1.\" 2.\" Mach Operating System 3.\" Copyright (c) 1991,1990 Carnegie Mellon University 4.\" Copyright (c) 2007 Robert N. M. Watson 5.\" All Rights Reserved. 6.\" 7.\" Permission to use, copy, modify and distribute this software and its 8.\" documentation is hereby granted, provided that both the copyright 9.\" notice and this permission notice appear in all copies of the 10.\" software, derivative works or modified versions, and any portions 11.\" thereof, and that both notices appear in supporting documentation. 12.\" 13.\" CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 14.\" CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR 15.\" ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 16.\" 17.\" Carnegie Mellon requests users of this software to return to 18.\" 19.\" Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU 20.\" School of Computer Science 21.\" Carnegie Mellon University 22.\" Pittsburgh PA 15213-3890 23.\" 24.\" any improvements or extensions that they make and grant Carnegie Mellon 25.\" the rights to redistribute these changes. 26.\" 27.\" changed a \# to #, since groff choked on it. 28.\" 29.\" HISTORY 30.\" ddb.4,v 31.\" Revision 1.1 1993/07/15 18:41:02 brezak 32.\" Man page for DDB 33.\" 34.\" Revision 2.6 92/04/08 08:52:57 rpd 35.\" Changes from OSF. 36.\" [92/01/17 14:19:22 jsb] 37.\" Changes for OSF debugger modifications. 38.\" [91/12/12 tak] 39.\" 40.\" Revision 2.5 91/06/25 13:50:22 rpd 41.\" Added some watchpoint explanation. 42.\" [91/06/25 rpd] 43.\" 44.\" Revision 2.4 91/06/17 15:47:31 jsb 45.\" Added documentation for continue/c, match, search, and watchpoints. 46.\" I've not actually explained what a watchpoint is; maybe Rich can 47.\" do that (hint, hint). 48.\" [91/06/17 10:58:08 jsb] 49.\" 50.\" Revision 2.3 91/05/14 17:04:23 mrt 51.\" Correcting copyright 52.\" 53.\" Revision 2.2 91/02/14 14:10:06 mrt 54.\" Changed to new Mach copyright 55.\" [91/02/12 18:10:12 mrt] 56.\" 57.\" Revision 2.2 90/08/30 14:23:15 dbg 58.\" Created. 59.\" [90/08/30 dbg] 60.\" 61.\" $FreeBSD$ 62.\" 63.Dd May 24, 2010 64.Dt DDB 4 65.Os 66.Sh NAME 67.Nm ddb 68.Nd interactive kernel debugger 69.Sh SYNOPSIS 70In order to enable kernel debugging facilities include: 71.Bd -ragged -offset indent 72.Cd options KDB 73.Cd options DDB 74.Ed 75.Pp 76To prevent activation of the debugger on kernel 77.Xr panic 9 : 78.Bd -ragged -offset indent 79.Cd options KDB_UNATTENDED 80.Ed 81.Pp 82In order to print a stack trace of the current thread on the console 83for a panic: 84.Bd -ragged -offset indent 85.Cd options KDB_TRACE 86.Ed 87.Pp 88To print the numerical value of symbols in addition to the symbolic 89representation, define: 90.Bd -ragged -offset indent 91.Cd options DDB_NUMSYM 92.Ed 93.Pp 94To enable the 95.Xr gdb 1 96backend, so that remote debugging with 97.Xr kgdb 1 98is possible, include: 99.Bd -ragged -offset indent 100.Cd options GDB 101.Ed 102.Sh DESCRIPTION 103The 104.Nm 105kernel debugger is an interactive debugger with a syntax inspired by 106.Xr gdb 1 . 107If linked into the running kernel, 108it can be invoked locally with the 109.Ql debug 110.Xr keymap 5 111action. 112The debugger is also invoked on kernel 113.Xr panic 9 114if the 115.Va debug.debugger_on_panic 116.Xr sysctl 8 117MIB variable is set non-zero, 118which is the default 119unless the 120.Dv KDB_UNATTENDED 121option is specified. 122.Pp 123The current location is called 124.Va dot . 125The 126.Va dot 127is displayed with 128a hexadecimal format at a prompt. 129The commands 130.Ic examine 131and 132.Ic write 133update 134.Va dot 135to the address of the last line 136examined or the last location modified, and set 137.Va next 138to the address of 139the next location to be examined or changed. 140Other commands do not change 141.Va dot , 142and set 143.Va next 144to be the same as 145.Va dot . 146.Pp 147The general command syntax is: 148.Ar command Ns Op Li / Ns Ar modifier 149.Ar address Ns Op Li , Ns Ar count 150.Pp 151A blank line repeats the previous command from the address 152.Va next 153with 154count 1 and no modifiers. 155Specifying 156.Ar address 157sets 158.Va dot 159to the address. 160Omitting 161.Ar address 162uses 163.Va dot . 164A missing 165.Ar count 166is taken 167to be 1 for printing commands or infinity for stack traces. 168.Pp 169The 170.Nm 171debugger has a pager feature (like the 172.Xr more 1 173command) 174for the output. 175If an output line exceeds the number set in the 176.Va lines 177variable, it displays 178.Dq Li --More-- 179and waits for a response. 180The valid responses for it are: 181.Pp 182.Bl -tag -compact -width ".Li SPC" 183.It Li SPC 184one more page 185.It Li RET 186one more line 187.It Li q 188abort the current command, and return to the command input mode 189.El 190.Pp 191Finally, 192.Nm 193provides a small (currently 10 items) command history, and offers 194simple 195.Nm emacs Ns -style 196command line editing capabilities. 