><span class=cF0> | E1000_CTRLF_SLU);
<a name="l377"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l378"></a>
<a name="l379"></a> </span><span class=cF1>if</span><span class=cF0> (</span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;icr, E1000_ICRf_RXO</span><span class=cF7>)</span><span class=cF0> || </span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;icr, E1000_ICRf_RXDMT</span><span class=cF7>)</span><span class=cF0>) </span><span class=cF2>// 'rx underrun / min threshold' ?</span><span class=cF0>
<a name="l380"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l381"></a> </span><span class=cF5>Btr</span><span class=cF0>(&amp;icr, E1000_ICRf_RXO);
<a name="l382"></a> </span><span class=cF5>Btr</span><span class=cF0>(&amp;icr, E1000_ICRf_RXDMT);
<a name="l383"></a>
<a name="l384"></a> poll = </span><span class=cF3>TRUE</span><span class=cF0>;
<a name="l385"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l386"></a>
<a name="l387"></a> </span><span class=cF1>if</span><span class=cF0> (</span><span class=cF5>Bt</span><span class=cF7>(</span><span class=cF0>&amp;icr, E1000_ICRf_RXT</span><span class=cF7>)</span><span class=cF0>) </span><span class=cF2>// 'packet pending' ?</span><span class=cF0>
<a name="l388"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l389"></a> </span><span class=cF5>Btr</span><span class=cF0>(&amp;icr, E1000_ICRf_RXT);
<a name="l390"></a>
<a name="l391"></a> poll = </span><span class=cF3>TRUE</span><span class=cF0>;
<a name="l392"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l393"></a>
<a name="l394"></a> </span><span class=cF1>if</span><span class=cF0> (poll)
<a name="l395"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l396"></a> </span><span class=cF1>while</span><span class=cF0> (E1000DriverOwnsRX</span><span class=cF7>(</span><span class=cF0>&amp;entry[e1000.current_rx_de_index]</span><span class=cF7>)</span><span class=cF0>)
<a name="l397"></a> {
<a name="l398"></a> NetLog(</span><span class=cF6>&quot;$BG,LTCYAN$$FG,WHITE$&quot;</span><span class=cF0>
<a name="l399"></a> </span><span class=cF6>&quot;==== E1000 IRQ ====&quot;</span><span class=cF0>
<a name="l400"></a> </span><span class=cF6>&quot;$BG$$FG$&quot;</span><span class=cF0>);
<a name="l401"></a>
<a name="l402"></a> NetLog(</span><span class=cF6>&quot;$BD,CYAN$$FD,WHITE$&quot;</span><span class=cF0>
<a name="l403"></a> </span><span class=cF6>&quot;E1000 IRQ: Saw owned RX DE index %d.&quot;</span><span class=cF0>, e1000.current_rx_de_index);
<a name="l404"></a>
<a name="l405"></a> de_index = E1000PacketReceive(&amp;packet_buffer, &amp;packet_length);
<a name="l406"></a>
<a name="l407"></a> </span><span class=cF1>if</span><span class=cF0> (de_index &gt;= </span><span class=cFE>0</span><span class=cF0>)
<a name="l408"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l409"></a> NetLog(</span><span class=cF6>&quot;E1000 IRQ: Pushing copy into Net Queue, releasing receive packet.&quot;</span><span class=cF0>);
<a name="l410"></a> NetQueuePush(packet_buffer, packet_length);
<a name="l411"></a> E1000ReceivePacketRelease(de_index);
<a name="l412"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l413"></a>
<a name="l414"></a> NetLog(</span><span class=cF6>&quot;E1000 IRQ: Exiting.\n&quot;</span><span class=cF0>
<a name="l415"></a> </span><span class=cF6>&quot;$BD,WHITE$$FD,LTGRAY$&quot;</span><span class=cF0>
<a name="l416"></a> </span><span class=cF6>&quot;$BG,LTCYAN$$FG,WHITE$&quot;</span><span class=cF0>
