1/*
2 * Copyright (c) 2012-2013 ARM Limited
3 * All rights reserved
4 *
5 * The license below extends only to copyright in the software and shall
6 * not be construed as granting a license to any other intellectual
7 * property including but not limited to intellectual property relating
8 * to a hardware implementation of the functionality of the software
9 * licensed hereunder. You may use the software subject to the license
10 * terms below provided that you ensure that this notice is replicated
11 * unmodified and in its entirety in all distributions of the software,
12 * modified or unmodified, in source code or in binary form.
13 *
14 * Copyright (c) 2006 The Regents of The University of Michigan
15 * Copyright (c) 2010 Advanced Micro Devices, Inc.
16 * All rights reserved.
17 *
18 * Redistribution and use in source and binary forms, with or without
19 * modification, are permitted provided that the following conditions are
20 * met: redistributions of source code must retain the above copyright
21 * notice, this list of conditions and the following disclaimer;
22 * redistributions in binary form must reproduce the above copyright
23 * notice, this list of conditions and the following disclaimer in the
24 * documentation and/or other materials provided with the distribution;
25 * neither the name of the copyright holders nor the names of its
26 * contributors may be used to endorse or promote products derived from
27 * this software without specific prior written permission.
28 *
29 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
30 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
31 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
32 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
33 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
34 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
35 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
36 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
37 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
38 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
39 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
40 *
41 * Authors: Ron Dreslinski
42 * Steve Reinhardt
43 * Ali Saidi
44 * Andreas Hansson
45 */
46
47/**
48 * @file
49 * Declaration of the Packet class.
50 */
51
52#ifndef __MEM_PACKET_HH__
53#define __MEM_PACKET_HH__
54
55#include <bitset>
56#include <cassert>
57#include <list>
58
59#include "base/cast.hh"
60#include "base/compiler.hh"
61#include "base/flags.hh"
62#include "base/misc.hh"
63#include "base/printable.hh"
64#include "base/types.hh"
65#include "mem/request.hh"
66#include "sim/core.hh"
67
68class Packet;
69typedef Packet *PacketPtr;
70typedef uint8_t* PacketDataPtr;
71typedef std::list<PacketPtr> PacketList;
72
73class MemCmd
74{
75 friend class Packet;
76
77 public:
78 /**
79 * List of all commands associated with a packet.
80 */
81 enum Command
82 {
83 InvalidCmd,
84 ReadReq,
85 ReadResp,
86 ReadRespWithInvalidate,
87 WriteReq,
88 WriteResp,
89 Writeback,
90 SoftPFReq,
91 HardPFReq,
92 SoftPFResp,
93 HardPFResp,
94 // WriteInvalidateReq transactions used to be generated by the
95 // DMA ports when writing full blocks to memory, however, it
96 // is not used anymore since we put the I/O cache in place to
97 // deal with partial block writes. Hence, WriteInvalidateReq
98 // and WriteInvalidateResp are currently unused. The
99 // implication is that the I/O cache does read-exclusive
100 // operations on every full-cache-block DMA, and ultimately
101 // this needs to be fixed.
102 WriteInvalidateReq,
103 WriteInvalidateResp,
104 UpgradeReq,
105 SCUpgradeReq, // Special "weak" upgrade for StoreCond
106 UpgradeResp,
107 SCUpgradeFailReq, // Failed SCUpgradeReq in MSHR (never sent)
108 UpgradeFailResp, // Valid for SCUpgradeReq only
109 ReadExReq,
110 ReadExResp,
111 LoadLockedReq,
112 StoreCondReq,
113 StoreCondFailReq, // Failed StoreCondReq in MSHR (never sent)
114 StoreCondResp,
115 SwapReq,
116 SwapResp,
117 MessageReq,
118 MessageResp,
119 // Error responses
120 // @TODO these should be classified as responses rather than
121 // requests; coding them as requests initially for backwards
122 // compatibility
123 InvalidDestError, // packet dest field invalid
124 BadAddressError, // memory address invalid
125 FunctionalReadError, // unable to fulfill functional read
126 FunctionalWriteError, // unable to fulfill functional write
127 // Fake simulator-only commands
128 PrintReq, // Print state matching address
129 FlushReq, //request for a cache flush
130 InvalidationReq, // request for address to be invalidated from lsq
131 NUM_MEM_CMDS
132 };
133
134 private:
135 /**
136 * List of command attributes.
137 */
138 enum Attribute
139 {
140 IsRead, //!< Data flows from responder to requester
141 IsWrite, //!< Data flows from requester to responder
142 IsUpgrade,
143 IsInvalidate,
144 NeedsExclusive, //!< Requires exclusive copy to complete in-cache
145 IsRequest, //!< Issued by requester
146 IsResponse, //!< Issue by responder
147 NeedsResponse, //!< Requester needs response from target
148 IsSWPrefetch,
149 IsHWPrefetch,
150 IsLlsc, //!< Alpha/MIPS LL or SC access
151 HasData, //!< There is an associated payload
152 IsError, //!< Error response
153 IsPrint, //!< Print state matching address (for debugging)
154 IsFlush, //!< Flush the address from caches
155 NUM_COMMAND_ATTRIBUTES
156 };
157
158 /**
159 * Structure that defines attributes and other data associated
160 * with a Command.
161 */
162 struct CommandInfo
163 {
164 /// Set of attribute flags.
165 const std::bitset<NUM_COMMAND_ATTRIBUTES> attributes;
166 /// Corresponding response for requests; InvalidCmd if no
167 /// response is applicable.
168 const Command response;
169 /// String representation (for printing)
170 const std::string str;
171 };
172
173 /// Array to map Command enum to associated info.
174 static const CommandInfo commandInfo[];
175
176 private:
177
178 Command cmd;
179
180 bool
181 testCmdAttrib(MemCmd::Attribute attrib) const
182 {
183 return commandInfo[cmd].attributes[attrib] != 0;
184 }
185
186 public:
187
188 bool isRead() const { return testCmdAttrib(IsRead); }
189 bool isWrite() const { return testCmdAttrib(IsWrite); }
190 bool isUpgrade() const { return testCmdAttrib(IsUpgrade); }
191 bool isRequest() const { return testCmdAttrib(IsRequest); }
192 bool isResponse() const { return testCmdAttrib(IsResponse); }
193 bool needsExclusive() const { return testCmdAttrib(NeedsExclusive); }
194 bool needsResponse() const { return testCmdAttrib(NeedsResponse); }
195 bool isInvalidate() const { return testCmdAttrib(IsInvalidate); }
196 bool hasData() const { return testCmdAttrib(HasData); }
197 bool isReadWrite() const { return isRead() && isWrite(); }
198 bool isLLSC() const { return testCmdAttrib(IsLlsc); }
199 bool isError() const { return testCmdAttrib(IsError); }
200 bool isPrint() const { return testCmdAttrib(IsPrint); }
201 bool isFlush() const { return testCmdAttrib(IsFlush); }
202
203 const Command
204 responseCommand() const
205 {
206 return commandInfo[cmd].response;
207 }
208
209 /// Return the string to a cmd given by idx.