197In addition to 198the 199.Nm emacs 200control keys, the usual 201.Tn ANSI 202arrow keys may be used to 203browse through the history buffer, and move the cursor within the 204current line. 205.Sh COMMANDS 206.Bl -tag -width indent -compact 207.It Ic examine 208.It Ic x 209Display the addressed locations according to the formats in the modifier. 210Multiple modifier formats display multiple locations. 211If no format is specified, the last format specified for this command 212is used. 213.Pp 214The format characters are: 215.Bl -tag -compact -width indent 216.It Cm b 217look at by bytes (8 bits) 218.It Cm h 219look at by half words (16 bits) 220.It Cm l 221look at by long words (32 bits) 222.It Cm a 223print the location being displayed 224.It Cm A 225print the location with a line number if possible 226.It Cm x 227display in unsigned hex 228.It Cm z 229display in signed hex 230.It Cm o 231display in unsigned octal 232.It Cm d 233display in signed decimal 234.It Cm u 235display in unsigned decimal 236.It Cm r 237display in current radix, signed 238.It Cm c 239display low 8 bits as a character. 240Non-printing characters are displayed as an octal escape code (e.g., 241.Ql \e000 ) . 242.It Cm s 243display the null-terminated string at the location. 244Non-printing characters are displayed as octal escapes. 245.It Cm m 246display in unsigned hex with character dump at the end of each line. 247The location is also displayed in hex at the beginning of each line. 248.It Cm i 249display as an instruction 250.It Cm I 251display as an instruction with possible alternate formats depending on the 252machine: 253.Bl -tag -width ".Tn powerpc" -compact 254.It Tn amd64 255No alternate format. 256.It Tn i386 257No alternate format. 258.It Tn ia64 259No alternate format. 260.It Tn powerpc 261No alternate format. 262.It Tn sparc64 263No alternate format. 264.El 265.It Cm S 266display a symbol name for the pointer stored at the address 267.El 268.Pp 269.It Ic xf 270Examine forward: 271execute an 272.Ic examine 273command with the last specified parameters to it 274except that the next address displayed by it is used as the start address. 275.Pp 276.It Ic xb 277Examine backward: 278execute an 279.Ic examine 280command with the last specified parameters to it 281except that the last start address subtracted by the size displayed by it 282is used as the start address. 283.Pp 284.It Ic print Ns Op Li / Ns Cm acdoruxz 285.It Ic p Ns Op Li / Ns Cm acdoruxz 286Print 287.Ar addr Ns s 288according to the modifier character (as described above for 289.Cm examine ) . 290Valid formats are: 291.Cm a , x , z , o , d , u , r , 292and 293.Cm c . 294If no modifier is specified, the last one specified to it is used. 295The argument 296.Ar addr 297can be a string, in which case it is printed as it is. 298For example: 299.Bd -literal -offset indent 300print/x "eax = " $eax "\enecx = " $ecx "\en" 301.Ed 302.Pp 303will print like: 304.Bd -literal -offset indent 305eax = xxxxxx 306ecx = yyyyyy 307.Ed 308.Pp 309.It Xo 310.Ic write Ns Op Li / Ns Cm bhl 311.Ar addr expr1 Op Ar expr2 ... 312.Xc 313.It Xo 314.Ic w Ns Op Li / Ns Cm bhl 315.Ar addr expr1 Op Ar expr2 ... 316.Xc 317Write the expressions specified after 318.Ar addr 319on the command line at succeeding locations starting with 320.Ar addr . 321The write unit size can be specified in the modifier with a letter 322.Cm b 323(byte), 324.Cm h 325(half word) or 326.Cm l 327(long word) respectively. 328If omitted, 329long word is assumed. 330.Pp 331.Sy Warning : 332since there is no delimiter between expressions, strange 333things may happen. 334It is best to enclose each expression in parentheses. 335.Pp 336.It Ic set Li $ Ns Ar variable Oo Li = Oc Ar expr 337Set the named variable or register with the value of 338.Ar expr . 339Valid variable names are described below. 340.Pp 341.It Ic break Ns Op Li / Ns Cm u 342.It Ic b Ns Op Li / Ns Cm u 343Set a break point at 344.Ar addr . 345If 346.Ar count 347is supplied, continues 348.Ar count 349\- 1 times before stopping at the 350break point. 351If the break point is set, a break point number is 352printed with 353.Ql # . 354This number can be used in deleting the break point 355or adding conditions to it. 356.Pp 357If the 358.Cm u 359modifier is specified, this command sets a break point in user 360address space. 361Without the 362.Cm u 363option, the address is considered to be in the kernel 364space, and a wrong space address is rejected with an error message. 365This modifier can be used only if it is supported by machine dependent 366routines. 367.Pp 368.Sy Warning : 369If a user text is shadowed by a normal user space debugger, 370user space break points may not work correctly. 