DevE1000.cpp@ 85146

Last change on this file since 85146 was 85146, checked in by vboxsync, 4 years ago
Dev/E1000,PDM: (bugref:9764) disable UFO, UDP header checks, zero MSS handling.
Property svn:eol-style set to `native` Property svn:keywords set to `Author Date Id Revision`
File size: 326.0 KB

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1	/* $Id: DevE1000.cpp 85146 2020-07-09 10:20:38Z vboxsync $ */
2	/** @file
3	* DevE1000 - Intel 82540EM Ethernet Controller Emulation.
4	*
5	* Implemented in accordance with the specification:
6	*
7	* PCI/PCI-X Family of Gigabit Ethernet Controllers Software Developer's Manual
8	* 82540EP/EM, 82541xx, 82544GC/EI, 82545GM/EM, 82546GB/EB, and 82547xx
9	*
10	* 317453-002 Revision 3.5
11	*
12	* @todo IPv6 checksum offloading support
13	* @todo Flexible Filter / Wakeup (optional?)
14	*/
15
16	/*
17	* Copyright (C) 2007-2020 Oracle Corporation
18	*
19	* This file is part of VirtualBox Open Source Edition (OSE), as
20	* available from http://www.virtualbox.org. This file is free software;
21	* you can redistribute it and/or modify it under the terms of the GNU
22	* General Public License (GPL) as published by the Free Software
23	* Foundation, in version 2 as it comes in the "COPYING" file of the
24	* VirtualBox OSE distribution. VirtualBox OSE is distributed in the
25	* hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
26	*/
27
28
29	/*********************************************************************************************************************************
30	* Header Files *
31	*********************************************************************************************************************************/
32	#define LOG_GROUP LOG_GROUP_DEV_E1000
33	#include <iprt/crc.h>
34	#include <iprt/ctype.h>
35	#include <iprt/net.h>
36	#include <iprt/semaphore.h>
37	#include <iprt/string.h>
38	#include <iprt/time.h>
39	#include <iprt/uuid.h>
40	#include <VBox/vmm/pdmdev.h>
41	#include <VBox/vmm/pdmnetifs.h>
42	#include <VBox/vmm/pdmnetinline.h>
43	#include <VBox/param.h>
44	#include "VBoxDD.h"
45
46	#include "DevEEPROM.h"
47	#include "DevE1000Phy.h"
48
49
50	/*********************************************************************************************************************************
51	* Defined Constants And Macros *
52	*********************************************************************************************************************************/
53	/** @name E1000 Build Options
54	* @{ */
55	/** @def E1K_INIT_RA0
56	* E1K_INIT_RA0 forces E1000 to set the first entry in Receive Address filter
57	* table to MAC address obtained from CFGM. Most guests read MAC address from
58	* EEPROM and write it to RA[0] explicitly, but Mac OS X seems to depend on it
59	* being already set (see @bugref{4657}).
60	*/
61	#define E1K_INIT_RA0
62	/** @def E1K_LSC_ON_RESET
63	* E1K_LSC_ON_RESET causes e1000 to generate Link Status Change
64	* interrupt after hard reset. This makes the E1K_LSC_ON_SLU option unnecessary.
65	* With unplugged cable, LSC is triggerred for 82543GC only.
66	*/
67	#define E1K_LSC_ON_RESET
68	/** @def E1K_LSC_ON_SLU
69	* E1K_LSC_ON_SLU causes E1000 to generate Link Status Change interrupt when
70	* the guest driver brings up the link via STATUS.LU bit. Again the only guest
71	* that requires it is Mac OS X (see @bugref{4657}).
72	*/
73	//#define E1K_LSC_ON_SLU
74	/** @def E1K_INIT_LINKUP_DELAY
75	* E1K_INIT_LINKUP_DELAY prevents the link going up while the driver is still
76	* in init (see @bugref{8624}).
77	*/
78	#define E1K_INIT_LINKUP_DELAY_US (2000 * 1000)
79	/** @def E1K_IMS_INT_DELAY_NS
80	* E1K_IMS_INT_DELAY_NS prevents interrupt storms in Windows guests on enabling
81	* interrupts (see @bugref{8624}).
82	*/
83	#define E1K_IMS_INT_DELAY_NS 100
84	/** @def E1K_TX_DELAY
85	* E1K_TX_DELAY aims to improve guest-host transfer rate for TCP streams by
86	* preventing packets to be sent immediately. It allows to send several
87	* packets in a batch reducing the number of acknowledgments. Note that it
88	* effectively disables R0 TX path, forcing sending in R3.
89	*/
90	//#define E1K_TX_DELAY 150
91	/** @def E1K_USE_TX_TIMERS
92	* E1K_USE_TX_TIMERS aims to reduce the number of generated TX interrupts if a
93	* guest driver set the delays via the Transmit Interrupt Delay Value (TIDV)
94	* register. Enabling it showed no positive effects on existing guests so it
95	* stays disabled. See sections 3.2.7.1 and 3.4.3.1 in "8254x Family of Gigabit
96	* Ethernet Controllers Software Developer’s Manual" for more detailed
97	* explanation.
98	*/
99	//#define E1K_USE_TX_TIMERS
100	/** @def E1K_NO_TAD
101	* E1K_NO_TAD disables one of two timers enabled by E1K_USE_TX_TIMERS, the
102	* Transmit Absolute Delay time. This timer sets the maximum time interval
103	* during which TX interrupts can be postponed (delayed). It has no effect
104	* if E1K_USE_TX_TIMERS is not defined.
105	*/
106	//#define E1K_NO_TAD
107	/** @def E1K_REL_DEBUG
108	* E1K_REL_DEBUG enables debug logging of l1, l2, l3 in release build.
109	*/
110	//#define E1K_REL_DEBUG
111	/** @def E1K_INT_STATS
112	* E1K_INT_STATS enables collection of internal statistics used for
113	* debugging of delayed interrupts, etc.
114	*/
115	#define E1K_INT_STATS
116	/** @def E1K_WITH_MSI
117	* E1K_WITH_MSI enables rudimentary MSI support. Not implemented.
118	*/
119	//#define E1K_WITH_MSI
120	/** @def E1K_WITH_TX_CS
121	* E1K_WITH_TX_CS protects e1kXmitPending with a critical section.
122	*/
123	#define E1K_WITH_TX_CS
124	/** @def E1K_WITH_TXD_CACHE
125	* E1K_WITH_TXD_CACHE causes E1000 to fetch multiple TX descriptors in a
126	* single physical memory read (or two if it wraps around the end of TX
127	* descriptor ring). It is required for proper functioning of bandwidth
128	* resource control as it allows to compute exact sizes of packets prior
129	* to allocating their buffers (see @bugref{5582}).
130	*/
131	#define E1K_WITH_TXD_CACHE
132	/** @def E1K_WITH_RXD_CACHE
133	* E1K_WITH_RXD_CACHE causes E1000 to fetch multiple RX descriptors in a
134	* single physical memory read (or two if it wraps around the end of RX
135	* descriptor ring). Intel's packet driver for DOS needs this option in
136	* order to work properly (see @bugref{6217}).
137	*/
138	#define E1K_WITH_RXD_CACHE
139	/** @def E1K_WITH_PREREG_MMIO
140	* E1K_WITH_PREREG_MMIO enables a new style MMIO registration and is
141	* currently only done for testing the relateted PDM, IOM and PGM code. */
142	//#define E1K_WITH_PREREG_MMIO
143	/* @} */
144	/* End of Options ************************************************************/
145
146	#ifdef E1K_WITH_TXD_CACHE
147	/**
148	* E1K_TXD_CACHE_SIZE specifies the maximum number of TX descriptors stored
149	* in the state structure. It limits the amount of descriptors loaded in one
150	* batch read. For example, Linux guest may use up to 20 descriptors per
151	* TSE packet. The largest TSE packet seen (Windows guest) was 45 descriptors.
152	*/
153	# define E1K_TXD_CACHE_SIZE 64u
154	#endif /* E1K_WITH_TXD_CACHE */
155
156	#ifdef E1K_WITH_RXD_CACHE
157	/**
158	* E1K_RXD_CACHE_SIZE specifies the maximum number of RX descriptors stored
159	* in the state structure. It limits the amount of descriptors loaded in one
160	* batch read. For example, XP guest adds 15 RX descriptors at a time.
161	*/
162	# define E1K_RXD_CACHE_SIZE 16u
163	#endif /* E1K_WITH_RXD_CACHE */
164
165
166	/* Little helpers ************************************************************/
167	#undef htons
168	#undef ntohs
169	#undef htonl
170	#undef ntohl
171	#define htons(x) ((((x) & 0xff00) >> 8) \| (((x) & 0x00ff) << 8))
172	#define ntohs(x) htons(x)
173	#define htonl(x) ASMByteSwapU32(x)
174	#define ntohl(x) htonl(x)
175
176	#ifndef DEBUG
177	# ifdef E1K_REL_DEBUG
178	# define DEBUG
179	# define E1kLog(a) LogRel(a)
180	# define E1kLog2(a) LogRel(a)
181	# define E1kLog3(a) LogRel(a)
182	# define E1kLogX(x, a) LogRel(a)
183	//# define E1kLog3(a) do {} while (0)
184	# else
185	# define E1kLog(a) do {} while (0)
186	# define E1kLog2(a) do {} while (0)
187	# define E1kLog3(a) do {} while (0)
188	# define E1kLogX(x, a) do {} while (0)
189	# endif
190	#else
191	# define E1kLog(a) Log(a)
192	# define E1kLog2(a) Log2(a)
193	# define E1kLog3(a) Log3(a)
194	# define E1kLogX(x, a) LogIt(x, LOG_GROUP, a)
195	//# define E1kLog(a) do {} while (0)
196	//# define E1kLog2(a) do {} while (0)
197	//# define E1kLog3(a) do {} while (0)
198	#endif
199
200	#if 0
201	# define LOG_ENABLED
202	# define E1kLogRel(a) LogRel(a)
203	# undef Log6
204	# define Log6(a) LogRel(a)
205	#else
206	# define E1kLogRel(a) do { } while (0)
207	#endif
208
209	//#undef DEBUG
210
211	#define E1K_RELOCATE(p, o) (RTHCUINTPTR )&p += o
212
213	#define E1K_INC_CNT32(cnt) \
214	do { \
215	if (cnt < UINT32_MAX) \
216	cnt++; \
217	} while (0)
218
219	#define E1K_ADD_CNT64(cntLo, cntHi, val) \
220	do { \
221	uint64_t u64Cnt = RT_MAKE_U64(cntLo, cntHi); \
222	uint64_t tmp = u64Cnt; \
223	u64Cnt += val; \
224	if (tmp > u64Cnt ) \
225	u64Cnt = UINT64_MAX; \
226	cntLo = (uint32_t)u64Cnt; \
227	cntHi = (uint32_t)(u64Cnt >> 32); \
228	} while (0)
229
230	#ifdef E1K_INT_STATS
231	# define E1K_INC_ISTAT_CNT(cnt) do { ++cnt; } while (0)
232	#else /* E1K_INT_STATS */
233	# define E1K_INC_ISTAT_CNT(cnt) do { } while (0)
234	#endif /* E1K_INT_STATS */
235
236
237	/*****************************************************************************/
238
239	typedef uint32_t E1KCHIP;
240	#define E1K_CHIP_82540EM 0
241	#define E1K_CHIP_82543GC 1
242	#define E1K_CHIP_82545EM 2
243
244	#ifdef IN_RING3
245	/** Different E1000 chips. */
246	static const struct E1kChips
247	{
248	uint16_t uPCIVendorId;
249	uint16_t uPCIDeviceId;
250	uint16_t uPCISubsystemVendorId;
251	uint16_t uPCISubsystemId;
252	const char *pcszName;
253	} g_aChips[] =
254	{
255	/* Vendor Device SSVendor SubSys Name */
256	{ 0x8086,
257	/* Temporary code, as MSI-aware driver dislike 0x100E. How to do that right? */
258	# ifdef E1K_WITH_MSI
259	0x105E,
260	# else
261	0x100E,
262	# endif
263	0x8086, 0x001E, "82540EM" }, /* Intel 82540EM-A in Intel PRO/1000 MT Desktop */
264	{ 0x8086, 0x1004, 0x8086, 0x1004, "82543GC" }, /* Intel 82543GC in Intel PRO/1000 T Server */
265	{ 0x8086, 0x100F, 0x15AD, 0x0750, "82545EM" } /* Intel 82545EM-A in VMWare Network Adapter */
266	};
267	#endif /* IN_RING3 */
268
269
270	/* The size of register area mapped to I/O space */
271	#define E1K_IOPORT_SIZE 0x8
272	/* The size of memory-mapped register area */
273	#define E1K_MM_SIZE 0x20000
274
275	#define E1K_MAX_TX_PKT_SIZE 16288
276	#define E1K_MAX_RX_PKT_SIZE 16384
277
278	/*****************************************************************************/
279
280	/** Gets the specfieid bits from the register. */
281	#define GET_BITS(reg, bits) ((reg & reg##_##bits##_MASK) >> reg##_##bits##_SHIFT)
282	#define GET_BITS_V(val, reg, bits) ((val & reg##_##bits##_MASK) >> reg##_##bits##_SHIFT)
283	#define BITS(reg, bits, bitval) (bitval << reg##_##bits##_SHIFT)
284	#define SET_BITS(reg, bits, bitval) do { reg = (reg & ~reg##_##bits##_MASK) \| (bitval << reg##_##bits##_SHIFT); } while (0)
285	#define SET_BITS_V(val, reg, bits, bitval) do { val = (val & ~reg##_##bits##_MASK) \| (bitval << reg##_##bits##_SHIFT); } while (0)
286
287	#define CTRL_SLU UINT32_C(0x00000040)
288	#define CTRL_MDIO UINT32_C(0x00100000)
289	#define CTRL_MDC UINT32_C(0x00200000)
290	#define CTRL_MDIO_DIR UINT32_C(0x01000000)
291	#define CTRL_MDC_DIR UINT32_C(0x02000000)
292	#define CTRL_RESET UINT32_C(0x04000000)
293	#define CTRL_VME UINT32_C(0x40000000)
294
295	#define STATUS_LU UINT32_C(0x00000002)
296	#define STATUS_TXOFF UINT32_C(0x00000010)
297
298	#define EECD_EE_WIRES UINT32_C(0x0F)
299	#define EECD_EE_REQ UINT32_C(0x40)
300	#define EECD_EE_GNT UINT32_C(0x80)
301
302	#define EERD_START UINT32_C(0x00000001)
303	#define EERD_DONE UINT32_C(0x00000010)
304	#define EERD_DATA_MASK UINT32_C(0xFFFF0000)
305	#define EERD_DATA_SHIFT 16
306	#define EERD_ADDR_MASK UINT32_C(0x0000FF00)
307	#define EERD_ADDR_SHIFT 8
308
309	#define MDIC_DATA_MASK UINT32_C(0x0000FFFF)
310	#define MDIC_DATA_SHIFT 0
311	#define MDIC_REG_MASK UINT32_C(0x001F0000)
312	#define MDIC_REG_SHIFT 16
313	#define MDIC_PHY_MASK UINT32_C(0x03E00000)
314	#define MDIC_PHY_SHIFT 21
315	#define MDIC_OP_WRITE UINT32_C(0x04000000)
316	#define MDIC_OP_READ UINT32_C(0x08000000)
317	#define MDIC_READY UINT32_C(0x10000000)
318	#define MDIC_INT_EN UINT32_C(0x20000000)
319	#define MDIC_ERROR UINT32_C(0x40000000)
320
321	#define TCTL_EN UINT32_C(0x00000002)
322	#define TCTL_PSP UINT32_C(0x00000008)
323
324	#define RCTL_EN UINT32_C(0x00000002)
325	#define RCTL_UPE UINT32_C(0x00000008)
326	#define RCTL_MPE UINT32_C(0x00000010)
327	#define RCTL_LPE UINT32_C(0x00000020)
328	#define RCTL_LBM_MASK UINT32_C(0x000000C0)
329	#define RCTL_LBM_SHIFT 6
330	#define RCTL_RDMTS_MASK UINT32_C(0x00000300)
331	#define RCTL_RDMTS_SHIFT 8
332	#define RCTL_LBM_TCVR UINT32_C(3) /*< PHY or external SerDes loopback. /
333	#define RCTL_MO_MASK UINT32_C(0x00003000)
334	#define RCTL_MO_SHIFT 12
335	#define RCTL_BAM UINT32_C(0x00008000)
336	#define RCTL_BSIZE_MASK UINT32_C(0x00030000)
337	#define RCTL_BSIZE_SHIFT 16
338	#define RCTL_VFE UINT32_C(0x00040000)
339	#define RCTL_CFIEN UINT32_C(0x00080000)
340	#define RCTL_CFI UINT32_C(0x00100000)
341	#define RCTL_BSEX UINT32_C(0x02000000)
342	#define RCTL_SECRC UINT32_C(0x04000000)
343
344	#define ICR_TXDW UINT32_C(0x00000001)
345	#define ICR_TXQE UINT32_C(0x00000002)
346	#define ICR_LSC UINT32_C(0x00000004)
347	#define ICR_RXDMT0 UINT32_C(0x00000010)
348	#define ICR_RXT0 UINT32_C(0x00000080)
349	#define ICR_TXD_LOW UINT32_C(0x00008000)
350	#define RDTR_FPD UINT32_C(0x80000000)
351
352	#define PBA_st ((PBAST*)(pThis->auRegs + PBA_IDX))
353	typedef struct
354	{
355	unsigned rxa : 7;
356	unsigned rxa_r : 9;
357	unsigned txa : 16;
358	} PBAST;
359	AssertCompileSize(PBAST, 4);
360
361	#define TXDCTL_WTHRESH_MASK 0x003F0000
362	#define TXDCTL_WTHRESH_SHIFT 16
363	#define TXDCTL_LWTHRESH_MASK 0xFE000000
364	#define TXDCTL_LWTHRESH_SHIFT 25
365
366	#define RXCSUM_PCSS_MASK UINT32_C(0x000000FF)
367	#define RXCSUM_PCSS_SHIFT 0
368
369	/** @name Register access macros
370	* @remarks These ASSUME alocal variable @a pThis of type PE1KSTATE.
371	* @{ */
372	#define CTRL pThis->auRegs[CTRL_IDX]
373	#define STATUS pThis->auRegs[STATUS_IDX]
374	#define EECD pThis->auRegs[EECD_IDX]
375	#define EERD pThis->auRegs[EERD_IDX]
376	#define CTRL_EXT pThis->auRegs[CTRL_EXT_IDX]
377	#define FLA pThis->auRegs[FLA_IDX]
378	#define MDIC pThis->auRegs[MDIC_IDX]
379	#define FCAL pThis->auRegs[FCAL_IDX]
380	#define FCAH pThis->auRegs[FCAH_IDX]
381	#define FCT pThis->auRegs[FCT_IDX]
382	#define VET pThis->auRegs[VET_IDX]
383	#define ICR pThis->auRegs[ICR_IDX]
384	#define ITR pThis->auRegs[ITR_IDX]
385	#define ICS pThis->auRegs[ICS_IDX]
386	#define IMS pThis->auRegs[IMS_IDX]
387	#define IMC pThis->auRegs[IMC_IDX]
388	#define RCTL pThis->auRegs[RCTL_IDX]
389	#define FCTTV pThis->auRegs[FCTTV_IDX]
390	#define TXCW pThis->auRegs[TXCW_IDX]
391	#define RXCW pThis->auRegs[RXCW_IDX]
392	#define TCTL pThis->auRegs[TCTL_IDX]
393	#define TIPG pThis->auRegs[TIPG_IDX]
394	#define AIFS pThis->auRegs[AIFS_IDX]
395	#define LEDCTL pThis->auRegs[LEDCTL_IDX]
396	#define PBA pThis->auRegs[PBA_IDX]
397	#define FCRTL pThis->auRegs[FCRTL_IDX]
398	#define FCRTH pThis->auRegs[FCRTH_IDX]
399	#define RDFH pThis->auRegs[RDFH_IDX]
400	#define RDFT pThis->auRegs[RDFT_IDX]
401	#define RDFHS pThis->auRegs[RDFHS_IDX]
402	#define RDFTS pThis->auRegs[RDFTS_IDX]
403	#define RDFPC pThis->auRegs[RDFPC_IDX]
404	#define RDBAL pThis->auRegs[RDBAL_IDX]
405	#define RDBAH pThis->auRegs[RDBAH_IDX]
406	#define RDLEN pThis->auRegs[RDLEN_IDX]
407	#define RDH pThis->auRegs[RDH_IDX]
408	#define RDT pThis->auRegs[RDT_IDX]
409	#define RDTR pThis->auRegs[RDTR_IDX]
410	#define RXDCTL pThis->auRegs[RXDCTL_IDX]
411	#define RADV pThis->auRegs[RADV_IDX]
412	#define RSRPD pThis->auRegs[RSRPD_IDX]
413	#define TXDMAC pThis->auRegs[TXDMAC_IDX]
414	#define TDFH pThis->auRegs[TDFH_IDX]
415	#define TDFT pThis->auRegs[TDFT_IDX]
416	#define TDFHS pThis->auRegs[TDFHS_IDX]
417	#define TDFTS pThis->auRegs[TDFTS_IDX]
418	#define TDFPC pThis->auRegs[TDFPC_IDX]
419	#define TDBAL pThis->auRegs[TDBAL_IDX]
420	#define TDBAH pThis->auRegs[TDBAH_IDX]
421	#define TDLEN pThis->auRegs[TDLEN_IDX]
422	#define TDH pThis->auRegs[TDH_IDX]
423	#define TDT pThis->auRegs[TDT_IDX]
424	#define TIDV pThis->auRegs[TIDV_IDX]
425	#define TXDCTL pThis->auRegs[TXDCTL_IDX]
426	#define TADV pThis->auRegs[TADV_IDX]
427	#define TSPMT pThis->auRegs[TSPMT_IDX]
428	#define CRCERRS pThis->auRegs[CRCERRS_IDX]
429	#define ALGNERRC pThis->auRegs[ALGNERRC_IDX]
430	#define SYMERRS pThis->auRegs[SYMERRS_IDX]
431	#define RXERRC pThis->auRegs[RXERRC_IDX]
432	#define MPC pThis->auRegs[MPC_IDX]
433	#define SCC pThis->auRegs[SCC_IDX]
434	#define ECOL pThis->auRegs[ECOL_IDX]
435	#define MCC pThis->auRegs[MCC_IDX]
436	#define LATECOL pThis->auRegs[LATECOL_IDX]
437	#define COLC pThis->auRegs[COLC_IDX]
438	#define DC pThis->auRegs[DC_IDX]
439	#define TNCRS pThis->auRegs[TNCRS_IDX]
440	/* #define SEC pThis->auRegs[SEC_IDX] Conflict with sys/time.h */
441	#define CEXTERR pThis->auRegs[CEXTERR_IDX]
442	#define RLEC pThis->auRegs[RLEC_IDX]
443	#define XONRXC pThis->auRegs[XONRXC_IDX]
444	#define XONTXC pThis->auRegs[XONTXC_IDX]
445	#define XOFFRXC pThis->auRegs[XOFFRXC_IDX]
446	#define XOFFTXC pThis->auRegs[XOFFTXC_IDX]
447	#define FCRUC pThis->auRegs[FCRUC_IDX]
448	#define PRC64 pThis->auRegs[PRC64_IDX]
449	#define PRC127 pThis->auRegs[PRC127_IDX]
450	#define PRC255 pThis->auRegs[PRC255_IDX]
451	#define PRC511 pThis->auRegs[PRC511_IDX]
452	#define PRC1023 pThis->auRegs[PRC1023_IDX]
453	#define PRC1522 pThis->auRegs[PRC1522_IDX]
454	#define GPRC pThis->auRegs[GPRC_IDX]
455	#define BPRC pThis->auRegs[BPRC_IDX]
456	#define MPRC pThis->auRegs[MPRC_IDX]
457	#define GPTC pThis->auRegs[GPTC_IDX]
458	#define GORCL pThis->auRegs[GORCL_IDX]
459	#define GORCH pThis->auRegs[GORCH_IDX]
460	#define GOTCL pThis->auRegs[GOTCL_IDX]
461	#define GOTCH pThis->auRegs[GOTCH_IDX]
462	#define RNBC pThis->auRegs[RNBC_IDX]
463	#define RUC pThis->auRegs[RUC_IDX]
464	#define RFC pThis->auRegs[RFC_IDX]
465	#define ROC pThis->auRegs[ROC_IDX]
466	#define RJC pThis->auRegs[RJC_IDX]
467	#define MGTPRC pThis->auRegs[MGTPRC_IDX]
468	#define MGTPDC pThis->auRegs[MGTPDC_IDX]
469	#define MGTPTC pThis->auRegs[MGTPTC_IDX]
470	#define TORL pThis->auRegs[TORL_IDX]
471	#define TORH pThis->auRegs[TORH_IDX]
472	#define TOTL pThis->auRegs[TOTL_IDX]
473	#define TOTH pThis->auRegs[TOTH_IDX]
474	#define TPR pThis->auRegs[TPR_IDX]
475	#define TPT pThis->auRegs[TPT_IDX]
476	#define PTC64 pThis->auRegs[PTC64_IDX]
477	#define PTC127 pThis->auRegs[PTC127_IDX]
478	#define PTC255 pThis->auRegs[PTC255_IDX]
479	#define PTC511 pThis->auRegs[PTC511_IDX]
480	#define PTC1023 pThis->auRegs[PTC1023_IDX]
481	#define PTC1522 pThis->auRegs[PTC1522_IDX]
482	#define MPTC pThis->auRegs[MPTC_IDX]
483	#define BPTC pThis->auRegs[BPTC_IDX]
484	#define TSCTC pThis->auRegs[TSCTC_IDX]
485	#define TSCTFC pThis->auRegs[TSCTFC_IDX]
486	#define RXCSUM pThis->auRegs[RXCSUM_IDX]
487	#define WUC pThis->auRegs[WUC_IDX]
488	#define WUFC pThis->auRegs[WUFC_IDX]
489	#define WUS pThis->auRegs[WUS_IDX]
490	#define MANC pThis->auRegs[MANC_IDX]
491	#define IPAV pThis->auRegs[IPAV_IDX]
492	#define WUPL pThis->auRegs[WUPL_IDX]
493	/** @} */
494
495	/**
496	* Indices of memory-mapped registers in register table.
497	*/
498	typedef enum
499	{
500	CTRL_IDX,
501	STATUS_IDX,
502	EECD_IDX,
503	EERD_IDX,
504	CTRL_EXT_IDX,
505	FLA_IDX,
506	MDIC_IDX,
507	FCAL_IDX,
508	FCAH_IDX,
509	FCT_IDX,
510	VET_IDX,
511	ICR_IDX,
512	ITR_IDX,
513	ICS_IDX,
514	IMS_IDX,
515	IMC_IDX,
516	RCTL_IDX,
517	FCTTV_IDX,
518	TXCW_IDX,
519	RXCW_IDX,
520	TCTL_IDX,
521	TIPG_IDX,
522	AIFS_IDX,
523	LEDCTL_IDX,
524	PBA_IDX,
525	FCRTL_IDX,
526	FCRTH_IDX,
527	RDFH_IDX,
528	RDFT_IDX,
529	RDFHS_IDX,
530	RDFTS_IDX,
531	RDFPC_IDX,
532	RDBAL_IDX,
533	RDBAH_IDX,
534	RDLEN_IDX,
535	RDH_IDX,
536	RDT_IDX,
537	RDTR_IDX,
538	RXDCTL_IDX,
539	RADV_IDX,
540	RSRPD_IDX,
541	TXDMAC_IDX,
542	TDFH_IDX,
543	TDFT_IDX,
544	TDFHS_IDX,
545	TDFTS_IDX,
546	TDFPC_IDX,
547	TDBAL_IDX,
548	TDBAH_IDX,
549	TDLEN_IDX,
550	TDH_IDX,
551	TDT_IDX,
552	TIDV_IDX,
553	TXDCTL_IDX,
554	TADV_IDX,
555	TSPMT_IDX,
556	CRCERRS_IDX,
557	ALGNERRC_IDX,
558	SYMERRS_IDX,
559	RXERRC_IDX,
560	MPC_IDX,
561	SCC_IDX,
562	ECOL_IDX,
563	MCC_IDX,
564	LATECOL_IDX,
565	COLC_IDX,
566	DC_IDX,
567	TNCRS_IDX,
568	SEC_IDX,
569	CEXTERR_IDX,
570	RLEC_IDX,
571	XONRXC_IDX,
572	XONTXC_IDX,
573	XOFFRXC_IDX,
574	XOFFTXC_IDX,
575	FCRUC_IDX,
576	PRC64_IDX,
577	PRC127_IDX,
578	PRC255_IDX,
579	PRC511_IDX,
580	PRC1023_IDX,
581	PRC1522_IDX,
582	GPRC_IDX,
583	BPRC_IDX,
584	MPRC_IDX,
585	GPTC_IDX,
586	GORCL_IDX,
587	GORCH_IDX,
588	GOTCL_IDX,
589	GOTCH_IDX,
590	RNBC_IDX,
591	RUC_IDX,
592	RFC_IDX,
593	ROC_IDX,
594	RJC_IDX,
595	MGTPRC_IDX,
596	MGTPDC_IDX,
597	MGTPTC_IDX,
598	TORL_IDX,
599	TORH_IDX,
600	TOTL_IDX,
601	TOTH_IDX,
602	TPR_IDX,
603	TPT_IDX,
604	PTC64_IDX,
605	PTC127_IDX,
606	PTC255_IDX,
607	PTC511_IDX,
608	PTC1023_IDX,
609	PTC1522_IDX,
610	MPTC_IDX,
611	BPTC_IDX,
612	TSCTC_IDX,
613	TSCTFC_IDX,
614	RXCSUM_IDX,
615	WUC_IDX,
616	WUFC_IDX,
617	WUS_IDX,
618	MANC_IDX,
619	IPAV_IDX,
620	WUPL_IDX,
621	MTA_IDX,
622	RA_IDX,
623	VFTA_IDX,
624	IP4AT_IDX,
625	IP6AT_IDX,
626	WUPM_IDX,
627	FFLT_IDX,
628	FFMT_IDX,
629	FFVT_IDX,
630	PBM_IDX,
631	RA_82542_IDX,
632	MTA_82542_IDX,
633	VFTA_82542_IDX,
634	E1K_NUM_OF_REGS
635	} E1kRegIndex;
636
637	#define E1K_NUM_OF_32BIT_REGS MTA_IDX
638	/** The number of registers with strictly increasing offset. */
639	#define E1K_NUM_OF_BINARY_SEARCHABLE (WUPL_IDX + 1)
640
641
642	/**
643	* Define E1000-specific EEPROM layout.
644	*/
645	struct E1kEEPROM
646	{
647	public:
648	EEPROM93C46 eeprom;
649
650	#ifdef IN_RING3
651	/**
652	* Initialize EEPROM content.
653	*
654	* @param macAddr MAC address of E1000.
655	*/
656	void init(RTMAC &macAddr)
657	{
658	eeprom.init();
659	memcpy(eeprom.m_au16Data, macAddr.au16, sizeof(macAddr.au16));
660	eeprom.m_au16Data[0x04] = 0xFFFF;
661	/*
662	* bit 3 - full support for power management
663	* bit 10 - full duplex
664	*/
665	eeprom.m_au16Data[0x0A] = 0x4408;
666	eeprom.m_au16Data[0x0B] = 0x001E;
667	eeprom.m_au16Data[0x0C] = 0x8086;
668	eeprom.m_au16Data[0x0D] = 0x100E;
669	eeprom.m_au16Data[0x0E] = 0x8086;
670	eeprom.m_au16Data[0x0F] = 0x3040;
671	eeprom.m_au16Data[0x21] = 0x7061;
672	eeprom.m_au16Data[0x22] = 0x280C;
673	eeprom.m_au16Data[0x23] = 0x00C8;
674	eeprom.m_au16Data[0x24] = 0x00C8;
675	eeprom.m_au16Data[0x2F] = 0x0602;
676	updateChecksum();
677	};
678
679	/**
680	* Compute the checksum as required by E1000 and store it
681	* in the last word.
682	*/
683	void updateChecksum()
684	{
685	uint16_t u16Checksum = 0;
686
687	for (int i = 0; i < eeprom.SIZE-1; i++)
688	u16Checksum += eeprom.m_au16Data[i];
689	eeprom.m_au16Data[eeprom.SIZE-1] = 0xBABA - u16Checksum;
690	};
691
692	/**
693	* First 6 bytes of EEPROM contain MAC address.
694	*
695	* @returns MAC address of E1000.
696	*/
697	void getMac(PRTMAC pMac)
698	{
699	memcpy(pMac->au16, eeprom.m_au16Data, sizeof(pMac->au16));
700	};
701
702	uint32_t read()
703	{
704	return eeprom.read();
705	}
706
707	void write(uint32_t u32Wires)
708	{
709	eeprom.write(u32Wires);
710	}
711
712	bool readWord(uint32_t u32Addr, uint16_t *pu16Value)
713	{
714	return eeprom.readWord(u32Addr, pu16Value);
715	}
716
717	int load(PCPDMDEVHLPR3 pHlp, PSSMHANDLE pSSM)
718	{
719	return eeprom.load(pHlp, pSSM);
720	}
721
722	void save(PCPDMDEVHLPR3 pHlp, PSSMHANDLE pSSM)
723	{
724	eeprom.save(pHlp, pSSM);
725	}
726	#endif /* IN_RING3 */
727	};
728
729
730	#define E1K_SPEC_VLAN(s) (s & 0xFFF)
731	#define E1K_SPEC_CFI(s) (!!((s>>12) & 0x1))
732	#define E1K_SPEC_PRI(s) ((s>>13) & 0x7)
733
734	struct E1kRxDStatus
735	{
736	/** @name Descriptor Status field (3.2.3.1)
737	* @{ */
738	unsigned fDD : 1; /*< Descriptor Done. /
739	unsigned fEOP : 1; /*< End of packet. /
740	unsigned fIXSM : 1; /*< Ignore checksum indication. /
741	unsigned fVP : 1; /*< VLAN, matches VET. /
742	unsigned : 1;
743	unsigned fTCPCS : 1; /*< RCP Checksum calculated on the packet. /
744	unsigned fIPCS : 1; /*< IP Checksum calculated on the packet. /
745	unsigned fPIF : 1; /*< Passed in-exact filter /
746	/** @} */
747	/** @name Descriptor Errors field (3.2.3.2)
748	* (Only valid when fEOP and fDD are set.)
749	* @{ */
750	unsigned fCE : 1; /*< CRC or alignment error. /
751	unsigned : 4; /*< Reserved, varies with different models... /
752	unsigned fTCPE : 1; /*< TCP/UDP checksum error. /
753	unsigned fIPE : 1; /*< IP Checksum error. /
754	unsigned fRXE : 1; /*< RX Data error. /
755	/** @} */
756	/** @name Descriptor Special field (3.2.3.3)
757	* @{ */
758	unsigned u16Special : 16; /*< VLAN: Id, Canonical form, Priority. /
759	/** @} */
760	};
761	typedef struct E1kRxDStatus E1KRXDST;
762
763	struct E1kRxDesc_st
764	{
765	uint64_t u64BufAddr; /*< Address of data buffer /
766	uint16_t u16Length; /*< Length of data in buffer /
767	uint16_t u16Checksum; /*< Packet checksum /
768	E1KRXDST status;
769	};
770	typedef struct E1kRxDesc_st E1KRXDESC;
771	AssertCompileSize(E1KRXDESC, 16);
772
773	#define E1K_DTYP_LEGACY -1
774	#define E1K_DTYP_CONTEXT 0
775	#define E1K_DTYP_DATA 1
776
777	struct E1kTDLegacy
778	{
779	uint64_t u64BufAddr; /*< Address of data buffer /
780	struct TDLCmd_st
781	{
782	unsigned u16Length : 16;
783	unsigned u8CSO : 8;
784	/* CMD field : 8 */
785	unsigned fEOP : 1;
786	unsigned fIFCS : 1;
787	unsigned fIC : 1;
788	unsigned fRS : 1;
789	unsigned fRPS : 1;
790	unsigned fDEXT : 1;
791	unsigned fVLE : 1;
792	unsigned fIDE : 1;
793	} cmd;
794	struct TDLDw3_st
795	{
796	/* STA field */
797	unsigned fDD : 1;
798	unsigned fEC : 1;
799	unsigned fLC : 1;
800	unsigned fTURSV : 1;
801	/* RSV field */
802	unsigned u4RSV : 4;
803	/* CSS field */
804	unsigned u8CSS : 8;
805	/* Special field*/
806	unsigned u16Special: 16;
807	} dw3;
808	};
809
810	/**
811	* TCP/IP Context Transmit Descriptor, section 3.3.6.
812	*/
813	struct E1kTDContext
814	{
815	struct CheckSum_st
816	{
817	/** TSE: Header start. !TSE: Checksum start. */
818	unsigned u8CSS : 8;
819	/** Checksum offset - where to store it. */
820	unsigned u8CSO : 8;
821	/** Checksum ending (inclusive) offset, 0 = end of packet. */
822	unsigned u16CSE : 16;
823	} ip;
824	struct CheckSum_st tu;
825	struct TDCDw2_st
826	{
827	/** TSE: The total number of payload bytes for this context. Sans header. */
828	unsigned u20PAYLEN : 20;
829	/** The descriptor type - E1K_DTYP_CONTEXT (0). */
830	unsigned u4DTYP : 4;
831	/** TUCMD field, 8 bits
832	* @{ */
833	/** TSE: TCP (set) or UDP (clear). */
834	unsigned fTCP : 1;
835	/** TSE: IPv4 (set) or IPv6 (clear) - for finding the payload length field in
836	* the IP header. Does not affect the checksumming.
837	* @remarks 82544GC/EI interprets a cleared field differently. */
838	unsigned fIP : 1;
839	/** TSE: TCP segmentation enable. When clear the context describes */
840	unsigned fTSE : 1;
841	/** Report status (only applies to dw3.fDD for here). */
842	unsigned fRS : 1;
843	/** Reserved, MBZ. */
844	unsigned fRSV1 : 1;
845	/** Descriptor extension, must be set for this descriptor type. */
846	unsigned fDEXT : 1;
847	/** Reserved, MBZ. */
848	unsigned fRSV2 : 1;
849	/** Interrupt delay enable. */
850	unsigned fIDE : 1;
851	/** @} */
852	} dw2;
853	struct TDCDw3_st
854	{
855	/** Descriptor Done. */
856	unsigned fDD : 1;
857	/** Reserved, MBZ. */
858	unsigned u7RSV : 7;
859	/** TSO: The header (prototype) length (Ethernet[, VLAN tag], IP, TCP/UDP. */
860	unsigned u8HDRLEN : 8;
861	/** TSO: Maximum segment size. */
862	unsigned u16MSS : 16;
863	} dw3;
864	};
865	typedef struct E1kTDContext E1KTXCTX;
866
867	/**
868	* TCP/IP Data Transmit Descriptor, section 3.3.7.
869	*/
870	struct E1kTDData
871	{
872	uint64_t u64BufAddr; /*< Address of data buffer /
873	struct TDDCmd_st
874	{
875	/** The total length of data pointed to by this descriptor. */
876	unsigned u20DTALEN : 20;
877	/** The descriptor type - E1K_DTYP_DATA (1). */
878	unsigned u4DTYP : 4;
879	/** @name DCMD field, 8 bits (3.3.7.1).
880	* @{ */
881	/** End of packet. Note TSCTFC update. */
882	unsigned fEOP : 1;
883	/** Insert Ethernet FCS/CRC (requires fEOP to be set). */
884	unsigned fIFCS : 1;
885	/** Use the TSE context when set and the normal when clear. */
886	unsigned fTSE : 1;
887	/** Report status (dw3.STA). */
888	unsigned fRS : 1;
889	/** Reserved. 82544GC/EI defines this report packet set (RPS). */
890	unsigned fRPS : 1;
891	/** Descriptor extension, must be set for this descriptor type. */
892	unsigned fDEXT : 1;
893	/** VLAN enable, requires CTRL.VME, auto enables FCS/CRC.
894	* Insert dw3.SPECIAL after ethernet header. */
895	unsigned fVLE : 1;
896	/** Interrupt delay enable. */
897	unsigned fIDE : 1;
898	/** @} */
899	} cmd;
900	struct TDDDw3_st
901	{
902	/** @name STA field (3.3.7.2)
903	* @{ */
904	unsigned fDD : 1; /*< Descriptor done. /
905	unsigned fEC : 1; /*< Excess collision. /
906	unsigned fLC : 1; /*< Late collision. /
907	/** Reserved, except for the usual oddball (82544GC/EI) where it's called TU. */
908	unsigned fTURSV : 1;
909	/** @} */
910	unsigned u4RSV : 4; /*< Reserved field, MBZ. /
911	/** @name POPTS (Packet Option) field (3.3.7.3)
912	* @{ */
913	unsigned fIXSM : 1; /*< Insert IP checksum. /
914	unsigned fTXSM : 1; /*< Insert TCP/UDP checksum. /
915	unsigned u6RSV : 6; /*< Reserved, MBZ. /
916	/** @} */
917	/** @name SPECIAL field - VLAN tag to be inserted after ethernet header.
918	* Requires fEOP, fVLE and CTRL.VME to be set.
919	* @{ */
920	unsigned u16Special: 16; /*< VLAN: Id, Canonical form, Priority. /
921	/** @} */
922	} dw3;
923	};
924	typedef struct E1kTDData E1KTXDAT;
925
926	union E1kTxDesc
927	{
928	struct E1kTDLegacy legacy;
929	struct E1kTDContext context;
930	struct E1kTDData data;
931	};
932	typedef union E1kTxDesc E1KTXDESC;
933	AssertCompileSize(E1KTXDESC, 16);
934
935	#define RA_CTL_AS 0x0003
936	#define RA_CTL_AV 0x8000
937
938	union E1kRecAddr
939	{
940	uint32_t au32[32];
941	struct RAArray
942	{
943	uint8_t addr[6];
944	uint16_t ctl;
945	} array[16];
946	};
947	typedef struct E1kRecAddr::RAArray E1KRAELEM;
948	typedef union E1kRecAddr E1KRA;
949	AssertCompileSize(E1KRA, 8*16);
950
951	#define E1K_IP_RF UINT16_C(0x8000) /*< reserved fragment flag /
952	#define E1K_IP_DF UINT16_C(0x4000) /*< dont fragment flag /
953	#define E1K_IP_MF UINT16_C(0x2000) /*< more fragments flag /
954	#define E1K_IP_OFFMASK UINT16_C(0x1fff) /*< mask for fragmenting bits /
955
956	/** @todo use+extend RTNETIPV4 */
957	struct E1kIpHeader
958	{
959	/* type of service / version / header length */
960	uint16_t tos_ver_hl;
961	/* total length */
962	uint16_t total_len;
963	/* identification */
964	uint16_t ident;
965	/* fragment offset field */
966	uint16_t offset;
967	/* time to live / protocol*/
968	uint16_t ttl_proto;
969	/* checksum */
970	uint16_t chksum;
971	/* source IP address */
972	uint32_t src;
973	/* destination IP address */
974	uint32_t dest;
975	};
976	AssertCompileSize(struct E1kIpHeader, 20);
977
978	#define E1K_TCP_FIN UINT16_C(0x01)
979	#define E1K_TCP_SYN UINT16_C(0x02)
980	#define E1K_TCP_RST UINT16_C(0x04)
981	#define E1K_TCP_PSH UINT16_C(0x08)
982	#define E1K_TCP_ACK UINT16_C(0x10)
983	#define E1K_TCP_URG UINT16_C(0x20)
984	#define E1K_TCP_ECE UINT16_C(0x40)
985	#define E1K_TCP_CWR UINT16_C(0x80)
986	#define E1K_TCP_FLAGS UINT16_C(0x3f)
987
988	/** @todo use+extend RTNETTCP */
989	struct E1kTcpHeader
990	{
991	uint16_t src;
992	uint16_t dest;
993	uint32_t seqno;
994	uint32_t ackno;
995	uint16_t hdrlen_flags;
996	uint16_t wnd;
997	uint16_t chksum;
998	uint16_t urgp;
999	};
1000	AssertCompileSize(struct E1kTcpHeader, 20);
1001
1002
1003	#ifdef E1K_WITH_TXD_CACHE
1004	/** The current Saved state version. */
1005	# define E1K_SAVEDSTATE_VERSION 4
1006	/** Saved state version for VirtualBox 4.2 with VLAN tag fields. */
1007	# define E1K_SAVEDSTATE_VERSION_VBOX_42_VTAG 3
1008	#else /* !E1K_WITH_TXD_CACHE */
1009	/** The current Saved state version. */
1010	# define E1K_SAVEDSTATE_VERSION 3
1011	#endif /* !E1K_WITH_TXD_CACHE */
1012	/** Saved state version for VirtualBox 4.1 and earlier.
1013	* These did not include VLAN tag fields. */
1014	#define E1K_SAVEDSTATE_VERSION_VBOX_41 2
1015	/** Saved state version for VirtualBox 3.0 and earlier.
1016	* This did not include the configuration part nor the E1kEEPROM. */
1017	#define E1K_SAVEDSTATE_VERSION_VBOX_30 1
1018
1019	/**
1020	* E1000 shared device state.
1021	*
1022	* This is shared between ring-0 and ring-3.