<a name="l417"></a> </span><span class=cF6>&quot;===================&quot;</span><span class=cF0>
<a name="l418"></a> </span><span class=cF6>&quot;$BG$$FG$&quot;</span><span class=cF0>);
<a name="l419"></a> }
<a name="l420"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l421"></a>
<a name="l422"></a> E1000MMIORead(E1000_REG_ICR); </span><span class=cF2>// clear pending interrupts?</span><span class=cF0>
<a name="l423"></a>
<a name="l424"></a> *(</span><span class=cFB>dev</span><span class=cF0>.uncached_alias + </span><span class=cF3>LAPIC_EOI</span><span class=cF0>)(</span><span class=cF9>U32</span><span class=cF0>*) = </span><span class=cFE>0</span><span class=cF0>;
<a name="l425"></a>}
<a name="l426"></a>
<a name="l427"></a></span><span class=cF1>U0</span><span class=cF0> PCIInterruptsReroute(</span><span class=cF9>I64</span><span class=cF0> base)
<a name="l428"></a>{ </span><span class=cF2>// todo: comments explaining process, maybe better var names</span><span class=cF0>
<a name="l429"></a> </span><span class=cF9>I64</span><span class=cF0> i;
<a name="l430"></a> </span><span class=cF1>U8</span><span class=cF0> *da = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + </span><span class=cF3>IOAPIC_REG</span><span class=cF0>;
<a name="l431"></a> </span><span class=cF9>U32</span><span class=cF0> *_d = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + </span><span class=cF3>IOAPIC_DATA</span><span class=cF0>;
<a name="l432"></a>
<a name="l433"></a> </span><span class=cF1>for</span><span class=cF0> (i = </span><span class=cFE>0</span><span class=cF0>; i &lt; </span><span class=cFE>4</span><span class=cF0>; i++)
<a name="l434"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l435"></a> *da = </span><span class=cF3>IOREDTAB</span><span class=cF0> + i * </span><span class=cFE>2</span><span class=cF0> + </span><span class=cFE>1</span><span class=cF0>;
<a name="l436"></a> *_d = </span><span class=cFB>dev</span><span class=cF0>.mp_apic_ids[INT_DEST_CPU] &lt;&lt; </span><span class=cFE>24</span><span class=cF0>;
<a name="l437"></a> *da = </span><span class=cF3>IOREDTAB</span><span class=cF0> + i * </span><span class=cFE>2</span><span class=cF0>;
<a name="l438"></a> *_d = </span><span class=cFE>0x4000</span><span class=cF0> + base + i;
<a name="l439"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l440"></a>}
<a name="l441"></a>
<a name="l442"></a>
<a name="l443"></a></span><span class=cF1>U0</span><span class=cF0> E1000InterruptsSetup()
<a name="l444"></a>{ </span><span class=cF2>// .. ?</span><span class=cF0>
<a name="l445"></a> </span><span class=cF9>I64</span><span class=cF0> irq, i;
<a name="l446"></a>
<a name="l447"></a> </span><span class=cF1>for</span><span class=cF0> (i = </span><span class=cFE>0</span><span class=cF0>; i &lt; </span><span class=cFE>4</span><span class=cF0>; i++)
<a name="l448"></a> </span><span class=cF5>IntEntrySet</span><span class=cF0>(</span><span class=cF7>(</span><span class=cF0>irq = </span><span class=cF5>IntEntryAlloc</span><span class=cF7>)</span><span class=cF0>, &amp;E1000IRQ);
<a name="l449"></a>
<a name="l450"></a> PCIInterruptsReroute(irq);
<a name="l451"></a>}
<a name="l452"></a>
<a name="l453"></a></span><span class=cF1>U0</span><span class=cF0> E1000InitRX()
<a name="l454"></a>{
<a name="l455"></a> </span><span class=cF9>I64</span><span class=cF0> de_index;
<a name="l456"></a>