371Setting a break 372point at the low-level code paths may also cause strange behavior. 373.Pp 374.It Ic delete Ar addr 375.It Ic d Ar addr 376.It Ic delete Li # Ns Ar number 377.It Ic d Li # Ns Ar number 378Delete the break point. 379The target break point can be specified by a 380break point number with 381.Ql # , 382or by using the same 383.Ar addr 384specified in the original 385.Ic break 386command. 387.Pp 388.It Ic watch Ar addr Ns Li , Ns Ar size 389Set a watchpoint for a region. 390Execution stops when an attempt to modify the region occurs. 391The 392.Ar size 393argument defaults to 4. 394If you specify a wrong space address, the request is rejected 395with an error message. 396.Pp 397.Sy Warning : 398Attempts to watch wired kernel memory 399may cause unrecoverable error in some systems such as i386. 400Watchpoints on user addresses work best. 401.Pp 402.It Ic hwatch Ar addr Ns Li , Ns Ar size 403Set a hardware watchpoint for a region if supported by the 404architecture. 405Execution stops when an attempt to modify the region occurs. 406The 407.Ar size 408argument defaults to 4. 409.Pp 410.Sy Warning : 411The hardware debug facilities do not have a concept of separate 412address spaces like the watch command does. 413Use 414.Ic hwatch 415for setting watchpoints on kernel address locations only, and avoid 416its use on user mode address spaces. 417.Pp 418.It Ic dhwatch Ar addr Ns Li , Ns Ar size 419Delete specified hardware watchpoint. 420.Pp 421.It Ic step Ns Op Li / Ns Cm p 422.It Ic s Ns Op Li / Ns Cm p 423Single step 424.Ar count 425times (the comma is a mandatory part of the syntax). 426If the 427.Cm p 428modifier is specified, print each instruction at each step. 429Otherwise, only print the last instruction. 430.Pp 431.Sy Warning : 432depending on machine type, it may not be possible to 433single-step through some low-level code paths or user space code. 434On machines with software-emulated single-stepping (e.g., pmax), 435stepping through code executed by interrupt handlers will probably 436do the wrong thing. 437.Pp 438.It Ic continue Ns Op Li / Ns Cm c 439.It Ic c Ns Op Li / Ns Cm c 440Continue execution until a breakpoint or watchpoint. 441If the 442.Cm c 443modifier is specified, count instructions while executing. 444Some machines (e.g., pmax) also count loads and stores. 445.Pp 446.Sy Warning : 447when counting, the debugger is really silently single-stepping. 448This means that single-stepping on low-level code may cause strange 449behavior. 450.Pp 451.It Ic until Ns Op Li / Ns Cm p 452Stop at the next call or return instruction. 453If the 454.Cm p 455modifier is specified, print the call nesting depth and the 456cumulative instruction count at each call or return. 457Otherwise, 458only print when the matching return is hit. 459.Pp 460.It Ic next Ns Op Li / Ns Cm p 461.It Ic match Ns Op Li / Ns Cm p 462Stop at the matching return instruction. 463If the 464.Cm p 465modifier is specified, print the call nesting depth and the 466cumulative instruction count at each call or return. 467Otherwise, only print when the matching return is hit. 468.Pp 469.It Xo 470.Ic trace Ns Op Li / Ns Cm u 471.Op Ar pid | tid 472.Op Li , Ns Ar count 473.Xc 474.It Xo 475.Ic t Ns Op Li / Ns Cm u 476.Op Ar pid | tid 477.Op Li , Ns Ar count 478.Xc 479.It Xo 480.Ic where Ns Op Li / Ns Cm u 481.Op Ar pid | tid 482.Op Li , Ns Ar count 483.Xc 484.It Xo 485.Ic bt Ns Op Li / Ns Cm u 486.Op Ar pid | tid 487.Op Li , Ns Ar count 488.Xc 489Stack trace. 490The 491.Cm u 492option traces user space; if omitted, 493.Ic trace 494only traces 495kernel space. 496The optional argument 497.Ar count 498is the number of frames to be traced. 499If 500.Ar count 501is omitted, all frames are printed. 502.Pp 503.Sy Warning : 504User space stack trace is valid 505only if the machine dependent code supports it. 506.Pp 507.It Xo 508.Ic search Ns Op Li / Ns Cm bhl 509.Ar addr 510.Ar value 511.Op Ar mask 512.Op Li , Ns Ar count 513.Xc 514Search memory for 515.Ar value . 516This command might fail in interesting 517ways if it does not find the searched-for value. 518This is because 519.Nm 520does not always recover from touching bad memory. 521The optional 522.Ar count 523argument limits the search. 524.\" 525.Pp 526.It Ic show Cm all procs Ns Op Li / Ns Cm m 527.It Ic ps Ns Op Li / Ns Cm m 528Display all process information. 529The process information may not be shown if it is not 530supported in the machine, or the bottom of the stack of the 531target process is not in the main memory at that time. 532The 533.Cm m 534modifier will alter the display to show VM map 535addresses for the process and not show other information. 536.\" 537.Pp 538.It Ic show Cm all ttys 539Show all TTY's within the system. 