210 const std::string &toString() const { return commandInfo[cmd].str; }
211 int toInt() const { return (int)cmd; }
212
213 MemCmd(Command _cmd) : cmd(_cmd) { }
214 MemCmd(int _cmd) : cmd((Command)_cmd) { }
215 MemCmd() : cmd(InvalidCmd) { }
216
217 bool operator==(MemCmd c2) const { return (cmd == c2.cmd); }
218 bool operator!=(MemCmd c2) const { return (cmd != c2.cmd); }
219};
220
221/**
222 * A Packet is used to encapsulate a transfer between two objects in
223 * the memory system (e.g., the L1 and L2 cache). (In contrast, a
224 * single Request travels all the way from the requester to the
225 * ultimate destination and back, possibly being conveyed by several
226 * different Packets along the way.)
227 */
228class Packet : public Printable
229{
230 public:
231 typedef uint32_t FlagsType;
232 typedef ::Flags<FlagsType> Flags;
233
234 private:
235 static const FlagsType PUBLIC_FLAGS = 0x00000000;
236 static const FlagsType PRIVATE_FLAGS = 0x00007F0F;
237 static const FlagsType COPY_FLAGS = 0x0000000F;
238
239 static const FlagsType SHARED = 0x00000001;
240 // Special control flags
241 /// Special timing-mode atomic snoop for multi-level coherence.
242 static const FlagsType EXPRESS_SNOOP = 0x00000002;
243 /// Does supplier have exclusive copy?
244 /// Useful for multi-level coherence.
245 static const FlagsType SUPPLY_EXCLUSIVE = 0x00000004;
246 // Snoop response flags
247 static const FlagsType MEM_INHIBIT = 0x00000008;
248 /// Are the 'addr' and 'size' fields valid?
249 static const FlagsType VALID_ADDR = 0x00000100;
250 static const FlagsType VALID_SIZE = 0x00000200;
251 /// Is the data pointer set to a value that shouldn't be freed
252 /// when the packet is destroyed?
253 static const FlagsType STATIC_DATA = 0x00001000;
254 /// The data pointer points to a value that should be freed when
255 /// the packet is destroyed.
256 static const FlagsType DYNAMIC_DATA = 0x00002000;
257 /// the data pointer points to an array (thus delete []) needs to
258 /// be called on it rather than simply delete.
259 static const FlagsType ARRAY_DATA = 0x00004000;
260 /// suppress the error if this packet encounters a functional
261 /// access failure.
262 static const FlagsType SUPPRESS_FUNC_ERROR = 0x00008000;
263
264 Flags flags;
265
266 public:
267 typedef MemCmd::Command Command;
268
269 /// The command field of the packet.
270 MemCmd cmd;
271
272 /// A pointer to the original request.
273 RequestPtr req;
274
275 private:
276 /**
277 * A pointer to the data being transfered. It can be differnt
278 * sizes at each level of the heirarchy so it belongs in the
279 * packet, not request. This may or may not be populated when a
280 * responder recieves the packet. If not populated it memory should
281 * be allocated.
282 */
283 PacketDataPtr data;
284
285 /// The address of the request. This address could be virtual or
286 /// physical, depending on the system configuration.
287 Addr addr;
288
289 /// The size of the request or transfer.
290 unsigned size;
291
292 /**
293 * Source port identifier set on a request packet to enable
294 * appropriate routing of the responses. The source port
295 * identifier is set by any multiplexing component, e.g. a bus, as
296 * the timing responses need this information to be routed back to
297 * the appropriate port at a later point in time. The field can be
298 * updated (over-written) as the request packet passes through
299 * additional multiplexing components, and it is their
300 * responsibility to remember the original source port identifier,
301 * for example by using an appropriate sender state. The latter is
302 * done in the cache and bridge.
303 */
304 PortID src;
305
306 /**
307 * Destination port identifier that is present on all response
308 * packets that passed through a multiplexing component as a
309 * request packet. The source port identifier is turned into a
310 * destination port identifier when the packet is turned into a
311 * response, and the destination is used, e.g. by the bus, to
312 * select the appropriate path through the interconnect.
313 */
314 PortID dest;
315
316 /**
317 * The original value of the command field. Only valid when the
318 * current command field is an error condition; in that case, the
319 * previous contents of the command field are copied here. This
320 * field is *not* set on non-error responses.
321 */
322 MemCmd origCmd;
323
324 /**
325 * These values specify the range of bytes found that satisfy a
326 * functional read.
327 */
328 uint16_t bytesValidStart;
329 uint16_t bytesValidEnd;
330
331 public:
| 1/*
2 * Copyright (c) 2012-2013 ARM Limited
3 * All rights reserved
4 *
5 * The license below extends only to copyright in the software and shall
6 * not be construed as granting a license to any other intellectual
7 * property including but not limited to intellectual property relating
8 * to a hardware implementation of the functionality of the software
9 * licensed hereunder. You may use the software subject to the license
10 * terms below provided that you ensure that this notice is replicated
11 * unmodified and in its entirety in all distributions of the software,
12 * modified or unmodified, in source code or in binary form.
13 *
14 * Copyright (c) 2006 The Regents of The University of Michigan
15 * Copyright (c) 2010 Advanced Micro Devices, Inc.
16 * All rights reserved.
17 *
18 * Redistribution and use in source and binary forms, with or without
19 * modification, are permitted provided that the following conditions are
20 * met: redistributions of source code must retain the above copyright
21 * notice, this list of conditions and the following disclaimer;
22 * redistributions in binary form must reproduce the above copyright
23 * notice, this list of conditions and the following disclaimer in the
24 * documentation and/or other materials provided with the distribution;
25 * neither the name of the copyright holders nor the names of its
26 * contributors may be used to endorse or promote products derived from
27 * this software without specific prior written permission.
28 *
29 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
30 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
31 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
32 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
33 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
34 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
35 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
36 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
37 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
38 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
39 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
40 *
41 * Authors: Ron Dreslinski
42 * Steve Reinhardt
43 * Ali Saidi
44 * Andreas Hansson
45 */
46
47/**
48 * @file
49 * Declaration of the Packet class.
50 */
51
52#ifndef __MEM_PACKET_HH__
53#define __MEM_PACKET_HH__
54
55#include <bitset>
56#include <cassert>
57#include <list>
58
59#include "base/cast.hh"
60#include "base/compiler.hh"
61#include "base/flags.hh"
62#include "base/misc.hh"
63#include "base/printable.hh"
64#include "base/types.hh"
65#include "mem/request.hh"
66#include "sim/core.hh"
67
68class Packet;
69typedef Packet *PacketPtr;
70typedef uint8_t* PacketDataPtr;
71typedef std::list<PacketPtr> PacketList;
72
73class MemCmd
74{
75 friend class Packet;
76
77 public:
78 /**
79 * List of all commands associated with a packet.
80 */
81 enum Command
82 {
83 InvalidCmd,
84 ReadReq,
85 ReadResp,
86 ReadRespWithInvalidate,
87 WriteReq,
88 WriteResp,
89 Writeback,
90 SoftPFReq,
91 HardPFReq,
92 SoftPFResp,
93 HardPFResp,
94 // WriteInvalidateReq transactions used to be generated by the
95 // DMA ports when writing full blocks to memory, however, it
96 // is not used anymore since we put the I/O cache in place to
97 // deal with partial block writes. Hence, WriteInvalidateReq
98 // and WriteInvalidateResp are currently unused. The
99 // implication is that the I/O cache does read-exclusive
100 // operations on every full-cache-block DMA, and ultimately
101 // this needs to be fixed.
