/* htop - Row.c (C) 2004-2015 Hisham H. Muhammad (C) 2020-2023 Red Hat, Inc. All Rights Reserved. Released under the GNU GPLv2+, see the COPYING file in the source distribution for its full text. */ #include "config.h" // IWYU pragma: keep #include "Row.h" #include #include #include #include #include #include #include #include "CRT.h" #include "DynamicColumn.h" #include "Hashtable.h" #include "Machine.h" #include "Macros.h" #include "Process.h" #include "RichString.h" #include "Settings.h" #include "XUtils.h" int Row_pidDigits = ROW_MIN_PID_DIGITS; int Row_uidDigits = ROW_MIN_UID_DIGITS; void Row_init(Row* this, const Machine* host) { this->host = host; this->tag = false; this->showChildren = true; this->show = true; this->wasShown = false; this->updated = false; } void Row_done(Row* this) { assert(this != NULL); (void) this; } static inline bool Row_isNew(const Row* this) { const Machine* host = this->host; if (host->monotonicMs < this->seenStampMs) return false; const Settings* settings = host->settings; return host->monotonicMs - this->seenStampMs <= 1000 * (uint64_t)settings->highlightDelaySecs; } static inline bool Row_isTomb(const Row* this) { return this->tombStampMs > 0; } void Row_display(const Object* cast, RichString* out) { const Row* this = (const Row*) cast; const Settings* settings = this->host->settings; const RowField* fields = settings->ss->fields; for (int i = 0; fields[i]; i++) As_Row(this)->writeField(this, out, fields[i]); if (Row_isHighlighted(this)) RichString_setAttr(out, CRT_colors[PROCESS_SHADOW]); if (this->tag == true) RichString_setAttr(out, CRT_colors[PROCESS_TAG]); if (settings->highlightChanges) { if (Row_isTomb(this)) out->highlightAttr = CRT_colors[PROCESS_TOMB]; else if (Row_isNew(this)) out->highlightAttr = CRT_colors[PROCESS_NEW]; } assert(RichString_size(out) > 0); } void Row_setPidColumnWidth(pid_t maxPid) { if (maxPid < (int)pow(10, ROW_MIN_PID_DIGITS)) { Row_pidDigits = ROW_MIN_PID_DIGITS; return; } Row_pidDigits = (int)log10(maxPid) + 1; assert(Row_pidDigits <= ROW_MAX_PID_DIGITS); } void Row_setUidColumnWidth(uid_t maxUid) { if (maxUid < (uid_t)pow(10, ROW_MIN_UID_DIGITS)) { Row_uidDigits = ROW_MIN_UID_DIGITS; return; } Row_uidDigits = (int)log10(maxUid) + 1; assert(Row_uidDigits <= ROW_MAX_UID_DIGITS); } uint8_t Row_fieldWidths[LAST_PROCESSFIELD] = { 0 }; void Row_resetFieldWidths(void) { for (size_t i = 0; i < LAST_PROCESSFIELD; i++) { if (!Process_fields[i].autoWidth) continue; size_t len = strlen(Process_fields[i].title); assert(len <= UINT8_MAX); Row_fieldWidths[i] = (uint8_t)len; } } void Row_updateFieldWidth(RowField key, size_t width) { if (width > UINT8_MAX) Row_fieldWidths[key] = UINT8_MAX; else if (width > Row_fieldWidths[key]) Row_fieldWidths[key] = (uint8_t)width; } // helper function to fill an aligned title string for a dynamic column static const char* alignedTitleDynamicColumn(const Settings* settings, int key, char* titleBuffer, size_t titleBufferSize) { const DynamicColumn* column = Hashtable_get(settings->dynamicColumns, key); if (column == NULL) return "- "; int width = column->width; if (!width || abs(width) > DYNAMIC_MAX_COLUMN_WIDTH) width = DYNAMIC_DEFAULT_COLUMN_WIDTH; xSnprintf(titleBuffer, titleBufferSize, "%*s ", width, column->heading); return titleBuffer; } // helper function to fill an aligned title string for a process field static const char* alignedTitleProcessField(ProcessField