1023	*/
1024	typedef struct E1KSTATE
1025	{
1026	char szPrf[8]; /*< Log prefix, e.g. E1000#1. /
1027
1028	/** Handle to PCI region \#0, the MMIO region. */
1029	IOMIOPORTHANDLE hMmioRegion;
1030	/** Handle to PCI region \#2, the I/O ports. */
1031	IOMIOPORTHANDLE hIoPorts;
1032
1033	/** Receive Interrupt Delay Timer. */
1034	TMTIMERHANDLE hRIDTimer;
1035	/** Receive Absolute Delay Timer. */
1036	TMTIMERHANDLE hRADTimer;
1037	/** Transmit Interrupt Delay Timer. */
1038	TMTIMERHANDLE hTIDTimer;
1039	/** Transmit Absolute Delay Timer. */
1040	TMTIMERHANDLE hTADTimer;
1041	/** Transmit Delay Timer. */
1042	TMTIMERHANDLE hTXDTimer;
1043	/** Late Interrupt Timer. */
1044	TMTIMERHANDLE hIntTimer;
1045	/** Link Up(/Restore) Timer. */
1046	TMTIMERHANDLE hLUTimer;
1047
1048	/** Transmit task. */
1049	PDMTASKHANDLE hTxTask;
1050
1051	/** Critical section - what is it protecting? */
1052	PDMCRITSECT cs;
1053	/** RX Critical section. */
1054	PDMCRITSECT csRx;
1055	#ifdef E1K_WITH_TX_CS
1056	/** TX Critical section. */
1057	PDMCRITSECT csTx;
1058	#endif /* E1K_WITH_TX_CS */
1059	/** MAC address obtained from the configuration. */
1060	RTMAC macConfigured;
1061	uint16_t u16Padding0;
1062	/** EMT: Last time the interrupt was acknowledged. */
1063	uint64_t u64AckedAt;
1064	/** All: Used for eliminating spurious interrupts. */
1065	bool fIntRaised;
1066	/** EMT: false if the cable is disconnected by the GUI. */
1067	bool fCableConnected;
1068	/** EMT: Compute Ethernet CRC for RX packets. */
1069	bool fEthernetCRC;
1070	/** All: throttle interrupts. */
1071	bool fItrEnabled;
1072	/** All: throttle RX interrupts. */
1073	bool fItrRxEnabled;
1074	/** All: Delay TX interrupts using TIDV/TADV. */
1075	bool fTidEnabled;
1076	bool afPadding[2];
1077	/** Link up delay (in milliseconds). */
1078	uint32_t cMsLinkUpDelay;
1079
1080	/** All: Device register storage. */
1081	uint32_t auRegs[E1K_NUM_OF_32BIT_REGS];
1082	/** TX/RX: Status LED. */
1083	PDMLED led;
1084	/** TX/RX: Number of packet being sent/received to show in debug log. */
1085	uint32_t u32PktNo;
1086
1087	/** EMT: Offset of the register to be read via IO. */
1088	uint32_t uSelectedReg;
1089	/** EMT: Multicast Table Array. */
1090	uint32_t auMTA[128];
1091	/** EMT: Receive Address registers. */
1092	E1KRA aRecAddr;
1093	/** EMT: VLAN filter table array. */
1094	uint32_t auVFTA[128];
1095	/** EMT: Receive buffer size. */
1096	uint16_t u16RxBSize;
1097	/** EMT: Locked state -- no state alteration possible. */
1098	bool fLocked;
1099	/** EMT: */
1100	bool fDelayInts;
1101	/** All: */
1102	bool fIntMaskUsed;
1103
1104	/** N/A: */
1105	bool volatile fMaybeOutOfSpace;
1106	/** EMT: Gets signalled when more RX descriptors become available. */
1107	SUPSEMEVENT hEventMoreRxDescAvail;
1108	#ifdef E1K_WITH_RXD_CACHE
1109	/** RX: Fetched RX descriptors. */
1110	E1KRXDESC aRxDescriptors[E1K_RXD_CACHE_SIZE];
1111	//uint64_t aRxDescAddr[E1K_RXD_CACHE_SIZE];
1112	/** RX: Actual number of fetched RX descriptors. */
1113	uint32_t nRxDFetched;
1114	/** RX: Index in cache of RX descriptor being processed. */
1115	uint32_t iRxDCurrent;
1116	#endif /* E1K_WITH_RXD_CACHE */
1117
1118	/** TX: Context used for TCP segmentation packets. */
1119	E1KTXCTX contextTSE;
1120	/** TX: Context used for ordinary packets. */
1121	E1KTXCTX contextNormal;
1122	#ifdef E1K_WITH_TXD_CACHE
1123	/** TX: Fetched TX descriptors. */
1124	E1KTXDESC aTxDescriptors[E1K_TXD_CACHE_SIZE];
1125	/** TX: Actual number of fetched TX descriptors. */
1126	uint8_t nTxDFetched;
1127	/** TX: Index in cache of TX descriptor being processed. */
1128	uint8_t iTxDCurrent;
1129	/** TX: Will this frame be sent as GSO. */
1130	bool fGSO;
1131	/** Alignment padding. */
1132	bool fReserved;
1133	/** TX: Number of bytes in next packet. */
1134	uint32_t cbTxAlloc;
1135
1136	#endif /* E1K_WITH_TXD_CACHE */
1137	/** GSO context. u8Type is set to PDMNETWORKGSOTYPE_INVALID when not
1138	* applicable to the current TSE mode. */
1139	PDMNETWORKGSO GsoCtx;
1140	/** Scratch space for holding the loopback / fallback scatter / gather
1141	* descriptor. */
1142	union
1143	{
1144	PDMSCATTERGATHER Sg;
1145	uint8_t padding[8 * sizeof(RTUINTPTR)];
1146	} uTxFallback;
1147	/** TX: Transmit packet buffer use for TSE fallback and loopback. */
1148	uint8_t aTxPacketFallback[E1K_MAX_TX_PKT_SIZE];
1149	/** TX: Number of bytes assembled in TX packet buffer. */
1150	uint16_t u16TxPktLen;
1151	/** TX: False will force segmentation in e1000 instead of sending frames as GSO. */
1152	bool fGSOEnabled;
1153	/** TX: IP checksum has to be inserted if true. */
1154	bool fIPcsum;
1155	/** TX: TCP/UDP checksum has to be inserted if true. */
1156	bool fTCPcsum;
1157	/** TX: VLAN tag has to be inserted if true. */
1158	bool fVTag;
1159	/** TX: TCI part of VLAN tag to be inserted. */
1160	uint16_t u16VTagTCI;
1161	/** TX TSE fallback: Number of payload bytes remaining in TSE context. */
1162	uint32_t u32PayRemain;
1163	/** TX TSE fallback: Number of header bytes remaining in TSE context. */
1164	uint16_t u16HdrRemain;
1165	/** TX TSE fallback: Flags from template header. */
1166	uint16_t u16SavedFlags;
1167	/** TX TSE fallback: Partial checksum from template header. */
1168	uint32_t u32SavedCsum;
1169	/** ?: Emulated controller type. */
1170	E1KCHIP eChip;
1171
1172	/** EMT: Physical interface emulation. */
1173	PHY phy;
1174
1175	#if 0
1176	/** Alignment padding. */
1177	uint8_t Alignment[HC_ARCH_BITS == 64 ? 8 : 4];
1178	#endif
1179
1180	STAMCOUNTER StatReceiveBytes;
1181	STAMCOUNTER StatTransmitBytes;
1182	#if defined(VBOX_WITH_STATISTICS)
1183	STAMPROFILEADV StatMMIOReadRZ;
1184	STAMPROFILEADV StatMMIOReadR3;
1185	STAMPROFILEADV StatMMIOWriteRZ;
1186	STAMPROFILEADV StatMMIOWriteR3;
1187	STAMPROFILEADV StatEEPROMRead;
1188	STAMPROFILEADV StatEEPROMWrite;
1189	STAMPROFILEADV StatIOReadRZ;
1190	STAMPROFILEADV StatIOReadR3;
1191	STAMPROFILEADV StatIOWriteRZ;
1192	STAMPROFILEADV StatIOWriteR3;
1193	STAMPROFILEADV StatLateIntTimer;
1194	STAMCOUNTER StatLateInts;
1195	STAMCOUNTER StatIntsRaised;
1196	STAMCOUNTER StatIntsPrevented;
1197	STAMPROFILEADV StatReceive;
1198	STAMPROFILEADV StatReceiveCRC;
1199	STAMPROFILEADV StatReceiveFilter;
1200	STAMPROFILEADV StatReceiveStore;
1201	STAMPROFILEADV StatTransmitRZ;
1202	STAMPROFILEADV StatTransmitR3;
1203	STAMPROFILE StatTransmitSendRZ;
1204	STAMPROFILE StatTransmitSendR3;
1205	STAMPROFILE StatRxOverflow;
1206	STAMCOUNTER StatRxOverflowWakeupRZ;
1207	STAMCOUNTER StatRxOverflowWakeupR3;
1208	STAMCOUNTER StatTxDescCtxNormal;
1209	STAMCOUNTER StatTxDescCtxTSE;
1210	STAMCOUNTER StatTxDescLegacy;
1211	STAMCOUNTER StatTxDescData;
1212	STAMCOUNTER StatTxDescTSEData;
1213	STAMCOUNTER StatTxPathFallback;
1214	STAMCOUNTER StatTxPathGSO;
1215	STAMCOUNTER StatTxPathRegular;
1216	STAMCOUNTER StatPHYAccesses;
1217	STAMCOUNTER aStatRegWrites[E1K_NUM_OF_REGS];
1218	STAMCOUNTER aStatRegReads[E1K_NUM_OF_REGS];
1219	#endif /* VBOX_WITH_STATISTICS */
1220
1221	#ifdef E1K_INT_STATS
1222	/* Internal stats */
1223	uint64_t u64ArmedAt;
1224	uint64_t uStatMaxTxDelay;
1225	uint32_t uStatInt;
1226	uint32_t uStatIntTry;
1227	uint32_t uStatIntLower;
1228	uint32_t uStatNoIntICR;
1229	int32_t iStatIntLost;
1230	int32_t iStatIntLostOne;
1231	uint32_t uStatIntIMS;
1232	uint32_t uStatIntSkip;
1233	uint32_t uStatIntLate;
1234	uint32_t uStatIntMasked;
1235	uint32_t uStatIntEarly;
1236	uint32_t uStatIntRx;
1237	uint32_t uStatIntTx;
1238	uint32_t uStatIntICS;
1239	uint32_t uStatIntRDTR;
1240	uint32_t uStatIntRXDMT0;
1241	uint32_t uStatIntTXQE;
1242	uint32_t uStatTxNoRS;
1243	uint32_t uStatTxIDE;
1244	uint32_t uStatTxDelayed;
1245	uint32_t uStatTxDelayExp;
1246	uint32_t uStatTAD;
1247	uint32_t uStatTID;
1248	uint32_t uStatRAD;
1249	uint32_t uStatRID;
1250	uint32_t uStatRxFrm;
1251	uint32_t uStatTxFrm;
1252	uint32_t uStatDescCtx;
1253	uint32_t uStatDescDat;
1254	uint32_t uStatDescLeg;
1255	uint32_t uStatTx1514;
1256	uint32_t uStatTx2962;
1257	uint32_t uStatTx4410;
1258	uint32_t uStatTx5858;
1259	uint32_t uStatTx7306;
1260	uint32_t uStatTx8754;
1261	uint32_t uStatTx16384;
1262	uint32_t uStatTx32768;
1263	uint32_t uStatTxLarge;
1264	uint32_t uStatAlign;
1265	#endif /* E1K_INT_STATS */
1266	} E1KSTATE;
1267	/** Pointer to the E1000 device state. */
1268	typedef E1KSTATE *PE1KSTATE;
1269
1270	/**
1271	* E1000 ring-3 device state
1272	*
1273	* @implements PDMINETWORKDOWN
1274	* @implements PDMINETWORKCONFIG
1275	* @implements PDMILEDPORTS
1276	*/
1277	typedef struct E1KSTATER3
1278	{
1279	PDMIBASE IBase;
1280	PDMINETWORKDOWN INetworkDown;
1281	PDMINETWORKCONFIG INetworkConfig;
1282	/** LED interface */
1283	PDMILEDPORTS ILeds;
1284	/** Attached network driver. */
1285	R3PTRTYPE(PPDMIBASE) pDrvBase;
1286	R3PTRTYPE(PPDMILEDCONNECTORS) pLedsConnector;
1287
1288	/** Pointer to the shared state. */
1289	R3PTRTYPE(PE1KSTATE) pShared;
1290
1291	/** Device instance. */
1292	PPDMDEVINSR3 pDevInsR3;
1293	/** Attached network driver. */
1294	PPDMINETWORKUPR3 pDrvR3;
1295	/** The scatter / gather buffer used for the current outgoing packet. */
1296	R3PTRTYPE(PPDMSCATTERGATHER) pTxSgR3;
1297
1298	/** EMT: EEPROM emulation */
1299	E1kEEPROM eeprom;
1300	} E1KSTATER3;
1301	/** Pointer to the E1000 ring-3 device state. */
1302	typedef E1KSTATER3 *PE1KSTATER3;
1303
1304
1305	/**
1306	* E1000 ring-0 device state
1307	*/
1308	typedef struct E1KSTATER0
1309	{
1310	/** Device instance. */
1311	PPDMDEVINSR0 pDevInsR0;
1312	/** Attached network driver. */
1313	PPDMINETWORKUPR0 pDrvR0;
1314	/** The scatter / gather buffer used for the current outgoing packet - R0. */
1315	R0PTRTYPE(PPDMSCATTERGATHER) pTxSgR0;
1316	} E1KSTATER0;
1317	/** Pointer to the E1000 ring-0 device state. */
1318	typedef E1KSTATER0 *PE1KSTATER0;
1319
1320
1321	/**
1322	* E1000 raw-mode device state
1323	*/
1324	typedef struct E1KSTATERC
1325	{
1326	/** Device instance. */
1327	PPDMDEVINSRC pDevInsRC;
1328	/** Attached network driver. */
1329	PPDMINETWORKUPRC pDrvRC;
1330	/** The scatter / gather buffer used for the current outgoing packet. */
1331	RCPTRTYPE(PPDMSCATTERGATHER) pTxSgRC;
1332	} E1KSTATERC;
1333	/** Pointer to the E1000 raw-mode device state. */
1334	typedef E1KSTATERC *PE1KSTATERC;
1335
1336
1337	/** @def PE1KSTATECC
1338	* Pointer to the instance data for the current context. */
1339	#ifdef IN_RING3
1340	typedef E1KSTATER3 E1KSTATECC;
1341	typedef PE1KSTATER3 PE1KSTATECC;
1342	#elif defined(IN_RING0)
1343	typedef E1KSTATER0 E1KSTATECC;
1344	typedef PE1KSTATER0 PE1KSTATECC;
1345	#elif defined(IN_RC)
1346	typedef E1KSTATERC E1KSTATECC;
1347	typedef PE1KSTATERC PE1KSTATECC;
1348	#else
1349	# error "Not IN_RING3, IN_RING0 or IN_RC"
1350	#endif
1351
1352
1353	#ifndef VBOX_DEVICE_STRUCT_TESTCASE
1354
1355	/* Forward declarations ******************************************************/
1356	static int e1kXmitPending(PPDMDEVINS pDevIns, PE1KSTATE pThis, bool fOnWorkerThread);
1357
1358	/**
1359	* E1000 register read handler.
1360	*/
1361	typedef int (FNE1KREGREAD)(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value);
1362	/**
1363	* E1000 register write handler.
1364	*/
1365	typedef int (FNE1KREGWRITE)(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t u32Value);
1366
1367	static FNE1KREGREAD e1kRegReadUnimplemented;
1368	static FNE1KREGWRITE e1kRegWriteUnimplemented;
1369	static FNE1KREGREAD e1kRegReadAutoClear;
1370	static FNE1KREGREAD e1kRegReadDefault;
1371	static FNE1KREGWRITE e1kRegWriteDefault;
1372	#if 0 /* unused */
1373	static FNE1KREGREAD e1kRegReadCTRL;
1374	#endif
1375	static FNE1KREGWRITE e1kRegWriteCTRL;
1376	static FNE1KREGREAD e1kRegReadEECD;
1377	static FNE1KREGWRITE e1kRegWriteEECD;
1378	static FNE1KREGWRITE e1kRegWriteEERD;
1379	static FNE1KREGWRITE e1kRegWriteMDIC;
1380	static FNE1KREGREAD e1kRegReadICR;
1381	static FNE1KREGWRITE e1kRegWriteICR;
1382	static FNE1KREGWRITE e1kRegWriteICS;
1383	static FNE1KREGWRITE e1kRegWriteIMS;
1384	static FNE1KREGWRITE e1kRegWriteIMC;
1385	static FNE1KREGWRITE e1kRegWriteRCTL;
1386	static FNE1KREGWRITE e1kRegWritePBA;
1387	static FNE1KREGWRITE e1kRegWriteRDT;
1388	static FNE1KREGWRITE e1kRegWriteRDTR;
1389	static FNE1KREGWRITE e1kRegWriteTDT;
1390	static FNE1KREGREAD e1kRegReadMTA;
1391	static FNE1KREGWRITE e1kRegWriteMTA;
1392	static FNE1KREGREAD e1kRegReadRA;
1393	static FNE1KREGWRITE e1kRegWriteRA;
1394	static FNE1KREGREAD e1kRegReadVFTA;
1395	static FNE1KREGWRITE e1kRegWriteVFTA;
1396
1397	/**
1398	* Register map table.
1399	*
1400	* Override pfnRead and pfnWrite to get register-specific behavior.
1401	*/
1402	static const struct E1kRegMap_st
1403	{
1404	/** Register offset in the register space. */
1405	uint32_t offset;
1406	/** Size in bytes. Registers of size > 4 are in fact tables. */
1407	uint32_t size;
1408	/** Readable bits. */
1409	uint32_t readable;
1410	/** Writable bits. */
1411	uint32_t writable;
1412	/** Read callback. */
1413	FNE1KREGREAD *pfnRead;
1414	/** Write callback. */
1415	FNE1KREGWRITE *pfnWrite;
1416	/** Abbreviated name. */
1417	const char *abbrev;
1418	/** Full name. */
1419	const char *name;
1420	} g_aE1kRegMap[E1K_NUM_OF_REGS] =
1421	{
1422	/* offset size read mask write mask read callback write callback abbrev full name */
1423	/------- ------- ---------- ---------- ----------------------- ------------------------ ---------- ------------------------------/
1424	{ 0x00000, 0x00004, 0xDBF31BE9, 0xDBF31BE9, e1kRegReadDefault , e1kRegWriteCTRL , "CTRL" , "Device Control" },
1425	{ 0x00008, 0x00004, 0x0000FDFF, 0x00000000, e1kRegReadDefault , e1kRegWriteUnimplemented, "STATUS" , "Device Status" },
1426	{ 0x00010, 0x00004, 0x000027F0, 0x00000070, e1kRegReadEECD , e1kRegWriteEECD , "EECD" , "EEPROM/Flash Control/Data" },
1427	{ 0x00014, 0x00004, 0xFFFFFF10, 0xFFFFFF00, e1kRegReadDefault , e1kRegWriteEERD , "EERD" , "EEPROM Read" },
1428	{ 0x00018, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "CTRL_EXT", "Extended Device Control" },
1429	{ 0x0001c, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FLA" , "Flash Access (N/A)" },
1430	{ 0x00020, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteMDIC , "MDIC" , "MDI Control" },
1431	{ 0x00028, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCAL" , "Flow Control Address Low" },
1432	{ 0x0002c, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCAH" , "Flow Control Address High" },
1433	{ 0x00030, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCT" , "Flow Control Type" },
1434	{ 0x00038, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "VET" , "VLAN EtherType" },
1435	{ 0x000c0, 0x00004, 0x0001F6DF, 0x0001F6DF, e1kRegReadICR , e1kRegWriteICR , "ICR" , "Interrupt Cause Read" },
1436	{ 0x000c4, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "ITR" , "Interrupt Throttling" },
1437	{ 0x000c8, 0x00004, 0x00000000, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteICS , "ICS" , "Interrupt Cause Set" },
1438	{ 0x000d0, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteIMS , "IMS" , "Interrupt Mask Set/Read" },
1439	{ 0x000d8, 0x00004, 0x00000000, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteIMC , "IMC" , "Interrupt Mask Clear" },
1440	{ 0x00100, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteRCTL , "RCTL" , "Receive Control" },
1441	{ 0x00170, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCTTV" , "Flow Control Transmit Timer Value" },
1442	{ 0x00178, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TXCW" , "Transmit Configuration Word (N/A)" },
1443	{ 0x00180, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RXCW" , "Receive Configuration Word (N/A)" },
1444	{ 0x00400, 0x00004, 0x017FFFFA, 0x017FFFFA, e1kRegReadDefault , e1kRegWriteDefault , "TCTL" , "Transmit Control" },
1445	{ 0x00410, 0x00004, 0x3FFFFFFF, 0x3FFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "TIPG" , "Transmit IPG" },
1446	{ 0x00458, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "AIFS" , "Adaptive IFS Throttle - AIT" },
1447	{ 0x00e00, 0x00004, 0xCFCFCFCF, 0xCFCFCFCF, e1kRegReadDefault , e1kRegWriteDefault , "LEDCTL" , "LED Control" },
1448	{ 0x01000, 0x00004, 0xFFFF007F, 0x0000007F, e1kRegReadDefault , e1kRegWritePBA , "PBA" , "Packet Buffer Allocation" },
1449	{ 0x02160, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCRTL" , "Flow Control Receive Threshold Low" },
1450	{ 0x02168, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCRTH" , "Flow Control Receive Threshold High" },
1451	{ 0x02410, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RDFH" , "Receive Data FIFO Head" },
1452	{ 0x02418, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RDFT" , "Receive Data FIFO Tail" },
1453	{ 0x02420, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RDFHS" , "Receive Data FIFO Head Saved Register" },
1454	{ 0x02428, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RDFTS" , "Receive Data FIFO Tail Saved Register" },
1455	{ 0x02430, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RDFPC" , "Receive Data FIFO Packet Count" },
1456	{ 0x02800, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "RDBAL" , "Receive Descriptor Base Low" },
1457	{ 0x02804, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "RDBAH" , "Receive Descriptor Base High" },
1458	{ 0x02808, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "RDLEN" , "Receive Descriptor Length" },
1459	{ 0x02810, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "RDH" , "Receive Descriptor Head" },
1460	{ 0x02818, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteRDT , "RDT" , "Receive Descriptor Tail" },
1461	{ 0x02820, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteRDTR , "RDTR" , "Receive Delay Timer" },
1462	{ 0x02828, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RXDCTL" , "Receive Descriptor Control" },
1463	{ 0x0282c, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "RADV" , "Receive Interrupt Absolute Delay Timer" },
1464	{ 0x02c00, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RSRPD" , "Receive Small Packet Detect Interrupt" },
1465	{ 0x03000, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TXDMAC" , "TX DMA Control (N/A)" },
1466	{ 0x03410, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TDFH" , "Transmit Data FIFO Head" },
1467	{ 0x03418, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TDFT" , "Transmit Data FIFO Tail" },
1468	{ 0x03420, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TDFHS" , "Transmit Data FIFO Head Saved Register" },
1469	{ 0x03428, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TDFTS" , "Transmit Data FIFO Tail Saved Register" },
1470	{ 0x03430, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TDFPC" , "Transmit Data FIFO Packet Count" },
1471	{ 0x03800, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "TDBAL" , "Transmit Descriptor Base Low" },
1472	{ 0x03804, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "TDBAH" , "Transmit Descriptor Base High" },
1473	{ 0x03808, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "TDLEN" , "Transmit Descriptor Length" },
1474	{ 0x03810, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "TDH" , "Transmit Descriptor Head" },
1475	{ 0x03818, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteTDT , "TDT" , "Transmit Descriptor Tail" },
1476	{ 0x03820, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "TIDV" , "Transmit Interrupt Delay Value" },
1477	{ 0x03828, 0x00004, 0xFF3F3F3F, 0xFF3F3F3F, e1kRegReadDefault , e1kRegWriteDefault , "TXDCTL" , "Transmit Descriptor Control" },
1478	{ 0x0382c, 0x00004, 0x0000FFFF, 0x0000FFFF, e1kRegReadDefault , e1kRegWriteDefault , "TADV" , "Transmit Absolute Interrupt Delay Timer" },
1479	{ 0x03830, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "TSPMT" , "TCP Segmentation Pad and Threshold" },
1480	{ 0x04000, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "CRCERRS" , "CRC Error Count" },
1481	{ 0x04004, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "ALGNERRC", "Alignment Error Count" },
1482	{ 0x04008, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "SYMERRS" , "Symbol Error Count" },
1483	{ 0x0400c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RXERRC" , "RX Error Count" },
1484	{ 0x04010, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "MPC" , "Missed Packets Count" },
1485	{ 0x04014, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "SCC" , "Single Collision Count" },
1486	{ 0x04018, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "ECOL" , "Excessive Collisions Count" },
1487	{ 0x0401c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "MCC" , "Multiple Collision Count" },
1488	{ 0x04020, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "LATECOL" , "Late Collisions Count" },
1489	{ 0x04028, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "COLC" , "Collision Count" },
1490	{ 0x04030, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "DC" , "Defer Count" },
1491	{ 0x04034, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "TNCRS" , "Transmit - No CRS" },
1492	{ 0x04038, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "SEC" , "Sequence Error Count" },
1493	{ 0x0403c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "CEXTERR" , "Carrier Extension Error Count" },
1494	{ 0x04040, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RLEC" , "Receive Length Error Count" },
1495	{ 0x04048, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "XONRXC" , "XON Received Count" },
1496	{ 0x0404c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "XONTXC" , "XON Transmitted Count" },
1497	{ 0x04050, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "XOFFRXC" , "XOFF Received Count" },
1498	{ 0x04054, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "XOFFTXC" , "XOFF Transmitted Count" },
1499	{ 0x04058, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FCRUC" , "FC Received Unsupported Count" },
1500	{ 0x0405c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC64" , "Packets Received (64 Bytes) Count" },
1501	{ 0x04060, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC127" , "Packets Received (65-127 Bytes) Count" },
1502	{ 0x04064, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC255" , "Packets Received (128-255 Bytes) Count" },
1503	{ 0x04068, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC511" , "Packets Received (256-511 Bytes) Count" },
1504	{ 0x0406c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC1023" , "Packets Received (512-1023 Bytes) Count" },
1505	{ 0x04070, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PRC1522" , "Packets Received (1024-Max Bytes)" },
1506	{ 0x04074, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GPRC" , "Good Packets Received Count" },
1507	{ 0x04078, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "BPRC" , "Broadcast Packets Received Count" },
1508	{ 0x0407c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "MPRC" , "Multicast Packets Received Count" },
1509	{ 0x04080, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GPTC" , "Good Packets Transmitted Count" },
1510	{ 0x04088, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GORCL" , "Good Octets Received Count (Low)" },
1511	{ 0x0408c, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GORCH" , "Good Octets Received Count (Hi)" },
1512	{ 0x04090, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GOTCL" , "Good Octets Transmitted Count (Low)" },
1513	{ 0x04094, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "GOTCH" , "Good Octets Transmitted Count (Hi)" },
1514	{ 0x040a0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RNBC" , "Receive No Buffers Count" },
1515	{ 0x040a4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RUC" , "Receive Undersize Count" },
1516	{ 0x040a8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RFC" , "Receive Fragment Count" },
1517	{ 0x040ac, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "ROC" , "Receive Oversize Count" },
1518	{ 0x040b0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "RJC" , "Receive Jabber Count" },
1519	{ 0x040b4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "MGTPRC" , "Management Packets Received Count" },
1520	{ 0x040b8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "MGTPDC" , "Management Packets Dropped Count" },
1521	{ 0x040bc, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "MGTPTC" , "Management Pkts Transmitted Count" },
1522	{ 0x040c0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TORL" , "Total Octets Received (Lo)" },
1523	{ 0x040c4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TORH" , "Total Octets Received (Hi)" },
1524	{ 0x040c8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TOTL" , "Total Octets Transmitted (Lo)" },
1525	{ 0x040cc, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TOTH" , "Total Octets Transmitted (Hi)" },
1526	{ 0x040d0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TPR" , "Total Packets Received" },
1527	{ 0x040d4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TPT" , "Total Packets Transmitted" },
1528	{ 0x040d8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC64" , "Packets Transmitted (64 Bytes) Count" },
1529	{ 0x040dc, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC127" , "Packets Transmitted (65-127 Bytes) Count" },
1530	{ 0x040e0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC255" , "Packets Transmitted (128-255 Bytes) Count" },
1531	{ 0x040e4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC511" , "Packets Transmitted (256-511 Bytes) Count" },
1532	{ 0x040e8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC1023" , "Packets Transmitted (512-1023 Bytes) Count" },
1533	{ 0x040ec, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "PTC1522" , "Packets Transmitted (1024 Bytes or Greater) Count" },
1534	{ 0x040f0, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "MPTC" , "Multicast Packets Transmitted Count" },
1535	{ 0x040f4, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "BPTC" , "Broadcast Packets Transmitted Count" },
1536	{ 0x040f8, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TSCTC" , "TCP Segmentation Context Transmitted Count" },
1537	{ 0x040fc, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadAutoClear , e1kRegWriteUnimplemented, "TSCTFC" , "TCP Segmentation Context Tx Fail Count" },
1538	{ 0x05000, 0x00004, 0x000007FF, 0x000007FF, e1kRegReadDefault , e1kRegWriteDefault , "RXCSUM" , "Receive Checksum Control" },
1539	{ 0x05800, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "WUC" , "Wakeup Control" },
1540	{ 0x05808, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "WUFC" , "Wakeup Filter Control" },
1541	{ 0x05810, 0x00004, 0xFFFFFFFF, 0x00000000, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "WUS" , "Wakeup Status" },
1542	{ 0x05820, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadDefault , e1kRegWriteDefault , "MANC" , "Management Control" },
1543	{ 0x05838, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "IPAV" , "IP Address Valid" },
1544	{ 0x05900, 0x00004, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "WUPL" , "Wakeup Packet Length" },
1545	{ 0x05200, 0x00200, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadMTA , e1kRegWriteMTA , "MTA" , "Multicast Table Array (n)" },
1546	{ 0x05400, 0x00080, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadRA , e1kRegWriteRA , "RA" , "Receive Address (64-bit) (n)" },
1547	{ 0x05600, 0x00200, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadVFTA , e1kRegWriteVFTA , "VFTA" , "VLAN Filter Table Array (n)" },
1548	{ 0x05840, 0x0001c, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "IP4AT" , "IPv4 Address Table" },
1549	{ 0x05880, 0x00010, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "IP6AT" , "IPv6 Address Table" },
1550	{ 0x05a00, 0x00080, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "WUPM" , "Wakeup Packet Memory" },
1551	{ 0x05f00, 0x0001c, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FFLT" , "Flexible Filter Length Table" },
1552	{ 0x09000, 0x003fc, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FFMT" , "Flexible Filter Mask Table" },
1553	{ 0x09800, 0x003fc, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "FFVT" , "Flexible Filter Value Table" },
1554	{ 0x10000, 0x10000, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadUnimplemented, e1kRegWriteUnimplemented, "PBM" , "Packet Buffer Memory (n)" },
1555	{ 0x00040, 0x00080, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadRA , e1kRegWriteRA , "RA82542" , "Receive Address (64-bit) (n) (82542)" },
1556	{ 0x00200, 0x00200, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadMTA , e1kRegWriteMTA , "MTA82542", "Multicast Table Array (n) (82542)" },
1557	{ 0x00600, 0x00200, 0xFFFFFFFF, 0xFFFFFFFF, e1kRegReadVFTA , e1kRegWriteVFTA , "VFTA82542", "VLAN Filter Table Array (n) (82542)" }
1558	};
1559
1560	#ifdef LOG_ENABLED
1561
1562	/**
1563	* Convert U32 value to hex string. Masked bytes are replaced with dots.
1564	*
1565	* @remarks The mask has half-byte byte (not bit) granularity (e.g. 0000000F).
1566	*
1567	* @returns The buffer.
1568	*
1569	* @param u32 The word to convert into string.
1570	* @param mask Selects which bytes to convert.
1571	* @param buf Where to put the result.
1572	*/
1573	static char e1kU32toHex(uint32_t u32, uint32_t mask, char buf)
1574	{
1575	for (char *ptr = buf + 7; ptr >= buf; --ptr, u32 >>=4, mask >>=4)
1576	{
1577	if (mask & 0xF)
1578	*ptr = (u32 & 0xF) + ((u32 & 0xF) > 9 ? '7' : '0');
1579	else
1580	*ptr = '.';
1581	}
1582	buf[8] = 0;
1583	return buf;
1584	}
1585
1586	/**
1587	* Returns timer name for debug purposes.
1588	*
1589	* @returns The timer name.
1590	*
1591	* @param pThis The device state structure.
1592	* @param hTimer The timer to name.
1593	*/
1594	DECLINLINE(const char *) e1kGetTimerName(PE1KSTATE pThis, TMTIMERHANDLE hTimer)
1595	{
1596	if (hTimer == pThis->hTIDTimer)
1597	return "TID";
1598	if (hTimer == pThis->hTADTimer)
1599	return "TAD";
1600	if (hTimer == pThis->hRIDTimer)
1601	return "RID";
1602	if (hTimer == pThis->hRADTimer)
1603	return "RAD";
1604	if (hTimer == pThis->hIntTimer)
1605	return "Int";
1606	if (hTimer == pThis->hTXDTimer)
1607	return "TXD";
1608	if (hTimer == pThis->hLUTimer)
1609	return "LinkUp";
1610	return "unknown";
1611	}
1612
1613	#endif /* LOG_ENABLED */
1614
1615	/**
1616	* Arm a timer.
1617	*
1618	* @param pDevIns The device instance.
1619	* @param pThis Pointer to the device state structure.
1620	* @param hTimer The timer to arm.
1621	* @param uExpireIn Expiration interval in microseconds.
1622	*/
1623	DECLINLINE(void) e1kArmTimer(PPDMDEVINS pDevIns, PE1KSTATE pThis, TMTIMERHANDLE hTimer, uint32_t uExpireIn)
1624	{
1625	if (pThis->fLocked)
1626	return;
1627
1628	E1kLog2(("%s Arming %s timer to fire in %d usec...\n",
1629	pThis->szPrf, e1kGetTimerName(pThis, hTimer), uExpireIn));
1630	int rc = PDMDevHlpTimerSetMicro(pDevIns, hTimer, uExpireIn);
1631	AssertRC(rc);
1632	}
1633
1634	#ifdef IN_RING3
1635	/**
1636	* Cancel a timer.
1637	*
1638	* @param pDevIns The device instance.
1639	* @param pThis Pointer to the device state structure.
1640	* @param pTimer Pointer to the timer.
1641	*/
1642	DECLINLINE(void) e1kCancelTimer(PPDMDEVINS pDevIns, PE1KSTATE pThis, TMTIMERHANDLE hTimer)
1643	{
1644	E1kLog2(("%s Stopping %s timer...\n",
1645	pThis->szPrf, e1kGetTimerName(pThis, hTimer)));
1646	int rc = PDMDevHlpTimerStop(pDevIns, hTimer);
1647	if (RT_FAILURE(rc))
1648	E1kLog2(("%s e1kCancelTimer: TMTimerStop(%s) failed with %Rrc\n",
1649	pThis->szPrf, e1kGetTimerName(pThis, hTimer), rc));
1650	RT_NOREF_PV(pThis);
1651	}
1652	#endif /* IN_RING3 */
1653
1654	#define e1kCsEnter(ps, rc) PDMDevHlpCritSectEnter(pDevIns, &ps->cs, rc)
1655	#define e1kCsLeave(ps) PDMDevHlpCritSectLeave(pDevIns, &ps->cs)
1656
1657	#define e1kCsRxEnter(ps, rc) PDMDevHlpCritSectEnter(pDevIns, &ps->csRx, rc)
1658	#define e1kCsRxLeave(ps) PDMDevHlpCritSectLeave(pDevIns, &ps->csRx)
1659	#define e1kCsRxIsOwner(ps) PDMDevHlpCritSectIsOwner(pDevIns, &ps->csRx)
1660
1661	#ifndef E1K_WITH_TX_CS
1662	# define e1kCsTxEnter(ps, rc) VINF_SUCCESS
1663	# define e1kCsTxLeave(ps) do { } while (0)
1664	#else /* E1K_WITH_TX_CS */
1665	# define e1kCsTxEnter(ps, rc) PDMDevHlpCritSectEnter(pDevIns, &ps->csTx, rc)
1666	# define e1kCsTxLeave(ps) PDMDevHlpCritSectLeave(pDevIns, &ps->csTx)
1667	#endif /* E1K_WITH_TX_CS */
1668
1669
1670	/**
1671	* Wakeup the RX thread.
1672	*/
1673	static void e1kWakeupReceive(PPDMDEVINS pDevIns, PE1KSTATE pThis)
1674	{
1675	if ( pThis->fMaybeOutOfSpace
1676	&& pThis->hEventMoreRxDescAvail != NIL_SUPSEMEVENT)
1677	{
1678	STAM_COUNTER_INC(&pThis->CTX_SUFF_Z(StatRxOverflowWakeup));
1679	E1kLog(("%s Waking up Out-of-RX-space semaphore\n", pThis->szPrf));
1680	int rc = PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEventMoreRxDescAvail);
1681	AssertRC(rc);
1682	}
1683	}
1684
1685	#ifdef IN_RING3
1686
1687	/**
1688	* Hardware reset. Revert all registers to initial values.
1689	*
1690	* @param pDevIns The device instance.
1691	* @param pThis The device state structure.
1692	* @param pThisCC The current context instance data.
1693	*/
1694	static void e1kR3HardReset(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC)
1695	{
1696	E1kLog(("%s Hard reset triggered\n", pThis->szPrf));
1697	/* No interrupts should survive device reset, see @bugref(9556). */
1698	if (pThis->fIntRaised)
1699	{
1700	/* Lower(0) INTA(0) */
1701	PDMDevHlpPCISetIrq(pDevIns, 0, 0);
1702	pThis->fIntRaised = false;
1703	E1kLog(("%s e1kR3HardReset: Lowered IRQ: ICR=%08x\n", pThis->szPrf, ICR));
1704	}
1705	memset(pThis->auRegs, 0, sizeof(pThis->auRegs));
1706	memset(pThis->aRecAddr.au32, 0, sizeof(pThis->aRecAddr.au32));
1707	#ifdef E1K_INIT_RA0
1708	memcpy(pThis->aRecAddr.au32, pThis->macConfigured.au8,
1709	sizeof(pThis->macConfigured.au8));
1710	pThis->aRecAddr.array[0].ctl \|= RA_CTL_AV;
1711	#endif /* E1K_INIT_RA0 */
1712	STATUS = 0x0081; /* SPEED=10b (1000 Mb/s), FD=1b (Full Duplex) */
1713	EECD = 0x0100; /* EE_PRES=1b (EEPROM present) */
1714	CTRL = 0x0a09; /* FRCSPD=1b SPEED=10b LRST=1b FD=1b */
1715	TSPMT = 0x01000400;/* TSMT=0400h TSPBP=0100h */
1716	Assert(GET_BITS(RCTL, BSIZE) == 0);
1717	pThis->u16RxBSize = 2048;
1718
1719	uint16_t u16LedCtl = 0x0602; /* LED0/LINK_UP#, LED2/LINK100# */
1720	pThisCC->eeprom.readWord(0x2F, &u16LedCtl); /* Read LEDCTL defaults from EEPROM */
1721	LEDCTL = 0x07008300 \| (((uint32_t)u16LedCtl & 0xCF00) << 8) \| (u16LedCtl & 0xCF); /* Only LED0 and LED2 defaults come from EEPROM */
1722
1723	/* Reset promiscuous mode */
1724	if (pThisCC->pDrvR3)
1725	pThisCC->pDrvR3->pfnSetPromiscuousMode(pThisCC->pDrvR3, false);
1726
1727	#ifdef E1K_WITH_TXD_CACHE
1728	int rc = e1kCsTxEnter(pThis, VERR_SEM_BUSY);
1729	if (RT_LIKELY(rc == VINF_SUCCESS))
1730	{
1731	pThis->nTxDFetched = 0;
1732	pThis->iTxDCurrent = 0;
1733	pThis->fGSO = false;
1734	pThis->cbTxAlloc = 0;
1735	e1kCsTxLeave(pThis);
1736	}
1737	#endif /* E1K_WITH_TXD_CACHE */
1738	#ifdef E1K_WITH_RXD_CACHE
1739	if (RT_LIKELY(e1kCsRxEnter(pThis, VERR_SEM_BUSY) == VINF_SUCCESS))
1740	{
1741	pThis->iRxDCurrent = pThis->nRxDFetched = 0;
1742	e1kCsRxLeave(pThis);
1743	}
1744	#endif /* E1K_WITH_RXD_CACHE */
1745	#ifdef E1K_LSC_ON_RESET
1746	E1kLog(("%s Will trigger LSC in %d seconds...\n",
1747	pThis->szPrf, pThis->cMsLinkUpDelay / 1000));
1748	e1kArmTimer(pDevIns, pThis, pThis->hLUTimer, pThis->cMsLinkUpDelay * 1000);
1749	#endif /* E1K_LSC_ON_RESET */
1750	}
1751
1752	#endif /* IN_RING3 */
1753
1754	/**
1755	* Compute Internet checksum.
1756	*
1757	* @remarks Refer to http://www.netfor2.com/checksum.html for short intro.
1758	*
1759	* @param pThis The device state structure.
1760	* @param cpPacket The packet.
1761	* @param cb The size of the packet.
1762	* @param pszText A string denoting direction of packet transfer.
1763	*
1764	* @return The 1's complement of the 1's complement sum.
1765	*
1766	* @thread E1000_TX
1767	*/
1768	static uint16_t e1kCSum16(const void *pvBuf, size_t cb)
1769	{
1770	uint32_t csum = 0;
1771	uint16_t pu16 = (uint16_t )pvBuf;
1772
1773	while (cb > 1)
1774	{
1775	csum += *pu16++;
1776	cb -= 2;
1777	}
1778	if (cb)
1779	csum += (uint8_t)pu16;
1780	while (csum >> 16)
1781	csum = (csum >> 16) + (csum & 0xFFFF);
1782	Assert(csum < 65536);
1783	return (uint16_t)~csum;
1784	}
1785
1786	/**
1787	* Dump a packet to debug log.
1788	*
1789	* @param pDevIns The device instance.
1790	* @param pThis The device state structure.
1791	* @param cpPacket The packet.
1792	* @param cb The size of the packet.
1793	* @param pszText A string denoting direction of packet transfer.
1794	* @thread E1000_TX
1795	*/
1796	DECLINLINE(void) e1kPacketDump(PPDMDEVINS pDevIns, PE1KSTATE pThis, const uint8_t cpPacket, size_t cb, const char pszText)
1797	{
1798	#ifdef DEBUG
1799	if (RT_LIKELY(e1kCsEnter(pThis, VERR_SEM_BUSY) == VINF_SUCCESS))
1800	{
1801	Log4(("%s --- %s packet #%d: %RTmac => %RTmac (%d bytes) ---\n",
1802	pThis->szPrf, pszText, ++pThis->u32PktNo, cpPacket+6, cpPacket, cb));
1803	if (ntohs((uint16_t)(cpPacket+12)) == 0x86DD)
1804	{
1805	Log4(("%s --- IPv6: %RTnaipv6 => %RTnaipv6\n",
1806	pThis->szPrf, cpPacket+14+8, cpPacket+14+24));
1807	if (*(cpPacket+14+6) == 0x6)
1808	Log4(("%s --- TCP: seq=%x ack=%x\n", pThis->szPrf,
1809	ntohl((uint32_t)(cpPacket+14+40+4)), ntohl((uint32_t)(cpPacket+14+40+8))));
1810	}
1811	else if (ntohs((uint16_t)(cpPacket+12)) == 0x800)
1812	{
1813	Log4(("%s --- IPv4: %RTnaipv4 => %RTnaipv4\n",
1814	pThis->szPrf, (uint32_t)(cpPacket+14+12), (uint32_t)(cpPacket+14+16)));
1815	if (*(cpPacket+14+6) == 0x6)
1816	Log4(("%s --- TCP: seq=%x ack=%x\n", pThis->szPrf,
1817	ntohl((uint32_t)(cpPacket+14+20+4)), ntohl((uint32_t)(cpPacket+14+20+8))));
1818	}
1819	E1kLog3(("%.*Rhxd\n", cb, cpPacket));
1820	e1kCsLeave(pThis);
1821	}
1822	#else
1823	if (RT_LIKELY(e1kCsEnter(pThis, VERR_SEM_BUSY) == VINF_SUCCESS))
1824	{
1825	if (ntohs((uint16_t)(cpPacket+12)) == 0x86DD)
1826	E1kLogRel(("E1000: %s packet #%d, %RTmac => %RTmac, %RTnaipv6 => %RTnaipv6, seq=%x ack=%x\n",
1827	pszText, ++pThis->u32PktNo, cpPacket+6, cpPacket, cpPacket+14+8, cpPacket+14+24,
1828	ntohl((uint32_t)(cpPacket+14+40+4)), ntohl((uint32_t)(cpPacket+14+40+8))));
1829	else
1830	E1kLogRel(("E1000: %s packet #%d, %RTmac => %RTmac, %RTnaipv4 => %RTnaipv4, seq=%x ack=%x\n",
1831	pszText, ++pThis->u32PktNo, cpPacket+6, cpPacket,
1832	(uint32_t)(cpPacket+14+12), (uint32_t)(cpPacket+14+16),
1833	ntohl((uint32_t)(cpPacket+14+20+4)), ntohl((uint32_t)(cpPacket+14+20+8))));
1834	e1kCsLeave(pThis);
1835	}
1836	RT_NOREF2(cb, pszText);
1837	#endif
1838	}
1839
1840	/**
1841	* Determine the type of transmit descriptor.
1842	*
1843	* @returns Descriptor type. See E1K_DTYP_XXX defines.
1844	*
1845	* @param pDesc Pointer to descriptor union.
1846	* @thread E1000_TX
1847	*/
1848	DECLINLINE(int) e1kGetDescType(E1KTXDESC *pDesc)
1849	{
1850	if (pDesc->legacy.cmd.fDEXT)
1851	return pDesc->context.dw2.u4DTYP;
1852	return E1K_DTYP_LEGACY;
1853	}
1854
1855
1856	#ifdef E1K_WITH_RXD_CACHE
1857	/**
1858	* Return the number of RX descriptor that belong to the hardware.
1859	*
1860	* @returns the number of available descriptors in RX ring.
1861	* @param pThis The device state structure.
1862	* @thread ???
1863	*/
1864	DECLINLINE(uint32_t) e1kGetRxLen(PE1KSTATE pThis)
1865	{
1866	/**
1867	* Make sure RDT won't change during computation. EMT may modify RDT at
1868	* any moment.
1869	*/
1870	uint32_t rdt = RDT;
1871	return (RDH > rdt ? RDLEN/sizeof(E1KRXDESC) : 0) + rdt - RDH;
1872	}
1873
1874	DECLINLINE(unsigned) e1kRxDInCache(PE1KSTATE pThis)
1875	{
1876	return pThis->nRxDFetched > pThis->iRxDCurrent ?
1877	pThis->nRxDFetched - pThis->iRxDCurrent : 0;
1878	}
1879
1880	DECLINLINE(unsigned) e1kRxDIsCacheEmpty(PE1KSTATE pThis)
1881	{
1882	return pThis->iRxDCurrent >= pThis->nRxDFetched;
1883	}
1884
1885	/**
1886	* Load receive descriptors from guest memory. The caller needs to be in Rx
1887	* critical section.
1888	*
1889	* We need two physical reads in case the tail wrapped around the end of RX
1890	* descriptor ring.
1891	*
1892	* @returns the actual number of descriptors fetched.
1893	* @param pDevIns The device instance.
1894	* @param pThis The device state structure.
1895	* @thread EMT, RX
1896	*/
1897	DECLINLINE(unsigned) e1kRxDPrefetch(PPDMDEVINS pDevIns, PE1KSTATE pThis)
1898	{
1899	/* We've already loaded pThis->nRxDFetched descriptors past RDH. */
1900	unsigned nDescsAvailable = e1kGetRxLen(pThis) - e1kRxDInCache(pThis);
1901	unsigned nDescsToFetch = RT_MIN(nDescsAvailable, E1K_RXD_CACHE_SIZE - pThis->nRxDFetched);
1902	unsigned nDescsTotal = RDLEN / sizeof(E1KRXDESC);
1903	Assert(nDescsTotal != 0);
1904	if (nDescsTotal == 0)
1905	return 0;
1906	unsigned nFirstNotLoaded = (RDH + e1kRxDInCache(pThis)) % nDescsTotal;
1907	unsigned nDescsInSingleRead = RT_MIN(nDescsToFetch, nDescsTotal - nFirstNotLoaded);
1908	E1kLog3(("%s e1kRxDPrefetch: nDescsAvailable=%u nDescsToFetch=%u "
1909	"nDescsTotal=%u nFirstNotLoaded=0x%x nDescsInSingleRead=%u\n",
1910	pThis->szPrf, nDescsAvailable, nDescsToFetch, nDescsTotal,
1911	nFirstNotLoaded, nDescsInSingleRead));
1912	if (nDescsToFetch == 0)
1913	return 0;
1914	E1KRXDESC* pFirstEmptyDesc = &pThis->aRxDescriptors[pThis->nRxDFetched];
1915	PDMDevHlpPhysRead(pDevIns,
1916	((uint64_t)RDBAH << 32) + RDBAL + nFirstNotLoaded * sizeof(E1KRXDESC),
1917	pFirstEmptyDesc, nDescsInSingleRead * sizeof(E1KRXDESC));
1918	// uint64_t addrBase = ((uint64_t)RDBAH << 32) + RDBAL;
1919	// unsigned i, j;
1920	// for (i = pThis->nRxDFetched; i < pThis->nRxDFetched + nDescsInSingleRead; ++i)
1921	// {
1922	// pThis->aRxDescAddr[i] = addrBase + (nFirstNotLoaded + i - pThis->nRxDFetched) * sizeof(E1KRXDESC);
1923	// E1kLog3(("%s aRxDescAddr[%d] = %p\n", pThis->szPrf, i, pThis->aRxDescAddr[i]));
1924	// }
1925	E1kLog3(("%s Fetched %u RX descriptors at %08x%08x(0x%x), RDLEN=%08x, RDH=%08x, RDT=%08x\n",
1926	pThis->szPrf, nDescsInSingleRead,
1927	RDBAH, RDBAL + RDH * sizeof(E1KRXDESC),
1928	nFirstNotLoaded, RDLEN, RDH, RDT));
1929	if (nDescsToFetch > nDescsInSingleRead)
1930	{
1931	PDMDevHlpPhysRead(pDevIns,
1932	((uint64_t)RDBAH << 32) + RDBAL,
1933	pFirstEmptyDesc + nDescsInSingleRead,
1934	(nDescsToFetch - nDescsInSingleRead) * sizeof(E1KRXDESC));
1935	// Assert(i == pThis->nRxDFetched + nDescsInSingleRead);
1936	// for (j = 0; i < pThis->nRxDFetched + nDescsToFetch; ++i, ++j)
1937	// {
1938	// pThis->aRxDescAddr[i] = addrBase + j * sizeof(E1KRXDESC);
1939	// E1kLog3(("%s aRxDescAddr[%d] = %p\n", pThis->szPrf, i, pThis->aRxDescAddr[i]));
1940	// }
1941	E1kLog3(("%s Fetched %u RX descriptors at %08x%08x\n",
1942	pThis->szPrf, nDescsToFetch - nDescsInSingleRead,
1943	RDBAH, RDBAL));
1944	}
1945	pThis->nRxDFetched += nDescsToFetch;
1946	return nDescsToFetch;
1947	}
1948
1949	# ifdef IN_RING3 /* currently only used in ring-3 due to stack space requirements of the caller */
1950	/**
1951	* Dump receive descriptor to debug log.
1952	*
1953	* @param pThis The device state structure.
1954	* @param pDesc Pointer to the descriptor.
1955	* @thread E1000_RX
1956	*/
1957	static void e1kPrintRDesc(PE1KSTATE pThis, E1KRXDESC *pDesc)
1958	{
1959	RT_NOREF2(pThis, pDesc);
1960	E1kLog2(("%s <-- Receive Descriptor (%d bytes):\n", pThis->szPrf, pDesc->u16Length));
1961	E1kLog2((" Address=%16LX Length=%04X Csum=%04X\n",
1962	pDesc->u64BufAddr, pDesc->u16Length, pDesc->u16Checksum));
1963	E1kLog2((" STA: %s %s %s %s %s %s %s ERR: %s %s %s %s SPECIAL: %s VLAN=%03x PRI=%x\n",
1964	pDesc->status.fPIF ? "PIF" : "pif",
1965	pDesc->status.fIPCS ? "IPCS" : "ipcs",
1966	pDesc->status.fTCPCS ? "TCPCS" : "tcpcs",
1967	pDesc->status.fVP ? "VP" : "vp",
1968	pDesc->status.fIXSM ? "IXSM" : "ixsm",
1969	pDesc->status.fEOP ? "EOP" : "eop",
1970	pDesc->status.fDD ? "DD" : "dd",
1971	pDesc->status.fRXE ? "RXE" : "rxe",
1972	pDesc->status.fIPE ? "IPE" : "ipe",
1973	pDesc->status.fTCPE ? "TCPE" : "tcpe",
1974	pDesc->status.fCE ? "CE" : "ce",
1975	E1K_SPEC_CFI(pDesc->status.u16Special) ? "CFI" :"cfi",
1976	E1K_SPEC_VLAN(pDesc->status.u16Special),
1977	E1K_SPEC_PRI(pDesc->status.u16Special)));
1978	}
1979	# endif /* IN_RING3 */
1980	#endif /* E1K_WITH_RXD_CACHE */
1981
1982	/**
1983	* Dump transmit descriptor to debug log.
1984	*
1985	* @param pThis The device state structure.
1986	* @param pDesc Pointer to descriptor union.
1987	* @param pszDir A string denoting direction of descriptor transfer
1988	* @thread E1000_TX
1989	*/
1990	static void e1kPrintTDesc(PE1KSTATE pThis, E1KTXDESC pDesc, const char pszDir,
1991	unsigned uLevel = RTLOGGRPFLAGS_LEVEL_2)
1992	{
1993	RT_NOREF4(pThis, pDesc, pszDir, uLevel);
1994
1995	/*
1996	* Unfortunately we cannot use our format handler here, we want R0 logging
1997	* as well.
1998	*/
1999	switch (e1kGetDescType(pDesc))
2000	{
2001	case E1K_DTYP_CONTEXT:
2002	E1kLogX(uLevel, ("%s %s Context Transmit Descriptor %s\n",
2003	pThis->szPrf, pszDir, pszDir));
2004	E1kLogX(uLevel, (" IPCSS=%02X IPCSO=%02X IPCSE=%04X TUCSS=%02X TUCSO=%02X TUCSE=%04X\n",
2005	pDesc->context.ip.u8CSS, pDesc->context.ip.u8CSO, pDesc->context.ip.u16CSE,
2006	pDesc->context.tu.u8CSS, pDesc->context.tu.u8CSO, pDesc->context.tu.u16CSE));
2007	E1kLogX(uLevel, (" TUCMD:%s%s%s %s %s PAYLEN=%04x HDRLEN=%04x MSS=%04x STA: %s\n",
2008	pDesc->context.dw2.fIDE ? " IDE":"",
2009	pDesc->context.dw2.fRS ? " RS" :"",
2010	pDesc->context.dw2.fTSE ? " TSE":"",
2011	pDesc->context.dw2.fIP ? "IPv4":"IPv6",
2012	pDesc->context.dw2.fTCP ? "TCP":"UDP",
2013	pDesc->context.dw2.u20PAYLEN,
2014	pDesc->context.dw3.u8HDRLEN,
2015	pDesc->context.dw3.u16MSS,
2016	pDesc->context.dw3.fDD?"DD":""));
2017	break;
2018	case E1K_DTYP_DATA:
2019	E1kLogX(uLevel, ("%s %s Data Transmit Descriptor (%d bytes) %s\n",
2020	pThis->szPrf, pszDir, pDesc->data.cmd.u20DTALEN, pszDir));
2021	E1kLogX(uLevel, (" Address=%16LX DTALEN=%05X\n",
2022	pDesc->data.u64BufAddr,
2023	pDesc->data.cmd.u20DTALEN));
2024	E1kLogX(uLevel, (" DCMD:%s%s%s%s%s%s%s STA:%s%s%s POPTS:%s%s SPECIAL:%s VLAN=%03x PRI=%x\n",
2025	pDesc->data.cmd.fIDE ? " IDE" :"",
2026	pDesc->data.cmd.fVLE ? " VLE" :"",
2027	pDesc->data.cmd.fRPS ? " RPS" :"",
2028	pDesc->data.cmd.fRS ? " RS" :"",
2029	pDesc->data.cmd.fTSE ? " TSE" :"",
2030	pDesc->data.cmd.fIFCS? " IFCS":"",
2031	pDesc->data.cmd.fEOP ? " EOP" :"",
2032	pDesc->data.dw3.fDD ? " DD" :"",
2033	pDesc->data.dw3.fEC ? " EC" :"",
2034	pDesc->data.dw3.fLC ? " LC" :"",
2035	pDesc->data.dw3.fTXSM? " TXSM":"",
2036	pDesc->data.dw3.fIXSM? " IXSM":"",
2037	E1K_SPEC_CFI(pDesc->data.dw3.u16Special) ? "CFI" :"cfi",
2038	E1K_SPEC_VLAN(pDesc->data.dw3.u16Special),
2039	E1K_SPEC_PRI(pDesc->data.dw3.u16Special)));
2040	break;
2041	case E1K_DTYP_LEGACY:
2042	E1kLogX(uLevel, ("%s %s Legacy Transmit Descriptor (%d bytes) %s\n",
2043	pThis->szPrf, pszDir, pDesc->legacy.cmd.u16Length, pszDir));
2044	E1kLogX(uLevel, (" Address=%16LX DTALEN=%05X\n",
2045	pDesc->data.u64BufAddr,
2046	pDesc->legacy.cmd.u16Length));
2047	E1kLogX(uLevel, (" CMD:%s%s%s%s%s%s%s STA:%s%s%s CSO=%02x CSS=%02x SPECIAL:%s VLAN=%03x PRI=%x\n",
2048	pDesc->legacy.cmd.fIDE ? " IDE" :"",
2049	pDesc->legacy.cmd.fVLE ? " VLE" :"",
2050	pDesc->legacy.cmd.fRPS ? " RPS" :"",
2051	pDesc->legacy.cmd.fRS ? " RS" :"",
2052	pDesc->legacy.cmd.fIC ? " IC" :"",
2053	pDesc->legacy.cmd.fIFCS? " IFCS":"",
2054	pDesc->legacy.cmd.fEOP ? " EOP" :"",
2055	pDesc->legacy.dw3.fDD ? " DD" :"",
2056	pDesc->legacy.dw3.fEC ? " EC" :"",
2057	pDesc->legacy.dw3.fLC ? " LC" :"",
2058	pDesc->legacy.cmd.u8CSO,
2059	pDesc->legacy.dw3.u8CSS,
2060	E1K_SPEC_CFI(pDesc->legacy.dw3.u16Special) ? "CFI" :"cfi",
2061	E1K_SPEC_VLAN(pDesc->legacy.dw3.u16Special),
2062	E1K_SPEC_PRI(pDesc->legacy.dw3.u16Special)));
2063	break;
2064	default:
2065	E1kLog(("%s %s Invalid Transmit Descriptor %s\n",
2066	pThis->szPrf, pszDir, pszDir));
2067	break;
2068	}
2069	}
2070
2071	/**
2072	* Raise an interrupt later.