540Output is similar to 541.Xr pstat 8 , 542but also includes the address of the TTY structure. 543.\" 544.Pp 545.It Ic show Cm allchains 546Show the same information like "show lockchain" does, but 547for every thread in the system. 548.\" 549.Pp 550.It Ic show Cm alllocks 551Show all locks that are currently held. 552This command is only available if 553.Xr witness 4 554is included in the kernel. 555.\" 556.Pp 557.It Ic show Cm allpcpu 558The same as "show pcpu", but for every CPU present in the system. 559.\" 560.Pp 561.It Ic show Cm allrman 562Show information related with resource management, including 563interrupt request lines, DMA request lines, I/O ports and I/O memory 564addresses. 565.\" 566.Pp 567.It Ic show Cm apic 568Dump data about APIC IDT vector mappings. 569.\" 570.Pp 571.It Ic show Cm breaks 572Show breakpoints set with the "break" command. 573.\" 574.Pp 575.It Ic show Cm buffer 576Show buffer structure of 577.Vt struct buf 578type. 579Such a structure is used within the 580.Fx 581kernel for the I/O subsystem 582implementation. 583For an exact interpretation of the output, please see the 584.Pa sys/buf.h 585header file. 586.\" 587.Pp 588.It Ic show Cm cbstat 589Show brief information about the TTY subsystem. 590.\" 591.Pp 592.It Ic show Cm conifhk 593Lists hooks currently waiting for completion in 594run_interrupt_driven_config_hooks(). 595.\" 596.Pp 597.It Ic show Cm cpusets 598Print numbered root and assigned CPU affinity sets. 599See 600.Xr cpuset 2 601for more details. 602.\" 603.Pp 604.It Ic show Cm cyrixreg 605Show registers specific to the Cyrix processor. 606.\" 607.Pp 608.It Ic show Cm domain Ar addr 609Print protocol domain structure 610.Vt struct domain 611at address 612.Ar addr . 613See the 614.Pa sys/domain.h 615header file for more details on the exact meaning of the structure fields. 616.\" 617.Pp 618.It Ic show Cm ffs Op Ar addr 619Show brief information about ffs mount at the address 620.Ar addr , 621if argument is given. 622Otherwise, provides the summary about each ffs mount. 623.\" 624.Pp 625.It Ic show Cm file Ar addr 626Show information about the file structure 627.Vt struct file 628present at address 629.Ar addr . 630.\" 631.Pp 632.It Ic show Cm files 633Show information about every file structure in the system. 634.\" 635.Pp 636.It Ic show Cm freepages 637Show the number of physical pages in each of the free lists. 638.\" 639.Pp 640.It Ic show Cm geom Op Ar addr 641If the 642.Ar addr 643argument is not given, displays the entire GEOM topology. 644If 645.Ar addr 646is given, displays details about the given GEOM object (class, geom, 647provider or consumer). 648.\" 649.Pp 650.It Ic show Cm idt 651Show IDT layout. 652The first column specifies the IDT vector. 653The second one is the name of the interrupt/trap handler. 654Those functions are machine dependent. 655.\" 656.Pp 657.It Ic show Cm inodedeps Op Ar addr 658Show brief information about each inodedep structure. 659If 660.Ar addr 661is given, only inodedeps belonging to the fs located at the 662supplied address are shown. 663.\" 664.Pp 665.It Ic show Cm inpcb Ar addr 666Show information on IP Control Block 667.Vt struct in_pcb 668present at 669.Ar addr . 670.\" 671.Pp 672.It Ic show Cm intr 673Dump information about interrupt handlers. 674.\" 675.Pp 676.It Ic show Cm intrcnt 677Dump the interrupt statistics. 678.\" 679.Pp 680.It Ic show Cm irqs 681Show interrupt lines and their respective kernel threads. 682.\" 683.Pp 684.It Ic show Cm jails 685Show the list of 686.Xr jail 8 687instances. 688In addition to what 689.Xr jls 8 690shows, also list kernel internal details. 691.\" 692.Pp 693.It Ic show Cm lapic 694Show information from the local APIC registers for this CPU. 695.\" 696.Pp 697.It Ic show Cm lock Ar addr 698Show lock structure. 699The output format is as follows: 700.Bl -tag -width "flags" 701.It Ic class: 702Class of the lock. 703Possible types include 704.Xr mutex 9 , 705.Xr rmlock 9 , 706.Xr rwlock 9 , 707.Xr sx 9 . 708.It Ic name: 709Name of the lock. 710.It Ic flags: 711Flags passed to the lock initialization function. 712For exact possibilities see manual pages of possible lock types. 713.It Ic state: 714Current state of a lock. 715As well as 716.Ic flags 717it's lock-specific. 718.It Ic owner: 719Lock owner. 720.El 721.\" 722.Pp 723.It Ic show Cm lockchain Ar addr 724Show all threads a particular thread at address 725.Ar addr 726is waiting on based on non-sleepable and non-spin locks. 727.\" 728.Pp 729.It Ic show Cm lockedbufs 730Show the same information as "show buf", but for every locked 731.Vt struct buf 732object. 733.\" 734.Pp 735.It Ic show Cm lockedvnods 736List all locked vnodes in the system. 737.\" 738.Pp 739.It Ic show Cm locks 740Prints all locks that are currently acquired. 