<a name="l457"></a> e1000.rx_de_buffer_phys = </span><span class=cF5>CAllocAligned</span><span class=cF0>(</span><span class=cF1>sizeof</span><span class=cF7>(</span><span class=cF0>CE1000DescriptorEntryRX</span><span class=cF7>)</span><span class=cF0> * E1000_RX_BUFF_COUNT,
<a name="l458"></a> </span><span class=cFE>16</span><span class=cF0>,
<a name="l459"></a> </span><span class=cF5>Fs</span><span class=cF0>-&gt;code_heap);
<a name="l460"></a>
<a name="l461"></a> e1000.rx_de_buffer = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + e1000.rx_de_buffer_phys;
<a name="l462"></a>
<a name="l463"></a> e1000.rx_buffer_addr_phys = </span><span class=cF5>CAlloc</span><span class=cF0>(ETHERNET_FRAME_SIZE * E1000_RX_BUFF_COUNT, </span><span class=cF5>Fs</span><span class=cF0>-&gt;code_heap);
<a name="l464"></a>
<a name="l465"></a> e1000.rx_buffer_addr = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + e1000.rx_buffer_addr_phys;
<a name="l466"></a>
<a name="l467"></a> </span><span class=cF2>// iterate de's and make packet buffers for each</span><span class=cF0>
<a name="l468"></a> CE1000DescriptorEntryRX *entry = e1000.rx_de_buffer;
<a name="l469"></a> </span><span class=cF1>for</span><span class=cF0> (de_index = </span><span class=cFE>0</span><span class=cF0>; de_index &lt; E1000_RX_BUFF_COUNT; de_index++)
<a name="l470"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l471"></a> entry-&gt;address = e1000.rx_buffer_addr + de_index * ETHERNET_FRAME_SIZE; </span><span class=cF2>// is this right? might need to change ?..</span><span class=cF0>
<a name="l472"></a> </span><span class=cF2>// 01000101 MAlloc's 8208 for each DE</span><span class=cF0>
<a name="l473"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l474"></a>
<a name="l475"></a> </span><span class=cF2>// setup rx de ring buffer</span><span class=cF0>
<a name="l476"></a> E1000MMIOWrite(E1000_REG_RDBAH, e1000.rx_de_buffer &gt;&gt; </span><span class=cFE>32</span><span class=cF0>); </span><span class=cF2>// should we be using uncached addr here ?</span><span class=cF0>
<a name="l477"></a> E1000MMIOWrite(E1000_REG_RDBAL, e1000.rx_de_buffer &amp; </span><span class=cFE>0xFFFFFFFF</span><span class=cF0>);
<a name="l478"></a>
<a name="l479"></a> </span><span class=cF2>// set receive buffer length</span><span class=cF0>
<a name="l480"></a> E1000MMIOWrite(E1000_REG_RDLEN, E1000_RX_BUFF_COUNT * </span><span class=cFE>16</span><span class=cF0>);
<a name="l481"></a>
<a name="l482"></a> </span><span class=cF2>// set head tail pointers</span><span class=cF0>
<a name="l483"></a> E1000MMIOWrite(E1000_REG_RDH, </span><span class=cFE>0</span><span class=cF0>);
<a name="l484"></a> E1000MMIOWrite(E1000_REG_RDT, E1000_RX_BUFF_COUNT);
<a name="l485"></a>
<a name="l486"></a> </span><span class=cF2>// set receive control reg</span><span class=cF0>
<a name="l487"></a> E1000MMIOWrite(E1000_REG_RCTL, E1000_RCTLF_SBP |
<a name="l488"></a></span><span class=cF2>//</span><span class=cF0> </span><span class=cF2>E1000_RCTLF_UPE</span><span class=cF0> </span><span class=cF2>|</span><span class=cF0>
<a name="l489"></a></span><span class=cF2>//</span><span class=cF0> </span><span class=cF2>E1000_RCTLF_RDMTS_HALF</span><span class=cF0> </span><span class=cF2>|</span><span class=cF0>
<a name="l490"></a></span><span class=cF2>//</span><span class=cF0> </span><span class=cF2>E1000_RCTLF_BSIZE_2048</span><span class=cF0> </span><span class=cF2>|</span><span class=cF0>