2073	*
2074	* @param pThis The device state structure.
2075	*/
2076	DECLINLINE(void) e1kPostponeInterrupt(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint64_t nsDeadline)
2077	{
2078	if (!PDMDevHlpTimerIsActive(pDevIns, pThis->hIntTimer))
2079	PDMDevHlpTimerSetNano(pDevIns, pThis->hIntTimer, nsDeadline);
2080	}
2081
2082	/**
2083	* Raise interrupt if not masked.
2084	*
2085	* @param pThis The device state structure.
2086	*/
2087	static int e1kRaiseInterrupt(PPDMDEVINS pDevIns, PE1KSTATE pThis, int rcBusy, uint32_t u32IntCause = 0)
2088	{
2089	int rc = e1kCsEnter(pThis, rcBusy);
2090	if (RT_UNLIKELY(rc != VINF_SUCCESS))
2091	return rc;
2092
2093	E1K_INC_ISTAT_CNT(pThis->uStatIntTry);
2094	ICR \|= u32IntCause;
2095	if (ICR & IMS)
2096	{
2097	if (pThis->fIntRaised)
2098	{
2099	E1K_INC_ISTAT_CNT(pThis->uStatIntSkip);
2100	E1kLog2(("%s e1kRaiseInterrupt: Already raised, skipped. ICR&IMS=%08x\n",
2101	pThis->szPrf, ICR & IMS));
2102	}
2103	else
2104	{
2105	uint64_t tsNow = PDMDevHlpTimerGet(pDevIns, pThis->hIntTimer);
2106	if (!!ITR && tsNow - pThis->u64AckedAt < ITR * 256
2107	&& pThis->fItrEnabled && (pThis->fItrRxEnabled \|\| !(ICR & ICR_RXT0)))
2108	{
2109	E1K_INC_ISTAT_CNT(pThis->uStatIntEarly);
2110	E1kLog2(("%s e1kRaiseInterrupt: Too early to raise again: %d ns < %d ns.\n",
2111	pThis->szPrf, (uint32_t)(tsNow - pThis->u64AckedAt), ITR * 256));
2112	e1kPostponeInterrupt(pDevIns, pThis, ITR * 256);
2113	}
2114	else
2115	{
2116
2117	/* Since we are delivering the interrupt now
2118	* there is no need to do it later -- stop the timer.
2119	*/
2120	PDMDevHlpTimerStop(pDevIns, pThis->hIntTimer);
2121	E1K_INC_ISTAT_CNT(pThis->uStatInt);
2122	STAM_COUNTER_INC(&pThis->StatIntsRaised);
2123	/* Got at least one unmasked interrupt cause */
2124	pThis->fIntRaised = true;
2125	/* Raise(1) INTA(0) */
2126	E1kLogRel(("E1000: irq RAISED icr&mask=0x%x, icr=0x%x\n", ICR & IMS, ICR));
2127	PDMDevHlpPCISetIrq(pDevIns, 0, 1);
2128	E1kLog(("%s e1kRaiseInterrupt: Raised. ICR&IMS=%08x\n",
2129	pThis->szPrf, ICR & IMS));
2130	}
2131	}
2132	}
2133	else
2134	{
2135	E1K_INC_ISTAT_CNT(pThis->uStatIntMasked);
2136	E1kLog2(("%s e1kRaiseInterrupt: Not raising, ICR=%08x, IMS=%08x\n",
2137	pThis->szPrf, ICR, IMS));
2138	}
2139	e1kCsLeave(pThis);
2140	return VINF_SUCCESS;
2141	}
2142
2143	/**
2144	* Compute the physical address of the descriptor.
2145	*
2146	* @returns the physical address of the descriptor.
2147	*
2148	* @param baseHigh High-order 32 bits of descriptor table address.
2149	* @param baseLow Low-order 32 bits of descriptor table address.
2150	* @param idxDesc The descriptor index in the table.
2151	*/
2152	DECLINLINE(RTGCPHYS) e1kDescAddr(uint32_t baseHigh, uint32_t baseLow, uint32_t idxDesc)
2153	{
2154	AssertCompile(sizeof(E1KRXDESC) == sizeof(E1KTXDESC));
2155	return ((uint64_t)baseHigh << 32) + baseLow + idxDesc * sizeof(E1KRXDESC);
2156	}
2157
2158	#ifdef IN_RING3 /* currently only used in ring-3 due to stack space requirements of the caller */
2159	/**
2160	* Advance the head pointer of the receive descriptor queue.
2161	*
2162	* @remarks RDH always points to the next available RX descriptor.
2163	*
2164	* @param pDevIns The device instance.
2165	* @param pThis The device state structure.
2166	*/
2167	DECLINLINE(void) e1kAdvanceRDH(PPDMDEVINS pDevIns, PE1KSTATE pThis)
2168	{
2169	Assert(e1kCsRxIsOwner(pThis));
2170	//e1kCsEnter(pThis, RT_SRC_POS);
2171	if (++RDH * sizeof(E1KRXDESC) >= RDLEN)
2172	RDH = 0;
2173	#ifdef E1K_WITH_RXD_CACHE
2174	/*
2175	* We need to fetch descriptors now as the guest may advance RDT all the way
2176	* to RDH as soon as we generate RXDMT0 interrupt. This is mostly to provide
2177	* compatibility with Phar Lap ETS, see @bugref(7346). Note that we do not
2178	* check if the receiver is enabled. It must be, otherwise we won't get here
2179	* in the first place.
2180	*
2181	* Note that we should have moved both RDH and iRxDCurrent by now.
2182	*/
2183	if (e1kRxDIsCacheEmpty(pThis))
2184	{
2185	/* Cache is empty, reset it and check if we can fetch more. */
2186	pThis->iRxDCurrent = pThis->nRxDFetched = 0;
2187	E1kLog3(("%s e1kAdvanceRDH: Rx cache is empty, RDH=%x RDT=%x "
2188	"iRxDCurrent=%x nRxDFetched=%x\n",
2189	pThis->szPrf, RDH, RDT, pThis->iRxDCurrent, pThis->nRxDFetched));
2190	e1kRxDPrefetch(pDevIns, pThis);
2191	}
2192	#endif /* E1K_WITH_RXD_CACHE */
2193	/*
2194	* Compute current receive queue length and fire RXDMT0 interrupt
2195	* if we are low on receive buffers
2196	*/
2197	uint32_t uRQueueLen = RDH>RDT ? RDLEN/sizeof(E1KRXDESC)-RDH+RDT : RDT-RDH;
2198	/*
2199	* The minimum threshold is controlled by RDMTS bits of RCTL:
2200	* 00 = 1/2 of RDLEN
2201	* 01 = 1/4 of RDLEN
2202	* 10 = 1/8 of RDLEN
2203	* 11 = reserved
2204	*/
2205	uint32_t uMinRQThreshold = RDLEN / sizeof(E1KRXDESC) / (2 << GET_BITS(RCTL, RDMTS));
2206	if (uRQueueLen <= uMinRQThreshold)
2207	{
2208	E1kLogRel(("E1000: low on RX descriptors, RDH=%x RDT=%x len=%x threshold=%x\n", RDH, RDT, uRQueueLen, uMinRQThreshold));
2209	E1kLog2(("%s Low on RX descriptors, RDH=%x RDT=%x len=%x threshold=%x, raise an interrupt\n",
2210	pThis->szPrf, RDH, RDT, uRQueueLen, uMinRQThreshold));
2211	E1K_INC_ISTAT_CNT(pThis->uStatIntRXDMT0);
2212	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_RXDMT0);
2213	}
2214	E1kLog2(("%s e1kAdvanceRDH: at exit RDH=%x RDT=%x len=%x\n",
2215	pThis->szPrf, RDH, RDT, uRQueueLen));
2216	//e1kCsLeave(pThis);
2217	}
2218	#endif /* IN_RING3 */
2219
2220	#ifdef E1K_WITH_RXD_CACHE
2221
2222	# ifdef IN_RING3 /* currently only used in ring-3 due to stack space requirements of the caller */
2223
2224	/**
2225	* Obtain the next RX descriptor from RXD cache, fetching descriptors from the
2226	* RX ring if the cache is empty.
2227	*
2228	* Note that we cannot advance the cache pointer (iRxDCurrent) yet as it will
2229	* go out of sync with RDH which will cause trouble when EMT checks if the
2230	* cache is empty to do pre-fetch @bugref(6217).
2231	*
2232	* @param pDevIns The device instance.
2233	* @param pThis The device state structure.
2234	* @thread RX
2235	*/
2236	DECLINLINE(E1KRXDESC *) e1kRxDGet(PPDMDEVINS pDevIns, PE1KSTATE pThis)
2237	{
2238	Assert(e1kCsRxIsOwner(pThis));
2239	/* Check the cache first. */
2240	if (pThis->iRxDCurrent < pThis->nRxDFetched)
2241	return &pThis->aRxDescriptors[pThis->iRxDCurrent];
2242	/* Cache is empty, reset it and check if we can fetch more. */
2243	pThis->iRxDCurrent = pThis->nRxDFetched = 0;
2244	if (e1kRxDPrefetch(pDevIns, pThis))
2245	return &pThis->aRxDescriptors[pThis->iRxDCurrent];
2246	/* Out of Rx descriptors. */
2247	return NULL;
2248	}
2249
2250
2251	/**
2252	* Return the RX descriptor obtained with e1kRxDGet() and advance the cache
2253	* pointer. The descriptor gets written back to the RXD ring.
2254	*
2255	* @param pDevIns The device instance.
2256	* @param pThis The device state structure.
2257	* @param pDesc The descriptor being "returned" to the RX ring.
2258	* @thread RX
2259	*/
2260	DECLINLINE(void) e1kRxDPut(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KRXDESC* pDesc)
2261	{
2262	Assert(e1kCsRxIsOwner(pThis));
2263	pThis->iRxDCurrent++;
2264	// Assert(pDesc >= pThis->aRxDescriptors);
2265	// Assert(pDesc < pThis->aRxDescriptors + E1K_RXD_CACHE_SIZE);
2266	// uint64_t addr = e1kDescAddr(RDBAH, RDBAL, RDH);
2267	// uint32_t rdh = RDH;
2268	// Assert(pThis->aRxDescAddr[pDesc - pThis->aRxDescriptors] == addr);
2269	PDMDevHlpPCIPhysWrite(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), pDesc, sizeof(E1KRXDESC));
2270	/*
2271	* We need to print the descriptor before advancing RDH as it may fetch new
2272	* descriptors into the cache.
2273	*/
2274	e1kPrintRDesc(pThis, pDesc);
2275	e1kAdvanceRDH(pDevIns, pThis);
2276	}
2277
2278	/**
2279	* Store a fragment of received packet at the specifed address.
2280	*
2281	* @param pDevIns The device instance.
2282	* @param pThis The device state structure.
2283	* @param pDesc The next available RX descriptor.
2284	* @param pvBuf The fragment.
2285	* @param cb The size of the fragment.
2286	*/
2287	static void e1kStoreRxFragment(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KRXDESC pDesc, const void pvBuf, size_t cb)
2288	{
2289	STAM_PROFILE_ADV_START(&pThis->StatReceiveStore, a);
2290	E1kLog2(("%s e1kStoreRxFragment: store fragment of %04X at %016LX, EOP=%d\n",
2291	pThis->szPrf, cb, pDesc->u64BufAddr, pDesc->status.fEOP));
2292	PDMDevHlpPCIPhysWrite(pDevIns, pDesc->u64BufAddr, pvBuf, cb);
2293	pDesc->u16Length = (uint16_t)cb;
2294	Assert(pDesc->u16Length == cb);
2295	STAM_PROFILE_ADV_STOP(&pThis->StatReceiveStore, a);
2296	RT_NOREF(pThis);
2297	}
2298
2299	# endif /* IN_RING3 */
2300
2301	#else /* !E1K_WITH_RXD_CACHE */
2302
2303	/**
2304	* Store a fragment of received packet that fits into the next available RX
2305	* buffer.
2306	*
2307	* @remarks Trigger the RXT0 interrupt if it is the last fragment of the packet.
2308	*
2309	* @param pDevIns The device instance.
2310	* @param pThis The device state structure.
2311	* @param pDesc The next available RX descriptor.
2312	* @param pvBuf The fragment.
2313	* @param cb The size of the fragment.
2314	*/
2315	static void e1kStoreRxFragment(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KRXDESC pDesc, const void pvBuf, size_t cb)
2316	{
2317	STAM_PROFILE_ADV_START(&pThis->StatReceiveStore, a);
2318	E1kLog2(("%s e1kStoreRxFragment: store fragment of %04X at %016LX, EOP=%d\n", pThis->szPrf, cb, pDesc->u64BufAddr, pDesc->status.fEOP));
2319	PDMDevHlpPCIPhysWrite(pDevIns, pDesc->u64BufAddr, pvBuf, cb);
2320	pDesc->u16Length = (uint16_t)cb; Assert(pDesc->u16Length == cb);
2321	/* Write back the descriptor */
2322	PDMDevHlpPCIPhysWrite(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), pDesc, sizeof(E1KRXDESC));
2323	e1kPrintRDesc(pThis, pDesc);
2324	E1kLogRel(("E1000: Wrote back RX desc, RDH=%x\n", RDH));
2325	/* Advance head */
2326	e1kAdvanceRDH(pDevIns, pThis);
2327	//E1kLog2(("%s e1kStoreRxFragment: EOP=%d RDTR=%08X RADV=%08X\n", pThis->szPrf, pDesc->fEOP, RDTR, RADV));
2328	if (pDesc->status.fEOP)
2329	{
2330	/* Complete packet has been stored -- it is time to let the guest know. */
2331	#ifdef E1K_USE_RX_TIMERS
2332	if (RDTR)
2333	{
2334	/* Arm the timer to fire in RDTR usec (discard .024) */
2335	e1kArmTimer(pDevIns, pThis, pThis->hRIDTimer, RDTR);
2336	/* If absolute timer delay is enabled and the timer is not running yet, arm it. */
2337	if (RADV != 0 && !PDMDevHlpTimerIsActive(pDevIns, pThis->CTX_SUFF(pRADTimer)))
2338	e1kArmTimer(pThis, pThis->hRADTimer, RADV);
2339	}
2340	else
2341	{
2342	#endif
2343	/* 0 delay means immediate interrupt */
2344	E1K_INC_ISTAT_CNT(pThis->uStatIntRx);
2345	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_RXT0);
2346	#ifdef E1K_USE_RX_TIMERS
2347	}
2348	#endif
2349	}
2350	STAM_PROFILE_ADV_STOP(&pThis->StatReceiveStore, a);
2351	}
2352
2353	#endif /* !E1K_WITH_RXD_CACHE */
2354
2355	/**
2356	* Returns true if it is a broadcast packet.
2357	*
2358	* @returns true if destination address indicates broadcast.
2359	* @param pvBuf The ethernet packet.
2360	*/
2361	DECLINLINE(bool) e1kIsBroadcast(const void *pvBuf)
2362	{
2363	static const uint8_t s_abBcastAddr[] = { 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF };
2364	return memcmp(pvBuf, s_abBcastAddr, sizeof(s_abBcastAddr)) == 0;
2365	}
2366
2367	/**
2368	* Returns true if it is a multicast packet.
2369	*
2370	* @remarks returns true for broadcast packets as well.
2371	* @returns true if destination address indicates multicast.
2372	* @param pvBuf The ethernet packet.
2373	*/
2374	DECLINLINE(bool) e1kIsMulticast(const void *pvBuf)
2375	{
2376	return ((char)pvBuf) & 1;
2377	}
2378
2379	#ifdef IN_RING3 /* currently only used in ring-3 due to stack space requirements of the caller */
2380	/**
2381	* Set IXSM, IPCS and TCPCS flags according to the packet type.
2382	*
2383	* @remarks We emulate checksum offloading for major packets types only.
2384	*
2385	* @returns VBox status code.
2386	* @param pThis The device state structure.
2387	* @param pFrame The available data.
2388	* @param cb Number of bytes available in the buffer.
2389	* @param status Bit fields containing status info.
2390	*/
2391	static int e1kRxChecksumOffload(PE1KSTATE pThis, const uint8_t pFrame, size_t cb, E1KRXDST pStatus)
2392	{
2393	/** @todo
2394	* It is not safe to bypass checksum verification for packets coming
2395	* from real wire. We currently unable to tell where packets are
2396	* coming from so we tell the driver to ignore our checksum flags
2397	* and do verification in software.
2398	*/
2399	# if 0
2400	uint16_t uEtherType = ntohs((uint16_t)(pFrame + 12));
2401
2402	E1kLog2(("%s e1kRxChecksumOffload: EtherType=%x\n", pThis->szPrf, uEtherType));
2403
2404	switch (uEtherType)
2405	{
2406	case 0x800: /* IPv4 */
2407	{
2408	pStatus->fIXSM = false;
2409	pStatus->fIPCS = true;
2410	PRTNETIPV4 pIpHdr4 = (PRTNETIPV4)(pFrame + 14);
2411	/* TCP/UDP checksum offloading works with TCP and UDP only */
2412	pStatus->fTCPCS = pIpHdr4->ip_p == 6 \|\| pIpHdr4->ip_p == 17;
2413	break;
2414	}
2415	case 0x86DD: /* IPv6 */
2416	pStatus->fIXSM = false;
2417	pStatus->fIPCS = false;
2418	pStatus->fTCPCS = true;
2419	break;
2420	default: /* ARP, VLAN, etc. */
2421	pStatus->fIXSM = true;
2422	break;
2423	}
2424	# else
2425	pStatus->fIXSM = true;
2426	RT_NOREF_PV(pThis); RT_NOREF_PV(pFrame); RT_NOREF_PV(cb);
2427	# endif
2428	return VINF_SUCCESS;
2429	}
2430	#endif /* IN_RING3 */
2431
2432	/**
2433	* Pad and store received packet.
2434	*
2435	* @remarks Make sure that the packet appears to upper layer as one coming
2436	* from real Ethernet: pad it and insert FCS.
2437	*
2438	* @returns VBox status code.
2439	* @param pDevIns The device instance.
2440	* @param pThis The device state structure.
2441	* @param pvBuf The available data.
2442	* @param cb Number of bytes available in the buffer.
2443	* @param status Bit fields containing status info.
2444	*/
2445	static int e1kHandleRxPacket(PPDMDEVINS pDevIns, PE1KSTATE pThis, const void *pvBuf, size_t cb, E1KRXDST status)
2446	{
2447	#if defined(IN_RING3) /** @todo Remove this extra copying, it's gonna make us run out of kernel / hypervisor stack! */
2448	uint8_t rxPacket[E1K_MAX_RX_PKT_SIZE];
2449	uint8_t *ptr = rxPacket;
2450
2451	int rc = e1kCsRxEnter(pThis, VERR_SEM_BUSY);
2452	if (RT_UNLIKELY(rc != VINF_SUCCESS))
2453	return rc;
2454
2455	if (cb > 70) /* unqualified guess */
2456	pThis->led.Asserted.s.fReading = pThis->led.Actual.s.fReading = 1;
2457
2458	Assert(cb <= E1K_MAX_RX_PKT_SIZE);
2459	Assert(cb > 16);
2460	size_t cbMax = ((RCTL & RCTL_LPE) ? E1K_MAX_RX_PKT_SIZE - 4 : 1518) - (status.fVP ? 0 : 4);
2461	E1kLog3(("%s Max RX packet size is %u\n", pThis->szPrf, cbMax));
2462	if (status.fVP)
2463	{
2464	/* VLAN packet -- strip VLAN tag in VLAN mode */
2465	if ((CTRL & CTRL_VME) && cb > 16)
2466	{
2467	uint16_t u16Ptr = (uint16_t)pvBuf;
2468	memcpy(rxPacket, pvBuf, 12); /* Copy src and dst addresses */
2469	status.u16Special = RT_BE2H_U16(u16Ptr[7]); /* Extract VLAN tag */
2470	memcpy(rxPacket + 12, (uint8_t)pvBuf + 16, cb - 16); / Copy the rest of the packet */
2471	cb -= 4;
2472	E1kLog3(("%s Stripped tag for VLAN %u (cb=%u)\n",
2473	pThis->szPrf, status.u16Special, cb));
2474	}
2475	else
2476	{
2477	status.fVP = false; /* Set VP only if we stripped the tag */
2478	memcpy(rxPacket, pvBuf, cb);
2479	}
2480	}
2481	else
2482	memcpy(rxPacket, pvBuf, cb);
2483	/* Pad short packets */
2484	if (cb < 60)
2485	{
2486	memset(rxPacket + cb, 0, 60 - cb);
2487	cb = 60;
2488	}
2489	if (!(RCTL & RCTL_SECRC) && cb <= cbMax)
2490	{
2491	STAM_PROFILE_ADV_START(&pThis->StatReceiveCRC, a);
2492	/*
2493	* Add FCS if CRC stripping is not enabled. Since the value of CRC
2494	* is ignored by most of drivers we may as well save us the trouble
2495	* of calculating it (see EthernetCRC CFGM parameter).
2496	*/
2497	if (pThis->fEthernetCRC)
2498	(uint32_t)(rxPacket + cb) = RTCrc32(rxPacket, cb);
2499	cb += sizeof(uint32_t);
2500	STAM_PROFILE_ADV_STOP(&pThis->StatReceiveCRC, a);
2501	E1kLog3(("%s Added FCS (cb=%u)\n", pThis->szPrf, cb));
2502	}
2503	/* Compute checksum of complete packet */
2504	size_t cbCSumStart = RT_MIN(GET_BITS(RXCSUM, PCSS), cb);
2505	uint16_t checksum = e1kCSum16(rxPacket + cbCSumStart, cb - cbCSumStart);
2506	e1kRxChecksumOffload(pThis, rxPacket, cb, &status);
2507
2508	/* Update stats */
2509	E1K_INC_CNT32(GPRC);
2510	if (e1kIsBroadcast(pvBuf))
2511	E1K_INC_CNT32(BPRC);
2512	else if (e1kIsMulticast(pvBuf))
2513	E1K_INC_CNT32(MPRC);
2514	/* Update octet receive counter */
2515	E1K_ADD_CNT64(GORCL, GORCH, cb);
2516	STAM_REL_COUNTER_ADD(&pThis->StatReceiveBytes, cb);
2517	if (cb == 64)
2518	E1K_INC_CNT32(PRC64);
2519	else if (cb < 128)
2520	E1K_INC_CNT32(PRC127);
2521	else if (cb < 256)
2522	E1K_INC_CNT32(PRC255);
2523	else if (cb < 512)
2524	E1K_INC_CNT32(PRC511);
2525	else if (cb < 1024)
2526	E1K_INC_CNT32(PRC1023);
2527	else
2528	E1K_INC_CNT32(PRC1522);
2529
2530	E1K_INC_ISTAT_CNT(pThis->uStatRxFrm);
2531
2532	# ifdef E1K_WITH_RXD_CACHE
2533	while (cb > 0)
2534	{
2535	E1KRXDESC *pDesc = e1kRxDGet(pDevIns, pThis);
2536
2537	if (pDesc == NULL)
2538	{
2539	E1kLog(("%s Out of receive buffers, dropping the packet "
2540	"(cb=%u, in_cache=%u, RDH=%x RDT=%x)\n",
2541	pThis->szPrf, cb, e1kRxDInCache(pThis), RDH, RDT));
2542	break;
2543	}
2544	# else /* !E1K_WITH_RXD_CACHE */
2545	if (RDH == RDT)
2546	{
2547	E1kLog(("%s Out of receive buffers, dropping the packet\n",
2548	pThis->szPrf));
2549	}
2550	/* Store the packet to receive buffers */
2551	while (RDH != RDT)
2552	{
2553	/* Load the descriptor pointed by head */
2554	E1KRXDESC desc, *pDesc = &desc;
2555	PDMDevHlpPhysRead(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), &desc, sizeof(desc));
2556	# endif /* !E1K_WITH_RXD_CACHE */
2557	if (pDesc->u64BufAddr)
2558	{
2559	uint16_t u16RxBufferSize = pThis->u16RxBSize; /* see @bugref{9427} */
2560
2561	/* Update descriptor */
2562	pDesc->status = status;
2563	pDesc->u16Checksum = checksum;
2564	pDesc->status.fDD = true;
2565
2566	/*
2567	* We need to leave Rx critical section here or we risk deadlocking
2568	* with EMT in e1kRegWriteRDT when the write is to an unallocated
2569	* page or has an access handler associated with it.
2570	* Note that it is safe to leave the critical section here since
2571	* e1kRegWriteRDT() never modifies RDH. It never touches already
2572	* fetched RxD cache entries either.
2573	*/
2574	if (cb > u16RxBufferSize)
2575	{
2576	pDesc->status.fEOP = false;
2577	e1kCsRxLeave(pThis);
2578	e1kStoreRxFragment(pDevIns, pThis, pDesc, ptr, u16RxBufferSize);
2579	rc = e1kCsRxEnter(pThis, VERR_SEM_BUSY);
2580	if (RT_UNLIKELY(rc != VINF_SUCCESS))
2581	return rc;
2582	ptr += u16RxBufferSize;
2583	cb -= u16RxBufferSize;
2584	}
2585	else
2586	{
2587	pDesc->status.fEOP = true;
2588	e1kCsRxLeave(pThis);
2589	e1kStoreRxFragment(pDevIns, pThis, pDesc, ptr, cb);
2590	# ifdef E1K_WITH_RXD_CACHE
2591	rc = e1kCsRxEnter(pThis, VERR_SEM_BUSY);
2592	if (RT_UNLIKELY(rc != VINF_SUCCESS))
2593	return rc;
2594	cb = 0;
2595	# else /* !E1K_WITH_RXD_CACHE */
2596	pThis->led.Actual.s.fReading = 0;
2597	return VINF_SUCCESS;
2598	# endif /* !E1K_WITH_RXD_CACHE */
2599	}
2600	/*
2601	* Note: RDH is advanced by e1kStoreRxFragment if E1K_WITH_RXD_CACHE
2602	* is not defined.
2603	*/
2604	}
2605	# ifdef E1K_WITH_RXD_CACHE
2606	/* Write back the descriptor. */
2607	pDesc->status.fDD = true;
2608	e1kRxDPut(pDevIns, pThis, pDesc);
2609	# else /* !E1K_WITH_RXD_CACHE */
2610	else
2611	{
2612	/* Write back the descriptor. */
2613	pDesc->status.fDD = true;
2614	PDMDevHlpPCIPhysWrite(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), pDesc, sizeof(E1KRXDESC));
2615	e1kAdvanceRDH(pDevIns, pThis);
2616	}
2617	# endif /* !E1K_WITH_RXD_CACHE */
2618	}
2619
2620	if (cb > 0)
2621	E1kLog(("%s Out of receive buffers, dropping %u bytes", pThis->szPrf, cb));
2622
2623	pThis->led.Actual.s.fReading = 0;
2624
2625	e1kCsRxLeave(pThis);
2626	# ifdef E1K_WITH_RXD_CACHE
2627	/* Complete packet has been stored -- it is time to let the guest know. */
2628	# ifdef E1K_USE_RX_TIMERS
2629	if (RDTR)
2630	{
2631	/* Arm the timer to fire in RDTR usec (discard .024) */
2632	e1kArmTimer(pThis, pThis->hRIDTimer, RDTR);
2633	/* If absolute timer delay is enabled and the timer is not running yet, arm it. */
2634	if (RADV != 0 && !PDMDevHlpTimerIsActive(pDevIns, pThis->hRADTimer))
2635	e1kArmTimer(pThis, pThis->hRADTimer, RADV);
2636	}
2637	else
2638	{
2639	# endif /* E1K_USE_RX_TIMERS */
2640	/* 0 delay means immediate interrupt */
2641	E1K_INC_ISTAT_CNT(pThis->uStatIntRx);
2642	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_RXT0);
2643	# ifdef E1K_USE_RX_TIMERS
2644	}
2645	# endif /* E1K_USE_RX_TIMERS */
2646	# endif /* E1K_WITH_RXD_CACHE */
2647
2648	return VINF_SUCCESS;
2649	#else /* !IN_RING3 */
2650	RT_NOREF(pDevIns, pThis, pvBuf, cb, status);
2651	return VERR_INTERNAL_ERROR_2;
2652	#endif /* !IN_RING3 */
2653	}
2654
2655
2656	#ifdef IN_RING3
2657	/**
2658	* Bring the link up after the configured delay, 5 seconds by default.
2659	*
2660	* @param pDevIns The device instance.
2661	* @param pThis The device state structure.
2662	* @thread any
2663	*/
2664	DECLINLINE(void) e1kBringLinkUpDelayed(PPDMDEVINS pDevIns, PE1KSTATE pThis)
2665	{
2666	E1kLog(("%s Will bring up the link in %d seconds...\n",
2667	pThis->szPrf, pThis->cMsLinkUpDelay / 1000));
2668	e1kArmTimer(pDevIns, pThis, pThis->hLUTimer, pThis->cMsLinkUpDelay * 1000);
2669	}
2670
2671	/**
2672	* Bring up the link immediately.
2673	*
2674	* @param pDevIns The device instance.
2675	* @param pThis The device state structure.
2676	* @param pThisCC The current context instance data.
2677	*/
2678	DECLINLINE(void) e1kR3LinkUp(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC)
2679	{
2680	E1kLog(("%s Link is up\n", pThis->szPrf));
2681	STATUS \|= STATUS_LU;
2682	Phy::setLinkStatus(&pThis->phy, true);
2683	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_LSC);
2684	if (pThisCC->pDrvR3)
2685	pThisCC->pDrvR3->pfnNotifyLinkChanged(pThisCC->pDrvR3, PDMNETWORKLINKSTATE_UP);
2686	/* Trigger processing of pending TX descriptors (see @bugref{8942}). */
2687	PDMDevHlpTaskTrigger(pDevIns, pThis->hTxTask);
2688	}
2689
2690	/**
2691	* Bring down the link immediately.
2692	*
2693	* @param pDevIns The device instance.
2694	* @param pThis The device state structure.
2695	* @param pThisCC The current context instance data.
2696	*/
2697	DECLINLINE(void) e1kR3LinkDown(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC)
2698	{
2699	E1kLog(("%s Link is down\n", pThis->szPrf));
2700	STATUS &= ~STATUS_LU;
2701	#ifdef E1K_LSC_ON_RESET
2702	Phy::setLinkStatus(&pThis->phy, false);
2703	#endif /* E1K_LSC_ON_RESET */
2704	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_LSC);
2705	if (pThisCC->pDrvR3)
2706	pThisCC->pDrvR3->pfnNotifyLinkChanged(pThisCC->pDrvR3, PDMNETWORKLINKSTATE_DOWN);
2707	}
2708
2709	/**
2710	* Bring down the link temporarily.
2711	*
2712	* @param pDevIns The device instance.
2713	* @param pThis The device state structure.
2714	* @param pThisCC The current context instance data.
2715	*/
2716	DECLINLINE(void) e1kR3LinkDownTemp(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC)
2717	{
2718	E1kLog(("%s Link is down temporarily\n", pThis->szPrf));
2719	STATUS &= ~STATUS_LU;
2720	Phy::setLinkStatus(&pThis->phy, false);
2721	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_LSC);
2722	/*
2723	* Notifying the associated driver that the link went down (even temporarily)
2724	* seems to be the right thing, but it was not done before. This may cause
2725	* a regression if the driver does not expect the link to go down as a result
2726	* of sending PDMNETWORKLINKSTATE_DOWN_RESUME to this device. Earlier versions
2727	* of code notified the driver that the link was up! See @bugref{7057}.
2728	*/
2729	if (pThisCC->pDrvR3)
2730	pThisCC->pDrvR3->pfnNotifyLinkChanged(pThisCC->pDrvR3, PDMNETWORKLINKSTATE_DOWN);
2731	e1kBringLinkUpDelayed(pDevIns, pThis);
2732	}
2733	#endif /* IN_RING3 */
2734
2735	#if 0 /* unused */
2736	/**
2737	* Read handler for Device Status register.
2738	*
2739	* Get the link status from PHY.
2740	*
2741	* @returns VBox status code.
2742	*
2743	* @param pThis The device state structure.
2744	* @param offset Register offset in memory-mapped frame.
2745	* @param index Register index in register array.
2746	* @param mask Used to implement partial reads (8 and 16-bit).
2747	*/
2748	static int e1kRegReadCTRL(PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
2749	{
2750	E1kLog(("%s e1kRegReadCTRL: mdio dir=%s mdc dir=%s mdc=%d\n",
2751	pThis->szPrf, (CTRL & CTRL_MDIO_DIR)?"OUT":"IN ",
2752	(CTRL & CTRL_MDC_DIR)?"OUT":"IN ", !!(CTRL & CTRL_MDC)));
2753	if ((CTRL & CTRL_MDIO_DIR) == 0 && (CTRL & CTRL_MDC))
2754	{
2755	/* MDC is high and MDIO pin is used for input, read MDIO pin from PHY */
2756	if (Phy::readMDIO(&pThis->phy))
2757	*pu32Value = CTRL \| CTRL_MDIO;
2758	else
2759	*pu32Value = CTRL & ~CTRL_MDIO;
2760	E1kLog(("%s e1kRegReadCTRL: Phy::readMDIO(%d)\n",
2761	pThis->szPrf, !!(*pu32Value & CTRL_MDIO)));
2762	}
2763	else
2764	{
2765	/* MDIO pin is used for output, ignore it */
2766	*pu32Value = CTRL;
2767	}
2768	return VINF_SUCCESS;
2769	}
2770	#endif /* unused */
2771
2772	/**
2773	* A callback used by PHY to indicate that the link needs to be updated due to
2774	* reset of PHY.
2775	*
2776	* @param pDevIns The device instance.
2777	* @thread any
2778	*/
2779	void e1kPhyLinkResetCallback(PPDMDEVINS pDevIns)
2780	{
2781	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
2782
2783	/* Make sure we have cable connected and MAC can talk to PHY */
2784	if (pThis->fCableConnected && (CTRL & CTRL_SLU))
2785	e1kArmTimer(pDevIns, pThis, pThis->hLUTimer, E1K_INIT_LINKUP_DELAY_US);
2786	}
2787
2788	/**
2789	* Write handler for Device Control register.
2790	*
2791	* Handles reset.
2792	*
2793	* @param pThis The device state structure.
2794	* @param offset Register offset in memory-mapped frame.
2795	* @param index Register index in register array.
2796	* @param value The value to store.
2797	* @param mask Used to implement partial writes (8 and 16-bit).
2798	* @thread EMT
2799	*/
2800	static int e1kRegWriteCTRL(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
2801	{
2802	int rc = VINF_SUCCESS;
2803
2804	if (value & CTRL_RESET)
2805	{ /* RST */
2806	#ifndef IN_RING3
2807	return VINF_IOM_R3_MMIO_WRITE;
2808	#else
2809	e1kR3HardReset(pDevIns, pThis, PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC));
2810	#endif
2811	}
2812	else
2813	{
2814	#ifdef E1K_LSC_ON_SLU
2815	/*
2816	* When the guest changes 'Set Link Up' bit from 0 to 1 we check if
2817	* the link is down and the cable is connected, and if they are we
2818	* bring the link up, see @bugref{8624}.
2819	*/
2820	if ( (value & CTRL_SLU)
2821	&& !(CTRL & CTRL_SLU)
2822	&& pThis->fCableConnected
2823	&& !(STATUS & STATUS_LU))
2824	{
2825	/* It should take about 2 seconds for the link to come up */
2826	e1kArmTimer(pDevIns, pThis, pThis->hLUTimer, E1K_INIT_LINKUP_DELAY_US);
2827	}
2828	#else /* !E1K_LSC_ON_SLU */
2829	if ( (value & CTRL_SLU)
2830	&& !(CTRL & CTRL_SLU)
2831	&& pThis->fCableConnected
2832	&& !PDMDevHlpTimerIsActive(pDevIns, pThis->hLUTimer))
2833	{
2834	/* PXE does not use LSC interrupts, see @bugref{9113}. */
2835	STATUS \|= STATUS_LU;
2836	}
2837	#endif /* !E1K_LSC_ON_SLU */
2838	if ((value & CTRL_VME) != (CTRL & CTRL_VME))
2839	{
2840	E1kLog(("%s VLAN Mode %s\n", pThis->szPrf, (value & CTRL_VME) ? "Enabled" : "Disabled"));
2841	}
2842	Log7(("%s e1kRegWriteCTRL: mdio dir=%s mdc dir=%s mdc=%s mdio=%d\n",
2843	pThis->szPrf, (value & CTRL_MDIO_DIR)?"OUT":"IN ",
2844	(value & CTRL_MDC_DIR)?"OUT":"IN ", (value & CTRL_MDC)?"HIGH":"LOW ", !!(value & CTRL_MDIO)));
2845	if (value & CTRL_MDC)
2846	{
2847	if (value & CTRL_MDIO_DIR)
2848	{
2849	Log7(("%s e1kRegWriteCTRL: Phy::writeMDIO(%d)\n", pThis->szPrf, !!(value & CTRL_MDIO)));
2850	/* MDIO direction pin is set to output and MDC is high, write MDIO pin value to PHY */
2851	Phy::writeMDIO(&pThis->phy, !!(value & CTRL_MDIO), pDevIns);
2852	}
2853	else
2854	{
2855	if (Phy::readMDIO(&pThis->phy))
2856	value \|= CTRL_MDIO;
2857	else
2858	value &= ~CTRL_MDIO;
2859	Log7(("%s e1kRegWriteCTRL: Phy::readMDIO(%d)\n", pThis->szPrf, !!(value & CTRL_MDIO)));
2860	}
2861	}
2862	rc = e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
2863	}
2864
2865	return rc;
2866	}
2867
2868	/**
2869	* Write handler for EEPROM/Flash Control/Data register.
2870	*
2871	* Handles EEPROM access requests; forwards writes to EEPROM device if access has been granted.
2872	*
2873	* @param pThis The device state structure.
2874	* @param offset Register offset in memory-mapped frame.
2875	* @param index Register index in register array.
2876	* @param value The value to store.
2877	* @param mask Used to implement partial writes (8 and 16-bit).
2878	* @thread EMT
2879	*/
2880	static int e1kRegWriteEECD(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
2881	{
2882	RT_NOREF(pDevIns, offset, index);
2883	#ifdef IN_RING3
2884	/* So far we are concerned with lower byte only */
2885	if ((EECD & EECD_EE_GNT) \|\| pThis->eChip == E1K_CHIP_82543GC)
2886	{
2887	/* Access to EEPROM granted -- forward 4-wire bits to EEPROM device */
2888	/* Note: 82543GC does not need to request EEPROM access */
2889	STAM_PROFILE_ADV_START(&pThis->StatEEPROMWrite, a);
2890	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
2891	pThisCC->eeprom.write(value & EECD_EE_WIRES);
2892	STAM_PROFILE_ADV_STOP(&pThis->StatEEPROMWrite, a);
2893	}
2894	if (value & EECD_EE_REQ)
2895	EECD \|= EECD_EE_REQ\|EECD_EE_GNT;
2896	else
2897	EECD &= ~EECD_EE_GNT;
2898	//e1kRegWriteDefault(pThis, offset, index, value );
2899
2900	return VINF_SUCCESS;
2901	#else /* !IN_RING3 */
2902	RT_NOREF(pThis, value);
2903	return VINF_IOM_R3_MMIO_WRITE;
2904	#endif /* !IN_RING3 */
2905	}
2906
2907	/**
2908	* Read handler for EEPROM/Flash Control/Data register.
2909	*
2910	* Lower 4 bits come from EEPROM device if EEPROM access has been granted.
2911	*
2912	* @returns VBox status code.
2913	*
2914	* @param pThis The device state structure.
2915	* @param offset Register offset in memory-mapped frame.
2916	* @param index Register index in register array.
2917	* @param mask Used to implement partial reads (8 and 16-bit).
2918	* @thread EMT
2919	*/
2920	static int e1kRegReadEECD(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
2921	{
2922	#ifdef IN_RING3
2923	uint32_t value = 0; /* Get rid of false positive in parfait. */
2924	int rc = e1kRegReadDefault(pDevIns, pThis, offset, index, &value);
2925	if (RT_SUCCESS(rc))
2926	{
2927	if ((value & EECD_EE_GNT) \|\| pThis->eChip == E1K_CHIP_82543GC)
2928	{
2929	/* Note: 82543GC does not need to request EEPROM access */
2930	/* Access to EEPROM granted -- get 4-wire bits to EEPROM device */
2931	STAM_PROFILE_ADV_START(&pThis->StatEEPROMRead, a);
2932	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
2933	value \|= pThisCC->eeprom.read();
2934	STAM_PROFILE_ADV_STOP(&pThis->StatEEPROMRead, a);
2935	}
2936	*pu32Value = value;
2937	}
2938
2939	return rc;
2940	#else /* !IN_RING3 */
2941	RT_NOREF_PV(pDevIns); RT_NOREF_PV(pThis); RT_NOREF_PV(offset); RT_NOREF_PV(index); RT_NOREF_PV(pu32Value);
2942	return VINF_IOM_R3_MMIO_READ;
2943	#endif /* !IN_RING3 */
2944	}
2945
2946	/**
2947	* Write handler for EEPROM Read register.
2948	*
2949	* Handles EEPROM word access requests, reads EEPROM and stores the result
2950	* into DATA field.
2951	*
2952	* @param pThis The device state structure.
2953	* @param offset Register offset in memory-mapped frame.
2954	* @param index Register index in register array.
2955	* @param value The value to store.
2956	* @param mask Used to implement partial writes (8 and 16-bit).
2957	* @thread EMT
2958	*/
2959	static int e1kRegWriteEERD(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
2960	{
2961	#ifdef IN_RING3
2962	/* Make use of 'writable' and 'readable' masks. */
2963	e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
2964	/* DONE and DATA are set only if read was triggered by START. */
2965	if (value & EERD_START)
2966	{
2967	STAM_PROFILE_ADV_START(&pThis->StatEEPROMRead, a);
2968	uint16_t tmp;
2969	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
2970	if (pThisCC->eeprom.readWord(GET_BITS_V(value, EERD, ADDR), &tmp))
2971	SET_BITS(EERD, DATA, tmp);
2972	EERD \|= EERD_DONE;
2973	STAM_PROFILE_ADV_STOP(&pThis->StatEEPROMRead, a);
2974	}
2975
2976	return VINF_SUCCESS;
2977	#else /* !IN_RING3 */
2978	RT_NOREF_PV(pDevIns); RT_NOREF_PV(pThis); RT_NOREF_PV(offset); RT_NOREF_PV(index); RT_NOREF_PV(value);
2979	return VINF_IOM_R3_MMIO_WRITE;
2980	#endif /* !IN_RING3 */
2981	}
2982
2983
2984	/**
2985	* Write handler for MDI Control register.
2986	*
2987	* Handles PHY read/write requests; forwards requests to internal PHY device.
2988	*
2989	* @param pThis The device state structure.
2990	* @param offset Register offset in memory-mapped frame.
2991	* @param index Register index in register array.
2992	* @param value The value to store.
2993	* @param mask Used to implement partial writes (8 and 16-bit).
2994	* @thread EMT
2995	*/
2996	static int e1kRegWriteMDIC(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
2997	{
2998	if (value & MDIC_INT_EN)
2999	{
3000	E1kLog(("%s ERROR! Interrupt at the end of an MDI cycle is not supported yet.\n",
3001	pThis->szPrf));
3002	}
3003	else if (value & MDIC_READY)
3004	{
3005	E1kLog(("%s ERROR! Ready bit is not reset by software during write operation.\n",
3006	pThis->szPrf));
3007	}
3008	else if (GET_BITS_V(value, MDIC, PHY) != 1)
3009	{
3010	E1kLog(("%s WARNING! Access to invalid PHY detected, phy=%d.\n",
3011	pThis->szPrf, GET_BITS_V(value, MDIC, PHY)));
3012	/*
3013	* Some drivers scan the MDIO bus for a PHY. We can work with these
3014	* drivers if we set MDIC_READY and MDIC_ERROR when there isn't a PHY
3015	* at the requested address, see @bugref{7346}.
3016	*/
3017	MDIC = MDIC_READY \| MDIC_ERROR;
3018	}
3019	else
3020	{
3021	/* Store the value */
3022	e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
3023	STAM_COUNTER_INC(&pThis->StatPHYAccesses);
3024	/* Forward op to PHY */
3025	if (value & MDIC_OP_READ)
3026	SET_BITS(MDIC, DATA, Phy::readRegister(&pThis->phy, GET_BITS_V(value, MDIC, REG), pDevIns));
3027	else
3028	Phy::writeRegister(&pThis->phy, GET_BITS_V(value, MDIC, REG), value & MDIC_DATA_MASK, pDevIns);
3029	/* Let software know that we are done */
3030	MDIC \|= MDIC_READY;
3031	}
3032
3033	return VINF_SUCCESS;
3034	}
3035
3036	/**
3037	* Write handler for Interrupt Cause Read register.
3038	*
3039	* Bits corresponding to 1s in 'value' will be cleared in ICR register.
3040	*
3041	* @param pThis The device state structure.
3042	* @param offset Register offset in memory-mapped frame.
3043	* @param index Register index in register array.
3044	* @param value The value to store.
3045	* @param mask Used to implement partial writes (8 and 16-bit).
3046	* @thread EMT
3047	*/
3048	static int e1kRegWriteICR(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3049	{
3050	ICR &= ~value;
3051
3052	RT_NOREF_PV(pDevIns); RT_NOREF_PV(pThis); RT_NOREF_PV(offset); RT_NOREF_PV(index);
3053	return VINF_SUCCESS;
3054	}
3055
3056	/**
3057	* Read handler for Interrupt Cause Read register.
3058	*
3059	* Reading this register acknowledges all interrupts.
3060	*
3061	* @returns VBox status code.
3062	*
3063	* @param pThis The device state structure.
3064	* @param offset Register offset in memory-mapped frame.
3065	* @param index Register index in register array.
3066	* @param mask Not used.
3067	* @thread EMT
3068	*/
3069	static int e1kRegReadICR(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
3070	{
3071	int rc = e1kCsEnter(pThis, VINF_IOM_R3_MMIO_READ);
3072	if (RT_UNLIKELY(rc != VINF_SUCCESS))
3073	return rc;
3074
3075	uint32_t value = 0;
3076	rc = e1kRegReadDefault(pDevIns, pThis, offset, index, &value);
3077	if (RT_SUCCESS(rc))
3078	{
3079	if (value)
3080	{
3081	if (!pThis->fIntRaised)
3082	E1K_INC_ISTAT_CNT(pThis->uStatNoIntICR);
3083	/*
3084	* Not clearing ICR causes QNX to hang as it reads ICR in a loop
3085	* with disabled interrupts.
3086	*/
3087	//if (IMS)
3088	if (1)
3089	{
3090	/*
3091	* Interrupts were enabled -- we are supposedly at the very
3092	* beginning of interrupt handler
3093	*/
3094	E1kLogRel(("E1000: irq lowered, icr=0x%x\n", ICR));
3095	E1kLog(("%s e1kRegReadICR: Lowered IRQ (%08x)\n", pThis->szPrf, ICR));
3096	/* Clear all pending interrupts */
3097	ICR = 0;
3098	pThis->fIntRaised = false;
3099	/* Lower(0) INTA(0) */
3100	PDMDevHlpPCISetIrq(pDevIns, 0, 0);
3101
3102	pThis->u64AckedAt = PDMDevHlpTimerGet(pDevIns, pThis->hIntTimer);
3103	if (pThis->fIntMaskUsed)
3104	pThis->fDelayInts = true;
3105	}
3106	else
3107	{
3108	/*
3109	* Interrupts are disabled -- in windows guests ICR read is done
3110	* just before re-enabling interrupts
3111	*/
3112	E1kLog(("%s e1kRegReadICR: Suppressing auto-clear due to disabled interrupts (%08x)\n", pThis->szPrf, ICR));
3113	}
3114	}
3115	*pu32Value = value;
3116	}
3117	e1kCsLeave(pThis);
3118
3119	return rc;
3120	}
3121
3122	/**
3123	* Write handler for Interrupt Cause Set register.
3124	*
3125	* Bits corresponding to 1s in 'value' will be set in ICR register.
3126	*
3127	* @param pThis The device state structure.
3128	* @param offset Register offset in memory-mapped frame.
3129	* @param index Register index in register array.
3130	* @param value The value to store.
3131	* @param mask Used to implement partial writes (8 and 16-bit).
3132	* @thread EMT
3133	*/
3134	static int e1kRegWriteICS(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3135	{
3136	RT_NOREF_PV(offset); RT_NOREF_PV(index);
3137	E1K_INC_ISTAT_CNT(pThis->uStatIntICS);
3138	return e1kRaiseInterrupt(pDevIns, pThis, VINF_IOM_R3_MMIO_WRITE, value & g_aE1kRegMap[ICS_IDX].writable);
3139	}
3140
3141	/**
3142	* Write handler for Interrupt Mask Set register.
3143	*
3144	* Will trigger pending interrupts.
3145	*
3146	* @param pThis The device state structure.
3147	* @param offset Register offset in memory-mapped frame.
3148	* @param index Register index in register array.
3149	* @param value The value to store.
3150	* @param mask Used to implement partial writes (8 and 16-bit).
3151	* @thread EMT
3152	*/
3153	static int e1kRegWriteIMS(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3154	{
3155	RT_NOREF_PV(offset); RT_NOREF_PV(index);
3156
3157	IMS \|= value;
3158	E1kLogRel(("E1000: irq enabled, RDH=%x RDT=%x TDH=%x TDT=%x\n", RDH, RDT, TDH, TDT));
3159	E1kLog(("%s e1kRegWriteIMS: IRQ enabled\n", pThis->szPrf));
3160	/*
3161	* We cannot raise an interrupt here as it will occasionally cause an interrupt storm
3162	* in Windows guests (see @bugref{8624}, @bugref{5023}).
3163	*/
3164	if ((ICR & IMS) && !pThis->fLocked)
3165	{
3166	E1K_INC_ISTAT_CNT(pThis->uStatIntIMS);
3167	e1kPostponeInterrupt(pDevIns, pThis, E1K_IMS_INT_DELAY_NS);
3168	}
3169
3170	return VINF_SUCCESS;
3171	}
3172
3173	/**
3174	* Write handler for Interrupt Mask Clear register.
3175	*
3176	* Bits corresponding to 1s in 'value' will be cleared in IMS register.
3177	*
3178	* @param pThis The device state structure.
3179	* @param offset Register offset in memory-mapped frame.
3180	* @param index Register index in register array.
3181	* @param value The value to store.
3182	* @param mask Used to implement partial writes (8 and 16-bit).
