1========================== 2Coresight CPU Debug Module 3========================== 4 5 :Author: Leo Yan <leo.yan@linaro.org> 6 :Date: April 5th, 2017 7 8Introduction 9------------ 10 11Coresight CPU debug module is defined in ARMv8-a architecture reference manual 12(ARM DDI 0487A.k) Chapter 'Part H: External debug', the CPU can integrate 13debug module and it is mainly used for two modes: self-hosted debug and 14external debug. Usually the external debug mode is well known as the external 15debugger connects with SoC from JTAG port; on the other hand the program can 16explore debugging method which rely on self-hosted debug mode, this document 17is to focus on this part. 18 19The debug module provides sample-based profiling extension, which can be used 20to sample CPU program counter, secure state and exception level, etc; usually 21every CPU has one dedicated debug module to be connected. Based on self-hosted 22debug mechanism, Linux kernel can access these related registers from mmio 23region when the kernel panic happens. The callback notifier for kernel panic 24will dump related registers for every CPU; finally this is good for assistant 25analysis for panic. 26 27 28Implementation 29-------------- 30 31- During driver registration, it uses EDDEVID and EDDEVID1 - two device ID 32 registers to decide if sample-based profiling is implemented or not. On some 33 platforms this hardware feature is fully or partially implemented; and if 34 this feature is not supported then registration will fail. 35 36- At the time this documentation was written, the debug driver mainly relies on 37 information gathered by the kernel panic callback notifier from three 38 sampling registers: EDPCSR, EDVIDSR and EDCIDSR: from EDPCSR we can get 39 program counter; EDVIDSR has information for secure state, exception level, 40 bit width, etc; EDCIDSR is context ID value which contains the sampled value 41 of CONTEXTIDR_EL1. 42 43- The driver supports a CPU running in either AArch64 or AArch32 mode. The 44 registers naming convention is a bit different between them, AArch64 uses 45 'ED' for register prefix (ARM DDI 0487A.k, chapter H9.1) and AArch32 uses 46 'DBG' as prefix (ARM DDI 0487A.k, chapter G5.1). The driver is unified to 47 use AArch64 naming convention. 48 49- ARMv8-a (ARM DDI 0487A.k) and ARMv7-a (ARM DDI 0406C.b) have different 50 register bits definition. So the driver consolidates two difference: 51 52 If PCSROffset=0b0000, on ARMv8-a the feature of EDPCSR is not implemented; 53 but ARMv7-a defines "PCSR samples are offset by a value that depends on the 54 instruction set state". For ARMv7-a, the driver checks furthermore if CPU 55 runs with ARM or thumb instruction set and calibrate PCSR value, the 56 detailed description for offset is in ARMv7-a ARM (ARM DDI 0406C.b) chapter 57 C11.11.34 "DBGPCSR, Program Counter Sampling Register". 58 59 If PCSROffset=0b0010, ARMv8-a defines "EDPCSR implemented, and samples have 60 no offset applied and do not sample the instruction set state in AArch32 61 state". So on ARMv8 if EDDEVID1.PCSROffset is 0b0010 and the CPU operates 62 in AArch32 state, EDPCSR is not sampled; when the CPU operates in AArch64 63 state EDPCSR is sampled and no offset are applied. 64 65 66Clock and power domain 67---------------------- 68 69Before accessing debug registers, we should ensure the clock and power domain 70have been enabled properly. In ARMv8-a ARM (ARM DDI 0487A.k) chapter 'H9.1 71Debug registers', the debug registers are spread into two domains: the debug 72domain and the CPU domain. 73:: 74 75 +---------------+ 76 | | 77 | | 78 +----------+--+ | 79 dbg_clock -->| |**| |<-- cpu_clock 80 | Debug |**| CPU | 81 dbg_power_domain -->| |**| |<-- cpu_power_domain 82 +----------+--+ | 83 | | 84 | | 85 +---------------+ 86 87For debug domain, the user uses DT binding "clocks" and "power-domains" to 88specify the corresponding clock source and power supply for the debug logic. 89The driver calls the pm_runtime_{put|get} operations as needed to handle the 90debug power domain. 