<a name="l491"></a></span><span class=cF2>//</span><span class=cF0> </span><span class=cF2>E1000_RCTLF_MPE</span><span class=cF0> </span><span class=cF2>|</span><span class=cF0>
<a name="l492"></a> E1000_RCTLF_SECRC |
<a name="l493"></a> E1000_RCTLF_LPE |
<a name="l494"></a> E1000_RCTLF_BAM);
<a name="l495"></a>}
<a name="l496"></a>
<a name="l497"></a></span><span class=cF1>U0</span><span class=cF0> E1000InitTX()
<a name="l498"></a>{
<a name="l499"></a> e1000.tx_de_buffer_phys = </span><span class=cF5>CAllocAligned</span><span class=cF0>(</span><span class=cF1>sizeof</span><span class=cF7>(</span><span class=cF0>CE1000DescriptorEntryTX</span><span class=cF7>)</span><span class=cF0> * E1000_TX_BUFF_COUNT,
<a name="l500"></a> </span><span class=cFE>16</span><span class=cF0>,
<a name="l501"></a> </span><span class=cF5>Fs</span><span class=cF0>-&gt;code_heap);
<a name="l502"></a>
<a name="l503"></a> e1000.tx_de_buffer = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + e1000.tx_de_buffer_phys;
<a name="l504"></a>
<a name="l505"></a> e1000.tx_buffer_addr_phys = </span><span class=cF5>CAlloc</span><span class=cF0>(ETHERNET_FRAME_SIZE * E1000_TX_BUFF_COUNT, </span><span class=cF5>Fs</span><span class=cF0>-&gt;code_heap);
<a name="l506"></a>
<a name="l507"></a> e1000.tx_buffer_addr = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + e1000.tx_buffer_addr_phys;
<a name="l508"></a>
<a name="l509"></a> </span><span class=cF2>// setup tx de ring buffer</span><span class=cF0>
<a name="l510"></a> E1000MMIOWrite(E1000_REG_TDBAH, e1000.tx_de_buffer &gt;&gt; </span><span class=cFE>32</span><span class=cF0>); </span><span class=cF2>// should we be using uncached addr here ?</span><span class=cF0>
<a name="l511"></a> E1000MMIOWrite(E1000_REG_TDBAL, e1000.tx_de_buffer &amp; </span><span class=cFE>0xFFFFFFFF</span><span class=cF0>);
<a name="l512"></a>
<a name="l513"></a> </span><span class=cF2>// set tx buffer length</span><span class=cF0>
<a name="l514"></a> E1000MMIOWrite(E1000_REG_TDLEN, E1000_TX_BUFF_COUNT * </span><span class=cFE>16</span><span class=cF0>);
<a name="l515"></a>
<a name="l516"></a> </span><span class=cF2>// set head tail pointers</span><span class=cF0>
<a name="l517"></a> E1000MMIOWrite(E1000_REG_TDH, </span><span class=cFE>0</span><span class=cF0>);
<a name="l518"></a> E1000MMIOWrite(E1000_REG_TDT, E1000_RX_BUFF_COUNT);
<a name="l519"></a>
<a name="l520"></a> </span><span class=cF2>// set transmit control reg</span><span class=cF0>
<a name="l521"></a> E1000MMIOWrite(E1000_REG_TCTL, E1000_TCTLF_EN | E1000_TCTLF_PSP);
<a name="l522"></a>
<a name="l523"></a>}
<a name="l524"></a>
<a name="l525"></a>
<a name="l526"></a></span><span class=cF1>U0</span><span class=cF0> E1000Init()
<a name="l527"></a>{
<a name="l528"></a> </span><span class=cF9>I64</span><span class=cF0> i;
<a name="l529"></a>
<a name="l530"></a> </span><span class=cF5>MemSet</span><span class=cF0>(&amp;e1000, </span><span class=cFE>0</span><span class=cF0>, </span><span class=cF1>sizeof</span><span class=cF7>(</span><span class=cF0>CE1000</span><span class=cF7>)</span><span class=cF0>); </span><span class=cF2>// e1000 global var will hold member data the driver uses often.</span><span class=cF0>
<a name="l531"></a> </span><span class=cF6>&quot;\nE1000 driver WIP\n\n&quot;</span><span class=cF0>;
<a name="l532"></a>
<a name="l533"></a> e1000.pci = E1000PCIDevFind;
<a name="l534"></a> </span><span class=cF1>if</span><span class=cF0> (!e1000.pci)