field, char* titleBuffer, size_t titleBufferSize) { const char* title = Process_fields[field].title; if (!title) return "- "; if (Process_fields[field].pidColumn) { xSnprintf(titleBuffer, titleBufferSize, "%*s ", Row_pidDigits, title); return titleBuffer; } if (field == ST_UID) { xSnprintf(titleBuffer, titleBufferSize, "%*s ", Row_uidDigits, title); return titleBuffer; } if (Process_fields[field].autoWidth) { if (Process_fields[field].autoTitleRightAlign) xSnprintf(titleBuffer, titleBufferSize, "%*s ", Row_fieldWidths[field], title); else xSnprintf(titleBuffer, titleBufferSize, "%-*.*s ", Row_fieldWidths[field], Row_fieldWidths[field], title); return titleBuffer; } return title; } // helper function to create an aligned title string for a given field const char* RowField_alignedTitle(const Settings* settings, RowField field) { static char titleBuffer[UINT8_MAX + sizeof(" ")]; assert(sizeof(titleBuffer) >= DYNAMIC_MAX_COLUMN_WIDTH + sizeof(" ")); assert(sizeof(titleBuffer) >= ROW_MAX_PID_DIGITS + sizeof(" ")); assert(sizeof(titleBuffer) >= ROW_MAX_UID_DIGITS + sizeof(" ")); if (field < LAST_PROCESSFIELD) return alignedTitleProcessField((ProcessField)field, titleBuffer, sizeof(titleBuffer)); return alignedTitleDynamicColumn(settings, field, titleBuffer, sizeof(titleBuffer)); } RowField RowField_keyAt(const Settings* settings, int at) { const RowField* fields = (const RowField*) settings->ss->fields; RowField field; int x = 0; for (int i = 0; (field = fields[i]); i++) { int len = strlen(RowField_alignedTitle(settings, field)); if (at >= x && at <= x + len) { return field; } x += len; } return COMM; } void Row_printKBytes(RichString* str, unsigned long long number, bool coloring) { char buffer[16]; int len; int color = CRT_colors[PROCESS]; int nextUnitColor = CRT_colors[PROCESS]; const int colors[4] = { [0] = CRT_colors[PROCESS], [1] = CRT_colors[PROCESS_MEGABYTES], [2] = CRT_colors[PROCESS_GIGABYTES], [3] = CRT_colors[LARGE_NUMBER] }; if (number == ULLONG_MAX) goto invalidNumber; if (coloring) { color = colors[0]; nextUnitColor = colors[1]; } if (number < 1000) { // Plain number, no markings len = xSnprintf(buffer, sizeof(buffer), "%5u ", (unsigned int)number); RichString_appendnAscii(str, color, buffer, len); return; } if (number < 100000) { // 2 digits for M, 3 digits for K len = xSnprintf(buffer, sizeof(buffer), "%2u", (unsigned int)(number / 1000)); RichString_appendnAscii(str, nextUnitColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%03u ", (unsigned int)(number % 1000)); RichString_appendnAscii(str, color, buffer, len); return; } // 100000 KiB (97.6 MiB) or greater. A unit prefix would be added. const size_t maxUnitIndex = (sizeof(number) * CHAR_BIT - 1) / 10 + 1; const bool canOverflow = maxUnitIndex >= ARRAYSIZE(unitPrefixes); size_t i = 1; int prevUnitColor; // Convert KiB to (1/100) of MiB unsigned long long hundredths = (number / 256) * 25 + (number % 256) * 25 / 256; while (true) { if (canOverflow && i >= ARRAYSIZE(unitPrefixes)) goto invalidNumber; prevUnitColor = color; color = nextUnitColor; if (coloring && i + 1 < ARRAYSIZE(colors)) nextUnitColor = colors[i + 1]; if (hundredths < 1000000) break; hundredths /= ONE_K; i++; } number = hundredths / 100; hundredths %= 100; if (number < 100) { if (number < 10) { // 1 digit + decimal point + 2 digits // "9.76G", "9.99G", "9.76T", "9.99T", etc. len = xSnprintf(buffer, sizeof(buffer), "%1u", (unsigned int)number); RichString_appendnAscii(str, color, buffer, len); len = xSnprintf(buffer, sizeof(buffer), ".