741This command is only available if 742.Xr witness 4 743is included in the kernel. 744.\" 745.Pp 746.It Ic show Cm locktree 747.\" 748.Pp 749.It Ic show Cm malloc 750Prints 751.Xr malloc 9 752memory allocator statistics. 753The output format is as follows: 754.Pp 755.Bl -tag -compact -offset indent -width "Requests" 756.It Ic Type 757Specifies a type of memory. 758It is the same as a description string used while defining the 759given memory type with 760.Xr MALLOC_DECLARE 9 . 761.It Ic InUse 762Number of memory allocations of the given type, for which 763.Xr free 9 764has not been called yet. 765.It Ic MemUse 766Total memory consumed by the given allocation type. 767.It Ic Requests 768Number of memory allocation requests for the given 769memory type. 770.El 771.Pp 772The same information can be gathered in userspace with 773.Dq Nm vmstat Fl m . 774.\" 775.Pp 776.It Ic show Cm map Ns Oo Li / Ns Cm f Oc Ar addr 777Prints the VM map at 778.Ar addr . 779If the 780.Cm f 781modifier is specified the 782complete map is printed. 783.\" 784.Pp 785.It Ic show Cm msgbuf 786Print the system's message buffer. 787It is the same output as in the 788.Dq Nm dmesg 789case. 790It is useful if you got a kernel panic, attached a serial cable 791to the machine and want to get the boot messages from before the 792system hang. 793.\" 794.It Ic show Cm mount 795Displays short info about all currently mounted file systems. 796.Pp 797.It Ic show Cm mount Ar addr 798Displays details about the given mount point. 799.Pp 800.\" 801.Pp 802.It Ic show Cm object Ns Oo Li / Ns Cm f Oc Ar addr 803Prints the VM object at 804.Ar addr . 805If the 806.Cm f 807option is specified the 808complete object is printed. 809.\" 810.Pp 811.It Ic show Cm page 812Show statistics on VM pages. 813.\" 814.Pp 815.It Ic show Cm pageq 816Show statistics on VM page queues. 817.\" 818.Pp 819.It Ic show Cm pciregs 820Print PCI bus registers. 821The same information can be gathered in userspace by running 822.Dq Nm pciconf Fl lv . 823.\" 824.Pp 825.It Ic show Cm pcpu 826Print current processor state. 827The output format is as follows: 828.Pp 829.Bl -tag -compact -offset indent -width "spin locks held:" 830.It Ic cpuid 831Processor identifier. 832.It Ic curthread 833Thread pointer, process identifier and the name of the process. 834.It Ic curpcb 835Control block pointer. 836.It Ic fpcurthread 837FPU thread pointer. 838.It Ic idlethread 839Idle thread pointer. 840.It Ic APIC ID 841CPU identifier coming from APIC. 842.It Ic currentldt 843LDT pointer. 844.It Ic spin locks held 845Names of spin locks held. 846.El 847.\" 848.Pp 849.It Ic show Cm pgrpdump 850Dump process groups present within the system. 851.\" 852.Pp 853.It Ic show Cm proc Op Ar addr 854If no 855.Op Ar addr 856is specified, print information about the current process. 857Otherwise, show information about the process at address 858.Ar addr . 859.\" 860.Pp 861.It Ic show Cm procvm 862Show process virtual memory layout. 863.\" 864.Pp 865.It Ic show Cm protosw Ar addr 866Print protocol switch structure 867.Vt struct protosw 868at address 869.Ar addr . 870.\" 871.Pp 872.It Ic show Cm registers Ns Op Li / Ns Cm u 873Display the register set. 874If the 875.Cm u 876modifier is specified, it displays user registers instead of 877kernel registers or the currently saved one. 878.Pp 879.Sy Warning : 880The support of the 881.Cm u 882modifier depends on the machine. 883If not supported, incorrect information will be displayed. 884.\" 885.Pp 886.It Ic show Cm rman Ar addr 887Show resource manager object 888.Vt struct rman 889at address 890.Ar addr . 891Addresses of particular pointers can be gathered with "show allrman" 892command. 893.\" 894.Pp 895.It Ic show Cm rtc 896Show real time clock value. 897Useful for long debugging sessions. 898.\" 899.Pp 900.It Ic show Cm sleepchain 901Show all the threads a particular thread is waiting on based on 902sleepable locks. 903.\" 904.Pp 905.It Ic show Cm sleepq 906.It Ic show Cm sleepqueue 907Both commands provide the same functionality. 908They show sleepqueue 909.Vt struct sleepqueue 910structure. 911Sleepqueues are used within the 912.Fx 913kernel to implement sleepable 914synchronization primitives (thread holding a lock might sleep or 915be context switched), which at the time of writing are: 916.Xr condvar 9 , 917.Xr sx 9 918and standard 919.Xr msleep 9 920interface. 921.\" 922.Pp 923.It Ic show Cm sockbuf Ar addr 924.It Ic show Cm socket Ar addr 925Those commands print 926.Vt struct sockbuf 927and 928.Vt struct socket 929objects placed at 930.Ar addr . 931Output consists of all values present in structures mentioned. 932For exact interpretation and more details, visit 933.Pa sys/socket.h 934header file. 935.\" 936.Pp 937.It Ic show Cm sysregs 938Show system registers (e.g., 939.Li cr0-4 940on i386.) 