<a name="l535"></a> </span><span class=cF1>return</span><span class=cF0>; </span><span class=cF2>// if we don't find the card, quit.</span><span class=cF0>
<a name="l536"></a>
<a name="l537"></a>
<a name="l538"></a> e1000.mmio_address = </span><span class=cFB>dev</span><span class=cF0>.uncached_alias + e1000.pci-&gt;base[</span><span class=cFE>0</span><span class=cF0>] &amp; ~</span><span class=cFE>0xF</span><span class=cF0>;
<a name="l539"></a> </span><span class=cF2>// Assuming card supports MMIO... lower 4 bits are hardwired zero (?)</span><span class=cF0>
<a name="l540"></a>
<a name="l541"></a> </span><span class=cF6>&quot;\nMMIO address: 0x%0X\n&quot;</span><span class=cF0>, e1000.mmio_address;
<a name="l542"></a>
<a name="l543"></a> </span><span class=cF2>// init rx/tx addrs? (linux)</span><span class=cF0>
<a name="l544"></a>
<a name="l545"></a> </span><span class=cF2>// eeprom? MAC ?</span><span class=cF0>
<a name="l546"></a> E1000MACGet;
<a name="l547"></a>
<a name="l548"></a> </span><span class=cF2>// setup link? (01000101's driver)</span><span class=cF0>
<a name="l549"></a> E1000MMIOWrite(E1000_REG_CTRL, E1000MMIORead</span><span class=cF7>(</span><span class=cF0>E1000_REG_CTRL</span><span class=cF7>)</span><span class=cF0> | E1000_CTRLF_SLU);
<a name="l550"></a>
<a name="l551"></a> </span><span class=cF2>// zero out multicast hash? (linux)</span><span class=cF0>
<a name="l552"></a> </span><span class=cF2>// zero out multicast table array (01000101's driver)</span><span class=cF0>
<a name="l553"></a> </span><span class=cF1>for</span><span class=cF0> (i = </span><span class=cFE>0</span><span class=cF0>; i &lt; </span><span class=cFE>128</span><span class=cF0>; i++)
<a name="l554"></a> E1000MMIOWrite(E1000_REG_MTA + i*</span><span class=cFE>4</span><span class=cF0>, </span><span class=cFE>0</span><span class=cF0>);
<a name="l555"></a>
<a name="l556"></a> </span><span class=cF2>// setup link? (linux)</span><span class=cF0>
<a name="l557"></a>
<a name="l558"></a> </span><span class=cF2>// clear all statistics regs after link establish attempt (linux)</span><span class=cF0>
<a name="l559"></a>
<a name="l560"></a> </span><span class=cF2>// enable &amp; clear existing interupts (01000101's driver)</span><span class=cF0>
<a name="l561"></a> E1000MMIOWrite(E1000_REG_IMS, E1000_IMSF_LSC |
<a name="l562"></a> E1000_IMSF_RXSEQ |
<a name="l563"></a> E1000_IMSF_RXDMT |
<a name="l564"></a> E1000_IMSF_RXO |
<a name="l565"></a> E1000_IMSF_RXT |
<a name="l566"></a> E1000_IMSF_MDAC |
<a name="l567"></a> E1000_IMSF_RXCFG |
<a name="l568"></a> E1000_IMSF_PHYINT |
<a name="l569"></a> E1000_IMSF_GPI |
<a name="l570"></a> E1000_IMSF_TXDLOW |
<a name="l571"></a> E1000_IMSF_SRPD);
<a name="l572"></a>
<a name="l573"></a> E1000MMIORead(E1000_REG_ICR); </span><span class=cF2>// clear pending interrupts ?</span><span class=cF0>
<a name="l574"></a>
<a name="l575"></a> </span><span class=cF2>// start rx tx?</span><span class=cF0>
<a name="l576"></a> E1000InitRX;
<a name="l577"></a> E1000InitTX;
<a name="l578"></a>
<a name="l579"></a> E1000InterruptsSetup;
<a name="l580"></a>
<a name="l581"></a>
<a name="l582"></a> NetErr(</span><span class=cF6>&quot;TODO E1000&quot;</span><span class=cF0>);
<a name="l583"></a> </span><span class=cF6>&quot;\n&quot;</span><span class=cF0>;
<a name="l584"></a> </span><span class=cF5>ClassRep</span><span class=cF0>(&amp;e1000);
<a name="l585"></a>}
<a name="l586"></a>