3183	* @thread EMT
3184	*/
3185	static int e1kRegWriteIMC(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3186	{
3187	RT_NOREF_PV(offset); RT_NOREF_PV(index);
3188
3189	int rc = e1kCsEnter(pThis, VINF_IOM_R3_MMIO_WRITE);
3190	if (RT_UNLIKELY(rc != VINF_SUCCESS))
3191	return rc;
3192	if (pThis->fIntRaised)
3193	{
3194	/*
3195	* Technically we should reset fIntRaised in ICR read handler, but it will cause
3196	* Windows to freeze since it may receive an interrupt while still in the very beginning
3197	* of interrupt handler.
3198	*/
3199	E1K_INC_ISTAT_CNT(pThis->uStatIntLower);
3200	STAM_COUNTER_INC(&pThis->StatIntsPrevented);
3201	E1kLogRel(("E1000: irq lowered (IMC), icr=0x%x\n", ICR));
3202	/* Lower(0) INTA(0) */
3203	PDMDevHlpPCISetIrq(pDevIns, 0, 0);
3204	pThis->fIntRaised = false;
3205	E1kLog(("%s e1kRegWriteIMC: Lowered IRQ: ICR=%08x\n", pThis->szPrf, ICR));
3206	}
3207	IMS &= ~value;
3208	E1kLog(("%s e1kRegWriteIMC: IRQ disabled\n", pThis->szPrf));
3209	e1kCsLeave(pThis);
3210
3211	return VINF_SUCCESS;
3212	}
3213
3214	/**
3215	* Write handler for Receive Control register.
3216	*
3217	* @param pThis The device state structure.
3218	* @param offset Register offset in memory-mapped frame.
3219	* @param index Register index in register array.
3220	* @param value The value to store.
3221	* @param mask Used to implement partial writes (8 and 16-bit).
3222	* @thread EMT
3223	*/
3224	static int e1kRegWriteRCTL(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3225	{
3226	/* Update promiscuous mode */
3227	bool fBecomePromiscous = !!(value & (RCTL_UPE \| RCTL_MPE));
3228	if (fBecomePromiscous != !!( RCTL & (RCTL_UPE \| RCTL_MPE)))
3229	{
3230	/* Promiscuity has changed, pass the knowledge on. */
3231	#ifndef IN_RING3
3232	return VINF_IOM_R3_MMIO_WRITE;
3233	#else
3234	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
3235	if (pThisCC->pDrvR3)
3236	pThisCC->pDrvR3->pfnSetPromiscuousMode(pThisCC->pDrvR3, fBecomePromiscous);
3237	#endif
3238	}
3239
3240	/* Adjust receive buffer size */
3241	unsigned cbRxBuf = 2048 >> GET_BITS_V(value, RCTL, BSIZE);
3242	if (value & RCTL_BSEX)
3243	cbRxBuf *= 16;
3244	if (cbRxBuf > E1K_MAX_RX_PKT_SIZE)
3245	cbRxBuf = E1K_MAX_RX_PKT_SIZE;
3246	if (cbRxBuf != pThis->u16RxBSize)
3247	E1kLog2(("%s e1kRegWriteRCTL: Setting receive buffer size to %d (old %d)\n",
3248	pThis->szPrf, cbRxBuf, pThis->u16RxBSize));
3249	Assert(cbRxBuf < 65536);
3250	pThis->u16RxBSize = (uint16_t)cbRxBuf;
3251
3252	/* Update the register */
3253	return e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
3254	}
3255
3256	/**
3257	* Write handler for Packet Buffer Allocation register.
3258	*
3259	* TXA = 64 - RXA.
3260	*
3261	* @param pThis The device state structure.
3262	* @param offset Register offset in memory-mapped frame.
3263	* @param index Register index in register array.
3264	* @param value The value to store.
3265	* @param mask Used to implement partial writes (8 and 16-bit).
3266	* @thread EMT
3267	*/
3268	static int e1kRegWritePBA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3269	{
3270	e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
3271	PBA_st->txa = 64 - PBA_st->rxa;
3272
3273	return VINF_SUCCESS;
3274	}
3275
3276	/**
3277	* Write handler for Receive Descriptor Tail register.
3278	*
3279	* @remarks Write into RDT forces switch to HC and signal to
3280	* e1kR3NetworkDown_WaitReceiveAvail().
3281	*
3282	* @returns VBox status code.
3283	*
3284	* @param pThis The device state structure.
3285	* @param offset Register offset in memory-mapped frame.
3286	* @param index Register index in register array.
3287	* @param value The value to store.
3288	* @param mask Used to implement partial writes (8 and 16-bit).
3289	* @thread EMT
3290	*/
3291	static int e1kRegWriteRDT(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3292	{
3293	#ifndef IN_RING3
3294	/* XXX */
3295	// return VINF_IOM_R3_MMIO_WRITE;
3296	#endif
3297	int rc = e1kCsRxEnter(pThis, VINF_IOM_R3_MMIO_WRITE);
3298	if (RT_LIKELY(rc == VINF_SUCCESS))
3299	{
3300	E1kLog(("%s e1kRegWriteRDT\n", pThis->szPrf));
3301	#ifndef E1K_WITH_RXD_CACHE
3302	/*
3303	* Some drivers advance RDT too far, so that it equals RDH. This
3304	* somehow manages to work with real hardware but not with this
3305	* emulated device. We can work with these drivers if we just
3306	* write 1 less when we see a driver writing RDT equal to RDH,
3307	* see @bugref{7346}.
3308	*/
3309	if (value == RDH)
3310	{
3311	if (RDH == 0)
3312	value = (RDLEN / sizeof(E1KRXDESC)) - 1;
3313	else
3314	value = RDH - 1;
3315	}
3316	#endif /* !E1K_WITH_RXD_CACHE */
3317	rc = e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
3318	#ifdef E1K_WITH_RXD_CACHE
3319	/*
3320	* We need to fetch descriptors now as RDT may go whole circle
3321	* before we attempt to store a received packet. For example,
3322	* Intel's DOS drivers use 2 (!) RX descriptors with the total ring
3323	* size being only 8 descriptors! Note that we fetch descriptors
3324	* only when the cache is empty to reduce the number of memory reads
3325	* in case of frequent RDT writes. Don't fetch anything when the
3326	* receiver is disabled either as RDH, RDT, RDLEN can be in some
3327	* messed up state.
3328	* Note that despite the cache may seem empty, meaning that there are
3329	* no more available descriptors in it, it may still be used by RX
3330	* thread which has not yet written the last descriptor back but has
3331	* temporarily released the RX lock in order to write the packet body
3332	* to descriptor's buffer. At this point we still going to do prefetch
3333	* but it won't actually fetch anything if there are no unused slots in
3334	* our "empty" cache (nRxDFetched==E1K_RXD_CACHE_SIZE). We must not
3335	* reset the cache here even if it appears empty. It will be reset at
3336	* a later point in e1kRxDGet().
3337	*/
3338	if (e1kRxDIsCacheEmpty(pThis) && (RCTL & RCTL_EN))
3339	e1kRxDPrefetch(pDevIns, pThis);
3340	#endif /* E1K_WITH_RXD_CACHE */
3341	e1kCsRxLeave(pThis);
3342	if (RT_SUCCESS(rc))
3343	{
3344	/* Signal that we have more receive descriptors available. */
3345	e1kWakeupReceive(pDevIns, pThis);
3346	}
3347	}
3348	return rc;
3349	}
3350
3351	/**
3352	* Write handler for Receive Delay Timer register.
3353	*
3354	* @param pThis The device state structure.
3355	* @param offset Register offset in memory-mapped frame.
3356	* @param index Register index in register array.
3357	* @param value The value to store.
3358	* @param mask Used to implement partial writes (8 and 16-bit).
3359	* @thread EMT
3360	*/
3361	static int e1kRegWriteRDTR(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
3362	{
3363	e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
3364	if (value & RDTR_FPD)
3365	{
3366	/* Flush requested, cancel both timers and raise interrupt */
3367	#ifdef E1K_USE_RX_TIMERS
3368	e1kCancelTimer(pDevIns, pThis, pThis->hRIDTimer);
3369	e1kCancelTimer(pDevIns, pThis, pThis->hRADTimer);
3370	#endif
3371	E1K_INC_ISTAT_CNT(pThis->uStatIntRDTR);
3372	return e1kRaiseInterrupt(pDevIns, pThis, VINF_IOM_R3_MMIO_WRITE, ICR_RXT0);
3373	}
3374
3375	return VINF_SUCCESS;
3376	}
3377
3378	DECLINLINE(uint32_t) e1kGetTxLen(PE1KSTATE pThis)
3379	{
3380	/**
3381	* Make sure TDT won't change during computation. EMT may modify TDT at
3382	* any moment.
3383	*/
3384	uint32_t tdt = TDT;
3385	return (TDH>tdt ? TDLEN/sizeof(E1KTXDESC) : 0) + tdt - TDH;
3386	}
3387
3388	#ifdef IN_RING3
3389
3390	# ifdef E1K_TX_DELAY
3391	/**
3392	* Transmit Delay Timer handler.
3393	*
3394	* @remarks We only get here when the timer expires.
3395	*
3396	* @param pDevIns Pointer to device instance structure.
3397	* @param pTimer Pointer to the timer.
3398	* @param pvUser NULL.
3399	* @thread EMT
3400	*/
3401	static DECLCALLBACK(void) e1kR3TxDelayTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3402	{
3403	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3404	Assert(PDMCritSectIsOwner(&pThis->csTx));
3405
3406	E1K_INC_ISTAT_CNT(pThis->uStatTxDelayExp);
3407	# ifdef E1K_INT_STATS
3408	uint64_t u64Elapsed = RTTimeNanoTS() - pThis->u64ArmedAt;
3409	if (u64Elapsed > pThis->uStatMaxTxDelay)
3410	pThis->uStatMaxTxDelay = u64Elapsed;
3411	# endif
3412	int rc = e1kXmitPending(pDevIns, pThis, false /fOnWorkerThread/);
3413	AssertMsg(RT_SUCCESS(rc) \|\| rc == VERR_TRY_AGAIN, ("%Rrc\n", rc));
3414	}
3415	# endif /* E1K_TX_DELAY */
3416
3417	//# ifdef E1K_USE_TX_TIMERS
3418
3419	/**
3420	* Transmit Interrupt Delay Timer handler.
3421	*
3422	* @remarks We only get here when the timer expires.
3423	*
3424	* @param pDevIns Pointer to device instance structure.
3425	* @param pTimer Pointer to the timer.
3426	* @param pvUser NULL.
3427	* @thread EMT
3428	*/
3429	static DECLCALLBACK(void) e1kR3TxIntDelayTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3430	{
3431	RT_NOREF(pDevIns);
3432	RT_NOREF(pTimer);
3433	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3434
3435	E1K_INC_ISTAT_CNT(pThis->uStatTID);
3436	/* Cancel absolute delay timer as we have already got attention */
3437	# ifndef E1K_NO_TAD
3438	e1kCancelTimer(pDevIns, pThis, pThis->hTADTimer);
3439	# endif
3440	e1kRaiseInterrupt(pDevIns, pThis, ICR_TXDW);
3441	}
3442
3443	/**
3444	* Transmit Absolute Delay Timer handler.
3445	*
3446	* @remarks We only get here when the timer expires.
3447	*
3448	* @param pDevIns Pointer to device instance structure.
3449	* @param pTimer Pointer to the timer.
3450	* @param pvUser NULL.
3451	* @thread EMT
3452	*/
3453	static DECLCALLBACK(void) e1kR3TxAbsDelayTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3454	{
3455	RT_NOREF(pDevIns);
3456	RT_NOREF(pTimer);
3457	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3458
3459	E1K_INC_ISTAT_CNT(pThis->uStatTAD);
3460	/* Cancel interrupt delay timer as we have already got attention */
3461	e1kCancelTimer(pDevIns, pThis, pThis->hTIDTimer);
3462	e1kRaiseInterrupt(pDevIns, pThis, ICR_TXDW);
3463	}
3464
3465	//# endif /* E1K_USE_TX_TIMERS */
3466	# ifdef E1K_USE_RX_TIMERS
3467
3468	/**
3469	* Receive Interrupt Delay Timer handler.
3470	*
3471	* @remarks We only get here when the timer expires.
3472	*
3473	* @param pDevIns Pointer to device instance structure.
3474	* @param pTimer Pointer to the timer.
3475	* @param pvUser NULL.
3476	* @thread EMT
3477	*/
3478	static DECLCALLBACK(void) e1kR3RxIntDelayTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3479	{
3480	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3481
3482	E1K_INC_ISTAT_CNT(pThis->uStatRID);
3483	/* Cancel absolute delay timer as we have already got attention */
3484	e1kCancelTimer(pDevIns, pThis, pThis->hRADTimer);
3485	e1kRaiseInterrupt(pDevIns, pThis, ICR_RXT0);
3486	}
3487
3488	/**
3489	* Receive Absolute Delay Timer handler.
3490	*
3491	* @remarks We only get here when the timer expires.
3492	*
3493	* @param pDevIns Pointer to device instance structure.
3494	* @param pTimer Pointer to the timer.
3495	* @param pvUser NULL.
3496	* @thread EMT
3497	*/
3498	static DECLCALLBACK(void) e1kR3RxAbsDelayTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3499	{
3500	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3501
3502	E1K_INC_ISTAT_CNT(pThis->uStatRAD);
3503	/* Cancel interrupt delay timer as we have already got attention */
3504	e1kCancelTimer(pDevIns, pThis, pThis->hRIDTimer);
3505	e1kRaiseInterrupt(pDevIns, pThis, ICR_RXT0);
3506	}
3507
3508	# endif /* E1K_USE_RX_TIMERS */
3509
3510	/**
3511	* Late Interrupt Timer handler.
3512	*
3513	* @param pDevIns Pointer to device instance structure.
3514	* @param pTimer Pointer to the timer.
3515	* @param pvUser NULL.
3516	* @thread EMT
3517	*/
3518	static DECLCALLBACK(void) e1kR3LateIntTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3519	{
3520	RT_NOREF(pDevIns, pTimer);
3521	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3522
3523	STAM_PROFILE_ADV_START(&pThis->StatLateIntTimer, a);
3524	STAM_COUNTER_INC(&pThis->StatLateInts);
3525	E1K_INC_ISTAT_CNT(pThis->uStatIntLate);
3526	# if 0
3527	if (pThis->iStatIntLost > -100)
3528	pThis->iStatIntLost--;
3529	# endif
3530	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, 0);
3531	STAM_PROFILE_ADV_STOP(&pThis->StatLateIntTimer, a);
3532	}
3533
3534	/**
3535	* Link Up Timer handler.
3536	*
3537	* @param pDevIns Pointer to device instance structure.
3538	* @param pTimer Pointer to the timer.
3539	* @param pvUser NULL.
3540	* @thread EMT
3541	*/
3542	static DECLCALLBACK(void) e1kR3LinkUpTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser)
3543	{
3544	RT_NOREF(pTimer);
3545	PE1KSTATE pThis = (PE1KSTATE)pvUser;
3546	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
3547
3548	/*
3549	* This can happen if we set the link status to down when the Link up timer was
3550	* already armed (shortly after e1kLoadDone() or when the cable was disconnected
3551	* and connect+disconnect the cable very quick. Moreover, 82543GC triggers LSC
3552	* on reset even if the cable is unplugged (see @bugref{8942}).
3553	*/
3554	if (pThis->fCableConnected)
3555	{
3556	/* 82543GC does not have an internal PHY */
3557	if (pThis->eChip == E1K_CHIP_82543GC \|\| (CTRL & CTRL_SLU))
3558	e1kR3LinkUp(pDevIns, pThis, pThisCC);
3559	}
3560	# ifdef E1K_LSC_ON_RESET
3561	else if (pThis->eChip == E1K_CHIP_82543GC)
3562	e1kR3LinkDown(pDevIns, pThis, pThisCC);
3563	# endif /* E1K_LSC_ON_RESET */
3564	}
3565
3566	#endif /* IN_RING3 */
3567
3568	/**
3569	* Sets up the GSO context according to the TSE new context descriptor.
3570	*
3571	* @param pGso The GSO context to setup.
3572	* @param pCtx The context descriptor.
3573	*/
3574	DECLINLINE(void) e1kSetupGsoCtx(PPDMNETWORKGSO pGso, E1KTXCTX const *pCtx)
3575	{
3576	pGso->u8Type = PDMNETWORKGSOTYPE_INVALID;
3577
3578	/*
3579	* See if the context descriptor describes something that could be TCP or
3580	* UDP over IPv[46].
3581	*/
3582	/* Check the header ordering and spacing: 1. Ethernet, 2. IP, 3. TCP/UDP. */
3583	if (RT_UNLIKELY( pCtx->ip.u8CSS < sizeof(RTNETETHERHDR) ))
3584	{
3585	E1kLog(("e1kSetupGsoCtx: IPCSS=%#x\n", pCtx->ip.u8CSS));
3586	return;
3587	}
3588	if (RT_UNLIKELY( pCtx->tu.u8CSS < (size_t)pCtx->ip.u8CSS + (pCtx->dw2.fIP ? RTNETIPV4_MIN_LEN : RTNETIPV6_MIN_LEN) ))
3589	{
3590	E1kLog(("e1kSetupGsoCtx: TUCSS=%#x\n", pCtx->tu.u8CSS));
3591	return;
3592	}
3593	if (RT_UNLIKELY( pCtx->dw2.fTCP
3594	? pCtx->dw3.u8HDRLEN < (size_t)pCtx->tu.u8CSS + RTNETTCP_MIN_LEN
3595	: pCtx->dw3.u8HDRLEN != (size_t)pCtx->tu.u8CSS + RTNETUDP_MIN_LEN ))
3596	{
3597	E1kLog(("e1kSetupGsoCtx: HDRLEN=%#x TCP=%d\n", pCtx->dw3.u8HDRLEN, pCtx->dw2.fTCP));
3598	return;
3599	}
3600
3601	/* The end of the TCP/UDP checksum should stop at the end of the packet or at least after the headers. */
3602	if (RT_UNLIKELY( pCtx->tu.u16CSE > 0 && pCtx->tu.u16CSE <= pCtx->dw3.u8HDRLEN ))
3603	{
3604	E1kLog(("e1kSetupGsoCtx: TUCSE=%#x HDRLEN=%#x\n", pCtx->tu.u16CSE, pCtx->dw3.u8HDRLEN));
3605	return;
3606	}
3607
3608	/* IPv4 checksum offset. */
3609	if (RT_UNLIKELY( pCtx->dw2.fIP && (size_t)pCtx->ip.u8CSO - pCtx->ip.u8CSS != RT_UOFFSETOF(RTNETIPV4, ip_sum) ))
3610	{
3611	E1kLog(("e1kSetupGsoCtx: IPCSO=%#x IPCSS=%#x\n", pCtx->ip.u8CSO, pCtx->ip.u8CSS));
3612	return;
3613	}
3614
3615	/* TCP/UDP checksum offsets. */
3616	if (RT_UNLIKELY( (size_t)pCtx->tu.u8CSO - pCtx->tu.u8CSS
3617	!= ( pCtx->dw2.fTCP
3618	? RT_UOFFSETOF(RTNETTCP, th_sum)
3619	: RT_UOFFSETOF(RTNETUDP, uh_sum) ) ))
3620	{
3621	E1kLog(("e1kSetupGsoCtx: TUCSO=%#x TUCSS=%#x TCP=%d\n", pCtx->ip.u8CSO, pCtx->ip.u8CSS, pCtx->dw2.fTCP));
3622	return;
3623	}
3624
3625	/*
3626	* Because of internal networking using a 16-bit size field for GSO context
3627	* plus frame, we have to make sure we don't exceed this.
3628	*/
3629	if (RT_UNLIKELY( pCtx->dw3.u8HDRLEN + pCtx->dw2.u20PAYLEN > VBOX_MAX_GSO_SIZE ))
3630	{
3631	E1kLog(("e1kSetupGsoCtx: HDRLEN(=%#x) + PAYLEN(=%#x) = %#x, max is %#x\n",
3632	pCtx->dw3.u8HDRLEN, pCtx->dw2.u20PAYLEN, pCtx->dw3.u8HDRLEN + pCtx->dw2.u20PAYLEN, VBOX_MAX_GSO_SIZE));
3633	return;
3634	}
3635
3636	/*
3637	* We're good for now - we'll do more checks when seeing the data.
3638	* So, figure the type of offloading and setup the context.
3639	*/
3640	if (pCtx->dw2.fIP)
3641	{
3642	if (pCtx->dw2.fTCP)
3643	{
3644	pGso->u8Type = PDMNETWORKGSOTYPE_IPV4_TCP;
3645	pGso->cbHdrsSeg = pCtx->dw3.u8HDRLEN;
3646	}
3647	else
3648	{
3649	pGso->u8Type = PDMNETWORKGSOTYPE_IPV4_UDP;
3650	pGso->cbHdrsSeg = pCtx->tu.u8CSS; /* IP header only */
3651	}
3652	/** @todo Detect IPv4-IPv6 tunneling (need test setup since linux doesn't do
3653	* this yet it seems)... */
3654	}
3655	else
3656	{
3657	pGso->cbHdrsSeg = pCtx->dw3.u8HDRLEN; /** @todo IPv6 UFO */
3658	if (pCtx->dw2.fTCP)
3659	pGso->u8Type = PDMNETWORKGSOTYPE_IPV6_TCP;
3660	else
3661	pGso->u8Type = PDMNETWORKGSOTYPE_IPV6_UDP;
3662	}
3663	pGso->offHdr1 = pCtx->ip.u8CSS;
3664	pGso->offHdr2 = pCtx->tu.u8CSS;
3665	pGso->cbHdrsTotal = pCtx->dw3.u8HDRLEN;
3666	pGso->cbMaxSeg = pCtx->dw3.u16MSS + (pGso->u8Type == PDMNETWORKGSOTYPE_IPV4_UDP ? pGso->offHdr2 : 0);
3667	Assert(PDMNetGsoIsValid(pGso, sizeof(pGso), pGso->cbMaxSeg 5));
3668	E1kLog2(("e1kSetupGsoCtx: mss=%#x hdr=%#x hdrseg=%#x hdr1=%#x hdr2=%#x %s\n",
3669	pGso->cbMaxSeg, pGso->cbHdrsTotal, pGso->cbHdrsSeg, pGso->offHdr1, pGso->offHdr2, PDMNetGsoTypeName((PDMNETWORKGSOTYPE)pGso->u8Type) ));
3670	}
3671
3672	/**
3673	* Checks if we can use GSO processing for the current TSE frame.
3674	*
3675	* @param pThis The device state structure.
3676	* @param pGso The GSO context.
3677	* @param pData The first data descriptor of the frame.
3678	* @param pCtx The TSO context descriptor.
3679	*/
3680	DECLINLINE(bool) e1kCanDoGso(PE1KSTATE pThis, PCPDMNETWORKGSO pGso, E1KTXDAT const pData, E1KTXCTX const pCtx)
3681	{
3682	if (!pData->cmd.fTSE)
3683	{
3684	E1kLog2(("e1kCanDoGso: !TSE\n"));
3685	return false;
3686	}
3687	if (pData->cmd.fVLE) /** @todo VLAN tagging. */
3688	{
3689	E1kLog(("e1kCanDoGso: VLE\n"));
3690	return false;
3691	}
3692	if (RT_UNLIKELY(!pThis->fGSOEnabled))
3693	{
3694	E1kLog3(("e1kCanDoGso: GSO disabled via CFGM\n"));
3695	return false;
3696	}
3697
3698	switch ((PDMNETWORKGSOTYPE)pGso->u8Type)
3699	{
3700	case PDMNETWORKGSOTYPE_IPV4_TCP:
3701	case PDMNETWORKGSOTYPE_IPV4_UDP:
3702	if (!pData->dw3.fIXSM)
3703	{
3704	E1kLog(("e1kCanDoGso: !IXSM (IPv4)\n"));
3705	return false;
3706	}
3707	if (!pData->dw3.fTXSM)
3708	{
3709	E1kLog(("e1kCanDoGso: !TXSM (IPv4)\n"));
3710	return false;
3711	}
3712	/** @todo what more check should we perform here? Ethernet frame type? */
3713	E1kLog2(("e1kCanDoGso: OK, IPv4\n"));
3714	return true;
3715
3716	case PDMNETWORKGSOTYPE_IPV6_TCP:
3717	case PDMNETWORKGSOTYPE_IPV6_UDP:
3718	if (pData->dw3.fIXSM && pCtx->ip.u8CSO)
3719	{
3720	E1kLog(("e1kCanDoGso: IXSM (IPv6)\n"));
3721	return false;
3722	}
3723	if (!pData->dw3.fTXSM)
3724	{
3725	E1kLog(("e1kCanDoGso: TXSM (IPv6)\n"));
3726	return false;
3727	}
3728	/** @todo what more check should we perform here? Ethernet frame type? */
3729	E1kLog2(("e1kCanDoGso: OK, IPv4\n"));
3730	return true;
3731
3732	default:
3733	Assert(pGso->u8Type == PDMNETWORKGSOTYPE_INVALID);
3734	E1kLog2(("e1kCanDoGso: e1kSetupGsoCtx failed\n"));
3735	return false;
3736	}
3737	}
3738
3739	/**
3740	* Frees the current xmit buffer.
3741	*
3742	* @param pThis The device state structure.
3743	*/
3744	static void e1kXmitFreeBuf(PE1KSTATE pThis, PE1KSTATECC pThisCC)
3745	{
3746	PPDMSCATTERGATHER pSg = pThisCC->CTX_SUFF(pTxSg);
3747	if (pSg)
3748	{
3749	pThisCC->CTX_SUFF(pTxSg) = NULL;
3750
3751	if (pSg->pvAllocator != pThis)
3752	{
3753	PPDMINETWORKUP pDrv = pThisCC->CTX_SUFF(pDrv);
3754	if (pDrv)
3755	pDrv->pfnFreeBuf(pDrv, pSg);
3756	}
3757	else
3758	{
3759	/* loopback */
3760	AssertCompileMemberSize(E1KSTATE, uTxFallback.Sg, 8 * sizeof(size_t));
3761	Assert(pSg->fFlags == (PDMSCATTERGATHER_FLAGS_MAGIC \| PDMSCATTERGATHER_FLAGS_OWNER_3));
3762	pSg->fFlags = 0;
3763	pSg->pvAllocator = NULL;
3764	}
3765	}
3766	}
3767
3768	#ifndef E1K_WITH_TXD_CACHE
3769	/**
3770	* Allocates an xmit buffer.
3771	*
3772	* @returns See PDMINETWORKUP::pfnAllocBuf.
3773	* @param pThis The device state structure.
3774	* @param cbMin The minimum frame size.
3775	* @param fExactSize Whether cbMin is exact or if we have to max it
3776	* out to the max MTU size.
3777	* @param fGso Whether this is a GSO frame or not.
3778	*/
3779	DECLINLINE(int) e1kXmitAllocBuf(PE1KSTATE pThis, PE1KSTATECC pThisCC, size_t cbMin, bool fExactSize, bool fGso)
3780	{
3781	/* Adjust cbMin if necessary. */
3782	if (!fExactSize)
3783	cbMin = RT_MAX(cbMin, E1K_MAX_TX_PKT_SIZE);
3784
3785	/* Deal with existing buffer (descriptor screw up, reset, etc). */
3786	if (RT_UNLIKELY(pThisCC->CTX_SUFF(pTxSg)))
3787	e1kXmitFreeBuf(pThis, pThisCC);
3788	Assert(pThisCC->CTX_SUFF(pTxSg) == NULL);
3789
3790	/*
3791	* Allocate the buffer.
3792	*/
3793	PPDMSCATTERGATHER pSg;
3794	if (RT_LIKELY(GET_BITS(RCTL, LBM) != RCTL_LBM_TCVR))
3795	{
3796	PPDMINETWORKUP pDrv = pThisCC->CTX_SUFF(pDrv);
3797	if (RT_UNLIKELY(!pDrv))
3798	return VERR_NET_DOWN;
3799	int rc = pDrv->pfnAllocBuf(pDrv, cbMin, fGso ? &pThis->GsoCtx : NULL, &pSg);
3800	if (RT_FAILURE(rc))
3801	{
3802	/* Suspend TX as we are out of buffers atm */
3803	STATUS \|= STATUS_TXOFF;
3804	return rc;
3805	}
3806	}
3807	else
3808	{
3809	/* Create a loopback using the fallback buffer and preallocated SG. */
3810	AssertCompileMemberSize(E1KSTATE, uTxFallback.Sg, 8 * sizeof(size_t));
3811	pSg = &pThis->uTxFallback.Sg;
3812	pSg->fFlags = PDMSCATTERGATHER_FLAGS_MAGIC \| PDMSCATTERGATHER_FLAGS_OWNER_3;
3813	pSg->cbUsed = 0;
3814	pSg->cbAvailable = 0;
3815	pSg->pvAllocator = pThis;
3816	pSg->pvUser = NULL; /* No GSO here. */
3817	pSg->cSegs = 1;
3818	pSg->aSegs[0].pvSeg = pThis->aTxPacketFallback;
3819	pSg->aSegs[0].cbSeg = sizeof(pThis->aTxPacketFallback);
3820	}
3821
3822	pThisCC->CTX_SUFF(pTxSg) = pSg;
3823	return VINF_SUCCESS;
3824	}
3825	#else /* E1K_WITH_TXD_CACHE */
3826	/**
3827	* Allocates an xmit buffer.
3828	*
3829	* @returns See PDMINETWORKUP::pfnAllocBuf.
3830	* @param pThis The device state structure.
3831	* @param cbMin The minimum frame size.
3832	* @param fExactSize Whether cbMin is exact or if we have to max it
3833	* out to the max MTU size.
3834	* @param fGso Whether this is a GSO frame or not.
3835	*/
3836	DECLINLINE(int) e1kXmitAllocBuf(PE1KSTATE pThis, PE1KSTATECC pThisCC, bool fGso)
3837	{
3838	/* Deal with existing buffer (descriptor screw up, reset, etc). */
3839	if (RT_UNLIKELY(pThisCC->CTX_SUFF(pTxSg)))
3840	e1kXmitFreeBuf(pThis, pThisCC);
3841	Assert(pThisCC->CTX_SUFF(pTxSg) == NULL);
3842
3843	/*
3844	* Allocate the buffer.
3845	*/
3846	PPDMSCATTERGATHER pSg;
3847	if (RT_LIKELY(GET_BITS(RCTL, LBM) != RCTL_LBM_TCVR))
3848	{
3849	if (pThis->cbTxAlloc == 0)
3850	{
3851	/* Zero packet, no need for the buffer */
3852	return VINF_SUCCESS;
3853	}
3854	if (fGso && pThis->GsoCtx.u8Type == PDMNETWORKGSOTYPE_INVALID)
3855	{
3856	E1kLog3(("Invalid GSO context, won't allocate this packet, cb=%u %s%s\n",
3857	pThis->cbTxAlloc, pThis->fVTag ? "VLAN " : "", pThis->fGSO ? "GSO " : ""));
3858	/* No valid GSO context is available, ignore this packet. */
3859	pThis->cbTxAlloc = 0;
3860	return VINF_SUCCESS;
3861	}
3862
3863	PPDMINETWORKUP pDrv = pThisCC->CTX_SUFF(pDrv);
3864	if (RT_UNLIKELY(!pDrv))
3865	return VERR_NET_DOWN;
3866	int rc = pDrv->pfnAllocBuf(pDrv, pThis->cbTxAlloc, fGso ? &pThis->GsoCtx : NULL, &pSg);
3867	if (RT_FAILURE(rc))
3868	{
3869	/* Suspend TX as we are out of buffers atm */
3870	STATUS \|= STATUS_TXOFF;
3871	return rc;
3872	}
3873	E1kLog3(("%s Allocated buffer for TX packet: cb=%u %s%s\n",
3874	pThis->szPrf, pThis->cbTxAlloc,
3875	pThis->fVTag ? "VLAN " : "",
3876	pThis->fGSO ? "GSO " : ""));
3877	}
3878	else
3879	{
3880	/* Create a loopback using the fallback buffer and preallocated SG. */
3881	AssertCompileMemberSize(E1KSTATE, uTxFallback.Sg, 8 * sizeof(size_t));
3882	pSg = &pThis->uTxFallback.Sg;
3883	pSg->fFlags = PDMSCATTERGATHER_FLAGS_MAGIC \| PDMSCATTERGATHER_FLAGS_OWNER_3;
3884	pSg->cbUsed = 0;
3885	pSg->cbAvailable = sizeof(pThis->aTxPacketFallback);
3886	pSg->pvAllocator = pThis;
3887	pSg->pvUser = NULL; /* No GSO here. */
3888	pSg->cSegs = 1;
3889	pSg->aSegs[0].pvSeg = pThis->aTxPacketFallback;
3890	pSg->aSegs[0].cbSeg = sizeof(pThis->aTxPacketFallback);
3891	}
3892	pThis->cbTxAlloc = 0;
3893
3894	pThisCC->CTX_SUFF(pTxSg) = pSg;
3895	return VINF_SUCCESS;
3896	}
3897	#endif /* E1K_WITH_TXD_CACHE */
3898
3899	/**
3900	* Checks if it's a GSO buffer or not.
3901	*
3902	* @returns true / false.
3903	* @param pTxSg The scatter / gather buffer.
3904	*/
3905	DECLINLINE(bool) e1kXmitIsGsoBuf(PDMSCATTERGATHER const *pTxSg)
3906	{
3907	#if 0
3908	if (!pTxSg)
3909	E1kLog(("e1kXmitIsGsoBuf: pTxSG is NULL\n"));
3910	if (pTxSg && pTxSg->pvUser)
3911	E1kLog(("e1kXmitIsGsoBuf: pvUser is NULL\n"));
3912	#endif
3913	return pTxSg && pTxSg->pvUser /* GSO indicator */;
3914	}
3915
3916	#ifndef E1K_WITH_TXD_CACHE
3917	/**
3918	* Load transmit descriptor from guest memory.
3919	*
3920	* @param pDevIns The device instance.
3921	* @param pDesc Pointer to descriptor union.
3922	* @param addr Physical address in guest context.
3923	* @thread E1000_TX
3924	*/
3925	DECLINLINE(void) e1kLoadDesc(PPDMDEVINS pDevIns, E1KTXDESC *pDesc, RTGCPHYS addr)
3926	{
3927	PDMDevHlpPhysRead(pDevIns, addr, pDesc, sizeof(E1KTXDESC));
3928	}
3929	#else /* E1K_WITH_TXD_CACHE */
3930	/**
3931	* Load transmit descriptors from guest memory.
3932	*
3933	* We need two physical reads in case the tail wrapped around the end of TX
3934	* descriptor ring.
3935	*
3936	* @returns the actual number of descriptors fetched.
3937	* @param pDevIns The device instance.
3938	* @param pThis The device state structure.
3939	* @thread E1000_TX
3940	*/
3941	DECLINLINE(unsigned) e1kTxDLoadMore(PPDMDEVINS pDevIns, PE1KSTATE pThis)
3942	{
3943	Assert(pThis->iTxDCurrent == 0);
3944	/* We've already loaded pThis->nTxDFetched descriptors past TDH. */
3945	unsigned nDescsAvailable = e1kGetTxLen(pThis) - pThis->nTxDFetched;
3946	/* The following two lines ensure that pThis->nTxDFetched never overflows. */
3947	AssertCompile(E1K_TXD_CACHE_SIZE < (256 * sizeof(pThis->nTxDFetched)));
3948	unsigned nDescsToFetch = RT_MIN(nDescsAvailable, E1K_TXD_CACHE_SIZE - pThis->nTxDFetched);
3949	unsigned nDescsTotal = TDLEN / sizeof(E1KTXDESC);
3950	unsigned nFirstNotLoaded = (TDH + pThis->nTxDFetched) % nDescsTotal;
3951	unsigned nDescsInSingleRead = RT_MIN(nDescsToFetch, nDescsTotal - nFirstNotLoaded);
3952	E1kLog3(("%s e1kTxDLoadMore: nDescsAvailable=%u nDescsToFetch=%u nDescsTotal=%u nFirstNotLoaded=0x%x nDescsInSingleRead=%u\n",
3953	pThis->szPrf, nDescsAvailable, nDescsToFetch, nDescsTotal,
3954	nFirstNotLoaded, nDescsInSingleRead));
3955	if (nDescsToFetch == 0)
3956	return 0;
3957	E1KTXDESC* pFirstEmptyDesc = &pThis->aTxDescriptors[pThis->nTxDFetched];
3958	PDMDevHlpPhysRead(pDevIns,
3959	((uint64_t)TDBAH << 32) + TDBAL + nFirstNotLoaded * sizeof(E1KTXDESC),
3960	pFirstEmptyDesc, nDescsInSingleRead * sizeof(E1KTXDESC));
3961	E1kLog3(("%s Fetched %u TX descriptors at %08x%08x(0x%x), TDLEN=%08x, TDH=%08x, TDT=%08x\n",
3962	pThis->szPrf, nDescsInSingleRead,
3963	TDBAH, TDBAL + TDH * sizeof(E1KTXDESC),
3964	nFirstNotLoaded, TDLEN, TDH, TDT));
3965	if (nDescsToFetch > nDescsInSingleRead)
3966	{
3967	PDMDevHlpPhysRead(pDevIns,
3968	((uint64_t)TDBAH << 32) + TDBAL,
3969	pFirstEmptyDesc + nDescsInSingleRead,
3970	(nDescsToFetch - nDescsInSingleRead) * sizeof(E1KTXDESC));
3971	E1kLog3(("%s Fetched %u TX descriptors at %08x%08x\n",
3972	pThis->szPrf, nDescsToFetch - nDescsInSingleRead,
3973	TDBAH, TDBAL));
3974	}
3975	pThis->nTxDFetched += (uint8_t)nDescsToFetch;
3976	return nDescsToFetch;
3977	}
3978
3979	/**
3980	* Load transmit descriptors from guest memory only if there are no loaded
3981	* descriptors.
3982	*
3983	* @returns true if there are descriptors in cache.
3984	* @param pDevIns The device instance.
3985	* @param pThis The device state structure.
3986	* @thread E1000_TX
3987	*/
3988	DECLINLINE(bool) e1kTxDLazyLoad(PPDMDEVINS pDevIns, PE1KSTATE pThis)
3989	{
3990	if (pThis->nTxDFetched == 0)
3991	return e1kTxDLoadMore(pDevIns, pThis) != 0;
3992	return true;
3993	}
3994	#endif /* E1K_WITH_TXD_CACHE */
3995
3996	/**
3997	* Write back transmit descriptor to guest memory.
3998	*
3999	* @param pDevIns The device instance.
4000	* @param pThis The device state structure.
4001	* @param pDesc Pointer to descriptor union.
4002	* @param addr Physical address in guest context.
4003	* @thread E1000_TX
4004	*/
4005	DECLINLINE(void) e1kWriteBackDesc(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KTXDESC *pDesc, RTGCPHYS addr)
4006	{
4007	/* Only the last half of the descriptor has to be written back. */
4008	e1kPrintTDesc(pThis, pDesc, "^^^");
4009	PDMDevHlpPCIPhysWrite(pDevIns, addr, pDesc, sizeof(E1KTXDESC));
4010	}
4011
4012	/**
4013	* Transmit complete frame.
4014	*
4015	* @remarks We skip the FCS since we're not responsible for sending anything to
4016	* a real ethernet wire.
4017	*
4018	* @param pDevIns The device instance.
4019	* @param pThis The device state structure.
4020	* @param pThisCC The current context instance data.
4021	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
4022	* @thread E1000_TX
4023	*/
4024	static void e1kTransmitFrame(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC, bool fOnWorkerThread)
4025	{
4026	PPDMSCATTERGATHER pSg = pThisCC->CTX_SUFF(pTxSg);
4027	uint32_t cbFrame = pSg ? (uint32_t)pSg->cbUsed : 0;
4028	Assert(!pSg \|\| pSg->cSegs == 1);
4029
4030	if (cbFrame > 70) /* unqualified guess */
4031	pThis->led.Asserted.s.fWriting = pThis->led.Actual.s.fWriting = 1;
4032
4033	#ifdef E1K_INT_STATS
4034	if (cbFrame <= 1514)
4035	E1K_INC_ISTAT_CNT(pThis->uStatTx1514);
4036	else if (cbFrame <= 2962)
4037	E1K_INC_ISTAT_CNT(pThis->uStatTx2962);
4038	else if (cbFrame <= 4410)
4039	E1K_INC_ISTAT_CNT(pThis->uStatTx4410);
4040	else if (cbFrame <= 5858)
4041	E1K_INC_ISTAT_CNT(pThis->uStatTx5858);
4042	else if (cbFrame <= 7306)
4043	E1K_INC_ISTAT_CNT(pThis->uStatTx7306);
4044	else if (cbFrame <= 8754)
4045	E1K_INC_ISTAT_CNT(pThis->uStatTx8754);
4046	else if (cbFrame <= 16384)
4047	E1K_INC_ISTAT_CNT(pThis->uStatTx16384);
4048	else if (cbFrame <= 32768)
4049	E1K_INC_ISTAT_CNT(pThis->uStatTx32768);
4050	else
4051	E1K_INC_ISTAT_CNT(pThis->uStatTxLarge);
4052	#endif /* E1K_INT_STATS */
4053
4054	/* Add VLAN tag */
4055	if (cbFrame > 12 && pThis->fVTag)
4056	{
4057	E1kLog3(("%s Inserting VLAN tag %08x\n",
4058	pThis->szPrf, RT_BE2H_U16((uint16_t)VET) \| (RT_BE2H_U16(pThis->u16VTagTCI) << 16)));
4059	memmove((uint8_t)pSg->aSegs[0].pvSeg + 16, (uint8_t)pSg->aSegs[0].pvSeg + 12, cbFrame - 12);
4060	((uint32_t)pSg->aSegs[0].pvSeg + 3) = RT_BE2H_U16((uint16_t)VET) \| (RT_BE2H_U16(pThis->u16VTagTCI) << 16);
4061	pSg->cbUsed += 4;
4062	cbFrame += 4;
4063	Assert(pSg->cbUsed == cbFrame);
4064	Assert(pSg->cbUsed <= pSg->cbAvailable);
4065	}
4066	/* E1kLog2(("%s < < < Outgoing packet. Dump follows: > > >\n"
4067	"%.*Rhxd\n"
4068	"%s < < < < < < < < < < < < < End of dump > > > > > > > > > > > >\n",
4069	pThis->szPrf, cbFrame, pSg->aSegs[0].pvSeg, pThis->szPrf));*/
4070
4071	/* Update the stats */
4072	E1K_INC_CNT32(TPT);
4073	E1K_ADD_CNT64(TOTL, TOTH, cbFrame);
4074	E1K_INC_CNT32(GPTC);
4075	if (pSg && e1kIsBroadcast(pSg->aSegs[0].pvSeg))
4076	E1K_INC_CNT32(BPTC);
4077	else if (pSg && e1kIsMulticast(pSg->aSegs[0].pvSeg))
4078	E1K_INC_CNT32(MPTC);
4079	/* Update octet transmit counter */
4080	E1K_ADD_CNT64(GOTCL, GOTCH, cbFrame);
4081	if (pThisCC->CTX_SUFF(pDrv))
4082	STAM_REL_COUNTER_ADD(&pThis->StatTransmitBytes, cbFrame);
4083	if (cbFrame == 64)
4084	E1K_INC_CNT32(PTC64);
4085	else if (cbFrame < 128)
4086	E1K_INC_CNT32(PTC127);
4087	else if (cbFrame < 256)
4088	E1K_INC_CNT32(PTC255);
4089	else if (cbFrame < 512)
4090	E1K_INC_CNT32(PTC511);
4091	else if (cbFrame < 1024)
4092	E1K_INC_CNT32(PTC1023);
4093	else
4094	E1K_INC_CNT32(PTC1522);
4095
4096	E1K_INC_ISTAT_CNT(pThis->uStatTxFrm);
4097
4098	/*
4099	* Dump and send the packet.
4100	*/
4101	int rc = VERR_NET_DOWN;
4102	if (pSg && pSg->pvAllocator != pThis)
4103	{
4104	e1kPacketDump(pDevIns, pThis, (uint8_t const *)pSg->aSegs[0].pvSeg, cbFrame, "--> Outgoing");
4105
4106	pThisCC->CTX_SUFF(pTxSg) = NULL;
4107	PPDMINETWORKUP pDrv = pThisCC->CTX_SUFF(pDrv);
4108	if (pDrv)
4109	{
4110	/* Release critical section to avoid deadlock in CanReceive */
4111	//e1kCsLeave(pThis);
4112	STAM_PROFILE_START(&pThis->CTX_SUFF_Z(StatTransmitSend), a);
4113	rc = pDrv->pfnSendBuf(pDrv, pSg, fOnWorkerThread);
4114	STAM_PROFILE_STOP(&pThis->CTX_SUFF_Z(StatTransmitSend), a);
4115	//e1kCsEnter(pThis, RT_SRC_POS);
4116	}
4117	}
4118	else if (pSg)
4119	{
4120	Assert(pSg->aSegs[0].pvSeg == pThis->aTxPacketFallback);
4121	e1kPacketDump(pDevIns, pThis, (uint8_t const *)pSg->aSegs[0].pvSeg, cbFrame, "--> Loopback");
4122
4123	/** @todo do we actually need to check that we're in loopback mode here? */
4124	if (GET_BITS(RCTL, LBM) == RCTL_LBM_TCVR)
4125	{
4126	E1KRXDST status;
4127	RT_ZERO(status);
4128	status.fPIF = true;
4129	e1kHandleRxPacket(pDevIns, pThis, pSg->aSegs[0].pvSeg, cbFrame, status);
4130	rc = VINF_SUCCESS;
4131	}
4132	e1kXmitFreeBuf(pThis, pThisCC);
4133	}
4134	else
4135	rc = VERR_NET_DOWN;
4136	if (RT_FAILURE(rc))
4137	{
4138	E1kLogRel(("E1000: ERROR! pfnSend returned %Rrc\n", rc));
4139	/** @todo handle VERR_NET_DOWN and VERR_NET_NO_BUFFER_SPACE. Signal error ? */
4140	}
4141
4142	pThis->led.Actual.s.fWriting = 0;
4143	}
4144
4145	/**
4146	* Compute and write internet checksum (e1kCSum16) at the specified offset.
4147	*
4148	* @param pThis The device state structure.
4149	* @param pPkt Pointer to the packet.
4150	* @param u16PktLen Total length of the packet.
4151	* @param cso Offset in packet to write checksum at.
4152	* @param css Offset in packet to start computing
4153	* checksum from.
4154	* @param cse Offset in packet to stop computing
4155	* checksum at.
4156	* @thread E1000_TX
4157	*/
4158	static void e1kInsertChecksum(PE1KSTATE pThis, uint8_t *pPkt, uint16_t u16PktLen, uint8_t cso, uint8_t css, uint16_t cse)
4159	{
4160	RT_NOREF1(pThis);
4161
4162	if (css >= u16PktLen)
4163	{
4164	E1kLog2(("%s css(%X) is greater than packet length-1(%X), checksum is not inserted\n",
4165	pThis->szPrf, cso, u16PktLen));
4166	return;
4167	}
4168
4169	if (cso >= u16PktLen - 1)
4170	{
4171	E1kLog2(("%s cso(%X) is greater than packet length-2(%X), checksum is not inserted\n",
4172	pThis->szPrf, cso, u16PktLen));
4173	return;
4174	}
4175
4176	if (cse == 0 \|\| cse >= u16PktLen)
4177	cse = u16PktLen - 1;
4178	else if (cse < css)
4179	{
4180	E1kLog2(("%s css(%X) is greater than cse(%X), checksum is not inserted\n",
4181	pThis->szPrf, css, cse));
4182	return;
4183	}
4184
4185	uint16_t u16ChkSum = e1kCSum16(pPkt + css, cse - css + 1);
4186	E1kLog2(("%s Inserting csum: %04X at %02X, old value: %04X\n", pThis->szPrf,
4187	u16ChkSum, cso, (uint16_t)(pPkt + cso)));
4188	(uint16_t)(pPkt + cso) = u16ChkSum;
4189	}
4190
4191	/**
4192	* Add a part of descriptor's buffer to transmit frame.
4193	*
4194	* @remarks data.u64BufAddr is used unconditionally for both data
4195	* and legacy descriptors since it is identical to
4196	* legacy.u64BufAddr.
4197	*
4198	* @param pDevIns The device instance.
4199	* @param pThis The device state structure.
4200	* @param pDesc Pointer to the descriptor to transmit.
4201	* @param u16Len Length of buffer to the end of segment.
4202	* @param fSend Force packet sending.
4203	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
4204	* @thread E1000_TX
4205	*/
4206	#ifndef E1K_WITH_TXD_CACHE
4207	static void e1kFallbackAddSegment(PPDMDEVINS pDevIns, PE1KSTATE pThis, RTGCPHYS PhysAddr, uint16_t u16Len, bool fSend, bool fOnWorkerThread)
4208	{
4209	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
4210	/* TCP header being transmitted */
4211	struct E1kTcpHeader pTcpHdr = (struct E1kTcpHeader )(pThis->aTxPacketFallback + pThis->contextTSE.tu.u8CSS);
4212	/* IP header being transmitted */
4213	struct E1kIpHeader pIpHdr = (struct E1kIpHeader )(pThis->aTxPacketFallback + pThis->contextTSE.ip.u8CSS);
4214
4215	E1kLog3(("%s e1kFallbackAddSegment: Length=%x, remaining payload=%x, header=%x, send=%RTbool\n",
4216	pThis->szPrf, u16Len, pThis->u32PayRemain, pThis->u16HdrRemain, fSend));
4217	Assert(pThis->u32PayRemain + pThis->u16HdrRemain > 0);
4218
4219	PDMDevHlpPhysRead(pDevIns, PhysAddr, pThis->aTxPacketFallback + pThis->u16TxPktLen, u16Len);
4220	E1kLog3(("%s Dump of the segment:\n"
4221	"%.*Rhxd\n"
4222	"%s --- End of dump ---\n",
4223	pThis->szPrf, u16Len, pThis->aTxPacketFallback + pThis->u16TxPktLen, pThis->szPrf));
4224	pThis->u16TxPktLen += u16Len;
4225	E1kLog3(("%s e1kFallbackAddSegment: pThis->u16TxPktLen=%x\n",
4226	pThis->szPrf, pThis->u16TxPktLen));
4227	if (pThis->u16HdrRemain > 0)
4228	{
4229	/* The header was not complete, check if it is now */
4230	if (u16Len >= pThis->u16HdrRemain)
4231	{
4232	/* The rest is payload */
4233	u16Len -= pThis->u16HdrRemain;
4234	pThis->u16HdrRemain = 0;
4235	/* Save partial checksum and flags */
4236	pThis->u32SavedCsum = pTcpHdr->chksum;
4237	pThis->u16SavedFlags = pTcpHdr->hdrlen_flags;
4238	/* Clear FIN and PSH flags now and set them only in the last segment */
4239	pTcpHdr->hdrlen_flags &= ~htons(E1K_TCP_FIN \| E1K_TCP_PSH);
4240	}
4241	else
4242	{
4243	/* Still not */
4244	pThis->u16HdrRemain -= u16Len;
4245	E1kLog3(("%s e1kFallbackAddSegment: Header is still incomplete, 0x%x bytes remain.\n",
4246	pThis->szPrf, pThis->u16HdrRemain));
4247	return;
4248	}
4249	}
4250
4251	pThis->u32PayRemain -= u16Len;
4252
4253	if (fSend)
4254	{
4255	/* Leave ethernet header intact */
4256	/* IP Total Length = payload + headers - ethernet header */
4257	pIpHdr->total_len = htons(pThis->u16TxPktLen - pThis->contextTSE.ip.u8CSS);
4258	E1kLog3(("%s e1kFallbackAddSegment: End of packet, pIpHdr->total_len=%x\n",
4259	pThis->szPrf, ntohs(pIpHdr->total_len)));
4260	/* Update IP Checksum */
4261	pIpHdr->chksum = 0;
4262	e1kInsertChecksum(pThis, pThis->aTxPacketFallback, pThis->u16TxPktLen,
4263	pThis->contextTSE.ip.u8CSO,
4264	pThis->contextTSE.ip.u8CSS,
4265	pThis->contextTSE.ip.u16CSE);
4266
4267	/* Update TCP flags */
4268	/* Restore original FIN and PSH flags for the last segment */
4269	if (pThis->u32PayRemain == 0)
4270	{
4271	pTcpHdr->hdrlen_flags = pThis->u16SavedFlags;
4272	E1K_INC_CNT32(TSCTC);
4273	}
4274	/* Add TCP length to partial pseudo header sum */
4275	uint32_t csum = pThis->u32SavedCsum
4276	+ htons(pThis->u16TxPktLen - pThis->contextTSE.tu.u8CSS);
4277	while (csum >> 16)
4278	csum = (csum >> 16) + (csum & 0xFFFF);
4279	pTcpHdr->chksum = csum;
4280	/* Compute final checksum */
4281	e1kInsertChecksum(pThis, pThis->aTxPacketFallback, pThis->u16TxPktLen,
4282	pThis->contextTSE.tu.u8CSO,
4283	pThis->contextTSE.tu.u8CSS,
4284	pThis->contextTSE.tu.u16CSE);
4285
4286	/*
4287	* Transmit it. If we've use the SG already, allocate a new one before
4288	* we copy of the data.