102 WriteInvalidateReq,
103 WriteInvalidateResp,
104 UpgradeReq,
105 SCUpgradeReq, // Special "weak" upgrade for StoreCond
106 UpgradeResp,
107 SCUpgradeFailReq, // Failed SCUpgradeReq in MSHR (never sent)
108 UpgradeFailResp, // Valid for SCUpgradeReq only
109 ReadExReq,
110 ReadExResp,
111 LoadLockedReq,
112 StoreCondReq,
113 StoreCondFailReq, // Failed StoreCondReq in MSHR (never sent)
114 StoreCondResp,
115 SwapReq,
116 SwapResp,
117 MessageReq,
118 MessageResp,
119 // Error responses
120 // @TODO these should be classified as responses rather than
121 // requests; coding them as requests initially for backwards
122 // compatibility
123 InvalidDestError, // packet dest field invalid
124 BadAddressError, // memory address invalid
125 FunctionalReadError, // unable to fulfill functional read
126 FunctionalWriteError, // unable to fulfill functional write
127 // Fake simulator-only commands
128 PrintReq, // Print state matching address
129 FlushReq, //request for a cache flush
130 InvalidationReq, // request for address to be invalidated from lsq
131 NUM_MEM_CMDS
132 };
133
134 private:
135 /**
136 * List of command attributes.
137 */
138 enum Attribute
139 {
140 IsRead, //!< Data flows from responder to requester
141 IsWrite, //!< Data flows from requester to responder
142 IsUpgrade,
143 IsInvalidate,
144 NeedsExclusive, //!< Requires exclusive copy to complete in-cache
145 IsRequest, //!< Issued by requester
146 IsResponse, //!< Issue by responder
147 NeedsResponse, //!< Requester needs response from target
148 IsSWPrefetch,
149 IsHWPrefetch,
150 IsLlsc, //!< Alpha/MIPS LL or SC access
151 HasData, //!< There is an associated payload
152 IsError, //!< Error response
153 IsPrint, //!< Print state matching address (for debugging)
154 IsFlush, //!< Flush the address from caches
155 NUM_COMMAND_ATTRIBUTES
156 };
157
158 /**
159 * Structure that defines attributes and other data associated
160 * with a Command.
161 */
162 struct CommandInfo
163 {
164 /// Set of attribute flags.
165 const std::bitset<NUM_COMMAND_ATTRIBUTES> attributes;
166 /// Corresponding response for requests; InvalidCmd if no
167 /// response is applicable.
168 const Command response;
169 /// String representation (for printing)
170 const std::string str;
171 };
172
173 /// Array to map Command enum to associated info.
174 static const CommandInfo commandInfo[];
175
176 private:
177
178 Command cmd;
179
180 bool
181 testCmdAttrib(MemCmd::Attribute attrib) const
182 {
183 return commandInfo[cmd].attributes[attrib] != 0;
184 }
185
186 public:
187
188 bool isRead() const { return testCmdAttrib(IsRead); }
189 bool isWrite() const { return testCmdAttrib(IsWrite); }
190 bool isUpgrade() const { return testCmdAttrib(IsUpgrade); }
191 bool isRequest() const { return testCmdAttrib(IsRequest); }
192 bool isResponse() const { return testCmdAttrib(IsResponse); }
193 bool needsExclusive() const { return testCmdAttrib(NeedsExclusive); }
194 bool needsResponse() const { return testCmdAttrib(NeedsResponse); }
195 bool isInvalidate() const { return testCmdAttrib(IsInvalidate); }
196 bool hasData() const { return testCmdAttrib(HasData); }
197 bool isReadWrite() const { return isRead() && isWrite(); }
198 bool isLLSC() const { return testCmdAttrib(IsLlsc); }
199 bool isError() const { return testCmdAttrib(IsError); }
200 bool isPrint() const { return testCmdAttrib(IsPrint); }
201 bool isFlush() const { return testCmdAttrib(IsFlush); }
202
203 const Command
204 responseCommand() const
205 {
206 return commandInfo[cmd].response;
207 }
208
209 /// Return the string to a cmd given by idx.
210 const std::string &toString() const { return commandInfo[cmd].str; }
211 int toInt() const { return (int)cmd; }
212
213 MemCmd(Command _cmd) : cmd(_cmd) { }
214 MemCmd(int _cmd) : cmd((Command)_cmd) { }
215 MemCmd() : cmd(InvalidCmd) { }
216
217 bool operator==(MemCmd c2) const { return (cmd == c2.cmd); }
218 bool operator!=(MemCmd c2) const { return (cmd != c2.cmd); }
219};
220
221/**
222 * A Packet is used to encapsulate a transfer between two objects in
223 * the memory system (e.g., the L1 and L2 cache). (In contrast, a
224 * single Request travels all the way from the requester to the
225 * ultimate destination and back, possibly being conveyed by several
226 * different Packets along the way.)
227 */
228class Packet : public Printable
229{
230 public:
231 typedef uint32_t FlagsType;
232 typedef ::Flags<FlagsType> Flags;
233
234 private:
235 static const FlagsType PUBLIC_FLAGS = 0x00000000;
236 static const FlagsType PRIVATE_FLAGS = 0x00007F0F;
237 static const FlagsType COPY_FLAGS = 0x0000000F;
238
239 static const FlagsType SHARED = 0x00000001;
240 // Special control flags
241 /// Special timing-mode atomic snoop for multi-level coherence.
242 static const FlagsType EXPRESS_SNOOP = 0x00000002;
243 /// Does supplier have exclusive copy?
244 /// Useful for multi-level coherence.
245 static const FlagsType SUPPLY_EXCLUSIVE = 0x00000004;
246 // Snoop response flags
247 static const FlagsType MEM_INHIBIT = 0x00000008;
248 /// Are the 'addr' and 'size' fields valid?
249 static const FlagsType VALID_ADDR = 0x00000100;
250 static const FlagsType VALID_SIZE = 0x00000200;
251 /// Is the data pointer set to a value that shouldn't be freed
252 /// when the packet is destroyed?
253 static const FlagsType STATIC_DATA = 0x00001000;
254 /// The data pointer points to a value that should be freed when
255 /// the packet is destroyed.
256 static const FlagsType DYNAMIC_DATA = 0x00002000;
257 /// the data pointer points to an array (thus delete []) needs to
258 /// be called on it rather than simply delete.
259 static const FlagsType ARRAY_DATA = 0x00004000;
260 /// suppress the error if this packet encounters a functional
261 /// access failure.
262 static const FlagsType SUPPRESS_FUNC_ERROR = 0x00008000;
263
264 Flags flags;
265
266 public:
267 typedef MemCmd::Command Command;
268
269 /// The command field of the packet.
270 MemCmd cmd;
271
272 /// A pointer to the original request.
273 RequestPtr req;
274
275 private:
276 /**
277 * A pointer to the data being transfered. It can be differnt
278 * sizes at each level of the heirarchy so it belongs in the
279 * packet, not request. This may or may not be populated when a
280 * responder recieves the packet. If not populated it memory should
281 * be allocated.
282 */
283 PacketDataPtr data;
284
285 /// The address of the request. This address could be virtual or
286 /// physical, depending on the system configuration.
287 Addr addr;
288
289 /// The size of the request or transfer.
290 unsigned size;
291
292 /**
293 * Source port identifier set on a request packet to enable
294 * appropriate routing of the responses. The source port
295 * identifier is set by any multiplexing component, e.g. a bus, as
296 * the timing responses need this information to be routed back to
297 * the appropriate port at a later point in time. The field can be
298 * updated (over-written) as the request packet passes through
299 * additional multiplexing components, and it is their
300 * responsibility to remember the original source port identifier,
301 * for example by using an appropriate sender state. The latter is
302 * done in the cache and bridge.