<a name="l587"></a></span><span class=cF9>I64</span><span class=cF0> EthernetFrameAllocate(</span><span class=cF1>U8</span><span class=cF0> **packet_buffer_out,
<a name="l588"></a> </span><span class=cF1>U8</span><span class=cF0> *source_address,
<a name="l589"></a> </span><span class=cF1>U8</span><span class=cF0> *destination_address,
<a name="l590"></a> </span><span class=cF9>U16</span><span class=cF0> ethertype,
<a name="l591"></a> </span><span class=cF9>I64</span><span class=cF0> packet_length)
<a name="l592"></a>{
<a name="l593"></a> </span><span class=cF1>U8</span><span class=cF0> *ethernet_frame;
<a name="l594"></a> </span><span class=cF9>I64</span><span class=cF0> de_index;
<a name="l595"></a>
<a name="l596"></a> </span><span class=cF1>if</span><span class=cF0> (packet_length &lt; ETHERNET_MIN_FRAME_SIZE)
<a name="l597"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l598"></a> NetWarn(</span><span class=cF6>&quot;ETHERNET FRAME ALLOCATE: Truncating length&quot;</span><span class=cF0>);
<a name="l599"></a> packet_length = ETHERNET_MIN_FRAME_SIZE;
<a name="l600"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l601"></a>
<a name="l602"></a> de_index = E1000TransmitPacketAllocate(&amp;ethernet_frame, ETHERNET_MAC_HEADER_LENGTH + packet_length);
<a name="l603"></a>
<a name="l604"></a> </span><span class=cF1>if</span><span class=cF0> (de_index &lt; </span><span class=cFE>0</span><span class=cF0>)
<a name="l605"></a> </span><span class=cF7>{</span><span class=cF0>
<a name="l606"></a> NetErr(</span><span class=cF6>&quot;ETHERNET FRAME ALLOCATE: Failure&quot;</span><span class=cF0>);
<a name="l607"></a> </span><span class=cF1>return</span><span class=cF0> -</span><span class=cFE>1</span><span class=cF0>; </span><span class=cF2>// Positive value expected. Functions calling this must factor this in.</span><span class=cF0>
<a name="l608"></a> </span><span class=cF7>}</span><span class=cF0>
<a name="l609"></a>
<a name="l610"></a> </span><span class=cF5>MemCopy</span><span class=cF0>(ethernet_frame, destination_address, MAC_ADDRESS_LENGTH);
<a name="l611"></a> </span><span class=cF5>MemCopy</span><span class=cF0>(ethernet_frame + MAC_ADDRESS_LENGTH, source_address, MAC_ADDRESS_LENGTH);
<a name="l612"></a>
<a name="l613"></a> ethernet_frame[ETHERNET_ETHERTYPE_OFFSET] = ethertype &gt;&gt; </span><span class=cFE>8</span><span class=cF0>;
<a name="l614"></a> ethernet_frame[ETHERNET_ETHERTYPE_OFFSET + </span><span class=cFE>1</span><span class=cF0>] = ethertype &amp; </span><span class=cFE>0xFF</span><span class=cF0>;
<a name="l615"></a>
<a name="l616"></a> *packet_buffer_out = ethernet_frame + ETHERNET_MAC_HEADER_LENGTH;
<a name="l617"></a>
<a name="l618"></a> </span><span class=cF1>return</span><span class=cF0> de_index;
<a name="l619"></a>
<a name="l620"></a>}
<a name="l621"></a>
<a name="l622"></a></span><span class=cF1>U8</span><span class=cF0> *EthernetMACGet()
<a name="l623"></a>{
<a name="l624"></a> </span><span class=cF1>return</span><span class=cF0> e1000.mac_address;
<a name="l625"></a>}
<a name="l626"></a>
<a name="l627"></a></span><span class=cF1>U0</span><span class=cF0> NetStop()
<a name="l628"></a>{
<a name="l629"></a>
<a name="l630"></a>}
<a name="l631"></a>
<a name="l632"></a></span><span class=cF1>U0</span><span class=cF0> NetStart()
<a name="l633"></a>{
<a name="l634"></a>
<a name="l635"></a>}
<a name="l636"></a>
<a name="l637"></a>E1000Init;</span></pre></body>
</html>
Reference in a new issue View git blame Copy permalink