4289	*/
4290	PPDMSCATTERGATHER pTxSg = pThisCC->CTX_SUFF(pTxSg);
4291	if (!pTxSg)
4292	{
4293	e1kXmitAllocBuf(pThis, pThisCC, pThis->u16TxPktLen + (pThis->fVTag ? 4 : 0), true /fExactSize/, false /fGso/);
4294	pTxSg = pThisCC->CTX_SUFF(pTxSg);
4295	}
4296	if (pTxSg)
4297	{
4298	Assert(pThis->u16TxPktLen <= pThisCC->CTX_SUFF(pTxSg)->cbAvailable);
4299	Assert(pTxSg->cSegs == 1);
4300	if (pThis->CCCTX_SUFF(pTxSg)->aSegs[0].pvSeg != pThis->aTxPacketFallback)
4301	memcpy(pTxSg->aSegs[0].pvSeg, pThis->aTxPacketFallback, pThis->u16TxPktLen);
4302	pTxSg->cbUsed = pThis->u16TxPktLen;
4303	pTxSg->aSegs[0].cbSeg = pThis->u16TxPktLen;
4304	}
4305	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
4306
4307	/* Update Sequence Number */
4308	pTcpHdr->seqno = htonl(ntohl(pTcpHdr->seqno) + pThis->u16TxPktLen
4309	- pThis->contextTSE.dw3.u8HDRLEN);
4310	/* Increment IP identification */
4311	pIpHdr->ident = htons(ntohs(pIpHdr->ident) + 1);
4312	}
4313	}
4314	#else /* E1K_WITH_TXD_CACHE */
4315	static int e1kFallbackAddSegment(PPDMDEVINS pDevIns, PE1KSTATE pThis, RTGCPHYS PhysAddr, uint16_t u16Len, bool fSend, bool fOnWorkerThread)
4316	{
4317	int rc = VINF_SUCCESS;
4318	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
4319	/* TCP header being transmitted */
4320	struct E1kTcpHeader pTcpHdr = (struct E1kTcpHeader )(pThis->aTxPacketFallback + pThis->contextTSE.tu.u8CSS);
4321	/* IP header being transmitted */
4322	struct E1kIpHeader pIpHdr = (struct E1kIpHeader )(pThis->aTxPacketFallback + pThis->contextTSE.ip.u8CSS);
4323
4324	E1kLog3(("%s e1kFallbackAddSegment: Length=%x, remaining payload=%x, header=%x, send=%RTbool\n",
4325	pThis->szPrf, u16Len, pThis->u32PayRemain, pThis->u16HdrRemain, fSend));
4326	AssertReturn(pThis->u32PayRemain + pThis->u16HdrRemain > 0, VINF_SUCCESS);
4327
4328	if (pThis->u16TxPktLen + u16Len <= sizeof(pThis->aTxPacketFallback))
4329	PDMDevHlpPhysRead(pDevIns, PhysAddr, pThis->aTxPacketFallback + pThis->u16TxPktLen, u16Len);
4330	else
4331	E1kLog(("%s e1kFallbackAddSegment: writing beyond aTxPacketFallback, u16TxPktLen=%d(0x%x) + u16Len=%d(0x%x) > %d\n",
4332	pThis->szPrf, pThis->u16TxPktLen, pThis->u16TxPktLen, u16Len, u16Len, sizeof(pThis->aTxPacketFallback)));
4333	E1kLog3(("%s Dump of the segment:\n"
4334	"%.*Rhxd\n"
4335	"%s --- End of dump ---\n",
4336	pThis->szPrf, u16Len, pThis->aTxPacketFallback + pThis->u16TxPktLen, pThis->szPrf));
4337	pThis->u16TxPktLen += u16Len;
4338	E1kLog3(("%s e1kFallbackAddSegment: pThis->u16TxPktLen=%x\n",
4339	pThis->szPrf, pThis->u16TxPktLen));
4340	if (pThis->u16HdrRemain > 0)
4341	{
4342	/* The header was not complete, check if it is now */
4343	if (u16Len >= pThis->u16HdrRemain)
4344	{
4345	/* The rest is payload */
4346	u16Len -= pThis->u16HdrRemain;
4347	pThis->u16HdrRemain = 0;
4348	/* Save partial checksum and flags */
4349	pThis->u32SavedCsum = pTcpHdr->chksum;
4350	pThis->u16SavedFlags = pTcpHdr->hdrlen_flags;
4351	/* Clear FIN and PSH flags now and set them only in the last segment */
4352	pTcpHdr->hdrlen_flags &= ~htons(E1K_TCP_FIN \| E1K_TCP_PSH);
4353	}
4354	else
4355	{
4356	/* Still not */
4357	pThis->u16HdrRemain -= u16Len;
4358	E1kLog3(("%s e1kFallbackAddSegment: Header is still incomplete, 0x%x bytes remain.\n",
4359	pThis->szPrf, pThis->u16HdrRemain));
4360	return rc;
4361	}
4362	}
4363
4364	if (u16Len > pThis->u32PayRemain)
4365	pThis->u32PayRemain = 0;
4366	else
4367	pThis->u32PayRemain -= u16Len;
4368
4369	if (fSend)
4370	{
4371	/* Leave ethernet header intact */
4372	/* IP Total Length = payload + headers - ethernet header */
4373	pIpHdr->total_len = htons(pThis->u16TxPktLen - pThis->contextTSE.ip.u8CSS);
4374	E1kLog3(("%s e1kFallbackAddSegment: End of packet, pIpHdr->total_len=%x\n",
4375	pThis->szPrf, ntohs(pIpHdr->total_len)));
4376	/* Update IP Checksum */
4377	pIpHdr->chksum = 0;
4378	e1kInsertChecksum(pThis, pThis->aTxPacketFallback, pThis->u16TxPktLen,
4379	pThis->contextTSE.ip.u8CSO,
4380	pThis->contextTSE.ip.u8CSS,
4381	pThis->contextTSE.ip.u16CSE);
4382
4383	/* Update TCP flags */
4384	/* Restore original FIN and PSH flags for the last segment */
4385	if (pThis->u32PayRemain == 0)
4386	{
4387	pTcpHdr->hdrlen_flags = pThis->u16SavedFlags;
4388	E1K_INC_CNT32(TSCTC);
4389	}
4390	/* Add TCP length to partial pseudo header sum */
4391	uint32_t csum = pThis->u32SavedCsum
4392	+ htons(pThis->u16TxPktLen - pThis->contextTSE.tu.u8CSS);
4393	while (csum >> 16)
4394	csum = (csum >> 16) + (csum & 0xFFFF);
4395	Assert(csum < 65536);
4396	pTcpHdr->chksum = (uint16_t)csum;
4397	/* Compute final checksum */
4398	e1kInsertChecksum(pThis, pThis->aTxPacketFallback, pThis->u16TxPktLen,
4399	pThis->contextTSE.tu.u8CSO,
4400	pThis->contextTSE.tu.u8CSS,
4401	pThis->contextTSE.tu.u16CSE);
4402
4403	/*
4404	* Transmit it.
4405	*/
4406	PPDMSCATTERGATHER pTxSg = pThisCC->CTX_SUFF(pTxSg);
4407	if (pTxSg)
4408	{
4409	/* Make sure the packet fits into the allocated buffer */
4410	size_t cbCopy = RT_MIN(pThis->u16TxPktLen, pThisCC->CTX_SUFF(pTxSg)->cbAvailable);
4411	#ifdef DEBUG
4412	if (pThis->u16TxPktLen > pTxSg->cbAvailable)
4413	E1kLog(("%s e1kFallbackAddSegment: truncating packet, u16TxPktLen=%d(0x%x) > cbAvailable=%d(0x%x)\n",
4414	pThis->szPrf, pThis->u16TxPktLen, pThis->u16TxPktLen, pTxSg->cbAvailable, pTxSg->cbAvailable));
4415	#endif /* DEBUG */
4416	Assert(pTxSg->cSegs == 1);
4417	if (pTxSg->aSegs[0].pvSeg != pThis->aTxPacketFallback)
4418	memcpy(pTxSg->aSegs[0].pvSeg, pThis->aTxPacketFallback, cbCopy);
4419	pTxSg->cbUsed = cbCopy;
4420	pTxSg->aSegs[0].cbSeg = cbCopy;
4421	}
4422	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
4423
4424	/* Update Sequence Number */
4425	pTcpHdr->seqno = htonl(ntohl(pTcpHdr->seqno) + pThis->u16TxPktLen
4426	- pThis->contextTSE.dw3.u8HDRLEN);
4427	/* Increment IP identification */
4428	pIpHdr->ident = htons(ntohs(pIpHdr->ident) + 1);
4429
4430	/* Allocate new buffer for the next segment. */
4431	if (pThis->u32PayRemain)
4432	{
4433	pThis->cbTxAlloc = RT_MIN(pThis->u32PayRemain,
4434	pThis->contextTSE.dw3.u16MSS)
4435	+ pThis->contextTSE.dw3.u8HDRLEN;
4436	/* Do not add VLAN tags to empty packets. */
4437	if (pThis->fVTag && pThis->cbTxAlloc > 0)
4438	pThis->cbTxAlloc += 4;
4439	rc = e1kXmitAllocBuf(pThis, pThisCC, false /* fGSO */);
4440	}
4441	}
4442
4443	return rc;
4444	}
4445	#endif /* E1K_WITH_TXD_CACHE */
4446
4447	#ifndef E1K_WITH_TXD_CACHE
4448	/**
4449	* TCP segmentation offloading fallback: Add descriptor's buffer to transmit
4450	* frame.
4451	*
4452	* We construct the frame in the fallback buffer first and the copy it to the SG
4453	* buffer before passing it down to the network driver code.
4454	*
4455	* @returns true if the frame should be transmitted, false if not.
4456	*
4457	* @param pThis The device state structure.
4458	* @param pDesc Pointer to the descriptor to transmit.
4459	* @param cbFragment Length of descriptor's buffer.
4460	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
4461	* @thread E1000_TX
4462	*/
4463	static bool e1kFallbackAddToFrame(PE1KSTATE pThis, E1KTXDESC *pDesc, uint32_t cbFragment, bool fOnWorkerThread)
4464	{
4465	PPDMSCATTERGATHER pTxSg = pThisCC->CTX_SUFF(pTxSg);
4466	Assert(e1kGetDescType(pDesc) == E1K_DTYP_DATA);
4467	Assert(pDesc->data.cmd.fTSE);
4468	Assert(!e1kXmitIsGsoBuf(pTxSg));
4469
4470	uint16_t u16MaxPktLen = pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw3.u16MSS;
4471	Assert(u16MaxPktLen != 0);
4472	Assert(u16MaxPktLen < E1K_MAX_TX_PKT_SIZE);
4473
4474	/*
4475	* Carve out segments.
4476	*/
4477	do
4478	{
4479	/* Calculate how many bytes we have left in this TCP segment */
4480	uint32_t cb = u16MaxPktLen - pThis->u16TxPktLen;
4481	if (cb > cbFragment)
4482	{
4483	/* This descriptor fits completely into current segment */
4484	cb = cbFragment;
4485	e1kFallbackAddSegment(pDevIns, pThis, pDesc->data.u64BufAddr, cb, pDesc->data.cmd.fEOP /fSend/, fOnWorkerThread);
4486	}
4487	else
4488	{
4489	e1kFallbackAddSegment(pDevIns, pThis, pDesc->data.u64BufAddr, cb, true /fSend/, fOnWorkerThread);
4490	/*
4491	* Rewind the packet tail pointer to the beginning of payload,
4492	* so we continue writing right beyond the header.
4493	*/
4494	pThis->u16TxPktLen = pThis->contextTSE.dw3.u8HDRLEN;
4495	}
4496
4497	pDesc->data.u64BufAddr += cb;
4498	cbFragment -= cb;
4499	} while (cbFragment > 0);
4500
4501	if (pDesc->data.cmd.fEOP)
4502	{
4503	/* End of packet, next segment will contain header. */
4504	if (pThis->u32PayRemain != 0)
4505	E1K_INC_CNT32(TSCTFC);
4506	pThis->u16TxPktLen = 0;
4507	e1kXmitFreeBuf(pThis, PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC));
4508	}
4509
4510	return false;
4511	}
4512	#else /* E1K_WITH_TXD_CACHE */
4513	/**
4514	* TCP segmentation offloading fallback: Add descriptor's buffer to transmit
4515	* frame.
4516	*
4517	* We construct the frame in the fallback buffer first and the copy it to the SG
4518	* buffer before passing it down to the network driver code.
4519	*
4520	* @returns error code
4521	*
4522	* @param pDevIns The device instance.
4523	* @param pThis The device state structure.
4524	* @param pDesc Pointer to the descriptor to transmit.
4525	* @param cbFragment Length of descriptor's buffer.
4526	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
4527	* @thread E1000_TX
4528	*/
4529	static int e1kFallbackAddToFrame(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KTXDESC *pDesc, bool fOnWorkerThread)
4530	{
4531	#ifdef VBOX_STRICT
4532	PPDMSCATTERGATHER pTxSg = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC)->CTX_SUFF(pTxSg);
4533	Assert(e1kGetDescType(pDesc) == E1K_DTYP_DATA);
4534	Assert(pDesc->data.cmd.fTSE);
4535	Assert(!e1kXmitIsGsoBuf(pTxSg));
4536	#endif
4537
4538	uint16_t u16MaxPktLen = pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw3.u16MSS;
4539	/* We cannot produce empty packets, ignore all TX descriptors (see @bugref{9571}) */
4540	if (u16MaxPktLen == 0)
4541	return VINF_SUCCESS;
4542
4543	/*
4544	* Carve out segments.
4545	*/
4546	int rc = VINF_SUCCESS;
4547	do
4548	{
4549	/* Calculate how many bytes we have left in this TCP segment */
4550	uint16_t cb = u16MaxPktLen - pThis->u16TxPktLen;
4551	if (cb > pDesc->data.cmd.u20DTALEN)
4552	{
4553	/* This descriptor fits completely into current segment */
4554	cb = (uint16_t)pDesc->data.cmd.u20DTALEN; /* u20DTALEN at this point is guarantied to fit into 16 bits. */
4555	rc = e1kFallbackAddSegment(pDevIns, pThis, pDesc->data.u64BufAddr, cb, pDesc->data.cmd.fEOP /fSend/, fOnWorkerThread);
4556	}
4557	else
4558	{
4559	rc = e1kFallbackAddSegment(pDevIns, pThis, pDesc->data.u64BufAddr, cb, true /fSend/, fOnWorkerThread);
4560	/*
4561	* Rewind the packet tail pointer to the beginning of payload,
4562	* so we continue writing right beyond the header.
4563	*/
4564	pThis->u16TxPktLen = pThis->contextTSE.dw3.u8HDRLEN;
4565	}
4566
4567	pDesc->data.u64BufAddr += cb;
4568	pDesc->data.cmd.u20DTALEN -= cb;
4569	} while (pDesc->data.cmd.u20DTALEN > 0 && RT_SUCCESS(rc));
4570
4571	if (pDesc->data.cmd.fEOP)
4572	{
4573	/* End of packet, next segment will contain header. */
4574	if (pThis->u32PayRemain != 0)
4575	E1K_INC_CNT32(TSCTFC);
4576	pThis->u16TxPktLen = 0;
4577	e1kXmitFreeBuf(pThis, PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC));
4578	}
4579
4580	return VINF_SUCCESS; /// @todo consider rc;
4581	}
4582	#endif /* E1K_WITH_TXD_CACHE */
4583
4584
4585	/**
4586	* Add descriptor's buffer to transmit frame.
4587	*
4588	* This deals with GSO and normal frames, e1kFallbackAddToFrame deals with the
4589	* TSE frames we cannot handle as GSO.
4590	*
4591	* @returns true on success, false on failure.
4592	*
4593	* @param pDevIns The device instance.
4594	* @param pThisCC The current context instance data.
4595	* @param pThis The device state structure.
4596	* @param PhysAddr The physical address of the descriptor buffer.
4597	* @param cbFragment Length of descriptor's buffer.
4598	* @thread E1000_TX
4599	*/
4600	static bool e1kAddToFrame(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC, RTGCPHYS PhysAddr, uint32_t cbFragment)
4601	{
4602	PPDMSCATTERGATHER pTxSg = pThisCC->CTX_SUFF(pTxSg);
4603	bool const fGso = e1kXmitIsGsoBuf(pTxSg);
4604	uint32_t const cbNewPkt = cbFragment + pThis->u16TxPktLen;
4605
4606	LogFlow(("%s e1kAddToFrame: ENTER cbFragment=%d u16TxPktLen=%d cbUsed=%d cbAvailable=%d fGSO=%s\n",
4607	pThis->szPrf, cbFragment, pThis->u16TxPktLen, pTxSg->cbUsed, pTxSg->cbAvailable,
4608	fGso ? "true" : "false"));
4609	PCPDMNETWORKGSO pGso = (PCPDMNETWORKGSO)pTxSg->pvUser;
4610	if (pGso)
4611	{
4612	if (RT_UNLIKELY(pGso->cbMaxSeg == 0))
4613	{
4614	E1kLog(("%s zero-sized fragments are not allowed\n", pThis->szPrf));
4615	return false;
4616	}
4617	if (RT_UNLIKELY(pGso->u8Type == PDMNETWORKGSOTYPE_IPV4_UDP))
4618	{
4619	E1kLog(("%s UDP fragmentation is no longer supported\n", pThis->szPrf));
4620	return false;
4621	}
4622	}
4623	if (RT_UNLIKELY( !fGso && cbNewPkt > E1K_MAX_TX_PKT_SIZE ))
4624	{
4625	E1kLog(("%s Transmit packet is too large: %u > %u(max)\n", pThis->szPrf, cbNewPkt, E1K_MAX_TX_PKT_SIZE));
4626	return false;
4627	}
4628	if (RT_UNLIKELY( cbNewPkt > pTxSg->cbAvailable ))
4629	{
4630	E1kLog(("%s Transmit packet is too large: %u > %u(max)\n", pThis->szPrf, cbNewPkt, pTxSg->cbAvailable));
4631	return false;
4632	}
4633
4634	if (RT_LIKELY(pTxSg))
4635	{
4636	Assert(pTxSg->cSegs == 1);
4637	if (pTxSg->cbUsed != pThis->u16TxPktLen)
4638	E1kLog(("%s e1kAddToFrame: pTxSg->cbUsed=%d(0x%x) != u16TxPktLen=%d(0x%x)\n",
4639	pThis->szPrf, pTxSg->cbUsed, pTxSg->cbUsed, pThis->u16TxPktLen, pThis->u16TxPktLen));
4640
4641	PDMDevHlpPhysRead(pDevIns, PhysAddr, (uint8_t *)pTxSg->aSegs[0].pvSeg + pThis->u16TxPktLen, cbFragment);
4642
4643	pTxSg->cbUsed = cbNewPkt;
4644	}
4645	pThis->u16TxPktLen = cbNewPkt;
4646
4647	return true;
4648	}
4649
4650
4651	/**
4652	* Write the descriptor back to guest memory and notify the guest.
4653	*
4654	* @param pThis The device state structure.
4655	* @param pDesc Pointer to the descriptor have been transmitted.
4656	* @param addr Physical address of the descriptor in guest memory.
4657	* @thread E1000_TX
4658	*/
4659	static void e1kDescReport(PPDMDEVINS pDevIns, PE1KSTATE pThis, E1KTXDESC *pDesc, RTGCPHYS addr)
4660	{
4661	/*
4662	* We fake descriptor write-back bursting. Descriptors are written back as they are
4663	* processed.
4664	*/
4665	/* Let's pretend we process descriptors. Write back with DD set. */
4666	/*
4667	* Prior to r71586 we tried to accomodate the case when write-back bursts
4668	* are enabled without actually implementing bursting by writing back all
4669	* descriptors, even the ones that do not have RS set. This caused kernel
4670	* panics with Linux SMP kernels, as the e1000 driver tried to free up skb
4671	* associated with written back descriptor if it happened to be a context
4672	* descriptor since context descriptors do not have skb associated to them.
4673	* Starting from r71586 we write back only the descriptors with RS set,
4674	* which is a little bit different from what the real hardware does in
4675	* case there is a chain of data descritors where some of them have RS set
4676	* and others do not. It is very uncommon scenario imho.
4677	* We need to check RPS as well since some legacy drivers use it instead of
4678	* RS even with newer cards.
4679	*/
4680	if (pDesc->legacy.cmd.fRS \|\| pDesc->legacy.cmd.fRPS)
4681	{
4682	pDesc->legacy.dw3.fDD = 1; /* Descriptor Done */
4683	e1kWriteBackDesc(pDevIns, pThis, pDesc, addr);
4684	if (pDesc->legacy.cmd.fEOP)
4685	{
4686	//#ifdef E1K_USE_TX_TIMERS
4687	if (pThis->fTidEnabled && pDesc->legacy.cmd.fIDE)
4688	{
4689	E1K_INC_ISTAT_CNT(pThis->uStatTxIDE);
4690	//if (pThis->fIntRaised)
4691	//{
4692	// /* Interrupt is already pending, no need for timers */
4693	// ICR \|= ICR_TXDW;
4694	//}
4695	//else {
4696	/* Arm the timer to fire in TIVD usec (discard .024) */
4697	e1kArmTimer(pDevIns, pThis, pThis->hTIDTimer, TIDV);
4698	# ifndef E1K_NO_TAD
4699	/* If absolute timer delay is enabled and the timer is not running yet, arm it. */
4700	E1kLog2(("%s Checking if TAD timer is running\n",
4701	pThis->szPrf));
4702	if (TADV != 0 && !PDMDevHlpTimerIsActive(pDevIns, pThis->hTADTimer))
4703	e1kArmTimer(pDevIns, pThis, pThis->hTADTimer, TADV);
4704	# endif /* E1K_NO_TAD */
4705	}
4706	else
4707	{
4708	if (pThis->fTidEnabled)
4709	{
4710	E1kLog2(("%s No IDE set, cancel TAD timer and raise interrupt\n",
4711	pThis->szPrf));
4712	/* Cancel both timers if armed and fire immediately. */
4713	# ifndef E1K_NO_TAD
4714	PDMDevHlpTimerStop(pDevIns, pThis->hTADTimer);
4715	# endif
4716	PDMDevHlpTimerStop(pDevIns, pThis->hTIDTimer);
4717	}
4718	//#endif /* E1K_USE_TX_TIMERS */
4719	E1K_INC_ISTAT_CNT(pThis->uStatIntTx);
4720	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_TXDW);
4721	//#ifdef E1K_USE_TX_TIMERS
4722	}
4723	//#endif /* E1K_USE_TX_TIMERS */
4724	}
4725	}
4726	else
4727	{
4728	E1K_INC_ISTAT_CNT(pThis->uStatTxNoRS);
4729	}
4730	}
4731
4732	#ifndef E1K_WITH_TXD_CACHE
4733
4734	/**
4735	* Process Transmit Descriptor.
4736	*
4737	* E1000 supports three types of transmit descriptors:
4738	* - legacy data descriptors of older format (context-less).
4739	* - data the same as legacy but providing new offloading capabilities.
4740	* - context sets up the context for following data descriptors.
4741	*
4742	* @param pDevIns The device instance.
4743	* @param pThis The device state structure.
4744	* @param pThisCC The current context instance data.
4745	* @param pDesc Pointer to descriptor union.
4746	* @param addr Physical address of descriptor in guest memory.
4747	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
4748	* @thread E1000_TX
4749	*/
4750	static int e1kXmitDesc(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC, E1KTXDESC *pDesc,
4751	RTGCPHYS addr, bool fOnWorkerThread)
4752	{
4753	int rc = VINF_SUCCESS;
4754	uint32_t cbVTag = 0;
4755
4756	e1kPrintTDesc(pThis, pDesc, "vvv");
4757
4758	//#ifdef E1K_USE_TX_TIMERS
4759	if (pThis->fTidEnabled)
4760	e1kCancelTimer(pDevIns, pThis, pThis->hTIDTimer);
4761	//#endif /* E1K_USE_TX_TIMERS */
4762
4763	switch (e1kGetDescType(pDesc))
4764	{
4765	case E1K_DTYP_CONTEXT:
4766	if (pDesc->context.dw2.fTSE)
4767	{
4768	pThis->contextTSE = pDesc->context;
4769	pThis->u32PayRemain = pDesc->context.dw2.u20PAYLEN;
4770	pThis->u16HdrRemain = pDesc->context.dw3.u8HDRLEN;
4771	e1kSetupGsoCtx(&pThis->GsoCtx, &pDesc->context);
4772	STAM_COUNTER_INC(&pThis->StatTxDescCtxTSE);
4773	}
4774	else
4775	{
4776	pThis->contextNormal = pDesc->context;
4777	STAM_COUNTER_INC(&pThis->StatTxDescCtxNormal);
4778	}
4779	E1kLog2(("%s %s context updated: IP CSS=%02X, IP CSO=%02X, IP CSE=%04X"
4780	", TU CSS=%02X, TU CSO=%02X, TU CSE=%04X\n", pThis->szPrf,
4781	pDesc->context.dw2.fTSE ? "TSE" : "Normal",
4782	pDesc->context.ip.u8CSS,
4783	pDesc->context.ip.u8CSO,
4784	pDesc->context.ip.u16CSE,
4785	pDesc->context.tu.u8CSS,
4786	pDesc->context.tu.u8CSO,
4787	pDesc->context.tu.u16CSE));
4788	E1K_INC_ISTAT_CNT(pThis->uStatDescCtx);
4789	e1kDescReport(pThis, pDesc, addr);
4790	break;
4791
4792	case E1K_DTYP_DATA:
4793	{
4794	if (pDesc->data.cmd.u20DTALEN == 0 \|\| pDesc->data.u64BufAddr == 0)
4795	{
4796	E1kLog2(("% Empty data descriptor, skipped.\n", pThis->szPrf));
4797	/** @todo Same as legacy when !TSE. See below. */
4798	break;
4799	}
4800	STAM_COUNTER_INC(pDesc->data.cmd.fTSE?
4801	&pThis->StatTxDescTSEData:
4802	&pThis->StatTxDescData);
4803	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatTransmit), a);
4804	E1K_INC_ISTAT_CNT(pThis->uStatDescDat);
4805
4806	/*
4807	* The last descriptor of non-TSE packet must contain VLE flag.
4808	* TSE packets have VLE flag in the first descriptor. The later
4809	* case is taken care of a bit later when cbVTag gets assigned.
4810	*
4811	* 1) pDesc->data.cmd.fEOP && !pDesc->data.cmd.fTSE
4812	*/
4813	if (pDesc->data.cmd.fEOP && !pDesc->data.cmd.fTSE)
4814	{
4815	pThis->fVTag = pDesc->data.cmd.fVLE;
4816	pThis->u16VTagTCI = pDesc->data.dw3.u16Special;
4817	}
4818	/*
4819	* First fragment: Allocate new buffer and save the IXSM and TXSM
4820	* packet options as these are only valid in the first fragment.
4821	*/
4822	if (pThis->u16TxPktLen == 0)
4823	{
4824	pThis->fIPcsum = pDesc->data.dw3.fIXSM;
4825	pThis->fTCPcsum = pDesc->data.dw3.fTXSM;
4826	E1kLog2(("%s Saving checksum flags:%s%s; \n", pThis->szPrf,
4827	pThis->fIPcsum ? " IP" : "",
4828	pThis->fTCPcsum ? " TCP/UDP" : ""));
4829	if (pDesc->data.cmd.fTSE)
4830	{
4831	/* 2) pDesc->data.cmd.fTSE && pThis->u16TxPktLen == 0 */
4832	pThis->fVTag = pDesc->data.cmd.fVLE;
4833	pThis->u16VTagTCI = pDesc->data.dw3.u16Special;
4834	cbVTag = pThis->fVTag ? 4 : 0;
4835	}
4836	else if (pDesc->data.cmd.fEOP)
4837	cbVTag = pDesc->data.cmd.fVLE ? 4 : 0;
4838	else
4839	cbVTag = 4;
4840	E1kLog3(("%s About to allocate TX buffer: cbVTag=%u\n", pThis->szPrf, cbVTag));
4841	if (e1kCanDoGso(pThis, &pThis->GsoCtx, &pDesc->data, &pThis->contextTSE))
4842	rc = e1kXmitAllocBuf(pThis, pThisCC, pThis->contextTSE.dw2.u20PAYLEN + pThis->contextTSE.dw3.u8HDRLEN + cbVTag,
4843	true /fExactSize/, true /fGso/);
4844	else if (pDesc->data.cmd.fTSE)
4845	rc = e1kXmitAllocBuf(pThis, pThisCC, , pThis->contextTSE.dw3.u16MSS + pThis->contextTSE.dw3.u8HDRLEN + cbVTag,
4846	pDesc->data.cmd.fTSE /fExactSize/, false /fGso/);
4847	else
4848	rc = e1kXmitAllocBuf(pThis, pThisCC, pDesc->data.cmd.u20DTALEN + cbVTag,
4849	pDesc->data.cmd.fEOP /fExactSize/, false /fGso/);
4850
4851	/**
4852	* @todo: Perhaps it is not that simple for GSO packets! We may
4853	* need to unwind some changes.
4854	*/
4855	if (RT_FAILURE(rc))
4856	{
4857	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
4858	break;
4859	}
4860	/** @todo Is there any way to indicating errors other than collisions? Like
4861	* VERR_NET_DOWN. */
4862	}
4863
4864	/*
4865	* Add the descriptor data to the frame. If the frame is complete,
4866	* transmit it and reset the u16TxPktLen field.
4867	*/
4868	if (e1kXmitIsGsoBuf(pThisCC->CTX_SUFF(pTxSg)))
4869	{
4870	STAM_COUNTER_INC(&pThis->StatTxPathGSO);
4871	bool fRc = e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->data.cmd.u20DTALEN);
4872	if (pDesc->data.cmd.fEOP)
4873	{
4874	if ( fRc
4875	&& pThisCC->CTX_SUFF(pTxSg)
4876	&& pThisCC->CTX_SUFF(pTxSg)->cbUsed == (size_t)pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw2.u20PAYLEN)
4877	{
4878	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
4879	E1K_INC_CNT32(TSCTC);
4880	}
4881	else
4882	{
4883	if (fRc)
4884	E1kLog(("%s bad GSO/TSE %p or %u < %u\n" , pThis->szPrf,
4885	pThisCC->CTX_SUFF(pTxSg), pThisCC->CTX_SUFF(pTxSg) ? pThisCC->CTX_SUFF(pTxSg)->cbUsed : 0,
4886	pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw2.u20PAYLEN));
4887	e1kXmitFreeBuf(pThis);
4888	E1K_INC_CNT32(TSCTFC);
4889	}
4890	pThis->u16TxPktLen = 0;
4891	}
4892	}
4893	else if (!pDesc->data.cmd.fTSE)
4894	{
4895	STAM_COUNTER_INC(&pThis->StatTxPathRegular);
4896	bool fRc = e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->data.cmd.u20DTALEN);
4897	if (pDesc->data.cmd.fEOP)
4898	{
4899	if (fRc && pThisCC->CTX_SUFF(pTxSg))
4900	{
4901	Assert(pThisCC->CTX_SUFF(pTxSg)->cSegs == 1);
4902	if (pThis->fIPcsum)
4903	e1kInsertChecksum(pThis, (uint8_t *)pThisCC->CTX_SUFF(pTxSg)->aSegs[0].pvSeg, pThis->u16TxPktLen,
4904	pThis->contextNormal.ip.u8CSO,
4905	pThis->contextNormal.ip.u8CSS,
4906	pThis->contextNormal.ip.u16CSE);
4907	if (pThis->fTCPcsum)
4908	e1kInsertChecksum(pThis, (uint8_t *)pThisCC->CTX_SUFF(pTxSg)->aSegs[0].pvSeg, pThis->u16TxPktLen,
4909	pThis->contextNormal.tu.u8CSO,
4910	pThis->contextNormal.tu.u8CSS,
4911	pThis->contextNormal.tu.u16CSE);
4912	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
4913	}
4914	else
4915	e1kXmitFreeBuf(pThis);
4916	pThis->u16TxPktLen = 0;
4917	}
4918	}
4919	else
4920	{
4921	STAM_COUNTER_INC(&pThis->StatTxPathFallback);
4922	e1kFallbackAddToFrame(pDevIns, pThis, pDesc, pDesc->data.cmd.u20DTALEN, fOnWorkerThread);
4923	}
4924
4925	e1kDescReport(pThis, pDesc, addr);
4926	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
4927	break;
4928	}
4929
4930	case E1K_DTYP_LEGACY:
4931	if (pDesc->legacy.cmd.u16Length == 0 \|\| pDesc->legacy.u64BufAddr == 0)
4932	{
4933	E1kLog(("%s Empty legacy descriptor, skipped.\n", pThis->szPrf));
4934	/** @todo 3.3.3, Length/Buffer Address: RS set -> write DD when processing. */
4935	break;
4936	}
4937	STAM_COUNTER_INC(&pThis->StatTxDescLegacy);
4938	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatTransmit), a);
4939
4940	/* First fragment: allocate new buffer. */
4941	if (pThis->u16TxPktLen == 0)
4942	{
4943	if (pDesc->legacy.cmd.fEOP)
4944	cbVTag = pDesc->legacy.cmd.fVLE ? 4 : 0;
4945	else
4946	cbVTag = 4;
4947	E1kLog3(("%s About to allocate TX buffer: cbVTag=%u\n", pThis->szPrf, cbVTag));
4948	/** @todo reset status bits? */
4949	rc = e1kXmitAllocBuf(pThis, pThisCC, pDesc->legacy.cmd.u16Length + cbVTag, pDesc->legacy.cmd.fEOP, false /fGso/);
4950	if (RT_FAILURE(rc))
4951	{
4952	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
4953	break;
4954	}
4955
4956	/** @todo Is there any way to indicating errors other than collisions? Like
4957	* VERR_NET_DOWN. */
4958	}
4959
4960	/* Add fragment to frame. */
4961	if (e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->legacy.cmd.u16Length))
4962	{
4963	E1K_INC_ISTAT_CNT(pThis->uStatDescLeg);
4964
4965	/* Last fragment: Transmit and reset the packet storage counter. */
4966	if (pDesc->legacy.cmd.fEOP)
4967	{
4968	pThis->fVTag = pDesc->legacy.cmd.fVLE;
4969	pThis->u16VTagTCI = pDesc->legacy.dw3.u16Special;
4970	/** @todo Offload processing goes here. */
4971	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
4972	pThis->u16TxPktLen = 0;
4973	}
4974	}
4975	/* Last fragment + failure: free the buffer and reset the storage counter. */
4976	else if (pDesc->legacy.cmd.fEOP)
4977	{
4978	e1kXmitFreeBuf(pThis);
4979	pThis->u16TxPktLen = 0;
4980	}
4981
4982	e1kDescReport(pThis, pDesc, addr);
4983	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
4984	break;
4985
4986	default:
4987	E1kLog(("%s ERROR Unsupported transmit descriptor type: 0x%04x\n",
4988	pThis->szPrf, e1kGetDescType(pDesc)));
4989	break;
4990	}
4991
4992	return rc;
4993	}
4994
4995	#else /* E1K_WITH_TXD_CACHE */
4996
4997	/**
4998	* Process Transmit Descriptor.
4999	*
5000	* E1000 supports three types of transmit descriptors:
5001	* - legacy data descriptors of older format (context-less).
5002	* - data the same as legacy but providing new offloading capabilities.
5003	* - context sets up the context for following data descriptors.
5004	*
5005	* @param pDevIns The device instance.
5006	* @param pThis The device state structure.
5007	* @param pThisCC The current context instance data.
5008	* @param pDesc Pointer to descriptor union.
5009	* @param addr Physical address of descriptor in guest memory.
5010	* @param fOnWorkerThread Whether we're on a worker thread or an EMT.
5011	* @param cbPacketSize Size of the packet as previously computed.
5012	* @thread E1000_TX
5013	*/
5014	static int e1kXmitDesc(PPDMDEVINS pDevIns, PE1KSTATE pThis, PE1KSTATECC pThisCC, E1KTXDESC *pDesc,
5015	RTGCPHYS addr, bool fOnWorkerThread)
5016	{
5017	int rc = VINF_SUCCESS;
5018
5019	e1kPrintTDesc(pThis, pDesc, "vvv");
5020
5021	if (pDesc->legacy.dw3.fDD)
5022	{
5023	E1kLog(("%s e1kXmitDesc: skipping bad descriptor ^^^\n", pThis->szPrf));
5024	e1kDescReport(pDevIns, pThis, pDesc, addr);
5025	return VINF_SUCCESS;
5026	}
5027
5028	//#ifdef E1K_USE_TX_TIMERS
5029	if (pThis->fTidEnabled)
5030	PDMDevHlpTimerStop(pDevIns, pThis->hTIDTimer);
5031	//#endif /* E1K_USE_TX_TIMERS */
5032
5033	switch (e1kGetDescType(pDesc))
5034	{
5035	case E1K_DTYP_CONTEXT:
5036	/* The caller have already updated the context */
5037	E1K_INC_ISTAT_CNT(pThis->uStatDescCtx);
5038	e1kDescReport(pDevIns, pThis, pDesc, addr);
5039	break;
5040
5041	case E1K_DTYP_DATA:
5042	{
5043	STAM_COUNTER_INC(pDesc->data.cmd.fTSE?
5044	&pThis->StatTxDescTSEData:
5045	&pThis->StatTxDescData);
5046	E1K_INC_ISTAT_CNT(pThis->uStatDescDat);
5047	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatTransmit), a);
5048	if (pDesc->data.cmd.u20DTALEN == 0 \|\| pDesc->data.u64BufAddr == 0)
5049	{
5050	E1kLog2(("% Empty data descriptor, skipped.\n", pThis->szPrf));
5051	if (pDesc->data.cmd.fEOP)
5052	{
5053	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
5054	pThis->u16TxPktLen = 0;
5055	}
5056	}
5057	else
5058	{
5059	/*
5060	* Add the descriptor data to the frame. If the frame is complete,
5061	* transmit it and reset the u16TxPktLen field.
5062	*/
5063	if (e1kXmitIsGsoBuf(pThisCC->CTX_SUFF(pTxSg)))
5064	{
5065	STAM_COUNTER_INC(&pThis->StatTxPathGSO);
5066	bool fRc = e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->data.cmd.u20DTALEN);
5067	if (pDesc->data.cmd.fEOP)
5068	{
5069	if ( fRc
5070	&& pThisCC->CTX_SUFF(pTxSg)
5071	&& pThisCC->CTX_SUFF(pTxSg)->cbUsed == (size_t)pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw2.u20PAYLEN)
5072	{
5073	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
5074	E1K_INC_CNT32(TSCTC);
5075	}
5076	else
5077	{
5078	if (fRc)
5079	E1kLog(("%s bad GSO/TSE %p or %u < %u\n" , pThis->szPrf,
5080	pThisCC->CTX_SUFF(pTxSg), pThisCC->CTX_SUFF(pTxSg) ? pThisCC->CTX_SUFF(pTxSg)->cbUsed : 0,
5081	pThis->contextTSE.dw3.u8HDRLEN + pThis->contextTSE.dw2.u20PAYLEN));
5082	e1kXmitFreeBuf(pThis, pThisCC);
5083	E1K_INC_CNT32(TSCTFC);
5084	}
5085	pThis->u16TxPktLen = 0;
5086	}
5087	}
5088	else if (!pDesc->data.cmd.fTSE)
5089	{
5090	STAM_COUNTER_INC(&pThis->StatTxPathRegular);
5091	bool fRc = e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->data.cmd.u20DTALEN);
5092	if (pDesc->data.cmd.fEOP)
5093	{
5094	if (fRc && pThisCC->CTX_SUFF(pTxSg))
5095	{
5096	Assert(pThisCC->CTX_SUFF(pTxSg)->cSegs == 1);
5097	if (pThis->fIPcsum)
5098	e1kInsertChecksum(pThis, (uint8_t *)pThisCC->CTX_SUFF(pTxSg)->aSegs[0].pvSeg, pThis->u16TxPktLen,
5099	pThis->contextNormal.ip.u8CSO,
5100	pThis->contextNormal.ip.u8CSS,
5101	pThis->contextNormal.ip.u16CSE);
5102	if (pThis->fTCPcsum)
5103	e1kInsertChecksum(pThis, (uint8_t *)pThisCC->CTX_SUFF(pTxSg)->aSegs[0].pvSeg, pThis->u16TxPktLen,
5104	pThis->contextNormal.tu.u8CSO,
5105	pThis->contextNormal.tu.u8CSS,
5106	pThis->contextNormal.tu.u16CSE);
5107	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
5108	}
5109	else
5110	e1kXmitFreeBuf(pThis, pThisCC);
5111	pThis->u16TxPktLen = 0;
5112	}
5113	}
5114	else
5115	{
5116	STAM_COUNTER_INC(&pThis->StatTxPathFallback);
5117	rc = e1kFallbackAddToFrame(pDevIns, pThis, pDesc, fOnWorkerThread);
5118	}
5119	}
5120	e1kDescReport(pDevIns, pThis, pDesc, addr);
5121	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
5122	break;
5123	}
5124
5125	case E1K_DTYP_LEGACY:
5126	STAM_COUNTER_INC(&pThis->StatTxDescLegacy);
5127	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatTransmit), a);
5128	if (pDesc->legacy.cmd.u16Length == 0 \|\| pDesc->legacy.u64BufAddr == 0)
5129	{
5130	E1kLog(("%s Empty legacy descriptor, skipped.\n", pThis->szPrf));
5131	}
5132	else
5133	{
5134	/* Add fragment to frame. */
5135	if (e1kAddToFrame(pDevIns, pThis, pThisCC, pDesc->data.u64BufAddr, pDesc->legacy.cmd.u16Length))
5136	{
5137	E1K_INC_ISTAT_CNT(pThis->uStatDescLeg);
5138
5139	/* Last fragment: Transmit and reset the packet storage counter. */
5140	if (pDesc->legacy.cmd.fEOP)
5141	{
5142	if (pDesc->legacy.cmd.fIC)
5143	{
5144	e1kInsertChecksum(pThis,
5145	(uint8_t *)pThisCC->CTX_SUFF(pTxSg)->aSegs[0].pvSeg,
5146	pThis->u16TxPktLen,
5147	pDesc->legacy.cmd.u8CSO,
5148	pDesc->legacy.dw3.u8CSS,
5149	0);
5150	}
5151	e1kTransmitFrame(pDevIns, pThis, pThisCC, fOnWorkerThread);
5152	pThis->u16TxPktLen = 0;
5153	}
5154	}
5155	/* Last fragment + failure: free the buffer and reset the storage counter. */
5156	else if (pDesc->legacy.cmd.fEOP)
5157	{
5158	e1kXmitFreeBuf(pThis, pThisCC);
5159	pThis->u16TxPktLen = 0;
5160	}
5161	}
5162	e1kDescReport(pDevIns, pThis, pDesc, addr);
5163	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
5164	break;
5165
5166	default:
5167	E1kLog(("%s ERROR Unsupported transmit descriptor type: 0x%04x\n",
5168	pThis->szPrf, e1kGetDescType(pDesc)));
5169	break;
5170	}
5171
5172	return rc;
5173	}
5174
5175	DECLINLINE(void) e1kUpdateTxContext(PE1KSTATE pThis, E1KTXDESC *pDesc)
5176	{
5177	if (pDesc->context.dw2.fTSE)
5178	{
5179	pThis->contextTSE = pDesc->context;
5180	uint32_t cbMaxSegmentSize = pThis->contextTSE.dw3.u16MSS + pThis->contextTSE.dw3.u8HDRLEN + 4; /VTAG/
5181	if (RT_UNLIKELY(cbMaxSegmentSize > E1K_MAX_TX_PKT_SIZE))
5182	{
5183	pThis->contextTSE.dw3.u16MSS = E1K_MAX_TX_PKT_SIZE - pThis->contextTSE.dw3.u8HDRLEN - 4; /VTAG/
5184	LogRelMax(10, ("%s: Transmit packet is too large: %u > %u(max). Adjusted MSS to %u.\n",
5185	pThis->szPrf, cbMaxSegmentSize, E1K_MAX_TX_PKT_SIZE, pThis->contextTSE.dw3.u16MSS));
5186	}
5187	pThis->u32PayRemain = pThis->contextTSE.dw2.u20PAYLEN;
5188	pThis->u16HdrRemain = pThis->contextTSE.dw3.u8HDRLEN;
5189	e1kSetupGsoCtx(&pThis->GsoCtx, &pThis->contextTSE);
5190	STAM_COUNTER_INC(&pThis->StatTxDescCtxTSE);
5191	}
5192	else
5193	{
5194	pThis->contextNormal = pDesc->context;
5195	STAM_COUNTER_INC(&pThis->StatTxDescCtxNormal);
5196	}
5197	E1kLog2(("%s %s context updated: IP CSS=%02X, IP CSO=%02X, IP CSE=%04X"
5198	", TU CSS=%02X, TU CSO=%02X, TU CSE=%04X\n", pThis->szPrf,
5199	pDesc->context.dw2.fTSE ? "TSE" : "Normal",
5200	pDesc->context.ip.u8CSS,
5201	pDesc->context.ip.u8CSO,
5202	pDesc->context.ip.u16CSE,
5203	pDesc->context.tu.u8CSS,
5204	pDesc->context.tu.u8CSO,
5205	pDesc->context.tu.u16CSE));
5206	}
5207
5208	static bool e1kLocateTxPacket(PE1KSTATE pThis)
5209	{
5210	LogFlow(("%s e1kLocateTxPacket: ENTER cbTxAlloc=%d\n",
5211	pThis->szPrf, pThis->cbTxAlloc));
5212	/* Check if we have located the packet already. */
5213	if (pThis->cbTxAlloc)
5214	{
5215	LogFlow(("%s e1kLocateTxPacket: RET true cbTxAlloc=%d\n",
5216	pThis->szPrf, pThis->cbTxAlloc));
5217	return true;
5218	}
5219
5220	bool fTSE = false;
5221	uint32_t cbPacket = 0;
5222
5223	for (int i = pThis->iTxDCurrent; i < pThis->nTxDFetched; ++i)
5224	{
5225	E1KTXDESC *pDesc = &pThis->aTxDescriptors[i];
5226	switch (e1kGetDescType(pDesc))
5227	{
5228	case E1K_DTYP_CONTEXT:
5229	if (cbPacket == 0)
5230	e1kUpdateTxContext(pThis, pDesc);
5231	else
5232	E1kLog(("%s e1kLocateTxPacket: ignoring a context descriptor in the middle of a packet, cbPacket=%d\n",
5233	pThis->szPrf, cbPacket));
5234	continue;
5235	case E1K_DTYP_LEGACY:
5236	/* Skip invalid descriptors. */
5237	if (cbPacket > 0 && (pThis->fGSO \|\| fTSE))
5238	{
5239	E1kLog(("%s e1kLocateTxPacket: ignoring a legacy descriptor in the segmentation context, cbPacket=%d\n",
5240	pThis->szPrf, cbPacket));
5241	pDesc->legacy.dw3.fDD = true; /* Make sure it is skipped by processing */
5242	continue;
5243	}
5244	/* Skip empty descriptors. */
5245	if (!pDesc->legacy.u64BufAddr \|\| !pDesc->legacy.cmd.u16Length)
5246	break;
5247	cbPacket += pDesc->legacy.cmd.u16Length;
5248	pThis->fGSO = false;
5249	break;
5250	case E1K_DTYP_DATA:
5251	/* Skip invalid descriptors. */
5252	if (cbPacket > 0 && (bool)pDesc->data.cmd.fTSE != fTSE)
5253	{
5254	E1kLog(("%s e1kLocateTxPacket: ignoring %sTSE descriptor in the %ssegmentation context, cbPacket=%d\n",
5255	pThis->szPrf, pDesc->data.cmd.fTSE ? "" : "non-", fTSE ? "" : "non-", cbPacket));
5256	pDesc->data.dw3.fDD = true; /* Make sure it is skipped by processing */
5257	continue;
5258	}
5259	/* Skip empty descriptors. */
5260	if (!pDesc->data.u64BufAddr \|\| !pDesc->data.cmd.u20DTALEN)
5261	break;
5262	if (cbPacket == 0)
5263	{
5264	/*
5265	* The first fragment: save IXSM and TXSM options
5266	* as these are only valid in the first fragment.
5267	*/
5268	pThis->fIPcsum = pDesc->data.dw3.fIXSM;
5269	pThis->fTCPcsum = pDesc->data.dw3.fTXSM;
5270	fTSE = pDesc->data.cmd.fTSE;
5271	/*
5272	* TSE descriptors have VLE bit properly set in
5273	* the first fragment.
5274	*/
5275	if (fTSE)
5276	{
5277	pThis->fVTag = pDesc->data.cmd.fVLE;
5278	pThis->u16VTagTCI = pDesc->data.dw3.u16Special;
5279	}
5280	pThis->fGSO = e1kCanDoGso(pThis, &pThis->GsoCtx, &pDesc->data, &pThis->contextTSE);
5281	}
5282	cbPacket += pDesc->data.cmd.u20DTALEN;
5283	break;
5284	default:
5285	AssertMsgFailed(("Impossible descriptor type!"));
5286	continue;
5287	}
5288	if (pDesc->legacy.cmd.fEOP)
5289	{
5290	/*
5291	* Non-TSE descriptors have VLE bit properly set in
5292	* the last fragment.
5293	*/
5294	if (!fTSE)
5295	{
5296	pThis->fVTag = pDesc->data.cmd.fVLE;
5297	pThis->u16VTagTCI = pDesc->data.dw3.u16Special;
5298	}
5299	/*
5300	* Compute the required buffer size. If we cannot do GSO but still
5301	* have to do segmentation we allocate the first segment only.
5302	*/
5303	pThis->cbTxAlloc = (!fTSE \|\| pThis->fGSO) ?