303 */
304 PortID src;
305
306 /**
307 * Destination port identifier that is present on all response
308 * packets that passed through a multiplexing component as a
309 * request packet. The source port identifier is turned into a
310 * destination port identifier when the packet is turned into a
311 * response, and the destination is used, e.g. by the bus, to
312 * select the appropriate path through the interconnect.
313 */
314 PortID dest;
315
316 /**
317 * The original value of the command field. Only valid when the
318 * current command field is an error condition; in that case, the
319 * previous contents of the command field are copied here. This
320 * field is *not* set on non-error responses.
321 */
322 MemCmd origCmd;
323
324 /**
325 * These values specify the range of bytes found that satisfy a
326 * functional read.
327 */
328 uint16_t bytesValidStart;
329 uint16_t bytesValidEnd;
330
331 public:
|
332 /// Used to calculate latencies for each packet.
333 Tick time;
| |
334
335 /// The time at which the packet will be fully transmitted
336 Tick finishTime;
337
338 /// The time at which the first chunk of the packet will be transmitted
339 Tick firstWordTime;
340
341 /**
342 * A virtual base opaque structure used to hold state associated
343 * with the packet (e.g., an MSHR), specific to a MemObject that
344 * sees the packet. A pointer to this state is returned in the
345 * packet's response so that the MemObject in question can quickly
346 * look up the state needed to process it. A specific subclass
347 * would be derived from this to carry state specific to a
348 * particular sending device.
349 *
350 * As multiple MemObjects may add their SenderState throughout the
351 * memory system, the SenderStates create a stack, where a
352 * MemObject can add a new Senderstate, as long as the
353 * predecessing SenderState is restored when the response comes
354 * back. For this reason, the predecessor should always be
355 * populated with the current SenderState of a packet before
356 * modifying the senderState field in the request packet.
357 */
358 struct SenderState
359 {
360 SenderState* predecessor;
361 SenderState() : predecessor(NULL) {}
362 virtual ~SenderState() {}
363 };
364
365 /**
366 * Object used to maintain state of a PrintReq. The senderState
367 * field of a PrintReq should always be of this type.
368 */
369 class PrintReqState : public SenderState
370 {
371 private:
372 /**
373 * An entry in the label stack.
374 */
375 struct LabelStackEntry
376 {
377 const std::string label;
378 std::string *prefix;
379 bool labelPrinted;
380 LabelStackEntry(const std::string &_label, std::string *_prefix);
381 };
382
383 typedef std::list<LabelStackEntry> LabelStack;
384 LabelStack labelStack;
385
386 std::string *curPrefixPtr;
387
388 public:
389 std::ostream &os;
390 const int verbosity;
391
392 PrintReqState(std::ostream &os, int verbosity = 0);
393 ~PrintReqState();
394
395 /**
396 * Returns the current line prefix.
397 */
398 const std::string &curPrefix() { return *curPrefixPtr; }
399
400 /**
401 * Push a label onto the label stack, and prepend the given
402 * prefix string onto the current prefix. Labels will only be
403 * printed if an object within the label's scope is printed.
404 */
405 void pushLabel(const std::string &lbl,
406 const std::string &prefix = " ");
407
408 /**
409 * Pop a label off the label stack.
410 */
411 void popLabel();
412
413 /**
414 * Print all of the pending unprinted labels on the
415 * stack. Called by printObj(), so normally not called by
416 * users unless bypassing printObj().
417 */
418 void printLabels();
419
420 /**
421 * Print a Printable object to os, because it matched the
422 * address on a PrintReq.
423 */
424 void printObj(Printable *obj);
425 };
426
427 /**
428 * This packet's sender state. Devices should use dynamic_cast<>
429 * to cast to the state appropriate to the sender. The intent of
430 * this variable is to allow a device to attach extra information
431 * to a request. A response packet must return the sender state
432 * that was attached to the original request (even if a new packet
433 * is created).
434 */
435 SenderState *senderState;
436
437 /**
438 * Push a new sender state to the packet and make the current
439 * sender state the predecessor of the new one. This should be
440 * prefered over direct manipulation of the senderState member
441 * variable.
442 *
443 * @param sender_state SenderState to push at the top of the stack
444 */
445 void pushSenderState(SenderState *sender_state);
446
447 /**
448 * Pop the top of the state stack and return a pointer to it. This
449 * assumes the current sender state is not NULL. This should be
450 * preferred over direct manipulation of the senderState member
451 * variable.
452 *
453 * @return The current top of the stack
454 */
455 SenderState *popSenderState();
456
457 /**
458 * Go through the sender state stack and return the first instance
459 * that is of type T (as determined by a dynamic_cast). If there
460 * is no sender state of type T, NULL is returned.
461 *
462 * @return The topmost state of type T
463 */
464 template <typename T>
465 T * findNextSenderState() const
466 {
467 T *t = NULL;
468 SenderState* sender_state = senderState;
469 while (t == NULL && sender_state != NULL) {
470 t = dynamic_cast<T*>(sender_state);
471 sender_state = sender_state->predecessor;
472 }
473 return t;
474 }
475
476 /// Return the string name of the cmd field (for debugging and
477 /// tracing).
478 const std::string &cmdString() const { return cmd.toString(); }
479
480 /// Return the index of this command.
481 inline int cmdToIndex() const { return cmd.toInt(); }
482
483 bool isRead() const { return cmd.isRead(); }
484 bool isWrite() const { return cmd.isWrite(); }
485 bool isUpgrade() const { return cmd.isUpgrade(); }
486 bool isRequest() const { return cmd.isRequest(); }
487 bool isResponse() const { return cmd.isResponse(); }
488 bool needsExclusive() const { return cmd.needsExclusive(); }
489 bool needsResponse() const { return cmd.needsResponse(); }
490 bool isInvalidate() const { return cmd.isInvalidate(); }
491 bool hasData() const { return cmd.hasData(); }
492 bool isReadWrite() const { return cmd.isReadWrite(); }
493 bool isLLSC() const { return cmd.isLLSC(); }
494 bool isError() const { return cmd.isError(); }
495 bool isPrint() const { return cmd.isPrint(); }
496 bool isFlush() const { return cmd.isFlush(); }
497
498 // Snoop flags
499 void assertMemInhibit() { flags.set(MEM_INHIBIT); }
500 bool memInhibitAsserted() { return flags.isSet(MEM_INHIBIT); }
501 void assertShared() { flags.set(SHARED); }
502 bool sharedAsserted() { return flags.isSet(SHARED); }
503
504 // Special control flags
505 void setExpressSnoop() { flags.set(EXPRESS_SNOOP); }
506 bool isExpressSnoop() { return flags.isSet(EXPRESS_SNOOP); }
507 void setSupplyExclusive() { flags.set(SUPPLY_EXCLUSIVE); }
508 void clearSupplyExclusive() { flags.clear(SUPPLY_EXCLUSIVE); }
509 bool isSupplyExclusive() { return flags.isSet(SUPPLY_EXCLUSIVE); }
510 void setSuppressFuncError() { flags.set(SUPPRESS_FUNC_ERROR); }
511 bool suppressFuncError() { return flags.isSet(SUPPRESS_FUNC_ERROR); }
512
513 // Network error conditions... encapsulate them as methods since
514 // their encoding keeps changing (from result field to command
515 // field, etc.)