91 92For CPU domain, the different SoC designs have different power management 93schemes and finally this heavily impacts external debug module. So we can 94divide into below cases: 95 96- On systems with a sane power controller which can behave correctly with 97 respect to CPU power domain, the CPU power domain can be controlled by 98 register EDPRCR in driver. The driver firstly writes bit EDPRCR.COREPURQ 99 to power up the CPU, and then writes bit EDPRCR.CORENPDRQ for emulation 100 of CPU power down. As result, this can ensure the CPU power domain is 101 powered on properly during the period when access debug related registers; 102 103- Some designs will power down an entire cluster if all CPUs on the cluster 104 are powered down - including the parts of the debug registers that should 105 remain powered in the debug power domain. The bits in EDPRCR are not 106 respected in these cases, so these designs do not support debug over 107 power down in the way that the CoreSight / Debug designers anticipated. 108 This means that even checking EDPRSR has the potential to cause a bus hang 109 if the target register is unpowered. 110 111 In this case, accessing to the debug registers while they are not powered 112 is a recipe for disaster; so we need preventing CPU low power states at boot 113 time or when user enable module at the run time. Please see chapter 114 "How to use the module" for detailed usage info for this. 115 116 117Device Tree Bindings 118-------------------- 119 120See Documentation/devicetree/bindings/arm/arm,coresight-cpu-debug.yaml for 121details. 122 123 124How to use the module 125--------------------- 126 127If you want to enable debugging functionality at boot time, you can add 128"coresight_cpu_debug.enable=1" to the kernel command line parameter. 129 130The driver also can work as module, so can enable the debugging when insmod 131module:: 132 133 # insmod coresight_cpu_debug.ko debug=1 134 135When boot time or insmod module you have not enabled the debugging, the driver 136uses the debugfs file system to provide a knob to dynamically enable or disable 137debugging: 138 139To enable it, write a '1' into /sys/kernel/debug/coresight_cpu_debug/enable:: 140 141 # echo 1 > /sys/kernel/debug/coresight_cpu_debug/enable 142 143To disable it, write a '0' into /sys/kernel/debug/coresight_cpu_debug/enable:: 144 145 # echo 0 > /sys/kernel/debug/coresight_cpu_debug/enable 146 147As explained in chapter "Clock and power domain", if you are working on one 148platform which has idle states to power off debug logic and the power 149controller cannot work well for the request from EDPRCR, then you should 150firstly constraint CPU idle states before enable CPU debugging feature; so can 151ensure the accessing to debug logic. 152 153If you want to limit idle states at boot time, you can use "nohlt" or 154"cpuidle.off=1" in the kernel command line. 155 156At the runtime you can disable idle states with below methods: 157 158It is possible to disable CPU idle states by way of the PM QoS 159subsystem, more specifically by using the "/dev/cpu_dma_latency" 160interface (see Documentation/power/pm_qos_interface.rst for more 161details). As specified in the PM QoS documentation the requested 162parameter will stay in effect until the file descriptor is released. 163For example:: 164 165 # exec 3<> /dev/cpu_dma_latency; echo 0 >&3 166 ... 167 Do some work... 168 ... 169 # exec 3<>- 170 171The same can also be done from an application program. 172 173Disable specific CPU's specific idle state from cpuidle sysfs (see 174Documentation/admin-guide/pm/cpuidle.rst):: 175 176 # echo 1 > /sys/devices/system/cpu/cpu$cpu/cpuidle/state$state/disable 177 178Output format 179------------- 180 181Here is an example of the debugging output format:: 182 183 ARM external debug module: 184 coresight-cpu-debug 850000.debug: CPU[0]: 185 coresight-cpu-debug 850000.debug: EDPRSR: 00000001 (Power:On DLK:Unlock) 186 coresight-cpu-debug 850000.debug: EDPCSR: handle_IPI+0x174/0x1d8 187 coresight-cpu-debug 850000.debug: EDCIDSR: 00000000 188 coresight-cpu-debug 850000.debug: EDVIDSR: 90000000 (State:Non-secure Mode:EL1/0 Width:64bits VMID:0) 189 coresight-cpu-debug 852000.debug: CPU[1]: 190 coresight-cpu-debug 852000.debug: EDPRSR: 00000001 (Power:On DLK:Unlock) 191 coresight-cpu-debug 852000.debug: EDPCSR: debug_notifier_call+0x23c/0x358 192 coresight-cpu-debug 852000.debug: EDCIDSR: 00000000 193 coresight-cpu-debug 852000.debug: EDVIDSR: 90000000 (State:Non-secure Mode:EL1/0 Width:64bits VMID:0) 194