5304	cbPacket :
5305	RT_MIN(cbPacket, pThis->contextTSE.dw3.u16MSS + pThis->contextTSE.dw3.u8HDRLEN);
5306	/* Do not add VLAN tags to empty packets. */
5307	if (pThis->fVTag && pThis->cbTxAlloc > 0)
5308	pThis->cbTxAlloc += 4;
5309	LogFlow(("%s e1kLocateTxPacket: RET true cbTxAlloc=%d cbPacket=%d%s%s\n",
5310	pThis->szPrf, pThis->cbTxAlloc, cbPacket,
5311	pThis->fGSO ? " GSO" : "", fTSE ? " TSE" : ""));
5312	return true;
5313	}
5314	}
5315
5316	if (cbPacket == 0 && pThis->nTxDFetched - pThis->iTxDCurrent > 0)
5317	{
5318	/* All descriptors were empty, we need to process them as a dummy packet */
5319	LogFlow(("%s e1kLocateTxPacket: RET true cbTxAlloc=%d, zero packet!\n",
5320	pThis->szPrf, pThis->cbTxAlloc));
5321	return true;
5322	}
5323	LogFlow(("%s e1kLocateTxPacket: RET false cbTxAlloc=%d cbPacket=%d\n",
5324	pThis->szPrf, pThis->cbTxAlloc, cbPacket));
5325	return false;
5326	}
5327
5328	static int e1kXmitPacket(PPDMDEVINS pDevIns, PE1KSTATE pThis, bool fOnWorkerThread)
5329	{
5330	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
5331	int rc = VINF_SUCCESS;
5332
5333	LogFlow(("%s e1kXmitPacket: ENTER current=%d fetched=%d\n",
5334	pThis->szPrf, pThis->iTxDCurrent, pThis->nTxDFetched));
5335
5336	while (pThis->iTxDCurrent < pThis->nTxDFetched)
5337	{
5338	E1KTXDESC *pDesc = &pThis->aTxDescriptors[pThis->iTxDCurrent];
5339	E1kLog3(("%s About to process new TX descriptor at %08x%08x, TDLEN=%08x, TDH=%08x, TDT=%08x\n",
5340	pThis->szPrf, TDBAH, TDBAL + TDH * sizeof(E1KTXDESC), TDLEN, TDH, TDT));
5341	rc = e1kXmitDesc(pDevIns, pThis, pThisCC, pDesc, e1kDescAddr(TDBAH, TDBAL, TDH), fOnWorkerThread);
5342	if (RT_FAILURE(rc))
5343	break;
5344	if (++TDH * sizeof(E1KTXDESC) >= TDLEN)
5345	TDH = 0;
5346	uint32_t uLowThreshold = GET_BITS(TXDCTL, LWTHRESH)*8;
5347	if (uLowThreshold != 0 && e1kGetTxLen(pThis) <= uLowThreshold)
5348	{
5349	E1kLog2(("%s Low on transmit descriptors, raise ICR.TXD_LOW, len=%x thresh=%x\n",
5350	pThis->szPrf, e1kGetTxLen(pThis), GET_BITS(TXDCTL, LWTHRESH)*8));
5351	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_TXD_LOW);
5352	}
5353	++pThis->iTxDCurrent;
5354	if (e1kGetDescType(pDesc) != E1K_DTYP_CONTEXT && pDesc->legacy.cmd.fEOP)
5355	break;
5356	}
5357
5358	LogFlow(("%s e1kXmitPacket: RET %Rrc current=%d fetched=%d\n",
5359	pThis->szPrf, rc, pThis->iTxDCurrent, pThis->nTxDFetched));
5360	return rc;
5361	}
5362
5363	#endif /* E1K_WITH_TXD_CACHE */
5364	#ifndef E1K_WITH_TXD_CACHE
5365
5366	/**
5367	* Transmit pending descriptors.
5368	*
5369	* @returns VBox status code. VERR_TRY_AGAIN is returned if we're busy.
5370	*
5371	* @param pDevIns The device instance.
5372	* @param pThis The E1000 state.
5373	* @param fOnWorkerThread Whether we're on a worker thread or on an EMT.
5374	*/
5375	static int e1kXmitPending(PPDMDEVINS pDevIns, PE1KSTATE pThis, bool fOnWorkerThread)
5376	{
5377	int rc = VINF_SUCCESS;
5378	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
5379
5380	/* Check if transmitter is enabled. */
5381	if (!(TCTL & TCTL_EN))
5382	return VINF_SUCCESS;
5383	/*
5384	* Grab the xmit lock of the driver as well as the E1K device state.
5385	*/
5386	rc = e1kCsTxEnter(pThis, VERR_SEM_BUSY);
5387	if (RT_LIKELY(rc == VINF_SUCCESS))
5388	{
5389	PPDMINETWORKUP pDrv = pThis->CTX_SUFF(pDrv);
5390	if (pDrv)
5391	{
5392	rc = pDrv->pfnBeginXmit(pDrv, fOnWorkerThread);
5393	if (RT_FAILURE(rc))
5394	{
5395	e1kCsTxLeave(pThis);
5396	return rc;
5397	}
5398	}
5399	/*
5400	* Process all pending descriptors.
5401	* Note! Do not process descriptors in locked state
5402	*/
5403	while (TDH != TDT && !pThis->fLocked)
5404	{
5405	E1KTXDESC desc;
5406	E1kLog3(("%s About to process new TX descriptor at %08x%08x, TDLEN=%08x, TDH=%08x, TDT=%08x\n",
5407	pThis->szPrf, TDBAH, TDBAL + TDH * sizeof(desc), TDLEN, TDH, TDT));
5408
5409	e1kLoadDesc(pDevIns, &desc, ((uint64_t)TDBAH << 32) + TDBAL + TDH * sizeof(desc));
5410	rc = e1kXmitDesc(pDevIns, pThis, pThisCC, &desc, e1kDescAddr(TDBAH, TDBAL, TDH), fOnWorkerThread);
5411	/* If we failed to transmit descriptor we will try it again later */
5412	if (RT_FAILURE(rc))
5413	break;
5414	if (++TDH * sizeof(desc) >= TDLEN)
5415	TDH = 0;
5416
5417	if (e1kGetTxLen(pThis) <= GET_BITS(TXDCTL, LWTHRESH)*8)
5418	{
5419	E1kLog2(("%s Low on transmit descriptors, raise ICR.TXD_LOW, len=%x thresh=%x\n",
5420	pThis->szPrf, e1kGetTxLen(pThis), GET_BITS(TXDCTL, LWTHRESH)*8));
5421	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_TXD_LOW);
5422	}
5423
5424	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
5425	}
5426
5427	/// @todo uncomment: pThis->uStatIntTXQE++;
5428	/// @todo uncomment: e1kRaiseInterrupt(pDevIns, pThis, ICR_TXQE);
5429	/*
5430	* Release the lock.
5431	*/
5432	if (pDrv)
5433	pDrv->pfnEndXmit(pDrv);
5434	e1kCsTxLeave(pThis);
5435	}
5436
5437	return rc;
5438	}
5439
5440	#else /* E1K_WITH_TXD_CACHE */
5441
5442	static void e1kDumpTxDCache(PPDMDEVINS pDevIns, PE1KSTATE pThis)
5443	{
5444	unsigned i, cDescs = TDLEN / sizeof(E1KTXDESC);
5445	uint32_t tdh = TDH;
5446	LogRel(("E1000: -- Transmit Descriptors (%d total) --\n", cDescs));
5447	for (i = 0; i < cDescs; ++i)
5448	{
5449	E1KTXDESC desc;
5450	PDMDevHlpPhysRead(pDevIns , e1kDescAddr(TDBAH, TDBAL, i), &desc, sizeof(desc));
5451	if (i == tdh)
5452	LogRel(("E1000: >>> "));
5453	LogRel(("E1000: %RGp: %R[e1ktxd]\n", e1kDescAddr(TDBAH, TDBAL, i), &desc));
5454	}
5455	LogRel(("E1000: -- Transmit Descriptors in Cache (at %d (TDH %d)/ fetched %d / max %d) --\n",
5456	pThis->iTxDCurrent, TDH, pThis->nTxDFetched, E1K_TXD_CACHE_SIZE));
5457	if (tdh > pThis->iTxDCurrent)
5458	tdh -= pThis->iTxDCurrent;
5459	else
5460	tdh = cDescs + tdh - pThis->iTxDCurrent;
5461	for (i = 0; i < pThis->nTxDFetched; ++i)
5462	{
5463	if (i == pThis->iTxDCurrent)
5464	LogRel(("E1000: >>> "));
5465	LogRel(("E1000: %RGp: %R[e1ktxd]\n", e1kDescAddr(TDBAH, TDBAL, tdh++ % cDescs), &pThis->aTxDescriptors[i]));
5466	}
5467	}
5468
5469	/**
5470	* Transmit pending descriptors.
5471	*
5472	* @returns VBox status code. VERR_TRY_AGAIN is returned if we're busy.
5473	*
5474	* @param pDevIns The device instance.
5475	* @param pThis The E1000 state.
5476	* @param fOnWorkerThread Whether we're on a worker thread or on an EMT.
5477	*/
5478	static int e1kXmitPending(PPDMDEVINS pDevIns, PE1KSTATE pThis, bool fOnWorkerThread)
5479	{
5480	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
5481	int rc = VINF_SUCCESS;
5482
5483	/* Check if transmitter is enabled. */
5484	if (!(TCTL & TCTL_EN))
5485	return VINF_SUCCESS;
5486	/*
5487	* Grab the xmit lock of the driver as well as the E1K device state.
5488	*/
5489	PPDMINETWORKUP pDrv = pThisCC->CTX_SUFF(pDrv);
5490	if (pDrv)
5491	{
5492	rc = pDrv->pfnBeginXmit(pDrv, fOnWorkerThread);
5493	if (RT_FAILURE(rc))
5494	return rc;
5495	}
5496
5497	/*
5498	* Process all pending descriptors.
5499	* Note! Do not process descriptors in locked state
5500	*/
5501	rc = e1kCsTxEnter(pThis, VERR_SEM_BUSY);
5502	if (RT_LIKELY(rc == VINF_SUCCESS))
5503	{
5504	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatTransmit), a);
5505	/*
5506	* fIncomplete is set whenever we try to fetch additional descriptors
5507	* for an incomplete packet. If fail to locate a complete packet on
5508	* the next iteration we need to reset the cache or we risk to get
5509	* stuck in this loop forever.
5510	*/
5511	bool fIncomplete = false;
5512	while (!pThis->fLocked && e1kTxDLazyLoad(pDevIns, pThis))
5513	{
5514	while (e1kLocateTxPacket(pThis))
5515	{
5516	fIncomplete = false;
5517	/* Found a complete packet, allocate it. */
5518	rc = e1kXmitAllocBuf(pThis, pThisCC, pThis->fGSO);
5519	/* If we're out of bandwidth we'll come back later. */
5520	if (RT_FAILURE(rc))
5521	goto out;
5522	/* Copy the packet to allocated buffer and send it. */
5523	rc = e1kXmitPacket(pDevIns, pThis, fOnWorkerThread);
5524	/* If we're out of bandwidth we'll come back later. */
5525	if (RT_FAILURE(rc))
5526	goto out;
5527	}
5528	uint8_t u8Remain = pThis->nTxDFetched - pThis->iTxDCurrent;
5529	if (RT_UNLIKELY(fIncomplete))
5530	{
5531	static bool fTxDCacheDumped = false;
5532	/*
5533	* The descriptor cache is full, but we were unable to find
5534	* a complete packet in it. Drop the cache and hope that
5535	* the guest driver can recover from network card error.
5536	*/
5537	LogRel(("%s: No complete packets in%s TxD cache! "
5538	"Fetched=%d, current=%d, TX len=%d.\n",
5539	pThis->szPrf,
5540	u8Remain == E1K_TXD_CACHE_SIZE ? " full" : "",
5541	pThis->nTxDFetched, pThis->iTxDCurrent,
5542	e1kGetTxLen(pThis)));
5543	if (!fTxDCacheDumped)
5544	{
5545	fTxDCacheDumped = true;
5546	e1kDumpTxDCache(pDevIns, pThis);
5547	}
5548	pThis->iTxDCurrent = pThis->nTxDFetched = 0;
5549	/*
5550	* Returning an error at this point means Guru in R0
5551	* (see @bugref{6428}).
5552	*/
5553	# ifdef IN_RING3
5554	rc = VERR_NET_INCOMPLETE_TX_PACKET;
5555	# else /* !IN_RING3 */
5556	rc = VINF_IOM_R3_MMIO_WRITE;
5557	# endif /* !IN_RING3 */
5558	goto out;
5559	}
5560	if (u8Remain > 0)
5561	{
5562	Log4(("%s Incomplete packet at %d. Already fetched %d, "
5563	"%d more are available\n",
5564	pThis->szPrf, pThis->iTxDCurrent, u8Remain,
5565	e1kGetTxLen(pThis) - u8Remain));
5566
5567	/*
5568	* A packet was partially fetched. Move incomplete packet to
5569	* the beginning of cache buffer, then load more descriptors.
5570	*/
5571	memmove(pThis->aTxDescriptors,
5572	&pThis->aTxDescriptors[pThis->iTxDCurrent],
5573	u8Remain * sizeof(E1KTXDESC));
5574	pThis->iTxDCurrent = 0;
5575	pThis->nTxDFetched = u8Remain;
5576	e1kTxDLoadMore(pDevIns, pThis);
5577	fIncomplete = true;
5578	}
5579	else
5580	pThis->nTxDFetched = 0;
5581	pThis->iTxDCurrent = 0;
5582	}
5583	if (!pThis->fLocked && GET_BITS(TXDCTL, LWTHRESH) == 0)
5584	{
5585	E1kLog2(("%s Out of transmit descriptors, raise ICR.TXD_LOW\n",
5586	pThis->szPrf));
5587	e1kRaiseInterrupt(pDevIns, pThis, VERR_SEM_BUSY, ICR_TXD_LOW);
5588	}
5589	out:
5590	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatTransmit), a);
5591
5592	/// @todo uncomment: pThis->uStatIntTXQE++;
5593	/// @todo uncomment: e1kRaiseInterrupt(pDevIns, pThis, ICR_TXQE);
5594
5595	e1kCsTxLeave(pThis);
5596	}
5597
5598
5599	/*
5600	* Release the lock.
5601	*/
5602	if (pDrv)
5603	pDrv->pfnEndXmit(pDrv);
5604	return rc;
5605	}
5606
5607	#endif /* E1K_WITH_TXD_CACHE */
5608	#ifdef IN_RING3
5609
5610	/**
5611	* @interface_method_impl{PDMINETWORKDOWN,pfnXmitPending}
5612	*/
5613	static DECLCALLBACK(void) e1kR3NetworkDown_XmitPending(PPDMINETWORKDOWN pInterface)
5614	{
5615	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkDown);
5616	PE1KSTATE pThis = pThisCC->pShared;
5617	/* Resume suspended transmission */
5618	STATUS &= ~STATUS_TXOFF;
5619	e1kXmitPending(pThisCC->pDevInsR3, pThis, true /fOnWorkerThread/);
5620	}
5621
5622	/**
5623	* @callback_method_impl{FNPDMTASKDEV,
5624	* Executes e1kXmitPending at the behest of ring-0/raw-mode.}
5625	* @note Not executed on EMT.
5626	*/
5627	static DECLCALLBACK(void) e1kR3TxTaskCallback(PPDMDEVINS pDevIns, void *pvUser)
5628	{
5629	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
5630	E1kLog2(("%s e1kR3TxTaskCallback:\n", pThis->szPrf));
5631
5632	int rc = e1kXmitPending(pDevIns, pThis, false /fOnWorkerThread/);
5633	AssertMsg(RT_SUCCESS(rc) \|\| rc == VERR_TRY_AGAIN \|\| rc == VERR_NET_DOWN, ("%Rrc\n", rc));
5634
5635	RT_NOREF(rc, pvUser);
5636	}
5637
5638	#endif /* IN_RING3 */
5639
5640	/**
5641	* Write handler for Transmit Descriptor Tail register.
5642	*
5643	* @param pThis The device state structure.
5644	* @param offset Register offset in memory-mapped frame.
5645	* @param index Register index in register array.
5646	* @param value The value to store.
5647	* @param mask Used to implement partial writes (8 and 16-bit).
5648	* @thread EMT
5649	*/
5650	static int e1kRegWriteTDT(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5651	{
5652	int rc = e1kRegWriteDefault(pDevIns, pThis, offset, index, value);
5653
5654	/* All descriptors starting with head and not including tail belong to us. */
5655	/* Process them. */
5656	E1kLog2(("%s e1kRegWriteTDT: TDBAL=%08x, TDBAH=%08x, TDLEN=%08x, TDH=%08x, TDT=%08x\n",
5657	pThis->szPrf, TDBAL, TDBAH, TDLEN, TDH, TDT));
5658
5659	/* Ignore TDT writes when the link is down. */
5660	if (TDH != TDT && (STATUS & STATUS_LU))
5661	{
5662	Log5(("E1000: TDT write: TDH=%08x, TDT=%08x, %d descriptors to process\n", TDH, TDT, e1kGetTxLen(pThis)));
5663	E1kLog(("%s e1kRegWriteTDT: %d descriptors to process\n",
5664	pThis->szPrf, e1kGetTxLen(pThis)));
5665
5666	/* Transmit pending packets if possible, defer it if we cannot do it
5667	in the current context. */
5668	#ifdef E1K_TX_DELAY
5669	rc = e1kCsTxEnter(pThis, VERR_SEM_BUSY);
5670	if (RT_LIKELY(rc == VINF_SUCCESS))
5671	{
5672	if (!PDMDevInsTimerIsActive(pDevIns, pThis->hTXDTimer))
5673	{
5674	# ifdef E1K_INT_STATS
5675	pThis->u64ArmedAt = RTTimeNanoTS();
5676	# endif
5677	e1kArmTimer(pDevIns, pThis, pThis->hTXDTimer, E1K_TX_DELAY);
5678	}
5679	E1K_INC_ISTAT_CNT(pThis->uStatTxDelayed);
5680	e1kCsTxLeave(pThis);
5681	return rc;
5682	}
5683	/* We failed to enter the TX critical section -- transmit as usual. */
5684	#endif /* E1K_TX_DELAY */
5685	#ifndef IN_RING3
5686	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
5687	if (!pThisCC->CTX_SUFF(pDrv))
5688	{
5689	PDMDevHlpTaskTrigger(pDevIns, pThis->hTxTask);
5690	rc = VINF_SUCCESS;
5691	}
5692	else
5693	#endif
5694	{
5695	rc = e1kXmitPending(pDevIns, pThis, false /fOnWorkerThread/);
5696	if (rc == VERR_TRY_AGAIN)
5697	rc = VINF_SUCCESS;
5698	#ifndef IN_RING3
5699	else if (rc == VERR_SEM_BUSY)
5700	rc = VINF_IOM_R3_MMIO_WRITE;
5701	#endif
5702	AssertRC(rc);
5703	}
5704	}
5705
5706	return rc;
5707	}
5708
5709	/**
5710	* Write handler for Multicast Table Array registers.
5711	*
5712	* @param pThis The device state structure.
5713	* @param offset Register offset in memory-mapped frame.
5714	* @param index Register index in register array.
5715	* @param value The value to store.
5716	* @thread EMT
5717	*/
5718	static int e1kRegWriteMTA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5719	{
5720	RT_NOREF_PV(pDevIns);
5721	AssertReturn(offset - g_aE1kRegMap[index].offset < sizeof(pThis->auMTA), VERR_DEV_IO_ERROR);
5722	pThis->auMTA[(offset - g_aE1kRegMap[index].offset) / sizeof(pThis->auMTA[0])] = value;
5723
5724	return VINF_SUCCESS;
5725	}
5726
5727	/**
5728	* Read handler for Multicast Table Array registers.
5729	*
5730	* @returns VBox status code.
5731	*
5732	* @param pThis The device state structure.
5733	* @param offset Register offset in memory-mapped frame.
5734	* @param index Register index in register array.
5735	* @thread EMT
5736	*/
5737	static int e1kRegReadMTA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5738	{
5739	RT_NOREF_PV(pDevIns);
5740	AssertReturn(offset - g_aE1kRegMap[index].offset < sizeof(pThis->auMTA), VERR_DEV_IO_ERROR);
5741	*pu32Value = pThis->auMTA[(offset - g_aE1kRegMap[index].offset)/sizeof(pThis->auMTA[0])];
5742
5743	return VINF_SUCCESS;
5744	}
5745
5746	/**
5747	* Write handler for Receive Address registers.
5748	*
5749	* @param pThis The device state structure.
5750	* @param offset Register offset in memory-mapped frame.
5751	* @param index Register index in register array.
5752	* @param value The value to store.
5753	* @thread EMT
5754	*/
5755	static int e1kRegWriteRA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5756	{
5757	RT_NOREF_PV(pDevIns);
5758	AssertReturn(offset - g_aE1kRegMap[index].offset < sizeof(pThis->aRecAddr.au32), VERR_DEV_IO_ERROR);
5759	pThis->aRecAddr.au32[(offset - g_aE1kRegMap[index].offset)/sizeof(pThis->aRecAddr.au32[0])] = value;
5760
5761	return VINF_SUCCESS;
5762	}
5763
5764	/**
5765	* Read handler for Receive Address registers.
5766	*
5767	* @returns VBox status code.
5768	*
5769	* @param pThis The device state structure.
5770	* @param offset Register offset in memory-mapped frame.
5771	* @param index Register index in register array.
5772	* @thread EMT
5773	*/
5774	static int e1kRegReadRA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5775	{
5776	RT_NOREF_PV(pDevIns);
5777	AssertReturn(offset - g_aE1kRegMap[index].offset< sizeof(pThis->aRecAddr.au32), VERR_DEV_IO_ERROR);
5778	*pu32Value = pThis->aRecAddr.au32[(offset - g_aE1kRegMap[index].offset)/sizeof(pThis->aRecAddr.au32[0])];
5779
5780	return VINF_SUCCESS;
5781	}
5782
5783	/**
5784	* Write handler for VLAN Filter Table Array registers.
5785	*
5786	* @param pThis The device state structure.
5787	* @param offset Register offset in memory-mapped frame.
5788	* @param index Register index in register array.
5789	* @param value The value to store.
5790	* @thread EMT
5791	*/
5792	static int e1kRegWriteVFTA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5793	{
5794	RT_NOREF_PV(pDevIns);
5795	AssertReturn(offset - g_aE1kRegMap[index].offset < sizeof(pThis->auVFTA), VINF_SUCCESS);
5796	pThis->auVFTA[(offset - g_aE1kRegMap[index].offset)/sizeof(pThis->auVFTA[0])] = value;
5797
5798	return VINF_SUCCESS;
5799	}
5800
5801	/**
5802	* Read handler for VLAN Filter Table Array registers.
5803	*
5804	* @returns VBox status code.
5805	*
5806	* @param pThis The device state structure.
5807	* @param offset Register offset in memory-mapped frame.
5808	* @param index Register index in register array.
5809	* @thread EMT
5810	*/
5811	static int e1kRegReadVFTA(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5812	{
5813	RT_NOREF_PV(pDevIns);
5814	AssertReturn(offset - g_aE1kRegMap[index].offset< sizeof(pThis->auVFTA), VERR_DEV_IO_ERROR);
5815	*pu32Value = pThis->auVFTA[(offset - g_aE1kRegMap[index].offset)/sizeof(pThis->auVFTA[0])];
5816
5817	return VINF_SUCCESS;
5818	}
5819
5820	/**
5821	* Read handler for unimplemented registers.
5822	*
5823	* Merely reports reads from unimplemented registers.
5824	*
5825	* @returns VBox status code.
5826	*
5827	* @param pThis The device state structure.
5828	* @param offset Register offset in memory-mapped frame.
5829	* @param index Register index in register array.
5830	* @thread EMT
5831	*/
5832	static int e1kRegReadUnimplemented(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5833	{
5834	RT_NOREF(pDevIns, pThis, offset, index);
5835	E1kLog(("%s At %08X read (00000000) attempt from unimplemented register %s (%s)\n",
5836	pThis->szPrf, offset, g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
5837	*pu32Value = 0;
5838
5839	return VINF_SUCCESS;
5840	}
5841
5842	/**
5843	* Default register read handler with automatic clear operation.
5844	*
5845	* Retrieves the value of register from register array in device state structure.
5846	* Then resets all bits.
5847	*
5848	* @remarks The 'mask' parameter is simply ignored as masking and shifting is
5849	* done in the caller.
5850	*
5851	* @returns VBox status code.
5852	*
5853	* @param pThis The device state structure.
5854	* @param offset Register offset in memory-mapped frame.
5855	* @param index Register index in register array.
5856	* @thread EMT
5857	*/
5858	static int e1kRegReadAutoClear(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5859	{
5860	AssertReturn(index < E1K_NUM_OF_32BIT_REGS, VERR_DEV_IO_ERROR);
5861	int rc = e1kRegReadDefault(pDevIns, pThis, offset, index, pu32Value);
5862	pThis->auRegs[index] = 0;
5863
5864	return rc;
5865	}
5866
5867	/**
5868	* Default register read handler.
5869	*
5870	* Retrieves the value of register from register array in device state structure.
5871	* Bits corresponding to 0s in 'readable' mask will always read as 0s.
5872	*
5873	* @remarks The 'mask' parameter is simply ignored as masking and shifting is
5874	* done in the caller.
5875	*
5876	* @returns VBox status code.
5877	*
5878	* @param pThis The device state structure.
5879	* @param offset Register offset in memory-mapped frame.
5880	* @param index Register index in register array.
5881	* @thread EMT
5882	*/
5883	static int e1kRegReadDefault(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t *pu32Value)
5884	{
5885	RT_NOREF_PV(pDevIns); RT_NOREF_PV(offset);
5886
5887	AssertReturn(index < E1K_NUM_OF_32BIT_REGS, VERR_DEV_IO_ERROR);
5888	*pu32Value = pThis->auRegs[index] & g_aE1kRegMap[index].readable;
5889
5890	return VINF_SUCCESS;
5891	}
5892
5893	/**
5894	* Write handler for unimplemented registers.
5895	*
5896	* Merely reports writes to unimplemented registers.
5897	*
5898	* @param pThis The device state structure.
5899	* @param offset Register offset in memory-mapped frame.
5900	* @param index Register index in register array.
5901	* @param value The value to store.
5902	* @thread EMT
5903	*/
5904
5905	static int e1kRegWriteUnimplemented(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5906	{
5907	RT_NOREF_PV(pDevIns); RT_NOREF_PV(pThis); RT_NOREF_PV(offset); RT_NOREF_PV(index); RT_NOREF_PV(value);
5908
5909	E1kLog(("%s At %08X write attempt (%08X) to unimplemented register %s (%s)\n",
5910	pThis->szPrf, offset, value, g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
5911
5912	return VINF_SUCCESS;
5913	}
5914
5915	/**
5916	* Default register write handler.
5917	*
5918	* Stores the value to the register array in device state structure. Only bits
5919	* corresponding to 1s both in 'writable' and 'mask' will be stored.
5920	*
5921	* @returns VBox status code.
5922	*
5923	* @param pThis The device state structure.
5924	* @param offset Register offset in memory-mapped frame.
5925	* @param index Register index in register array.
5926	* @param value The value to store.
5927	* @param mask Used to implement partial writes (8 and 16-bit).
5928	* @thread EMT
5929	*/
5930
5931	static int e1kRegWriteDefault(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offset, uint32_t index, uint32_t value)
5932	{
5933	RT_NOREF(pDevIns, offset);
5934
5935	AssertReturn(index < E1K_NUM_OF_32BIT_REGS, VERR_DEV_IO_ERROR);
5936	pThis->auRegs[index] = (value & g_aE1kRegMap[index].writable)
5937	\| (pThis->auRegs[index] & ~g_aE1kRegMap[index].writable);
5938
5939	return VINF_SUCCESS;
5940	}
5941
5942	/**
5943	* Search register table for matching register.
5944	*
5945	* @returns Index in the register table or -1 if not found.
5946	*
5947	* @param offReg Register offset in memory-mapped region.
5948	* @thread EMT
5949	*/
5950	static int e1kRegLookup(uint32_t offReg)
5951	{
5952
5953	#if 0
5954	int index;
5955
5956	for (index = 0; index < E1K_NUM_OF_REGS; index++)
5957	{
5958	if (g_aE1kRegMap[index].offset <= offReg && offReg < g_aE1kRegMap[index].offset + g_aE1kRegMap[index].size)
5959	{
5960	return index;
5961	}
5962	}
5963	#else
5964	int iStart = 0;
5965	int iEnd = E1K_NUM_OF_BINARY_SEARCHABLE;
5966	for (;;)
5967	{
5968	int i = (iEnd - iStart) / 2 + iStart;
5969	uint32_t offCur = g_aE1kRegMap[i].offset;
5970	if (offReg < offCur)
5971	{
5972	if (i == iStart)
5973	break;
5974	iEnd = i;
5975	}
5976	else if (offReg >= offCur + g_aE1kRegMap[i].size)
5977	{
5978	i++;
5979	if (i == iEnd)
5980	break;
5981	iStart = i;
5982	}
5983	else
5984	return i;
5985	Assert(iEnd > iStart);
5986	}
5987
5988	for (unsigned i = E1K_NUM_OF_BINARY_SEARCHABLE; i < RT_ELEMENTS(g_aE1kRegMap); i++)
5989	if (offReg - g_aE1kRegMap[i].offset < g_aE1kRegMap[i].size)
5990	return (int)i;
5991
5992	# ifdef VBOX_STRICT
5993	for (unsigned i = 0; i < RT_ELEMENTS(g_aE1kRegMap); i++)
5994	Assert(offReg - g_aE1kRegMap[i].offset >= g_aE1kRegMap[i].size);
5995	# endif
5996
5997	#endif
5998
5999	return -1;
6000	}
6001
6002	/**
6003	* Handle unaligned register read operation.
6004	*
6005	* Looks up and calls appropriate handler.
6006	*
6007	* @returns VBox status code.
6008	*
6009	* @param pDevIns The device instance.
6010	* @param pThis The device state structure.
6011	* @param offReg Register offset in memory-mapped frame.
6012	* @param pv Where to store the result.
6013	* @param cb Number of bytes to read.
6014	* @thread EMT
6015	* @remarks IOM takes care of unaligned and small reads via MMIO. For I/O port
6016	* accesses we have to take care of that ourselves.
6017	*/
6018	static int e1kRegReadUnaligned(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offReg, void *pv, uint32_t cb)
6019	{
6020	uint32_t u32 = 0;
6021	uint32_t shift;
6022	int rc = VINF_SUCCESS;
6023	int index = e1kRegLookup(offReg);
6024	#ifdef LOG_ENABLED
6025	char buf[9];
6026	#endif
6027
6028	/*
6029	* From the spec:
6030	* For registers that should be accessed as 32-bit double words, partial writes (less than a 32-bit
6031	* double word) is ignored. Partial reads return all 32 bits of data regardless of the byte enables.
6032	*/
6033
6034	/*
6035	* To be able to read bytes and short word we convert them to properly
6036	* shifted 32-bit words and masks. The idea is to keep register-specific
6037	* handlers simple. Most accesses will be 32-bit anyway.
6038	*/
6039	uint32_t mask;
6040	switch (cb)
6041	{
6042	case 4: mask = 0xFFFFFFFF; break;
6043	case 2: mask = 0x0000FFFF; break;
6044	case 1: mask = 0x000000FF; break;
6045	default:
6046	return PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS, "unsupported op size: offset=%#10x cb=%#10x\n", offReg, cb);
6047	}
6048	if (index >= 0)
6049	{
6050	RT_UNTRUSTED_VALIDATED_FENCE(); /* paranoia because of port I/O. */
6051	if (g_aE1kRegMap[index].readable)
6052	{
6053	/* Make the mask correspond to the bits we are about to read. */
6054	shift = (offReg - g_aE1kRegMap[index].offset) % sizeof(uint32_t) * 8;
6055	mask <<= shift;
6056	if (!mask)
6057	return PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS, "Zero mask: offset=%#10x cb=%#10x\n", offReg, cb);
6058	/*
6059	* Read it. Pass the mask so the handler knows what has to be read.
6060	* Mask out irrelevant bits.
6061	*/
6062	//rc = e1kCsEnter(pThis, VERR_SEM_BUSY, RT_SRC_POS);
6063	if (RT_UNLIKELY(rc != VINF_SUCCESS))
6064	return rc;
6065	//pThis->fDelayInts = false;
6066	//pThis->iStatIntLost += pThis->iStatIntLostOne;
6067	//pThis->iStatIntLostOne = 0;
6068	rc = g_aE1kRegMap[index].pfnRead(pDevIns, pThis, offReg & 0xFFFFFFFC, (uint32_t)index, &u32);
6069	u32 &= mask;
6070	//e1kCsLeave(pThis);
6071	E1kLog2(("%s At %08X read %s from %s (%s)\n",
6072	pThis->szPrf, offReg, e1kU32toHex(u32, mask, buf), g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
6073	Log6(("%s At %08X read %s from %s (%s) [UNALIGNED]\n",
6074	pThis->szPrf, offReg, e1kU32toHex(u32, mask, buf), g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
6075	/* Shift back the result. */
6076	u32 >>= shift;
6077	}
6078	else
6079	E1kLog(("%s At %08X read (%s) attempt from write-only register %s (%s)\n",
6080	pThis->szPrf, offReg, e1kU32toHex(u32, mask, buf), g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
6081	if (IOM_SUCCESS(rc))
6082	STAM_COUNTER_INC(&pThis->aStatRegReads[index]);
6083	}
6084	else
6085	E1kLog(("%s At %08X read (%s) attempt from non-existing register\n",
6086	pThis->szPrf, offReg, e1kU32toHex(u32, mask, buf)));
6087
6088	memcpy(pv, &u32, cb);
6089	return rc;
6090	}
6091
6092	/**
6093	* Handle 4 byte aligned and sized read operation.
6094	*
6095	* Looks up and calls appropriate handler.
6096	*
6097	* @returns VBox status code.
6098	*
6099	* @param pDevIns The device instance.
6100	* @param pThis The device state structure.
6101	* @param offReg Register offset in memory-mapped frame.
6102	* @param pu32 Where to store the result.
6103	* @thread EMT
6104	*/
6105	static VBOXSTRICTRC e1kRegReadAlignedU32(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offReg, uint32_t *pu32)
6106	{
6107	Assert(!(offReg & 3));
6108
6109	/*
6110	* Lookup the register and check that it's readable.
6111	*/
6112	VBOXSTRICTRC rc = VINF_SUCCESS;
6113	int idxReg = e1kRegLookup(offReg);
6114	if (RT_LIKELY(idxReg >= 0))
6115	{
6116	RT_UNTRUSTED_VALIDATED_FENCE(); /* paranoia because of port I/O. */
6117	if (RT_UNLIKELY(g_aE1kRegMap[idxReg].readable))
6118	{
6119	/*
6120	* Read it. Pass the mask so the handler knows what has to be read.
6121	* Mask out irrelevant bits.
6122	*/
6123	//rc = e1kCsEnter(pThis, VERR_SEM_BUSY, RT_SRC_POS);
6124	//if (RT_UNLIKELY(rc != VINF_SUCCESS))
6125	// return rc;
6126	//pThis->fDelayInts = false;
6127	//pThis->iStatIntLost += pThis->iStatIntLostOne;
6128	//pThis->iStatIntLostOne = 0;
6129	rc = g_aE1kRegMap[idxReg].pfnRead(pDevIns, pThis, offReg & 0xFFFFFFFC, (uint32_t)idxReg, pu32);
6130	//e1kCsLeave(pThis);
6131	Log6(("%s At %08X read %08X from %s (%s)\n",
6132	pThis->szPrf, offReg, *pu32, g_aE1kRegMap[idxReg].abbrev, g_aE1kRegMap[idxReg].name));
6133	if (IOM_SUCCESS(rc))
6134	STAM_COUNTER_INC(&pThis->aStatRegReads[idxReg]);
6135	}
6136	else
6137	E1kLog(("%s At %08X read attempt from non-readable register %s (%s)\n",
6138	pThis->szPrf, offReg, g_aE1kRegMap[idxReg].abbrev, g_aE1kRegMap[idxReg].name));
6139	}
6140	else
6141	E1kLog(("%s At %08X read attempt from non-existing register\n", pThis->szPrf, offReg));
6142	return rc;
6143	}
6144
6145	/**
6146	* Handle 4 byte sized and aligned register write operation.
6147	*
6148	* Looks up and calls appropriate handler.
6149	*
6150	* @returns VBox status code.
6151	*
6152	* @param pDevIns The device instance.
6153	* @param pThis The device state structure.
6154	* @param offReg Register offset in memory-mapped frame.
6155	* @param u32Value The value to write.
6156	* @thread EMT
6157	*/
6158	static VBOXSTRICTRC e1kRegWriteAlignedU32(PPDMDEVINS pDevIns, PE1KSTATE pThis, uint32_t offReg, uint32_t u32Value)
6159	{
6160	VBOXSTRICTRC rc = VINF_SUCCESS;
6161	int index = e1kRegLookup(offReg);
6162	if (RT_LIKELY(index >= 0))
6163	{
6164	RT_UNTRUSTED_VALIDATED_FENCE(); /* paranoia because of port I/O. */
6165	if (RT_LIKELY(g_aE1kRegMap[index].writable))
6166	{
6167	/*
6168	* Write it. Pass the mask so the handler knows what has to be written.
6169	* Mask out irrelevant bits.
6170	*/
6171	Log6(("%s At %08X write %08X to %s (%s)\n",
6172	pThis->szPrf, offReg, u32Value, g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
6173	//rc = e1kCsEnter(pThis, VERR_SEM_BUSY, RT_SRC_POS);
6174	//if (RT_UNLIKELY(rc != VINF_SUCCESS))
6175	// return rc;
6176	//pThis->fDelayInts = false;
6177	//pThis->iStatIntLost += pThis->iStatIntLostOne;
6178	//pThis->iStatIntLostOne = 0;
6179	rc = g_aE1kRegMap[index].pfnWrite(pDevIns, pThis, offReg, (uint32_t)index, u32Value);
6180	//e1kCsLeave(pThis);
6181	}
6182	else
6183	E1kLog(("%s At %08X write attempt (%08X) to read-only register %s (%s)\n",
6184	pThis->szPrf, offReg, u32Value, g_aE1kRegMap[index].abbrev, g_aE1kRegMap[index].name));
6185	if (IOM_SUCCESS(rc))
6186	STAM_COUNTER_INC(&pThis->aStatRegWrites[index]);
6187	}
6188	else
6189	E1kLog(("%s At %08X write attempt (%08X) to non-existing register\n",
6190	pThis->szPrf, offReg, u32Value));
6191	return rc;
6192	}
6193
6194
6195	/* -=-=-=-=- MMIO and I/O Port Callbacks -=-=-=-=- */
6196
6197	/**
6198	* @callback_method_impl{FNIOMMMIONEWREAD}
6199	*/
6200	static DECLCALLBACK(VBOXSTRICTRC) e1kMMIORead(PPDMDEVINS pDevIns, void pvUser, RTGCPHYS off, void pv, uint32_t cb)
6201	{
6202	RT_NOREF2(pvUser, cb);
6203	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6204	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatMMIORead), a);
6205
6206	Assert(off < E1K_MM_SIZE);
6207	Assert(cb == 4);
6208	Assert(!(off & 3));
6209
6210	VBOXSTRICTRC rcStrict = e1kRegReadAlignedU32(pDevIns, pThis, (uint32_t)off, (uint32_t *)pv);
6211
6212	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatMMIORead), a);
6213	return rcStrict;
6214	}
6215
6216	/**
6217	* @callback_method_impl{FNIOMMMIONEWWRITE}
6218	*/
6219	static DECLCALLBACK(VBOXSTRICTRC) e1kMMIOWrite(PPDMDEVINS pDevIns, void pvUser, RTGCPHYS off, void const pv, uint32_t cb)
6220	{
6221	RT_NOREF2(pvUser, cb);
6222	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6223	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatMMIOWrite), a);
6224
6225	Assert(off < E1K_MM_SIZE);
6226	Assert(cb == 4);
6227	Assert(!(off & 3));
6228
6229	VBOXSTRICTRC rcStrict = e1kRegWriteAlignedU32(pDevIns, pThis, (uint32_t)off, (uint32_t const )pv);
6230
6231	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatMMIOWrite), a);
6232	return rcStrict;
6233	}
6234
6235	/**
6236	* @callback_method_impl{FNIOMIOPORTNEWIN}
6237	*/
6238	static DECLCALLBACK(VBOXSTRICTRC) e1kIOPortIn(PPDMDEVINS pDevIns, void pvUser, RTIOPORT offPort, uint32_t pu32, unsigned cb)
6239	{
6240	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6241	VBOXSTRICTRC rc;
6242	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatIORead), a);
6243	RT_NOREF_PV(pvUser);
6244
6245	if (RT_LIKELY(cb == 4))
6246	switch (offPort)
6247	{
6248	case 0x00: /* IOADDR */
6249	*pu32 = pThis->uSelectedReg;
6250	E1kLog2(("%s e1kIOPortIn: IOADDR(0), selecting register %#010x, val=%#010x\n", pThis->szPrf, pThis->uSelectedReg, *pu32));
6251	rc = VINF_SUCCESS;
6252	break;
6253
6254	case 0x04: /* IODATA */
6255	if (!(pThis->uSelectedReg & 3))
6256	rc = e1kRegReadAlignedU32(pDevIns, pThis, pThis->uSelectedReg, pu32);
6257	else /** @todo r=bird: I wouldn't be surprised if this unaligned branch wasn't necessary. */
6258	rc = e1kRegReadUnaligned(pDevIns, pThis, pThis->uSelectedReg, pu32, cb);
6259	if (rc == VINF_IOM_R3_MMIO_READ)
6260	rc = VINF_IOM_R3_IOPORT_READ;
6261	E1kLog2(("%s e1kIOPortIn: IODATA(4), reading from selected register %#010x, val=%#010x\n", pThis->szPrf, pThis->uSelectedReg, *pu32));
6262	break;
6263
6264	default:
6265	E1kLog(("%s e1kIOPortIn: invalid port %#010x\n", pThis->szPrf, offPort));
6266	/** @todo r=bird: Check what real hardware returns here. */
6267	//rc = VERR_IOM_IOPORT_UNUSED; /* Why not? */
6268	rc = VINF_IOM_MMIO_UNUSED_00; /* used to return VINF_SUCCESS and not touch pu32, which amounted to this. /
6269	break;
6270	}
6271	else
6272	{
6273	E1kLog(("%s e1kIOPortIn: invalid op size: offPort=%RTiop cb=%08x", pThis->szPrf, offPort, cb));
6274	rc = PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS, "%s e1kIOPortIn: invalid op size: offPort=%RTiop cb=%08x\n", pThis->szPrf, offPort, cb);
6275	pu32 = 0; /* @todo r=bird: Check what real hardware returns here. (Didn't used to set a value here, picked zero as that's what we'd end up in most cases.) */
6276	}
6277	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatIORead), a);
6278	return rc;
6279	}
6280
6281
6282	/**
6283	* @callback_method_impl{FNIOMIOPORTNEWOUT}
6284	*/
6285	static DECLCALLBACK(VBOXSTRICTRC) e1kIOPortOut(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT offPort, uint32_t u32, unsigned cb)
6286	{
6287	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6288	VBOXSTRICTRC rc;
6289	STAM_PROFILE_ADV_START(&pThis->CTX_SUFF_Z(StatIOWrite), a);
6290	RT_NOREF_PV(pvUser);
6291
6292	E1kLog2(("%s e1kIOPortOut: offPort=%RTiop value=%08x\n", pThis->szPrf, offPort, u32));
6293	if (RT_LIKELY(cb == 4))
6294	{
6295	switch (offPort)
6296	{
6297	case 0x00: /* IOADDR */
6298	pThis->uSelectedReg = u32;
6299	E1kLog2(("%s e1kIOPortOut: IOADDR(0), selected register %08x\n", pThis->szPrf, pThis->uSelectedReg));
6300	rc = VINF_SUCCESS;
6301	break;
6302
6303	case 0x04: /* IODATA */
6304	E1kLog2(("%s e1kIOPortOut: IODATA(4), writing to selected register %#010x, value=%#010x\n", pThis->szPrf, pThis->uSelectedReg, u32));
6305	if (RT_LIKELY(!(pThis->uSelectedReg & 3)))
6306	{
6307	rc = e1kRegWriteAlignedU32(pDevIns, pThis, pThis->uSelectedReg, u32);
6308	if (rc == VINF_IOM_R3_MMIO_WRITE)
6309	rc = VINF_IOM_R3_IOPORT_WRITE;
6310	}
6311	else
6312	rc = PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS,
6313	"Spec violation: misaligned offset: %#10x, ignored.\n", pThis->uSelectedReg);
6314	break;
6315
6316	default:
6317	E1kLog(("%s e1kIOPortOut: invalid port %#010x\n", pThis->szPrf, offPort));
6318	rc = PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS, "invalid port %#010x\n", offPort);
6319	}
6320	}
6321	else
6322	{
6323	E1kLog(("%s e1kIOPortOut: invalid op size: offPort=%RTiop cb=%08x\n", pThis->szPrf, offPort, cb));
6324	rc = PDMDevHlpDBGFStop(pDevIns, RT_SRC_POS, "%s: invalid op size: offPort=%RTiop cb=%#x\n", pThis->szPrf, offPort, cb);
6325	}
6326
6327	STAM_PROFILE_ADV_STOP(&pThis->CTX_SUFF_Z(StatIOWrite), a);
6328	return rc;
6329	}
6330
6331	#ifdef IN_RING3
6332
6333	/**
6334	* Dump complete device state to log.
6335	*
6336	* @param pThis Pointer to device state.
6337	*/
6338	static void e1kDumpState(PE1KSTATE pThis)
6339	{
6340	RT_NOREF(pThis);
6341	for (int i = 0; i < E1K_NUM_OF_32BIT_REGS; ++i)
6342	E1kLog2(("%s: %8.8s = %08x\n", pThis->szPrf, g_aE1kRegMap[i].abbrev, pThis->auRegs[i]));
6343	# ifdef E1K_INT_STATS
6344	LogRel(("%s: Interrupt attempts: %d\n", pThis->szPrf, pThis->uStatIntTry));
6345	LogRel(("%s: Interrupts raised : %d\n", pThis->szPrf, pThis->uStatInt));
6346	LogRel(("%s: Interrupts lowered: %d\n", pThis->szPrf, pThis->uStatIntLower));
6347	LogRel(("%s: ICR outside ISR : %d\n", pThis->szPrf, pThis->uStatNoIntICR));
6348	LogRel(("%s: IMS raised ints : %d\n", pThis->szPrf, pThis->uStatIntIMS));
6349	LogRel(("%s: Interrupts skipped: %d\n", pThis->szPrf, pThis->uStatIntSkip));
6350	LogRel(("%s: Masked interrupts : %d\n", pThis->szPrf, pThis->uStatIntMasked));
6351	LogRel(("%s: Early interrupts : %d\n", pThis->szPrf, pThis->uStatIntEarly));
6352	LogRel(("%s: Late interrupts : %d\n", pThis->szPrf, pThis->uStatIntLate));
6353	LogRel(("%s: Lost interrupts : %d\n", pThis->szPrf, pThis->iStatIntLost));
6354	LogRel(("%s: Interrupts by RX : %d\n", pThis->szPrf, pThis->uStatIntRx));
6355	LogRel(("%s: Interrupts by TX : %d\n", pThis->szPrf, pThis->uStatIntTx));
6356	LogRel(("%s: Interrupts by ICS : %d\n", pThis->szPrf, pThis->uStatIntICS));
6357	LogRel(("%s: Interrupts by RDTR: %d\n", pThis->szPrf, pThis->uStatIntRDTR));
6358	LogRel(("%s: Interrupts by RDMT: %d\n", pThis->szPrf, pThis->uStatIntRXDMT0));
6359	LogRel(("%s: Interrupts by TXQE: %d\n", pThis->szPrf, pThis->uStatIntTXQE));
6360	LogRel(("%s: TX int delay asked: %d\n", pThis->szPrf, pThis->uStatTxIDE));
6361	LogRel(("%s: TX delayed: %d\n", pThis->szPrf, pThis->uStatTxDelayed));
6362	LogRel(("%s: TX delay expired: %d\n", pThis->szPrf, pThis->uStatTxDelayExp));
6363	LogRel(("%s: TX no report asked: %d\n", pThis->szPrf, pThis->uStatTxNoRS));
6364	LogRel(("%s: TX abs timer expd : %d\n", pThis->szPrf, pThis->uStatTAD));
6365	LogRel(("%s: TX int timer expd : %d\n", pThis->szPrf, pThis->uStatTID));
6366	LogRel(("%s: RX abs timer expd : %d\n", pThis->szPrf, pThis->uStatRAD));
6367	LogRel(("%s: RX int timer expd : %d\n", pThis->szPrf, pThis->uStatRID));
6368	LogRel(("%s: TX CTX descriptors: %d\n", pThis->szPrf, pThis->uStatDescCtx));
6369	LogRel(("%s: TX DAT descriptors: %d\n", pThis->szPrf, pThis->uStatDescDat));
6370	LogRel(("%s: TX LEG descriptors: %d\n", pThis->szPrf, pThis->uStatDescLeg));
6371	LogRel(("%s: Received frames : %d\n", pThis->szPrf, pThis->uStatRxFrm));
6372	LogRel(("%s: Transmitted frames: %d\n", pThis->szPrf, pThis->uStatTxFrm));
6373	LogRel(("%s: TX frames up to 1514: %d\n", pThis->szPrf, pThis->uStatTx1514));
6374	LogRel(("%s: TX frames up to 2962: %d\n", pThis->szPrf, pThis->uStatTx2962));
6375	LogRel(("%s: TX frames up to 4410: %d\n", pThis->szPrf, pThis->uStatTx4410));
6376	LogRel(("%s: TX frames up to 5858: %d\n", pThis->szPrf, pThis->uStatTx5858));
6377	LogRel(("%s: TX frames up to 7306: %d\n", pThis->szPrf, pThis->uStatTx7306));
6378	LogRel(("%s: TX frames up to 8754: %d\n", pThis->szPrf, pThis->uStatTx8754));
6379	LogRel(("%s: TX frames up to 16384: %d\n", pThis->szPrf, pThis->uStatTx16384));
6380	LogRel(("%s: TX frames up to 32768: %d\n", pThis->szPrf, pThis->uStatTx32768));
6381	LogRel(("%s: Larger TX frames : %d\n", pThis->szPrf, pThis->uStatTxLarge));
6382	LogRel(("%s: Max TX Delay : %lld\n", pThis->szPrf, pThis->uStatMaxTxDelay));
6383	# endif /* E1K_INT_STATS */
6384	}
6385
6386
6387	/* -=-=-=-=- PDMINETWORKDOWN -=-=-=-=- */
6388
6389	/**
6390	* Check if the device can receive data now.
6391	* This must be called before the pfnRecieve() method is called.
6392	*
6393	* @returns Number of bytes the device can receive.
6394	* @param pDevIns The device instance.
6395	* @param pThis The instance data.