516 void
517 setBadAddress()
518 {
519 assert(isResponse());
520 cmd = MemCmd::BadAddressError;
521 }
522
523 bool hadBadAddress() const { return cmd == MemCmd::BadAddressError; }
524 void copyError(Packet *pkt) { assert(pkt->isError()); cmd = pkt->cmd; }
525
526 bool isSrcValid() const { return src != InvalidPortID; }
527 /// Accessor function to get the source index of the packet.
528 PortID getSrc() const { assert(isSrcValid()); return src; }
529 /// Accessor function to set the source index of the packet.
530 void setSrc(PortID _src) { src = _src; }
531 /// Reset source field, e.g. to retransmit packet on different bus.
532 void clearSrc() { src = InvalidPortID; }
533
534 bool isDestValid() const { return dest != InvalidPortID; }
535 /// Accessor function for the destination index of the packet.
536 PortID getDest() const { assert(isDestValid()); return dest; }
537 /// Accessor function to set the destination index of the packet.
538 void setDest(PortID _dest) { dest = _dest; }
539 /// Reset destination field, e.g. to turn a response into a request again.
540 void clearDest() { dest = InvalidPortID; }
541
542 Addr getAddr() const { assert(flags.isSet(VALID_ADDR)); return addr; }
543 /**
544 * Update the address of this packet mid-transaction. This is used
545 * by the address mapper to change an already set address to a new
546 * one based on the system configuration. It is intended to remap
547 * an existing address, so it asserts that the current address is
548 * valid.
549 */
550 void setAddr(Addr _addr) { assert(flags.isSet(VALID_ADDR)); addr = _addr; }
551
552 unsigned getSize() const { assert(flags.isSet(VALID_SIZE)); return size; }
553 Addr getOffset(int blkSize) const { return getAddr() & (Addr)(blkSize - 1); }
554
555 /**
556 * It has been determined that the SC packet should successfully update
557 * memory. Therefore, convert this SC packet to a normal write.
558 */
559 void
560 convertScToWrite()
561 {
562 assert(isLLSC());
563 assert(isWrite());
564 cmd = MemCmd::WriteReq;
565 }
566
567 /**
568 * When ruby is in use, Ruby will monitor the cache line and thus M5
569 * phys memory should treat LL ops as normal reads.
570 */
571 void
572 convertLlToRead()
573 {
574 assert(isLLSC());
575 assert(isRead());
576 cmd = MemCmd::ReadReq;
577 }
578
579 /**
580 * Constructor. Note that a Request object must be constructed
581 * first, but the Requests's physical address and size fields need
582 * not be valid. The command must be supplied.
583 */
584 Packet(Request *_req, MemCmd _cmd)
585 : cmd(_cmd), req(_req), data(NULL),
586 src(InvalidPortID), dest(InvalidPortID),
587 bytesValidStart(0), bytesValidEnd(0),
| 332
333 /// The time at which the packet will be fully transmitted
334 Tick finishTime;
335
336 /// The time at which the first chunk of the packet will be transmitted
337 Tick firstWordTime;
338
339 /**
340 * A virtual base opaque structure used to hold state associated
341 * with the packet (e.g., an MSHR), specific to a MemObject that
342 * sees the packet. A pointer to this state is returned in the
343 * packet's response so that the MemObject in question can quickly
344 * look up the state needed to process it. A specific subclass
345 * would be derived from this to carry state specific to a
346 * particular sending device.
347 *
348 * As multiple MemObjects may add their SenderState throughout the
349 * memory system, the SenderStates create a stack, where a
350 * MemObject can add a new Senderstate, as long as the
351 * predecessing SenderState is restored when the response comes
352 * back. For this reason, the predecessor should always be
353 * populated with the current SenderState of a packet before
354 * modifying the senderState field in the request packet.
355 */
356 struct SenderState
357 {
358 SenderState* predecessor;
359 SenderState() : predecessor(NULL) {}
360 virtual ~SenderState() {}
361 };
362
363 /**
364 * Object used to maintain state of a PrintReq. The senderState
365 * field of a PrintReq should always be of this type.
366 */
367 class PrintReqState : public SenderState
368 {
369 private:
370 /**
371 * An entry in the label stack.
372 */
373 struct LabelStackEntry
374 {
375 const std::string label;
376 std::string *prefix;
377 bool labelPrinted;
378 LabelStackEntry(const std::string &_label, std::string *_prefix);
379 };
380
381 typedef std::list<LabelStackEntry> LabelStack;
382 LabelStack labelStack;
383
384 std::string *curPrefixPtr;
385
386 public:
387 std::ostream &os;
388 const int verbosity;
389
390 PrintReqState(std::ostream &os, int verbosity = 0);
391 ~PrintReqState();
392
393 /**
394 * Returns the current line prefix.
395 */
396 const std::string &curPrefix() { return *curPrefixPtr; }
397
398 /**
399 * Push a label onto the label stack, and prepend the given
400 * prefix string onto the current prefix. Labels will only be
401 * printed if an object within the label's scope is printed.
402 */
403 void pushLabel(const std::string &lbl,
404 const std::string &prefix = " ");
405
406 /**
407 * Pop a label off the label stack.
408 */
409 void popLabel();
410
411 /**
412 * Print all of the pending unprinted labels on the
413 * stack. Called by printObj(), so normally not called by
414 * users unless bypassing printObj().
415 */
416 void printLabels();
417
418 /**
419 * Print a Printable object to os, because it matched the
420 * address on a PrintReq.
421 */
422 void printObj(Printable *obj);
423 };
424
425 /**
426 * This packet's sender state. Devices should use dynamic_cast<>
427 * to cast to the state appropriate to the sender. The intent of
428 * this variable is to allow a device to attach extra information
429 * to a request. A response packet must return the sender state
430 * that was attached to the original request (even if a new packet
431 * is created).
432 */
433 SenderState *senderState;
434
435 /**
436 * Push a new sender state to the packet and make the current
437 * sender state the predecessor of the new one. This should be
438 * prefered over direct manipulation of the senderState member
439 * variable.
440 *
441 * @param sender_state SenderState to push at the top of the stack
442 */
443 void pushSenderState(SenderState *sender_state);
444
445 /**
446 * Pop the top of the state stack and return a pointer to it. This
447 * assumes the current sender state is not NULL. This should be
448 * preferred over direct manipulation of the senderState member
449 * variable.
450 *
451 * @return The current top of the stack
452 */
453 SenderState *popSenderState();
454
455 /**
456 * Go through the sender state stack and return the first instance
457 * that is of type T (as determined by a dynamic_cast). If there
458 * is no sender state of type T, NULL is returned.
459 *
460 * @return The topmost state of type T
461 */
462 template <typename T>
463 T * findNextSenderState() const
464 {
465 T *t = NULL;
466 SenderState* sender_state = senderState;
467 while (t == NULL && sender_state != NULL) {
468 t = dynamic_cast<T*>(sender_state);
469 sender_state = sender_state->predecessor;
470 }
471 return t;
472 }
473
474 /// Return the string name of the cmd field (for debugging and
475 /// tracing).
476 const std::string &cmdString() const { return cmd.toString(); }
477
478 /// Return the index of this command.