941Not present on some platforms. 942.\" 943.Pp 944.It Ic show Cm tcpcb Ar addr 945Print TCP control block 946.Vt struct tcpcb 947lying at address 948.Ar addr . 949For exact interpretation of output, visit 950.Pa netinet/tcp.h 951header file. 952.\" 953.Pp 954.It Ic show Cm thread Op Ar addr 955If no 956.Ar addr 957is specified, show detailed information about current thread. 958Otherwise, information about thread at 959.Ar addr 960is printed. 961.\" 962.Pp 963.It Ic show Cm threads 964Show all threads within the system. 965Output format is as follows: 966.Pp 967.Bl -tag -compact -offset indent -width "Second column" 968.It Ic First column 969Thread identifier (TID) 970.It Ic Second column 971Thread structure address 972.It Ic Third column 973Backtrace. 974.El 975.\" 976.Pp 977.It Ic show Cm tty Ar addr 978Display the contents of a TTY structure in a readable form. 979.\" 980.Pp 981.It Ic show Cm turnstile Ar addr 982Show turnstile 983.Vt struct turnstile 984structure at address 985.Ar addr . 986Turnstiles are structures used within the 987.Fx 988kernel to implement 989synchronization primitives which, while holding a specific type of lock, cannot 990sleep or context switch to another thread. 991Currently, those are: 992.Xr mutex 9 , 993.Xr rwlock 9 , 994.Xr rmlock 9 . 995.\" 996.Pp 997.It Ic show Cm uma 998Show UMA allocator statistics. 999Output consists five columns: 1000.Pp 1001.Bl -tag -compact -offset indent -width "Requests" 1002.It Cm "Zone" 1003Name of the UMA zone. 1004The same string that was passed to 1005.Xr uma_zcreate 9 1006as a first argument. 1007.It Cm "Size" 1008Size of a given memory object (slab). 1009.It Cm "Used" 1010Number of slabs being currently used. 1011.It Cm "Free" 1012Number of free slabs within the UMA zone. 1013.It Cm "Requests" 1014Number of allocations requests to the given zone. 1015.El 1016.Pp 1017The very same information might be gathered in the userspace 1018with the help of 1019.Dq Nm vmstat Fl z 1020.\" 1021.Pp 1022.It Ic show Cm unpcb Ar addr 1023Shows UNIX domain socket private control block 1024.Vt struct unpcb 1025present at the address 1026.Ar addr 1027.\" 1028.Pp 1029.It Ic show Cm vmochk 1030Prints, whether the internal VM objects are in a map somewhere 1031and none have zero ref counts. 1032.\" 1033.Pp 1034.It Ic show Cm vmopag 1035This is supposed to show physical addresses consumed by a 1036VM object. 1037Currently, it is not possible to use this command when 1038.Xr witness 4 1039is compiled in the kernel. 1040.\" 1041.Pp 1042.It Ic show Cm vnode Op Ar addr 1043Prints vnode 1044.Vt struct vnode 1045structure lying at 1046.Op Ar addr . 1047For the exact interpretation of the output, look at the 1048.Pa sys/vnode.h 1049header file. 1050.\" 1051.Pp 1052.It Ic show Cm vnodebufs Ar addr 1053Shows clean/dirty buffer lists of the vnode located at 1054.Ar addr . 1055.\" 1056.Pp 1057.It Ic show Cm watches 1058Displays all watchpoints. 1059Shows watchpoints set with "watch" command. 1060.\" 1061.Pp 1062.It Ic show Cm witness 1063Shows information about lock acquisition coming from the 1064.Xr witness 4 1065subsystem. 1066.\" 1067.Pp 1068.It Ic gdb 1069Toggles between remote GDB and DDB mode. 1070In remote GDB mode, another machine is required that runs 1071.Xr gdb 1 1072using the remote debug feature, with a connection to the serial 1073console port on the target machine. 1074Currently only available on the 1075i386 1076architecture. 1077.Pp 1078.It Ic halt 1079Halt the system. 1080.Pp 1081.It Ic kill Ar sig pid 1082Send signal 1083.Ar sig 1084to process 1085.Ar pid . 1086The signal is acted on upon returning from the debugger. 1087This command can be used to kill a process causing resource contention 1088in the case of a hung system. 1089See 1090.Xr signal 3 1091for a list of signals. 1092Note that the arguments are reversed relative to 1093.Xr kill 2 . 1094.Pp 1095.It Ic reboot Op Ar seconds 1096.It Ic reset Op Ar seconds 1097Hard reset the system. 1098If the optional argument 1099.Ar seconds 1100is given, the debugger will wait for this long, at most a week, 1101before rebooting. 1102.Pp 1103.It Ic help 1104Print a short summary of the available commands and command 1105abbreviations. 1106.Pp 1107.It Ic capture on 1108.It Ic capture off 1109.It Ic capture reset 1110.It Ic capture status 1111.Nm 1112supports a basic output capture facility, which can be used to retrieve the 1113results of debugging commands from userpsace using 1114.Xr sysctl 2 . 1115.Ic capture on 1116enables output capture; 1117.Ic capture off 1118disables capture. 1119.Ic capture reset 1120will clear the capture buffer and disable capture. 1121.Ic capture status 1122will report current buffer use, buffer size, and disposition of output 1123capture. 