%02u", (unsigned int)hundredths); } else { // 2 digits + decimal point + 1 digit // "97.6M", "99.9M", "10.0G", "99.9G", etc. len = xSnprintf(buffer, sizeof(buffer), "%2u", (unsigned int)number); RichString_appendnAscii(str, color, buffer, len); len = xSnprintf(buffer, sizeof(buffer), ".%1u", (unsigned int)hundredths / 10); } RichString_appendnAscii(str, prevUnitColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%c ", unitPrefixes[i]); } else if (number < 1000) { // 3 digits // "100M", "999M", "100G", "999G", etc. len = xSnprintf(buffer, sizeof(buffer), "%4u%c ", (unsigned int)number, unitPrefixes[i]); } else { // 1 digit + 3 digits // "1000M", "9999M", "1000G", "9999G", etc. assert(number < 10000); len = xSnprintf(buffer, sizeof(buffer), "%1u", (unsigned int)number / 1000); RichString_appendnAscii(str, nextUnitColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%03u%c ", (unsigned int)number % 1000, unitPrefixes[i]); } RichString_appendnAscii(str, color, buffer, len); return; invalidNumber: if (coloring) color = CRT_colors[PROCESS_SHADOW]; RichString_appendAscii(str, color, " N/A "); } void Row_printBytes(RichString* str, unsigned long long number, bool coloring) { if (number == ULLONG_MAX) Row_printKBytes(str, ULLONG_MAX, coloring); else Row_printKBytes(str, number / ONE_K, coloring); } void Row_printCount(RichString* str, unsigned long long number, bool coloring) { char buffer[13]; int largeNumberColor = coloring ? CRT_colors[LARGE_NUMBER] : CRT_colors[PROCESS]; int megabytesColor = coloring ? CRT_colors[PROCESS_MEGABYTES] : CRT_colors[PROCESS]; int shadowColor = coloring ? CRT_colors[PROCESS_SHADOW] : CRT_colors[PROCESS]; int baseColor = CRT_colors[PROCESS]; if (number == ULLONG_MAX) { RichString_appendAscii(str, CRT_colors[PROCESS_SHADOW], " N/A "); } else if (number >= 100000LL * ONE_DECIMAL_T) { xSnprintf(buffer, sizeof(buffer), "%11llu ", number / ONE_DECIMAL_G); RichString_appendnAscii(str, largeNumberColor, buffer, 12); } else if (number >= 100LL * ONE_DECIMAL_T) { xSnprintf(buffer, sizeof(buffer), "%11llu ", number / ONE_DECIMAL_M); RichString_appendnAscii(str, largeNumberColor, buffer, 8); RichString_appendnAscii(str, megabytesColor, buffer + 8, 4); } else if (number >= 10LL * ONE_DECIMAL_G) { xSnprintf(buffer, sizeof(buffer), "%11llu ", number / ONE_DECIMAL_K); RichString_appendnAscii(str, largeNumberColor, buffer, 5); RichString_appendnAscii(str, megabytesColor, buffer + 5, 3); RichString_appendnAscii(str, baseColor, buffer + 8, 4); } else { xSnprintf(buffer, sizeof(buffer), "%11llu ", number); RichString_appendnAscii(str, largeNumberColor, buffer, 2); RichString_appendnAscii(str, megabytesColor, buffer + 2, 3); RichString_appendnAscii(str, baseColor, buffer + 5, 3); RichString_appendnAscii(str, shadowColor, buffer + 8, 4); } } void Row_printTime(RichString* str, unsigned long long totalHundredths, bool coloring) { char buffer[10]; int len; if (totalHundredths == 0) { int shadowColor = coloring ? CRT_colors[PROCESS_SHADOW] : CRT_colors[PROCESS]; RichString_appendAscii(str, shadowColor, " 0:00.00 "); return; } int yearColor = coloring ? CRT_colors[LARGE_NUMBER] : CRT_colors[PROCESS]; int dayColor = coloring ? CRT_colors[PROCESS_GIGABYTES] : CRT_colors[PROCESS]; int hourColor = coloring ? CRT_colors[PROCESS_MEGABYTES] : CRT_colors[PROCESS]; int baseColor = CRT_colors[PROCESS]; unsigned long long totalSeconds = totalHundredths / 100; unsigned long long totalMinutes = totalSeconds / 60; unsigned long long totalHours = totalMinutes / 60; unsigned int seconds = totalSeconds % 60; unsigned int minutes = totalMinutes % 60; if (totalMinutes < 60) { unsigned int hundredths = totalHundredths % 100; len = xSnprintf(buffer, sizeof(buffer), "%2u:%02u.