479 inline int cmdToIndex() const { return cmd.toInt(); }
480
481 bool isRead() const { return cmd.isRead(); }
482 bool isWrite() const { return cmd.isWrite(); }
483 bool isUpgrade() const { return cmd.isUpgrade(); }
484 bool isRequest() const { return cmd.isRequest(); }
485 bool isResponse() const { return cmd.isResponse(); }
486 bool needsExclusive() const { return cmd.needsExclusive(); }
487 bool needsResponse() const { return cmd.needsResponse(); }
488 bool isInvalidate() const { return cmd.isInvalidate(); }
489 bool hasData() const { return cmd.hasData(); }
490 bool isReadWrite() const { return cmd.isReadWrite(); }
491 bool isLLSC() const { return cmd.isLLSC(); }
492 bool isError() const { return cmd.isError(); }
493 bool isPrint() const { return cmd.isPrint(); }
494 bool isFlush() const { return cmd.isFlush(); }
495
496 // Snoop flags
497 void assertMemInhibit() { flags.set(MEM_INHIBIT); }
498 bool memInhibitAsserted() { return flags.isSet(MEM_INHIBIT); }
499 void assertShared() { flags.set(SHARED); }
500 bool sharedAsserted() { return flags.isSet(SHARED); }
501
502 // Special control flags
503 void setExpressSnoop() { flags.set(EXPRESS_SNOOP); }
504 bool isExpressSnoop() { return flags.isSet(EXPRESS_SNOOP); }
505 void setSupplyExclusive() { flags.set(SUPPLY_EXCLUSIVE); }
506 void clearSupplyExclusive() { flags.clear(SUPPLY_EXCLUSIVE); }
507 bool isSupplyExclusive() { return flags.isSet(SUPPLY_EXCLUSIVE); }
508 void setSuppressFuncError() { flags.set(SUPPRESS_FUNC_ERROR); }
509 bool suppressFuncError() { return flags.isSet(SUPPRESS_FUNC_ERROR); }
510
511 // Network error conditions... encapsulate them as methods since
512 // their encoding keeps changing (from result field to command
513 // field, etc.)
514 void
515 setBadAddress()
516 {
517 assert(isResponse());
518 cmd = MemCmd::BadAddressError;
519 }
520
521 bool hadBadAddress() const { return cmd == MemCmd::BadAddressError; }
522 void copyError(Packet *pkt) { assert(pkt->isError()); cmd = pkt->cmd; }
523
524 bool isSrcValid() const { return src != InvalidPortID; }
525 /// Accessor function to get the source index of the packet.
526 PortID getSrc() const { assert(isSrcValid()); return src; }
527 /// Accessor function to set the source index of the packet.
528 void setSrc(PortID _src) { src = _src; }
529 /// Reset source field, e.g. to retransmit packet on different bus.
530 void clearSrc() { src = InvalidPortID; }
531
532 bool isDestValid() const { return dest != InvalidPortID; }
533 /// Accessor function for the destination index of the packet.
534 PortID getDest() const { assert(isDestValid()); return dest; }
535 /// Accessor function to set the destination index of the packet.
536 void setDest(PortID _dest) { dest = _dest; }
537 /// Reset destination field, e.g. to turn a response into a request again.
538 void clearDest() { dest = InvalidPortID; }
539
540 Addr getAddr() const { assert(flags.isSet(VALID_ADDR)); return addr; }
541 /**
542 * Update the address of this packet mid-transaction. This is used
543 * by the address mapper to change an already set address to a new
544 * one based on the system configuration. It is intended to remap
545 * an existing address, so it asserts that the current address is
546 * valid.
547 */
548 void setAddr(Addr _addr) { assert(flags.isSet(VALID_ADDR)); addr = _addr; }
549
550 unsigned getSize() const { assert(flags.isSet(VALID_SIZE)); return size; }
551 Addr getOffset(int blkSize) const { return getAddr() & (Addr)(blkSize - 1); }
552
553 /**
554 * It has been determined that the SC packet should successfully update
555 * memory. Therefore, convert this SC packet to a normal write.
556 */
557 void
558 convertScToWrite()
559 {
560 assert(isLLSC());
561 assert(isWrite());
562 cmd = MemCmd::WriteReq;
563 }
564
565 /**
566 * When ruby is in use, Ruby will monitor the cache line and thus M5
567 * phys memory should treat LL ops as normal reads.
568 */
569 void
570 convertLlToRead()
571 {
572 assert(isLLSC());
573 assert(isRead());
574 cmd = MemCmd::ReadReq;
575 }
576
577 /**
578 * Constructor. Note that a Request object must be constructed
579 * first, but the Requests's physical address and size fields need
580 * not be valid. The command must be supplied.
581 */
582 Packet(Request *_req, MemCmd _cmd)
583 : cmd(_cmd), req(_req), data(NULL),
584 src(InvalidPortID), dest(InvalidPortID),
585 bytesValidStart(0), bytesValidEnd(0),
|
588 time(curTick()), senderState(NULL)
| 586 senderState(NULL)
|
589 {
590 if (req->hasPaddr()) {
591 addr = req->getPaddr();
592 flags.set(VALID_ADDR);
593 }
594 if (req->hasSize()) {
595 size = req->getSize();
596 flags.set(VALID_SIZE);
597 }
598 }
599
600 /**
601 * Alternate constructor if you are trying to create a packet with
602 * a request that is for a whole block, not the address from the
603 * req. this allows for overriding the size/addr of the req.
604 */
605 Packet(Request *_req, MemCmd _cmd, int _blkSize)
606 : cmd(_cmd), req(_req), data(NULL),
607 src(InvalidPortID), dest(InvalidPortID),
608 bytesValidStart(0), bytesValidEnd(0),
| 587 {
588 if (req->hasPaddr()) {
589 addr = req->getPaddr();
590 flags.set(VALID_ADDR);
591 }
592 if (req->hasSize()) {
593 size = req->getSize();
594 flags.set(VALID_SIZE);
595 }
596 }
597
598 /**
599 * Alternate constructor if you are trying to create a packet with
600 * a request that is for a whole block, not the address from the
601 * req. this allows for overriding the size/addr of the req.
602 */
603 Packet(Request *_req, MemCmd _cmd, int _blkSize)
604 : cmd(_cmd), req(_req), data(NULL),
605 src(InvalidPortID), dest(InvalidPortID),
606 bytesValidStart(0), bytesValidEnd(0),
|
609 time(curTick()), senderState(NULL)
| 607 senderState(NULL)
|
610 {
611 if (req->hasPaddr()) {
612 addr = req->getPaddr() & ~(_blkSize - 1);
613 flags.set(VALID_ADDR);
614 }
615 size = _blkSize;
616 flags.set(VALID_SIZE);
617 }
618
619 /**
620 * Alternate constructor for copying a packet. Copy all fields
621 * *except* if the original packet's data was dynamic, don't copy
622 * that, as we can't guarantee that the new packet's lifetime is
623 * less than that of the original packet. In this case the new
624 * packet should allocate its own data.
625 */
626 Packet(Packet *pkt, bool clearFlags = false)
627 : cmd(pkt->cmd), req(pkt->req),
628 data(pkt->flags.isSet(STATIC_DATA) ? pkt->data : NULL),
629 addr(pkt->addr), size(pkt->size), src(pkt->src), dest(pkt->dest),
630 bytesValidStart(pkt->bytesValidStart), bytesValidEnd(pkt->bytesValidEnd),
| 608 {
609 if (req->hasPaddr()) {
610 addr = req->getPaddr() & ~(_blkSize - 1);
611 flags.set(VALID_ADDR);
612 }
613 size = _blkSize;
614 flags.set(VALID_SIZE);
615 }
616
617 /**
618 * Alternate constructor for copying a packet. Copy all fields
619 * *except* if the original packet's data was dynamic, don't copy
620 * that, as we can't guarantee that the new packet's lifetime is
621 * less than that of the original packet. In this case the new
622 * packet should allocate its own data.