1124.Pp 1125Userspace processes may inspect and manage 1126.Nm 1127capture state using 1128.Xr sysctl 8 : 1129.Pp 1130.Dv debug.ddb.capture.bufsize 1131may be used to query or set the current capture buffer size. 1132.Pp 1133.Dv debug.ddb.capture.maxbufsize 1134may be used to query the compile-time limit on the capture buffer size. 1135.Pp 1136.Dv debug.ddb.capture.bytes 1137may be used to query the number of bytes of output currently in the capture 1138buffer. 1139.Pp 1140.Dv debug.ddb.capture.data 1141returns the contents of the buffer as a string to an appropriately privileged 1142process. 1143.Pp 1144This facility is particularly useful in concert with the scripting and 1145.Xr textdump 4 1146facilities, allowing scripted debugging output to be captured and 1147committed to disk as part of a textdump for later analysis. 1148The contents of the capture buffer may also be inspected in a kernel core dump 1149using 1150.Xr kgdb 1 . 1151.Pp 1152.It Ic run 1153.It Ic script 1154.It Ic scripts 1155.It Ic unscript 1156Run, define, list, and delete scripts. 1157See the 1158.Sx SCRIPTING 1159section for more information on the scripting facility. 1160.Pp 1161.It Ic textdump set 1162.It Ic textdump status 1163.It Ic textdump unset 1164The 1165.Ic textdump set 1166command may be used to force the next kernel core dump to be a textdump 1167rather than a traditional memory dump or minidump. 1168.Ic textdump status 1169reports whether a textdump has been scheduled. 1170.Ic textdump unset 1171cancels a request to perform a textdump as the next kernel core dump. 1172More information may be found in 1173.Xr textdump 4 . 1174.El 1175.Sh VARIABLES 1176The debugger accesses registers and variables as 1177.Li $ Ns Ar name . 1178Register names are as in the 1179.Dq Ic show Cm registers 1180command. 1181Some variables are suffixed with numbers, and may have some modifier 1182following a colon immediately after the variable name. 1183For example, register variables can have a 1184.Cm u 1185modifier to indicate user register (e.g., 1186.Dq Li $eax:u ) . 1187.Pp 1188Built-in variables currently supported are: 1189.Pp 1190.Bl -tag -width ".Va tabstops" -compact 1191.It Va radix 1192Input and output radix. 1193.It Va maxoff 1194Addresses are printed as 1195.Dq Ar symbol Ns Li + Ns Ar offset 1196unless 1197.Ar offset 1198is greater than 1199.Va maxoff . 1200.It Va maxwidth 1201The width of the displayed line. 1202.It Va lines 1203The number of lines. 1204It is used by the built-in pager. 1205.It Va tabstops 1206Tab stop width. 1207.It Va work Ns Ar xx 1208Work variable; 1209.Ar xx 1210can take values from 0 to 31. 1211.El 1212.Sh EXPRESSIONS 1213Most expression operators in C are supported except 1214.Ql ~ , 1215.Ql ^ , 1216and unary 1217.Ql & . 1218Special rules in 1219.Nm 1220are: 1221.Bl -tag -width ".No Identifiers" 1222.It Identifiers 1223The name of a symbol is translated to the value of the symbol, which 1224is the address of the corresponding object. 1225.Ql \&. 1226and 1227.Ql \&: 1228can be used in the identifier. 1229If supported by an object format dependent routine, 1230.Sm off 1231.Oo Ar filename : Oc Ar func : lineno , 1232.Sm on 1233.Oo Ar filename : Oc Ns Ar variable , 1234and 1235.Oo Ar filename : Oc Ns Ar lineno 1236can be accepted as a symbol. 1237.It Numbers 1238Radix is determined by the first two letters: 1239.Ql 0x : 1240hex, 1241.Ql 0o : 1242octal, 1243.Ql 0t : 1244decimal; otherwise, follow current radix. 1245.It Li \&. 1246.Va dot 1247.It Li + 1248.Va next 1249.It Li .. 1250address of the start of the last line examined. 1251Unlike 1252.Va dot 1253or 1254.Va next , 1255this is only changed by 1256.Ic examine 1257or 1258.Ic write 1259command. 1260.It Li ' 1261last address explicitly specified. 1262.It Li $ Ns Ar variable 1263Translated to the value of the specified variable. 1264It may be followed by a 1265.Ql \&: 1266and modifiers as described above. 1267.It Ar a Ns Li # Ns Ar b 1268A binary operator which rounds up the left hand side to the next 1269multiple of right hand side. 1270.It Li * Ns Ar expr 1271Indirection. 1272It may be followed by a 1273.Ql \&: 1274and modifiers as described above. 1275.El 1276.Sh SCRIPTING 1277.Nm 1278supports a basic scripting facility to allow automating tasks or responses to 1279specific events. 1280Each script consists of a list of DDB commands to be executed sequentially, 1281and is assigned a unique name. 1282Certain script names have special meaning, and will be automatically run on 1283various 1284.Nm 1285events if scripts by those names have been defined. 1286.Pp 1287The 1288.Ic script 1289command may be used to define a script by name. 1290Scripts consist of a series of 1291.Nm 1292commands separated with the 1293.Ic ; 1294character. 