6396	* @thread EMT
6397	*/
6398	static int e1kCanReceive(PPDMDEVINS pDevIns, PE1KSTATE pThis)
6399	{
6400	#ifndef E1K_WITH_RXD_CACHE
6401	size_t cb;
6402
6403	if (RT_UNLIKELY(e1kCsRxEnter(pThis, VERR_SEM_BUSY) != VINF_SUCCESS))
6404	return VERR_NET_NO_BUFFER_SPACE;
6405
6406	if (RT_UNLIKELY(RDLEN == sizeof(E1KRXDESC)))
6407	{
6408	E1KRXDESC desc;
6409	PDMDevHlpPhysRead(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), &desc, sizeof(desc));
6410	if (desc.status.fDD)
6411	cb = 0;
6412	else
6413	cb = pThis->u16RxBSize;
6414	}
6415	else if (RDH < RDT)
6416	cb = (RDT - RDH) * pThis->u16RxBSize;
6417	else if (RDH > RDT)
6418	cb = (RDLEN/sizeof(E1KRXDESC) - RDH + RDT) * pThis->u16RxBSize;
6419	else
6420	{
6421	cb = 0;
6422	E1kLogRel(("E1000: OUT of RX descriptors!\n"));
6423	}
6424	E1kLog2(("%s e1kCanReceive: at exit RDH=%d RDT=%d RDLEN=%d u16RxBSize=%d cb=%lu\n",
6425	pThis->szPrf, RDH, RDT, RDLEN, pThis->u16RxBSize, cb));
6426
6427	e1kCsRxLeave(pThis);
6428	return cb > 0 ? VINF_SUCCESS : VERR_NET_NO_BUFFER_SPACE;
6429	#else /* E1K_WITH_RXD_CACHE */
6430	int rc = VINF_SUCCESS;
6431
6432	if (RT_UNLIKELY(e1kCsRxEnter(pThis, VERR_SEM_BUSY) != VINF_SUCCESS))
6433	return VERR_NET_NO_BUFFER_SPACE;
6434
6435	if (RT_UNLIKELY(RDLEN == sizeof(E1KRXDESC)))
6436	{
6437	E1KRXDESC desc;
6438	PDMDevHlpPhysRead(pDevIns, e1kDescAddr(RDBAH, RDBAL, RDH), &desc, sizeof(desc));
6439	if (desc.status.fDD)
6440	rc = VERR_NET_NO_BUFFER_SPACE;
6441	}
6442	else if (e1kRxDIsCacheEmpty(pThis) && RDH == RDT)
6443	{
6444	/* Cache is empty, so is the RX ring. */
6445	rc = VERR_NET_NO_BUFFER_SPACE;
6446	}
6447	E1kLog2(("%s e1kCanReceive: at exit in_cache=%d RDH=%d RDT=%d RDLEN=%d"
6448	" u16RxBSize=%d rc=%Rrc\n", pThis->szPrf,
6449	e1kRxDInCache(pThis), RDH, RDT, RDLEN, pThis->u16RxBSize, rc));
6450
6451	e1kCsRxLeave(pThis);
6452	return rc;
6453	#endif /* E1K_WITH_RXD_CACHE */
6454	}
6455
6456	/**
6457	* @interface_method_impl{PDMINETWORKDOWN,pfnWaitReceiveAvail}
6458	*/
6459	static DECLCALLBACK(int) e1kR3NetworkDown_WaitReceiveAvail(PPDMINETWORKDOWN pInterface, RTMSINTERVAL cMillies)
6460	{
6461	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkDown);
6462	PE1KSTATE pThis = pThisCC->pShared;
6463	PPDMDEVINS pDevIns = pThisCC->pDevInsR3;
6464
6465	int rc = e1kCanReceive(pDevIns, pThis);
6466
6467	if (RT_SUCCESS(rc))
6468	return VINF_SUCCESS;
6469	if (RT_UNLIKELY(cMillies == 0))
6470	return VERR_NET_NO_BUFFER_SPACE;
6471
6472	rc = VERR_INTERRUPTED;
6473	ASMAtomicXchgBool(&pThis->fMaybeOutOfSpace, true);
6474	STAM_PROFILE_START(&pThis->StatRxOverflow, a);
6475	VMSTATE enmVMState;
6476	while (RT_LIKELY( (enmVMState = PDMDevHlpVMState(pDevIns)) == VMSTATE_RUNNING
6477	\|\| enmVMState == VMSTATE_RUNNING_LS))
6478	{
6479	int rc2 = e1kCanReceive(pDevIns, pThis);
6480	if (RT_SUCCESS(rc2))
6481	{
6482	rc = VINF_SUCCESS;
6483	break;
6484	}
6485	E1kLogRel(("E1000: e1kR3NetworkDown_WaitReceiveAvail: waiting cMillies=%u...\n", cMillies));
6486	E1kLog(("%s: e1kR3NetworkDown_WaitReceiveAvail: waiting cMillies=%u...\n", pThis->szPrf, cMillies));
6487	PDMDevHlpSUPSemEventWaitNoResume(pDevIns, pThis->hEventMoreRxDescAvail, cMillies);
6488	}
6489	STAM_PROFILE_STOP(&pThis->StatRxOverflow, a);
6490	ASMAtomicXchgBool(&pThis->fMaybeOutOfSpace, false);
6491
6492	return rc;
6493	}
6494
6495
6496	/**
6497	* Matches the packet addresses against Receive Address table. Looks for
6498	* exact matches only.
6499	*
6500	* @returns true if address matches.
6501	* @param pThis Pointer to the state structure.
6502	* @param pvBuf The ethernet packet.
6503	* @param cb Number of bytes available in the packet.
6504	* @thread EMT
6505	*/
6506	static bool e1kPerfectMatch(PE1KSTATE pThis, const void *pvBuf)
6507	{
6508	for (unsigned i = 0; i < RT_ELEMENTS(pThis->aRecAddr.array); i++)
6509	{
6510	E1KRAELEM* ra = pThis->aRecAddr.array + i;
6511
6512	/* Valid address? */
6513	if (ra->ctl & RA_CTL_AV)
6514	{
6515	Assert((ra->ctl & RA_CTL_AS) < 2);
6516	//unsigned char pAddr = (unsigned char)pvBuf + sizeof(ra->addr)*(ra->ctl & RA_CTL_AS);
6517	//E1kLog3(("%s Matching %02x:%02x:%02x:%02x:%02x:%02x against %02x:%02x:%02x:%02x:%02x:%02x...\n",
6518	// pThis->szPrf, pAddr[0], pAddr[1], pAddr[2], pAddr[3], pAddr[4], pAddr[5],
6519	// ra->addr[0], ra->addr[1], ra->addr[2], ra->addr[3], ra->addr[4], ra->addr[5]));
6520	/*
6521	* Address Select:
6522	* 00b = Destination address
6523	* 01b = Source address
6524	* 10b = Reserved
6525	* 11b = Reserved
6526	* Since ethernet header is (DA, SA, len) we can use address
6527	* select as index.
6528	*/
6529	if (memcmp((char)pvBuf + sizeof(ra->addr)(ra->ctl & RA_CTL_AS),
6530	ra->addr, sizeof(ra->addr)) == 0)
6531	return true;
6532	}
6533	}
6534
6535	return false;
6536	}
6537
6538	/**
6539	* Matches the packet addresses against Multicast Table Array.
6540	*
6541	* @remarks This is imperfect match since it matches not exact address but
6542	* a subset of addresses.
6543	*
6544	* @returns true if address matches.
6545	* @param pThis Pointer to the state structure.
6546	* @param pvBuf The ethernet packet.
6547	* @param cb Number of bytes available in the packet.
6548	* @thread EMT
6549	*/
6550	static bool e1kImperfectMatch(PE1KSTATE pThis, const void *pvBuf)
6551	{
6552	/* Get bits 32..47 of destination address */
6553	uint16_t u16Bit = ((uint16_t*)pvBuf)[2];
6554
6555	unsigned offset = GET_BITS(RCTL, MO);
6556	/*
6557	* offset means:
6558	* 00b = bits 36..47
6559	* 01b = bits 35..46
6560	* 10b = bits 34..45
6561	* 11b = bits 32..43
6562	*/
6563	if (offset < 3)
6564	u16Bit = u16Bit >> (4 - offset);
6565	return ASMBitTest(pThis->auMTA, u16Bit & 0xFFF);
6566	}
6567
6568	/**
6569	* Determines if the packet is to be delivered to upper layer.
6570	*
6571	* The following filters supported:
6572	* - Exact Unicast/Multicast
6573	* - Promiscuous Unicast/Multicast
6574	* - Multicast
6575	* - VLAN
6576	*
6577	* @returns true if packet is intended for this node.
6578	* @param pThis Pointer to the state structure.
6579	* @param pvBuf The ethernet packet.
6580	* @param cb Number of bytes available in the packet.
6581	* @param pStatus Bit field to store status bits.
6582	* @thread EMT
6583	*/
6584	static bool e1kAddressFilter(PE1KSTATE pThis, const void pvBuf, size_t cb, E1KRXDST pStatus)
6585	{
6586	Assert(cb > 14);
6587	/* Assume that we fail to pass exact filter. */
6588	pStatus->fPIF = false;
6589	pStatus->fVP = false;
6590	/* Discard oversized packets */
6591	if (cb > E1K_MAX_RX_PKT_SIZE)
6592	{
6593	E1kLog(("%s ERROR: Incoming packet is too big, cb=%d > max=%d\n",
6594	pThis->szPrf, cb, E1K_MAX_RX_PKT_SIZE));
6595	E1K_INC_CNT32(ROC);
6596	return false;
6597	}
6598	else if (!(RCTL & RCTL_LPE) && cb > 1522)
6599	{
6600	/* When long packet reception is disabled packets over 1522 are discarded */
6601	E1kLog(("%s Discarding incoming packet (LPE=0), cb=%d\n",
6602	pThis->szPrf, cb));
6603	E1K_INC_CNT32(ROC);
6604	return false;
6605	}
6606
6607	uint16_t u16Ptr = (uint16_t)pvBuf;
6608	/* Compare TPID with VLAN Ether Type */
6609	if (RT_BE2H_U16(u16Ptr[6]) == VET)
6610	{
6611	pStatus->fVP = true;
6612	/* Is VLAN filtering enabled? */
6613	if (RCTL & RCTL_VFE)
6614	{
6615	/* It is 802.1q packet indeed, let's filter by VID */
6616	if (RCTL & RCTL_CFIEN)
6617	{
6618	E1kLog3(("%s VLAN filter: VLAN=%d CFI=%d RCTL_CFI=%d\n", pThis->szPrf,
6619	E1K_SPEC_VLAN(RT_BE2H_U16(u16Ptr[7])),
6620	E1K_SPEC_CFI(RT_BE2H_U16(u16Ptr[7])),
6621	!!(RCTL & RCTL_CFI)));
6622	if (E1K_SPEC_CFI(RT_BE2H_U16(u16Ptr[7])) != !!(RCTL & RCTL_CFI))
6623	{
6624	E1kLog2(("%s Packet filter: CFIs do not match in packet and RCTL (%d!=%d)\n",
6625	pThis->szPrf, E1K_SPEC_CFI(RT_BE2H_U16(u16Ptr[7])), !!(RCTL & RCTL_CFI)));
6626	return false;
6627	}
6628	}
6629	else
6630	E1kLog3(("%s VLAN filter: VLAN=%d\n", pThis->szPrf,
6631	E1K_SPEC_VLAN(RT_BE2H_U16(u16Ptr[7]))));
6632	if (!ASMBitTest(pThis->auVFTA, E1K_SPEC_VLAN(RT_BE2H_U16(u16Ptr[7]))))
6633	{
6634	E1kLog2(("%s Packet filter: no VLAN match (id=%d)\n",
6635	pThis->szPrf, E1K_SPEC_VLAN(RT_BE2H_U16(u16Ptr[7]))));
6636	return false;
6637	}
6638	}
6639	}
6640	/* Broadcast filtering */
6641	if (e1kIsBroadcast(pvBuf) && (RCTL & RCTL_BAM))
6642	return true;
6643	E1kLog2(("%s Packet filter: not a broadcast\n", pThis->szPrf));
6644	if (e1kIsMulticast(pvBuf))
6645	{
6646	/* Is multicast promiscuous enabled? */
6647	if (RCTL & RCTL_MPE)
6648	return true;
6649	E1kLog2(("%s Packet filter: no promiscuous multicast\n", pThis->szPrf));
6650	/* Try perfect matches first */
6651	if (e1kPerfectMatch(pThis, pvBuf))
6652	{
6653	pStatus->fPIF = true;
6654	return true;
6655	}
6656	E1kLog2(("%s Packet filter: no perfect match\n", pThis->szPrf));
6657	if (e1kImperfectMatch(pThis, pvBuf))
6658	return true;
6659	E1kLog2(("%s Packet filter: no imperfect match\n", pThis->szPrf));
6660	}
6661	else {
6662	/* Is unicast promiscuous enabled? */
6663	if (RCTL & RCTL_UPE)
6664	return true;
6665	E1kLog2(("%s Packet filter: no promiscuous unicast\n", pThis->szPrf));
6666	if (e1kPerfectMatch(pThis, pvBuf))
6667	{
6668	pStatus->fPIF = true;
6669	return true;
6670	}
6671	E1kLog2(("%s Packet filter: no perfect match\n", pThis->szPrf));
6672	}
6673	E1kLog2(("%s Packet filter: packet discarded\n", pThis->szPrf));
6674	return false;
6675	}
6676
6677	/**
6678	* @interface_method_impl{PDMINETWORKDOWN,pfnReceive}
6679	*/
6680	static DECLCALLBACK(int) e1kR3NetworkDown_Receive(PPDMINETWORKDOWN pInterface, const void *pvBuf, size_t cb)
6681	{
6682	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkDown);
6683	PE1KSTATE pThis = pThisCC->pShared;
6684	PPDMDEVINS pDevIns = pThisCC->pDevInsR3;
6685	int rc = VINF_SUCCESS;
6686
6687	/*
6688	* Drop packets if the VM is not running yet/anymore.
6689	*/
6690	VMSTATE enmVMState = PDMDevHlpVMState(pDevIns);
6691	if ( enmVMState != VMSTATE_RUNNING
6692	&& enmVMState != VMSTATE_RUNNING_LS)
6693	{
6694	E1kLog(("%s Dropping incoming packet as VM is not running.\n", pThis->szPrf));
6695	return VINF_SUCCESS;
6696	}
6697
6698	/* Discard incoming packets in locked state */
6699	if (!(RCTL & RCTL_EN) \|\| pThis->fLocked \|\| !(STATUS & STATUS_LU))
6700	{
6701	E1kLog(("%s Dropping incoming packet as receive operation is disabled.\n", pThis->szPrf));
6702	return VINF_SUCCESS;
6703	}
6704
6705	STAM_PROFILE_ADV_START(&pThis->StatReceive, a);
6706
6707	//if (!e1kCsEnter(pThis, RT_SRC_POS))
6708	// return VERR_PERMISSION_DENIED;
6709
6710	e1kPacketDump(pDevIns, pThis, (const uint8_t*)pvBuf, cb, "<-- Incoming");
6711
6712	/* Update stats */
6713	if (RT_LIKELY(e1kCsEnter(pThis, VERR_SEM_BUSY) == VINF_SUCCESS))
6714	{
6715	E1K_INC_CNT32(TPR);
6716	E1K_ADD_CNT64(TORL, TORH, cb < 64? 64 : cb);
6717	e1kCsLeave(pThis);
6718	}
6719	STAM_PROFILE_ADV_START(&pThis->StatReceiveFilter, a);
6720	E1KRXDST status;
6721	RT_ZERO(status);
6722	bool fPassed = e1kAddressFilter(pThis, pvBuf, cb, &status);
6723	STAM_PROFILE_ADV_STOP(&pThis->StatReceiveFilter, a);
6724	if (fPassed)
6725	{
6726	rc = e1kHandleRxPacket(pDevIns, pThis, pvBuf, cb, status);
6727	}
6728	//e1kCsLeave(pThis);
6729	STAM_PROFILE_ADV_STOP(&pThis->StatReceive, a);
6730
6731	return rc;
6732	}
6733
6734
6735	/* -=-=-=-=- PDMILEDPORTS -=-=-=-=- */
6736
6737	/**
6738	* @interface_method_impl{PDMILEDPORTS,pfnQueryStatusLed}
6739	*/
6740	static DECLCALLBACK(int) e1kR3QueryStatusLed(PPDMILEDPORTS pInterface, unsigned iLUN, PPDMLED *ppLed)
6741	{
6742	if (iLUN == 0)
6743	{
6744	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, ILeds);
6745	*ppLed = &pThisCC->pShared->led;
6746	return VINF_SUCCESS;
6747	}
6748	return VERR_PDM_LUN_NOT_FOUND;
6749	}
6750
6751
6752	/* -=-=-=-=- PDMINETWORKCONFIG -=-=-=-=- */
6753
6754	/**
6755	* @interface_method_impl{PDMINETWORKCONFIG,pfnGetMac}
6756	*/
6757	static DECLCALLBACK(int) e1kR3GetMac(PPDMINETWORKCONFIG pInterface, PRTMAC pMac)
6758	{
6759	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkConfig);
6760	pThisCC->eeprom.getMac(pMac);
6761	return VINF_SUCCESS;
6762	}
6763
6764	/**
6765	* @interface_method_impl{PDMINETWORKCONFIG,pfnGetLinkState}
6766	*/
6767	static DECLCALLBACK(PDMNETWORKLINKSTATE) e1kR3GetLinkState(PPDMINETWORKCONFIG pInterface)
6768	{
6769	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkConfig);
6770	PE1KSTATE pThis = pThisCC->pShared;
6771	if (STATUS & STATUS_LU)
6772	return PDMNETWORKLINKSTATE_UP;
6773	return PDMNETWORKLINKSTATE_DOWN;
6774	}
6775
6776	/**
6777	* @interface_method_impl{PDMINETWORKCONFIG,pfnSetLinkState}
6778	*/
6779	static DECLCALLBACK(int) e1kR3SetLinkState(PPDMINETWORKCONFIG pInterface, PDMNETWORKLINKSTATE enmState)
6780	{
6781	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, INetworkConfig);
6782	PE1KSTATE pThis = pThisCC->pShared;
6783	PPDMDEVINS pDevIns = pThisCC->pDevInsR3;
6784
6785	E1kLog(("%s e1kR3SetLinkState: enmState=%d\n", pThis->szPrf, enmState));
6786	switch (enmState)
6787	{
6788	case PDMNETWORKLINKSTATE_UP:
6789	pThis->fCableConnected = true;
6790	/* If link was down, bring it up after a while. */
6791	if (!(STATUS & STATUS_LU))
6792	e1kBringLinkUpDelayed(pDevIns, pThis);
6793	break;
6794	case PDMNETWORKLINKSTATE_DOWN:
6795	pThis->fCableConnected = false;
6796	/* Always set the phy link state to down, regardless of the STATUS_LU bit.
6797	* We might have to set the link state before the driver initializes us. */
6798	Phy::setLinkStatus(&pThis->phy, false);
6799	/* If link was up, bring it down. */
6800	if (STATUS & STATUS_LU)
6801	e1kR3LinkDown(pDevIns, pThis, pThisCC);
6802	break;
6803	case PDMNETWORKLINKSTATE_DOWN_RESUME:
6804	/*
6805	* There is not much sense in bringing down the link if it has not come up yet.
6806	* If it is up though, we bring it down temporarely, then bring it up again.
6807	*/
6808	if (STATUS & STATUS_LU)
6809	e1kR3LinkDownTemp(pDevIns, pThis, pThisCC);
6810	break;
6811	default:
6812	;
6813	}
6814	return VINF_SUCCESS;
6815	}
6816
6817
6818	/* -=-=-=-=- PDMIBASE -=-=-=-=- */
6819
6820	/**
6821	* @interface_method_impl{PDMIBASE,pfnQueryInterface}
6822	*/
6823	static DECLCALLBACK(void ) e1kR3QueryInterface(struct PDMIBASE pInterface, const char *pszIID)
6824	{
6825	PE1KSTATECC pThisCC = RT_FROM_MEMBER(pInterface, E1KSTATECC, IBase);
6826	Assert(&pThisCC->IBase == pInterface);
6827
6828	PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pThisCC->IBase);
6829	PDMIBASE_RETURN_INTERFACE(pszIID, PDMINETWORKDOWN, &pThisCC->INetworkDown);
6830	PDMIBASE_RETURN_INTERFACE(pszIID, PDMINETWORKCONFIG, &pThisCC->INetworkConfig);
6831	PDMIBASE_RETURN_INTERFACE(pszIID, PDMILEDPORTS, &pThisCC->ILeds);
6832	return NULL;
6833	}
6834
6835
6836	/* -=-=-=-=- Saved State -=-=-=-=- */
6837
6838	/**
6839	* Saves the configuration.
6840	*
6841	* @param pThis The E1K state.
6842	* @param pSSM The handle to the saved state.
6843	*/
6844	static void e1kSaveConfig(PCPDMDEVHLPR3 pHlp, PE1KSTATE pThis, PSSMHANDLE pSSM)
6845	{
6846	pHlp->pfnSSMPutMem(pSSM, &pThis->macConfigured, sizeof(pThis->macConfigured));
6847	pHlp->pfnSSMPutU32(pSSM, pThis->eChip);
6848	}
6849
6850	/**
6851	* @callback_method_impl{FNSSMDEVLIVEEXEC,Save basic configuration.}
6852	*/
6853	static DECLCALLBACK(int) e1kLiveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uPass)
6854	{
6855	RT_NOREF(uPass);
6856	e1kSaveConfig(pDevIns->pHlpR3, PDMDEVINS_2_DATA(pDevIns, PE1KSTATE), pSSM);
6857	return VINF_SSM_DONT_CALL_AGAIN;
6858	}
6859
6860	/**
6861	* @callback_method_impl{FNSSMDEVSAVEPREP,Synchronize.}
6862	*/
6863	static DECLCALLBACK(int) e1kSavePrep(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
6864	{
6865	RT_NOREF(pSSM);
6866	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6867
6868	int rc = e1kCsEnter(pThis, VERR_SEM_BUSY);
6869	if (RT_UNLIKELY(rc != VINF_SUCCESS))
6870	return rc;
6871	e1kCsLeave(pThis);
6872	return VINF_SUCCESS;
6873	#if 0
6874	/* 1) Prevent all threads from modifying the state and memory */
6875	//pThis->fLocked = true;
6876	/* 2) Cancel all timers */
6877	#ifdef E1K_TX_DELAY
6878	e1kCancelTimer(pThis, pThis->CTX_SUFF(pTXDTimer));
6879	#endif /* E1K_TX_DELAY */
6880	//#ifdef E1K_USE_TX_TIMERS
6881	if (pThis->fTidEnabled)
6882	{
6883	e1kCancelTimer(pThis, pThis->CTX_SUFF(pTIDTimer));
6884	#ifndef E1K_NO_TAD
6885	e1kCancelTimer(pThis, pThis->CTX_SUFF(pTADTimer));
6886	#endif /* E1K_NO_TAD */
6887	}
6888	//#endif /* E1K_USE_TX_TIMERS */
6889	#ifdef E1K_USE_RX_TIMERS
6890	e1kCancelTimer(pThis, pThis->CTX_SUFF(pRIDTimer));
6891	e1kCancelTimer(pThis, pThis->CTX_SUFF(pRADTimer));
6892	#endif /* E1K_USE_RX_TIMERS */
6893	e1kCancelTimer(pThis, pThis->CTX_SUFF(pIntTimer));
6894	/* 3) Did I forget anything? */
6895	E1kLog(("%s Locked\n", pThis->szPrf));
6896	return VINF_SUCCESS;
6897	#endif
6898	}
6899
6900	/**
6901	* @callback_method_impl{FNSSMDEVSAVEEXEC}
6902	*/
6903	static DECLCALLBACK(int) e1kSaveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
6904	{
6905	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6906	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
6907	PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
6908
6909	e1kSaveConfig(pHlp, pThis, pSSM);
6910	pThisCC->eeprom.save(pHlp, pSSM);
6911	e1kDumpState(pThis);
6912	pHlp->pfnSSMPutMem(pSSM, pThis->auRegs, sizeof(pThis->auRegs));
6913	pHlp->pfnSSMPutBool(pSSM, pThis->fIntRaised);
6914	Phy::saveState(pHlp, pSSM, &pThis->phy);
6915	pHlp->pfnSSMPutU32(pSSM, pThis->uSelectedReg);
6916	pHlp->pfnSSMPutMem(pSSM, pThis->auMTA, sizeof(pThis->auMTA));
6917	pHlp->pfnSSMPutMem(pSSM, &pThis->aRecAddr, sizeof(pThis->aRecAddr));
6918	pHlp->pfnSSMPutMem(pSSM, pThis->auVFTA, sizeof(pThis->auVFTA));
6919	pHlp->pfnSSMPutU64(pSSM, pThis->u64AckedAt);
6920	pHlp->pfnSSMPutU16(pSSM, pThis->u16RxBSize);
6921	//pHlp->pfnSSMPutBool(pSSM, pThis->fDelayInts);
6922	//pHlp->pfnSSMPutBool(pSSM, pThis->fIntMaskUsed);
6923	pHlp->pfnSSMPutU16(pSSM, pThis->u16TxPktLen);
6924	/** @todo State wrt to the TSE buffer is incomplete, so little point in
6925	* saving this actually. */
6926	pHlp->pfnSSMPutMem(pSSM, pThis->aTxPacketFallback, pThis->u16TxPktLen);
6927	pHlp->pfnSSMPutBool(pSSM, pThis->fIPcsum);
6928	pHlp->pfnSSMPutBool(pSSM, pThis->fTCPcsum);
6929	pHlp->pfnSSMPutMem(pSSM, &pThis->contextTSE, sizeof(pThis->contextTSE));
6930	pHlp->pfnSSMPutMem(pSSM, &pThis->contextNormal, sizeof(pThis->contextNormal));
6931	pHlp->pfnSSMPutBool(pSSM, pThis->fVTag);
6932	pHlp->pfnSSMPutU16(pSSM, pThis->u16VTagTCI);
6933	#ifdef E1K_WITH_TXD_CACHE
6934	# if 0
6935	pHlp->pfnSSMPutU8(pSSM, pThis->nTxDFetched);
6936	pHlp->pfnSSMPutMem(pSSM, pThis->aTxDescriptors,
6937	pThis->nTxDFetched * sizeof(pThis->aTxDescriptors[0]));
6938	# else
6939	/*
6940	* There is no point in storing TX descriptor cache entries as we can simply
6941	* fetch them again. Moreover, normally the cache is always empty when we
6942	* save the state. Store zero entries for compatibility.
6943	*/
6944	pHlp->pfnSSMPutU8(pSSM, 0);
6945	# endif
6946	#endif /* E1K_WITH_TXD_CACHE */
6947	/** @todo GSO requires some more state here. */
6948	E1kLog(("%s State has been saved\n", pThis->szPrf));
6949	return VINF_SUCCESS;
6950	}
6951
6952	#if 0
6953	/**
6954	* @callback_method_impl{FNSSMDEVSAVEDONE}
6955	*/
6956	static DECLCALLBACK(int) e1kSaveDone(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
6957	{
6958	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6959
6960	/* If VM is being powered off unlocking will result in assertions in PGM */
6961	if (PDMDevHlpGetVM(pDevIns)->enmVMState == VMSTATE_RUNNING)
6962	pThis->fLocked = false;
6963	else
6964	E1kLog(("%s VM is not running -- remain locked\n", pThis->szPrf));
6965	E1kLog(("%s Unlocked\n", pThis->szPrf));
6966	return VINF_SUCCESS;
6967	}
6968	#endif
6969
6970	/**
6971	* @callback_method_impl{FNSSMDEVLOADPREP,Synchronize.}
6972	*/
6973	static DECLCALLBACK(int) e1kLoadPrep(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
6974	{
6975	RT_NOREF(pSSM);
6976	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6977
6978	int rc = e1kCsEnter(pThis, VERR_SEM_BUSY);
6979	if (RT_UNLIKELY(rc != VINF_SUCCESS))
6980	return rc;
6981	e1kCsLeave(pThis);
6982	return VINF_SUCCESS;
6983	}
6984
6985	/**
6986	* @callback_method_impl{FNSSMDEVLOADEXEC}
6987	*/
6988	static DECLCALLBACK(int) e1kLoadExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass)
6989	{
6990	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
6991	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
6992	PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
6993	int rc;
6994
6995	if ( uVersion != E1K_SAVEDSTATE_VERSION
6996	#ifdef E1K_WITH_TXD_CACHE
6997	&& uVersion != E1K_SAVEDSTATE_VERSION_VBOX_42_VTAG
6998	#endif /* E1K_WITH_TXD_CACHE */
6999	&& uVersion != E1K_SAVEDSTATE_VERSION_VBOX_41
7000	&& uVersion != E1K_SAVEDSTATE_VERSION_VBOX_30)
7001	return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION;
7002
7003	if ( uVersion > E1K_SAVEDSTATE_VERSION_VBOX_30
7004	\|\| uPass != SSM_PASS_FINAL)
7005	{
7006	/* config checks */
7007	RTMAC macConfigured;
7008	rc = pHlp->pfnSSMGetMem(pSSM, &macConfigured, sizeof(macConfigured));
7009	AssertRCReturn(rc, rc);
7010	if ( memcmp(&macConfigured, &pThis->macConfigured, sizeof(macConfigured))
7011	&& (uPass == 0 \|\| !PDMDevHlpVMTeleportedAndNotFullyResumedYet(pDevIns)) )
7012	LogRel(("%s: The mac address differs: config=%RTmac saved=%RTmac\n", pThis->szPrf, &pThis->macConfigured, &macConfigured));
7013
7014	E1KCHIP eChip;
7015	rc = pHlp->pfnSSMGetU32(pSSM, &eChip);
7016	AssertRCReturn(rc, rc);
7017	if (eChip != pThis->eChip)
7018	return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("The chip type differs: config=%u saved=%u"), pThis->eChip, eChip);
7019	}
7020
7021	if (uPass == SSM_PASS_FINAL)
7022	{
7023	if (uVersion > E1K_SAVEDSTATE_VERSION_VBOX_30)
7024	{
7025	rc = pThisCC->eeprom.load(pHlp, pSSM);
7026	AssertRCReturn(rc, rc);
7027	}
7028	/* the state */
7029	pHlp->pfnSSMGetMem(pSSM, &pThis->auRegs, sizeof(pThis->auRegs));
7030	pHlp->pfnSSMGetBool(pSSM, &pThis->fIntRaised);
7031	/** @todo PHY could be made a separate device with its own versioning */
7032	Phy::loadState(pHlp, pSSM, &pThis->phy);
7033	pHlp->pfnSSMGetU32(pSSM, &pThis->uSelectedReg);
7034	pHlp->pfnSSMGetMem(pSSM, &pThis->auMTA, sizeof(pThis->auMTA));
7035	pHlp->pfnSSMGetMem(pSSM, &pThis->aRecAddr, sizeof(pThis->aRecAddr));
7036	pHlp->pfnSSMGetMem(pSSM, &pThis->auVFTA, sizeof(pThis->auVFTA));
7037	pHlp->pfnSSMGetU64(pSSM, &pThis->u64AckedAt);
7038	pHlp->pfnSSMGetU16(pSSM, &pThis->u16RxBSize);
7039	//pHlp->pfnSSMGetBool(pSSM, pThis->fDelayInts);
7040	//pHlp->pfnSSMGetBool(pSSM, pThis->fIntMaskUsed);
7041	rc = pHlp->pfnSSMGetU16(pSSM, &pThis->u16TxPktLen);
7042	AssertRCReturn(rc, rc);
7043	if (pThis->u16TxPktLen > sizeof(pThis->aTxPacketFallback))
7044	pThis->u16TxPktLen = sizeof(pThis->aTxPacketFallback);
7045	pHlp->pfnSSMGetMem(pSSM, &pThis->aTxPacketFallback[0], pThis->u16TxPktLen);
7046	pHlp->pfnSSMGetBool(pSSM, &pThis->fIPcsum);
7047	pHlp->pfnSSMGetBool(pSSM, &pThis->fTCPcsum);
7048	pHlp->pfnSSMGetMem(pSSM, &pThis->contextTSE, sizeof(pThis->contextTSE));
7049	rc = pHlp->pfnSSMGetMem(pSSM, &pThis->contextNormal, sizeof(pThis->contextNormal));
7050	AssertRCReturn(rc, rc);
7051	if (uVersion > E1K_SAVEDSTATE_VERSION_VBOX_41)
7052	{
7053	pHlp->pfnSSMGetBool(pSSM, &pThis->fVTag);
7054	rc = pHlp->pfnSSMGetU16(pSSM, &pThis->u16VTagTCI);
7055	AssertRCReturn(rc, rc);
7056	}
7057	else
7058	{
7059	pThis->fVTag = false;
7060	pThis->u16VTagTCI = 0;
7061	}
7062	#ifdef E1K_WITH_TXD_CACHE
7063	if (uVersion > E1K_SAVEDSTATE_VERSION_VBOX_42_VTAG)
7064	{
7065	rc = pHlp->pfnSSMGetU8(pSSM, &pThis->nTxDFetched);
7066	AssertRCReturn(rc, rc);
7067	if (pThis->nTxDFetched)
7068	pHlp->pfnSSMGetMem(pSSM, pThis->aTxDescriptors,
7069	pThis->nTxDFetched * sizeof(pThis->aTxDescriptors[0]));
7070	}
7071	else
7072	pThis->nTxDFetched = 0;
7073	/**
7074	* @todo Perhaps we should not store TXD cache as the entries can be
7075	* simply fetched again from guest's memory. Or can't they?
7076	*/
7077	#endif /* E1K_WITH_TXD_CACHE */
7078	#ifdef E1K_WITH_RXD_CACHE
7079	/*
7080	* There is no point in storing the RX descriptor cache in the saved
7081	* state, we just need to make sure it is empty.
7082	*/
7083	pThis->iRxDCurrent = pThis->nRxDFetched = 0;
7084	#endif /* E1K_WITH_RXD_CACHE */
7085	rc = pHlp->pfnSSMHandleGetStatus(pSSM);
7086	AssertRCReturn(rc, rc);
7087
7088	/* derived state */
7089	e1kSetupGsoCtx(&pThis->GsoCtx, &pThis->contextTSE);
7090
7091	E1kLog(("%s State has been restored\n", pThis->szPrf));
7092	e1kDumpState(pThis);
7093	}
7094	return VINF_SUCCESS;
7095	}
7096
7097	/**
7098	* @callback_method_impl{FNSSMDEVLOADDONE, Link status adjustments after loading.}
7099	*/
7100	static DECLCALLBACK(int) e1kLoadDone(PPDMDEVINS pDevIns, PSSMHANDLE pSSM)
7101	{
7102	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7103	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
7104	RT_NOREF(pSSM);
7105
7106	/* Update promiscuous mode */
7107	if (pThisCC->pDrvR3)
7108	pThisCC->pDrvR3->pfnSetPromiscuousMode(pThisCC->pDrvR3, !!(RCTL & (RCTL_UPE \| RCTL_MPE)));
7109
7110	/*
7111	* Force the link down here, since PDMNETWORKLINKSTATE_DOWN_RESUME is never
7112	* passed to us. We go through all this stuff if the link was up and we
7113	* wasn't teleported.
7114	*/
7115	if ( (STATUS & STATUS_LU)
7116	&& !PDMDevHlpVMTeleportedAndNotFullyResumedYet(pDevIns)
7117	&& pThis->cMsLinkUpDelay)
7118	{
7119	e1kR3LinkDownTemp(pDevIns, pThis, pThisCC);
7120	}
7121	return VINF_SUCCESS;
7122	}
7123
7124
7125
7126	/* -=-=-=-=- Debug Info + Log Types -=-=-=-=- */
7127
7128	/**
7129	* @callback_method_impl{FNRTSTRFORMATTYPE}
7130	*/
7131	static DECLCALLBACK(size_t) e1kFmtRxDesc(PFNRTSTROUTPUT pfnOutput,
7132	void *pvArgOutput,
7133	const char *pszType,
7134	void const *pvValue,
7135	int cchWidth,
7136	int cchPrecision,
7137	unsigned fFlags,
7138	void *pvUser)
7139	{
7140	RT_NOREF(cchWidth, cchPrecision, fFlags, pvUser);
7141	AssertReturn(strcmp(pszType, "e1krxd") == 0, 0);
7142	E1KRXDESC* pDesc = (E1KRXDESC*)pvValue;
7143	if (!pDesc)
7144	return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "NULL_RXD");
7145
7146	size_t cbPrintf = 0;
7147	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "Address=%16LX Length=%04X Csum=%04X\n",
7148	pDesc->u64BufAddr, pDesc->u16Length, pDesc->u16Checksum);
7149	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, " STA: %s %s %s %s %s %s %s ERR: %s %s %s %s SPECIAL: %s VLAN=%03x PRI=%x",
7150	pDesc->status.fPIF ? "PIF" : "pif",
7151	pDesc->status.fIPCS ? "IPCS" : "ipcs",
7152	pDesc->status.fTCPCS ? "TCPCS" : "tcpcs",
7153	pDesc->status.fVP ? "VP" : "vp",
7154	pDesc->status.fIXSM ? "IXSM" : "ixsm",
7155	pDesc->status.fEOP ? "EOP" : "eop",
7156	pDesc->status.fDD ? "DD" : "dd",
7157	pDesc->status.fRXE ? "RXE" : "rxe",
7158	pDesc->status.fIPE ? "IPE" : "ipe",
7159	pDesc->status.fTCPE ? "TCPE" : "tcpe",
7160	pDesc->status.fCE ? "CE" : "ce",
7161	E1K_SPEC_CFI(pDesc->status.u16Special) ? "CFI" :"cfi",
7162	E1K_SPEC_VLAN(pDesc->status.u16Special),
7163	E1K_SPEC_PRI(pDesc->status.u16Special));
7164	return cbPrintf;
7165	}
7166
7167	/**
7168	* @callback_method_impl{FNRTSTRFORMATTYPE}
7169	*/
7170	static DECLCALLBACK(size_t) e1kFmtTxDesc(PFNRTSTROUTPUT pfnOutput,
7171	void *pvArgOutput,
7172	const char *pszType,
7173	void const *pvValue,
7174	int cchWidth,
7175	int cchPrecision,
7176	unsigned fFlags,
7177	void *pvUser)
7178	{
7179	RT_NOREF(cchWidth, cchPrecision, fFlags, pvUser);
7180	AssertReturn(strcmp(pszType, "e1ktxd") == 0, 0);
7181	E1KTXDESC pDesc = (E1KTXDESC)pvValue;
7182	if (!pDesc)
7183	return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "NULL_TXD");
7184
7185	size_t cbPrintf = 0;
7186	switch (e1kGetDescType(pDesc))
7187	{
7188	case E1K_DTYP_CONTEXT:
7189	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "Type=Context\n"
7190	" IPCSS=%02X IPCSO=%02X IPCSE=%04X TUCSS=%02X TUCSO=%02X TUCSE=%04X\n"
7191	" TUCMD:%s%s%s %s %s PAYLEN=%04x HDRLEN=%04x MSS=%04x STA: %s",
7192	pDesc->context.ip.u8CSS, pDesc->context.ip.u8CSO, pDesc->context.ip.u16CSE,
7193	pDesc->context.tu.u8CSS, pDesc->context.tu.u8CSO, pDesc->context.tu.u16CSE,
7194	pDesc->context.dw2.fIDE ? " IDE":"",
7195	pDesc->context.dw2.fRS ? " RS" :"",
7196	pDesc->context.dw2.fTSE ? " TSE":"",
7197	pDesc->context.dw2.fIP ? "IPv4":"IPv6",
7198	pDesc->context.dw2.fTCP ? "TCP":"UDP",
7199	pDesc->context.dw2.u20PAYLEN,
7200	pDesc->context.dw3.u8HDRLEN,
7201	pDesc->context.dw3.u16MSS,
7202	pDesc->context.dw3.fDD?"DD":"");
7203	break;
7204	case E1K_DTYP_DATA:
7205	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "Type=Data Address=%16LX DTALEN=%05X\n"
7206	" DCMD:%s%s%s%s%s%s%s STA:%s%s%s POPTS:%s%s SPECIAL:%s VLAN=%03x PRI=%x",
7207	pDesc->data.u64BufAddr,
7208	pDesc->data.cmd.u20DTALEN,
7209	pDesc->data.cmd.fIDE ? " IDE" :"",
7210	pDesc->data.cmd.fVLE ? " VLE" :"",
7211	pDesc->data.cmd.fRPS ? " RPS" :"",
7212	pDesc->data.cmd.fRS ? " RS" :"",
7213	pDesc->data.cmd.fTSE ? " TSE" :"",
7214	pDesc->data.cmd.fIFCS? " IFCS":"",
7215	pDesc->data.cmd.fEOP ? " EOP" :"",
7216	pDesc->data.dw3.fDD ? " DD" :"",
7217	pDesc->data.dw3.fEC ? " EC" :"",
7218	pDesc->data.dw3.fLC ? " LC" :"",
7219	pDesc->data.dw3.fTXSM? " TXSM":"",
7220	pDesc->data.dw3.fIXSM? " IXSM":"",
7221	E1K_SPEC_CFI(pDesc->data.dw3.u16Special) ? "CFI" :"cfi",
7222	E1K_SPEC_VLAN(pDesc->data.dw3.u16Special),
7223	E1K_SPEC_PRI(pDesc->data.dw3.u16Special));
7224	break;
7225	case E1K_DTYP_LEGACY:
7226	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "Type=Legacy Address=%16LX DTALEN=%05X\n"
7227	" CMD:%s%s%s%s%s%s%s STA:%s%s%s CSO=%02x CSS=%02x SPECIAL:%s VLAN=%03x PRI=%x",
7228	pDesc->data.u64BufAddr,
7229	pDesc->legacy.cmd.u16Length,
7230	pDesc->legacy.cmd.fIDE ? " IDE" :"",
7231	pDesc->legacy.cmd.fVLE ? " VLE" :"",
7232	pDesc->legacy.cmd.fRPS ? " RPS" :"",
7233	pDesc->legacy.cmd.fRS ? " RS" :"",
7234	pDesc->legacy.cmd.fIC ? " IC" :"",
7235	pDesc->legacy.cmd.fIFCS? " IFCS":"",
7236	pDesc->legacy.cmd.fEOP ? " EOP" :"",
7237	pDesc->legacy.dw3.fDD ? " DD" :"",
7238	pDesc->legacy.dw3.fEC ? " EC" :"",
7239	pDesc->legacy.dw3.fLC ? " LC" :"",
7240	pDesc->legacy.cmd.u8CSO,
7241	pDesc->legacy.dw3.u8CSS,
7242	E1K_SPEC_CFI(pDesc->legacy.dw3.u16Special) ? "CFI" :"cfi",
7243	E1K_SPEC_VLAN(pDesc->legacy.dw3.u16Special),
7244	E1K_SPEC_PRI(pDesc->legacy.dw3.u16Special));
7245	break;
7246	default:
7247	cbPrintf += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "Invalid Transmit Descriptor");
7248	break;
7249	}
7250
7251	return cbPrintf;
7252	}
7253
7254	/** Initializes debug helpers (logging format types). */
7255	static int e1kInitDebugHelpers(void)
7256	{
7257	int rc = VINF_SUCCESS;
7258	static bool s_fHelpersRegistered = false;
7259	if (!s_fHelpersRegistered)
7260	{
7261	s_fHelpersRegistered = true;
7262	rc = RTStrFormatTypeRegister("e1krxd", e1kFmtRxDesc, NULL);
7263	AssertRCReturn(rc, rc);
7264	rc = RTStrFormatTypeRegister("e1ktxd", e1kFmtTxDesc, NULL);
7265	AssertRCReturn(rc, rc);
7266	}
7267	return rc;
7268	}
7269
7270	/**
7271	* Status info callback.
7272	*
7273	* @param pDevIns The device instance.
7274	* @param pHlp The output helpers.
7275	* @param pszArgs The arguments.
7276	*/
7277	static DECLCALLBACK(void) e1kInfo(PPDMDEVINS pDevIns, PCDBGFINFOHLP pHlp, const char *pszArgs)
7278	{
7279	RT_NOREF(pszArgs);
7280	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7281	unsigned i;
7282	// bool fRcvRing = false;
7283	// bool fXmtRing = false;
7284
7285	/*
7286	* Parse args.
7287	if (pszArgs)
7288	{
7289	fRcvRing = strstr(pszArgs, "verbose") \|\| strstr(pszArgs, "rcv");
7290	fXmtRing = strstr(pszArgs, "verbose") \|\| strstr(pszArgs, "xmt");
7291	}
7292	*/
7293
7294	/*
7295	* Show info.
7296	*/
7297	pHlp->pfnPrintf(pHlp, "E1000 #%d: port=%04x mmio=%RGp mac-cfg=%RTmac %s%s%s\n",
7298	pDevIns->iInstance,
7299	PDMDevHlpIoPortGetMappingAddress(pDevIns, pThis->hIoPorts),
7300	PDMDevHlpMmioGetMappingAddress(pDevIns, pThis->hMmioRegion),
7301	&pThis->macConfigured, g_aChips[pThis->eChip].pcszName,
7302	pDevIns->fRCEnabled ? " RC" : "", pDevIns->fR0Enabled ? " R0" : "");
7303
7304	e1kCsEnter(pThis, VERR_INTERNAL_ERROR); /* Not sure why but PCNet does it */
7305
7306	for (i = 0; i < E1K_NUM_OF_32BIT_REGS; ++i)
7307	pHlp->pfnPrintf(pHlp, "%8.8s = %08x\n", g_aE1kRegMap[i].abbrev, pThis->auRegs[i]);
7308
7309	for (i = 0; i < RT_ELEMENTS(pThis->aRecAddr.array); i++)
7310	{
7311	E1KRAELEM* ra = pThis->aRecAddr.array + i;
7312	if (ra->ctl & RA_CTL_AV)
7313	{
7314	const char *pcszTmp;
7315	switch (ra->ctl & RA_CTL_AS)
7316	{
7317	case 0: pcszTmp = "DST"; break;
7318	case 1: pcszTmp = "SRC"; break;
7319	default: pcszTmp = "reserved";
7320	}
7321	pHlp->pfnPrintf(pHlp, "RA%02d: %s %RTmac\n", i, pcszTmp, ra->addr);
7322	}
7323	}
7324	unsigned cDescs = RDLEN / sizeof(E1KRXDESC);
7325	uint32_t rdh = RDH;
7326	pHlp->pfnPrintf(pHlp, "\n-- Receive Descriptors (%d total) --\n", cDescs);
7327	for (i = 0; i < cDescs; ++i)
7328	{
7329	E1KRXDESC desc;
7330	PDMDevHlpPhysRead(pDevIns, e1kDescAddr(RDBAH, RDBAL, i),
7331	&desc, sizeof(desc));
7332	if (i == rdh)
7333	pHlp->pfnPrintf(pHlp, ">>> ");
7334	pHlp->pfnPrintf(pHlp, "%RGp: %R[e1krxd]\n", e1kDescAddr(RDBAH, RDBAL, i), &desc);
7335	}
7336	#ifdef E1K_WITH_RXD_CACHE
7337	pHlp->pfnPrintf(pHlp, "\n-- Receive Descriptors in Cache (at %d (RDH %d)/ fetched %d / max %d) --\n",
7338	pThis->iRxDCurrent, RDH, pThis->nRxDFetched, E1K_RXD_CACHE_SIZE);
7339	if (rdh > pThis->iRxDCurrent)
7340	rdh -= pThis->iRxDCurrent;
7341	else
7342	rdh = cDescs + rdh - pThis->iRxDCurrent;
7343	for (i = 0; i < pThis->nRxDFetched; ++i)
7344	{
7345	if (i == pThis->iRxDCurrent)
7346	pHlp->pfnPrintf(pHlp, ">>> ");
7347	pHlp->pfnPrintf(pHlp, "%RGp: %R[e1krxd]\n",
7348	e1kDescAddr(RDBAH, RDBAL, rdh++ % cDescs),
7349	&pThis->aRxDescriptors[i]);
7350	}
7351	#endif /* E1K_WITH_RXD_CACHE */
7352
7353	cDescs = TDLEN / sizeof(E1KTXDESC);
7354	uint32_t tdh = TDH;
7355	pHlp->pfnPrintf(pHlp, "\n-- Transmit Descriptors (%d total) --\n", cDescs);
7356	for (i = 0; i < cDescs; ++i)
7357	{
7358	E1KTXDESC desc;
7359	PDMDevHlpPhysRead(pDevIns, e1kDescAddr(TDBAH, TDBAL, i),
7360	&desc, sizeof(desc));
7361	if (i == tdh)
7362	pHlp->pfnPrintf(pHlp, ">>> ");
7363	pHlp->pfnPrintf(pHlp, "%RGp: %R[e1ktxd]\n", e1kDescAddr(TDBAH, TDBAL, i), &desc);
7364	}
7365	#ifdef E1K_WITH_TXD_CACHE
7366	pHlp->pfnPrintf(pHlp, "\n-- Transmit Descriptors in Cache (at %d (TDH %d)/ fetched %d / max %d) --\n",
7367	pThis->iTxDCurrent, TDH, pThis->nTxDFetched, E1K_TXD_CACHE_SIZE);
7368	if (tdh > pThis->iTxDCurrent)
7369	tdh -= pThis->iTxDCurrent;
7370	else
7371	tdh = cDescs + tdh - pThis->iTxDCurrent;
7372	for (i = 0; i < pThis->nTxDFetched; ++i)
7373	{
7374	if (i == pThis->iTxDCurrent)
7375	pHlp->pfnPrintf(pHlp, ">>> ");
7376	pHlp->pfnPrintf(pHlp, "%RGp: %R[e1ktxd]\n",
7377	e1kDescAddr(TDBAH, TDBAL, tdh++ % cDescs),
7378	&pThis->aTxDescriptors[i]);
7379	}
7380	#endif /* E1K_WITH_TXD_CACHE */
7381
7382
7383	#ifdef E1K_INT_STATS
7384	pHlp->pfnPrintf(pHlp, "Interrupt attempts: %d\n", pThis->uStatIntTry);
7385	pHlp->pfnPrintf(pHlp, "Interrupts raised : %d\n", pThis->uStatInt);
7386	pHlp->pfnPrintf(pHlp, "Interrupts lowered: %d\n", pThis->uStatIntLower);
7387	pHlp->pfnPrintf(pHlp, "ICR outside ISR : %d\n", pThis->uStatNoIntICR);
7388	pHlp->pfnPrintf(pHlp, "IMS raised ints : %d\n", pThis->uStatIntIMS);
7389	pHlp->pfnPrintf(pHlp, "Interrupts skipped: %d\n", pThis->uStatIntSkip);
7390	pHlp->pfnPrintf(pHlp, "Masked interrupts : %d\n", pThis->uStatIntMasked);
7391	pHlp->pfnPrintf(pHlp, "Early interrupts : %d\n", pThis->uStatIntEarly);
7392	pHlp->pfnPrintf(pHlp, "Late interrupts : %d\n", pThis->uStatIntLate);
7393	pHlp->pfnPrintf(pHlp, "Lost interrupts : %d\n", pThis->iStatIntLost);
7394	pHlp->pfnPrintf(pHlp, "Interrupts by RX : %d\n", pThis->uStatIntRx);
7395	pHlp->pfnPrintf(pHlp, "Interrupts by TX : %d\n", pThis->uStatIntTx);
7396	pHlp->pfnPrintf(pHlp, "Interrupts by ICS : %d\n", pThis->uStatIntICS);
7397	pHlp->pfnPrintf(pHlp, "Interrupts by RDTR: %d\n", pThis->uStatIntRDTR);
7398	pHlp->pfnPrintf(pHlp, "Interrupts by RDMT: %d\n", pThis->uStatIntRXDMT0);
7399	pHlp->pfnPrintf(pHlp, "Interrupts by TXQE: %d\n", pThis->uStatIntTXQE);
7400	pHlp->pfnPrintf(pHlp, "TX int delay asked: %d\n", pThis->uStatTxIDE);
7401	pHlp->pfnPrintf(pHlp, "TX delayed: %d\n", pThis->uStatTxDelayed);
7402	pHlp->pfnPrintf(pHlp, "TX delayed expired: %d\n", pThis->uStatTxDelayExp);
7403	pHlp->pfnPrintf(pHlp, "TX no report asked: %d\n", pThis->uStatTxNoRS);
7404	pHlp->pfnPrintf(pHlp, "TX abs timer expd : %d\n", pThis->uStatTAD);
7405	pHlp->pfnPrintf(pHlp, "TX int timer expd : %d\n", pThis->uStatTID);
7406	pHlp->pfnPrintf(pHlp, "RX abs timer expd : %d\n", pThis->uStatRAD);
7407	pHlp->pfnPrintf(pHlp, "RX int timer expd : %d\n", pThis->uStatRID);
7408	pHlp->pfnPrintf(pHlp, "TX CTX descriptors: %d\n", pThis->uStatDescCtx);
7409	pHlp->pfnPrintf(pHlp, "TX DAT descriptors: %d\n", pThis->uStatDescDat);
7410	pHlp->pfnPrintf(pHlp, "TX LEG descriptors: %d\n", pThis->uStatDescLeg);
7411	pHlp->pfnPrintf(pHlp, "Received frames : %d\n", pThis->uStatRxFrm);
7412	pHlp->pfnPrintf(pHlp, "Transmitted frames: %d\n", pThis->uStatTxFrm);
7413	pHlp->pfnPrintf(pHlp, "TX frames up to 1514: %d\n", pThis->uStatTx1514);
7414	pHlp->pfnPrintf(pHlp, "TX frames up to 2962: %d\n", pThis->uStatTx2962);
7415	pHlp->pfnPrintf(pHlp, "TX frames up to 4410: %d\n", pThis->uStatTx4410);
7416	pHlp->pfnPrintf(pHlp, "TX frames up to 5858: %d\n", pThis->uStatTx5858);
7417	pHlp->pfnPrintf(pHlp, "TX frames up to 7306: %d\n", pThis->uStatTx7306);
7418	pHlp->pfnPrintf(pHlp, "TX frames up to 8754: %d\n", pThis->uStatTx8754);
7419	pHlp->pfnPrintf(pHlp, "TX frames up to 16384: %d\n", pThis->uStatTx16384);
7420	pHlp->pfnPrintf(pHlp, "TX frames up to 32768: %d\n", pThis->uStatTx32768);
7421	pHlp->pfnPrintf(pHlp, "Larger TX frames : %d\n", pThis->uStatTxLarge);
7422	#endif /* E1K_INT_STATS */
7423
7424	e1kCsLeave(pThis);
7425	}
7426
7427
7428
7429	/* -=-=-=-=- PDMDEVREG -=-=-=-=- */
7430
7431	/**
7432	* Detach notification.