623 */
624 Packet(Packet *pkt, bool clearFlags = false)
625 : cmd(pkt->cmd), req(pkt->req),
626 data(pkt->flags.isSet(STATIC_DATA) ? pkt->data : NULL),
627 addr(pkt->addr), size(pkt->size), src(pkt->src), dest(pkt->dest),
628 bytesValidStart(pkt->bytesValidStart), bytesValidEnd(pkt->bytesValidEnd),
|
631 time(curTick()), senderState(pkt->senderState)
| 629 senderState(pkt->senderState)
|
632 {
633 if (!clearFlags)
634 flags.set(pkt->flags & COPY_FLAGS);
635
636 flags.set(pkt->flags & (VALID_ADDR|VALID_SIZE));
637 flags.set(pkt->flags & STATIC_DATA);
638
639 }
640
641 /**
642 * clean up packet variables
643 */
644 ~Packet()
645 {
646 // If this is a request packet for which there's no response,
647 // delete the request object here, since the requester will
648 // never get the chance.
649 if (req && isRequest() && !needsResponse())
650 delete req;
651 deleteData();
652 }
653
654 /**
655 * Reinitialize packet address and size from the associated
656 * Request object, and reset other fields that may have been
657 * modified by a previous transaction. Typically called when a
658 * statically allocated Request/Packet pair is reused for multiple
659 * transactions.
660 */
661 void
662 reinitFromRequest()
663 {
664 assert(req->hasPaddr());
665 flags = 0;
666 addr = req->getPaddr();
667 size = req->getSize();
| 630 {
631 if (!clearFlags)
632 flags.set(pkt->flags & COPY_FLAGS);
633
634 flags.set(pkt->flags & (VALID_ADDR|VALID_SIZE));
635 flags.set(pkt->flags & STATIC_DATA);
636
637 }
638
639 /**
640 * clean up packet variables
641 */
642 ~Packet()
643 {
644 // If this is a request packet for which there's no response,
645 // delete the request object here, since the requester will
646 // never get the chance.
647 if (req && isRequest() && !needsResponse())
648 delete req;
649 deleteData();
650 }
651
652 /**
653 * Reinitialize packet address and size from the associated
654 * Request object, and reset other fields that may have been
655 * modified by a previous transaction. Typically called when a
656 * statically allocated Request/Packet pair is reused for multiple
657 * transactions.
658 */
659 void
660 reinitFromRequest()
661 {
662 assert(req->hasPaddr());
663 flags = 0;
664 addr = req->getPaddr();
665 size = req->getSize();
|
668 time = req->time();
| |
669
670 flags.set(VALID_ADDR|VALID_SIZE);
671 deleteData();
672 }
673
674 /**
675 * Take a request packet and modify it in place to be suitable for
676 * returning as a response to that request. The source field is
677 * turned into the destination, and subsequently cleared. Note
678 * that the latter is not necessary for atomic requests, but
679 * causes no harm as neither field is valid.
680 */
681 void
682 makeResponse()
683 {
684 assert(needsResponse());
685 assert(isRequest());
686 origCmd = cmd;
687 cmd = cmd.responseCommand();
688
689 // responses are never express, even if the snoop that
690 // triggered them was
691 flags.clear(EXPRESS_SNOOP);
692
693 dest = src;
694 clearSrc();
695 }
696
697 void
698 makeAtomicResponse()
699 {
700 makeResponse();
701 }
702
703 void
704 makeTimingResponse()
705 {
706 makeResponse();
707 }
708
709 void
710 setFunctionalResponseStatus(bool success)
711 {
712 if (!success) {
713 if (isWrite()) {
714 cmd = MemCmd::FunctionalWriteError;
715 } else {
716 cmd = MemCmd::FunctionalReadError;
717 }
718 }
719 }
720
721 void
722 setSize(unsigned size)
723 {
724 assert(!flags.isSet(VALID_SIZE));
725
726 this->size = size;
727 flags.set(VALID_SIZE);
728 }
729
730
731 /**
732 * Set the data pointer to the following value that should not be
733 * freed.
734 */
735 template <typename T>
736 void
737 dataStatic(T *p)
738 {
739 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
740 data = (PacketDataPtr)p;
741 flags.set(STATIC_DATA);
742 }
743
744 /**
745 * Set the data pointer to a value that should have delete []
746 * called on it.
747 */
748 template <typename T>
749 void
750 dataDynamicArray(T *p)
751 {
752 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
753 data = (PacketDataPtr)p;
754 flags.set(DYNAMIC_DATA|ARRAY_DATA);
755 }
756
757 /**
758 * set the data pointer to a value that should have delete called
759 * on it.
760 */
761 template <typename T>
762 void
763 dataDynamic(T *p)
764 {
765 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
766 data = (PacketDataPtr)p;
767 flags.set(DYNAMIC_DATA);
768 }
769
770 /**
771 * get a pointer to the data ptr.
772 */
773 template <typename T>
774 T*
775 getPtr(bool null_ok = false)
776 {
777 assert(null_ok || flags.isSet(STATIC_DATA|DYNAMIC_DATA));
778 return (T*)data;
779 }
780
781 /**
782 * return the value of what is pointed to in the packet.
783 */
784 template <typename T>
785 T get();
786
787 /**
788 * set the value in the data pointer to v.
789 */
790 template <typename T>
791 void set(T v);
792
793 /**
794 * Copy data into the packet from the provided pointer.
795 */
796 void
797 setData(uint8_t *p)
798 {
799 if (p != getPtr<uint8_t>())
800 std::memcpy(getPtr<uint8_t>(), p, getSize());
801 }
802
803 /**
804 * Copy data into the packet from the provided block pointer,
805 * which is aligned to the given block size.
806 */
807 void
808 setDataFromBlock(uint8_t *blk_data, int blkSize)
809 {
810 setData(blk_data + getOffset(blkSize));
811 }
812
813 /**
814 * Copy data from the packet to the provided block pointer, which
815 * is aligned to the given block size.
816 */
817 void
818 writeData(uint8_t *p)
819 {
820 std::memcpy(p, getPtr<uint8_t>(), getSize());
821 }
822
823 /**
824 * Copy data from the packet to the memory at the provided pointer.
825 */
826 void
827 writeDataToBlock(uint8_t *blk_data, int blkSize)
828 {
829 writeData(blk_data + getOffset(blkSize));
830 }
831
832 /**
833 * delete the data pointed to in the data pointer. Ok to call to
834 * matter how data was allocted.
835 */
836 void
837 deleteData()
838 {
839 if (flags.isSet(ARRAY_DATA))
840 delete [] data;
841 else if (flags.isSet(DYNAMIC_DATA))
842 delete data;
843
844 flags.clear(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA);
845 data = NULL;
846 }
847
848 /** If there isn't data in the packet, allocate some. */
849 void
850 allocate()
851 {
852 if (data) {
853 assert(flags.isSet(STATIC_DATA|DYNAMIC_DATA));
854 return;
855 }
856
857 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA));
858 flags.set(DYNAMIC_DATA|ARRAY_DATA);
859 data = new uint8_t[getSize()];
860 }
861
862 /**
863 * Check a functional request against a memory value represented
864 * by a base/size pair and an associated data array. If the
865 * functional request is a read, it may be satisfied by the memory
866 * value. If the functional request is a write, it may update the
867 * memory value.
