This section provides examples of useful debugging tasks. The tasks in this section can be performed with either mdb or kmdb unless specifically noted. This section assumes a basic knowledge of the use of kmdb and mdb. Note that the information presented here is dependent on the type of system used. A Sun Blade 100 workstation running the 64-bit kernel was used to produce these examples.
Because irreversible destruction of data can result from modifying data in kernel structures, you should exercise extreme caution. Do not modify or rely on data in structures that are not part of the Oracle Solaris DDI. See the Intro(9S) man page for information on structures that are part of the Oracle Solaris DDI.
The kmdb debugger can display machine registers as a group or individually. To display all registers as a group, use $r as shown in the following example.
[0]: $r g0 0 l0 0 g1 100130a4 debug_enter l1 edd00028 g2 10411c00 tsbmiss_area+0xe00 l2 10449c90 g3 10442000 ti_statetbl+0x1ba l3 1b g4 3000061a004 l4 10474400 ecc_syndrome_tab+0x80 g5 0 l5 3b9aca00 g6 0 l6 0 g7 2a10001fd40 l7 0 o0 0 i0 0 o1 c i1 10449e50 o2 20 i2 0 o3 300006b2d08 i3 10 o4 0 i4 0 o5 0 i5 b0 sp 2a10001b451 fp 2a10001b521 o7 1001311c debug_enter+0x78 i7 1034bb24 zsa_xsint+0x2c4 y 0 tstate: 1604 (ccr=0x0, asi=0x0, pstate=0x16, cwp=0x4) pstate: ag:0 ie:1 priv:1 am:0 pef:1 mm:0 tle:0 cle:0 mg:0 ig:0 winreg: cur:4 other:0 clean:7 cansave:1 canrest:5 wstate:14 tba 0x10000000 pc edd000d8 edd000d8: ta %icc,%g0 + 125 npc edd000dc edd000dc: nop |
The debugger exports each register value to a variable with the same name as the register. If you read the variable, the current value of the register is returned. If you write to the variable, the value of the associated machine register is changed. The following example changes the value of the %o0 register from 0 to 1 on an x86 machine.
[0]> &<eax=K c1e6e0f0 [0]> 0>eax [0]> &<eax=K 0 [0]> c1e6e0f0>eax |
If you need to inspect the registers of a different processor, you can use the ::cpuregs dcmd. The ID of the processor to be examined can be supplied as either the address to the dcmd or as the value of the -c option, as shown in the following example.
[0]> 0::cpuregs %cs = 0x0158 %eax = 0xc1e6e0f0 kmdbmod`kaif_dvec %ds = 0x0160 %ebx = 0x00000000 |
The following example switches from processor 0 to processor 3 on a SPARC machine. The %g3 register is inspected and then cleared. To confirm the new value, %g3 is read again.
[0]> 3::switch [3]> <g3=K 24 [3]> 0>g3 [3]> <g3 0 |
The ::findleaks dcmd provides powerful, efficient detection of memory leaks in kernel crash dumps. The full set of kernel-memory debugging features must be enabled for ::findleaks to be effective. For more information, see Setting kmem_flags Debugging Flags. Run ::findleaks during driver development and testing to detect code that leaks memory, thus wasting kernel resources. See Chapter 9, Debugging With the Kernel Memory Allocator, in Oracle Solaris Modular Debugger Guide for a complete discussion of ::findleaks.
Code that leaks kernel memory can render the system vulnerable to denial-of-service attacks.
The mdb debugger provides a powerful API for implementing debugger facilities that you customize to debug your driver. The Oracle Solaris Modular Debugger Guide explains the programming API in detail.
The SUNWmdbdm package installs sample mdb source code in the directory /usr/demo/mdb. You can use mdb to automate lengthy debugging chores or help to validate that your driver is behaving properly. You can also package your mdb debugging modules with your driver product. With packaging, these facilities are available to service personnel at a customer site.
The Oracle Solaris kernel provides data type information in structures that can be inspected with either kmdb or mdb.
The kmdb and mdb dcmds can be used only with objects that contain compressed symbolic debugging information that has been designed for use with mdb. This information is currently available only for certain Oracle Solaris kernel modules. The SUNWzlib package must be installed to process the symbolic debugging information.
The following example demonstrates how to display the data in the scsi_pkt structure.
> 7079ceb0::print -t 'struct scsi_pkt' { opaque_t pkt_ha_private = 0x7079ce20 struct scsi_address pkt_address = { struct scsi_hba_tran *a_hba_tran = 0x70175e68 ushort_t a_target = 0x6 uchar_t a_lun = 0 uchar_t a_sublun = 0 } opaque_t pkt_private = 0x708db4d0 int (*)() *pkt_comp = sd_intr uint_t pkt_flags = 0 int pkt_time = 0x78 uchar_t *pkt_scbp = 0x7079ce74 uchar_t *pkt_cdbp = 0x7079ce64 ssize_t pkt_resid = 0 uint_t pkt_state = 0x37 uint_t pkt_statistics = 0 uchar_t pkt_reason = 0 } |
The size of a data structure can be useful in debugging. Use the ::sizeof dcmd to obtain the size of a structure, as shown in the following example.
> ::sizeof struct scsi_pkt sizeof (struct scsi_pkt) = 0x58 |
The address of a specific member within a structure is also useful in debugging. Several methods are available for determining a member's address.
Use the ::offsetof dcmd to obtain the offset for a given member of a structure, as in the following example.
> ::offsetof struct scsi_pkt pkt_state offsetof (struct pkt_state) = 0x48 |
Use the ::print dcmd with the -a option to display the addresses of all members of a structure, as in the following example.