%02u ", (unsigned int)totalMinutes, seconds, hundredths); RichString_appendnAscii(str, baseColor, buffer, len); return; } if (totalHours < 24) { len = xSnprintf(buffer, sizeof(buffer), "%2uh", (unsigned int)totalHours); RichString_appendnAscii(str, hourColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%02u:%02u ", minutes, seconds); RichString_appendnAscii(str, baseColor, buffer, len); return; } unsigned long long totalDays = totalHours / 24; unsigned int hours = totalHours % 24; if (totalDays < 10) { len = xSnprintf(buffer, sizeof(buffer), "%1ud", (unsigned int)totalDays); RichString_appendnAscii(str, dayColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%02uh", hours); RichString_appendnAscii(str, hourColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%02um ", minutes); RichString_appendnAscii(str, baseColor, buffer, len); return; } if (totalDays < /* Ignore leap years */365) { len = xSnprintf(buffer, sizeof(buffer), "%4ud", (unsigned int)totalDays); RichString_appendnAscii(str, dayColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%02uh ", hours); RichString_appendnAscii(str, hourColor, buffer, len); return; } unsigned long long years = totalDays / 365; unsigned int days = totalDays % 365; if (years < 1000) { len = xSnprintf(buffer, sizeof(buffer), "%3uy", (unsigned int)years); RichString_appendnAscii(str, yearColor, buffer, len); len = xSnprintf(buffer, sizeof(buffer), "%03ud ", days); RichString_appendnAscii(str, dayColor, buffer, len); } else if (years < 10000000) { len = xSnprintf(buffer, sizeof(buffer), "%7luy ", (unsigned long)years); RichString_appendnAscii(str, yearColor, buffer, len); } else { RichString_appendAscii(str, yearColor, "eternity "); } } void Row_printNanoseconds(RichString* str, unsigned long long totalNanoseconds, bool coloring) { if (totalNanoseconds == 0) { int shadowColor = coloring ? CRT_colors[PROCESS_SHADOW] : CRT_colors[PROCESS]; RichString_appendAscii(str, shadowColor, " 0ns "); return; } char buffer[10]; int len; int baseColor = CRT_colors[PROCESS]; if (totalNanoseconds < 1000000) { len = xSnprintf(buffer, sizeof(buffer), "%6luns ", (unsigned long)totalNanoseconds); RichString_appendnAscii(str, baseColor, buffer, len); return; } unsigned long long totalMicroseconds = totalNanoseconds / 1000; if (totalMicroseconds < 1000000) { len = xSnprintf(buffer, sizeof(buffer), ".%06lus ", (unsigned long)totalMicroseconds); RichString_appendnAscii(str, baseColor, buffer, len); return; } unsigned long long totalSeconds = totalMicroseconds / 1000000; unsigned long microseconds = totalMicroseconds % 1000000; if (totalSeconds < 60) { int width = 5; unsigned long fraction = microseconds / 10; if (totalSeconds >= 10) { width--; fraction /= 10; } len = xSnprintf(buffer, sizeof(buffer), "%u.%0*lus ", (unsigned int)totalSeconds, width, fraction); RichString_appendnAscii(str, baseColor, buffer, len); return; } if (totalSeconds < 600) { unsigned int minutes = totalSeconds / 60; unsigned int seconds = totalSeconds % 60; unsigned int milliseconds = microseconds / 1000; len = xSnprintf(buffer, sizeof(buffer), "%u:%02u.