868 */
869 bool checkFunctional(Printable *obj, Addr base, int size, uint8_t *data);
870
871 /**
872 * Check a functional request against a memory value stored in
873 * another packet (i.e. an in-transit request or response).
874 */
875 bool
876 checkFunctional(PacketPtr other)
877 {
878 uint8_t *data = other->hasData() ? other->getPtr<uint8_t>() : NULL;
879 return checkFunctional(other, other->getAddr(), other->getSize(),
880 data);
881 }
882
883 /**
884 * Push label for PrintReq (safe to call unconditionally).
885 */
886 void
887 pushLabel(const std::string &lbl)
888 {
889 if (isPrint())
890 safe_cast<PrintReqState*>(senderState)->pushLabel(lbl);
891 }
892
893 /**
894 * Pop label for PrintReq (safe to call unconditionally).
895 */
896 void
897 popLabel()
898 {
899 if (isPrint())
900 safe_cast<PrintReqState*>(senderState)->popLabel();
901 }
902
903 void print(std::ostream &o, int verbosity = 0,
904 const std::string &prefix = "") const;
905};
906
907#endif //__MEM_PACKET_HH
| 666
667 flags.set(VALID_ADDR|VALID_SIZE);
668 deleteData();
669 }
670
671 /**
672 * Take a request packet and modify it in place to be suitable for
673 * returning as a response to that request. The source field is
674 * turned into the destination, and subsequently cleared. Note
675 * that the latter is not necessary for atomic requests, but
676 * causes no harm as neither field is valid.
677 */
678 void
679 makeResponse()
680 {
681 assert(needsResponse());
682 assert(isRequest());
683 origCmd = cmd;
684 cmd = cmd.responseCommand();
685
686 // responses are never express, even if the snoop that
687 // triggered them was
688 flags.clear(EXPRESS_SNOOP);
689
690 dest = src;
691 clearSrc();
692 }
693
694 void
695 makeAtomicResponse()
696 {
697 makeResponse();
698 }
699
700 void
701 makeTimingResponse()
702 {
703 makeResponse();
704 }
705
706 void
707 setFunctionalResponseStatus(bool success)
708 {
709 if (!success) {
710 if (isWrite()) {
711 cmd = MemCmd::FunctionalWriteError;
712 } else {
713 cmd = MemCmd::FunctionalReadError;
714 }
715 }
716 }
717
718 void
719 setSize(unsigned size)
720 {
721 assert(!flags.isSet(VALID_SIZE));
722
723 this->size = size;
724 flags.set(VALID_SIZE);
725 }
726
727
728 /**
729 * Set the data pointer to the following value that should not be
730 * freed.
731 */
732 template <typename T>
733 void
734 dataStatic(T *p)
735 {
736 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
737 data = (PacketDataPtr)p;
738 flags.set(STATIC_DATA);
739 }
740
741 /**
742 * Set the data pointer to a value that should have delete []
743 * called on it.
744 */
745 template <typename T>
746 void
747 dataDynamicArray(T *p)
748 {
749 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
750 data = (PacketDataPtr)p;
751 flags.set(DYNAMIC_DATA|ARRAY_DATA);
752 }
753
754 /**
755 * set the data pointer to a value that should have delete called
756 * on it.
757 */
758 template <typename T>
759 void
760 dataDynamic(T *p)
761 {
762 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA));
763 data = (PacketDataPtr)p;
764 flags.set(DYNAMIC_DATA);
765 }
766
767 /**
768 * get a pointer to the data ptr.
769 */
770 template <typename T>
771 T*
772 getPtr(bool null_ok = false)
773 {
774 assert(null_ok || flags.isSet(STATIC_DATA|DYNAMIC_DATA));
775 return (T*)data;
776 }
777
778 /**
779 * return the value of what is pointed to in the packet.
780 */
781 template <typename T>
782 T get();
783
784 /**
785 * set the value in the data pointer to v.
786 */
787 template <typename T>
788 void set(T v);
789
790 /**
791 * Copy data into the packet from the provided pointer.
792 */
793 void
794 setData(uint8_t *p)
795 {
796 if (p != getPtr<uint8_t>())
797 std::memcpy(getPtr<uint8_t>(), p, getSize());
798 }
799
800 /**
801 * Copy data into the packet from the provided block pointer,
802 * which is aligned to the given block size.
803 */
804 void
805 setDataFromBlock(uint8_t *blk_data, int blkSize)
806 {
807 setData(blk_data + getOffset(blkSize));
808 }
809
810 /**
811 * Copy data from the packet to the provided block pointer, which
812 * is aligned to the given block size.
813 */
814 void
815 writeData(uint8_t *p)
816 {
817 std::memcpy(p, getPtr<uint8_t>(), getSize());
818 }
819
820 /**
821 * Copy data from the packet to the memory at the provided pointer.
822 */
823 void
824 writeDataToBlock(uint8_t *blk_data, int blkSize)
825 {
826 writeData(blk_data + getOffset(blkSize));
827 }
828
829 /**
830 * delete the data pointed to in the data pointer. Ok to call to
831 * matter how data was allocted.
832 */
833 void
834 deleteData()
835 {
836 if (flags.isSet(ARRAY_DATA))
837 delete [] data;
838 else if (flags.isSet(DYNAMIC_DATA))
839 delete data;
840
841 flags.clear(STATIC_DATA|DYNAMIC_DATA|ARRAY_DATA);
842 data = NULL;
843 }
844
845 /** If there isn't data in the packet, allocate some. */
846 void
847 allocate()
848 {
849 if (data) {
850 assert(flags.isSet(STATIC_DATA|DYNAMIC_DATA));
851 return;
852 }
853
854 assert(flags.noneSet(STATIC_DATA|DYNAMIC_DATA));
855 flags.set(DYNAMIC_DATA|ARRAY_DATA);
856 data = new uint8_t[getSize()];
857 }
858
859 /**
860 * Check a functional request against a memory value represented
861 * by a base/size pair and an associated data array. If the
862 * functional request is a read, it may be satisfied by the memory
863 * value. If the functional request is a write, it may update the
864 * memory value.
865 */
866 bool checkFunctional(Printable *obj, Addr base, int size, uint8_t *data);
867
868 /**
869 * Check a functional request against a memory value stored in
870 * another packet (i.e. an in-transit request or response).
871 */
872 bool
873 checkFunctional(PacketPtr other)
874 {
875 uint8_t *data = other->hasData() ? other->getPtr<uint8_t>() : NULL;
876 return checkFunctional(other, other->getAddr(), other->getSize(),
877 data);
878 }
879
880 /**
881 * Push label for PrintReq (safe to call unconditionally).
882 */
883 void
884 pushLabel(const std::string &lbl)
885 {
886 if (isPrint())
887 safe_cast<PrintReqState*>(senderState)->pushLabel(lbl);
888 }
889
890 /**
891 * Pop label for PrintReq (safe to call unconditionally).
892 */
893 void
894 popLabel()
895 {
896 if (isPrint())
897 safe_cast<PrintReqState*>(senderState)->popLabel();
898 }
899
900 void print(std::ostream &o, int verbosity = 0,
901 const std::string &prefix = "") const;
902};
903
904#endif //__MEM_PACKET_HH
|