> ::print -a struct scsi_pkt { 0 pkt_ha_private 8 pkt_address { ... } 18 pkt_private ... } |
If an address is specified with ::print in conjunction with the -a option, the absolute address for each member is displayed.
> 10000000::print -a struct scsi_pkt { 10000000 pkt_ha_private 10000008 pkt_address { ... } 10000018 pkt_private ... } |
The ::print, ::sizeof and ::offsetof dcmds enable you to debug problems when your driver interacts with the Oracle Solaris kernel.
This facility provides access to raw kernel data structures. You can examine any structure whether or not that structure appears as part of the DDI. Therefore, you should refrain from relying on any data structure that is not explicitly part of the DDI.
These dcmds should be used only with objects that contain compressed symbolic debugging information that has been designed for use with mdb. Symbolic debugging information is currently available for certain Oracle Solaris kernel modules only. The SUNWzlib (32-bit) or SUNWzlibx (64-bit) decompression software must be installed to process the symbolic debugging information. The kmdb debugger can process symbolic type data with or without the SUNWzlib or SUNWzlibx packages.
The mdb debugger provides the ::prtconf dcmd for displaying the kernel device tree. The output of the ::prtconf dcmd is similar to the output of the prtconf(1M) command.
> ::prtconf 300015d3e08 SUNW,Sun-Blade-100 300015d3c28 packages (driver not attached) 300015d3868 SUNW,builtin-drivers (driver not attached) 300015d3688 deblocker (driver not attached) 300015d34a8 disk-label (driver not attached) 300015d32c8 terminal-emulator (driver not attached) 300015d30e8 obp-tftp (driver not attached) 300015d2f08 dropins (driver not attached) 300015d2d28 kbd-translator (driver not attached) 300015d2b48 ufs-file-system (driver not attached) 300015d3a48 chosen (driver not attached) 300015d2968 openprom (driver not attached) |
You can display the node by using a macro, such as the ::devinfo dcmd, as shown in the following example.
> 300015d3e08::devinfo 300015d3e08 SUNW,Sun-Blade-100 System properties at 0x300015abdc0: name='relative-addressing' type=int items=1 value=00000001 name='MMU_PAGEOFFSET' type=int items=1 value=00001fff name='MMU_PAGESIZE' type=int items=1 value=00002000 name='PAGESIZE' type=int items=1 value=00002000 Driver properties at 0x300015abe00: name='pm-hardware-state' type=string items=1 value='no-suspend-resume' |
Use ::prtconf to see where your driver has attached in the device tree, and to display device properties. You can also specify the verbose (-v) flag to ::prtconf to display the properties for each device node, as follows.
> ::prtconf -v DEVINFO NAME 300015d3e08 SUNW,Sun-Blade-100 System properties at 0x300015abdc0: name='relative-addressing' type=int items=1 value=00000001 name='MMU_PAGEOFFSET' type=int items=1 value=00001fff name='MMU_PAGESIZE' type=int items=1 value=00002000 name='PAGESIZE' type=int items=1 value=00002000 Driver properties at 0x300015abe00: name='pm-hardware-state' type=string items=1 value='no-suspend-resume' ... 300015ce798 pci10b9,5229, instance #0 Driver properties at 0x300015ab980: name='target2-dcd-options' type=any items=4 value=00.00.00.a4 name='target1-dcd-options' type=any items=4 value=00.00.00.a2 name='target0-dcd-options' type=any items=4 value=00.00.00.a4 |
Another way to locate instances of your driver is the ::devbindings dcmd. Given a driver name, the command displays a list of all instances of the named driver as demonstrated in the following example.
> ::devbindings dad 300015ce3d8 ide-disk (driver not attached) 300015c9a60 dad, instance #0 System properties at 0x300015ab400: name='lun' type=int items=1 value=00000000 name='target' type=int items=1 value=00000000 name='class_prop' type=string items=1 value='ata' name='type' type=string items=1 value='ata' name='class' type=string items=1 value='dada' ... 300015c9880 dad, instance #1 System properties at 0x300015ab080: name='lun' type=int items=1 value=00000000 name='target' type=int items=1 value=00000002 name='class_prop' type=string items=1 value='ata' name='type' type=string items=1 value='ata' name='class' type=string items=1 value='dada' |
A common problem when debugging a driver is retrieving the soft state for a particular driver instance. The soft state is allocated with the ddi_soft_state_zalloc(9F) routine. The driver can obtain the soft state through ddi_get_soft_state(9F). The name of the soft state pointer is the first argument to ddi_soft_state_init(9F)). With the name, you can use mdb to retrieve the soft state for a particular driver instance through the ::softstate dcmd:
> *bst_state::softstate 0x3 702b7578 |
In this case, ::softstate is used to fetch the soft state for instance 3 of the bst sample driver. This pointer references a bst_soft structure that is used by the driver to track state for this instance.
You can use both kmdb and mdb to modify kernel variables or other kernel state. Kernel state modification with mdb should be done with care, because mdb does not stop the kernel before making modifications. Groups of modifications can be made atomically by using kmdb, because kmdb stops the kernel before allowing access by the user. The mdb debugger is capable of making single atomic modifications only.
Be sure to use the proper format specifier to perform the modification. The formats are:
w – Writes the lowest two bytes of the value of each expression to the target beginning at the location specified by dot
W – Writes the lowest 4 bytes of the value of each expression to the target beginning at the location specified by dot
Z – Write the complete 8 bytes of the value of each expression to the target beginning at the location specified by dot
Use the ::sizeof dcmd to determine the size of the variable to be modified.
The following example overwrites the value of moddebug with the value 0x80000000.
> moddebug/W 0x80000000 moddebug: 0 = 0x80000000 |