%03u ", minutes, seconds, milliseconds); RichString_appendnAscii(str, baseColor, buffer, len); return; } unsigned long long totalHundredths = totalMicroseconds / 1000 / 10; Row_printTime(str, totalHundredths, coloring); } void Row_printRate(RichString* str, double rate, bool coloring) { char buffer[16]; int largeNumberColor = CRT_colors[LARGE_NUMBER]; int megabytesColor = CRT_colors[PROCESS_MEGABYTES]; int shadowColor = CRT_colors[PROCESS_SHADOW]; int baseColor = CRT_colors[PROCESS]; if (!coloring) { largeNumberColor = CRT_colors[PROCESS]; megabytesColor = CRT_colors[PROCESS]; } if (!isNonnegative(rate)) { RichString_appendAscii(str, shadowColor, " N/A "); } else if (rate < 0.005) { int len = snprintf(buffer, sizeof(buffer), "%7.2f B/s ", rate); RichString_appendnAscii(str, shadowColor, buffer, len); } else if (rate < ONE_K) { int len = snprintf(buffer, sizeof(buffer), "%7.2f B/s ", rate); RichString_appendnAscii(str, baseColor, buffer, len); } else if (rate < ONE_M) { int len = snprintf(buffer, sizeof(buffer), "%7.2f K/s ", rate / ONE_K); RichString_appendnAscii(str, baseColor, buffer, len); } else if (rate < ONE_G) { int len = snprintf(buffer, sizeof(buffer), "%7.2f M/s ", rate / ONE_M); RichString_appendnAscii(str, megabytesColor, buffer, len); } else if (rate < ONE_T) { int len = snprintf(buffer, sizeof(buffer), "%7.2f G/s ", rate / ONE_G); RichString_appendnAscii(str, largeNumberColor, buffer, len); } else if (rate < ONE_P) { int len = snprintf(buffer, sizeof(buffer), "%7.2f T/s ", rate / ONE_T); RichString_appendnAscii(str, largeNumberColor, buffer, len); } else { int len = snprintf(buffer, sizeof(buffer), "%7.2f P/s ", rate / ONE_P); RichString_appendnAscii(str, largeNumberColor, buffer, len); } } void Row_printLeftAlignedField(RichString* str, int attr, const char* content, unsigned int width) { int columns = width; RichString_appendnWideColumns(str, attr, content, strlen(content), &columns); RichString_appendChr(str, attr, ' ', width + 1 - columns); } int Row_printPercentage(float val, char* buffer, size_t n, uint8_t width, int* attr) { assert(n >= 6 && width >= 4 && "Invalid width in Row_printPercentage()"); // truncate in favour of abort in xSnprintf() width = (uint8_t)CLAMP(width, 4, n - 2); assert(width < n - 1 && "Insufficient space to print column"); if (isNonnegative(val)) { if (val < 0.05F) *attr = CRT_colors[PROCESS_SHADOW]; else if (val >= 99.9F) *attr = CRT_colors[PROCESS_MEGABYTES]; int precision = 1; // Display "val" as "100" for columns like "MEM%". if (width == 4 && val > 99.9F) { precision = 0; val = 100.0F; } return xSnprintf(buffer, n, "%*.*f ", width, precision, val); } *attr = CRT_colors[PROCESS_SHADOW]; return xSnprintf(buffer, n, "%*.*s ", width, width, "N/A"); } void Row_toggleTag(Row* this) { this->tag = !this->tag; } int Row_compare(const void* v1, const void* v2) { const Row* r1 = (const Row*)v1; const Row* r2 = (const Row*)v2; return SPACESHIP_NUMBER(r1->id, r2->id); } int Row_compareByParent_Base(const void* v1, const void* v2) { const Row* r1 = (const Row*)v1; const Row* r2 = (const Row*)v2; int result = SPACESHIP_NUMBER( r1->isRoot ? 0 : Row_getGroupOrParent(r1), r2->isRoot ? 0 : Row_getGroupOrParent(r2) ); if (result != 0) return result; return Row_compare(v1, v2); } const RowClass Row_class = { .super = { .extends = Class(Object), .compare = Row_compare }, };