1295For example: 1296.Bd -literal -offset indent 1297script kdb.enter.panic=bt; show pcpu 1298script lockinfo=show alllocks; show lockedvnods 1299.Ed 1300.Pp 1301The 1302.Ic scripts 1303command lists currently defined scripts. 1304.Pp 1305The 1306.Ic run 1307command execute a script by name. 1308For example: 1309.Bd -literal -offset indent 1310run lockinfo 1311.Ed 1312.Pp 1313The 1314.Ic unscript 1315command may be used to delete a script by name. 1316For example: 1317.Bd -literal -offset indent 1318unscript kdb.enter.panic 1319.Ed 1320.Pp 1321These functions may also be performed from userspace using the 1322.Xr ddb 8 1323command. 1324.Pp 1325Certain scripts are run automatically, if defined, for specific 1326.Nm 1327events. 1328The follow scripts are run when various events occur: 1329.Bl -tag -width kdb.enter.powerfail 1330.It Dv kdb.enter.acpi 1331The kernel debugger was entered as a result of an 1332.Xr acpi 4 1333event. 1334.It Dv kdb.enter.bootflags 1335The kernel debugger was entered at boot as a result of the debugger boot 1336flag being set. 1337.It Dv kdb.enter.break 1338The kernel debugger was entered as a result of a serial or console break. 1339.It Dv kdb.enter.cam 1340The kernel debugger was entered as a result of a 1341.Xr CAM 4 1342event. 1343.It Dv kdb.enter.mac 1344The kernel debugger was entered as a result of an assertion failure in the 1345.Xr mac_test 4 1346module of the 1347TrustedBSD MAC Framework. 1348.It Dv kdb.enter.ndis 1349The kernel debugger was entered as a result of an 1350.Xr ndis 4 1351breakpoint event. 1352.It Dv kdb.enter.netgraph 1353The kernel debugger was entered as a result of a 1354.Xr netgraph 4 1355event. 1356.It Dv kdb.enter.panic 1357.Xr panic 9 1358was called. 1359.It Dv kdb.enter.powerfail 1360The kernel debugger was entered as a result of a powerfail NMI on the sparc64 1361platform. 1362.It Dv kdb.enter.powerpc 1363The kernel debugger was entered as a result of an unimplemented interrupt 1364type on the powerpc platform. 1365.It Dv kdb.enter.sysctl 1366The kernel debugger was entered as a result of the 1367.Dv debug.kdb.enter 1368sysctl being set. 1369.It Dv kdb.enter.trapsig 1370The kernel debugger was entered as a result of a trapsig event on the sparc64 1371or sun4v platform. 1372.It Dv kdb.enter.unionfs 1373The kernel debugger was entered as a result of an assertion failure in the 1374union file system. 1375.It Dv kdb.enter.unknown 1376The kernel debugger was entered, but no reason has been set. 1377.It Dv kdb.enter.vfslock 1378The kernel debugger was entered as a result of a VFS lock violation. 1379.It Dv kdb.enter.watchdog 1380The kernel debugger was entered as a result of a watchdog firing. 1381.It Dv kdb.enter.witness 1382The kernel debugger was entered as a result of a 1383.Xr witness 4 1384violation. 1385.El 1386.Pp 1387In the event that none of these scripts is found, 1388.Nm 1389will attempt to execute a default script: 1390.Bl -tag -width kdb.enter.powerfail 1391.It Dv kdb.enter.default 1392The kernel debugger was entered, but a script exactly matching the reason for 1393entering was not defined. 1394This can be used as a catch-all to handle cases not specifically of interest; 1395for example, 1396.Dv kdb.enter.witness 1397might be defined to have special handling, and 1398.Dv kdb.enter.default 1399might be defined to simply panic and reboot. 1400.El 1401.Sh HINTS 1402On machines with an ISA expansion bus, a simple NMI generation card can be 1403constructed by connecting a push button between the A01 and B01 (CHCHK# and 1404GND) card fingers. 1405Momentarily shorting these two fingers together may cause the bridge chipset to 1406generate an NMI, which causes the kernel to pass control to 1407.Nm . 1408Some bridge chipsets do not generate a NMI on CHCHK#, so your mileage may vary. 1409The NMI allows one to break into the debugger on a wedged machine to 1410diagnose problems. 1411Other bus' bridge chipsets may be able to generate NMI using bus specific 1412methods. 1413.Sh FILES 1414Header files mention in this manual page can be found below 1415.Pa /usr/include 1416directory. 1417.Pp 1418.Bl -dash -compact 1419.It 1420.Pa sys/buf.h 1421.It 1422.Pa sys/domain.h 1423.It 1424.Pa netinet/in_pcb.h 1425.It 1426.Pa sys/socket.h 1427.It 1428.Pa sys/vnode.h 1429.El 1430.Sh SEE ALSO 1431.Xr gdb 1 , 1432.Xr kgdb 1 , 1433.Xr acpi 4 , 1434.Xr CAM 4 , 1435.Xr mac_test 4 , 1436.Xr ndis 4 , 1437.Xr netgraph 4 , 1438.Xr textdump 4 , 1439.Xr witness 4 , 1440.Xr ddb 8 , 1441.Xr sysctl 8 , 1442.Xr panic 9 1443.Sh HISTORY 1444The 1445.Nm 1446debugger was developed for Mach, and ported to 1447.Bx 386 0.1 . 1448This manual page translated from 1449.Xr man 7 1450macros by 1451.An Garrett Wollman . 1452.Pp 1453.An Robert N. M. Watson 1454added support for 1455.Nm 1456output capture, 1457.Xr textdump 4 1458and scripting in 1459.Fx 7.1 . 1460