7433	*
7434	* One port on the network card has been disconnected from the network.
7435	*
7436	* @param pDevIns The device instance.
7437	* @param iLUN The logical unit which is being detached.
7438	* @param fFlags Flags, combination of the PDMDEVATT_FLAGS_* \#defines.
7439	*/
7440	static DECLCALLBACK(void) e1kR3Detach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags)
7441	{
7442	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7443	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
7444	Log(("%s e1kR3Detach:\n", pThis->szPrf));
7445	RT_NOREF(fFlags);
7446
7447	AssertLogRelReturnVoid(iLUN == 0);
7448
7449	PDMDevHlpCritSectEnter(pDevIns, &pThis->cs, VERR_SEM_BUSY);
7450
7451	/** @todo r=pritesh still need to check if i missed
7452	* to clean something in this function
7453	*/
7454
7455	/*
7456	* Zero some important members.
7457	*/
7458	pThisCC->pDrvBase = NULL;
7459	pThisCC->pDrvR3 = NULL;
7460	#if 0 /** @todo @bugref{9218} ring-0 driver stuff */
7461	pThisR0->pDrvR0 = NIL_RTR0PTR;
7462	pThisRC->pDrvRC = NIL_RTRCPTR;
7463	#endif
7464
7465	PDMDevHlpCritSectLeave(pDevIns, &pThis->cs);
7466	}
7467
7468	/**
7469	* Attach the Network attachment.
7470	*
7471	* One port on the network card has been connected to a network.
7472	*
7473	* @returns VBox status code.
7474	* @param pDevIns The device instance.
7475	* @param iLUN The logical unit which is being attached.
7476	* @param fFlags Flags, combination of the PDMDEVATT_FLAGS_* \#defines.
7477	*
7478	* @remarks This code path is not used during construction.
7479	*/
7480	static DECLCALLBACK(int) e1kR3Attach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags)
7481	{
7482	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7483	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
7484	LogFlow(("%s e1kR3Attach:\n", pThis->szPrf));
7485	RT_NOREF(fFlags);
7486
7487	AssertLogRelReturn(iLUN == 0, VERR_PDM_NO_SUCH_LUN);
7488
7489	PDMDevHlpCritSectEnter(pDevIns, &pThis->cs, VERR_SEM_BUSY);
7490
7491	/*
7492	* Attach the driver.
7493	*/
7494	int rc = PDMDevHlpDriverAttach(pDevIns, 0, &pThisCC->IBase, &pThisCC->pDrvBase, "Network Port");
7495	if (RT_SUCCESS(rc))
7496	{
7497	pThisCC->pDrvR3 = PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMINETWORKUP);
7498	AssertMsgStmt(pThisCC->pDrvR3, ("Failed to obtain the PDMINETWORKUP interface!\n"),
7499	rc = VERR_PDM_MISSING_INTERFACE_BELOW);
7500	if (RT_SUCCESS(rc))
7501	{
7502	#if 0 /** @todo @bugref{9218} ring-0 driver stuff */
7503	pThisR0->pDrvR0 = PDMIBASER0_QUERY_INTERFACE(PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMIBASER0), PDMINETWORKUP);
7504	pThisRC->pDrvRC = PDMIBASERC_QUERY_INTERFACE(PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMIBASERC), PDMINETWORKUP);
7505	#endif
7506	}
7507	}
7508	else if ( rc == VERR_PDM_NO_ATTACHED_DRIVER
7509	\|\| rc == VERR_PDM_CFG_MISSING_DRIVER_NAME)
7510	{
7511	/* This should never happen because this function is not called
7512	* if there is no driver to attach! */
7513	Log(("%s No attached driver!\n", pThis->szPrf));
7514	}
7515
7516	/*
7517	* Temporary set the link down if it was up so that the guest will know
7518	* that we have change the configuration of the network card
7519	*/
7520	if ((STATUS & STATUS_LU) && RT_SUCCESS(rc))
7521	e1kR3LinkDownTemp(pDevIns, pThis, pThisCC);
7522
7523	PDMDevHlpCritSectLeave(pDevIns, &pThis->cs);
7524	return rc;
7525	}
7526
7527	/**
7528	* @copydoc FNPDMDEVPOWEROFF
7529	*/
7530	static DECLCALLBACK(void) e1kR3PowerOff(PPDMDEVINS pDevIns)
7531	{
7532	/* Poke thread waiting for buffer space. */
7533	e1kWakeupReceive(pDevIns, PDMDEVINS_2_DATA(pDevIns, PE1KSTATE));
7534	}
7535
7536	/**
7537	* @copydoc FNPDMDEVRESET
7538	*/
7539	static DECLCALLBACK(void) e1kR3Reset(PPDMDEVINS pDevIns)
7540	{
7541	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7542	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
7543	#ifdef E1K_TX_DELAY
7544	e1kCancelTimer(pDevIns, pThis, pThis->hTXDTimer);
7545	#endif /* E1K_TX_DELAY */
7546	e1kCancelTimer(pDevIns, pThis, pThis->hIntTimer);
7547	e1kCancelTimer(pDevIns, pThis, pThis->hLUTimer);
7548	e1kXmitFreeBuf(pThis, pThisCC);
7549	pThis->u16TxPktLen = 0;
7550	pThis->fIPcsum = false;
7551	pThis->fTCPcsum = false;
7552	pThis->fIntMaskUsed = false;
7553	pThis->fDelayInts = false;
7554	pThis->fLocked = false;
7555	pThis->u64AckedAt = 0;
7556	e1kR3HardReset(pDevIns, pThis, pThisCC);
7557	}
7558
7559	/**
7560	* @copydoc FNPDMDEVSUSPEND
7561	*/
7562	static DECLCALLBACK(void) e1kR3Suspend(PPDMDEVINS pDevIns)
7563	{
7564	/* Poke thread waiting for buffer space. */
7565	e1kWakeupReceive(pDevIns, PDMDEVINS_2_DATA(pDevIns, PE1KSTATE));
7566	}
7567
7568	/**
7569	* Device relocation callback.
7570	*
7571	* When this callback is called the device instance data, and if the
7572	* device have a GC component, is being relocated, or/and the selectors
7573	* have been changed. The device must use the chance to perform the
7574	* necessary pointer relocations and data updates.
7575	*
7576	* Before the GC code is executed the first time, this function will be
7577	* called with a 0 delta so GC pointer calculations can be one in one place.
7578	*
7579	* @param pDevIns Pointer to the device instance.
7580	* @param offDelta The relocation delta relative to the old location.
7581	*
7582	* @remark A relocation CANNOT fail.
7583	*/
7584	static DECLCALLBACK(void) e1kR3Relocate(PPDMDEVINS pDevIns, RTGCINTPTR offDelta)
7585	{
7586	PE1KSTATERC pThisRC = PDMINS_2_DATA_RC(pDevIns, PE1KSTATERC);
7587	if (pThisRC)
7588	pThisRC->pDevInsRC = PDMDEVINS_2_RCPTR(pDevIns);
7589	RT_NOREF(offDelta);
7590	}
7591
7592	/**
7593	* Destruct a device instance.
7594	*
7595	* We need to free non-VM resources only.
7596	*
7597	* @returns VBox status code.
7598	* @param pDevIns The device instance data.
7599	* @thread EMT
7600	*/
7601	static DECLCALLBACK(int) e1kR3Destruct(PPDMDEVINS pDevIns)
7602	{
7603	PDMDEV_CHECK_VERSIONS_RETURN_QUIET(pDevIns);
7604	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7605
7606	e1kDumpState(pThis);
7607	E1kLog(("%s Destroying instance\n", pThis->szPrf));
7608	if (PDMDevHlpCritSectIsInitialized(pDevIns, &pThis->cs))
7609	{
7610	if (pThis->hEventMoreRxDescAvail != NIL_SUPSEMEVENT)
7611	{
7612	PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEventMoreRxDescAvail);
7613	RTThreadYield();
7614	PDMDevHlpSUPSemEventClose(pDevIns, pThis->hEventMoreRxDescAvail);
7615	pThis->hEventMoreRxDescAvail = NIL_SUPSEMEVENT;
7616	}
7617	#ifdef E1K_WITH_TX_CS
7618	PDMDevHlpCritSectDelete(pDevIns, &pThis->csTx);
7619	#endif /* E1K_WITH_TX_CS */
7620	PDMDevHlpCritSectDelete(pDevIns, &pThis->csRx);
7621	PDMDevHlpCritSectDelete(pDevIns, &pThis->cs);
7622	}
7623	return VINF_SUCCESS;
7624	}
7625
7626
7627	/**
7628	* Set PCI configuration space registers.
7629	*
7630	* @param pci Reference to PCI device structure.
7631	* @thread EMT
7632	*/
7633	static void e1kR3ConfigurePciDev(PPDMPCIDEV pPciDev, E1KCHIP eChip)
7634	{
7635	Assert(eChip < RT_ELEMENTS(g_aChips));
7636	/* Configure PCI Device, assume 32-bit mode ******************************/
7637	PDMPciDevSetVendorId(pPciDev, g_aChips[eChip].uPCIVendorId);
7638	PDMPciDevSetDeviceId(pPciDev, g_aChips[eChip].uPCIDeviceId);
7639	PDMPciDevSetWord( pPciDev, VBOX_PCI_SUBSYSTEM_VENDOR_ID, g_aChips[eChip].uPCISubsystemVendorId);
7640	PDMPciDevSetWord( pPciDev, VBOX_PCI_SUBSYSTEM_ID, g_aChips[eChip].uPCISubsystemId);
7641
7642	PDMPciDevSetWord( pPciDev, VBOX_PCI_COMMAND, 0x0000);
7643	/* DEVSEL Timing (medium device), 66 MHz Capable, New capabilities */
7644	PDMPciDevSetWord( pPciDev, VBOX_PCI_STATUS,
7645	VBOX_PCI_STATUS_DEVSEL_MEDIUM \| VBOX_PCI_STATUS_CAP_LIST \| VBOX_PCI_STATUS_66MHZ);
7646	/* Stepping A2 */
7647	PDMPciDevSetByte( pPciDev, VBOX_PCI_REVISION_ID, 0x02);
7648	/* Ethernet adapter */
7649	PDMPciDevSetByte( pPciDev, VBOX_PCI_CLASS_PROG, 0x00);
7650	PDMPciDevSetWord( pPciDev, VBOX_PCI_CLASS_DEVICE, 0x0200);
7651	/* normal single function Ethernet controller */
7652	PDMPciDevSetByte( pPciDev, VBOX_PCI_HEADER_TYPE, 0x00);
7653	/* Memory Register Base Address */
7654	PDMPciDevSetDWord(pPciDev, VBOX_PCI_BASE_ADDRESS_0, 0x00000000);
7655	/* Memory Flash Base Address */
7656	PDMPciDevSetDWord(pPciDev, VBOX_PCI_BASE_ADDRESS_1, 0x00000000);
7657	/* IO Register Base Address */
7658	PDMPciDevSetDWord(pPciDev, VBOX_PCI_BASE_ADDRESS_2, 0x00000001);
7659	/* Expansion ROM Base Address */
7660	PDMPciDevSetDWord(pPciDev, VBOX_PCI_ROM_ADDRESS, 0x00000000);
7661	/* Capabilities Pointer */
7662	PDMPciDevSetByte( pPciDev, VBOX_PCI_CAPABILITY_LIST, 0xDC);
7663	/* Interrupt Pin: INTA# */
7664	PDMPciDevSetByte( pPciDev, VBOX_PCI_INTERRUPT_PIN, 0x01);
7665	/* Max_Lat/Min_Gnt: very high priority and time slice */
7666	PDMPciDevSetByte( pPciDev, VBOX_PCI_MIN_GNT, 0xFF);
7667	PDMPciDevSetByte( pPciDev, VBOX_PCI_MAX_LAT, 0x00);
7668
7669	/* PCI Power Management Registers ****************************************/
7670	/* Capability ID: PCI Power Management Registers */
7671	PDMPciDevSetByte( pPciDev, 0xDC, VBOX_PCI_CAP_ID_PM);
7672	/* Next Item Pointer: PCI-X */
7673	PDMPciDevSetByte( pPciDev, 0xDC + 1, 0xE4);
7674	/* Power Management Capabilities: PM disabled, DSI */
7675	PDMPciDevSetWord( pPciDev, 0xDC + 2,
7676	0x0002 \| VBOX_PCI_PM_CAP_DSI);
7677	/* Power Management Control / Status Register: PM disabled */
7678	PDMPciDevSetWord( pPciDev, 0xDC + 4, 0x0000);
7679	/* PMCSR_BSE Bridge Support Extensions: Not supported */
7680	PDMPciDevSetByte( pPciDev, 0xDC + 6, 0x00);
7681	/* Data Register: PM disabled, always 0 */
7682	PDMPciDevSetByte( pPciDev, 0xDC + 7, 0x00);
7683
7684	/* PCI-X Configuration Registers *****************************************/
7685	/* Capability ID: PCI-X Configuration Registers */
7686	PDMPciDevSetByte( pPciDev, 0xE4, VBOX_PCI_CAP_ID_PCIX);
7687	#ifdef E1K_WITH_MSI
7688	PDMPciDevSetByte( pPciDev, 0xE4 + 1, 0x80);
7689	#else
7690	/* Next Item Pointer: None (Message Signalled Interrupts are disabled) */
7691	PDMPciDevSetByte( pPciDev, 0xE4 + 1, 0x00);
7692	#endif
7693	/* PCI-X Command: Enable Relaxed Ordering */
7694	PDMPciDevSetWord( pPciDev, 0xE4 + 2, VBOX_PCI_X_CMD_ERO);
7695	/* PCI-X Status: 32-bit, 66MHz*/
7696	/** @todo is this value really correct? fff8 doesn't look like actual PCI address */
7697	PDMPciDevSetDWord(pPciDev, 0xE4 + 4, 0x0040FFF8);
7698	}
7699
7700	/**
7701	* @interface_method_impl{PDMDEVREG,pfnConstruct}
7702	*/
7703	static DECLCALLBACK(int) e1kR3Construct(PPDMDEVINS pDevIns, int iInstance, PCFGMNODE pCfg)
7704	{
7705	PDMDEV_CHECK_VERSIONS_RETURN(pDevIns);
7706	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
7707	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
7708	int rc;
7709
7710	/*
7711	* Initialize the instance data (state).
7712	* Note! Caller has initialized it to ZERO already.
7713	*/
7714	RTStrPrintf(pThis->szPrf, sizeof(pThis->szPrf), "E1000#%d", iInstance);
7715	E1kLog(("%s Constructing new instance sizeof(E1KRXDESC)=%d\n", pThis->szPrf, sizeof(E1KRXDESC)));
7716	pThis->hEventMoreRxDescAvail = NIL_SUPSEMEVENT;
7717	pThis->u16TxPktLen = 0;
7718	pThis->fIPcsum = false;
7719	pThis->fTCPcsum = false;
7720	pThis->fIntMaskUsed = false;
7721	pThis->fDelayInts = false;
7722	pThis->fLocked = false;
7723	pThis->u64AckedAt = 0;
7724	pThis->led.u32Magic = PDMLED_MAGIC;
7725	pThis->u32PktNo = 1;
7726
7727	pThisCC->pDevInsR3 = pDevIns;
7728	pThisCC->pShared = pThis;
7729
7730	/* Interfaces */
7731	pThisCC->IBase.pfnQueryInterface = e1kR3QueryInterface;
7732
7733	pThisCC->INetworkDown.pfnWaitReceiveAvail = e1kR3NetworkDown_WaitReceiveAvail;
7734	pThisCC->INetworkDown.pfnReceive = e1kR3NetworkDown_Receive;
7735	pThisCC->INetworkDown.pfnXmitPending = e1kR3NetworkDown_XmitPending;
7736
7737	pThisCC->ILeds.pfnQueryStatusLed = e1kR3QueryStatusLed;
7738
7739	pThisCC->INetworkConfig.pfnGetMac = e1kR3GetMac;
7740	pThisCC->INetworkConfig.pfnGetLinkState = e1kR3GetLinkState;
7741	pThisCC->INetworkConfig.pfnSetLinkState = e1kR3SetLinkState;
7742
7743	/*
7744	* Internal validations.
7745	*/
7746	for (uint32_t iReg = 1; iReg < E1K_NUM_OF_BINARY_SEARCHABLE; iReg++)
7747	AssertLogRelMsgReturn( g_aE1kRegMap[iReg].offset > g_aE1kRegMap[iReg - 1].offset
7748	&& g_aE1kRegMap[iReg].offset + g_aE1kRegMap[iReg].size
7749	>= g_aE1kRegMap[iReg - 1].offset + g_aE1kRegMap[iReg - 1].size,
7750	("%s@%#xLB%#x vs %s@%#xLB%#x\n",
7751	g_aE1kRegMap[iReg].abbrev, g_aE1kRegMap[iReg].offset, g_aE1kRegMap[iReg].size,
7752	g_aE1kRegMap[iReg - 1].abbrev, g_aE1kRegMap[iReg - 1].offset, g_aE1kRegMap[iReg - 1].size),
7753	VERR_INTERNAL_ERROR_4);
7754
7755	/*
7756	* Validate configuration.
7757	*/
7758	PDMDEV_VALIDATE_CONFIG_RETURN(pDevIns,
7759	"MAC\|"
7760	"CableConnected\|"
7761	"AdapterType\|"
7762	"LineSpeed\|"
7763	"ItrEnabled\|"
7764	"ItrRxEnabled\|"
7765	"EthernetCRC\|"
7766	"GSOEnabled\|"
7767	"LinkUpDelay\|"
7768	"StatNo",
7769	"");
7770
7771	/** @todo LineSpeed unused! */
7772
7773	/*
7774	* Get config params
7775	*/
7776	PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3;
7777	rc = pHlp->pfnCFGMQueryBytes(pCfg, "MAC", pThis->macConfigured.au8, sizeof(pThis->macConfigured.au8));
7778	if (RT_FAILURE(rc))
7779	return PDMDEV_SET_ERROR(pDevIns, rc,
7780	N_("Configuration error: Failed to get MAC address"));
7781	rc = pHlp->pfnCFGMQueryBool(pCfg, "CableConnected", &pThis->fCableConnected);
7782	if (RT_FAILURE(rc))
7783	return PDMDEV_SET_ERROR(pDevIns, rc,
7784	N_("Configuration error: Failed to get the value of 'CableConnected'"));
7785	rc = pHlp->pfnCFGMQueryU32(pCfg, "AdapterType", (uint32_t*)&pThis->eChip);
7786	if (RT_FAILURE(rc))
7787	return PDMDEV_SET_ERROR(pDevIns, rc,
7788	N_("Configuration error: Failed to get the value of 'AdapterType'"));
7789	Assert(pThis->eChip <= E1K_CHIP_82545EM);
7790
7791	rc = pHlp->pfnCFGMQueryBoolDef(pCfg, "EthernetCRC", &pThis->fEthernetCRC, true);
7792	if (RT_FAILURE(rc))
7793	return PDMDEV_SET_ERROR(pDevIns, rc,
7794	N_("Configuration error: Failed to get the value of 'EthernetCRC'"));
7795
7796	rc = pHlp->pfnCFGMQueryBoolDef(pCfg, "GSOEnabled", &pThis->fGSOEnabled, true);
7797	if (RT_FAILURE(rc))
7798	return PDMDEV_SET_ERROR(pDevIns, rc,
7799	N_("Configuration error: Failed to get the value of 'GSOEnabled'"));
7800
7801	rc = pHlp->pfnCFGMQueryBoolDef(pCfg, "ItrEnabled", &pThis->fItrEnabled, false);
7802	if (RT_FAILURE(rc))
7803	return PDMDEV_SET_ERROR(pDevIns, rc,
7804	N_("Configuration error: Failed to get the value of 'ItrEnabled'"));
7805
7806	rc = pHlp->pfnCFGMQueryBoolDef(pCfg, "ItrRxEnabled", &pThis->fItrRxEnabled, true);
7807	if (RT_FAILURE(rc))
7808	return PDMDEV_SET_ERROR(pDevIns, rc,
7809	N_("Configuration error: Failed to get the value of 'ItrRxEnabled'"));
7810
7811	rc = pHlp->pfnCFGMQueryBoolDef(pCfg, "TidEnabled", &pThis->fTidEnabled, false);
7812	if (RT_FAILURE(rc))
7813	return PDMDEV_SET_ERROR(pDevIns, rc,
7814	N_("Configuration error: Failed to get the value of 'TidEnabled'"));
7815
7816	rc = pHlp->pfnCFGMQueryU32Def(pCfg, "LinkUpDelay", (uint32_t)&pThis->cMsLinkUpDelay, 3000); / ms */
7817	if (RT_FAILURE(rc))
7818	return PDMDEV_SET_ERROR(pDevIns, rc,
7819	N_("Configuration error: Failed to get the value of 'LinkUpDelay'"));
7820	Assert(pThis->cMsLinkUpDelay <= 300000); /* less than 5 minutes */
7821	if (pThis->cMsLinkUpDelay > 5000)
7822	LogRel(("%s: WARNING! Link up delay is set to %u seconds!\n", pThis->szPrf, pThis->cMsLinkUpDelay / 1000));
7823	else if (pThis->cMsLinkUpDelay == 0)
7824	LogRel(("%s: WARNING! Link up delay is disabled!\n", pThis->szPrf));
7825
7826	uint32_t uStatNo = (uint32_t)iInstance;
7827	rc = pHlp->pfnCFGMQueryU32Def(pCfg, "StatNo", &uStatNo, (uint32_t)iInstance);
7828	if (RT_FAILURE(rc))
7829	return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to get the \"StatNo\" value"));
7830
7831	LogRel(("%s: Chip=%s LinkUpDelay=%ums EthernetCRC=%s GSO=%s Itr=%s ItrRx=%s TID=%s R0=%s RC=%s\n", pThis->szPrf,
7832	g_aChips[pThis->eChip].pcszName, pThis->cMsLinkUpDelay,
7833	pThis->fEthernetCRC ? "on" : "off",
7834	pThis->fGSOEnabled ? "enabled" : "disabled",
7835	pThis->fItrEnabled ? "enabled" : "disabled",
7836	pThis->fItrRxEnabled ? "enabled" : "disabled",
7837	pThis->fTidEnabled ? "enabled" : "disabled",
7838	pDevIns->fR0Enabled ? "enabled" : "disabled",
7839	pDevIns->fRCEnabled ? "enabled" : "disabled"));
7840
7841	/*
7842	* Initialize sub-components and register everything with the VMM.
7843	*/
7844
7845	/* Initialize the EEPROM. */
7846	pThisCC->eeprom.init(pThis->macConfigured);
7847
7848	/* Initialize internal PHY. */
7849	Phy::init(&pThis->phy, iInstance, pThis->eChip == E1K_CHIP_82543GC ? PHY_EPID_M881000 : PHY_EPID_M881011);
7850
7851	/* Initialize critical sections. We do our own locking. */
7852	rc = PDMDevHlpSetDeviceCritSect(pDevIns, PDMDevHlpCritSectGetNop(pDevIns));
7853	AssertRCReturn(rc, rc);
7854
7855	rc = PDMDevHlpCritSectInit(pDevIns, &pThis->cs, RT_SRC_POS, "E1000#%d", iInstance);
7856	AssertRCReturn(rc, rc);
7857	rc = PDMDevHlpCritSectInit(pDevIns, &pThis->csRx, RT_SRC_POS, "E1000#%dRX", iInstance);
7858	AssertRCReturn(rc, rc);
7859	#ifdef E1K_WITH_TX_CS
7860	rc = PDMDevHlpCritSectInit(pDevIns, &pThis->csTx, RT_SRC_POS, "E1000#%dTX", iInstance);
7861	AssertRCReturn(rc, rc);
7862	#endif
7863
7864	/* Saved state registration. */
7865	rc = PDMDevHlpSSMRegisterEx(pDevIns, E1K_SAVEDSTATE_VERSION, sizeof(E1KSTATE), NULL,
7866	NULL, e1kLiveExec, NULL,
7867	e1kSavePrep, e1kSaveExec, NULL,
7868	e1kLoadPrep, e1kLoadExec, e1kLoadDone);
7869	AssertRCReturn(rc, rc);
7870
7871	/* Set PCI config registers and register ourselves with the PCI bus. */
7872	PDMPCIDEV_ASSERT_VALID(pDevIns, pDevIns->apPciDevs[0]);
7873	e1kR3ConfigurePciDev(pDevIns->apPciDevs[0], pThis->eChip);
7874	rc = PDMDevHlpPCIRegister(pDevIns, pDevIns->apPciDevs[0]);
7875	AssertRCReturn(rc, rc);
7876
7877	#ifdef E1K_WITH_MSI
7878	PDMMSIREG MsiReg;
7879	RT_ZERO(MsiReg);
7880	MsiReg.cMsiVectors = 1;
7881	MsiReg.iMsiCapOffset = 0x80;
7882	MsiReg.iMsiNextOffset = 0x0;
7883	MsiReg.fMsi64bit = false;
7884	rc = PDMDevHlpPCIRegisterMsi(pDevIns, &MsiReg);
7885	AssertRCReturn(rc, rc);
7886	#endif
7887
7888	/*
7889	* Map our registers to memory space (region 0, see e1kR3ConfigurePciDev)
7890	* From the spec (regarding flags):
7891	* For registers that should be accessed as 32-bit double words,
7892	* partial writes (less than a 32-bit double word) is ignored.
7893	* Partial reads return all 32 bits of data regardless of the
7894	* byte enables.
7895	*/
7896	rc = PDMDevHlpMmioCreateEx(pDevIns, E1K_MM_SIZE, IOMMMIO_FLAGS_READ_DWORD \| IOMMMIO_FLAGS_WRITE_ONLY_DWORD,
7897	pDevIns->apPciDevs[0], 0 /iPciRegion/,
7898	e1kMMIOWrite, e1kMMIORead, NULL /pfnFill/, NULL /pvUser/, "E1000", &pThis->hMmioRegion);
7899	AssertRCReturn(rc, rc);
7900	rc = PDMDevHlpPCIIORegionRegisterMmio(pDevIns, 0, E1K_MM_SIZE, PCI_ADDRESS_SPACE_MEM, pThis->hMmioRegion, NULL);
7901	AssertRCReturn(rc, rc);
7902
7903	/* Map our registers to IO space (region 2, see e1kR3ConfigurePciDev) */
7904	static IOMIOPORTDESC const s_aExtDescs[] =
7905	{
7906	{ "IOADDR", "IOADDR", NULL, NULL }, { "unused", "unused", NULL, NULL }, { "unused", "unused", NULL, NULL }, { "unused", "unused", NULL, NULL },
7907	{ "IODATA", "IODATA", NULL, NULL }, { "unused", "unused", NULL, NULL }, { "unused", "unused", NULL, NULL }, { "unused", "unused", NULL, NULL },
7908	{ NULL, NULL, NULL, NULL }
7909	};
7910	rc = PDMDevHlpIoPortCreate(pDevIns, E1K_IOPORT_SIZE, pDevIns->apPciDevs[0], 2 /iPciRegion/,
7911	e1kIOPortOut, e1kIOPortIn, NULL /pvUser/, "E1000", s_aExtDescs, &pThis->hIoPorts);
7912	AssertRCReturn(rc, rc);
7913	rc = PDMDevHlpPCIIORegionRegisterIo(pDevIns, 2, E1K_IOPORT_SIZE, pThis->hIoPorts);
7914	AssertRCReturn(rc, rc);
7915
7916	/* Create transmit queue */
7917	rc = PDMDevHlpTaskCreate(pDevIns, PDMTASK_F_RZ, "E1000-Xmit", e1kR3TxTaskCallback, NULL, &pThis->hTxTask);
7918	AssertRCReturn(rc, rc);
7919
7920	#ifdef E1K_TX_DELAY
7921	/* Create Transmit Delay Timer */
7922	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3TxDelayTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7923	"E1000 Transmit Delay Timer", &pThis->hTXDTimer);
7924	AssertRCReturn(rc, rc);
7925	rc = PDMDevHlpTimerSetCritSect(pDevIns, pThis->hTXDTimer, &pThis->csTx);
7926	AssertRCReturn(rc, rc);
7927	#endif /* E1K_TX_DELAY */
7928
7929	//#ifdef E1K_USE_TX_TIMERS
7930	if (pThis->fTidEnabled)
7931	{
7932	/* Create Transmit Interrupt Delay Timer */
7933	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3TxIntDelayTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7934	"E1000 Transmit Interrupt Delay Timer", &pThis->hTIDTimer);
7935	AssertRCReturn(rc, rc);
7936
7937	# ifndef E1K_NO_TAD
7938	/* Create Transmit Absolute Delay Timer */
7939	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3TxAbsDelayTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7940	"E1000 Transmit Absolute Delay Timer", &pThis->hTADTimer);
7941	AssertRCReturn(rc, rc);
7942	# endif /* E1K_NO_TAD */
7943	}
7944	//#endif /* E1K_USE_TX_TIMERS */
7945
7946	#ifdef E1K_USE_RX_TIMERS
7947	/* Create Receive Interrupt Delay Timer */
7948	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3RxIntDelayTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7949	"E1000 Receive Interrupt Delay Timer", &pThis->hRIDTimer);
7950	AssertRCReturn(rc, rc);
7951
7952	/* Create Receive Absolute Delay Timer */
7953	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3RxAbsDelayTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7954	"E1000 Receive Absolute Delay Timer", &pThis->hRADTimer);
7955	AssertRCReturn(rc, rc);
7956	#endif /* E1K_USE_RX_TIMERS */
7957
7958	/* Create Late Interrupt Timer */
7959	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3LateIntTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7960	"E1000 Late Interrupt Timer", &pThis->hIntTimer);
7961	AssertRCReturn(rc, rc);
7962
7963	/* Create Link Up Timer */
7964	rc = PDMDevHlpTimerCreate(pDevIns, TMCLOCK_VIRTUAL, e1kR3LinkUpTimer, pThis, TMTIMER_FLAGS_NO_CRIT_SECT,
7965	"E1000 Link Up Timer", &pThis->hLUTimer);
7966	AssertRCReturn(rc, rc);
7967
7968	/* Register the info item */
7969	char szTmp[20];
7970	RTStrPrintf(szTmp, sizeof(szTmp), "e1k%d", iInstance);
7971	PDMDevHlpDBGFInfoRegister(pDevIns, szTmp, "E1000 info.", e1kInfo);
7972
7973	/* Status driver */
7974	PPDMIBASE pBase;
7975	rc = PDMDevHlpDriverAttach(pDevIns, PDM_STATUS_LUN, &pThisCC->IBase, &pBase, "Status Port");
7976	if (RT_FAILURE(rc))
7977	return PDMDEV_SET_ERROR(pDevIns, rc, N_("Failed to attach the status LUN"));
7978	pThisCC->pLedsConnector = PDMIBASE_QUERY_INTERFACE(pBase, PDMILEDCONNECTORS);
7979
7980	/* Network driver */
7981	rc = PDMDevHlpDriverAttach(pDevIns, 0, &pThisCC->IBase, &pThisCC->pDrvBase, "Network Port");
7982	if (RT_SUCCESS(rc))
7983	{
7984	pThisCC->pDrvR3 = PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMINETWORKUP);
7985	AssertMsgReturn(pThisCC->pDrvR3, ("Failed to obtain the PDMINETWORKUP interface!\n"), VERR_PDM_MISSING_INTERFACE_BELOW);
7986
7987	#if 0 /** @todo @bugref{9218} ring-0 driver stuff */
7988	pThisR0->pDrvR0 = PDMIBASER0_QUERY_INTERFACE(PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMIBASER0), PDMINETWORKUP);
7989	pThisRC->pDrvRC = PDMIBASERC_QUERY_INTERFACE(PDMIBASE_QUERY_INTERFACE(pThisCC->pDrvBase, PDMIBASERC), PDMINETWORKUP);
7990	#endif
7991	}
7992	else if ( rc == VERR_PDM_NO_ATTACHED_DRIVER
7993	\|\| rc == VERR_PDM_CFG_MISSING_DRIVER_NAME)
7994	{
7995	/* No error! */
7996	E1kLog(("%s This adapter is not attached to any network!\n", pThis->szPrf));
7997	}
7998	else
7999	return PDMDEV_SET_ERROR(pDevIns, rc, N_("Failed to attach the network LUN"));
8000
8001	rc = PDMDevHlpSUPSemEventCreate(pDevIns, &pThis->hEventMoreRxDescAvail);
8002	AssertRCReturn(rc, rc);
8003
8004	rc = e1kInitDebugHelpers();
8005	AssertRCReturn(rc, rc);
8006
8007	e1kR3HardReset(pDevIns, pThis, pThisCC);
8008
8009	/*
8010	* Register statistics.
8011	* The /Public/ bits are official and used by session info in the GUI.
8012	*/
8013	PDMDevHlpSTAMRegisterF(pDevIns, &pThis->StatReceiveBytes, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_BYTES,
8014	"Amount of data received", "/Public/NetAdapter/%u/BytesReceived", uStatNo);
8015	PDMDevHlpSTAMRegisterF(pDevIns, &pThis->StatTransmitBytes, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_BYTES,
8016	"Amount of data transmitted", "/Public/NetAdapter/%u/BytesTransmitted", uStatNo);
8017	PDMDevHlpSTAMRegisterF(pDevIns, &pDevIns->iInstance, STAMTYPE_U32, STAMVISIBILITY_ALWAYS, STAMUNIT_NONE,
8018	"Device instance number", "/Public/NetAdapter/%u/%s", uStatNo, pDevIns->pReg->szName);
8019
8020	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatReceiveBytes, STAMTYPE_COUNTER, "ReceiveBytes", STAMUNIT_BYTES, "Amount of data received");
8021	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTransmitBytes, STAMTYPE_COUNTER, "TransmitBytes", STAMUNIT_BYTES, "Amount of data transmitted");
8022
8023	#if defined(VBOX_WITH_STATISTICS)
8024	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatMMIOReadRZ, STAMTYPE_PROFILE, "MMIO/ReadRZ", STAMUNIT_TICKS_PER_CALL, "Profiling MMIO reads in RZ");
8025	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatMMIOReadR3, STAMTYPE_PROFILE, "MMIO/ReadR3", STAMUNIT_TICKS_PER_CALL, "Profiling MMIO reads in R3");
8026	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatMMIOWriteRZ, STAMTYPE_PROFILE, "MMIO/WriteRZ", STAMUNIT_TICKS_PER_CALL, "Profiling MMIO writes in RZ");
8027	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatMMIOWriteR3, STAMTYPE_PROFILE, "MMIO/WriteR3", STAMUNIT_TICKS_PER_CALL, "Profiling MMIO writes in R3");
8028	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatEEPROMRead, STAMTYPE_PROFILE, "EEPROM/Read", STAMUNIT_TICKS_PER_CALL, "Profiling EEPROM reads");
8029	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatEEPROMWrite, STAMTYPE_PROFILE, "EEPROM/Write", STAMUNIT_TICKS_PER_CALL, "Profiling EEPROM writes");
8030	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIOReadRZ, STAMTYPE_PROFILE, "IO/ReadRZ", STAMUNIT_TICKS_PER_CALL, "Profiling IO reads in RZ");
8031	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIOReadR3, STAMTYPE_PROFILE, "IO/ReadR3", STAMUNIT_TICKS_PER_CALL, "Profiling IO reads in R3");
8032	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIOWriteRZ, STAMTYPE_PROFILE, "IO/WriteRZ", STAMUNIT_TICKS_PER_CALL, "Profiling IO writes in RZ");
8033	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIOWriteR3, STAMTYPE_PROFILE, "IO/WriteR3", STAMUNIT_TICKS_PER_CALL, "Profiling IO writes in R3");
8034	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatLateIntTimer, STAMTYPE_PROFILE, "LateInt/Timer", STAMUNIT_TICKS_PER_CALL, "Profiling late int timer");
8035	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatLateInts, STAMTYPE_COUNTER, "LateInt/Occured", STAMUNIT_OCCURENCES, "Number of late interrupts");
8036	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntsRaised, STAMTYPE_COUNTER, "Interrupts/Raised", STAMUNIT_OCCURENCES, "Number of raised interrupts");
8037	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatIntsPrevented, STAMTYPE_COUNTER, "Interrupts/Prevented", STAMUNIT_OCCURENCES, "Number of prevented interrupts");
8038	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatReceive, STAMTYPE_PROFILE, "Receive/Total", STAMUNIT_TICKS_PER_CALL, "Profiling receive");
8039	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatReceiveCRC, STAMTYPE_PROFILE, "Receive/CRC", STAMUNIT_TICKS_PER_CALL, "Profiling receive checksumming");
8040	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatReceiveFilter, STAMTYPE_PROFILE, "Receive/Filter", STAMUNIT_TICKS_PER_CALL, "Profiling receive filtering");
8041	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatReceiveStore, STAMTYPE_PROFILE, "Receive/Store", STAMUNIT_TICKS_PER_CALL, "Profiling receive storing");
8042	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRxOverflow, STAMTYPE_PROFILE, "RxOverflow", STAMUNIT_TICKS_PER_OCCURENCE, "Profiling RX overflows");
8043	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRxOverflowWakeupRZ, STAMTYPE_COUNTER, "RxOverflowWakeupRZ", STAMUNIT_OCCURENCES, "Nr of RX overflow wakeups in RZ");
8044	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatRxOverflowWakeupR3, STAMTYPE_COUNTER, "RxOverflowWakeupR3", STAMUNIT_OCCURENCES, "Nr of RX overflow wakeups in R3");
8045	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTransmitRZ, STAMTYPE_PROFILE, "Transmit/TotalRZ", STAMUNIT_TICKS_PER_CALL, "Profiling transmits in RZ");
8046	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTransmitR3, STAMTYPE_PROFILE, "Transmit/TotalR3", STAMUNIT_TICKS_PER_CALL, "Profiling transmits in R3");
8047	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTransmitSendRZ, STAMTYPE_PROFILE, "Transmit/SendRZ", STAMUNIT_TICKS_PER_CALL, "Profiling send transmit in RZ");
8048	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTransmitSendR3, STAMTYPE_PROFILE, "Transmit/SendR3", STAMUNIT_TICKS_PER_CALL, "Profiling send transmit in R3");
8049
8050	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxDescCtxNormal, STAMTYPE_COUNTER, "TxDesc/ContexNormal", STAMUNIT_OCCURENCES, "Number of normal context descriptors");
8051	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxDescCtxTSE, STAMTYPE_COUNTER, "TxDesc/ContextTSE", STAMUNIT_OCCURENCES, "Number of TSE context descriptors");
8052	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxDescData, STAMTYPE_COUNTER, "TxDesc/Data", STAMUNIT_OCCURENCES, "Number of TX data descriptors");
8053	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxDescLegacy, STAMTYPE_COUNTER, "TxDesc/Legacy", STAMUNIT_OCCURENCES, "Number of TX legacy descriptors");
8054	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxDescTSEData, STAMTYPE_COUNTER, "TxDesc/TSEData", STAMUNIT_OCCURENCES, "Number of TX TSE data descriptors");
8055	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxPathFallback, STAMTYPE_COUNTER, "TxPath/Fallback", STAMUNIT_OCCURENCES, "Fallback TSE descriptor path");
8056	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxPathGSO, STAMTYPE_COUNTER, "TxPath/GSO", STAMUNIT_OCCURENCES, "GSO TSE descriptor path");
8057	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatTxPathRegular, STAMTYPE_COUNTER, "TxPath/Normal", STAMUNIT_OCCURENCES, "Regular descriptor path");
8058	PDMDevHlpSTAMRegister(pDevIns, &pThis->StatPHYAccesses, STAMTYPE_COUNTER, "PHYAccesses", STAMUNIT_OCCURENCES, "Number of PHY accesses");
8059	for (unsigned iReg = 0; iReg < E1K_NUM_OF_REGS; iReg++)
8060	{
8061	PDMDevHlpSTAMRegisterF(pDevIns, &pThis->aStatRegReads[iReg], STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES,
8062	g_aE1kRegMap[iReg].name, "Regs/%s-Reads", g_aE1kRegMap[iReg].abbrev);
8063	PDMDevHlpSTAMRegisterF(pDevIns, &pThis->aStatRegWrites[iReg], STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES,
8064	g_aE1kRegMap[iReg].name, "Regs/%s-Writes", g_aE1kRegMap[iReg].abbrev);
8065	}
8066	#endif /* VBOX_WITH_STATISTICS */
8067
8068	#ifdef E1K_INT_STATS
8069	PDMDevHlpSTAMRegister(pDevIns, &pThis->u64ArmedAt, STAMTYPE_U64, "u64ArmedAt", STAMUNIT_NS, NULL);
8070	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatMaxTxDelay, STAMTYPE_U64, "uStatMaxTxDelay", STAMUNIT_NS, NULL);
8071	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatInt, STAMTYPE_U32, "uStatInt", STAMUNIT_NS, NULL);
8072	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntTry, STAMTYPE_U32, "uStatIntTry", STAMUNIT_NS, NULL);
8073	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntLower, STAMTYPE_U32, "uStatIntLower", STAMUNIT_NS, NULL);
8074	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatNoIntICR, STAMTYPE_U32, "uStatNoIntICR", STAMUNIT_NS, NULL);
8075	PDMDevHlpSTAMRegister(pDevIns, &pThis->iStatIntLost, STAMTYPE_U32, "iStatIntLost", STAMUNIT_NS, NULL);
8076	PDMDevHlpSTAMRegister(pDevIns, &pThis->iStatIntLostOne, STAMTYPE_U32, "iStatIntLostOne", STAMUNIT_NS, NULL);
8077	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntIMS, STAMTYPE_U32, "uStatIntIMS", STAMUNIT_NS, NULL);
8078	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntSkip, STAMTYPE_U32, "uStatIntSkip", STAMUNIT_NS, NULL);
8079	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntLate, STAMTYPE_U32, "uStatIntLate", STAMUNIT_NS, NULL);
8080	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntMasked, STAMTYPE_U32, "uStatIntMasked", STAMUNIT_NS, NULL);
8081	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntEarly, STAMTYPE_U32, "uStatIntEarly", STAMUNIT_NS, NULL);
8082	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntRx, STAMTYPE_U32, "uStatIntRx", STAMUNIT_NS, NULL);
8083	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntTx, STAMTYPE_U32, "uStatIntTx", STAMUNIT_NS, NULL);
8084	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntICS, STAMTYPE_U32, "uStatIntICS", STAMUNIT_NS, NULL);
8085	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntRDTR, STAMTYPE_U32, "uStatIntRDTR", STAMUNIT_NS, NULL);
8086	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntRXDMT0, STAMTYPE_U32, "uStatIntRXDMT0", STAMUNIT_NS, NULL);
8087	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatIntTXQE, STAMTYPE_U32, "uStatIntTXQE", STAMUNIT_NS, NULL);
8088	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxNoRS, STAMTYPE_U32, "uStatTxNoRS", STAMUNIT_NS, NULL);
8089	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxIDE, STAMTYPE_U32, "uStatTxIDE", STAMUNIT_NS, NULL);
8090	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxDelayed, STAMTYPE_U32, "uStatTxDelayed", STAMUNIT_NS, NULL);
8091	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxDelayExp, STAMTYPE_U32, "uStatTxDelayExp", STAMUNIT_NS, NULL);
8092	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTAD, STAMTYPE_U32, "uStatTAD", STAMUNIT_NS, NULL);
8093	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTID, STAMTYPE_U32, "uStatTID", STAMUNIT_NS, NULL);
8094	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatRAD, STAMTYPE_U32, "uStatRAD", STAMUNIT_NS, NULL);
8095	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatRID, STAMTYPE_U32, "uStatRID", STAMUNIT_NS, NULL);
8096	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatRxFrm, STAMTYPE_U32, "uStatRxFrm", STAMUNIT_NS, NULL);
8097	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxFrm, STAMTYPE_U32, "uStatTxFrm", STAMUNIT_NS, NULL);
8098	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatDescCtx, STAMTYPE_U32, "uStatDescCtx", STAMUNIT_NS, NULL);
8099	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatDescDat, STAMTYPE_U32, "uStatDescDat", STAMUNIT_NS, NULL);
8100	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatDescLeg, STAMTYPE_U32, "uStatDescLeg", STAMUNIT_NS, NULL);
8101	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx1514, STAMTYPE_U32, "uStatTx1514", STAMUNIT_NS, NULL);
8102	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx2962, STAMTYPE_U32, "uStatTx2962", STAMUNIT_NS, NULL);
8103	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx4410, STAMTYPE_U32, "uStatTx4410", STAMUNIT_NS, NULL);
8104	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx5858, STAMTYPE_U32, "uStatTx5858", STAMUNIT_NS, NULL);
8105	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx7306, STAMTYPE_U32, "uStatTx7306", STAMUNIT_NS, NULL);
8106	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx8754, STAMTYPE_U32, "uStatTx8754", STAMUNIT_NS, NULL);
8107	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx16384, STAMTYPE_U32, "uStatTx16384", STAMUNIT_NS, NULL);
8108	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTx32768, STAMTYPE_U32, "uStatTx32768", STAMUNIT_NS, NULL);
8109	PDMDevHlpSTAMRegister(pDevIns, &pThis->uStatTxLarge, STAMTYPE_U32, "uStatTxLarge", STAMUNIT_NS, NULL);
8110	#endif /* E1K_INT_STATS */
8111
8112	return VINF_SUCCESS;
8113	}
8114
8115	#else /* !IN_RING3 */
8116
8117	/**
8118	* @callback_method_impl{PDMDEVREGR0,pfnConstruct}
8119	*/
8120	static DECLCALLBACK(int) e1kRZConstruct(PPDMDEVINS pDevIns)
8121	{
8122	PDMDEV_CHECK_VERSIONS_RETURN(pDevIns);
8123	PE1KSTATE pThis = PDMDEVINS_2_DATA(pDevIns, PE1KSTATE);
8124	PE1KSTATECC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PE1KSTATECC);
8125
8126	/* Initialize context specific state data: */
8127	pThisCC->CTX_SUFF(pDevIns) = pDevIns;
8128	/** @todo @bugref{9218} ring-0 driver stuff */
8129	pThisCC->CTX_SUFF(pDrv) = NULL;
8130	pThisCC->CTX_SUFF(pTxSg) = NULL;
8131
8132	/* Configure critical sections the same way: */
8133	int rc = PDMDevHlpSetDeviceCritSect(pDevIns, PDMDevHlpCritSectGetNop(pDevIns));
8134	AssertRCReturn(rc, rc);
8135
8136	/* Set up MMIO and I/O port callbacks for this context: */
8137	rc = PDMDevHlpMmioSetUpContext(pDevIns, pThis->hMmioRegion, e1kMMIOWrite, e1kMMIORead, NULL /pvUser/);
8138	AssertRCReturn(rc, rc);
8139
8140	rc = PDMDevHlpIoPortSetUpContext(pDevIns, pThis->hIoPorts, e1kIOPortOut, e1kIOPortIn, NULL /pvUser/);
8141	AssertRCReturn(rc, rc);
8142
8143	return VINF_SUCCESS;
8144	}
8145
8146	#endif /* !IN_RING3 */
8147
8148	/**
8149	* The device registration structure.
8150	*/
8151	const PDMDEVREG g_DeviceE1000 =
8152	{
8153	/* .u32version = */ PDM_DEVREG_VERSION,
8154	/* .uReserved0 = */ 0,
8155	/* .szName = */ "e1000",
8156	/* .fFlags = */ PDM_DEVREG_FLAGS_DEFAULT_BITS \| PDM_DEVREG_FLAGS_RZ \| PDM_DEVREG_FLAGS_NEW_STYLE,
8157	/* .fClass = */ PDM_DEVREG_CLASS_NETWORK,
8158	/* .cMaxInstances = */ ~0U,
8159	/* .uSharedVersion = */ 42,
8160	/* .cbInstanceShared = */ sizeof(E1KSTATE),
8161	/* .cbInstanceCC = */ sizeof(E1KSTATECC),
8162	/* .cbInstanceRC = */ sizeof(E1KSTATERC),
8163	/* .cMaxPciDevices = */ 1,
8164	/* .cMaxMsixVectors = */ 0,
8165	/* .pszDescription = */ "Intel PRO/1000 MT Desktop Ethernet.",
8166	#if defined(IN_RING3)
8167	/* .pszRCMod = */ "VBoxDDRC.rc",
8168	/* .pszR0Mod = */ "VBoxDDR0.r0",
8169	/* .pfnConstruct = */ e1kR3Construct,
8170	/* .pfnDestruct = */ e1kR3Destruct,
8171	/* .pfnRelocate = */ e1kR3Relocate,
8172	/* .pfnMemSetup = */ NULL,
8173	/* .pfnPowerOn = */ NULL,
8174	/* .pfnReset = */ e1kR3Reset,
8175	/* .pfnSuspend = */ e1kR3Suspend,
8176	/* .pfnResume = */ NULL,
8177	/* .pfnAttach = */ e1kR3Attach,
8178	/* .pfnDeatch = */ e1kR3Detach,
8179	/* .pfnQueryInterface = */ NULL,
8180	/* .pfnInitComplete = */ NULL,
8181	/* .pfnPowerOff = */ e1kR3PowerOff,
8182	/* .pfnSoftReset = */ NULL,
8183	/* .pfnReserved0 = */ NULL,
8184	/* .pfnReserved1 = */ NULL,
8185	/* .pfnReserved2 = */ NULL,
8186	/* .pfnReserved3 = */ NULL,
8187	/* .pfnReserved4 = */ NULL,
8188	/* .pfnReserved5 = */ NULL,
8189	/* .pfnReserved6 = */ NULL,
8190	/* .pfnReserved7 = */ NULL,
8191	#elif defined(IN_RING0)
8192	/* .pfnEarlyConstruct = */ NULL,
8193	/* .pfnConstruct = */ e1kRZConstruct,
8194	/* .pfnDestruct = */ NULL,
8195	/* .pfnFinalDestruct = */ NULL,
8196	/* .pfnRequest = */ NULL,
8197	/* .pfnReserved0 = */ NULL,
8198	/* .pfnReserved1 = */ NULL,
8199	/* .pfnReserved2 = */ NULL,
8200	/* .pfnReserved3 = */ NULL,
8201	/* .pfnReserved4 = */ NULL,
8202	/* .pfnReserved5 = */ NULL,
8203	/* .pfnReserved6 = */ NULL,
8204	/* .pfnReserved7 = */ NULL,
8205	#elif defined(IN_RC)
8206	/* .pfnConstruct = */ e1kRZConstruct,
8207	/* .pfnReserved0 = */ NULL,
8208	/* .pfnReserved1 = */ NULL,
8209	/* .pfnReserved2 = */ NULL,
8210	/* .pfnReserved3 = */ NULL,
8211	/* .pfnReserved4 = */ NULL,
8212	/* .pfnReserved5 = */ NULL,
8213	/* .pfnReserved6 = */ NULL,
8214	/* .pfnReserved7 = */ NULL,
8215	#else
8216	# error "Not in IN_RING3, IN_RING0 or IN_RC!"
8217	#endif
8218	/* .u32VersionEnd = */ PDM_DEVREG_VERSION
8219	};
8220
8221	#endif /* !VBOX_DEVICE_STRUCT_TESTCASE */

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source: vbox/trunk/src/VBox/Devices/Network/DevE1000.cpp@ 85146

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